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Last Updated: March 29, 2024

Claims for Patent: 5,470,722


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Summary for Patent: 5,470,722
Title: Method for the amplification of unknown flanking DNA sequence
Abstract:A method that permits the rapid amplification of unknown DNA that flanks a known site, such that one can walk into an uncharacterized region of DNA. In this method, human genomic DNA is restriction enzyme digested and then ligated to a 5\' phosphorylated-oligonucleotide so that the 5\' end of each strand of genomic DNA is extended and phosphorylated. The phosphorylated-oligonucleotide is constructed to render 5\' end extensions that are complementary to the known sequence. Following denaturation and re-annealing under dilute conditions that promote intrastrand annealing and under high stringency, only those DNA strands containing the known sequence will form a stem-loop structure with a recessed and phosphorylated 5\' end, rendering a substrate for a subsequent heat-stable ligation reaction to another oligonucleotide. This second oligonucleotide is complementary to the sequence immediately adjacent to the phosphorylated-oligonucleotide high stringency annealing site. The heat-stable ligation reaction appends a known sequence to the DNA segments containing the two known contiguous DNA sequences used for oligonucleotide annealing. This heat-stable ligation of known sequence permits the subsequent highly specific amplification of the unknown flanking DNA.
Inventor(s): Jones; Douglas H. (Iowa City, IA)
Assignee: University of Iowa Research Foundation (Oakdale, IA)
Application Number:08/058,907
Patent Claims:1. A method for the amplification of an unknown DNA sequence that flanks a known DNA sequence, comprising the steps of:

(a) digesting a double-stranded DNA fragment with a restricuion enzyme to yield 5' phosphorylated nucleotide overhang sequences, wherein said DNA fragment comprises a region of known DNA sequence and a region of unknown flanking DNA sequence to be amplified;

(b) annealing a 5' phosphorylated single-stranded oligonucieotide to a bridging-oligonucleotide to yield a double-stranded oligonucleotide with a 5' phosphorylated end;

(c) ligating said 5' phosphorylated single-stranded oligonucleotide of said double-stranded oligonucleotide whose non-phosphorylated 5' end is complementary to the cohesive ends generated in step (a) of said double-stranded DNA fragment to yield 5' phosphorylated nucleotide sequences complementary to a sequence portion within said known sequence region of said DNA fragment, wherein said sequence portion is an annealing site for said 5' phosphorylated nucleotide sequences;

(d) denaturing said 5' end-modified DNA fragment to produce single-stranded fragments containing said 5' phosphorylated nucleotide sequences;

(e) intra-strand annealing of a 5' phosphorylated nucleotide sequence to said annealing site within said known sequence region of a single-stranded fragment, wherein said single-stranded fragment is a fragment containing said annealing site located downstream (3') to said unknown flanking sequence region, to form a single-stranded loop, or pan portion, with a double-stranded stem of an otherwise single-stranded handle, of a panhandle structure;

f) heat stable ligating an oligonucleotide primer 1, complementary to a known sequence region downstream (3') from said annealing cite for said 5' phosphorylated nucleotide sequences, to the recessed 5' phosphorylated end of said double-stranded portion of said handle to elongate said double-stranded portion of said otherwise single-stranded handle of said panhandle structure; and

(g) performing a first stage polymerace amplification reaction using a first set of oligonucleotide primers including said primer 1 annealing to said known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide sequences and a primer 2 complementary to a known sequence region both downstream (3') from said unknown flanking sequence region and upstream (5') from said annealing site for said 5' phosphorylated nucleotide sequences wherein initial priming by primer 2 occurs following annealing to said pan portion of said panhandle structure and is not inhibited by snapback annealing of said double-stranded handle of said panhandle structure.

2. The method of claim 1, further performing a second stage polymerase amplification reaction to produce a nested primer product using a second set of oligonucleotide primers including a primer 3 complementary to both a portion of said known sequence region complementary to primer 1 and a portion of said annealing site for said 5' phosphorylated nucleotide sequences and a primer 4 complementary to a known sequence region both downstream (3') from said unknown flanking sequence region and upstream (5') from said known sequence region complementary to primer 2.

3. The method of claim 1, wherein said double-stranded DNA is genomic.

4. The method of claim 1, wherein said region of known sequence is an insertion element and said region of unknown flanking DNA sequence to be retrieved is an integration site for said insertion element and flanking regions thereof.

5. The method of claim 4, wherein said insertion element is a viral insertion element or a transposon insertion element.

6. The method of claim 1, wherein said region of known sequence is a cDNA and said region of unknown flanking DNA sequence to be retrieved is from a 3' or 5' flanking region, intron-exon junction, or intron.

7. The method of claim 1, wherein said region of known sequence is a cloning vector arm and said region of unknown flanking DNA sequence to be retrieved is the cloned DNA sequence lying adjacent said arm.

8. The method of claim 7, wherein said cloning vector is a yeast artificial chromosome.

9. The method of claim 1, wherein said double-stranded DNA is known.

10. The method of claim 1, wherein said double-stranded DNA is a gene, disease marker, or pathogen.

11. A method for the amplification of an unknown DNA sequence that flanks a known DNA sequence, comprising the steps of:

(a) digesting a double-stranded DNA fragment with a restriction enzyme to yield 3' nucleotide overhang sequences, wherein said DNA fragment comprises a region of known DNA sequence and a region of unknown flanking DNA sequence to be amplified;

(b) ligating a 5' phosphorylated single-stranded oligonucleotide whose 3' end is complementary to the cohesive ends generated in step (a) of said double-stranded DNA fragment to yield 5' phosphorylated nucleotide overhang sequences complementary to a sequence portion within said known sequence region of said DNA fragment, wherein said sequence portion is an annealing site for said 5' phosphorylated nucleotide overhang sequences;

(c) denaturing said 5' end-modified DNA fragment to produce single-stranded fragments containing said 5' phosphorylated nucleotide sequences;

(d) intra-strand annealing of a 5' phosphorylated nucleotide overhang sequence to said annealing site within said known sequence region of a single-stranded fragment, wherein said single-stranded fragment is a fragment containing said annealing site located downstream (3') to said unknown flanking sequence region, to form a single-stranded loop, or pan portion, with a double-stranded stem of an otherwise single-stranded handle, of a panhandle structure;

(e) heat stable ligating an oligonucleotide primer 1, complementary to a known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide overhang sequences, to the recessed 5' phosphorylated end of said double-stranded portion of said handle to elongate said double-stranded portion of said otherwise single-stranded handle of said panhandle structure;

(f) performing a first stage polymerase amplification reaction using a first set of oligonucleotide primers including said primer 1 annealing to said known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide overhang sequences and a primer 2 complementary to a known sequence region both downstream (3') from said unknown flanking sequence region and upstream (5') from said annealing site for said 5' phosphorylated nucleotide sequences wherein inital priming by primer 2 occurs following annealing to said pan portion of said panhandle structure and is not inhibited by snapback annealing of said double-stranded handle of said panhandle structure; and

(g) further performing a second stage polymerase amplification reaction to produce a nested primer product using a second set of oligonucleotide primers including a primer 3 complementary to both a portion of said known sequence region complementary to primer 1 and a portion of said annealing site for said 5' phosphorylated nucleotide sequences and a primer 4 complementary to a known sequence region both downstream (3') from said unknown flanking sequence region and upstream (5') from said known sequence region complementary to primer 2.

12. A method for the amplification of an unknown DNA sequence that flanks a known DNA sequence, comprising the steps of:

(a) digesting a double-stranded DNA fragment with a restriction enzyme to yield 5' phosphorylated nucleotide overhang sequences, wherein said DNA fragment comprises a region of known DNA sequence and a region of unknown flanking DNA sequence to be amplified;

(b) annealing a 5' phosphorylated single-stranded oligonucleotide to a bridging-oligonucleotide to yield a double-stranded oligonucleotide with a phosphorylated 5' end;

(c) ligating said 5' phosphorylated single-stranded oligonucleotide of said double-stranded oligonucleotide whose non-phosphorylated 5' end is complementary to the cohesive ends generated in step (a) of said double-stranded DNA fragment to yield 5' phosphorylated nucleotide sequences complementary to a sequence portion within said known sequence region of said DNA fragment, wherein said sequence portion is an annealing site for said 5' phosphorylated nucleotide sequences;

(d) denaturing said 5' end-modified DNA fragment to produce single-stranded fragments containing said 5' phosphorylated nucleotide sequences;

(e) intra-strand annealing of a 5' phosphorylated nucleotide sequence to said annealing site within said known sequence region of a single-stranded fragment, wherein said single-stranded fragment is a fragment containing said annealing site located downstream (3') to said unknown flanking sequence region, to form a single-stranded loop, or pan portion, with a double-stranded stem of an otherwise single-stranded handle, of a panhandle structure;

(f) heat stable ligating an oligonucleotide primer 1, complementary to a known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide sequences, to the recessed 5' phosphorylated end of said double-stranded portion of said handle to elongate said double-stranded portion of said otherwise single-stranded handle of said panhandle structure;

(g) performing a first stage polymerase amplification reaction using said oligonucleotide primer 1 annealing to said known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide sequences;

(h) further performing a second stage polymerase chain reaction using an oligonucleotide primer 3 complementary to both a portion of said known sequence region complementary to primer 1 and a portion of said annealing site for said 5' phosphorylated nucleotide sequences; and

(i) further performing a third stage polymerase chain reaction using an oligonucleotide primer complementary to said annealing site for said 5' phosphorylated nucleotide sequences.

13. The method of claim 12, wherein said double-stranded DNA is genomic.

14. The method of claim 12, wherein said region of known sequence is an insertion element and said region of unknown flanking DNA sequence to be retrieved is an integration site for said insertion element and flanking regions thereof.

15. The method of claim 14, wherein said insertion element is a viral insertion element or a transposon insertion element.

16. The method of claim 12, wherein said region of known sequence is a cDNA and said region of unknown flanking DNA sequence to be retrieved is from a 3' or 5' flanking region, intron-exon junction, or intron.

17. The method of claim 12, wherein said region of known sequence is a cloning vector arm and said region of unknown flanking DNA sequence to be retrieved is the cloned DNA sequence lying adjacent said arm.

18. The method of claim 17, wherein said cloning vector is a yeast artificial chromosome.

19. The method of claim 12, wherein the double-stranded DNA is known.

20. The method of claim 12, wherein the double-stranded DNA is a gene, disease marker, or pathogen.

21. A method for the amplification of an unknown DNA sequence that flanks a known DNA sequence, comprising the steps of:

(a) digesting a double-stranded DNA fragment with a restriction enzyme to yield 5' phosphorylated nucleotide overhang sequences, wherein said DNA fragment comprises a region of known DNA sequence and a region of unknown flanking DNA sequence to be amplified;

(b) annealing a 5' phosphorylated single-stranded oligonucleotide to a bridging-oligonucleotide to yield a double-stranded oligonucleotide with a phosphorylated 5' end;

(c) ligating said 5' phosphorylated single-stranded oligonucleotide of said double-stranded oligonucleotide whose non-phosphorylated 5' end is complementary to the cohesive ends generated in step (a) of said double-stranded DNA fragment to yield 5' phosphorylated nucleotide sequences complementary to a sequence portion within said known sequence region of said DNA fragment, wherein said sequence portion is an annealing site for said 5' phosphorylated nucleotide sequences;

(d) denaturing said 5' end-modified DNA fragment to produce single-stranded fragments containing said 5' phosphorylated nucleotide sequences;

(e) intra-strand annealing of a 5' phosphorylated nucleotide sequence to said annealing site within said known sequence region of a single-stranded fragment, wherein said single-stranded fragment is a fragment containing said annealing site located downstream (3') to said unknown flanking sequence region, to form a single-stranded loop, or pan portion, with a double-stranded stem of an otherwise single-stranded handle, of a panhandle structure;

(f) heat stable ligating an oligonucleotide primer 1, complementary to a known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide sequences, to the recessed 5' phosphorylated end of said double-stranded portion of said handle to elongate said double-stranded portion of said otherwise single-stranded handle of said panhandle structure;

(g) performing a first stage polymerase amplification reaction using said oligonucleotide primer 1 annealing to said known sequence region downstream (3') from said annealing site for said 5' phosphorylated nucleotide sequences; and

(h) further performing a second stage polymerase chain reaction using an oligonucleotide primer complementary to said annealing site for said 5' phosphorylated nucleotide sequences.

22. The method of claim 21, wherein said double-stranded DNA is genomic.

23. The method of claim 21, wherein said region of known sequence is an insertion element and said region of unknown flanking DNA sequence to be retrieved is an integration site for said insertion element and flanking regions thereof.

24. The method of claim 23, wherein said insertion element is a viral insertion element or a transposon insertion element.

25. The method of claim 21, wherein said region of known sequence is a cDNA and said region of unknown flanking DNA sequence to be retrieved is from a 3' or 5' flanking region, intron-exon junction, or intron.

26. The method of claim 21, wherein said region of known sequence is a cloning vector arm and said region of unknown flanking DNA sequence to be retrieved is the cloned DNA sequence lying adjacent said arm.

27. The method of claim 21, wherein said cloning vector is a yeast artificial chromosome.

28. The method of claim 21, wherein said double-stranded DNA is known.

29. The method of claim 21, wherein said double-stranded DNA is a gene, disease marker, or pathogen.

Details for Patent 5,470,722

Applicant Tradename Biologic Ingredient Dosage Form BLA Approval Date Patent No. Expiredate
Merck Sharp & Dohme Corp. INTRON A interferon alfa-2b For Injection 103132 06/04/1986 ⤷  Try a Trial 2039-02-26
Merck Sharp & Dohme Corp. INTRON A interferon alfa-2b For Injection 103132 ⤷  Try a Trial 2039-02-26
Merck Sharp & Dohme Corp. INTRON A interferon alfa-2b Injection 103132 ⤷  Try a Trial 2039-02-26
>Applicant >Tradename >Biologic Ingredient >Dosage Form >BLA >Approval Date >Patent No. >Expiredate

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