NUCLEIC ACID COMPLEX, METHOD FOR FORMING NUCLEIC ACID HYBRIDIZATION, PHARMACEUTICAL COMPOSITION, NUCLEIC ACID PROBE, AND COMPLEMENTARY-STRAND NUCLEIC ACID COMPLEX
A nucleic acid complex includes a single-stranded nucleic acid and a cross-linked double-stranded nucleic acid including the first nucleic acid strand linked to at least one of the 5′ end and the 3′ end of the single-stranded nucleic acid and the second nucleic acid strand including a base sequence that is completely or sufficiently complementary to the first nucleic acid strand.
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The present disclosure relates to nucleic acid complexes, methods of nucleic acid hybridization, pharmaceutical compositions, probes for nucleic acid detection, and complementary strand nucleic acid complexes.
BACKGROUND ARTWhen nucleic acids are introduced into the body from the outside, the nucleic acid introduced is readily broken down by nucleases present in the blood or body fluids and is therefore unable to stably form hybrids with DNA or RNA that has a target sequence.
In view of this, for the purpose of improving nucleic acid's stability within a living organism, techniques for chemically modifying the nucleic acid have been developed.
Non Patent Literature 1 and 2 have reported that locked nucleic acids (LNAs) developed as modified nucleic acids are highly stabile in hybridization with RNA. In addition, Non Patent Literature 3 has reported chemical modification (2′-O-methyl (2′-OMe) nucleotides) of methylation of the 2′ hydroxyl group of the sugar moiety of nucleic acid to be hybridized.
In order to improve the durability of nucleic acids within a living organism, approaches different from the modified nucleic acid have been suggested.
Non Patent Literature 4 and 5 describe that formation of a complementary double stranded nucleic acid structure adjacent to an oligonucleotide sequence that hybridizes with miRNA improves nuclease resistance of the oligonucleotide sequence. In addition, Non Patent Literature 6 and 7 describe that a hairpin loop is designed to form in a complementary double stranded nucleic acid structure formed adjacent to an oligonucleotide sequence that hybridizes with miRNA.
CITATION LIST Non Patent Literature
- Non Patent Literature 1: Koshkin, A., Singh, S., Nielsen, P., Rajwanshi, V., Kumar, R., Meldgaard, M., Olsen, C. E. and Wengel, J. (1998). LNA (locked nucleic acids): synthesis of the adenine, cytosine, guanine, 5-methylcytosine, thymine and uracil bicyclonucleoside monomers, oligomerisation, and unprecedented nucleic acid recognition. Tetrahedron 54, 3607-3630.
Non Patent Literature 2: Obika, S., Nanbu, D., Hari, Y., Andoh, J., Morio, K., Doi, T. and Imanishi, T. (1998). Stability and structural features of the duplexes containing nucleoside analogues with a fixed N-type conformation, 2′-O,4′-C-methyleneribonucleosides. Tetrahedron Lett. 39, 5401-5404.
- Non Patent Literature 3: Inoue, H., Hayase, Y., Imura, A., Iwai, S., Miura, K. and Ohtsuka, E. (1987). Synthesis and hybridization studies on two complementary nona(2′-O-methyl)ribonucleotides. Nucleic Acids Res. 15, 6131-6148.
- Non Patent Literature 4: Haraguchi, T., Ozaki, Y. & Iba, H. (2009). Vectors expressing efficient RNA decoys achieve the long-term suppression of specific microRNA activity in mammalian cells. Nucleic Acids Res 37, e43.
- Non Patent Literature 5: Haraguchi, T., Nakano, H., Tagawa, T., Ohki, T., Ueno, Y., Yoshida, T. & Iba, H. (2012). A potent 2′-O-methylated RNA-based microRNA inhibitor with unique secondary structures. Nucleic Acids Res 40, e58.
- Non Patent Literature 6: Lennox, K. A. & Behlke, M. A. (2010). A direct comparison of anti-microRNA oligonucleotide potency. Pharm Res 27, 1788-1799.
- Non Patent Literature 7: Vermeulen, A., Robertson, B., Dalby, A. B., Marshall, W. S., Karpilow, J., Leake, D., Khvorova, A. & Baskerville, S. (2007). Double-stranded regions are essential design components of potent inhibitors of RISC function. RNA 13, 723-730.
There have, however, been drawbacks in the methods of Non Patent Literature 1 to 3; and the cost for the synthesis is high in particular when multiple nucleic acids are modified in the oligonucleotide sequence. In addition, the stability of the complementary double stranded nucleic acid structure formed adjacent to the oligonucleotide sequence that hybridizes with miRNA fluctuates according to changes in external factors such as temperature, ionic strength, or pH in the methods of Non Patent Literature 4 to 7; and there have thus been some cases where the complementary double stranded nucleic acid structure dissociates into single strands within a living organism.
The present disclosure was made in light of the above circumstances; and an objective thereof is to provide nucleic acid complexes capable of stably hybridizing with a target nucleic acid, methods of nucleic acid hybridization, pharmaceutical compositions, probes for nucleic acid detection, and complementary strand nucleic acid complexes.
Solution to ProblemIn order to achieve the above objective, the nucleic acid complex according to the first aspect of the present disclosure comprises
-
- a single-stranded nucleic acid and
- a cross-linked double-stranded nucleic acid comprising a first nucleic acid strand linked to at least one of the 5′ end and the 3′ end of the single-stranded nucleic acid and a second nucleic acid strand comprising a base sequence that is completely or sufficiently complementary to the first nucleic acid strand.
The above-mentioned cross-linked double-stranded nucleic acid is, for example, linked to the 5′ end of the single-stranded nucleic acid.
The above-mentioned cross-linked double-stranded nucleic acid is, for example, cross-linked by a bond via a sugar of at least one of the first nucleic acid strand and the second nucleic acid strand.
The above-mentioned cross-linked double-stranded nucleic acid is, for example, cross-linked by a bond between sugars of the first nucleic acid strand and the second nucleic acid strand.
The sugars of the first nucleic acid strand and the second nucleic acid strand are, for example, bound by at least one kind of covalent bond selected from the group consisting of an amide bond, an oxime bond, an alkylamide bond, an S—S bond, and a carbon-carbon bond.
The sugars of the first nucleic acid strand and the second nucleic acid strand are, for example, linked by a cross-linking reagent having an aminooxy group or an amino group.
The above-mentioned cross-linking reagent is, for example, a compound represented by general formula 1:
R1—NH—O-L1-D-L2-A (1)
(wherein
R1 is a protective group of a hydrogen atom, an alkyl group, or an amino group,
D is an aromatic group selected from a substituted or unsubstituted phenylene group, a substituted or unsubstituted anthrylene group, a substituted or unsubstituted naphthylene group, a substituted or unsubstituted phenanthrylene group, a substituted or unsubstituted anthraquinolylene group, and a substituted or unsubstituted acridinylene group, or a C2-10 alkyl group,
a substituent of the aromatic group is selected from the group consisting of a halogen atom, a C1-6 alkyl group, a nitro group, a cyano group, a C2-6 alkenyl group, a C3-10 cycloalkyl group, a C1-10 alkoxy group, and a C1-10 acyl group,
L1 is a direct bond or a divalent group represented by the following general formula 3 or 4:
(wherein R3 is a C1-9 alkylene group or —(CH2)o—(OCH2CH2)p—(CH2)q—, o to q are each independently an integer of 0 to 15, o+p+q is 1 to 15),
L2 is a direct bond or a divalent group represented by the following general formula 5 or 6:
(wherein R4 is a C1-9 alkylene group or —(CH2)r—(OCH2CH2)s—(CH2)t—, r to t are each independently an integer of 0 to 15, r+s+t is 1 to 15), and
A is an aminooxy group or a protected aminooxy group)
or a salt thereof
The above-mentioned cross-linking reagent, for example, has the aminooxy group, and
aldehyde groups in the sugar of the first nucleic acid strand and the second nucleic acid strand are linked via the aminooxy group of the cross-linking reagent in the cross-linked double-stranded nucleic acid.
The method of nucleic acid hybridization according to the second aspect of the present disclosure comprises
-
- the step of hybridizing the nucleic acid complex according to the first aspect of the present disclosure with a target nucleic acid comprising a base sequence that is completely or sufficiently complementary to a base sequence of a single-stranded nucleic acid that forms the nucleic acid complex.
The pharmaceutical composition according to the third aspect of the present disclosure comprises
-
- the nucleic acid complex according to the first aspect of the present disclosure.
The probe for nucleic acid detection according to the fourth aspect of the present disclosure comprises
-
- the nucleic acid complex according to the first aspect of the present disclosure.
The complementary strand nucleic acid complex according to the fifth aspect of the present disclosure comprises
-
- the first nucleic acid complex comprising the first single-stranded nucleic acid and the first cross-linked double-stranded nucleic acid linked to the 5′ end or the 3′ end of the first single-stranded nucleic acid and
- the second nucleic acid complex comprising the second single-stranded nucleic acid comprising a base sequence that is completely or sufficiently complementary to the base sequence of the first single-stranded nucleic acid,
- wherein the first single-stranded nucleic acid and the second single-stranded nucleic acid are hybridized.
The above-mentioned second nucleic acid complex, for example, comprises the second cross-linked double-stranded nucleic acid linked to the 3′ end or the 5′ end of the second single-stranded nucleic acid.
Advantageous Effects of InventionAccording to the present disclosure, it is possible to provide nucleic acid complexes capable of stably hybridizing with a target nucleic acid, methods of nucleic acid hybridization, pharmaceutical compositions, probes for nucleic acid detection, and complementary strand nucleic acid complexes.
First, the nucleic acid complex according to the present disclosure will be described in detail.
The nucleic acid complex according to the present disclosure comprises
-
- a single-stranded nucleic acid and
- a cross-linked double-stranded nucleic acid comprising the first nucleic acid strand linked to at least one of the 5′ end and the 3′ end of the single-stranded nucleic acid and the second nucleic acid strand comprising a base sequence that is completely or sufficiently complementary to the first nucleic acid strand.
The term “single-stranded nucleic acid” described above refers to a “nucleic acid comprising a base sequence that is completely or sufficiently complementary to the base sequence of a target nucleic acid.” In the present specification, the “single-stranded nucleic acid” may be DNA; RNA; a modified nucleic acid obtained by derivatization of a sugar moiety of nucleic acid such as 2′-O-methylated RNA (hereinafter referred to as 2′-OMe RNA) and locked nucleic acid (hereinafter referred to as LNA); a modified nucleic acid obtained by derivatization of a phosphodiester bond (for example, a phosphothioester bond in which an oxygen atom is replaced with a sulphur atom); other modified nucleic acids; or a mixture thereof. It is to be noted that these modified nucleic acids are disclosed in, for example, Deleavey, G. F. and Damha, M. J., Chemistry & Biology, 19, 937-954, 2012.
In the present specification, a “target nucleic acid” may be either DNA or RNA; and examples thereof can include non-coding RNA (microRNA, ribosomal RNA, tRNA, or the like), mRNA, and single-stranded DNA. The target nucleic acid may be those present within a living organism or those present outside of a living organism. The length of target nucleic acid is not particularly restricted and is, for example, preferably 5 to 30 mer and more preferably 10 to 25 mer.
In the present specification, “(a single-stranded nucleic acid) comprising a base sequence that is completely complementary (to the base sequence of a target nucleic acid)” means that the single-stranded nucleic acid comprises only a base sequence capable of pairing with all bases of the base sequence of a target nucleic acid.
In the present specification, “(a single-stranded nucleic acid) comprising a base sequence that is sufficiently complementary (to the base sequence of a target nucleic acid)” is those comprising a base sequence that can be paired with not less than 50% and less than 100%, preferably not less than 60% and less than 100%, more preferably not less than 70% and less than 100%, further preferably not less than 80% and less than 100%, still more preferably not less than 90% and less than 100% of bases in the base sequence of a target nucleic acid. To be specific, examples include cases where one or two to four bases in the nucleic acid strand comprising a base sequence that is completely complementary to the base sequence of a target nucleic acid are substituted with other bases and, as a result, nucleotide residues at the substitution positions become unable to make pairing (in these cases, the position at which the substitution with other bases takes place is referred to as a “mismatch site”) and cases where one or two to four bases in the nucleic acid strand comprising a base sequence that is completely complementary to the base sequence of a target nucleic acid are deleted and, as a result, nucleotide residues at the deletion positions become unable to make pairing.
In the present specification, a “single-stranded nucleic acid comprising a base sequence that is completely complementary to the base sequence of a target nucleic acid” and a “single-stranded nucleic acid comprising a base sequence that is sufficiently complementary to the base sequence of a target nucleic acid” may in some cases be collectively referred to as simply a “single-stranded nucleic acid”. It is to be noted that the “single-stranded nucleic acid” is shown using a lateral thin line in
The above-mentioned “cross-linked double-stranded nucleic acid” includes those comprising two nucleic acid strands comprising a completely or sufficiently complementary base sequence, which is linked to at least one of the 5′ end and the 3′ end of a single-stranded nucleic acid (the “cross-linked double-stranded nucleic acid” is indicated by two lateral bold arrows in
The two nucleic acid strands (that is, the first nucleic acid strand and the second nucleic acid strand) in the cross-linked double-stranded nucleic acid may be DNA; RNA; a modified nucleic acid obtained by derivatization of a sugar moiety of a nucleic acid such as 2′-OMe RNA and LNA; a modified nucleic acid obtained by derivatization of a phosphodiester bond; other modified nucleic acids; or a mixture thereof. It is to be noted that these modified nucleic acids are the same as described above. Further, the length of the first nucleic acid strand and the second nucleic acid strand is not particularly restricted and is, for example, preferably 5 bp to 30 bp, more preferably 7 bp to 20 bp, and still more preferably 9 bp to 12 bp. Further, the first nucleic acid strand and the second nucleic acid strand may have the same lengths or may have different lengths. In the case in which the length of the first nucleic acid strand and the second nucleic acid strand is the same, besides the mode shown in
It is to be noted that the “single-stranded nucleic acid” and the “cross-linked double-stranded nucleic acid” in the nucleic acid complex according to the present disclosure may be the same kind or different kinds of nucleic acids. For example, the “single-stranded nucleic acid” may be RNA and the “cross-linked double-stranded nucleic acid” may be DNA.
In the cross-linked double-stranded nucleic acid, two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand are bound and cross-linked; and a method of cross-linking is not particularly restricted and any can be as appropriate employed as long as it is a technique capable of linking the two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand. The two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand may be cross-linked by, for example, a bond via a sugar of at least one of the first nucleic acid strand and the second nucleic acid strand. Further, the two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand may be cross-linked by, for example, a bond between sugars of the first nucleic acid strand and the second nucleic acid strand; and in this case the sugars of the first nucleic acid strand and the second nucleic acid strand may be bound by a covalent bond including an amide bond, an oxime bond, an alkylamide bond, an S—S bond, and a carbon-carbon bond (for example, a bond via an alkyl chain having 2 to 10 carbon atoms).
In the case in which the first nucleic acid strand and the second nucleic acid strand are cross-linked between sugars thereof in the cross-linked double-stranded nucleic acid, a reactive group present in the sugar of the nucleic acid or a reactive group introduced to the sugar of the nucleic acid may, for example, be linked by a cross-linking reagent. Examples of the reactive group in this case can include an aldehyde group, a thiol group, an azide group, and an amino group.
The sugars in the nucleic acid strand of the first nucleic acid strand and the second nucleic acid strand may be linked by a cross-linking reagent having, for example, an aminooxy group or an amino group. In this case, the reactive groups of the sugars are linked by reacting a reactive group of the sugar (for example, an aldehyde group, a thiol group, an azide group, an amino group, or the like) with the aminooxy group or the amino group.
Examples of the cross-linking reagent with an aminooxy group or an amino group can include a compound represented by
general formula 1:
R1—NH—O-L1-D-L2-A (1)
(wherein
R1 is a protective group of a hydrogen atom, an alkyl group, or an amino group,
D is an aromatic group selected from a substituted or unsubstituted phenylene group, a substituted or unsubstituted anthrylene group, a substituted or unsubstituted naphthylene group, a substituted or unsubstituted phenanthrylene group, a substituted or unsubstituted anthraquinolylene group, and a substituted or unsubstituted acridinylene group, or a C2-10 alkyl group,
a substituent of the aromatic group is selected from the group consisting of a halogen atom, a C1-6 alkyl group, a nitro group, a cyano group, a C2-6 alkenyl group, a C3-10 cycloalkyl group, a C1-10 alkoxy group, and a C1-10 acyl group,
L1 is a direct bond or a divalent group represented by the following general formula 3 or 4:
(wherein R3 is a C1-9 alkylene group or —(CH2)o—(OCH2CH2)p—(CH2)q—, o to q are each independently an integer of 0 to 15, o+p+q is 1 to 15),
L2 is a direct bond or a divalent group represented by the following general formula 5 or 6:
(wherein R4 is a C1-9 alkylene group or —(CH2)rOCH2CH2)s—(CH2)t, r to t are each independently an integer of 0 to 15, r+s+t is 1 to 15), and
A is an aminooxy group or a protected aminooxy group)
or a salt thereof. This cross-linking reagent is as described in Japanese Patent No. 5196448.
In the cross-linked double-stranded nucleic acid, aldehyde groups in the sugars of the first nucleic acid strand and the second nucleic acid strand may be linked via an aminooxy group (divalent) of a cross-linking reagent. In this case, a cross-linking reagent having an aminooxy group is used; and N1,N5-bis(aminooxyacetyl)-1,5-diaminonaphthalene (aoNao) which is shown below may, for example, be used as the cross-linking reagent.
In the cross-linked double-stranded nucleic acid, in the case in which the aldehyde groups of the sugars of the first nucleic acid strand and the second nucleic acid strand are linked via the aminooxy group (divalent) of the cross-linking reagent, an example method is a method comprising synthesizing the first nucleic acid strand and the second nucleic acid strand so as to contain deoxyuridine at a position at which the first nucleic acid strand and the second nucleic acid strand make pairing; treating the first nucleic acid strand and the second nucleic acid strand with Uracil DNA glycosylase (UDG) to allow an AP site to be formed in the deoxyuridine of the first nucleic acid strand and the second nucleic acid strand (
The two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand may be cross-linked via, for example, a bond via a sugar of at least one of the first nucleic acid strand and the second nucleic acid strand and may be cross-linked by, for example, a bond between the sugar and the base of the two nucleic acid strands. As for the bond between the sugar and the base of the two nucleic acid strands of the first nucleic acid strand and the second nucleic acid strand, an example method is a method comprising treating, with Uracil DNA glycosylase (UDG), the first nucleic acid strand or the second nucleic acid strand synthesized so as to contain deoxyuridine allow an AP site to be form at the deoxyuridine in the first nucleic acid strand or the second nucleic acid strand; and reacting —NH group of guanine or adenine of the second nucleic acid strand or the first nucleic acid strand with the aldehyde group of the AP site formed in the first nucleic acid strand or the second nucleic acid strand, thereby cross-linking the first nucleic acid strand and the second nucleic acid strand.
It is to be noted that, although
In the nucleic acid complex according to the present disclosure, the cross-linked double-stranded nucleic acid is linked to at least one of the 5′ end and the 3′ end of a single-stranded nucleic acid. That is, one cross-linked double-stranded nucleic acid may be linked to the 3′ end of the single-stranded nucleic acid (
Means for linking the cross-linked double-stranded nucleic acid to the single-stranded nucleic acid is not particularly limited. In cases where the cross-linked double-stranded nucleic acid is linked to, for example, the 5′ end of the single-stranded nucleic acid, the nucleoside of the 5′ end of the single-stranded nucleic acid form a phosphodiester bond to be linked with the nucleoside of the 3′ end of one nucleic acid strand of the cross-linked double-stranded nucleic acid. In cases where the cross-linked double-stranded nucleic acid is linked to, for example, the 3′ end of the single-stranded nucleic acid, the nucleoside of the 3′ end of the single-stranded nucleic acid form a phosphodiester bond to be linked with the nucleoside of the 5′ end of one nucleic acid strand of the cross-linked double-stranded nucleic acid. Further, a “linker (spacer)” may be inserted between the single-stranded nucleic acid and one of the nucleic acid strands of the cross-linked double-stranded nucleic acid. In the present specification, the “linker (spacer)” may be, for example, one nucleotide (for example, guanine or the like) or a 2- to 20-mer polynucleotide (for example, several thymidine residues, GCC, or the like), or may be a linear alkyl chain having 1 to 20 carbon atoms. A propyl linker is shown below as an example of the “linear alkyl chain having 1 to 20 carbon atoms” in this case.
It is to be noted that he linker (spacer) described just above may be inserted or may not be inserted between the single-stranded nucleic acid and one of the nucleic acid strands of the cross-linked double-stranded nucleic acid.
An example of a method of synthesizing a nucleic acid complex (a nucleic acid complex in which both single-stranded nucleic acid and cross-linked double-stranded nucleic acid make of DNA) will be described. The first nucleic acid strand of the cross-linked double-stranded nucleic acid and an oligonucleotide having a base sequence of both of the second nucleic acid strand of the cross-linked double-stranded nucleic acid and a single-stranded nucleic acid, both strands being linked, are each synthesized by an automated DNA synthesizer (the first nucleic acid strand and the second nucleic acid strand are synthesized so as to contain deoxyuridine at a position at which the first nucleic acid strand and the second nucleic acid strand make pairing) and purified by a known method. The thus synthesized two kinds of DNA strands are placed in a solution containing Uracil DNA glycosylase (UDG) and reacted with the enzyme. To the obtained reaction solution, UDG is added for further reaction. To the obtained reaction solution, aoNao was added as a cross-linking reagent to allow for a reaction, thereby forming the cross-linked double-stranded nucleic acid. Purification is then carried out by HPLC to obtain the nucleic acid complex comprising DNA.
As described thus far, when the nucleic acid complex according to the present disclosure is hybridized with a target nucleic acid, the stability of hybridization between the target nucleic acid and the single-stranded nucleic acid in the nucleic acid complex is enhanced. Without wishing to be bound by a particular theory, this is thought to be because the structure of the cross-linked double-stranded nucleic acid becomes highly rigid due to the cross-linking in the nucleic acid complex according to the present disclosure and restricts physical movement, resulting in stable hybridization (between the target nucleic acid and the single-stranded nucleic acid) in adjacent sites. It is to be noted that, as described later in Examples, in the case in which one cross-linked double-stranded nucleic acid is linked to each of both 5′ end and 3′ end of the single-stranded nucleic acid (
Further because the cross-linked double-stranded nucleic acids exhibits a very high resistance to nucleases, the nucleic acid complex according to the present disclosure is able to continuously produce the effect within a living organism.
Further, according to the nucleic acid complex according to the present disclosure, because stable hybridization is feasible without chemical modification for stabilizing a target nucleic acid and a single-stranded nucleic acid hybridizing therewith, the cost of synthesis can be reduced.
Next, the method of nucleic acid hybridization according to the present disclosure will be described.
The method of nucleic acid hybridization according to the present disclosure comprises the step of hybridizing the nucleic acid complex described above with a target nucleic acid comprising a base sequence that is completely or sufficiently complementary (in the same way as described above) to the base sequence of the single-stranded nucleic acid (as described above) composing the nucleic acid complex. The step of “hybridizing the nucleic acid complex with a target nucleic acid” include, for example, introducing the nucleic acid complex to a living organism to hybridize with a target nucleic acid present within a living organism; adding the nucleic acid complex to a solution containing a target nucleic acid to hybridize with the target nucleic acid; bringing the nucleic acid complex into contact with a solid phase on which a target nucleic acid is supported to hybridize with the target nucleic acid; or the like. According to the method of nucleic acid hybridization according to the present disclosure, the stability of hybridization between the target nucleic acid and the single-stranded nucleic acid in the nucleic acid complex is enhanced.
Next, the pharmaceutical composition according to the present disclosure will be described.
The pharmaceutical composition according to the present disclosure contains the nucleic acid complex described above and can be used as an antisense nucleic acid pharmaceutical product targeting non-coding RNA (microRNA, Ribosomal RNA, tRNA, or the like), mRNA, single-stranded DNA, or the like which is present within a living organism. To be more specific, the entire sequence or a partial sequence of non-coding RNA (microRNA, Ribosomal RNA, tRNA, or the like), mRNA, single-stranded DNA, or the like which is present within a living organism is regarded as the “target nucleic acid”; and a nucleic acid complex containing a single-stranded nucleic acid comprising a base sequence that is completely or sufficiently complementary (in the same way as described above) to the base sequence of the target nucleic acid can be used as an antisense nucleic acid pharmaceutical product.
The pharmaceutical composition according to the present disclosure can for example be used as a microRNA inhibitor. In this case, the entire sequence or a partial sequence of microRNA present within a living organism is regarded as the “target nucleic acid”. Examples of the microRNA can include miRNA21, miRNA122, miRNA224, miRNA10b, miRNA221, miRNA222, miRNA20, miRNA18, miRNA23a, miRNA141, miRNA200b, miRNA27a, miRNA342, miRNA26a, miRNA30d, miRNA26b, miRNA107, miRNA203, miRNA204, miRNA211, miRNA105, miRNA181a, miRNA155, miRNA181b, miRNA25, miRNA424, miRNA151, miRNA223, miRNA25, miRNA17-5p, miRNA125b, miRNA106a, miRNA92, miRNA103, miRNA93, miRNA100, miRNA106b, miRNA20a, miRNA190, miRNA33, miRNA19a, miRNA140, miRNA123, miRNA188, miRNA154, miRNA217, miRNA101, miRNA196, miRNA134, miRNA132, miRNA192, miRNA16, miRNA15, miRNA200a, miRNA200c, miRNA191, miRNA210, miRNA32, miRNA182, miRNA31, and miRNA146a.
The pharmaceutical composition according to the present disclosure can, for example, be used to directly control mRNA. In this case, the entire sequence or a partial sequence of mRNA present within a living organism is regarded as the “target nucleic acid”.
Because the pharmaceutical composition according to the present disclosure contains the nucleic acid complex, it is able to enhance stable hybridization between the target nucleic acid and the single-stranded nucleic acid in the nucleic acid complex and to be thus highly effective as a pharmaceutical product. In addition, because the pharmaceutical composition is able to stably hybridize with the target nucleic acid, the amount of pharmaceutical composition to be administered is expected to be reduced.
Next, the probe for nucleic acid detection according to the present disclosure will be described.
The probe for nucleic acid detection according to the present disclosure contains the nucleic acid complex described above and can be used as a probe for nucleic acid detection targeting non-coding RNA (microRNA, Ribosomal RNA, tRNA, or the like), mRNA, single-stranded DNA, or the like which is present within or outside of a living organism. To be specific, the entire sequence or a partial sequence of non-coding RNA (microRNA, Ribosomal RNA, tRNA, or the like), mRNA, single-stranded DNA, or the like which is present within or outside of a living organism is regarded as the “target nucleic acid”; and a nucleic acid complex containing a single-stranded nucleic acid comprising a base sequence that is completely or sufficiently complementary (in the same way as described above) to the base sequence of the target nucleic acid can be used as a probe for nucleic acid detection. In order to detect the hybridization with the target nucleic acid, the nucleic acid complex may be labeled with a fluorescent substance.
Because the probe for nucleic acid detection according to the present disclosure contains the nucleic acid complex described above, enhanced stability of the hybridization between the target nucleic acid and the single-stranded nucleic acid in the nucleic acid complex can be attained, allowing highly sensitive detection of nucleic acids.
Next, the complementary strand nucleic acid complex according to the present disclosure will be described.
The complementary strand nucleic acid complex according to the present disclosure comprises
the first nucleic acid complex containing the first single-stranded nucleic acid and the first cross-linked double-stranded nucleic acid linked to the 5′ end or the 3′ end of the first single-stranded nucleic acid, and
the second nucleic acid complex containing the second single-stranded nucleic acid comprising a base sequence that is completely or sufficiently complementary to the base sequence of the first single-stranded nucleic acid,
wherein the first single-stranded nucleic acid and the second single-stranded nucleic acid are hybridized.
In the complementary strand nucleic acid complex according to the present disclosure, the second nucleic acid complex may, for example, contain the second cross-linked double-stranded nucleic acid linked to the 3′ end or the 5′ end of the second single-stranded nucleic acid. In this case, both of the first nucleic acid complex and the second nucleic acid complex have the cross-linked double-stranded nucleic acid. It is to be noted that the first cross-linked double-stranded nucleic acid and the second cross-linked double-stranded nucleic acid may have a hairpin loop structure as shown in
It is to be noted that, in the case in which both of the first nucleic acid complex and the second nucleic acid complex have the cross-linked double-stranded nucleic acid, the first cross-linked double-stranded nucleic acid and the second cross-linked double-stranded nucleic acid may have the same base sequence or may have different base sequences in each of the first form of the complementary strand nucleic acid complex and the second form of the complementary strand nucleic acid complex.
Because the complementary strand nucleic acid complex according to the present disclosure has the first cross-linked double-stranded nucleic acid or both of the first cross-linked double-stranded nucleic acid and the second cross-linked double-stranded nucleic acid, stable hybridization as double strands can be achieved.
It is to be noted that the complementary strand nucleic acid complex according to the present disclosure may further have, for example, nucleic acid strand C1 linked to the 5′ end of the first cross-linked double-stranded nucleic acid and nucleic acid strand C2 linked to the 5′ end of the second cross-linked double-stranded nucleic acid, as shown in
By way of example, the present disclosure will now be specifically described below. The present disclosure is, however, not limited to these examples.
Example A (Outline of Oligonucleotides Synthesized)As target nucleic acids (target RNAs), miR21 (SEQ ID NO: 1) and miR21-M (miR21 with one base mismatch) (SEQ ID NO: 2) (both have 22 mer) were selected; and an oligonucleotide complementary to miR21 or miR21-M was synthesized.
The base sequences of miR21 and miR21-M are shown below.
To be more specific with regard to the oligonucleotide complementary to miR21 or miR21-M, products with one cross-link (CL1) having a single-stranded nucleic acid comprising a base sequence that is completely or sufficiently complementary to the base sequence of a target nucleic acid (hereinafter referred to simply as a “complementary binding-like sequence” in the present Examples) and a double-stranded cross-linking adapter sequence at the 5′ side or the 3′ side (including those having the cross-linking adapter sequence with a hairpin loop structure and those having a linker inserted between the cross-linking adapter sequence and the complementary binding-like sequence); and products with two cross-links (CL2) having the complementary binding-like sequence and a double-stranded cross-linking adapter sequence at both of the 5′ side and the 3′ side were, as shown in
As for the oligonucleotides synthesized, the sequence of DNA (
The sequences of DNAs synthesized are shown in
As Example 1, d5′CL(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence was synthesized (
As Example 2, d5′CL(12/34T) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence with T (thymidine) as a linker therebetween was synthesized (
As Example 3, d5′CL(12/34P) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence with a propyl linker of the following formula therebetween was synthesized (
As Example 4, d5′CL(12/34T8) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence with eight T (thymidine) residues as a linker therebetween was synthesized (
As Example 5, d5′CL(12−5M/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence with a mismatched base pair in the 5′ side of the cross-linking site was synthesized (
As Example 6, d5′CL(12−3M/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence with a mismatched base pair in the 3′ side of the cross-linking site was synthesized (
As Example 7, d5′CL(12/37) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence (the terminal site of the cross-linking adapter sequence was cross-linked and three thymidine residues were linked to the end of the cross-linking adapter sequence) was synthesized (
As Example 8, d5′HP CL(50) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence (having a hairpin loop structure comprising four thymidine residues) in the 3′ side of the cross-linking site was synthesized (
As Example 9, dCL2(12-I,II/46) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence at both ends was synthesized (
As Example 10, dCL2 (12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence (with the cross-linking taking place at two sites) was synthesized (
As Comparative Example 1, dSS(34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded adapter sequence was synthesized (
As Comparative Example 2, d5′DS(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence was synthesized (
As Comparative Example 3, d5′HP50 having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence, and having a hairpin loop structure comprising four thymidine residues was synthesized (
As Comparative Example 4, d5′Lig(12/35) having a sequence complementary to miR21 (a complementary binding-like sequence), and a hairpin loop of linear alkyl linker that chemically linked a 12-mer DNA with a 35-mer DNA was synthesized (
As Comparative Example 5, dSS(46) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded adapter sequence at both ends was synthesized (
The sequences of RNAs synthesized are shown in
As Example 11, r5′CL(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence was synthesized (
As Example 12, dr5′CL(12/34) (chimeric molecule) having a sequence complementary to miR21 (a complementary binding-like sequence) (RNA) and a 12-mer double-stranded cross-linking adapter sequence (DNA) was synthesized (
As Comparative Example 6, r-asmi21 comprising a sequence complementary to miR21 (a complementary binding-like sequence) was synthesized (
As Comparative Example 7, rSS(34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded adapter sequence was synthesized (
As Comparative Example 8, r5′DS(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence was synthesized (
As Comparative Example 9, rHP50 having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence and having a hairpin loop structure comprising four uracil residues was synthesized (
The sequences of 2′-OMe RNAs synthesized are shown in
As Example 13, m5′CL(10/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 10-mer double-stranded cross-linking adapter sequence was synthesized (
As Example 14, m5′CL(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence was synthesized (
As Example 15, m3′CL(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence at the 3′ side was synthesized (
As Example 16, m3′CL(12/34-M) having a sequence that is not completely complementary to miR21 (with mismatch bases at two sites) (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence at the 3′ side was synthesized (
As Example 17, mCL2(12-I×2/46) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence at both ends was synthesized (
As Example 18, mCL2(12-I×2/46M) having a sequence that is not completely complementary to miR21 (with mismatch bases at two sites) (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking adapter sequence at both ends was synthesized (
As Comparative Example 10, m-asmiR21 having a sequence complementary to miR21 (a complementary binding-like sequence) was synthesized (
As Comparative Example 11, mSS(34)dU having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded adapter sequence was synthesized (
As Comparative Example 12, mSS(34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded adapter sequence was synthesized (
As Comparative Example 13, m5′DS(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence was synthesized (
As Comparative Example 14, mHP50 having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence and having a hairpin loop structure comprising four uracil residues was synthesized (
As Comparative Example 15, m3′DS(12/34) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded adapter sequence at the 3′ side was synthesized (
As Comparative Example 16, mSS(46) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer single-stranded cross-linking sequence at both ends was synthesized (
As Comparative Example 17, mDS2(12×2/46) having a sequence complementary to miR21 (a complementary binding-like sequence) and a 12-mer double-stranded cross-linking sequence at both ends was synthesized (
As Comparative Example 18, mCL2(12-I×2/34) having a sequence with a region hybridizing with miR21 of about 10 bases and a 12-mer double-stranded cross-linking adapter sequence at both ends was synthesized (
In order to prepare the molecules of Examples 1 to 18 and Comparative Examples 1 to 18, oligonucleotides were each synthesized as shown in Table 1 and Table 2. It is to be noted that, in Table 1 and Table 2, “m” in the sequence indicates that the nucleic acid strand in the parentheses is 2′-OMe RNA and “X” represents “u: deoxyuridine”.
The synthesis of the oligonucleotide was carried out using 3′-phosphoramidite (Glen Research) on an automated DNA.RNA synthesizer (model 3900; manufactured by PerkinElmer Japan Co., Ltd., Applied Biosystems division). The oligonucleotide was synthesized at 0.2 μmol scale. HPLC was carried out using Gilson's device and analysis was carried out using Waters 996 photodiode array detector.
After the synthesis was completed, a CPG (Controlled Pore Glass) to which the synthesized oligonucleotide was bound was heated in an ammonia-methylamine mixture (28% conc. ammonium water: 40% methylamine in water=1:1.2 mL) at 65° C. for 10 minutes to 15 minutes to cleave the oligonucleotide from the CPG and to carry out deprotection in the base moiety and the phosphodiester moiety. A reaction solution was collected and the solvent was evaporated to be removed.
DNA and 2′-O-methyl RNA (2′-OMe RNA) were dissolved in 2 mL of 0.2 M triethylamine acetate (pH 7.0) and subjected to a reversed phase open column (YMC cartridge 500 mg) to be thereby partially purified.
As for RNA, the solvent was evaporated to be removed after the deprotection reaction. The residues were added with dimethyl sulfoxide (115 μL), triethylamine (60 μL), and triethylamine trihydrofluoride (75 μL) and stirred to be dissolved, followed by heating at 65° C. for 2.5 hours. To the reaction solution, 1.75 mL of 1.8 M triethylamine acetate (pH 7.0); and the resultant was subjected to a reversed phase open column for partial purification.
The purified oligonucleotides (DNA, RNA, and 2′-OMe RNA) were purified by high performance liquid chromatography (HPLC). HPLC is carried out using Gilson's device connected to Waters μ-Bondasphere C18 300A (inner diameter: 3.9 mm×length 150 mm, Waters Corporation). In the case of a reversed phase, a concentration gradient of acetonitrile in 0.1 M triethylamine acetate buffer (TEAA, pH 7.0) was employed as a mobile phase. The types of the oligonucleotides synthesized and conditions for reversed phase HPLC are shown below.
Solution A: 5% acetonitrile/0.1 M TEAA (pH 7.0)
Solution B: 25% acetonitrile/0.1 M TEAA (pH 7.0)
Preparation of DNA Products with One Cross-Link (CL1) and DNA Products with Two Cross-Links (CL2) (Examples 1 to 10)A product with one cross-link of d5′CL(12/34) (Example 1,
Solution A: 5% acetonitrile/0.1 M TEAA (pH 7.0)
Solution B: 25% acetonitrile/0.1 M TEAA (pH 7.0)
A style of s bond between sugars of the nucleic acid strand of SEQ ID NO: 3 and the nucleic acid strand of SEQ ID NO: 4 in d5′CL(12/34) (Example 1) will be described (
Other products with one cross-link were prepared in the same manner as described above using the nucleic acid strand of SEQ ID NO: 3 and the nucleic acid strand of SEQ ID NO: 5 for d5′CL(12/34T) (Example 2), using the nucleic acid strand of SEQ ID NO: 3 and a sequence with SEQ ID NO: 6 and SEQ ID NO: 7 being linked via a propyl linker (Table 1) for d5′CL(12/34P) (Example 3), using the nucleic acid strand of SEQ ID NO: 3 and the nucleic acid strand of SEQ ID NO: 8 for d5′CL(12/34T8) (Example 4), using the nucleic acid strand of SEQ ID NO: 9 and the nucleic acid strand of SEQ ID NO: 4 for d5′CL(12−5M/34) (Example 5), and using the nucleic acid strand of SEQ ID NO: 10 and the nucleic acid strand of SEQ ID NO: 4 for d5′CL(12−3M/34) (Example 6).
d5′CL(12/37) (Example 7) having a cross-linking moiety at the end was prepared by a cross-linking reaction of 12-mer (d12Z-I) (SEQ ID NO: 11) in which an amidite reagent for 12-mer abasic site (abasic II phosphoramidite, Glen research) is bound at the 5′ end with d37dU (SEQ ID NO: 12) having a sequence complementary thereto (because UDG did not work on the end of oligonucleotide, a reagent capable of generating the AP site was, for the preparation, introduced at the stage of oligonucleotide synthesis and cross-linked). For the purpose of presenting the abasic site to the 5′ end, d12Z-I (4 nmol) was in advance subjected to acid treatment (left to stand in 50 μL of 80% acetic acid at room temperature for 30 minutes) and added with 2 M TEAA (200 μL) for neutralization, followed by desalting on NAP-5. This resultant was added to d37dU (2 nmol) that had been treated with UDG in the same method as described for the above d5′CL(12/34) (Example 1) and placed on ice for five minutes; and 2 mM aoNao (20 nmol, 10 μL) was added thereto to react at 17° C. for 16 hours. Purification was then carried out using HPLC with a reversed phase column, thereby obtaining a product with a cross-link or cross-links.
As for d5′HP CL(50) (Example 8) which was a 50-mer single-stranded product with a cross-link having a hairpin loop, the same reaction as described for the above d5′CL(12/34) (Example 1) was carried out using a 50-mer oligonucleotide (dHP50dUdU, SEQ ID NO: 13) with deoxyuridines in a facing portion of double strands, followed by the purification using reversed phase HPLC.
As for dCL2(12-I,II/46) (Example 9) which is a product with two cross-links, the nucleic acid strand of SEQ ID NO: 3 (7.56 nmol) and the nucleic acid strand of SEQ ID NO: 14 (7.56 nmol) was mixed with the nucleic acid strand of SEQ ID NO: 15 (2.52 nmol) and the mixture was subjected to a UDG reaction in the same method as described for d5′CL(12/34) (Example 1). Thereafter, 2 mM aoNao (50.4 nmol, 25.2 μL) was added thereto and the mixture was subjected to a cross-linking reaction and purification in the same manner as described for d5′CL(12/34) (Example 1).
As for dCL2(12/34) (Example 10) which is a product with two cross-links, d12dUdU (SEQ ID NO: 16) (2.4 nmol) and d34dUdU (SEQ ID NO: 17) (2.0 nmol) were mixed and the mixture was subjected to a UDG reaction in the same method as described for d5′CL(12/34) (Example 1). Thereafter, 2 mM aoNao (40 nmol, 20 μL) was added thereto and the mixture was subjected to a cross-linking reaction and purification in the same manner as described for d5′CL(12/34) (Example 1).
Preparation of DNA Products with No Cross-Links (DS) (Comparative Examples 2 to 4)d5′DS(12/34) (Comparative Example 2) was prepared by adding the nucleic acid strand of SEQ ID NO: 30 and the nucleic acid strand of SEQ ID NO: 29 at equimolar amounts and carrying out purification in the same manner as described for d5′CL(12/34) (Example 1).
d5′HP50 (Comparative Example 3) having a hairpin loop was prepared by carrying out a reaction using the nucleic acid strand of SEQ ID NO: 31 in the same method as described for the above d5′CL(12/34) (Example 1).
d5′Lig(12/35) (Comparative Example 4) which was a hairpin loop oligonucleotide having an alkyl linker was prepared from the following a ligation reaction. As for this reaction, employed was a reaction in which the ligation was achieved by allowing an oligonucleotide having a primary amino group to work on an oligonucleotide with an aldehyde group being generated at 3′ end to reduce a Schiff base. At the time of the preparation, Kojima, N., Sugino, M., Mikami, A. Nonaka, K., Fujinawa, Y.; Muto, I., Matsubara, K., Ohtsuka, E. and Komatsu, Y. Enhanced reactivity of amino-modified oligonucleotides by insertion of aromatic residue. Bioorg. Med. Chem. Lett., 2006, 16, 5118-5121 was used as a reference.
First, d35dU-rU (SEQ ID NO: 33) (2 nmol) in a 100 mM phosphate buffer (pH 6) was acted on by periodate (16 nmol) (reaction solution 48 μL) and heated at 27° C. for 90 minutes, thereby oxidizing the 3′ end. Subsequently, aminated oligonucleotide (ssH-d12A; 2.4 nmol) (SEQ ID NO: 32) which had a sequence complementary to d35dU-rU and had an amino linker (ssH-linker; Sigma Ald.) at the 5′ end was dissolved in sterilized water (6 μL) and added to d35dU-rU that had been in advance oxidized. The mixed solution was left to stand on ice for five minutes and then a binding reaction was carried out in the presence of 150 mM sodium cyanoborohydride (reaction solution 60 μL) at 27° C. for 16 hours. After the reaction, like the cross-linked oligonucleotide, the linked product was purified by reversed phase HPLC. A synthesis scheme for d5′Lig(12/35) (Comparative Example 4) is shown below.
With regard to the purified cross-linking adapter (Example 1 and Example 9), the molecular weight was checked by LC-MS and, at the same time, whether the cross-linking was achieved was checked by carrying out 20% denaturing polyacrylamide gel electrophoresis. To be more specific, it was confirmed, as shown in
HPLC conditions used in the purification of each molecule and the results of molecular weight measurement for each molecule are shown in Table 3.
r5′CL(12/34) (Example 11,
HPLC conditions used in the purification of each of the products with a cross-link are shown in Table 4.
r5′DS(12/34) (Comparative Example 8) was prepared by adding the nucleic acid strand of SEQ ID NO: 37 and the nucleic acid strand of SEQ ID NO: 36 at equimolar amounts and carrying out purification in the same manner as described for r5′CL(12/34) (Example 11).
rHP50 (Comparative Example 9) having a hairpin loop was prepared by carrying out a reaction using the nucleic acid strand of SEQ ID NO: 38 in the same method as described for the above r5′CL(12/34) (Example 11).
Preparation of 2′-OMe RNA Products with One Cross-Link (CL1) and RNA Products with Two Cross-Links (CL2) (Examples 13 to 18)m5′CL(12/34) (Example 14,
With regard to mCL(12-I×2/46) (Example 17,
m5′DS(12/34) (Comparative Example 13) was prepared by adding the nucleic acid strand of SEQ ID NO: 42 and the nucleic acid strand of SEQ ID NO: 41 at equimolar amounts and carrying out purification in the same manner as described for m5′CL(12/34) (Example 14); m3′ DS(12/34) (Comparative Example 15) was prepared by adding the nucleic acid strand of SEQ ID NO: 42 and the nucleic acid strand of SEQ ID NO: 44 at equimolar amounts and carrying out the purification; and mDS2(12×2/46) (Comparative Example 17) was prepared by adding the nucleic acid strand of SEQ ID NO: 42 and the nucleic acid strand of SEQ ID NO: 45 at equimolar amounts and carrying out the purification.
mHP50 (Comparative Example 14) having a hairpin loop was prepared by carrying out a reaction using the nucleic acid strand of SEQ ID NO: 43 in the same method as described for the above m5′CL(12/34)(Example 14).
mCL2(12-I×2/34)(Comparative Example 18) having the cross-linking adapter sequence at both ends was prepared using the nucleic acid strand of SEQ ID NO: 24 and the nucleic acid strand of SEQ ID NO: 46 in the same manner as described for m5′CL(12/34) (Example 14).
With regard to the purified molecule with the cross-linking adapter, the molecular weight was checked by LC-MS and, at the same time, whether the cross-linking was achieved was checked by carrying out 20% denaturing polyacrylamide gel electrophoresis. To be more specific, it was confirmed, as shown in
HPLC conditions used in the purification of each of the products with a cross-link or cross-links and the results of molecular weight measurement for each of the products with a cross-link or cross-links are shown in Table 5.
With regard to the molecules of the Examples and Comparative Examples which had been prepared in Example A, a melting curve was measured. As nucleic acids to be targeted, miR21 (SEQ ID NO: 1) and miR21-M (SEQ ID NO: 2) were selected.
The molecules (130 pmol) of Examples 1 to 15, and 17 or Comparative Examples 1 to 11 and 13 to 17 were mixed with miR-21 or miR-21-M (130 pmol) and the mixture was dissolved in a Tm measurement buffer (10 mM NaCl, 10 mM Na cacodylate (pH 7.0), 130 μL). The sample was heated at 90° C. for three minutes, then allowed to gradually cool to room temperature to anneal, and then left to stand at room temperature for five minutes; and 125 μL of the resultant was placed in a measurement cuvette to measure the melting curve. The measurement was carried out using UV2500PC (manufactured by Shimadzu Corporation) in a temperature range of 5° C. to 90° C. in conditions of a temperature rate of 0.5° C./min, a measurement interval of 0.2° C., start hold 600 seconds, and standby prior to measurement 0 seconds.
As shown in
As shown in
As shown in
It is to be noted in
From the above, it has been demonstrated that the product with one cross-link (CL1) and the product with two cross-links (CL2) according to the Examples stabilize the hybridization with the target nucleic acid. In addition, it has been confirmed that this effect of stabilizing hybridization is able to be attained regardless of whether the cross-linking adapter sequence is DNA, RNA, or 2′-OMe RNA.
Example C(Evaluation of miRNA-Suppression Activity)
2′-OMe RNA has excellent stability in cells and is used as an antisense. In view of this, Examples 14, 15, and 17 which were 2′-OMe RNA was evaluated for an inhibitory effect on a miRNA activity in cells. It is to be noted that miR-21 (SEQ ID NO: 1) was selected as a miRNA to be targeted.
A dual-luciferase assay system was employed to look at the inhibitory effect on miR-21. A vector was constructed as described below, which vector has a binding sequence for miR-21 introduced only to the 3′ UTR of a sequence encoding Renilla luciferase in psiCHECK-2 (registered trademark) vector (Promega). First, a double-stranded oligonucleotide was synthesized, the double-stranded oligonucleotide corresponding to miR-21 with part of the cleavage recognition sequence of restriction enzyme sites SgfI and PmeI at both ends and a complementary strand thereof (SEQ ID NO: 47 and SEQ ID NO: 48). A phosphate group necessary for ligation to the vector was introduced to the 5′ end of each oligonucleotide at the stage of the synthesis. Subsequently, to psiCHECK-2 (registered trademark) vector (Promega) that had been treated with SgfI (Promega) and PmeI (Promega), the above double stranded oligonucleotide that had been in advance annealed was ligated using T4 DNA ligase (Promega). The obtained vector is subjected to cloning and sequence confirmation by a common technique using Escherichia coli; and a vector with the binding sequence of miR-21 being inserted in an intended site (psiCHECK-2-miR-21) was obtained.
When the psiCHECK-2-miR-21 vector is introduced to cells, miR-21 within cells binds to the 3′ UTR of Renilla luciferase mRNA to inhibit the expression of Renilla luciferase; and no luminescence derived from the enzyme is detected. However, when a nucleic acid molecule (anti-miRNA oligonucleotide: AMO) that has a sequence complementary to miR-21 is introduced, the binding of miR-21 to mRNA is competitively inhibited and the expression of Renilla luciferase is induced to allow luminescence to be observed. HeLa cells express a large amount of miR-21. The cells were thus seeded at a concentration of 24 cells/well in a 96-well plate (Nunc) and cultured for 24 hours; and psiCHECK-2-miR-21 (0.1 mg/well) and the synthesized anti-miRNA oligonucleotide (0.05 to 50 nM/well) were introduced to the cells together with lipofectamine (registered trademark) 2000 (Life technologies, 0.3 mL/well). In addition, an experiment in which a vector (psiCHECK-2) having no miR-21 binding sequences was introduced to the cells was concurrently carried out as a positive control.
After the 24-hour culturing, the luminescence strength of each of Renilla and Firefly luciferases was measured by using a Dual-Glo (registered trademark) Luciferase assay system (Promega). A ratio (Rluc/Fluc) of the luminescence strength of Renilla luciferase with the luminescence strength of Firefly luciferase, which served as an internal control, was calculated and further normalized with a value calculated based on the vector having no miR-21 binding sequences. A relative value of Rluc/Fluc was plotted against the corresponding concentration of the anti-miRNA oligonucleotide to evaluate the inhibitory effect on the miRNA activity (
Commercially available anti-miRNA oligonucleotides used for comparison were shown below.
-
- LNA-miRCURY (miRCURY, LNA miRNA inhibitor hsa-miR21, Exiqon)
- LNA NC (miRCURY LNA microRNA Inhibitor Negative Control A, Exiqon)
- meridian (miRIDIAN microRNA hsa-miR-21-5p haripin inhibitor, GE Healthcare)
- Tough decoy (MISSION, Synthetic microRNA Inhibitor Human hsa-miR-21-5p, Sigma)
The results are shown in
As shown in
As shown in
As shown in
As shown in
From the above, it has been demonstrated that the product with one cross-link (CL1) and the product with two cross-links (CL2) according to the Examples have a higher miRNA-suppression activity.
Example DA complementary strand nucleic acid complex was prepared and a melting curve was measured. As a nucleic acid to be targeted, miR21 (SEQ ID NO: 1) was selected.
As Example 19, a complementary strand nucleic acid complex d5′CL(12/34)/dc34dU was prepared by mixing, at equimolar amounts, d5′CL(12/34) (Example 1) and the nucleic acid strand of SEQ ID NO: 49 which had a sequence complementary to the single-stranded region of d5′CL(12/34) to allow hybridization (
As Example 20, a complementary strand nucleic acid complex d5′CL(12/34)/dcCL(12/34) was prepared by mixing, at equimolar amounts, d5′CL(12/34) (Example 1) and dcCL(12/34) which had a sequence complementary to a single-stranded region of d5′CL(12/34) and had the cross-linking adapter sequence to allow hybridization (
As Comparative Example 19, a molecule d34dU/dc34dU was prepared by mixing, at equimolar amounts, dc34dU (the nucleic acid strand of SEQ ID NO: 49) and a nucleic acid strand d34dU (SEQ ID NO: 52) which had a sequence complementary to dc34dU to allow hybridization (
With regard to Examples 19 and 20 and Comparative Example 19, Tm was measured by the same method as described in Example B. The results are shown in
From the above, it has been demonstrated that the complementary strand nucleic acid complex according to this Example is stably hybridized.
Example EWith regard to Examples 14, 15, and 17 and Examples 21 to 23 (described later), each of which was 2′-OMe RNA, an inhibitory effect on a miRNA activity was evaluated 48 hours after transfection.
By the same method as described in Example A, the following molecules of Examples 21 to 23 were synthesized.
As Example 21, m3′CL(11/34) which had a sequence complementary to miR21 (a complementary binding-like sequence) and a 11-mer double-stranded cross-linking adapter sequence with, as a spacer (linker), a G (guanine) residue therebetween was synthesized (
As Example 22, m3′CL(9/34) which had a sequence complementary to miR21 (a complementary binding-like sequence) and a 9-mer double-stranded cross-linking adapter sequence with, as a spacer (linker), a 3-mer oligonucleotide (GCC) therebetween was synthesized (
As Example 23, m3′CL(10/34) which had a sequence complementary to miR21 (a complementary binding-like sequence) and a 10-mer double-stranded cross-linking adapter sequence was synthesized (
In order to prepare the molecules of Examples 21 to 23, each of oligonucleotides shown in Table 6 was used. With regard to “m” and “X”, the same as described in Example A is also applied here.
To look at an inhibitory effect on miR-21, the dual-luciferase assay system as described in Example C was employed and carried out in the same manner as described in Example C. Transfection was also carried out in the same manner as described in Example C.
Forty-eight hours after the culturing, the inhibitory effect on an miR-21 activity was evaluated by the same method as described in Example C (
As for miRIDIAN and Tough decoy which were used for a comparison purpose, the evaluation was carried out in the same manner as described in Example C.
The results are shown in
As shown in
As shown in
From the above, it has been demonstrated that the product with one cross-link (CL1) which had the cross-linking adapter sequence at the 5′ terminal side of the complementary binding-like sequence (single-stranded nucleic acid) had a higher miRNA-suppression activity.
The foregoing describes some example embodiments for explanatory purposes. Although the foregoing discussion has presented specific embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the broader spirit and scope of the invention. Accordingly, the specification and drawings are to be regarded in an illustrative rather than a restrictive sense. This detailed description, therefore, is not to be taken in a limiting sense, and the scope of the invention is defined only by the included claims, along with the full range of equivalents to which such claims are entitled.
The present application is based on Japanese Patent Application No. 2014-251847 filed on Dec. 12, 2014 and includes the specifications, claims, drawings, and abstract thereof. The disclosure in the above Japanese Patent Application is incorporated in the present specification by reference in their entirety.
INDUSTRIAL APPLICABILITYThe stabilization effect on the hybridization by the cross-linked double stranded structure of the present disclosure is believed to be useful in improving sensitivity of nucleic acid detection with RNA, DNA, or the like as a target and producing high pharmacological effects in nucleic acid medicines. In addition, because the present disclosure is a unique nucleic acid structure, it is possible to use in combination with various existing nucleic acid derivative monomers and to further improve effects of existing techniques. This enables the new structure of the nucleic acid of the present disclosure to use across a wide range of areas utilizing nucleic acids and to also offer high availability in industries.
SEQUENCE LISTING15F074-PCT_Sequence Listing.txt
Claims
1. A nucleic acid complex comprising: (wherein (wherein R3 is a C1-9 alkylene group or —(CH2)o—(OCH2CH2)p—(CH2)q—, o to q are each independently an integer of 0 to 15, o+p+q is 1 to 15), L2 is a direct bond or a divalent group represented by the following general formula 5 or 6: (wherein R4 is a C1-9 alkylene group or —(CH2)r(OCH2CH2)s—(CH2)t—, r to t are each independently an integer of 0 to 15, r+s+t is 1 to 15), and or a salt thereof.
- a single-stranded nucleic acid; and
- a cross-linked double-stranded nucleic acid comprising a first nucleic acid strand linked to at least one of a 5′ end and a 3′ end of the single-stranded nucleic acid and a second nucleic acid strand comprising a base sequence that is completely or sufficiently complementary to the first nucleic acid strand,
- wherein the cross-linked double-stranded nucleic acid is cross-linked by a bond between sugars of the first nucleic acid strand and the second nucleic acid strand,
- wherein the sugars of the first nucleic acid strand and the second nucleic acid strand are linked by a cross-linking reagent having an aminooxy group or an amino group,
- wherein the cross-linking reagent is a compound represented by general formula 1: R1—NH—O-L1-D-L2-A (1)
- R1 is a protective group of a hydrogen atom, an alkyl group, or an amino group,
- D is an aromatic group selected from a substituted or unsubstituted phenylene group, a substituted or unsubstituted anthrylene group, a substituted or unsubstituted naphthylene group, a substituted or unsubstituted phenanthrylene group, a substituted or unsubstituted anthraquinolylene group, and a substituted or unsubstituted acridinylene group, or a C2-10 alkyl group,
- a substituent of the aromatic group is selected from the group consisting of a halogen atom, a C1-6 alkyl group, a nitro group, a cyano group, a C2-6 alkenyl group, a C3-10 cycloalkyl group, a C1-10 alkoxy group, and a C1-10 acyl group,
- L1 is a direct bond or a divalent group represented by the following general formula 3 or 4;
- A is an aminooxy group or a protected aminooxy group)
2. The nucleic acid complex according to claim 1, wherein the cross-linked double-stranded nucleic acid is linked to the 5′ end of the single-stranded nucleic acid.
3. (canceled)
4. (canceled)
5. (canceled)
6. (canceled)
7. (canceled)
8. The nucleic acid complex according to claim 1,
- wherein the cross-linking reagent has/comprises the aminooxy group, and
- wherein aldehyde groups in the sugar of the first nucleic acid strand and the second nucleic acid strand are linked via the aminooxy group of the cross-linking reagent in the cross-linked double-stranded nucleic acid.
9. A method of nucleic acid hybridization comprising:
- the step of hybridizing the nucleic acid complex according to claim 1 with a target nucleic acid comprising a base sequence that is completely or sufficiently complementary to a base sequence of a single-stranded nucleic acid that forms the nucleic acid complex.
10. (canceled)
11. (canceled)
12. (canceled)
13. (canceled)
Type: Application
Filed: Dec 8, 2015
Publication Date: Dec 7, 2017
Applicant: NATIONAL INSTITUTE OF ADVANCED INDUSTRIAL SCIENCE AND TECHNOLOGY (Tokyo)
Inventors: Yasuo Komatsu (Sapporo-shi, Hokkaido), Yu Hirano (Sapporo-shi, Hokkaido), Yasuhiro Mie (Sapporo-shi, Hokkaido)
Application Number: 15/532,916