Glyphosate tolerant plants
Genes encoding a glyphosate oxidoreductase enzyme are disclosed. The genes are useful in producing transformed bacteria and plants which degrade glyphosate herbicide as well as crop plants which are tolerant to glyphosate herbicide.
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This is a continuation of application Ser. No. 08/391,339, filed Feb. 21, 1995; which is a continuation of application Ser. No. 08/156,968, filed Nov. 23, 1993, now abandoned, which is a continuation of application Ser. No. 07/717,370, filed Jun. 24, 1991, now abandoned, which is a continuation in part of application Ser. No. 07/543,236, filed Jun. 25, 1990, now abandoned.BACKGROUND OF THE INVENTION
Recent advances in genetic engineering have provided the requisite tools to transform plants to contain foreign genes. It is now possible to produce plants which have unique characteristics of agronomic importance. Certainly, one such advantageous trait is more cost effective, environmentally compatible weed control via herbicide tolerance. Herbicide-tolerant plants may reduce the need for tillage to control weeds thereby effectively reducing soil erosion.
One herbicide which is the subject of much investigation in this regard is N-phosphonomethyl-glycine commonly referred to as glyphosate. Glyphosate inhibits the shikimic acid pathway which leads to the biosynthesis of aromatic compounds including amino acids and vitamins. Specifically, glyphosate inhibits the conversion of phosphoenolpyruvic acid and 3-phosphoshikimic acid to 5-enolpyruvyl-3-phosphoshikimic acid by inhibiting the enzyme 5-enolpyruvyl-3-phosphoshikimic acid synthase (EPSP synthase or EPSPS).
It has been shown that glyphosate tolerant plants can be produced by inserting into the genome of the plant the capacity to produce a higher level of EPSP synthase which enzyme is preferably glyphosate tolerant (Shah et al., 1986). The introduction into plants of glyphosate degradation gene (s) could provide a means of conferring glyphosate tolerance to plants and/or to augment the tolerance of transgenic plants already expressing a glyphosate tolerant EPSP synthase depending upon the physiological effects of the degradation products.
Glyphosate metabolism (degradation) has been examined in a wide variety of plants and little degradation has been reported in most of those studies. In those instances where degradation has been reported, the initial breakdown product is usually aminomethylphosphonate (AMPA) (Coupland, 1985; Marshall et al., 1987). In these instances, it is not clear if glyphosate is metabolized by the plant or the contaminating microbes on the leaf surface to which glyphosate was applied. AMPA has been reported to be much less phytotoxic than glyphosate for most plant species (Franz, 1985) but not for all plant species (Maier, 1983; Tanaka et al., 1988). Glyphosate degradation in soils is much more extensive and rapid (Torstensson, 1985). The principal breakdown product identified is AMPA (Rueppel et al., 1977; Nomura and Hilton, 1977); a phosphonate that can be metabolized by a wide variety of microorganisms (Zeleznick et al., 1963; Mastalerz et al., 1965; Cook et al., 1978; Daughton et al., 1979a; 1979b; 1979c; Wackett et al., 1987a). A number of pure cultures of bacteria have been identified that degrade glyphosate by one of the two known routes (Moore et al., 1983; Talbot et al., 1984; Shinabarger and Braymer, 1986; Balthazor and Hallas, 1986; Kishore and Jacob, 1987; Wackett et al., 1987a; Pipke et al., 1987a; Pipke et al., 1987b; Hallas et al., 1988; Jacob et al., 1985 and 1988; Pipke and Amrhein, 1988; Quinn et al., 1988 and 1989; Lerbs et al., 1990; Schowanek and Verstraete, 1990; Weidhase et al., 1990; Liu et al., 1991). A route involving a “C-P lyase” that degrades glyphosate to sarcosine and inorganic orthophosphate (Pi) has been reported for a Pseudomonas sp. (Shinabarger and Braymer, 1986; Kishore and Jacob, 1987) and an Arthrobacter sp. (Pipke et al., 1987b). Pure cultures capable of degrading glyphosate to AMPA have been reported for a Flavobacterium sp. (Balthazor and Hallas, 1986), for a Pseudomonas sp. (Jacob et al., 1988) and for Arthrobacter atrocyaneus (Pipke and Amrhein, 1988). In addition, a large number of isolates that convert glyphosate to AMPA have been identified from industrial activated sludges that treat glyphosate wastes (Hallas et al., 1988). However, the number and nature of bacterial genes responsible for these degradations have not been heretofore determined nor have the gene(s) been isolated.
Hence, in one aspect, an object of the present invention is to provide novel genes which encode a glyphosate metabolizing enzyme which converts glyphosate to aminomethylphosphonate and glyoxylate.
Another object is to enhance the activity of the glyphosate metabolizing enzyme against glyphosate by replacement of specific amino acid residues.
Another object of the present invention is to provide genetically modified plants which express a gene which encodes a glyphosate metabolizing enzyme and which exhibit enhanced tolerance to glyphosate herbicide.
Another object is to demonstrate that a glyphosate metabolizing enzyme can be targeted to plastids using chloroplast transit peptides and the plastid targeted enzyme confers high level glyphosate tolerance.
A further object is to provide a method for selecting transformed plant tissue using the glyphosate metabolizing enzyme as the selectable marker in the presence of inhibitory concentrations of glyphosate.
These and other objects, aspects and features of the present invention will become evident to those skilled in the art from the following description and working examples.SUMMARY OF THE INVENTION
The present invention provides structural DNA constructs which encode a glyphosate oxido-reductase enzyme and which are useful in producing glyphosate degradation capability in heterologous microorganisms (e.g. bacteria and plants) and in producing glyphosate tolerant plants.
In accomplishing the foregoing, there is provided, in accordance with one aspect of the present invention, a method of producing genetically transformed plants which are tolerant toward glyphosate herbicide, comprising the steps of:
- (a) inserting into the genome of a. plant cell a recombinant, double-stranded DNA molecule comprising
- (i) a promoter which functions in plant cells to cause the production of an RNA sequence,
- (ii) a structural DNA sequence that causes the production of an RNA sequence which encodes a glyphosate oxidoreductase enzyme,
- (iii) a 3′ non-translated DNA sequence which functions in plant cells to cause the addition of polyadenylated nucleotides to the 3′ end of the RNA sequence;
- (a) inserting into the genome of a. plant cell a recombinant, double-stranded DNA molecule comprising
where the promoter is heterologous with respect to the coding sequence and adapted to cause sufficient expression of said enzyme in plant tissue, including nmeristematic tissue, to enhance the glyphosate resistance of a plant cell transformed with said gene;
- (b) obtaining a transformed plant cell; and
- (c) regenerating from the transformed plant cell a genetically transformed plant which has increased tolerance to glyphosate herbicide.
In accordance with another aspect of the present invention, there is provided a recombinant, double-stranded DNA molecule comprising in sequence:
- (a) a promoter which functions in plants to cause the production of an RNA sequence;
- (b) a structural DNA sequence that causes the production of an RNA sequence which encodes a glyphosate oxidoreductase enzyme; and
- (c) a 3′ non-translated region which functions in plants to cause the addition of polyadenylated nucleotides to the 3′ end of the RNA sequence. There has also been provided, in accordance with another aspect of the present invention, bacterial and transformed plant cells that contain, respectively, DNA comprised of the above-mentioned elements (a), (b) and (c).
In accordance with yet another aspect of the present invention, differentiated plants have been provided that comprise transformed plant cells, as described above, which exhibit tolerance toward glyphosate herbicide.
In accordance with still another aspect of the present invention, there has been provided a method for selectively controlling weeds in a field containing a crop having planted crop seeds or plants comprising the steps of:
- (a) planting said crop seeds or plants which are glyphosate tolerant as a result of a recombinant double-stranded DNA molecule being inserted into said crop seed or plant, said DNA molecule having
- (i) a promoter sequence which functions in plants to cause the production of an RNA sequence,
- (ii) a structural DNA sequence which causes the production of RNA which encodes a glyphosate oxidoreductase enzyme,
- (iii) a 3′ non-translated region which encodes a polyadenylation signal which functions in plants to cause the addition of polyadenylated nucleotides to the 3′ end of the RNA sequence,
- where the promoter is heterologous with respect to the coding sequence and adapted to cause sufficient expression of said enzyme in plant tissue, including meristematic tissue, to enhance the glyphosate tolerance of a plant cell transformed with said gene; and
- (b) applying to said crop and weeds in said field a sufficient amount of glyphosate herbicide to control said weeds without significantly affecting said crop.
- (a) planting said crop seeds or plants which are glyphosate tolerant as a result of a recombinant double-stranded DNA molecule being inserted into said crop seed or plant, said DNA molecule having
In a particularly preferred embodiment the double-stranded DNA molecule comprising a gene for plant expression comprises a structural DNA sequence encoding a fusion polypeptide containing an amino- terminal chloroplast transit peptide which is capable of causing importation of the carboxy-terminal glyphosate oxidoreductase enzyme into the chloroplast of the plant cell expressing said gene.
A further embodiment of the present invention is the use of the glyphosate oxidoreductase gene as a selectable marker to select and identify transformed plant tissue.
Only the changes made in the modified gene are indicated in the lower strand of sequences.
The expression of a plant gene which exists in double-stranded DNA form involves synthesis of messenger RNA (mRNA) from one strand of the DNA by RNA polymerase enzyme, and the subsequent processing of the MLRNA primary transcript inside the nucleus. This processing involves a 3′ signal region which facilitates addition of polyadenylate nucleotides to the 3′ end of the RNA.
Transcription of DNA into mRNA is regulated by a region of DNA usually referred to as the “promoter.” The promoter region contains a sequence of bases that signals RNA polymerase to associate with the DNA, and to initiate the transcription into MLRNA using one of the DNA strands as a template to make a corresponding complementary strand of RNA.
A number of promoters which are active in plant cells have been described in the literature. These include the nopaline synthase (NOS) and octopine synthase (OCS) promoters (which are carried on tumor-inducing plasmids of Agrobacterium tumefaciens), the caulimovirus promoters such as the cauliflower mosaic virus (CaMV) 19S and 35S promoters and the figwort mosaic virus (FMV) 35S promoter, the light-inducible promoter from the small subunit of ribulose bis-phosphate carboxylase (ssRUBISCO, a very abundant plant polypeptide). All of these promoters have been used to create various types of DNA constructs which have been expressed in plants; see, e.g., PCT publication WO 84/02913 (Rogers et al., Monsanto).
Promoters which are known or are found to cause transcription of DNA in plant cells can be used in the present invention. Such promoters may be obtained from a variety of sources such as plants and plant DNA viruses and include, but are not limited to, the CaMV35S and FMV35S promoters and promoters isolated from plant genes such as ssRUBISCO genes or the chlorophyll a/b binding proteins. As described below, it is preferred that the particular promoter selected should be capable of causing sufficient expression to result in the production of an efficient amount of glyphosate oxidoreductase to render the plant substantially tolerant to glyphosate herbicides. The amount of glyphosate oxidoreductase needed to induce the desired tolerance may vary with the plant species.
It is preferred that the promoters utilized have relatively high expression in all meristematic tissues in addition to other tissues inasmuch as it is now known that glyphosate is translocated and accumulated in this type of plant tissue. Alternatively, a combination of chimeric genes can be used to cumulatively result in the necessary overall expression level of glyphosate oxidoreductase enzyme to result in the glyphosate tolerant phenotype.
The MRNA produced by a DNA construct of the present invention also contains a 5′ non-translated leader sequence. This sequence can be derived from the promoter selected to express the gene, and can be specifically modified so as to increase translation of the rnRNA. The 5′ non-translated regions can also be obtained from viral RNAs, from suitable eukaryotic genes, or from a synthetic gene sequence. The present invention is not limited to constructs, as presented in the following examples, wherein the non-translated region is derived from both the 5′ non-translated sequence that accompanies the promoter sequence and part of the 5′ non-translated region of the virus coat protein gene. Rather, the non-translated leader sequence can be derived from an unrelated promoter or coding sequence as discussed above.
A preferred promoter for use in the present invention is the full-length transcript (35S) promoter from the fgwort mosaic virus (FMV) which functions as a strong and uniform promoter for chimeric genes inserted into plants, particularly dicotyledons. In general, the resulting transgenic plants express the protein encoded by the inserted gene at a higher and more uniform level throughout the tissues and cells than the same gene driven by an enhanced CaMV35S promoter. Referring to
The 3′ non-translated region of the chimeric plant gene contains a polyadenylation signal which functions in plants to cause the addition of polyadenylate nucleotides to the 3′ end of the RNA. Examples of suitable 3′ regions are (1) the 3′ transcribed, non-translated regions containing the polyadenylation signal of Agrobacterium tumor-inducing (Ti) plasmid genes, such as the nopaline synthase (NOS) gene, and (2) plant genes such as the soybean storage protein genes and the small subunit of the ribulose-1,5-bisphosphate carboxylase (ssRUBISCO) gene. An example of a preferred 3′ region is that from the ssRUBISCO gene from pea (E9), described in greater detail in the examples below.
The DNA constructs of the present invention also contain a structural coding sequence in double-stranded DNA form, which encodes a glyphosate oxidoreductase enzyme which converts glyphosate to aminomethylphosphonate and glyoxylate.
Summary of the Glyphosate Oxidoreductase Reaction
The enzyme glyphosate oxidoreductase catalyzes the cleavage of the C-N bond of glyphosate yielding aminomethyl phosphonate (AMPA) and glyoxylate as the reaction products. Under aerobic conditions, oxygen is utilized as a cosubstrate for the reaction. Other electron carriers such as phenazine methosulfate and ubiquinone stimulate the reaction under aerobic conditions. In the absence of oxygen, these compounds act as electron acceptors.
The enzymatic reaction can be assayed by oxygen uptake using an oxygen electrode. The glyphosate oxido-reductase from LBAA does not produce hydrogen peroxide as a product of oxygen reduction. This enzyme has a stoichiometry of two moles of glyphosate oxidized per mole of oxygen consumed and produces two moles each of AMPA and glyoxylate as reaction products.
An alternate method for the assay of glyphosate oxidoreductase involves reaction of the sample with 2,4-dinitrophenylhydrazine and determination of the amount of the glyoxylate-2,4-dinitrophenylhydrazone by HPLC analysis as described in detail in a later section.
A third method for the assay of glyphosate oxidoreductase consists of using [3—14C]-glyphosate as a substrate; the radioactive AMPA produced by the enzyme is separated from the substrate by HPLC on anion exchange column as described later. The radioactivity associated with AMPA is a measure of the extent of the glyphosate oxidoreductase reaction.
Glyphosate oxidoreductase from LBAA is a flavoprotein using FAD as a cofactor. One of the mechanisms we have proposed for the reaction catalyzed by this enzyme involves the reduction of the FAD at the active site of the enzyme by glyphosate. This leads to the formation of reduced FAD and a Schiff base of aminomethylphosphonate with glyoxylate. The Schiff base is hydrated by water and hydrolyzed to its components, AMPA and glyoxylate. The reduced flavin is reoxidized by molecular oxygen. We suggest that during the process of reoxidation of reduced FAD, an oxygenated flavin is produced as an intermediate. This flavin intermediate may catalyze the oxygenation of glyphosate yielding AMPA and glyoxylate. This hypothesis is in accordance with the observed stoichiometry and our inability to detect hydrogen peroxide in the reaction mixture.
In addition to glyphosate, glyphosate oxido-reductase from LBAA oxidizes iminodiacetic acid (IDA) to glycine and glyoxylate. The rate of the reaction with IDA is significantly faster than with glyphosate.
Isolation of Efficient Glyphosate-to-AMPA Degrading Bacterium
Bacteria capable of degrading glyphosate are known. (Hallas et al., 1988; Malik et al., 1989). A number of these bacteria were screened for the rapid degradation of glyphosate in the following manner: twenty three bacterial isolates were transferred from TSA (Trypticase Soya Agar; BBL) plates into medium A consisting of Dworkin-Foster salts medium containing glucose, gluconate and citrate (each at 0.1%) as carbon source and containing glyphosate at 0.1 mM as the phosphorous source.
Dworkin-Foster minimal medium was made up by combining in 1 liter (with autoclaved H2O) 1 ml each of A, B and C and 10 ml of D, thiamine HCl (5 mg), C-sources to final concentrations of 0.1% each and P-source (glyphosate or other phosphonates or Pi) to the required concentration:
- A. D-F Salts (1000× stock; per 100 ml; autoclaved):
- H3BO3 1 mg
- MnSO4.7H2O 1 mg
- ZnSO4.7H2O 12.5 mg
- CUSO4.5H2O 8 mg
- NaMoO3.3H2O 1.7 mg
- B. FeSO4.7H2O (1000× stock; per 100 ml; autoclaved)
- 0.1 g
- C. MgSO4.7H2O (1000× stock; per 100 ml; autoclaved)
- 20 g
- D. (NH4)2SO4(100× stock; per 100 ml; autoclaved)
- 20 g
Yeast Extract (YE; Difco) was added to a final concentration of
- 20 g
- 0.01 or 0.001%.
- A. D-F Salts (1000× stock; per 100 ml; autoclaved):
Each 1 ml of culture medium also contained approximately 200,000 cpm [3—14C]glyphosate (Amersham; CFA.745). The cultures were incubated with shaking at 30° C. Isolate LBAA showed significant growth at day one, while other test cultures showed little growth before day three. Determination of radioactivity (by scintillation counting) in the culture, cell pellet and culture supernatant (at day 4) revealed that total 14C radioactivity had decreased and that remaining was partitioned ˜1:1 in the supernatant and pellet, indicating that significant uptake and metabolism of glyphosate had taken place.
At day five, 75 μl of the culture supernatant of all test cultures was analyzed by HPLC as follows: a SYNCHROPAK™AX100 anion exchange column (P.J. Cobert) was used and the mobile phase consisted of 65 mM KH2PO4 (pH5.5 with NaOH; depending on the needs of the experiment the concentration of the phosphate buffer was varied from 50 to 75 mM in order to alter the retention times of the material), run isocratically and the eluted material monitored continuously using a radioactive detector. This analysis revealed, in one isolate in particular (LBAA), that the glyphosate peak (Retention Time [RT]=7.0 minutes in this analysis) was completely absent and a new peak of radioactivity had appeared, with the same RT as methylamine or N-acetylmethylamine (RT=3.5 minutes). The collection of bacteria, of which strain LBAA formed a part, had been characterized as degrading glyphosate to AMPA (Hallas et al., 1988); the detection of methylamine or N-Acetylmethyl-amine suggested that the AMPA or N-AcetylAMPA was being metabolized by the LBAA “C-P lyase” activity to release the phosphate required for growth in this experiment. Strain LBAA was examined in greater detail.
Conversion of Glyphosate in AMPA in Microbial Isolates
For clarity and brevity of disclosure, the following description of the isolation of genes encoding glyphosate oxidoreductase enzymes is directed to the isolation of such a gene from a bacterial isolate (LBAA). Those skilled in the art will recognize that the same or a similar strategy can be utilized to isolate such genes from other microbial isolates.
The glyphosate degradation pathway was characterized in resting cells of glyphosate-grown strain LBAA as follows: the cells from a 100 ml culture of LBAA, grown in DF medium with glucose, gluconate and citrate as carbon sources and with thiamine and Yeast Extract (0.01%) to supply trace requirements (=medium DF3S) and with glyphosate at 0.2 mM as a phosphorous source, were harvested at Klett=200, washed twice with 20 ml of DF3S medium and the equivalent of 20 ml cells resuspended in 100 ul of the same medium containing [3—14C] glyphosate (2.5 ul of 52 mCi/mmol). The cell mix was incubated at 30° C. with shaking and samples (20 ul) were withdrawn at intervals. The samples were centrifuged and both the supernatant and cell pellets were analyzed by HPLC (the cell pellets were resuspended in 100 ul of acid-DF3S [=DF3S, 0.65N HCl], boiled for 5 minutes, centrifuged briefly and this supernatant was analyzed; an acidified glyphosate control was also examined). In two hours the amount of radioactivity in the glyphosate peak (RT=7.8 minutes) in the supernatant had decreased to ˜33% of the starting level; about 3% of the glyphosate was found within the cell. Material co-eluting with the methylamine standard accounted for ˜5% of the starting counts in the supernatant and for ˜1.5% in the cell pellet. A new peak, accounting for ˜1.5% of the starting radioactivity with a RT of 7.7 minutes (glyphosate RT=8.9 minutes upon acidification in this experiment) was identified in the cell contents. The large decrease in overall radioactivity also suggested that the glyphosate was extensively metabolized in this experiment. The pathway was elucidated further in a subsequent experiment where the metabolism of [14C] AMPA was compared to that of [3—14C] glyphosate (as above) in resting cells harvested at Klett 165 and resuspended at the equivalent to 15 ml cells per 100 ul DF3S medium. The samples were analyzed by HPLC and consisted of whole cultures acidified and treated as described above. Within the first two hours of the glyphosate experiment, 25% of the radioactivity was found in the methylamine/N-acetylmethalamine peak (RT=4.8 minutes), 12.5% as AMPA (RT=6.4 minutes), 30% as the peak alluded to above (RT=9.4 minutes) and 30% as glyphosate (RT=11.8 minutes). In the AMPA experiment 15% of the radioactivity was found as N-acetylmethylamine/methyl-amine, 59% as AMPA and 18% in the peak with RT=9.4 minutes. The modified form of AMPA was identified as N-acetylAMPA. A similar acetylation step has been inferred from the products identified in E. coli growing in aminomethylphosphonates as sole sources of P (Avila et al., 1987). These data indicated that the glyphosate degradation pathway in LBAA is glyphosate→AMPA (→methylamine)→N-acetylAMPA→N-acetylmethylamine.
Cloning of the Glyphosate Oxidoreductase Gene(s) in E. coli
Having established the glyphosate-to-AMPA conversion in strain LBAA, a direct approach for the cloning of the gene(s) involved in this conversion into E. coli was investigated. Cloning and genetic techniques, unless otherwise indicated, were generally those described (Maniatis et al., 1982). The cloning strategy was as follows: introduction of a cosmid bank of strain LBAA into E. coli and selection for the glyphosate-to-AMPA gene(s) by requiring growth on glyphosate as a phosphorous (P) source. This selection relied on the use of AMPA generated by the glyphosate metabolizing enzyme as a P source, following the release of the Pi from the AMPA by the E. coli “C-P lyase.” Most E. coli strains are incapable of utilizing phosphonates as P sources upon initial challenge, however these strains usually adapt rapidly, independently of RccA, to utilize phosphonates (become Mpu+) (Wackett et al., 1987b). E coli Mpu+ was isolated from E. coli SR200 (Leu-, Pro-.recA, hsdr, supE, Smr. tona,) as follows: an aliquot of a fresh L-broth culture of E. coli SR200 was plated on MOPS (Neidhardt et al., 1974) complete agar (i.e., contains L-leucine and L-proline at 25 ug/ml and vitamin B1 [thiamine] at 10 ug/ml; agar=DIFCO “Purified”) containing aminomethylphosphonate (AMPA; 0.2 mM; Sigma) as P source.
- MOPS medium is:
- 10 ml 10× MOPS SALTS
- 2 ml 0.5 mg/ml Thiamine HCl
- 1 ml 20% glucose
- 10× MOPS Salts are:
- for 100 ml
- 40 ml 1M MOPS pH7.4
- 4 ml 1M Tiicine pH7.4
- 1 ml 0.01 M FeSO4.7H2O
- 5 ml 1.9 M NH4Cl
- 1 ml 0.276 M K2SO4
- 1 ml 0.5 mM CaCl2
- 1 ml 0.528 M MgCl2
- 10 ml 5M NaCl
- 1 ml 0.5% L-Methionine
- 1 ml Micronutrients
- Micronutrients are:
- 3×10−9M (NH4)6Mn7O24
- 4×10−7M H3BO4
- 3×10−8M CoCl2
- 1.6×10−8M CuSO4
- 8×10−8M MnCl2
- 1×10−8M ZnSO4
Six individual colonies were picked from this plate after three days incubation at 37° C. and streaked on MOPS complete agar containing either AMPA or methylphosphonate (Alfa) as P source. One colony, designated E. coli SR200 Mpu+, was chosen from those that grew equally and uniformly on both phosphonate media.
- MOPS medium is:
Chromosomal DNA was prepared from strain LBAA as follows: The cell pellet from a 100 ml L-Broth (Miller, 1972) late log phase culture of LBAA was resuspended in 10 ml of Solution I (Birnboim and Doly, 1979). SDS was added to a final concentration of 1% and the suspension was subjected to three freeze-thaw cycles, each consisting of immersion in dry ice for 15 minutes and in water at 70° C. for 10 minutes. The lysate was then extracted four times with equal volumes of phenol:chloroform (1:1; phenol saturated with TE) (TE=10 mM Tris pH8.0; 1.0 mM EDTA) and the phases separated by centrifugation (15000 g; 10 minutes). The ethanol-precipitable material was pelleted from the supernatant by brief centrifugation (8000 g; 5 minutes) following addition of two volumes of ethanol. The pellet was resuspended in 5 ml TE and dialyzed for 16 hours at 4° C. against 2 liters TE. This preparation yielded a 6 ml DNA solution of 150 g/ml.
Partially-restricted DNA was prepared as follows: Three 100 jg aliquot samples of LBAA DNA were treated for 1 hour at 37° C. with restriction endonuclease HindIII at rates of 4, 2 and 1 enzyme unit/μg DNA, respectively. The DNA samples were pooled, made 0.25 mM with EDTA and extracted with equal volume of phenol:chloroform. Following the addition of NaAcetate and ethanol, the DNA was precipitated with two volumes of ethanol and pelleted by centrifugation (12000 g; 10 minutes). The dried DNA pellet was resuspended in 500 μl TE and layered on a 10-40% Sucrose gradient (in 5% increments of 5.5 ml each) in 0.5M NaCl, 50 mM Tris pH8.0, 5 mM EDTA. Following centrifugation for 20 hours at 26,000 rpm in a SW28 rotor, the tubes were punctured and 1 ml fractions collected. Fifteen μl samples of each third fraction were run on 0.8% agarose gel and the size of the DNA determined by comparison with linearized lambda DNA and HindIII-digested lambda DNA standards. Fractions containing DNA of 25-35 kb fragments were pooled, desalted on AMICON10 columns (7000 rpm; 20° C.; 45 minutes) and concentrated by precipitation. This procedure yielded 50 μg of LBAA DNA of the required size.
Plasmid pHC79 (Hohn and Collins, 1980) DNA and a HindIII-phosphatase treated vector was prepared as described elsewhere (Maniatis et al., 1982). The ligation conditions were as follows:
The ligated DNA (4 μl) was packaged into lambda phage particles (Stratagene; Gigapack Gold) using the manufacturer's procedure.
E. coli SR200 Mpu+, grown overnight in L-Broth (with maltose at 0.2%), was infected with 50 μl of the packaged DNA. Transformants were selected on MOPS complete agar plus ampicillin and with glyphosate at 0.2 mM as P source.
Aliquot samples were also plated on MOPS (Neidhardt et al., 1974) complete agar plus ampicillin containing Pi at irmM to titer the packaged cosmids. Cosmid transformants were isolated on this latter medium at a rate of ˜105 per μg/LBAA HindIII DNA after 2 days at 37° C. Colonies arose on the glyphosate agar from day 3 until day 10 with a final rate of 1 per 200-300 cosmids. Plasmid DNA was prepared from twenty one cosmid transformants from the glyphosate plates. These cosmids fell into at least two classes based on the HindIII restriction pattern of the plasmid DNA. In Class I, all the cosmids had cloned 6.4 and 4.2 kb HindIII restriction fragments in common and in Class II, a ˜23 kbp fragment in common. Ten cosmids, representative of the diversity of the cloned fragments, were re-transformed into E. coli SR200 Mpu+ and the glyphosate utilization trait verified by selection for growth on MOPS complete agar plus ampicillin plus glyphosate plates. The final cell density achieved by the cultures using glyphosate (0.2 mM in MOPS medium) as a P source was also determined and little difference could be discerned between the different transformants. Transformants were also inoculated into MOPS complete broth with AMPA at 0.1 mM as P source (to ensure the presence of “C-P lyase” activity) and after 24 hours at 37° C. were diluted 100-fold into MOPS complete medium with glyphosate at 0.1 mM and [3—14C] glyphosate (40,000 cpm/ml). All the cosmid-containing cells degraded glyphosate and generated N-acetylAMPA and N-acetylmethylamine, with no great difference in the rate. The N-acetylAMPA was found in the culture supernatant in these tests. One cosmid from Class I, identified as pMON7468, was chosen for further study. A second glyphosate oxidoreductase gene has been identified from a Class II cosmid clone.
Cell-free lysates E. coli SR200 Mpu+/pMON7468 were prepared from cells grown on MOPS complete medium with glyphosate at 1.0 mM (and supplemented with L-phenylalanine, L-tyrosine and L-tryptophan each at 100 μg/ml and with para-hydroxybenzoic acid, 2,3-dihydroxybenzoic acid and para-aminobenzoic acid each at 5 μg/ml to minimize the effects of inhibition of the E. coli EPSP synthase). The cell pellet (approx. 0.5 g wet weight) was resuspended in 1 ml of lysis buffer (40 mM MOPS, pH7.4; 4 mM Tricine, pH 7.4; 10% glycerol; 1 mM DTT) and passed twice through a French Press. The cell debris was removed by centrifugation at 15000 rpm for 10 minutes. The supernatant was assayed, following addition of MgCl2 to 10 mM, for degradation of radiolabeled glyphosate. The glyphosate substrate was supplied as [3—14C] glyphosate (final concentration =17 μM). The products observed were predominantly AMPA and some N-acetylAMPA; the production of AMPA is indicative of the cloned enzymatic activity from strain LBAA but the N-acetylAMPA could be due to endogenous E. coli activities (Avila et al., 1987). The specific activity for AMPA formation under these conditions was 13.3 pmoles AMPA/minute.mg protein.
Characterization of the Glyphosate-to-AMPA Gene
The cloned region responsible for this glyphosate oxidoreductase enzymatic activity was then localized in the cosmid. Deletions of pMON7468 were isolated, primarily within the cloned region, by using restriction enzymes that cut infrequently within the insert, as follows: plasmid DNA samples of 0.5-2 μg were digested to completion with restriction endonucleases NotI, SacI, BglII or BamHI, extracted with phenol:chloroform, ethanol precipitated, resuspended in TE buffer and ligated for 2-4 hours at room temperature (or for 18 hours at 16° C.) in a final volume of 50 μl with ligation buffer and T4 DNA ligase. Transformants were selected in E. coli SR200 Mpu+ and these deletions were examined for loss or retention of the glyphosate utilization phenotype. These data, in conjunction with restriction mapping of the clones, were used to localize the active region to near the central portion of the insert in pMON7468 that included the two common HindIII fragments (6.4 and 4.2 kb). The HindIII restriction fragments from this region were then subcloned into pBlueScript (Stratagene) and their glyphosate phenotype determined in E. coli JM101 Mpu+(the Mpu+ derivative of JM101 was isolated as described for SR200 Mpu+). Clones containing the 6.4 kb HindIII fragment, in either orientation, resulted in glyphosate utilization. Following restriction mapping of this HindIII fragment, a series of deletion clones were isolated from the two 6.4 kb HindIII clones using enzymes that cut infrequently in the insert and also in the polylinker region. A number of restriction fragments internal to the HindIII fragment were also subcloned. The 3.5 kb PstI and 2.5 kb BglII fragments, in either orientation, were positive for glyphosate utilization. These data, combined with those from the deletions, were used to localize the active region to an approximately 1.8 kb BglII-XhoI fragment. In addition, deletions isolated from the 6.4 kb HindIII fragment indicated a minimum coding region size of around 0.7 kb, with the EcoRI and SacI sites probably located within the coding sequences.
The direction of transcription/expression of the locus responsible for the glyphosate-to-AMPA enzymatic activity was determined as follows: E. coli JM101 Mpu+ transformants of pMON7469 #1 and #4 (Clones of the 2.5 kb BglII fragment in the BamHI site of pUC118; opposite orientations) were grown in M9-glucose-thiamine- ampicillin broth, with and without the Plac inducer IPTG, harvested in late log phase (Klett 190-220), cell-free lysates of the four cultures were prepared as described above and were assayed for glyphosate-to-AMPA activity with glyphosate at 17 μM. The highest enzymatic activity was obtained for pMON7469 #1 plus IPTG, where the XhoI site is distal to the Plac, suggesting that the gene(s) were expressed in the BglII-to-XhoI direction.
The only product observed was AMPA, suggesting that the AMPA acetylating activity that was described earlier had been induced in E. coli transformants growing on glyphosate as the P source.
In a later experiment, cell lysates of pMON7469 #1 and pMON7470 (BglII-XhoI 1.8 kb in pUC118; formed from pMON7469 #1 by deletion of the ˜700 bp XhoI-SalI fragment) were assayed for glyphosate-to-AMPA activity with glyphosate at 2 mM (Sp. Act. [3—14C] glyphosate=3.7 mCi/mmol; 0.2 μCi/reaction; cultures grown with IPTG in medium) and much higher enzymatic activities were recorded, reflecting the improved assay conditions.
The proteins encoded by the BglII fragment were determined in vivo using a T7 expression system (Tabor and Richardson, 1985) following cloning of this fragment into the BamHI site in the vector pBlueScript (+) (pMON7471#1, #2; opposite orientations). Test and control plasmids were transformed into E. coli K38 containing pGP1-2 (Tabor and Richardson, 1985) and grown at 30° C. in L-broth (2 ml) with ampicillin and kanamycin (100 and 50 μg/ml, respectively) to a KMett reading of ˜50. An aliquot was removed and the cells collected by centrifugation, washed with M9 salts (Miller, 1972) and resuspended in 1 ml M9 medium containing glucose at 0.2%, thiamine at 20 μg/ml and containing the 18 amino acids at 0.01% (minus cysteine and methionine). Following incubation at 30° C. for 90 minutes, the cultures were transferred to a 42° C. water bath and held there for 15 minutes. Rifampicin (Sigma) was added to 200 μg/ml and the cultures held at 42° C. for 10 additional minutes and then transferred to 30° C. for 20 minutes. Samples were pulsed with 10 μCi of 35S-methionine for 5 minutes at 30° C., the cells collected by centrifugation and suspended in 60-120 μl cracking buffer (60 mM Tris-HCl 6.8/1% SDS/1% 2-mercaptoethanol/10% glycerol/0.01% bromophenol blue). Aliquot samples were electrophoresed on 12.5% SDS-PAGE and following soaking for 60 minutes in 10 volumes of Acetic Acid-Methanol-water (10:30:60), the gel was soaked in ENLIGHTNING™ (DUPONT) following manufacturer's directions, dried, and exposed at −70° C. to X-Ray Film. Proteins labeled using 35S-methionine were detected only for the BglII-to-XhoI direction, the largest about 45 kd in size. When the BglII-XhoI fragment was examined following cloning into the BamHI-XhoI sites of pBlueScript (to form pMON7472), this ˜45 kd protein was still expressed.
The effect of expression of the glyphosate-to-AMPA activity on glyphosate tolerance of E. coli was determined initially by examining the growth of recombinants in media containing inhibitory concentrations of glyphosate. The test compared the growth of E. coli JM101 containing a control vector (pUC118; Viera and Messing, 1987) or the pUC118 clones of the 2.5 kb BglII fragment (pMON7469#1, #4). There was a very clear correlation between the glyphosate-utilization ability and glyphosate tolerance. This tolerance phenotype (resistance to 15 mM glyphosate) was then employed as a screen to quickly monitor for the phenotype of deletion clones such as pMON7470 (BgIII-XhoI 1.8 kb in pUC118; formed from pMON7469 #1 by deletion of the ˜700 bp XhoI-SalI fragment) and later clones.
Nucleotide Sequence of the Structural Glyphosate Oxidoreductase Gene
The nucleotide sequence of the BglII-XhoI fragment (SEQ ID NO:3) was determined using single-stranded DNA templates (generated using the phagemid clones and the “helper” M13 phage R408) and the commercially available SEQUENASE™(International Biotechnologies, Inc.) kit. Computer analysis of the sequence (SEQ ID NO:3) revealed a single large open reading frame (ORF) in the BglII to XhoI direction and is presented in
There were two methionine codons (AUG; located at positions 120 and 186) that if used as the fMet would give rise to proteins of 46.140 and 44.002 kd, respectively, but neither was preceded by a clearly recognizable Shine-Dalgarno sequence.
The start of the protein was delineated more precisely as follows: BglII restriction site recognition sequences were introduced at positions upstream of the two potential start codons by site-directed mutagenesis of pMON7470, substituting AGATCT for the sequences AGACTG (“Bg120”) and GTATGC (“Bg186”), 21 and 9 bp upstream of the AUG120and AUG186, respectively. Except where noted, oligonucleotide primers for mutagenesis comprised the sequences to be altered flanked by 8-10 homologous bases on each side. The glyphosate tolerance was determined for the mutated clones. Introduction of the BglII site upstream of AUG120 had no effect on glyphosate tolerance while it was abolished by the mutagenesis that introduced the BglII site upstream of AUG186. The effects of these mutageneses on the ˜45 kd protein were examined by subcloning the mutated sequences into T7 expression vectors using a site in the polylinker of pMON7470 (Kpn I), just upstream of the original BglII site, and the downstream HindIII site. This complete fragment was recloned into p18UT3T7 (PHARMACIA) KpnI-HindIII and tested in vivo as described above. The ˜45 kd protein was still expressed and at comparable levels from both of the “BglII” mutagenized sequences. When the new BglII sites were used as 5′ ends (and the downstream HindIII site) for cloning into the pBlueScript BamHI-HindIII sites, the ˜45 kd protein was still expressed when the new BglII site upstream of AUG120 served as 5′ end, but not when that located upstream of AUG186 was the 5′ end. These data suggest strongly that the AUG120 (or some codon located very close to it) is the N-terminus of the glyphosate oxido- reductase protein. The BglII site introduced upstream of the AUG186 did not result in a prematurely terminated or highly unstable protein and suggests that the predicted coding sequence changes resulting from this mutagenesis (Val18—Cys19→Arg18—Ala19) had severe effects on the activity of the enzyme.
Further data to confirm the location of the N-terminus were obtained by introducing separately (by mutageneses of pMON7470), an NcoI restriction site recognition sequence (CCATGG for CTATGT; changes the second codon from Serine to Alanine) or an NdeI sequence (CATATG for CCTATG) at AUG120 and expressing this ORF using efficient E. coli expression vectors. The expression of the NdeI version is outlined here: the NdeI-HindIII fragment, beginning at the putative AUG, was cloned into pMON2123 (NdeI-HindIII) replacing the ompF-IGF-1 fusion fragment (Wong et al., 1988). The resultant clone was introduced into E. coli JM101 and the cells induced with nalidixic acid as described (Wong et al., 1988) for 2 hours. The resultant protein was indistinguishable in size from the ˜45 kd protein on SDS PAGE and a cell lysate from an induced culture had a glyphosate oxidoreductase specific activity of 12.8 nmoles AMPA/min.mg. When compared in a separate experiment, no differences were observed for the glyphosate oxidoreductase activity when the second codon was Alanine instead of Serine. The structural DNA sequence for the glyphosate oxidoreductase enzyme (SEQ ID NO:4) begins at nucleotide 120 and ends at nucleotide 1415 of the BglII-XhoI fragment of FIG. 2 and the glyphosate oxidoreductese enzyme consists of 431 amino acids (SEQ ID NO:5).
Construction of Glyphosate Oxidoreductase Plant Gene Transformation Vectors
To facilitate the manipulation of the structural glyphosate oxidoreductase gene, the internal EcoRI and NcoI restriction site recognition sequences were removed by sitedirected mutagenesis to substitute the sequence GAATTT for GAATTC and CCACGG for CCATGG, respectively. A glyphosate oxidoreductase coding sequence suitable for introduction into and expression in plant transformation vectors was assembled in the following way: the NcoI (“Met-Ala-”) N-terminus was combined with the NcoI- and EcoRI-deleted coding sequences, and the C-terminus deleted to the Scal site, in a number of cloning steps using the internal SphI and EcoRV restriction sites. In these steps a BglII site was located immediately upstream of the NcoI site and EcoRI and HindIII sites were located immediately downstream from the stop codon. The sequence of this manipulated glyphosate oxidoreductase gene (SEQ ID NO:6) is shown in FIG. 3. The manipulated glyphosate oxidoreductase gene still codes for the wild-type glyphosate oxidoreductase protein. The manipulations do not alter the amino acid sequence of the glyphosate oxidoreductase. This glyphosate oxidoreductase structural sequence (SEQ ID NO:6), as a BglII/NcoI—EcoRI/HindIII fragment of 1321 bp, is readily cloned into an appropriate plant expression cassette. This glyphosate oxidoreductase gene (SEQ ID NO:6) was cloned as a BglII-EcoRI fragment into the plant transformation and expression vector pMON979 to form pMON17073.
Modification and Resynthesis of the Glyphosate Oxidoreductase Gene Sequence
The glyphosate oxidoreductase gene from LBAA contains sequences that could be inimical to high expression of the gene in plants. These sequences include potential polyadenylation sites that are often A+T-rich, a higher G+C% than that frequently found in plant genes (56% versus ˜50%), concentrated stretches of G and C residues, and codons that are not used frequently in plant genes. The high G+C% in the glyphosate oxidoreductase gene has a number of potential consequences including the following: a higher usage of G or C than that found in plant genes in the third position in codons, and the potential to form strong hair-pin structures that may affect expression or stability of the RNA. The reduction in the G+C content of the glyphosate oxidoreductase gene, the disruption of stretches of G's and C's, the elimination of potential polyadenylation sequences, and improvements in the codon usage to that used more frequently in plant genes, could result in higher expression of glyphosate oxidoreductase in plants.
In the first phase of this experiment, selected regions of the gene were modified by site-directed mutagenesis. These modifications were directed primarily (but not exclusively) at reducing the G+C% and at breaking up some of the G+C clusters. The manipulated glyphosate oxidoreductase gene was first recloned into the phagemid vector pMON7258 as a NcoI-IlindIII fragment to form pMON17014. Single stranded DNA was prepared from a dut ung E. coli strain. Seven regions of the gene were modified by site-directed mutagenesis using the primers listed in Table IV and the Bio Rad mutagenesis kit (Catalog #170-3576) and following the protocols provided with this kit.
For the sake of clarity, the reverse complement of the actual primers is presented. The base positions, in the sequences presented in FIG. 2 and in
The resultant gene (SEQ ID NO:7) was confirmed by sequencing and by the ability to provide comparable glyphosate tolerance levels as the manipulated glyphosate oxidoreductase gene control. This modified gene (SEQ ID NO:7) is referred to as “modified glyphosate oxidoreductase.” The G+C% of the glyphosate oxidoreductase gene (SEQ ID NO:6) was reduced from ˜56% in the manipulated version to 52% in the modified version (SEQ ID NO:7). A comparison of the manipulated and modified glyphosate oxidoreductase gene is shown in
A synthetic glyphosate oxidoreductase gene (SEQ ID NO:8) was designed to change as completely as possible those inimical sequences discussed above. In summary, the gene sequence was redesigned to eliminate as much as possible the following sequences or sequence features (while avoiding the introduction of unnecessary restriction sites): stretches of G's and C's of 5 or greater; A+T rich regions (predominantly) that could function as polyadenylation sites or potential RNA destabilization region, and codons not frequently found in plant genes. A comparison of the manipulated (SEQ ID NO:6) and synthetic (SEQ ID NO:8) glyphosate oxidoreductase genes is presented in
Expression of Chloroplast Directed Glyphosate Oxidoreductase
The glyphosate target in plants, the 5-enolpyruvyl-shildmate-3-phosphate 5-enolpyruvyl-shikimate-3-phosphate synthase (EPSPS) enzyme, is located in the chloroplast. Although glyphosate oxidoreductase activity located in the cytoplasm reduces/prevents glyphosate from reaching the chloroplast in the transgenic plant, directing the glyphosate oxidoreductase enzyme to the chloroplast has been found to further minimize the effects of glyphosate on EPSP synthase. Many chloroplast-localized proteins are expressed from nuclear genes as precursors and are targeted to the chloroplast by a chloroplast transit peptide (CTP) that is removed during the import steps. Examples of such chloroplast proteins include the small subunit (SSU) of Ribulose-1,5-bisphosphate carboxylase (RUBISCO), 5-enol-pyruvyl-shikimate-3-phosphate synthase (EPSPS), Ferredoxin, Ferredoxin oxidoreductase, the Light-harvesting-complex protein I and protein II, and Thioredoxin F. It has been demonstrated in vivo and in vitro that non-chloroplast proteins may be targeted to the chloroplast by use of protein fusions with a CTP and that a CTP sequence is sufficient to target a protein to the chloroplast (della-Cioppa et al., 1987).
The glyphosate oxidoreductase protein was targeted to the chloroplast by construction of a fusion between the C-terminus of a CTP and the N-terminus of glypbosate oxidoreductase. In the first example, a specialized CTP, derived from the SSU 1A gene from Arabidopsis thaliana (Timko et al., 1988) was used. This CTP (designated CTP1) was constructed by a combination of site-directed mutageneses. The CTP1 structure (SEQ ID NO:9) (
In the second example, a CTP-glyphosate oxidoreductase fusion was constructed between the Arabidopsis thaliana EPSPS (Klee et al., 1987) CTP and the synthetic glyphosate oxidoreductase coding sequences. The Arabidopsis CTP was first engineered by site-directed mutagenesis to place a SphI restriction site at the CTP processing site. This mutagenesis replaced the Glu-Lys at this location with Cys-Met. The sequence of this CTP, designated CTP2, (SEQ ID NO:10) is shown in FIG. 9. The NcoI site of the synthetic glyphosate oxidoreductase gene (SEQ ID NO:8) was replaced with a SphI site that spans the Met codon. The second codon was converted to one for leucine in this step also. This change had no apparent effect on the in vivo activity of glyphosate oxidoreductase in E. coli. The CTP2-synthetic glyphosate oxidoreductase fusion was cloned into pBlueScript KS(+) and this template was transcribed in vitro using T7 polymerase and the 35S-methionine-labeled material was shown to import into chloroplasts with an efficiency comparable to that for the CTP1-glyphosate oxidoreductase fusion. This CTP2-synthetic glyphosate oxidoreductase fusion was then cloned as a XbaI-BamHI fragment into a plant expression vector to form pMON17164. A structural map of this plasmid is presented in FIG. 12.
The plant vector portion of pMON17164 (
Those skilled in the art will recognize that various chimeric constructs can be made which utilize the functionality of a particular CTP to import the contiguous glyphosate oxidoreductase enzyme into the plant cell chloroplast. The chloroplast import of the glyphosate oxidoreductase can be determined using the following assay.
Chloroplast Uptake Assay
Intact chloroplasts are isolated from lettuce (Latuca sativa, var. longifolia) by centrifugation in Percoll/ficoll gradients as modified from Bartlett et al. (1982). The final pellet of intact chloroplasts is suspended in 0.5 ml of sterile 330 mM sorbitol in 50 mM Hepes-KOH, pH 7.7, assayed for chlorophyll (Arnon, 1949), and adjusted to the final chlorophyll concentration of 4 mg/ml (using sorbitol/Hepes). The yield of intact chloroplasts from a single head of lettuce is 3-6mg chlorophyll.
A typical 300 μl uptake experiment contained 5 mM ATP, 8.3 mM unlabeled methionine, 322 mM sorbitol, 58.3 mM Hepes-KOH (pH 8.0), 50 μl reticulocyte lysate translation products, and intact chloroplasts from L. sativa (200 μg chlorophyll). The uptake mixture is gently rocked at room temperature (in 10×75 mm glass tubes) directly in front of a fiber optic illuminator set at maximum light intensity (150 Watt bulb). Aliquot samples of the uptake mix (about 50 μl) are removed at various times and fractionated over 100 μl silicone-oil gradients (in 150 μl polyethylene tubes) by centrifugation at 11,000×g for 30 seconds. Under these conditions, the intact chloroplasts form a pellet under the silicone-oil layer and the incubation medium (containing the reticulocyte lysate) floats on the surface. After centrifugation, the silicone-oil gradients are immediately frozen in dry ice. The chloroplast pellet is then resuspended in 50-100 μl of lysis buffer (10 mM Hepes-KOH pH 7.5, 1 mM PMSF, 1 mM benzamidine, 5 mM ε-amino-n-caproic acid, and 30 μg/ml aprotinin) and centrifuged at 15,000×g for 20 minutes to pellet the thylakoid membranes. The clear supernatant (stromal proteins) from this spin, and an aliquot of the reticulocyte lysate incubation medium from each uptake experiment, are mixed with an equal volume of 2×SDS-PAGE sample buffer for electrophoresis (see below).
SDS-PAGE is carried out according to Laemmli (1970) in 3-17% (w/v) acrylamide slab gels (60 mm×1.5 mm) with 3% (w/v) acrylamide stacking gels (5 mm×1.5 mm). The gel is fixed for 20-30 minutes in a solution with 40% methanol and 10% acetic acid. Then, the gel is soaked in EN3HANCE™(DuPont) for 20-30 minutes, followed by drying the gel on a gel dryer. The gel is imaged by autoradiography, using an intensifying screen and an overnight exposure to determine whether the glyphosate oxidoreductase is imported into the isolated chloroplasts.
Alternative Isolation Protocol for Other Glyphornk Oxidoreductase Structural Genes
A number of other glyphosate oxidoreductase genes have been identified and cloned, including the second LBAA glyphosate oxidoreductase gene from the Class II cosmid pMON7477. The gene was located, by Southern hybridization, on the ˜23 kb HindIII fragment, discussed in the cloning section above, using the first glyphosate oxidoreductase gene as a probe. Southern analysis also showed PstI and BglII hybridizing bands of ˜3.5 and ˜2.5 kb, respectively. The BglII fragment from pMON7477 was subcloned into the BamHI site of pBlueScript vector. A clone in E. coli JM101 (pMON7482), in which the cloned fragment was oriented relative to the lac promoter as in pMON7469#1, was induced with IPTG and assayed for glyphosate oxidoreductase activity. In this experiment a Sp. Act. of ˜93 nmol/min.mg was obtained. In a later experiment, Class I and Class II cosmids were also isolated following infection of E. coli JM101 with the same packaged cosmid preparation and selection directly for glyphosate tolerance at 3-5 mM glyphosate on M9 media.
A glyphosate oxidoreductase gene has also been subcloned from another microbial isolate, identified originally by its ability to utilize glyphosate as a phosphorous source and later shown to contain a putative glyphosate oxidoreductase gene by hybridization with the LBAA glyphosate oxidoreductase gene probe. This gene was cloned initially in a T7 promoter cosmid by screening for glyphosate tolerance in E. coli HB101/pGP1-2 (Boyer and Rolland-Dussoix, 1969; Tabor and Richardson, 1985) on M9 medium containing glyphosate at 3 mM. The presence of the glyphosate oxidoreductase gene was first indicated by a positive hybridization signal with the LBAA gene and by its location on a 2.5 kb Bglll fragment. This BglII fragment was cloned into the BamHI site in pBlueScript (pMON17183) and expressed from the lac promoter by addition of IPTG. In this experiment a glyphosate oxidoreductase with a specific activity of 53 nmoles/min.mg was obtained, confirming the isolation of the gene by this strategy. The following features have usually been found for these glyphosate oxidoreductase genes: the genes are found (by Southern hybridization using full-length glyphosate oxidoreductase gene probes) on ˜2.5 kb BgLII fragments, on ˜3.5 PstI fragments, contain one EcoRI site within the gene and the genes do not contain a HindIII site.
The high degree of similarity of glyphosate oxidoreductase genes also suggests another way by which new glyphosate oxidoreductase genes may be cloned. The apparent conservation of regions flanking the genes and the absence of certain restriction sites suggests the use of single-stranded oligonucleotide probes to the flanking regions, containing restriction sites for BglII, HindIII, PstI, BamHI, NdeI, or other suitable cloning sites, and PCR (Polymerase Chain Reaction; see Erlich, 1989, for complete details on PCR and its applications) to amplify a glyphosate oxidoreductase gene fragment suitable for cloning. The flanking sequences for 119 bp upstream (SEQ ID NO:11) of the wild-type (LBAA) isolate) glyphosate oxidoreductase gene and for ˜290 bp (SEQ ID NO:12) downstream of the gene are provided in FIG. 2.
Using this PCR approach, glyphosate oxidoreductase genes from a number of sources have been isolated. The presence of the glyphosate oxidoreductase activity was confirmed by cloning the glyphosate oxidoreductase gene from chromosomal DNA prepared from Pseudomonas sp. strain LBr (Jacob et al., 1988) and using primers homologous to the N- and C-termini of the LBAA glyphosate oxidoreductase gene and containing the following suitable restriction cloning sites: 5′-GAGAGACTGT CGACTCCGCG GGAGCATCAT ATG-3′ (SEQ ID NO:13) and 5′-GAACGAATCC AAGCTTCTCA CGACCGCGTA AGTAC-3′ (SEQ ID NO:14). Cyclotherm parameters used for these PCR reactions is as follows:
- Denature at 94° C. for 1 minute;
- Anneal at 60° C. for 2 minutes;
- Polymerize at 72° C. for 3 minutes,
- 30 cycles, no autoextension, linked to 4° C. incubation.
The expected ˜1.3 kb PCR produced was generated and following digestion with NdeI and HindIII, this fragment was cloned into pMON2123 for expression of the encoded enzyme. The glyphosate oxidoreductase activity was measured as described above and the Km for glyphosate was similar to that for enzymes from LBAA which is presented supra.
Bacteria isolated from glyphosate process waste stream treatment facilities may also be capable of converting glyphosate to AMPA. Pseudomonas strains LBAA and LBr are two such examples. Such bacteria may also be isolated de novo from these waste treatment facilities.
A population of bacteria was isolated from a fixed-bed immobilized cell column, which employed Mannville R-635 diatomaceous earth beads, by plating on Tryptone Soy Agar (Difco), containing cylcoheximide at 100 ug/ml, and incubating at 28° C. The column had been run for three months on a waste-water feed from the Monsanto Company's Luling, MS, glyphosate production plant. The column contained 50 mg/ml glyphosate and NH3 as NH4Cl. Total organic carbon was 300 mg/ml and BOD's (Biological Oxygen Demand—a measure of “soft” carbon availability) was less than 30 mg/ml. This treatment column has been described (Heitkamp et al., 1990). One of the predominant members of this population, identified as Agrobacterium sp. strain T10, was found to also grow in minimal broth in which the sole carbon source provided was glyphosate at 10 mM (this broth was made up as for DF medium but with glyphosate substituting for the glucose, gluconate and citrate). Chromosomal DNA was prepared from this isolate and subjected to the same PCR procedure and with the same primers as described above for the strain LBr. A fragment of the correct size was generated and cloned into the E. coli expression vector. The glyphosate oxidoreductase activity was assayed and the Km for glyphosate also determined:
Glyphosate-to-AMPA conversion has been reported for many different soils (see Malik et al., 1989 for a review) and a number of procedures are available for the extraction of total DNA from mixed environment samples such as soil (Holben et al., 1988; Steffan and Atlas, 1988; Tsai and Olson, 1991), indicating the possibility of cloning glyphosate oxidoreductase genes without having to first isolate such a degrading microorganism. Of course, the procedure described for the cloning of the glyphosate oxidoreductase genes, based on the conferring of a glyphosate utilization ability or glyphosate tolerance on E. coli, provides a scheme by which other glyphosate oxidoreductase genes and other glyphosate metabolizing genes may be cloned, without relying on the homology determined for the glyphosate oxidoreductase gene described here. It is possible also to enrich for glyphosate degrading bacteria, for example, by the repeated application of glyphosate to a patch of soil (Quinn et al., 1988, Talbot et al., 1984). This enrichment step might be used to increase the ease with which glyphosate oxidoreductase genes are recovered from soil or other environments.
Evidence for the presence of the glyphosate oxidoreductase gene in soil bacteria and a procedure for the isolation of such genes is outlined in the following: A population of suitable bacteria was enriched for selection of bacteria capable of growing in liquid media with glyphosate (at 10 mM) as a source of carbon (This medium is made up as described for the Dworkin-Foster medium but with the omission of the carbon sources and with Pi as a source of P). The inoculum was provided by extracting soil (from a recently harvested soybean field in Jerseyville, Ill.) and the population selected by successive culturing in the medium described above at 28° C. (cycloheximide was included at 100 μg/ml to prevent growth of fungi). Upon plating on L-agar medium, 5 colony types were identified. Chromosomal DNA was prepared from 2 ml L-broth cultures of these isolates and the presence of the glyphosate oxidoreductase gene was probed using PCR screening. Using the primers GCCGAGATGACCGTGGCCGAAAGC (SEQ ID NO:15) and GGGAATGCCGGATGCTTCAACGGC (SEQ ID NO:16), a DNA fragment of the predicted size was obtained with the chromosomal DNA from one of the isolates (designated S3). The PCR conditions used were as follows: 1 minute at 94° C.; 2 minutes at 40° C.; 3 minutes at 72° C.; 35 cycles. The DNA fragment generated in this way is used as a probe (following radiolabeling) to isolate the S3 glyphosate oxidoreductase gene candidate from a cosmid bank constructed as described for LBAA DNA and greatly facilitates the isolation of other glyphosate oxidoreductase genes. The primers used are homologous to internal sequences in the LBAA glyphosate oxidoreductase gene. The PCR conditions employed allow a fair degree of mismatch in the primers and the result suggests that the glyphosate oxidoreductase gene from S3 may not be as closely related to the other glyphosate oxidoreductase genes that were successfully isolated using the primers to the N- and C-termini of the LBAA gene.
A variety of procedures are available for the isolation of genes. Some of these procedures are based on the knowledge of gene function that allow the design of phenotypic screens to aid in the isolation. Others are based on at least partial DNA sequence information that allow the use of probes or primers with partial or complete homology, or are based on the use of antibodies that detect the gene product. All of these options may be applied to the cloning of glyphosate oxidoreductase genes.
Improvement of the Kinetic Properties of Glyphosate Oxidoreductase
Prior examples of engineered herbicide resistance by enzymatic inactivation of the herbicide have utilized enzymes with an ability to bind and metabilize the herbicides much more efficiently than glyphosate oxidoreductase metabolizes glyphosate. The glyphosate oxidoreductase enzyme has a K for glyphosate of 20-30 mM and, as a result, the reaction rate for the degradation of glyphosate may be enhanced for optimal efficiency in transgenic plants by either lowering the Km or by raising the V.
Random mutagenesis techniques coupled with appropriate selections and/or screens are powerful tools which have been used successfully to generate large numbers of mutagenized gene sequences and potential variants. The same approaches may be used to isolate and to identify glyphosate oxi.doreductase variants with improved glyphosate degradation efficiency. The mutagenesis techniques that may be employed include chemical mutagenesis of bacterial cultures containing the gene of interest or of purified DNA containing this gene and PCR methods used to generate copies of the gene (or portions of it) under conditions that favor misincorporation of nucleotides (errors) into the new strand. An example of such a condition would be carrying out the PCR reaction in the presence of Mn++.
Appropriate in vivo screens for improved variants following the mutagenesis could include those for improved glyphosate tolerance in E. coli or increased growth on glyphosate in Mpu+ strains. For the screen, the glyphosate oxidoreductase gene is cloned into a vector containing a weak bacterial promoter and/or in a replicon with a low copy number. The glyphosate tolerance phenotypes of different glyphosate oxidoreductase constructs have been shown to vary over a range of glyphosate concentrations and to correlate with the level of glyphosate oxidoreductase expression. For example, under uninduced conditions, Placglyphosate oxidoreductase vectors express less glyphosate oxidoreductase than PrecA-glyphosate oxidoreductase vectors and also display lower glyphosate tolerance. The mutagenized gene fragment is cloned into the most suitable vector and the resultant library screened. Variants are selected for their ability to grow at glyphosate levels which inhibit growth of the control strain containing the parent glyphosate oxidoreductase clone. Glyphosate oxidoreductase activity confers on E. coli the ability to convert glyphosate to AMPA and, in suitable E. coli strains, this AMPA can provide a source of phosphate following cleavage of the C-P bond by C-P lyase. Suitable E. coli strains are B strains or Mpu+ derivatives of K strains. The glyphosate oxidoreductase gene confers minimal growth on glyphosate as the sole phosphorus source in strain E. coli JM101 Mpu+ (=GB003). The growth rate on glyphosate has been shown to also correlate with the glyphosate oxidoreductase expression level. The mutagenized glyphosate oxidoreductase gene is cloned into the appropriate vector and the variant library screened by differential growth rates on plates or by culturing in media containing glyphosate as sole phosphorous source. Clones which demonstrate faster growth on plates relative to the control strain are subsequently re-screened by growth curve analysis.
So Glyphosate oxidoreductase variants which have been identified in each selection/screen are cloned into a vector for high-level expression and subjected to enzyme analysis to determine Km and Vmax values for glyphosate. The best glyphosate oxidoreductase variants are purified for complete kinetic characterization. Glyphosate oxidoreductase variants which have been identified with lower Km values and similar or higher Vmax values than wild-type enzyme values are analyzed by nucleic acid sequencing to determine the mutation(s). The goal in isolating variants would be to increase the kcat/Km ratio for glyphosate oxidoreductase-catalyzed glyphosate degradation.
A variant with such improvements was isolated.
The mutagenesis procedure used was that of Mn++-poisoned PCR and the template was a linearized glyphosate oxidoreductase gene plasmid containing the synthetic glyphosate oxidoreductase gene (SEQ ID NO:8). The oligonucleotide primers used were homologous to regions in the vector and flanking the glyphosate oxidoreductase gene. The PCR conditions employed were as follows: 1 minute at 94° C., 2 minutes at 55° C., and 3 minutes at 72° C. and with 35 cycles. A 5:1 ratio of dCTP+dGTP+TTP to dATP was used. The reactions contained MnCl2 at 125, 250, 375, or 500 μM. After the reaction, the amplified product was recloned into a vector containing a weak E. coli promoter. This vector was a pBR327 derivative containing the araBAD promoter and suitable cloning sites. One hundred colonies from this cloning step were then screened in E. coli GB993 for improved glyphosate tolerance and utilization phenotypes in media composed of MOPS minimal medium with glyphosate and Pi or with glyphosate alone, respectively. Growth rates were determined by measuring A550 over a 96 hour period. Three clones were identified that exhibited faster growth rates in these screens. These transformants had a 1.5-2.0-fold faster utilization phenotype. The glyphosate oxidoreductase gene was recloned into the expression vector portion and this phenotype verified. All kinetic analysis was performed on crude E. coli lysates. Putative glyphosate oxidoreductase variant proteins were overexpressed after subcloning the NcoI/HindIII variant glyphosate oxidoreductase gene into PrecA-gene10L expression vector. For overexpression in PrecA-gene10L constructs, GB993 cells containing the vector were induced at a Klett=110-120 in M9 minimal medium with 50 μg/ml nalidixic acid and allowed to grow for 2.5 hours at 37° C. with vigorous shaking. Cells were harvested by centrifugation at 4000 g, 5 minutes at 4° C., and resuspend in 100 mM Tris-HCl, pH 7.1, 1 mM EDTA, 35 mM KCl, 20% glycerol, and 1 mM benzamidine at 3 ml/g cell pellet. Lysates were prepared by breaking the cells in a French press, twice, at 1000 psi. Insoluble debris was removed by centrifugation at 12000 g, 15 minutes at 4° C., and the supernatant was de-salted by passing over a PD-10 column (Sephadex G-25, Pharmacia). The void volume fraction was used as the source of enzyme for kinetic analysis. Protein concentrations were determined using the Bio-Rad protein dye-binding assay. Time and enzyme concentration courses were performed to determine linear ranges. The enzyme assay was performed as follows: lysate and glyphosate oxidoreductase mix (final concentration=0.1M MOPS, 0.01M Tricine, pH 7.4, 0.01 mM FAD, 10 mM MgCl2) in a 100 μl reaction were pre-incubated at 30° C. for 2 minutes prior to the addition of glyphosate (analytical grade stock prepared in water adjusted to pH 7.0 with NaOH). Ten minutes was determined to be the optimal time for the enzyme assay using 10 μg lysate. After 10 minutes at 30° C. with shaking, 0.25 ml dinitrophenylhydrazine (DNPH) reagent (0.5 mg/ml in 0.5M HCl) was added and the reaction was allowed to proceed for an additional 5 minutes at 30° C. with shaking. A 1.5M NaOH solution (400 μl) was then added to the assay mix, and the reaction was continued for 5 minutes at 30° C. with shaking. Enzyme activity was determined from the amount of glyoxylate-DNPH adduct formed by measuring A520 against a standard of glyoxylate. Enzyme assays are performed in duplicate on at least two different single colony isolates of a putative glyphosate oxidoreductase variant. To determine Km and Vmax, enzyme assays were performed over a (0.2-2.0)×Km range of glyphosate concentrations. The Km and Vmax were determined from Lineweaver Burk, Eadie-Hofstee and hyperbolic kinetic plots. Vmax was estimated after determining the amount of immunoreactive glyphosate oxidoreductase protein in lysates by immunoblot analysis as described below. Immunoblot analysis was performed following SDS-PAGE and transfer of protein from the gel to nitrocellulose at 500 mA in a Hoeffer transfer apparatus in 25 mM Tris-HCl, 192 mM glycine containing 0.1% SDS and 25% methanol for 1-2 hours. After transfer, the nitrocellulose was incubated with 50 mM Tris-HCl, pH7.5, 0.9% NaCl, 0.01% Tween 20, 0.02% NaN3 containing 2% bovine serum albumin at room temperature with shaking for at least 30 minutes. After blocking, the same buffer containing a 1:25,000 dilution of goat anti-glyphosate oxidoreductase antiserum was added and the filter was allowed to shake at room temperature for 45 minutes. After incubation with primary glyphosate oxidoreductase antibody, the filter was washed for 45 minutes in buffer without antibody; buffer containing a 1:5000 dilution of rabbit anti-goat alkaline phosphatase-conjugated second antibody (from Pierce) was added and the filter was incubated for 45 minutes at room temperature with shaking. The filter was then washed in buffer without antibody for 30 minutes prior to addition of NBT and BCIP (Promega) to allow color development. Immunoreactive glyphosate oxidoreductase protein was also quantitated by dot blotting the lysate onto nitrocellulose and then processing the filter as described above, except that 125I-Protein G was used for detection. The amount of glyphosate oxidoreductase protein is lysates was determined by counting the dot and comparing the amount of radioactivity against a glyphosate oxidoreductase protein standard. One variant, v.247, showed a 3-4 fold higher specific activity for glyphosate oxidoreductase at 25 mM glyphosate and the immunoblot analysis indicated that this was not due to an elevated glyphosate oxidoreductase protein level. Subsequent assays indicated that this variant had a 10-fold lower Km for lglyphosate than the wild type glyphosate oxidoreductase. In a similar manner the Km for IDA was also determined and these data are presented below.
The glyphosate oxidoreductase gene from v.247 was sequenced (SEQ ID NO:17) and five nucleotide changes wer found. These changes are described in the following as they relate to the codons: GCT to GCC (codon 43), no amino acid change; AGC to GGC (codon 84). Ser to Gly: AAG to AGG (codon 153). Lys to Arg; CAC to CGC (codon 334). His to Arg, and CCA to CCG (codon 362), no amino acid change. The amino acid sequence of the glyphosate oxidoreductase gene from v.247 is presented as SEQ ID NO:18. The importance of these different amino acid changes was determined initially be recloning the altered regions into wild type glyphosate oxidoreductase and determining the effect on glyphosate oxidoreductase activity and kinetics. This was accomplished by recloning the NcoI-NheI fragment (contains codon 84), the NheI-ApaLI fragment (contains codon 153), and the ApaLI-HindIII fragment (contains codon 334), seperately into the wild type gene. These glyphosate oxidoreductase genes were then expressed and the kinetic analyses performed. The data are presented below and indicate that the change that occured in the ApaLI-HindIII fragment (contains codon 334) was responsible solely for the alternative in the enzyme.
This result was confirmed and extended by repeating the His to Arg change at codon 334 and introducing other specific changes at this residue by site-directed mutageneses. The primers used are listed in the following: Arg-CGTTCTCTAC ACTCGTGCTC GTAAGTTGC (SEQ ID NO:19); Lvs-CGTTCTCTAC ACTAAGGCTC GTAAGTTGC (SEQ ID NO:20); Gin-CGTTCTCTAC ACTCAAGCTC GTAAGTTGC (SEQ ID NO:21); and Ala-CGTTCTCTAC ACTGCTGCTC GTAAGTTGC (SEQ ID NO:22) (These sequences are the antisense to those actually used). The presence of these changes was confirmed by sequencing the mutagenized glyphosate oxidoreductase genes and a kinetic analysis of the expressed glyphosate oxidoreductase enzymes was performed. The data are presented in the following and show that a number of substitutions are possible at this position and which result in an enzyme with altered kinetic properties.
Additional mutageneses were performed to change the His334 residue to other amino acids. The primers to accomplish this and the new codon are listed in the following: Trp - CTCTACACTTGGGCTCGTAAGCTTCTTCCAGC (SEQ ID NO:23); le - CTCTACACTATCGCTCGTAAGCTTCTTCCAGC (SEQ ID NO:24); Lau - CTCTACACTCTGGCTCGTAAGCTTCTTCCAGC (SEQ ID NO:25); and Glu - CTCTACACTGAAGCTCGTAAGCTTCTTCCAGC (SEQ ID NO:26) (These sequences are the antisense of those actually used; these primers also add a “silent” HindIII that facilitates the identification of the mutagenized progeny from the population). The GLU334 variant retains substantial glyphosate oxidoreductase activity, while the TRP334, ILE334, and LEU334 variants retain much less activity.
From the first generation variants, those with the highest kcat/Kn ratio are preferably subjected to a second round of mutagenesis followed by subsequent screening and analysis. An alternative approach would be to construct second generation glyphosate oxidoreductase variants by combining single point mutations identified in the first generation variants.PLANT TRANSFORMATION
Plants which can be made glyphosate tolerant by practice of the present invention include, but are not limited to, soybean, cotton, corn, canola, oil seed rape, flax, sugarbeet, sunflower, potato, tobacco, tomato, wheat, rice, alfalfa, lettuce, apple, poplar and pine.
A double-stranded DNA molecule of the present invention (“chimeric gene”) can be inserted into the genome of a plant by any suitable method. Suitable plant transformation vectors include those derived from a Ti plasmid of Agrobacterium tumefaciens, as well as those disclosed, e.g., by Herrera-Estrella (1983), Bevan (1984), Klee (1985) and EPO publication 120.516 (Schilperoort et al.). In addition to plant transformation vectors derived from the Ti or root-inducing (Ri) plasmids of Agrobacterium, alternative methods can be used to insert the DNA constructs of this invention into plant cells. Such methods may involve, for example, the use of liposomes, electroporation, chemicals that increase free DNA uptake, free DNA delivery via microprojectile bombardment, and transformation using viruses or pollen.
The pMON979 plant transformation/expression vector was derived from pMON886 (described below) by replacing the neomycin phosphotransferase typeII (KAN) gene in pMON886 with the 0.89 kb fragment containing the bacterial gentamicin-3-N-acetyltransferase type III (AAC(3)-III) gene (Hayford et al., 1988). The chimeric P-35A/AA(3)-III/NOS 3′ gene encodes gentamicin resistance which permits selection of transformed plant cells. pMON979 also contains a 0.95 kb expression cassette consisting of the enhanced CaMV 35A promoter (Kay et al., 1987), several unique restriction sites, and the NOS 3′ end (P-En-CaMV35S/NOS 3′). The rest of the pMON979 DNA segments are exactly the same as in pMON886.
Plasmid pMON886 is made up of the following segments of DNA. The first is a 0.93 kb AvaI to engineered-EcoRV fragment isolated from transposon Tn7 that encodes bacterial spectinomycin/streptomycin resistance (Spc/Str), which is a determinant for selection in E. coli and Agrobacterium tumefaciens. This is joined to the 1.61 kb segment of DNA encoding a chimeric kanamycin resistance which permits selection of transformed plant cells. The chimeric gene (P-35S/KAN/NOS 3′) consists of the cauliflower mosaic virus (CaMV) 35S promoter, the neomycin phosphotransferase typeII (KAN) gene, and the 3′-nontranslated region of the nopaline synthase gene (NOS 3′) (Fraley et al., 1983). The next segment is the 0.75 kb oriV containing the origin of replication from the RK2 plasmid. It is joined to the 3.1 kb SalI to PvuI segment of pBR322 (ori322) which provides the origin of replication for maintenance in E. coli and the born site for the conjugational transfer into the Agrobacterium tumefaciens cells. The next segment is the 0.36 kb PvuI to BciI from pTiT37 that carries the nopaline-type T-DNA right border (Fraley et al., 1985).
The pMON981 plasmid contains the following DNA segments: the 0.93 kb fragment isolated from transposon Tn7 encoding bacterial spectinomycin/streptomycin resistance |Spc/Str; a determinant for selection in E. coli and Agrobacterium tumefaciens (Fling et al., 1985)|; the chimeric kanamycin resistance gene engineered for plant expression to allow selection of the transformed tissue, consisting of the 0.35 kb cauliflower mosaic virus 35S promoter (P-35S) (Odell et al., 1985), the 0.83 kb neomycin phosphotransferase typeII gene (KAN), and the 0.26 kb 3′-nontranslated region of the nopaline synthase gene (NOS 3′) (Fraley et al., 1983); the 0.75 kb origin of replication from the RK2 plasmid (oriV) (Stalker et al., 1981); the 3.1 kb SalI to PvuI segment of pBR322 which provides the origin of replication for maintenance in E. coli (ori-322) and the born site for the conjugational transfer into the Agrobacterium tumefaciens cells, and the 0.36 kb PvuI to BclI fragment from the pTiT37 plasmid containing the nonpaline-type T-DNA right border region (Fraley et al., 1985). The expression cassette consists of the 0.6 kb 35S promoter from the figwort mosaic virus (P-FMV) (Gowda et al., 1989) and the 0.7 kb 3′ non-translated region of the pea rbcS-E9 gene (E9 3′) (Coruzzi et al., 1984, and Morelli et al., 1985). The 0.6 kb SspI fragment containing the FMV35S promoter (
The plant vector was mobilized into the ABI Agrobacterium strain. The ABI strain is the A208 Agrobacterium tumefaciens carrying the disarmed Ti plasmid pTiC58 (pMP90RK) (Koncz and Schell, 1986). The Ti plasmid does not carry the T-DNA phytohormone genes and the strain is therefore unable to cause the crown gall disease. Mating of the plant vector into ABI was done by the triparental conjugation system using the helper plasmid pRK2013 (Ditta et al., 1980). When the plant tissue is incubated with the ABI:plant vector conjugate, the vector is transferred to the plant cells by the vir functions encoded by the disarmed pTiC58 plasmid. The vector opens at the T-DNA right border region, and the entire plant vector sequence may be inserted into the host plant chromosome. The pTiC58 Ti plasmid does not transfer to the plant cells but remains in the Agrobacterium.PLANT REGENERATION
When adequate production of the glyphosphate oxidoreductase activity is achieved in transformed cells (or protoplasts), the cells (or protoplasts) are regenerated into whole plants. Choice of methodology for the regeneration step is not critical, with suitable protocols being available for hosts from Leguminosae (alfalfa, soybean, clover, etc.). Umbelliferae (carrot, celery, parsnip). Cruciferae (cabbage, radish, rapeseed, etc.), Cucurbitaceae (melons and cucumber), Gramineae (wheat, rice, corn, etc.). Solanaceae (potato, tobacco, tomato, peppers) and various floral crops. See, e.g., Ammirato, 1984; Shimamoto, 1989; Fromm, 1990; Vasil, 1990.
The following examples are provided to better elucidate the practice of the present invention and should not be interpreted in any way to limit the scope of the present invention. Those skilled in the art will recognize that various modifications, truncations, etc. can be made to the methods and genes described herein while not departing from the spirit and scope of the present invention.EXAMPLES
Expression, Activity and PhenotLe of Glvphosate Oxidoreductase in Transformed Plants
The transformation, expression and activity of glyphosate oxidoreductase, and the glyphosate tolerance phenotype imparted to the plants by the glyphosate oxidoreductase genes, introduced into Nicotiana tabacum cv. “Sarnsun” and/or Brassica napus cv. Westar using the vectors pMON17073, pMON17032, pMON17065, pMON17066, pMON17138, and pMON17164, is described in the following exemplary embodiments. Initial data in tobacco on the expression of the manipulated glyphosate oxidoreductase gene (SEQ ID NO:6) under the control of the En-CaMV35S promoter (see data on pMON17073 in Tables VIII and IX, for example) indicated only low levels of expression of glyphosate oxidoreductase. The transcription of the gene was confirmed in the case of 3-4 plants by Northern and S1 analysis but no glyphosate oxidoreductase protein could be detected (limit of detection in that assay was ˜0.01% expression level). Analysis of Ro plants following spray with 0.4 lb/acre (approximately 0.448 kg/ha) glyphosate also showed only low levels of tolerance. Modification of the gene sequence (as described herein) resulted in improved expression in tobacco, as did the use of the FMV promoter and the use of a CTP fusion to the glyphosate oxidoreductase gene. For these reasons the majority of the data presented comes from transgenic plants derived using vectors containing these improved glyphosate oxidoreductase constructs. One set of experiments with the modified glyphosate oxidoreductase vector pMON17032 are presented in example 1 and a study of manipulated glyphosate oxidoreductase, synthetic glyphosate oxidoreductase, and CTP1-synthetic glyphosate oxidoreductase is presented in example 2. The transformation and expression of glyphosate oxidoreductase in canola is described in example 3.Example 1
The tobacco leaf disc transformation protocol employs healthy leaf tissue about 1 month old. After a 15-20 minute surface sterilization with 10% Clorox plus a surfactant, the leaves were rinsed 3 times in sterile water. Using a sterile paper punch, leaf discs are punched and placed upside down on MS104 media (MS salts 4.3 g/l, sucrose 30 g/l, B5 vitamins 50×2 ml/l. NAA 0.1 mg/l, and BA 1.0 mg/l) for a 1 day preculture.
The discs were then inoculated with an overnight culture of disarmed Agrobacterium ABI containing the subject vector that had been diluted 1/5 (ie: about 0.6 OD). The inoculation was done by placing the discs in centrifuge tubes with the culture. After 30 to 60 seconds, the liquid was drained off and the discs were blotted between sterile filter paper. The discs were then placed upside down on MS104 feeder plates with a filter disc to co-culture.
After 2-3 days of co-culture, the discs were transferred, still upside down, to selection plates with MS104 media. After 2-3 weeks, callus formed, and individual clumps were separated from the leaf discs. Shoots were cleanly cut from the callus when they were large enough to distinguish from stems. The shoots were placed on hormone-free rooting media (MSO: MS salts 4.3 g/l, sucrose 30 g/l, and B5 vitamins 50×2 ml/l) with selection. Roots formed in 1-2 weeks. Any leaf callus assays are preferably done on rooted shoots while still sterile. Rooted shoots were placed in soil and were kept in a high humidity environment (ie: plastic containers or bags). The shoots were hardened off by gradually exposing them to ambient humidity conditions.
A total of 45 Kanamycin resistant pMON17032 tobacco lines were examined (Table V).
Leaf recallusing on plant tissue culture media indicated a low level of glyphosate tolerance (rated as a +/−phenotype) for at least 11 of these lines. At least 24 of these lines expressed a detectable level of glyphosate oxidoreductase in the range of 0.5 to 2 ng per 50 μg of extractable protein. The glyphosate tolerance displayed in the leaf recallusing assay and the higher glyphosate oxidoreductase expression level indicate that the changes made to the glyphosate oxidoreductase coding sequences to make the modified glyphosate oxidoreductase gene (SEQ ID NO:7) had a marked effect on the ability of this gene to be expressed in plants. This same effect could also then be achieved by expressing the manipulated glyphosate oxidoreductase gene (SEQ ID NO:6) using stronger plant promoters, using better 3′ polyadenylation signal sequences, optimizing the sequences around the initiation codon for ribosome loading and translation initiation, or by combinations of these or other expression or regulatory sequences or factors. The R1 progeny of a number of these lines, including those with the highest glyphosate oxidoreductase expression level (#'s 18854 and 18848) were sprayed with glyphosate at rates of 0.4 and 1.0 lb/acre (0.448 and 1.12 kb/ha, respectively) and vegetative performance rated over a period of four weeks (Table VI).
Following an initial lag, and especially for those plants expressing the highest levels of glyphosate oxidoreductase, these lines showed vegetative glyphosate tolerance at both spray rates (that improved with time). Glyphosate oxidoreductase enzyme activity was determined for two of the pMON17032 lines (#'s 18858 and 18881). Leaf tissue (1 g) was harvested, frozen in liquid N2, and stored at −80° C. prior to extraction. For extraction, leaf tissue was pulverized in a mortar and pestle with liquid N2. To the powdered leaf tissue was then added 1 ml extraction buffer (100 mM TrisCl, pH 7.4, 1 mM EDTA, 20% glycerol, 35 mM KCl, 1 mM benzamidine HCl, 5 mM Na ascorbate, 5 mM dithiothreitol, and 1 mg/ml bovine serum albumin, 4° C.), and the sample was further ground for 1 minute. The resulting mixture was centrifuged for 5 minutes (high speed, Eppendorf) and the supernatant was treated with a saturated ammonium sulfate solution to give 70% final saturation (2.33 ml saturated solution/ml extract). The precipitated protein was collected by centrifugation as above, and the pellet was resuspended in 0.4 ml of extraction buffer. After centrifuging again to remove particulate matter, the sample was desalted using Sephadex G50 contained in a 1 ml syringe, equilibrated with extraction buffer, according to the method of Penefsky (1979). The desalted plant extracts were stored on ice, and protein concentrations were determined by the method of Bradford (1976). Glyphosate oxidoreductase reactions were carried out in duplicate for 60 minutes at 30° C. in an assay mixture of 0.1 MOPS/0.01 tricine buffer, pH 7.4, containing 10 mM MgCl2, 0.01 mM flavin adenine dinucleotide (FAD, Sigma), and 1 mM ubiquinone Qo, (Sigma). Plant extracts (75 μl) were preincubated in the assay mixture for 2 minutes, and reactions were then initiated by adding iminodiacetic acid (IDA, 20 μl) substrate to a final concentration of 50 mM (total assay volume was 0.2 ml). Reactions were quenched and derivatized as described below. Control reactions omitting IDA and omitting plant extract were also performed. Glyoxylate detection was carried out using 2,4-dinitrophenylhydrazine (2,4-DNPH) derivatization and reverse phase high performance liquid chromotagraphy (HPLC), using a modification of the method of Qureshi et al. (1982). Glyphosate oxidoreductase reactions (0.2 ml) were quenched with 0.25 ml of DNPH reagent (0.5 mgcml DNPH |Aldrich| in 0.5M HCl) and allowed to derivative for 5 minutes at 25° C. The samples were then extracted with ethyl acetate (2-0.3 ml) and the combined ethyl acetate extracts were extracted with 10% Na2CO3 (0.3 ml). The Na2CO3 phase was then washed once with ethyl acetate (0.2 ml) and the Na2CO3 phase injected (100 μl) on a Beckman Ultrasphere C18 IP HPLC column (5 μA, 4.6 mm×25 cm) using an LKB GTi binary HPLC system with a Waters 900 photodiode array UVNIS HPLC detector, via a Waters WISP HPLC autoinjector. The isocratic mobile phase was methanol-water-acetic acid (60:38.5:1.5) with 5 mM tetrabutylammonium phosphate (Pierce). The DNPH-glyoxylate peak (retention time=6.7 minutes) was detected at 365 nm and compared to a glyoxylate standard (Sigma, 20 μM in 0.2 ml) derivatized in exactly the same manner.
A series of transformed tobacco lines were derived using the “isogenic” glyphosate oxidoreductase vectors pMON17073 (manipulated glyphosate oxidoreductase) (SEQ ID NO:6), pMON17065 (synthetic glyphosate oxidoreductase) (SEQ ID NO:8), and pMON17066 (CTP1-synthetic glyphosate oxidoreductase). By Western analysis (see Table VII below) of a number of these lines, the manipulated glyphosate oxidoreductase plants were found to express up to ˜0.5 ng glyphosate oxidoreductase per 50 μg plant protein, the synthetic glyphosate oxidoreductase at levels from ˜0.5-2 ng per 50 μg, and at levels from ˜2-20 ng per 50 μg for the CTP1-synthetic glyphosate oxidoreductase plants.
A number of primary transformants Ro lines, expressing manipulated or synthetic glyphosate oxidoreductase or CTP1-synthetic glyphosate oxidoreductase, were sprayed with glyphosate at 0.4 lb/acre (0.448 kg/ha) and rated as before.
The synthetic glyphosate oxidoreductase line displayed a response similar to that noted for the modified glyphosate oxidoreductase R1 plants, in that there was some immediate glyphosate effects that were overcome with time, through the metabolism of the herbicide by glyphosate oxidoreductase to the derivatives AMPA and glyoxylate. Since the target of glyphosate (EPSP synthase) is located in the chloroplast, the activity of glyphosate oxidoreductase must be reducing the level of glyphosate within this organelle by removing the herbicide before it reaches the chloroplast. The CTP1-synthetic glyphosate oxidoreductase plants displayed a superior glyphosate tolerance in that these plants did not show much, if any, immediate glyphosate effects at the treated rate. In general, the treated tolerant plants also showed normal development, flowering and fertility.
The CTP1-synthetic glyphosate oxidoreductase plants showed a markedly higher level of glyphosate oxidoreductase expression than that shown for the other glyphosate oxidoreductase constructs. This increased glyphosate oxidoreductase level could be due to enhancement of translation of the fusion or to sequestering of glyphosate oxidoreductase within the chloroplast and leading to a longer protein half-life. The higher level of glyphosate oxidoreductase and/or its location in the chloroplast can result in higher levels of glyphosate tolerance through rapid detoxification of glyphosate in the chloroplast. The presence of glyphosate oxidoreductase within the chloroplast has been confirmed. Five leaves from each of four plants (#22844, 22854, 22886, 22887), shown to be Western positive for glyphosate oxidoreductase, were homogenized in Waring blender in 0.9 L GR+ buffer (Barlett, et al., 1982) for 3×3 seconds at high speed. The homogenate was filtered through 4 layers of Miracloth and centrifuged at 6,000 rpm in a GS-3 rotor. The pellet was resuspended in 4 ml total of GR+ buffer and placed on top of a 40/80% Percoll step gradient and spun at 9,500 rpm for 10 minutes. The intact chloroplasts (lower band) were washed once with GR-buffer (Bartlett, et al., 1982) and centrifuged (up to 6,000 rpm with brake off). They were then resuspended in 300 μl 50 mM Hepes pH 7.7, 300 mM Sorbitol and lysed on ice using by sonication (small probe, 30%—3 microtip setting×10 seconds). The debris was pelleted and the supernatant passed through a Sephadex G50 column into 50 mM Hepes, pH 7.5. The soluble protein concentration was 2.4 mg/ml. The enzyme assays were done as above using both 50 mM IDA and 50 mM glyphosate as substrates (30 minute assays), but without the addition of 1 mM ubiquinone.
A number of transformed lines of canola have been derived with vectors pMON17138 (CTP1-synthetic glyphosate oxidoreductase) and pMON17164 (CTP2-synthetic glyphosate oxidoreductase) as follows.
Seedlings of Brassica napus cv Westar were established in 2 inch (˜5 cm) pots containing Metro Mix 350. They were grown in a growth chamber at 24° C., 16/8 hour photoperiod, light intensity of 400 uEm−2sec−1 (HID lamps). They were fertilized with Peters 20-10-20 General Purpose Special. After 2½ weeks they were transplanted to 6 inch (˜15 cm) pots and grown in a growth chamber at 15/10° C. day/night temperature, 16/8 hour photoperiod, light intensity of 800 uEm−2sec−1 (HID lamps). They were fertilized with Peters 15-30-15 Hi-Phos Special.
Four terminal internodes from plants just prior to bolting or in the process of bolting but before flowering were removed and surfaced sterilized in 70% v/v ethanol for 1 minute, 2% w/v sodium hypochlorite for 20 minutes and rinsed 3 times with sterile deionized water. Stems with leaves attached could be refrigerated in moist plastic bags for up to 72 hours prior to sterilization. Six to seven stem segments were cut into 5 mm discs with a Redco Vegetable Slicer 200 maintaining orientation of basal end.
The Agrobacterium was grown overnight on a rotator at 24° C. in 2 mls of Luria Broth containing 50 mg/l kanamycin, 24 mg/l chloramphenicol and 100 mg/l spectinomycin. A 1:10 dilution was made in MS (Murashige and Skoog) media giving approximately 9×108 cells per ml. This was confirmed with optical density readings at 660 mu. The stem discs (explants) were inoculated with 1.0 ml of Agrobacterium and the excess was aspirated from the explants.
The explants were placed basal side down in petri plates containing 1/10× standard MS salts, B5 vitamins, 3% sucrose, 0.8% agar, pH 5.7, 1.0 mg/l 6-benzyladenine (BA). The plates were layered with 1.5 ml of media containing MS salts, B5 vitamins, 3% sucrose, pH 5.7, 4.0 mg/l p-chlorophenoxyacetic acid, 0.005 mg/i kinetin and covered with sterile filter paper.
Following a 2 to 3 day co-culture, the explants were transferred to deep dish petri plates containing MS salts, B5 vitamins, 3% sucrose, 0.8% agar, pH 5.7, 1 mg/l BA, 500 mg/l carbenicillin, 50 mg/l cefotaxime, 200 mg/l kanamycin or 175 mg/l gentamicin for selection. Seven explants were placed on each plate. After 3 weeks they were transferred to fresh media, 5 explants per plate. The explants were cultured in a growth room at 25° C., continuous light (Cool White).
After 3 weeks shoots were excised from the explants. Leaf recallusing assays were initiated to confirm modification of Ro shoots. Three tiny pieces of leaf tissue were placed on recallusing media containing MS salts, B5 vitamins, 3% sucrose, 0.8% agar, pH 5.7, 5.0 mg/i BA, 0.5 mg/l naphthalene acetic acid (NAA), 500 mg/l carbenicillin, 50 mg/l cefotaxime and 200 mg/l kanamycin or gentamicin or 0.5 mM glyphosate. The leaf assays were incubated in a growth room under the same conditions as explant culture. After 3 weeks the leaf recallusing assays were scored for herbicide tolerance (callus or green leaf tissue) or sensitivity (bleaching).
At the time of excision, the shoot stems were dipped in Rootone® and placed in 2 inch (˜5 cm) pots containing Metro-Mix 350 and placed in a closed humid environment. They were placed in a growth chamber at 24° C., 16/8 hour photoperiod, 400 uEm−1sec−2 (HID lamps) for a hardening-off period of approximately 3 weeks.
The seed harvested from Ro plants is R1 seed which gives rise to R1 plants. To evaluate the glyphosate tolerance of an Ro plant, its progeny are evaluated. Because an Ro plant is assumed to be hemizygous at each insert location, selfing results in maximum genotypic segregation in the R1. Because each insert acts as a dominant allele, in the absence of linkage and assuming only one hemizygous insert is required for tolerance expression, one insert would segregate 3:1, two inserts, 15:1, three inserts 63:1, etc. Therefore, relatively few R1 plants need be grown to find at least one resistant phenotype.
Seed from an Ro plant is harvested, threshed, and dried before planting in a glyphosate spray test. Various techniques have been used to grow the plants for R1 spray evaluations. Tests are conducted in both greenhouses and growth chambers. Two planting systems are used; ˜10 cm pots or plant trays containing 32 or 36 cells. Soil used for planting is either Metro 350 plus three types of slow release fertilizer or plant Metro 350. Irrigation is either overhead in greenhouses or subirrigation in growth chambers. Fertilizer is applied as required in irrigation water. Temperature regimes appropriate for canola were maintained. A sixteen hour photoperiod was maintained. At the onset of flowering, plants are transplanted to ˜15 cm pots for seed production.
A spray “batch” consists of several sets of R1 progenies all sprayed on the same date. Some batches may also include evaluations of other than R1 plants. Each batch also includes sprayed and unsprayed non-transgenic genotypes representing the genotypes in the particular batch whhich were putatively transformed. Also included in a batch is one or more non-segregating transformed genotypes previously identified as having some resistance.
Two-six plants from each individual R0 progeny are not sprayed and serve as controls to compare and measure the glyphosate tolerance, as well as to assess any variability not induced by the glyphosate. When the other plants reach the 2-4 leaf stage, usually 10 to 20 days after planting, glyphosate is applied at rates varying from 0.28 to 1.12 kg/ha, depending on objectives of the study. Low rate technology using low volumes has been adopted. A laboratory track sprayer has been calibrated to deliver a rate equivalent to field conditions.
A scale of 0 to 10 is used to rate the sprayed plants for vegetative resistance. The scale is relative to the unsprayed plants from the same R0 plant. A 0 is death, while a 10 represents no visible difference from the unsprayed plant. A higher number between 0 and 10 represents progressively less damage as compared to the unsprayed plant. Plants are scored at 7, 14, and 28 days after treatment (DAT), or until bolting, and a line is given the average score of the sprayed plants within an Ro plant family.
Six integers are used to qualitatively describe the degree of reproductive damage from glyphosate:
- 0: No floral bud development
- 2: Floral buds present, but aborted prior to opening
- 4: Flowers open, but no anthers, or anthers fail to extrude past petals
- 6: Sterile anthers
- 8: Partially sterile anthers
- 10: Fully fertile flowers
Plants are scored using this scale at or shortly after initiation of flowering, depending on the rate of floral structure development.
Tables X and XI below tabulate the vegetative and reproductive scores for canola plants transformed with pMON17138 (sprayed at a rate of 0.56 kg/ha and pMON17164 (sprayed at a rate of 0.84 kg/ha), respectively. The results presented below illustrate the glyphosate tolerance conferred to canola plants as a result of expression of a glyphosate oxidreductase gene in the plants.
The glyphosate oxidoreductase gene has also been introduced into and expressed in soybean and imparts glyphosate tolerance to such plants. The CTP2-synthetic glyphosate oxidoreductase fusion gene (as described above) was introduced into soybean under the control of the FMV promoter and with the NOS 3′ sequences in vector pMON17159, a map of which is presented in FIG. 10. This vector consists of the following elements in addition to the glyphosate oxidoreductase gene sequences; the pUC origin of replication, an NPTII bacterial selectable marker gene (kanamycin) and the beta-glucuronidase gene (GUS; Jefferson et a. 1986) under the control of the E35S promoter and with the E9 3′ sequences. The latter gene provides a scorable marker to facilitate the identification of transformed plant material.
Soybean plants are transformed with pMON17159 by the method of microprojectile injection using particle gun technology as described in Christou et al. (1988). The seed harvested from R0 plants is R1 seed which gives rise to R1 plants. To evaluate the glyphosate tolerance of an R0 plant, its progeny are evaluated. Because an R0 plant is assumed to be hemizygous at each insert location, selfing results in maximum genotypic segregation in the R1. Because each insert acts as a dominant allele, inthe absence of linkage and assuming only one hemizygous insert is required for tolerance expression, one insert would segregate 3:1, two inserts, 15:1, three inserts 63:1, etc. Therefore, relatively few R1 plants need be grown to find at least one resistant phenotype.
Seed from an R0 soybean plant is harvested, and dried before planting in a glyphosate spray test. Seeds are planted into 4 inch (˜5 cm) square pots containing Metro 350. Twenty seedlings from each R0 plant is considered adequate for testing. Plants are maintained and grown in a greenhouse environment. A 12.5-14 hour photoperiod and temperatures of 30° C. day and 24° C. night is regulated. Water soluble Peters Pete Lite fertilizer is applied as needed.
A spray “batch” consists of several sets of R1 progenies all sprayed on the same date. Some batches may also include evaluations of other than R1 plants. Each batch also includes sprayed and unsprayed non-transgenic genotypes representing the genotypes in the particular batch which were putatively transformed. Also included in a batch is one or more non-segregating transformed genotypes previously identified as having some resistance.
One to two plants from each individual R0 progeny are not sprayed and serve as controls to compare and measure the glyphosate tolerance, as well as to assess any variability not induced by the glyphosate. When the other plants reach the first trifoliolate leaf stage, usually 2-3 weeks after planting, glyphosate is applied at a rate equivalent of 128 oz./acre (8.895 kg/ha) of Roundup®. A laboratory track sprayer has been calibrated to deliver a rate equivalent to those conditions.
A vegetative score of 0 to 10 is used. The score is relative to the unsprayed progenies from the same R0 plant. A 0 is death, while a 10 represents no visible difference from the unsprayed plant. A higher number between 0 and 10 represents progressively less damage as compared to the unsprayed plant. Plants are scored at 7, 14, and 28 days after treatment (DAT).
The glyphosate oxidoreductase gene has also been introduced into Black Mexican Sweet (BMS) corn cells with expression of the protein detected in callus.
Plasmid pMON19632 was used to introduce the glyphosate oxidoreductase gene into corn cells. The backbone for this plasmid was constructed by inserting the 0.6 kb cauliflower mosaic virus (CaMV) 35S RNA promoter (E35S) containing a duplication of the −90 to −300 region (Kay et al., 1987), a 0.58 kb fragment containing the first intron from the maize alcohol dehydrogenase gene (Callis et al., 1987), and the 3′ termination sequences from the nopaline synthase (NOS) gene (Fraley et al., 1983) into pUC119 (Yanisch-Perron et al., 1985). pMON19632 was formed by inserting the 1.7 kb BglIII/EcoRI fragment from pMON17064 which contains the Arabidopsis SSU CTP fused to the synthetic glyphosate oxidoreductase coding sequence (SEQ IN NO:8).
Plasmid pMON19632 was introduced into BMS corn cells by co-bombardment with EC9, a plasmid containing a sulfonylurea-resistant form of the maize acetolactate synthase gene. 2.5 ˜g of each plasmid was coated onto tungsten particles and introduced into log-phase BMS cells using a PDS-1000 particle gun essentially as described in Klein et al., 1989. Transformants were selected on MS medium containing 20 ppb chlorsulfuron. After initial selection on chlorsulfuron, the calli was assayed by glyphosate oxidoreductase Western blot.
BMS callus (3 g wet weight) was dried on filter paper (Whatman#1) under vacuum, reweighted, and extraction buffer (500 lg dry weight; 100 mM Tris, 1 mM EDTA, 10% glycerol) was added. The tissue was homogenized with a Wheaton overhead stirrer for 30 seconds at 2.8 power setting. After centrifugation (3 minutes, Eppendorf microfuge), the supernatant was removed and the protein was quantitated (BioRad Protein Assay). Samples (50 g/well) were loaded on an SDS PAGE gel (Jule, 3-17%) along with glyphosate oxidoreductase standard (10 ng), electrophoresed, and transferred to nitrocellulose similarly to a previously described method (Padgette, 1987). The nitrocellulose blot was probed with goat anti-glyphosate oxidoreductase IgG, and developed with I-125 Protein G. The radioactive blot was visualized by autoradiography. Results were quantitated by densitometry on an LKB UltraScan XL laser densitometer and are tabulated below in Table XIII.
Table XIII illustrates that glyphosate oxidoreductase can be expressed and detected in a monocotyledonous plant, such as corn.Example 6
The glyphosate oxidoreductase gene may be used as a selectable marker for plant transformation directly on media containing glyphosate. The ability to select and to identify transformed plant material depends, in most cases, on the use of a dominant selectable marker gene to enable the preferential and continued growth of the transformed tissues in the presence of a normally inhibitory substance. Antibiotic resistance and herbicide tolerance genes have been used almost exclusively as such dominant selectable marker genes in the presence of the corresponding antibiotic or herbicide. The nptII/kanamycin selection scheme is probably the most frequently used. It has been demonstrated that glyphosate oxidoreductase is also a useful and perhaps superior selectable marker/selection scheme for producing and identifying transformed plants.
A plant transformation vector that may be used in this scheme is pMON17226 (FIG. 11). This plasmid resembles many of the other plasmids described infra and is essentially composed of the previously described bacterial replicon system that enables this plasmid to replicate in E. coli and to be introduced into and to replicate in Agrobacterium, the bacterial selectable marker gene (Spc/Str), and located between the T-DNA right border and left border is the CTP1-glyphosate oxidoreductase synthetic gene in the FMV promoter-E9 3′ cassette. This plasmid also has single sites for a number of restriction enzymes, located within the borders and outside of the expression cassette. This makes it possible to easily add other genes and genetic elements to the vector for introduction into plants.
The protocol for direct selection of transformed plants on glyphosate is outlined for tobacco. Explants are prepared for pre-culture as in the standard procedure as described in Example 1: surface sterilization of leaves from 1 month old tobacco plants (15 minutes in 10% clorox+surfactant; 3×dH20 washer); explants are cut in 0.5×0.5 cm squares, removing leaf edges, mid-rib, tip, and petiole end for uniform tissue type; explants are placed in single layer, upside down, on MS104 plates+2 ml 4COO5K media to moisten surface; pre-culture 1-2 days. Explants are inoculated using overnight culture of Agrobacterium containing the plant transformation plasmid that is adjusted to a titer of 1.2×109 bacteria/ml with 4COO5K media. Explants are placed into a centrifuge tube, the Agrobacterium suspension is added and the mixture of bacteria and explants is “Vortexed” on maximum setting for 25 seconds to ensure even penetration of bacteria. The bacteria are poured off and the explants are blotted between the layers of dry sterile filter paper to remove excess bacteria. The blotted explants are placed upside down on MS104 plates+2 ml 4COO5K media+filter disc. Co-culture is 2-3 days. The explants are transferred to MS104+Carbenicillin 1000 mgil+cefotaxime 100 mg/l for 3 days (delayed phase). The explants are then transferred to MS104+glyphosate 0.05 mM+Carbenicillin 1000 mg/l+cefotamine 100 mg/l for selection phase. At 4-6 weeks shoots are cut from callus and placed on MSO+Carbenicillin 500 mg/l rooting media. Roots form in 3-5 days, at which time leaf pieces can be taken from rooted plates to confirm glyphosate tolerance and that the material is transformed.
The presence of the glyphosate oxidoreductase protein is these transformed tissues has been confirmed by immunoblot analysis of leaf discs. The data from one experiment with pMON17226 is presented in the folllowing: 25 shoots formed on glyphosate from 100 explants inoculated with Agrobacterium ABI/pMON17226; 15 of these were positive on recallusing on glyphosate, and 19 of these were positive for glyphosate oxidoreductase protein as detected by immunoblot.
These data indicate a transformation rate of 15-19 per 100 explants, which makes this a highly efficient and time saving transformation procedure for plant. Similar transformation frequencies have been obtained with a pMON17226 derivative (pMON17241) containing the gene for the glyphosate oxidoreductase v.247 (SEQ ID NO:17). The glyphosate oxidoreductase gene has also been shown to enable direct selection of transformants in other plant species, including Arabidopsis, potato, and sugarbeet.
From the foregoing, it will be seen that this invention is one well adapted to attain all the ends and objects hereinabove set forth together with advantages which are obvious and which are inherent to the invention.
It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.
Since many possible embodiments may be made of the invention without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense.BIBLIOGRAPHY
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1. An isolated double-stranded DNA molecule which hybridizes to the DNA sequence of SEQ ID NO:3, wherein said DNA molecule encodes a glyphosate oxidoreductase enzyme.
2. A recombinant bacterium containing the double-straded DNA molecule of claim 1.
3. The DNA molecule of claim 1, wherein said DNA molecule comprises SEQ ID NO:17.
4. A An isolated DNA molecule comprising SEQ ID NO:4.
5. An isolated DNA molecule that is capable of hybridizing to the DNA sequence of SEQ ID NO:4, wherein said DNA molecule encodes a glyphosate oxireductase enzyme.
6. A bacterium containing the DNA molecule of claim 5.
7. A An isolated DNA molecule comprising SEQ ID NO:6.
8. An isolated DNA molecule that is capable of hybridizing to the DNA sequence of SEQ ID NO:6, wherein said DNA molecule encodes a glyphosate oxidoreductase enzyme.
9. A bacterium containing the DNA molecule of claim 8.
10. A An isolated DNA molecule comprising SEQ ID NO:7.
11. An isolated DNA molecule that is capable of hybridizing to the DNA sequence of SEQ ID NO:7, wherein said DNA molecule encodes a glyphosate oxidoreductase enzyme.
12. A bacterium containing the DNA molecule of claim 11.
13. A An isolated DNA molecule comprising SEQ ID NO:8.
14. An isolated DNA molecule that is capable of hybridizing to the DNA sequence of SEQ ID NO:8, wherein said DNA molecule encodes a glyphosate oxidoreductase enzyme.
15. A bacterium containing the DNA moledule of claim 14.
16. A An isolated DNA molecule comprising SEQ ID NO:17.
17. An isolated DNA molecule that is capable of hybridizing to the DNA sequence of SEQ ID NO:17, wherein said DNA molecule encodes a glyphosate oxidoreductase enzyme.
18. A bacterium containing the DNA molecule of claim 17.
19. A method for selecting transformed plant cells comprising:
- (a) introducing a chimeric gene comprising SEQ ID NO:3, 4, 6, 7, 8 or 17 into plant cells;
- (b) placing said plant cells on a plant growth media containing glyphosate; and
- (c) selecting plant cells that exhibit growth on said glyphosate containing media.
20. A method for selecting transformed plant cells comprising:
- (a) introducing a chimeric gene comprising a DNA molecule encoding a glyphosate oxidoreductase enzyme into plant cells, wherein the DNA molecule is capable of hybridizing to SEQ ID NO:3, 4, 6, 7, 8 or 17;
- (b) placing said plant cells on a plant growth media containing glyphosate; and
- (c) selecting plant cells that exhibit growth on said glyphosate containing media.
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Filed: Jul 7, 2000
Date of Patent: Oct 11, 2005
Assignee: Monsanto Technology LLC (St. Louis, MO)
Inventors: Gerard F. Barry (St. Louis, MO), Ganesh M. Kishore (Creve Coeur, MO)
Primary Examiner: Manjunath N. Rao
Attorney: Howrey Simon Arnold & White, LLP
Application Number: 09/612,404