1 / 73

Next–generation DNA sequencing technologies – theory & practice

Next–generation DNA sequencing technologies – theory & practice. Outline. Next-Generation sequencing (NGS) technologies – overview NGS targeted re-sequencing – fishing out the regions of interest NGS workflow: data collection and processing – the exome sequencing pipeline.

tammy
Télécharger la présentation

Next–generation DNA sequencing technologies – theory & practice

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Next–generation DNA sequencing technologies – theory & practice

  2. Outline • Next-Generation sequencing (NGS) technologies – overview • NGS targeted re-sequencing – fishing out the regions of interest • NGS workflow: data collection and processing – the exome sequencing pipeline

  3. PART I: NGS technologies Next-Generation sequencing (NGS) technologies – overview

  4. DNA Sequencing – the next generation • The automated Sanger method is considered as a ‘first-generation’ technology, and newer methods are referred to as next-generation sequencing (NGS).

  5. Landmarks in DNA sequencing • 1953 Discovery of DNA double helix structure • 1977 • A Maxam and W Gilbert "DNA seq by chemical degradation" • F Sanger"DNA sequencing with chain-terminating inhibitors" • 1984 DNA sequence of the Epstein-Barr virus, 170 kb • 1987 Applied Biosystems - first automated sequencer • 1991 Sequencing of human genome in Venter's lab • 1996 P. Nyrén and M Ronaghi - pyrosequencing • 2001 A draft sequence of the human genome • 2003 human genome completed • 2004 454 Life Sciences markets first NGS machine

  6. DNA Sequencing – the next generation

  7. DNA Sequencing – the next generation • The newer technologies constitute various strategies that rely on a combination of • Library/template preparation • Sequencing and imaging

  8. DNA Sequencing – the next generation • Commercially available technologies • Roche – 454 • GSFLX titanium • Junior • Illumina • HiSeq2000 • MySeq • Life – SOLiD • 5500xl • Ion torrent • HelicosBioSciences– HeliScope • Pacific Biosciences – PacBio RS

  9. DNA Sequencing – the next generation

  10. Template preparation: STEP1 • Produce a non-biased source of nucleic acid material from the genome

  11. Template preparation: STEP1 • Produce a non-biased source of nucleic acid material from the genome

  12. Template preparation • Produce a non-biased source of nucleic acid material from the genome • Current methods: • randomly breaking genomic DNA into smaller sizes • Ligate adaptors • attach or immobilize the template to a solid surface or support • the spatially separated template sites allows thousands to billions of sequencing reactions to be performed simultaneously

  13. Template preparation • Clonal amplification • Roche – 454 • Illumina– HiSeq • Life – SOLiD • Single molecule sequencing • HelicosBioSciences– HeliScope • Pacific Biosciences – PacBio RS

  14. Template preparation: Clonal amplification • In solution – emulsion PCR (emPCR) • Roche – 454 • Life – SOLiD • Solid phase – Bridge PCR • Illumina – HiSeq

  15. Template preparation: Clonal amplification - emPCR

  16. Sequencing SOLiD 454

  17. Pyrosequencing Picotitre plate Pyrosequencing

  18. Pyrosequencing

  19. Sequencing by ligation

  20. Sequencing by ligation

  21. Sequencing by ligation

  22. Template preparation: Clonal amplification – Bridge PCR

  23. Template preparation: Single molecule templates Heliscope BioPac

  24. HiSeq Heliscope

  25. DNA Sequencing – the next generation • The major advance offered by NGS is the ability to cheaply produce an enormous volume of data • The arrival of NGS technologies in the marketplace has changed the way we think about scientific approaches in basic, applied and clinical research

  26. PART II: NGS targeted resequencing fishing out the regions of interest

  27. The beginning

  28. DNA Sequencing – the next generation • Library/template preparation • Library enrichment for target • Sequencing and imaging

  29. Target enrichment strategies

  30. Target enrichment strategies

  31. Target enrichment strategies

  32. Target enrichment strategies

  33. Target enrichment strategies: MIP

  34. Hybrid Capture

  35. Hybrid Capture

  36. Target enrichment strategies

  37. PCR based approaches

  38. PCR based approaches: Raindance

  39. PCR based approaches: Fluidigm • 48.48 Access Array

  40. PCR based approaches: Fluidigm • 48.48 Access Array

  41. PCR based approaches: Fluidigm • 48.48 Access Array

  42. Target enrichment strategies

  43. PART III: NGS workflow data collection and processing – the exome sequencing pipeline

  44. WholeExomeSequencing • The human genome • Genome = 3Gb • Exome = 30Mb • 180 000 exons • Protein coding genes • constitute only approximately 1% of the human genome • It is estimated that 85% of the mutations with large effects on disease-related traits can be found in exons or splice sites

  45. Exome sequencing

  46. The past, present & future

  47. Exomesequencingcapacity • HiSeq specifications: • 2 flow cells • 16 lanes (8 per flow cell) • 200-300 Gbases per flow cell • 10 days for a single run • Exome throughput • 96 @ 60x coverage per run • 3000 @ 60x coverage per year

  48. Data processing workflow

  49. Data processing

More Related