Isolated hair keratin genes and their use in hair growth active identification assays
The present invention relates to an isolated human hair specific keratin gene or fragment thereof, comprising a DNA sequence selected from the group consisting of SEQ ID NO:11; and a DNA sequence comprising DNA sequences SEQ ID NO:6, SEQ ID NO:7, SEQ ID NO:8, SEQ ID NO:9 and SEQ ID NO:10. The present invention also relates to a method for detecting the level of hair specific keratin in a biological sample. The present invention further relates to a method of identifying hair growth regulating compounds and compositions comprising: a) treating a subject with a compound or composition of interest; b) isolating a sample of hair from the subject; and c) using a DNA sequence, or fragment thereof, which encodes hair specific keratin as a marker in a biological assay to detect an increase in the production of hair specific keratin in the hair sample.
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This invention relates to the field of regulating hair growth, and specifically to isolated human hair keratin intermediate filament genes, or fragments thereof, useful as biological markers for identifying compounds useful for regulating hair growth.
BACKGROUNDSociety in general continues to attach a stigma to hair loss. Men and women suffer from hair loss, often resulting in self-consciousness relating to the hair loss. Domestic animals, such as cats and dogs, also suffer from hair loss. While the animal is not likely to be emotionally affected by such hair loss, its owner may be, particularly if such an animal is to be shown in various competitions. Additionally, increased hair growth in livestock such as sheep, thereby resulting in increased wool production, is also desirable.
The desire for a healthy full head (or body, in the case of animals) of hair has resulted in a flurry of activity in the technical community to find compounds capable of inducing hair growth. Unfortunately, even the preliminary identification of compounds potentially useful for inducing hair growth is extremely time consuming. Currently, animal models which experience hair loss similar to humans are often used to identify useful compounds. Unfortunately, the researcher must frequently wait months or years for the animal to reach that stage in its life when it begins to lose hair. The researcher must then generally wait several more months following treatment with a compound of interest before assessing the treated area to determine if hair growth has in fact occurred. Such waiting periods are a clear impediment to the search for hair growth actives.
For the foregoing reasons, there is a need for a marker useful for quickly, reliably, and noninvasively identifying whether hair growth is occurring in a subject, as well as a need for a quick, reliable, noninvasive assay employing such a marker for identifying potential hair growth regulating compounds and compositions.
Objects of the Present InventionIt is an object of the present invention to provide an isolated human hair specific keratin gene, or fragment thereof.
It is also an object of the present invention to provide a method for detecting the level of hair specific keratin in a biological sample.
It is also an object of the present invention to provide a method of identifying hair growth regulating compounds and compositions.
It is also an object of the present invention to provide a method for detecting the efficacy of a known hair growth regulating compound with respect to a subject being treated with the compound.
It is also an object of the present invention to provide a method for detecting hair loss.
SUMMARYThe present invention is drawn to isolated hair keratin intermediate filament genes which satisfy the need for a marker useful in a quick, dependable, and noninvasive assay for identifying potential hair growth regulating compounds and compositions.
In one embodiment of the present invention, the isolated hair specific keratin gene has the following DNA sequence: SEQ ID NO:11.
In another embodiment of the present invention, the isolated hair specific keratin gene has a DNA sequence comprising the following DNA sequences: SEQ ID NO:6, SEQ ID NO:7, SEQ ID NO:8, SEQ ID NO:9, and SEQ ID NO:10.
The present invention also relates to a method for detecting the level of hair specific keratin in a biological sample, the method comprising: a) isolating the biological sample from a subject; and b) using a DNA sequence or fragment thereof which encodes for hair specific keratin as a marker in a biological assay to detect the level of hair specific keratin in the biological sample.
The present invention further relates to a method of identifying hair growth regulating compounds and compositions comprising: a) treating a subject with a compound or composition of interest; b) isolating a sample of hair from the subject; and c) using a DNA sequence, or fragment thereof, which encodes for hair specific keratin as a marker in a biological assay to detect an increase in the production of hair specific keratin in the hair sample.
DETAILED DESCRIPTIONHair specific keratin intermediate filament (IF) proteins are one of the major components of the hair shaft (the others being high-sulfur proteins, ultra-high sulfur proteins, and glycinetyrosine rich proteins). More than twenty species of the hair specific keratin IF proteins have been identified in different organs of the human body (Moll, R., W. Franke, D. Schiller, B. Geieger and R. Krepler, (1982) The Catalog of Human Cytokeratins: Patterns of Expression in Normal Epithelia, Tumor and Cultured Cells, Cell, Vol. 31, pp. 11-24), and eight species of hair specific keratin IF proteins are present in the hair shaft (Heid, H. W., I. Moll and W. W. Franke, (1988) "Patterns of Expression of Trichocytic and Epithelial Cytokeratins in Mammalian Tissues", Differentiation, Vol. 37, pp. 137-157).
The hair specific keratin IF proteins are produced by the trichocytes in the base (bulb) of the hair follicle. The process of hair specific keratin IF protein production is under tight regulation such that the hair specific keratin IF proteins are made at the appropriate site and appropriate time. This regulation of hair specific keratin IF protein production is primarily achieved by regulating the activation/inactivation of hair specific keratin gene expression. Activation of a hair specific keratin IF gene will result in an increase in production of its corresponding hair specific keratin IF protein, which, in turn, may result in an increase in hair shaft production. Therefore, activating hair specific keratin genes to produce hair specific keratin IF proteins will have a profound effect in stimulating hair shaft production. Any compounds which can do so are potentially useful for regulating hair growth. Identification of these compounds will be facilitated by isolation of one or more hair specific keratin IF genes.
The Applicants have determined that such an isolated hair specific keratin IF gene would be useful in a biological assay for identifying potential hair growth regulating compounds and compositions. The use of the hair specific keratin IF gene as a marker would have several advantages. The assay would have the advantage of reliability as hair specific keratin IF proteins are one of the major components of the hair shaft and measuring hair specific keratin IF RNA production would be a direct measurement of hair shaft formation. The assay would have the advantage of speed as an increase in hair specific keratin RNA production would occur much earlier (a few weeks) than an increase in hair shaft formation (several months) following treatment with a hair regulating compound. Lastly, the assay would have the advantage of noninvasiveness in that hair specific keratin RNA could be detected in a few plucked hairs without biopsying.
As used herein, "A", "T", "G", "C" and "U", refer to the nucleotides containing adenine, thymine, guanine, cytosine and uracil, respectively.
As used herein, "N" means an unknown nucleotide.
As used herein, "DNA" means deoxyribonucleic acid.
As used herein, "RNA" means ribonucleic acid.
As used herein, "gene" means a discreet segment of DNA of a chromosome, the segment of DNA being involved in producing RNA and/or one or more polypeptides.
As used herein, "regulating hair growth" means increasing the level of hair specific keratin RNA production, and/or inducing the formation of a greater number of hair strands, and/or increasing the diameter of the hair strand, and/or lengthening the hair strand, and/or converting the hair follicle from vellus to terminal, and/or preventing, retarding, or arresting the process of hair loss.
As used herein, "vellus hair follicle" means a hair follicle which produces a soft, short, and often colorless hair fiber. The size of the vellus follicle is considerably smaller than the terminal hair follicle. In an adult, vellus follicles can be found on the forehead, eyelids, and bald scalp.
As used herein, "terminal hair follicle" means a hair follicle which produces a coarse, long, and often pigmented hair follicle. The size of the terminal follicle is considerably larger than the vellus follicle. In the adult, the terminal follicles can be found on the scalp, axilla and pubic areas.
As used herein, "biological assay" means analyzing a sample for a biological substance of interest. For purposes of the present invention, the biological substance of interest is hair specific keratin RNA. Preferred biological assays include Northern Blotting Analysis, RNase Protection Assay, Dot Blotting Analysis, and Reverse Transcription-Polymerase Chain Reaction (RT-PCR); more preferably RT-PCR.
As used herein, "keratin" preferably refers to hair specific keratin intermediate filament.
As used herein, "subject" means animal or human, preferably human. Preferred animal subjects are rodents and simians. A preferred simian subject is the macaque. A preferred rodent subject is the mouse.
As used herein, "biological sample" preferably means hair strand, hair strands, or skin biopsies.
As used herein, "in vitro material" preferably means epithelial cells, hair follicle epithelial cells, hair follicle epithelial matrix cells, or hair follicle organ culture; more preferably hair follicle epithelial matrix cells.
As used herein, "comprising" means that other steps, ingredients, and/or base pairs which do not affect the end result can be added. This term encompasses the terms "consisting of" and "consisting essentially of."
As used herein, "Northern Blotting Analysis" means a technique for detecting the presence of specific RNA molecules such as the procedure disclosed by Maniatis, T., E. F. Fritsch and J. Sambrook (1982) Molecular Cloning: P A Laboratorv Manual, (Cold Spring Harbour Laboratory: New York), pp. 7.43-7.51, incorporated herein by reference. Briefly, RNA molecules in a sample are denatured by mixing them with an agent to prevent hydrogen bonds between base pairs so that the RNA is in unfolded, linear form. The RNA sample is then separated according to size by gel electrophoresis. The RNA sample is then transferred to a nitrocellulose filter to which the extended denatured RNA will adhere. The filter is exposed to a labeled DNA probe and subjected to autoradiography. This technique will indicate the presence as well as the quantity and size of a specific RNA in a sample.
As used herein, "RNase Protection Assay" means a technique for detecting the presence of specific RNA molecules. Briefly, a single-stranded, radioactive labeled RNA probe is synthesized. The labelled probe is mixed with an RNA sample. The probe specifically hybridizes with its corresponding RNA molecules to form double stranded hybrids. Upon digesting with RNase, the unhybridized single stranded RNA molecules and excess probe molecules are destroyed and only the double stranded hybrids are left intact. The hybrids are subsequently separated on a polyacrylamide gel and detected by autoradiography, thereby indicating the presence and amount of a specific RNA in a sample. Preferably, the procedure used is that of Ambion Inc.'s ribonuclease protection assay kit (RPA.TM.; Ambion, Inc., Austin, Tex.), incorporated herein by reference. The RPA.TM. protocol involves the following steps of a) hybridization of probe and sample RNA, b) RNase digestion of hybridized RNAs, and c) separation and detection of protected fragments:
Under the RPA.TM. protocol, the probe and sample RNA are hybridized by the following methods: For each experimental tube, mix .sup.32 P-labeled probe (usually about 150-900 pg or 2.times.10.sup.4 -1.2.times.10.sup.5 cpm) with sample RNA (usually about 1-10 .mu.g) in a 1.5 ml microfuge tube. Make 2 control tubes for every probe to be used, by mixing 2 .mu.l yeast RNA solution (5 mg/ml yeast RNA in dH.sub.2 O) with the same amount of labeled probe used for the experimental tubes in the preceding step. Ethanol precipitate samples by adjusting the concentration of NH.sub.4 OAc to 0.5 M and adding 2 1/2 volumes of EtOH. Place tubes in -80.degree. C. freezer for 15 min. Pellet probe and sample RNA for 15 min. at maximum speed of microcentrifuge, preferably at 4.degree. C. Carefully remove EtOH supernatant from each tube. Resuspend each pellet in 20 .mu.l hybridization buffer (80% deionized formamide/40 mM PIPES pH 6.4/400 mM NaOAc pH 6.4/1 mM EDTA) by thoroughly vortexing and briefly centrifuging tubes. Heat all tubes 80.degree.-90.degree. C. for 3-4 min. Incubate tubes submerged in 45.degree. C. heat block or in a 42.degree.-45.degree. C. incubator overnight.
RNase Digestion of Hybridized RNAs under the RPA.TM. protocol involves the following methods: Prepare working dilutions of concentrated RNase A/RNase T1 solutions (300 .mu.l of a mixture of 50 units/ml RNase A+10,000 units/ml RNase T1 (cloned)) in RNase digestion buffer. Typical dilution of the RNase A/RNase T1 solutions is 1:100. Remove tubes from 45.degree. C. block or incubator and microfuge briefly if condensation is present on sides of tubes. Add 200 .mu.l of diluted RNase solution (RNase digestion buffer and RNases) to all experimental tubes, and to one control tube of each pair of control tubes. Add 200 .mu.l of RNase digestion buffer without RNase to the remaining control tube(s), one for each different probe used. Vortex and microfuge all tubes briefly. Incubate tubes for 30 min. at 37.degree. C. Remove SDS solution (20% SDS) from freezer and thaw at 37.degree. C. or 42.degree. C., then mix together equal volumes of Proteinase K/yeast RNA solution (Proteinase K/yeast RNA in 50% glycerol) and SDS solution. Use 10 .mu.l of each solution for each tube in the assay. Add 20 .mu.l of the 1:1 mixture of the Proteinase K/yeast RNA solution and SDS solution to each tube. Vortex and microfuge all tubes briefly. Incubate all tubes for 15 min. at 37.degree. C. Add 250 .mu.l phenol/CHCl.sub.3 /isoamyl alcohol (25:24:1) to each tube; vortex thoroughly and microfuge for at least 1 min. to completely separate phases. Remove aqueous phases to corresponding fresh tubes. Add 625 .mu.l 100% EtOH to each tube. Vortex tubes and store at -80.degree. C. for 15 min.
Under the RPA.TM. protocol, separation and detection of protected fragments is conducted by the following methods: Prepare a denaturing polyacrylamide gel suitable for separation of protected fragments of expected size. Remove tubes from freezer and microfuge for 15 min. at mazimum speed at 4.degree. C. Carefully remove EtOH supernatant from each tube. Resuspend each pellet in 8 .mu.l loading buffer solution (80% formamide/0.1% xylene cyanol/0.1% bromophenol blue/2mM EDTA) by vigorous vortexing and brief microfuging. Heat all tubes for 3-4 min. at 80.degree.-90.degree. C. Re-vortex and re-microfuge tubes briefly. Load samples on polyacrylamide gel and run at approximately 250 volts for about 1 hour in Tris-borate buffer. Transfer gel to chromatography paper, cover with plastic wrap, and expose to X-ray film at -80.degree. C.
As used herein, "Dot Blotting Analysis" means a technique for detecting the presence of specific RNA molecules such as the procedure disclosed by Maniatis, pp. 7.37-7.52, incorporated herein by reference. Briefly, an RNA sample is denatured to fully extend the RNA molecules. An amount of RNA is transferred to a nitrocellulose filter with a Dotting apparatus (IBI Inc., subsidiary of Eastman Kodak Co., New Haven, Conn.). The filter is hybridized with the radioactive labeled nucleic acid probe and subjected to autoradiography thereby indicating the presence and amount of a specific RNA in a sample.
As used herein, "Reverse Transcription-Polymerase Chain Reaction" means a technique for detecting the presence of RNA molecules such as the procedure disclosed by Innis, M. A., D. H. Gelfand, J. J. Sninsky and T. J. White, (1990) PCR Protocols: A Guide to Method and Application, (Cetus Corporation: Emeryville, Calif.), incorporated herein by reference; or the procedure disclosed in U.S. Pat. No. 5,213,961, Bunn, Gilliland, Blanchard and Perrin, issued May 25, 1993, incorporated herein by reference. Briefly, a pair of sequence and species specific primers corresponding to the sequence of the RNA molecule to be detected are synthesized. The primer corresponding to the 3' portion of the RNA molecule (down stream primer) is used to convert RNA into cDNA in the presence of four types of deoxynucleoside triphosphates and reverse transcriptase. The primer corresponding to the 5' portion of the RNA molecule (upstream primer) and Taq polymerase are subsequently added. The mixture is heated so that the cDNA/RNA duplex will melt to separate into single stranded molecules. When the temperature is lowered to a certain point, the upstream primer will hybridize with the cDNA and extend along the cDNA molecule to form a DNA duplex. The DNA duplex is separated into single stranded molecules upon reheating. When the temperature is again reduced, the up and down stream primers hybridize to each DNA strand respectively, extending to form new DNA duplexes. Repeating the steps of increasing and decreasing temperature results in the amplification of the specific RNA molecule. The amplified molecules can be detected with either D scan, ethidium bromide staining or autoradiography. The technique is advantageous in that it will detect the presence of an extremely small amount of a specific RNA in a sample or detect the presence of a specific RNA from an extremely limited amount of RNA sample.
Hair Specific Keratin Genes and Fragments Thereof
The applicants have isolated two human hair specific keratin genes. The complete DNA sequence of the first isolated human hair specific keratin gene has been determined by the Applicants as follows: SEQ ID NO:11. This sequence encoding the first human hair specific keratin gene has been incorporated into a bacterial phage. This phage containing the first human hair specific keratin gene has been named HLXL2-6. Phage HL-XL2-6 was deposited with the American Type Culture Collection (ATCC) in Bethesda, Md. on Aug. 25, 1993. The deposited cell line has been assigned Accession No. ATCC 75537.
As is recognized in the art, there are occasionally errors in DNA and amino acid sequencing methods. As a result, the first isolated hair specific keratin gene sequence of the present invention encoded in the deposited material, ATCC Accesion No. ATCC 75537 is incorporated herein by reference and controlling in the event of an error in the sequence found in the written description of the present invention. It is further noted that one of ordinary skill in the art reproducing the Applicants' work from the written disclosure can discover any sequencing errors using routine skill.
Portions of the second isolated human hair specific keratin gene have been sequenced by the Applicants. The sequenced portions include the following DNA sequences: SEQ ID NO:6, SEQ ID NO:7, SEQ ID NO:8, SEQ ID NO:9 and SEQ ID NO:10.
The positional order of SEQ ID NO:7, SEQ ID NO:8 and SEQ ID NO:9, relative to one another, is believed to be as follows: There is a gap of unknown base pair length between SEQ ID NO:7 and SEQ ID NO:8, and a gap of unknown base pair length between SEQ ID NO:8 and SEQ ID NO:9. Preferably the portion of the isolated human hair specific keratin gene comprising these three sequences is less than about 40 kilobases, more preferably less than about 35 kilobases. Preferably either gap of unknown base pair length is from about 1 base to about 40,000 bases, more preferably from about 100 bases to about 30,000 bases, more preferably still from about 1,000 bases to about 10,000 bases.
SEQ ID NO:10 is believed to occur between SEQ ID NO:6 and the carboxy terminus of the second isolated human hair specific keratin gene.
SEQ ID NO:6 is believed to occur between SEQ ID NO:7 and SEQ ID NO:10 of the second isolated human hair specific keratin gene.
Schematically, the positional order of the sequenced portions of the second isolated hair specific keratin gene is as follows:
SEQ ID NO:10--SEQ ID NO:6--SEQ ID NO:7--SEQ ID NO:8--SEQ ID NO:9
As used herein, "fragment" means a segment of a keratin gene of the present invention, preferably of the first or second isolated human hair specific keratin gene of the present invention, having from about 5 to about 1,500 base pairs, preferably from about 10 to about 1,000 base pairs, more preferably from about 15 to about 500 base pairs, more preferably still from about 20 to about 200 base pairs. In one embodiment of the present invention, the fragment of the first isolated human hair specific keratin gene having SEQ ID NO:11 is preferably SEQ ID NO:5. In another embodiment of the present invention, the fragment of the second isolated human hair specific keratin gene is preferably selected from the group consisting of SEQ ID NO:6, SEQ ID NO:7, SEQ ID NO:8, SEQ ID NO:9, and SEQ ID NO:10.
Either of the first or second isolated hair specific keratin genes, or fragments thereof, including those fragments specifically identified, are useful in the following assays which involve measuring the level of hair specific keratin production.
Detecting the Level of Hair Specific Keratin in a Biological Sample
The present invention additionally relates to a method for detecting the level of hair specific keratin in a biological sample, the method comprising: a) isolating the biological sample from a subject; and b) using a DNA sequence which encodes hair specific keratin, or a fragment thereof, as a marker in a biological assay to detect the level of hair specific keratin in the biological sample.
Identification of Hair Growth Regulating Actives
The present invention additionally relates to a method of identifying hair growth regulating compounds and compositions comprising:
a) treating a subject with a compound or composition of interest (e.g., a compound believed to be potentially useful for regulating hair growth);
b) isolating a biological sample from the subject; and
c) using a DNA sequence which encodes hair specific keratin, or fragment thereof, as a marker in a biological assay to detect an increase in the production of hair specific keratin in the hair sample.
The present invention also relates to a method of identifying hair growth regulating compounds and compositions comprising:
a) treating in vitro material with a compound or composition of interest;
b) using a DNA sequence which encodes hair specific keratin, or fragment thereof, as a marker in a biological assay to detect an increase in the production of hair specific keratin in the in vitro hair follicle material.
Diagnostic Applications
The progression of hair loss is a complex biological process and is difficult to diagnose clinically until the thinning of hair is visibly apparent. Conversely, in bald individuals the response of a drug treatment, whether topical, parental or oral, is very difficult to ascertain until several months later. In both situations, the patient and doctor would benefit if the progression of hair loss and the effectiveness of the therapy could be monitored with a relatively inexpensive and non-invasive test.
The technique for Measuring Hair Specific Keratin Gene Expression via Reverse Transcription-Polymerase Chain Reaction, disclosed herein, (hereinafter, PCR Technique) can be utilized in diagnostic applications for early detection of hair loss and/or determination of effectiveness of hair growth regulation therapy.
a. Early Detection of Hair Loss
As used herein, "vertex region" means the region of the scalp encompassing the crown or topmost point of the vault of the skull.
As used herein, "frontotemporal region" means the region of the scalp encompassing the anterior or frontal portion of the skull; commonly referred to as "receding hairline".
As used herein, "occipital region" means the region of the scalp encompassing the back of the skull.
As used herein, "temporal region" means the region of the scalp encompassing either side of the skull above the ears, but not including the frontotemporal region.
Hair follicles progressively miniaturize with degeneration and become non-functional follicles in balding individuals. The progressive miniaturization results in a steady decrease in hair specific keratin message, detectable by the PCR Technique. Subjects concerned about hair loss but unable to visually detect thinning of the hair can have biological samples analyzed for comparison of hair specific keratin message among the areas of the scalp having a greater potential for experiencing extensive hair loss (e.g., the vertex and frontotemporal regions) and limited to no hair loss (e.g., occipital and temporal region). A large difference in hair specific keratin message would suggest that the subject is suffering from hair loss related to miniaturization of follicles and hence a disease condition (e.g., androgenetic alopecia). This early detection would allow the subject to seek treatment for the hair loss prior to visual detection of hair loss on the scalp.
Alternatively, subjects concerned about hair loss but unable to visually detect hair loss can have a biological sample isolated at an earlier date and a biological sample isolated at a later date, and analyzed for comparison of hair specific keratin message. A large decrease in hair specific keratin level of the later dated sample as compared to the earlier dated sample would suggest that the subject is suffering from hair loss related to miniaturization of follicles and hence a disease condition (e.g., androgenetic alopecia). This early detection would allow the subject to seek treatment for the hair loss prior to visual detection of hair loss on the scalp.
Such methods for detecting hair loss would comprise: a) isolating a first biological sample from a subject, b) isolating a second biological sample from the subject, c) using a DNA sequence which encodes hair specific keratin, or fragment thereof, as a marker in a biological assay to detect a difference in the production of hair specific keratin in the biological samples.
In one embodiment, the first biological sample is isolated from an area of the scalp having a greater potential for experiencing extensive hair loss, preferably an area selected from the group consisting of the vertex region and the frontotemporal region. The second biological sample is isolated from an area of the scalp having a limited to no potential for hair loss, preferably a region selected from the group consisting of the occipital region and the temporal region.
In another embodiment, the first biological sample is isolated at an earlier point in time with respect to extraction of the second biological sample. The second biological sample is isolated at a later point in time with respect to the first sample. Preferably the first and second samples are isolated from about the same region of the scalp. Preferably the second sample is isolated from about one week to about ten years after taking the first sample, more preferably from about two weeks to about five years, more preferably still from about three weeks to about one year, most preferably from about one month to about six months.
b. Early Detection of Treatment Efficacy
Clinical reports suggest many patients undergoing minoxidil treatment get frustrated and discontinue using the drug when they see no visible hair growth effect on the scalp following several months of treatment, even though they would have seen meaningful hair growth if they had continued on the drug for a few more months. The diagnostic use of the PCR Technique will allow these individuals to make a more informed decision. Patients may be asked to undergo the PCR Technique analysis. If the hair specific keratin message is detectable in a sufficient amount, discontinuation of the drug treatment would not be recommended. In contrast, if detectable hair specific keratin activity is not observed, the patient would get a prescription for a different dose regimen, or be placed on a different active for a better response. This would avoid unnecessary exposure of non-responding subjects to an ineffective treatment and, thereby, save the patient money and aggravation.
Such a method for early detection of treatment efficacy would comprise: a) isolating a first biological sample, b) treating a subject with a compound or composition known for increasing hair growth, c) isolating a second biological sample from the subject, and d) using a DNA sequence which encodes hair specific keratin, or fragment thereof, as a marker in a biological assay to detect an increase in the production of hair specific keratin in the sample. An increase in the level of hair specific keratin would indicate that the compound or composition is efficacious for that subject.
As previously stated, the isolated hair specific keratin genes, or fragments thereof, of the present invention are useful in the methods of the present invention for identifying potential hair growth compounds or efficacious compositions useful for regulating hair growth comprising such compounds. Various factors which may contribute to the efficacy of a hair growth composition may include, but are not limited to, the concentration of the active compound, penetration enhancing components, and the addition of complimentary hair growth actives.
EXAMPLE I Isolation of the Human Hair Specific Keratin GenesThe cDNAs encoding two species of mouse hair specific keratins, type I-A1 and type II-B2 are cloned. (Bertolino, A. P., D. M. Checilal, R. Notterman, I. Sklaver, T. A. Schiff, I. M. Freed berg and G. J. GiDona, (1988) "Cloning and Characterization of a Mouse Type I Hair Keratin cDNA", Journal of Investigative Dermatology, Vol. 75, pp. 311-315; and Yu, D. W., I. M. Freedberg and A. P. Bertolino, (1990) "Complementary DNA and Deduced Amino Acid Sequences of Mouse Type II Hair Keratins", Clin. Res., Vol. 38, pp. 655A, both incorporated herein by reference). The evolutionary conservation between mouse and human genes is taken advantage of to isolate the human genes corresponding to the mouse genes coding for the mouse hair specific keratins.
1. Synthesis of Oligonucleotides
Two pairs of oligonucleotides are synthesized based upon the individual cDNA strands of the mouse cDNA. One pair (SEQ ID NO:1 and SEQ ID NO:2) is designed according to the cDNA sequence of mouse type I-A1 hair specific keratin and the other pair (SEQ ID NO:3 and SEQ ID NO:4) is designed according to the cDNA sequence of mouse type II-B2 hair specific keratin.
2. Isolation of the Fragments of Human Hair Specific Keratin Genes
Human genomic DNA is obtained from a commercial supplier (Clontech Laboratories, Inc., Palo Alto, Calif.). The above two pairs of oligonucleotides are used to specifically amplify their human counterparts from the human genomic DNA through the use of the standard polymerase chain reaction (PCR) technique as disclosed by Innis, incorporated herein by reference. Briefly, each pair of oligonucleotides are mixed with the human genomic DNA. The oligonucleotides hybridize with their corresponding human DNA. The hybridized probe acts as a primer for DNA chain synthesis which begins upon the addition of four types of deoxy-nucleoside triphosphate (dATP, dCTP, dGTP and dTTP) and Taq polymerase. When synthesis is complete, the whole mixture is heated further to melt the newly formed DNA duplexes. When the temperature is lowered again, another round of synthesis can take place. This cycle of synthesizing and remelting is repeated to specifically amplify the sequences of interest. Two human hair specific keratin gene fragments are obtained by the PCR technique, SEQ ID NO:5 and SEQ ID NO:6.
3. Determining the Nucleotide Sequence of the Keratin Fragments
Both SEQ ID NO:5 AND SEQ ID NO:6 are subcloned into plasmid vector pGEM 3Z. (Promega Corp., Madison, Wisc.). The nucleotide sequence of both fragments is determined by the standard dideoxynucleotide sequencing technique disclosed by Maniatis, pp. 13.713.74, incorporated herein by reference.
4. Isolation of Complete Human Hair Specific Keratin Genes
SEQ ID NO:5 and SEQ ID NO:6 are used as probes to screen a genomic library to identify and isolate the human hair specific keratin genes respectively comprising those DNA sequences. The procedure used is as disclosed by Maniatis, pp. 1.90-1.104, incorporated herein by reference.
EXAMPLE II Isolation of a Polvnucleic Acid Comprising a Human Hair Specific Keratin GeneSEQ ID NO:6 is used as a probe to screen a genomic library (Clontech, Emeryville, Calif.) to identify a polynucleic acid comprising a human hair specific keratin gene comprising SEQ ID NO:6, following the procedure disclosed in Example I, part 4. SEQ ID NO:6 is .sup.32 P labeled and the probe is hybridized to a nitrocellulose filter to which the genomic clones are fixed. The positive hybridization signal is identified by autoradiography. After screening, a positive clone is identified hybridized to SEQ ID NO:6. The clone comprises DNA sequence SEQ ID NO:7, SEQ ID NO:8 and SEQ ID NO:9 wherein there is a gap of unknown base pair length between SEQ ID NO:7 and SEQ ID NO:8, and a gap of unknown base pair length between SEQ ID NO:8 and SEQ ID NO:9; as well as DNA sequence SEQ ID NO:10. Digestion of the isolated clone with EcoRI produces several fragments, one such fragment having SEQ ID NO:10, another such fragment having SEQ ID NO:7, SEQ ID NO:8 and SEQ ID NO:9 with gaps as described above.
EXAMPLE III Measuring Hair specific keratin Gene Expression via Reverse Transcription-Polymerase Chain ReactionAs discussed above, several biological assays employing a DNA sequence, or fragment thereof, which encodes for hair specific keratin as probes, may be used to measure the degree of hair specific keratin gene expression in a sample. In one embodiment of the present invention, the biological assay involves the Reverse Transcription-Polymerase Chain Reaction (RT-PCR), as disclosed by Innis, incorporated herein by reference, with the following modifications.
1. Synthesis of PCR primers
A pair of primers are synthesized according to SEQ ID NO:5. Primer #1 is made up of base pairs (b.p.) 53 to 75 of SEQ ID NO:5 (upstream primer). Primer #2 is made up of b.p. 1140 to 1165 of SEQ ID NO:6 (downstream primer).
2. Isolation of total RNA from Hair Samples
Hair is plucked from a subject (approximately 10 to 20 strands). The total RNA is isolated from the hair sample using an RNAzol Kit.TM. (Tel-Test, Inc., Freindswood, Tex.). The RNAzol Kit.TM. comprises reagents useful for isolating total RNA from a tissue or cultured cells. The major components of the RNAzol Kit198 comprise: guanidinium thiocyanate, phenol and buffer. The RNAzol Kit.TM. procedure is incorporated herein by reference, except that the hair roots from the plucked hairs are excised and placed into 250 .mu.l of RNAzol solution followed by vortexing for 20 seconds and subsequently removing undissolved debris. Hair samples are taken from the subject before and after treatment with a potential hair growth regulating compound.
3. Amplification of Hair Specific Keratin RNA
Primer #2 is used for carrying out reverse transcription. The primer is mixed with total RNA, four types of deoxynucleoside triphosphate (dATP, dCTP, dGTP and dTTP) and reverse transcriptase. Reverse transcription is carried out at 42.degree. C. for forty-five minutes. Upon the completion of reverse transcription, PCR is initiated by the addition of primer #1 and Taq polymerase. The reaction is performed under a temperature combination of 60.degree. C. and 95.degree. C. for 25 cycles. The amplified hair specific keratin product can be detected by gel electrophoresis and visualized under UV light after being stained with ethidium bromide.
4. Generate Control RNA for the Quantitative PCR
In order to apply the RT-PCR technique for the purpose of accurately quantitating hair specific keratin RNA level, an external control RNA is necessary. Incorporation of a control RNA to the reaction will minimize the variations which may occur during the PCR amplification process thereby increasing the accuracy of the quantitation results. Criteria for selecting a control RNA include: 1) the control RNA should use the same pair of primers as the hair specific keratin RNA in the process of RT-PCR, and 2) the size of amplified end products of control RNA should be different from that of the hair specific keratin RNA.
For purposes of this Example Ill, a control RNA is generated by in vitro transcription, a standard protocol of which is disclosed by Promega Corp., Madison, Wisc., in their In Vitro Transcription Kit.TM., incorporated herein by reference. The major components for in vitro transcription comprise: T7 or SPG polymerase; dATP, dCTP, dGTP and dTTP; RNase inhibitor; and buffer for the reaction. The template used for in vitro transcription is a derivative of the plasmid containing SEQ ID NO:5 from Example 1, part 3. This control RNA contains an almost identical sequence to that of SEQ ID NO:5 except base pairs 347 to 715 are removed.
5. Quantitation of Hair specific keratin RNA Level
Prior to RT-PCR amplification, an equal amount of control RNA is added to each sample (pre- and post- hair growth regulating compound treated samples). RT-PCR is carried out by following procedure 3, above, except 32P dCTP is added to the reaction. The control RNA and hair specific keratin RNA are co-amplified together. Upon completion of the PCR amplification, the end products (both control and hair specific keratin RNA) are separated by polyacrylamide gel electrophoresis and the signals are quantified with Beta-Scope (Betagen Inc., Waltham, Mass.). The amount of hair specific keratin RNA is determined by its relative signal intensity to the control RNA. The level of hair specific keratin RNA before and after treating with potential hair growth regulating compounds are compared. An increase in hair specific keratin RNA level, as compared to the control, is suggestive of a compound's use for regulating hair growth. Preferably there is an increase in specific keratin RNA level of 5%, more preferably 10%, more preferably still 25%.
The invention has been described herein with reference to certain preferred embodiments and examples. Obvious variations may appear to those skilled in the art. Therefore, the invention is not to be considered limited thereto but only by the claims which follow.
__________________________________________________________________________
# SEQUENCE LISTING
- (1) GENERAL INFORMATION:
- (iii) NUMBER OF SEQUENCES: 11
- (2) INFORMATION FOR SEQ ID NO:1:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 21 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:1:
#21 AGGA G
- (2) INFORMATION FOR SEQ ID NO:2:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 21 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:2:
#21 GCCA G
- (2) INFORMATION FOR SEQ ID NO:3:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 24 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:3:
# 24TGAA CTCC
- (2) INFORMATION FOR SEQ ID NO:4:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 21 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:4:
#21 ACGC C
- (2) INFORMATION FOR SEQ ID NO:5:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 1195 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: double
(D) TOPOLOGY: linear
- (ii) MOLECULE TYPE: DNA (genomic)
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:5:
- CTAGAGCGTC AGAACCAGGA GTACCAGGTG CTGCTGGATG TGCGTGCCCG GC - #TGGAGTGT
60
- GAGATCAACA CATACCGGAG CCTGCTGGAG AGCGAGGACG CAAGTGAGTA CA - #TGGCAGAC
120
- GTGTTTGATG AAATGATGCA CGTGTGACTG TAACAGTTGG ACACCATGCA AA - #TATTGCAT
180
- ACCTTGGAAA GGAAATTATG CCTTCACACT AGACATGCTC AAACAGAACT CA - #GACAACAT
240
- AATATGGCCA TCATTTAAAA CATAAATGGT TTGGTAGCAA GAGTTGTTTG AT - #GTACAAAC
300
- TGAAATTCGC ACTGCCAAGT CTTTGCATTC TAGTATGATA ATATGCATGA CT - #GCATGATA
360
- TGTGATCAAG CCTTGTTTTT ACAATACTGT ATTGCCTAGT GGGTACATTC CC - #ATAGGCTA
420
- CCTGATTTGA TCTTATAATT ACACCAGGGG GCTGGATCAG TATTCCCTCC AT - #TCTACAGG
480
- AAAGTAAACT GGGGCTTGGA GAAGGTAAAT GACTCACCCC ATGTCATCAG TT - #TGGCATGA
540
- ATGGATTTGA GAGTAGACAT CAGAGTTTCA GAGTTTCTGT CTACCTTGGT GC - #TCTATGGC
600
- AGGGAGACCA TTAACAATTT GAGTTAGTTA TCTTTGTAGC AGGGGAGTCT GT - #GCCTTTTC
660
- TGTTCTAGGC CATGGCAAGT CCCTTGACCC AGGCATTCTT ACCCTTGGGG AT - #ATCTCTGG
720
- CATATGATTT TAAAATTGCC CTTAACTCAC TTTTCCACAT CACTTTTGTC TC - #CAGTCTGC
780
- CCAGCAATCC CTGTGCCACG ACCAACGCGT GCAGCAAGCC CATCGGACCC TG - #TCTCTCCA
840
- ATCCCTGTAC CTCTTGTGTC CCTCCTGCCC CCTGCACACC CTGTGCCCCA CG - #CCCCCGCT
900
- GTGGGCCCTG CAATTCCTTC GGGCCTGCAA GGTAGGGAAT GCCAGAGGAG CA - #AGGATGCA
960
- GGGCCCAGGA CTGGAGAGCT GTGACCTGGC TCTGGTTCAA CAAAAGGGGC CT - #GAAAACAT
1020
- CATTTGCATG GCTGGAGTTG CCCGCGTAAG GCGCCCAAGA AACTCACCCA AA - #GCCTGTAG
1080
- CCTCCCCAAC TACTCCAGAC TGTCCTGCTC ACCCATTTCC TTCCTGGGGG TC - #TGTTCCTT
1140
- CCTATGCTCA CCCAGAGAAC TCTCTGATGT CGCACTGGCC CTCCCTTGTA AG - #CTT
1195
- (2) INFORMATION FOR SEQ ID NO:6:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 827 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (ii) MOLECULE TYPE: DNA (genomic)
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:6:
- GAATTCAGGA GGTGATGAAC TCCAAGCTGG GCCTGGACAT CGAGATCGCC AC - #CTACAGGC
60
- GCCTGCTGGA GGGCGAGGAG CAGAGCTGGG TCCAACCAAG GGTGGCCCAG AA - #CCACCCTT
120
- CCCCATCCCT GGCACAAGCC TACCCTTGGC CTTGCTGAGC AATGGCCAGG GC - #TCTGGGGG
180
- AAAAAAATAT TATTATTCAC TTCCGGTGTG GGGAGGGCGG TGTGTGAGTT TG - #TCTGAGGC
240
- AAGCTGTTCC CTCAGACTCT GTTCTTAATT GACCAGTTGT GGACCCTACC CT - #ATGAACTG
300
- GGGAGCTTTT TCAGCCACTC TGGGGCAGTC ACTAATGTTG CCTTTTTCTC TT - #TCGCCCTC
360
- AGGCTATGTG AAGGCATTGG GGCTGTGAAT GTCTGTGAGT ATTTGGGGTC CA - #GTGTGGAC
420
- AGATTTACTA ACTACCTGTG ATGGAGGGGA GAGTTTGGAA AAAGGAGTGT TA - #CTGAGATT
480
- GAATATAAAA GAGTGGGCTG GCATCACAAC AGGAGGGATT TGGGGTCATA CA - #TCCAAAAG
540
- ACCCCAGCTC TTGGACTAGA TGGACCTAGA ATTGTCCACA AAGATGCCTC TG - #ACTTTTCA
600
- TACCAGAGCT GAGGTCTTGG GCAGGGGCGG TTGTCAGGAG GGCAGGATGG CT - #TGCCCTTC
660
- AGAATTTTGA CTCAGCTTCG GGGTTCACAG GTGTCAGCAG CTGGCGGGGC GG - #GGTCGTGT
720
- GCGGGGACCT CTGCGTGTCA GGCTCCCGGC CAGTGACTGG CAGTGTCTGC AG - #CGCTCCGT
780
# 827GGTG AGCACCGGCC TGTGTGCGCC CTCTAGA
- (2) INFORMATION FOR SEQ ID NO:7:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 291 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:7:
- GAATTCTAGC TCTGCCACTC TCTAGCTGTG TAAACTCAGG CAATTACTTA GC - #CTCTATGT
60
- ACCTCATTTC ATGATTTCTA AAATGAAGAT AATAATAGTA CCCACCTCAT AA - #AGTTGTAA
120
- AGATTAAAAG AGTTAATCCA TGTAAATCAC TGAGAACTAA GCCTGGCACA CT - #CTAAGTGT
180
- GTAATCATAT TAGTTGTTGT TGTTGTTGCT GCTGATGCTG CTGCTGCAGA CG - #TATCAACA
240
# 291ATACTCA TCACATGCCT AAGCCATCTG TGTCCAGTTT T
- (2) INFORMATION FOR SEQ ID NO:8:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 376 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:8:
- TGCTGGAGGG CAAGGAGCAG AGGTGGGTCC AACCAAGGGT GGCCCAGAAC CA - #CCCTTCCC
60
- CATCCCTGGC ACAAGCCTAC CCTTGGCCTT GCTGAGCAAT GGCCAGGGCT CT - #GGGGGAAA
120
- AAATGTGGAC CCTACCCTAT GAACTGGGGG AGCTTTTTCA GCCACTCTGG GG - #CAGTCACT
180
- AATGTTGCCT TTTTCTCTTT TCGCCCTCAG GCTATGTGAA GGCATTGGGG CT - #GTGAATGT
240
- CTGTCAGTAT TTGGGGTCCA GTGTGGACAG ATTTACTAAC TACCTGTGAT GG - #AGGGCAGA
300
- GTTTGGAAAA AGGAGTGTTA CTGAGATTGA ATATAAAAGA GTGGGCTGGC AT - #CACAACAG
360
# 376
- (2) INFORMATION FOR SEQ ID NO:9:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 295 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:9:
- TACCGACACA ACCCTAATGA TACACCTTGC AGATGAAGAA GCCAGAACTC AG - #AGGCACTC
60
- AATAATTGGG GCAGGGTCAC CCACTTAGTT GGGTGGTTCA TCTGGGGTTT AA - #GCCCTGTG
120
- TGTGTCGCTA GTGCTGCATT TCACTAAACT GCAGCTGTCT CTCAGAAAAC AT - #CTCATGCA
180
- TATCTGCAAA CTGATGGATC ATGAAAATCA GATTCACCAA TCACTCAAAG CT - #TGAGGCAA
240
- CATCACCCAT TGCTTTGGTA GGGAAGACTC ATGCCTGAGT AATTTATTGG AA - #TTC
295
- (2) INFORMATION FOR SEQ ID NO:10:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 856 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:10:
- GAATTCCATC AGGGGTGGCT GAGAGACCTT GGTTTGATTC TAGCTTTTAC AG - #GAGAATTT
60
- GTTCTTTTCA GTCCACTCAC TTCTGGTCTC TTAATATTCT TAATAATTTC TA - #GTGCCCAG
120
- AAGGGTAGGG GTGGGGGACT CCCATTTCTG CTGTATTTTC TGGGCCTTGG AC - #TGGAAGTT
180
- TAGAGATTCA CTCCGGTTTA AAGATGTATG TTCAGGGAGT CACCTTGGCC CA - #TAGTGGGC
240
- GTGAGCTGTC ATCTTCCCCT TCCCCTACCT CATCAGTGTC AACTTAATAC TT - #CCATGCAT
300
- GAAGGAGCTG AATGGCCCTG GTAACCACGG AGGTTTCTCT CTGTACTTGC AA - #TCTCTGAT
360
- CACAGATATC AATGTAATAA GAGGTTGGCC ATAAGAGGCC CTGATCCCTA GA - #GGGACTTC
420
- TACTTTACAT TCTGCAAAAA GAATAACACT AATGATAAAA AATAGAGTGA TA - #ATTTTGTG
480
- GCATGCACCA TCTAAACCTT TTACGTATAT GAAATCCTTT AACTCATCAG CT - #TATGAGGT
540
- GGTTGCCCTT TCTATCATCC TCATTTTGGA GGTGTGGAAA CAGGCAGCAG AG - #AGGGAAAT
600
- ACATTGCCCA ACCCACTCAC CTAGGAAGGA CCAGGCCCGA GCTTGGGGCC CA - #GGCAGTCT
660
- GGCTGGAGTC CGTGTCCCCC CTCTATGCCA CATCATCTTG CTATGTGCTC TT - #TTCTGTCT
720
- TTGAGAAAAA TGTATCAGCT GTGGCAGGTC TCCAAAACCC CAGAGTGATG CC - #ATTTAAAA
780
- AAAAAAAAAG AAAGCCAACA TCAAAGGCTT TTTGAAACTT TAAATCATAT TC - #ATGTATTC
840
# 856
- (2) INFORMATION FOR SEQ ID NO:11:
- (i) SEQUENCE CHARACTERISTICS:
#pairs (A) LENGTH: 3914 base
(B) TYPE: nucleic acid
(C) STRANDEDNESS: single
(D) TOPOLOGY: linear
- (xi) SEQUENCE DESCRIPTION: SEQ ID NO:11:
- ACAGCTCTGT GGCTTGGAGA ATTTAGACTC TGTCTTCAGC CAGGCACTCC CT - #CCCTCCCT
60
- CCCAGCACTA TGCCCTACAA CTTCTGCCTG CCCAGCCTGA GCTGCCGCAC CA - #GCTGCTCC
120
- TCCCGGCCCT GCGTGCCCCC CAGCTGCCAC AGCTGCACCC TGCCCGGGGC CT - #GCAACATC
180
- CCCGCCAATG TGAGCAACTG CAACTGGTTC TGCGAGGGCT CCTTCAATGG TA - #GCGAGAAG
240
- GAGACTATGC AGTTCCTGAA CGACCGCCTG GCCAGCTACC TGGAGAAAGT GC - #GTCAGCTG
300
- GAGCGGGACA ACGCGGAGCT GGAGAACCTC ATCCGGGAGC GGTCTCAGCA GC - #AGGAGCCC
360
- TTGCTGTGCC CCAGTTACCA GTCCTATTTT AAGACCATTG AGGAGCTCCA GC - #AGAAGGTG
420
- AGCGGCATTG CTGTCATCTC CAAGCAAGAG AGTTTGCTGT GATTCTGTCT GT - #GATAGAGA
480
- AGTGTGTTTC TTGCTTCTGT GCTGTCATAA TTCTTGCTTC CTCTTTTATT TC - #AAAATGGC
540
- TTAAGTCATT TTTAAAAAGT TGATGATTTC ATATTTATTT TCAGTCCTCA CT - #AAGCCACC
600
- TCTCACTCCC CAGATCCTGT GTACCAAGTC TGAGAATGCC AGGCTTGTGG TG - #CAGATCGA
660
- CAACGCCAAG CTGGCTGCGG ATGATTTCAG AACCAAGTGA GTTGTTCGGA AT - #TTGCACTA
720
- GTGTCAATTG CTTCTGTTTA ATCTTTAAAG AAAAGGGATT TCCATCTGAA AA - #CAGATCTA
780
- CCCACTTGTT GTGAAGGATT CTGCAGAGGA CTGGGGAGAA CCAAGCAAAG AA - #ATGCAAAA
840
- ATGGATGAGG ACTCACATCA ATCTGTTTGT TTTGGGATGA ATATTGGGTA TT - #GATGGAGC
900
- CTCCAGAAAC CTCTGTCTCC TGGGCCTATT CATTACAGAA AGTGGAAAGA TA - #AGGCACAT
960
- GAGGTTATCA AAAATCATTC CTGTGAGTCT TGAAGATCTA CCAGGTAGTA CT - #CTGACCCT
1020
- GTCCTTGCGC AGGTACCAGA CCGAGCTGTC CCTGCGGCAG CTGGTGGAGT CG - #GACATCAA
1080
- CGGTCTGCGC AGGATCCTGG ATGAGCTGAC CCTGTGCAAG TCCGACCTGG AG - #GCCCAGGT
1140
- GGAGTCCCTG AAGGAGGAGC TGCTCTGCCT CAAGAGCAAC CATGAGCAGG TG - #AGACTAGA
1200
- AATGAGAAAT GCACAAACCT GTCTCAGCCT CTGGCTCAGG GTTGCTTTAG TG - #ATTTGGGG
1260
- CAGCAGAATG CAGAGTATGA GTACAAGACT GAGGGTTTCC TTTGAAAACA TC - #ACGGTAAG
1320
- AGAAAAATTG GAGAGAGATA AGACCTGTTC ATGTTCCCAG ACAGGAAACA TC - #TTTCACTT
1380
- TAAACTAGCA CATTATTTGA GTTGCCCGGA GCAGCTCCAT GTGCTTGCAG TT - #GATCAATA
1440
- GTTGTAGAAT GAGTCCTAGC ATTGCAGTGT TATTGCTTTG TAAAGTCTTT TT - #TTTTTTTT
1500
- TTTGGCAAAG GCCAAGAAAA AAAATATCAA ACCTTATAAA TGTGAGTCTC TA - #CTCTTTCA
1560
- AAGTATTGGT GAAGAGTGTT TGTGAGATTC TTCCTCTCTC TTGGGAGGGG CC - #ATGACATG
1620
- CTCTTACCTC TTACTTGACA GCAAGAGTTT TTTGATATAT GGTCTGAAAT TG - #CACAGCCT
1680
- ATTTTTTTTG GCATTCTGAG GTCCTCACAG CCAATTGTAA ACTGGGAAAG TT - #GAATATCA
1740
- ATTAGTTCAT CCTTCAGTGG CATCCAAGCA AACTTTTGGG ATTTTTTTCT GA - #AGCCAAGT
1800
- GCCATGGCAC AGCAGATGGT GGGGAGGGGG CTATGCCACA TGGAGTGCCT TG - #AGCTGTCA
1860
- CAAACTGCTC CACTCAAAGT TTCTTTTCCG AGAAAATAGA CTAACAGGGT TT - #CAACAAGC
1920
- AATGCCATTC CTTAGAGTTC ATTCTTTGCT GAGCATAGTA ACTCTTGTAT TT - #TCTGCATC
1980
- CATAGGAGGT CAATACCCTG CGCTGCCAGC TTGGAGACCG CCTCAATGTG GA - #GGTGGATG
2040
- CTGCTCCCAC TGTGGACCTG AATCGGGTGC TGAACGAGAC CAGGAGTCAG TA - #TGAGGCCC
2100
- TGGTGGAAAC CAACCGCAGG GAAGTGGAGC AATGGTTCAC CACGCAGGTG GG - #CATCTAAG
2160
- CACGTGGCCC CTCAGGACCC AAGGCCCCCC AGGGCCCCGG AGGCAGGGTC TG - #ATCCTTTC
2220
- TCCCCTTGGG TGTTTCAGAC CGAGGAGCTG AACAAGCAGG TGGTATCCAG CT - #CAGAGCAG
2280
- CTGCAGTCCT ACCAGGCGGA GATCATCGAG CTGAGACGCA CAGTCAACGC CC - #TGGAGATC
2340
- GAGCTGCAGG CCCAGCACAA CCTGGTGTGT ATTGTTCAGA CCTGCTGGTG AG - #CGACGGGA
2400
- ACTTGGGAGG CAGAGTCCCG GGGATGTGCT TGGGGCCACA CACTCTCCTT AG - #CTCTTGGA
2460
- GCTTGTGACT TCCTTGTAAT CCTGTGAAGA AACCCTTTGA AGGAGCAGCT CT - #CTGACATT
2520
- CCCAATCTTC TCCACCACAG CGAGACTCTC TGGAAAACAC GCTGACAGAG AG - #TGAGGCCC
2580
- GCTACAGCTC CCAGCTGTCC CAGGTGCAGA GCCTGATCAC CAACGTGGAG TC - #CCAGCTGG
2640
- CGGAGATCCG CAGTGACCTG GAGCGGCAGA ACCAGGAGTA CCAGGTGCTG CT - #GGATGTGC
2700
- GTGCCCGGCT GGAGTGTGAG ATCAACACAT ACCGGAGCCT GCTGGAGAGC GA - #GGACTGCA
2760
- AGTGAGTACA TGGGCAGACG TGTTTGATGA AATGATGCAC GTGTGAGTGT AA - #CAGTTAGA
2820
- CACCATGCAA ATATTGCATA CCTTGGAAAG GAAATTATGC CTTCACACTA GA - #CATGCTCA
2880
- AACAGAACTC AGACAACATA ATATGGCCAT CATTTAAAAC ATAAATGGTT TG - #GTAGCAAG
2940
- AGTTGTTTGA TGTACAAACT GAAATTGCAC TGCCAAGTCT TTGCATTCTA GT - #ATGATAAT
3000
- ATGCATGACT GCATGATATG TGATCAATGC CTTACTTTTT ACAATACTGT AT - #TGCCTAGT
3060
- GGGTACATTC CCATAGGCTA CCTGATTTGA TCTTATAATT ACCACCAGGT GG - #GCTGGATC
3120
- AGTATTCCCT CCATTCTACA GGAAAGTAAA CTGGGGCTTG GAGAAGGTAA AT - #GACTCACC
3180
- CCATGTCATC AGTTTGGCAT GAATGGATTT GAGAGTAGAC ATCAGAGTTT CA - #GAGTTTCT
3240
- GTCTACCTTG GTGCTCTATG GCAGGGAGAC CATTAACAAT TTGAGTTAGT TA - #TCTTTGTA
3300
- GCAGGGGAGT CTGTGCCTTT TCTGTTCTAG GCCAGGTCAA GTCCCTTGAC CC - #AGGCATTC
3360
- TTACCCTTGG GGATATCTCT GGCATATGAT TTTAAAATTG CCCTTAACTC AC - #TTTTCCAC
3420
- ATCATTCTTT TGTCTCCAGT CTGCCCAGCA ATCCCTGTGC CACGACCAAC GC - #GTGCAGCA
3480
- AGCCCATCGG ACCCTGTCTC TCCAATCCCT GTACCTCTTG TGTCCCTCCT GC - #CCCCTGCA
3540
- CACCCTGTGC CCCACGCCCC CGCTGTGGGC CCTGCAATTC CTTCGTGCGC TA - #GAACCTAG
3600
- GGAATGCCAG AGGAGCAAGG ATGCAGGGCC CAGGACTCCA GAGCTGTGAC CT - #GGCTCTGG
3660
- TTCAACAAAA GGGGCCTGAA AACATCATTT GCATGGCTGG AGTTGCCCGC GT - #AAGGCAGC
3720
- CAAGAAACTC ACCCAAAGCC TGTAGCCTCC CCAACTACTC CAGACTGTCC TG - #CTCACCCT
3780
- TTCCTTCCTG GGGGTCTGTT CCTTCCTATG CTCACCCAGA GAACTCTCTG AT - #GTGCCAGT
3840
- GGCCCTCCCT TTTAACCTCC TAATAAATAT CATTTCCTTG GCAAAGCAGA TG - #CCTTTTTC
3900
# 3914
__________________________________________________________________________
Claims
1. An isolated human hair specific keratin gene or fragment thereof having a DNA sequence selected from the group consisting of
- a) SEQ ID NO:11; and
- b) a DNA sequence comprising the following DNA sequences:
- i) SEQ ID NO:6
- ii) SEQ ID NO:7
- iii) SEQ ID NO:8
- iv) SEQ ID NO:9, and
- v) SEQ ID NO:10.
2. The human hair specific keratin gene, or fragment thereof, of claim 1 wherein the gene has the DNA sequence SEQ ID NO:11.
3. The human hair specific keratin gene, or fragment thereof, of claim 1 wherein the gene has the DNA sequence comprising the DNA sequences:
- a) SEQ ID NO:6
- b) SEQ ID NO:7
- c) SEQ ID NO:8
- d) SEQ ID NO:9, and
- e) SEQ ID NO:10.
Type: Grant
Filed: Sep 2, 1993
Date of Patent: Oct 3, 2000
Assignee: The Procter & Gamble Company (Cincinnati, OH)
Inventors: Paul Edward Bowden (South Glamorgan), Xiaochun Luo (West Chester, OH), Cynthia Jo. Wawrzyniak (Sharonville, OH)
Primary Examiner: Donald P. Walsh
Assistant Examiner: Anthony R. Chi
Attorneys: Brahm J. Corstanje, David L. Suter, Jacobus C. Rasser
Application Number: 8/117,373
International Classification: C07H 1700;
