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SEQUENCING-related topics

SEQUENCING-related topics. chain-termination sequencing the polymerase chain reaction (PCR) cycle sequencing large scale sequencing. stefanie . hartmann @ unc . edu (postdoc in Todd Vision’s lab). 1. chain termination sequencing. single-stranded, denatured DNA.

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SEQUENCING-related topics

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  1. SEQUENCING-related topics chain-termination sequencing the polymerase chain reaction (PCR) cycle sequencing large scale sequencing stefanie.hartmann @ unc.edu (postdoc in Todd Vision’s lab)

  2. 1. chain termination sequencing single-stranded, denatured DNA A C T T G T G C G A T G

  3. 1. chain termination sequencing single-stranded, denatured DNA reaction buffer, DNA polymerase, dNTPs, ddNTPs, primer A C T T G T G C G A T G T A C A T C G ATCG

  4. 1. chain termination sequencing single-stranded, denatured DNA reaction buffer, DNA polymerase, dNTPs, ddNTPs, primer randomly incorporated, ddNTPs stop the reaction, resulting in a nested set of DNA fragments A C T T G T G C G A T G T A C T G A A C A C G C T A CG A A C A C G C T A C A A C A C G C T A C A C A C G C T A C C A C G C T A C A C G C T A C C G C T A C G C T A C C T A C A T C G ATCG

  5. 1. chain termination sequencing single-stranded, denatured DNA reaction buffer, DNA polymerase, dNTPs, ddNTPs, primer randomly incorporated, ddNTPs stop the reaction, resulting in a nested set of DNA fragments DNA fragments are separated by electrophoresis A C T T G T G C G A T G T A C T G A A C A C G C T A CG A A C A C G C T A C A A C A C G C T A C A C A C G C T A C C A C G C T A C A C G C T A C C G C T A C G C T A C C T A C A T C G ATCG

  6. 2. polymerase chain reaction (PCR) iterative process, consists of 3 steps: denaturation of the template DNA by heat

  7. 2. polymerase chain reaction (PCR) iterative process, consists of 3 steps: denaturation of the template DNA by heat annealing of the oligonucleotide primers to the single-stranded target sequence

  8. 2. polymerase chain reaction (PCR) iterative process, consists of 3 steps: denaturation of the template DNA by heat annealing of the oligonucleotide primers to the single-stranded target sequence extension of the annealed primers by a thermostable DNA polymerase

  9. 2. polymerase chain reaction (PCR) iterative process, consists of 3 steps: denaturation of the template DNA by heat annealing of the oligonucleotide primers to the single-stranded target sequence extension of the annealed primers by a thermostable DNA polymerase repeat for 30-40 cycles; each cycle doubles the amount of DNA synthesized in the previous cycle - after 30th cycle: 230 x

  10. 3. (thermal) cycle sequencing (linear amplification DNA sequencing) contains sequencing reaction mixture of buffer, template, DNA polymerase, primer, dNTP, ddNTP consists, like a standard PCR, of cycles of denaturation, annealing, and extension BUT: uses only one primer to linearly amplify the extension products

  11. 4. large scale sequencing (shotgun sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into plasmid vectors CLONE LIBRARY sequence fragments without knowledge of their chromosomal location THOUSANDS OR MILLIONS OF SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  12. 4. large scale sequencing (shotgun sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into plasmid vectors CLONE LIBRARY sequence fragments without knowledge of their chromosomal location THOUSANDS OR MILLIONS OF SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  13. 4. large scale sequencing (shotgun sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into plasmid vectors CLONE LIBRARY sequence fragments without knowledge of their chromosomal location THOUSANDS OR MILLIONS OF SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  14. 4. large scale sequencing (shotgun sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into plasmid vectors CLONE LIBRARY sequence fragments without knowledge of their chromosomal location THOUSANDS OR MILLIONS OF SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  15. 4. large scale sequencing (hierarchical sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into BAC vectors, map fragments PHYSICAL MAP fragment and subclone inserts into plasmid vectors CLONE LIBRARY sequence the clones SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  16. 4. large scale sequencing (hierarchical sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into BAC vectors, map fragments PHYSICAL MAP fragment and subclone inserts into plasmid vectors CLONE LIBRARY sequence the clones SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  17. 4. large scale sequencing (hierarchical sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into BAC vectors, map fragments PHYSICAL MAP fragment and subclone inserts into plasmid vectors CLONE LIBRARY sequence the clones SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  18. 4. large scale sequencing (hierarchical sequencing) WHOLE GENOME break into random fragments FRAGMENTS clone into BAC vectors, map fragments PHYSICAL MAP fragment and subclone inserts into plasmid vectors CLONE LIBRARY sequence the clones SHORT SEQUENCES use a computer to assemble the entire sequence from the overlaps found CONTIGS resequence regions between contigs if necessary WHOLE GENOME SEQUENCE

  19. hierarchical sequencing vs. shotgun sequencing + filling gaps, resequencing uncertain regions is easier + distribute clones to different labs - constructing the physical map is expensive and time-consuming + physical map construction is not necessary + cost effective and fast + good for small genomes - filling gaps and keeping track of sequenced plasmids is more difficult - computationally more expensive

  20. hierarchical sequencing vs. shotgun sequencing + filling gaps, resequencing uncertain regions is easier + distribute clones to different labs - constructing the physical map is expensive and time-consuming + physical map construction is not necessary + cost effective and fast + good for small genomes - filling gaps and keeping track of sequenced plasmids is more difficult - computationally more expensive

  21. more info on PCR:

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