Strategies for de novo DNA sequencing

Blomstergren, Anna

January 2003

The development of improved sequencing technologies hasenabled the field of genomics to evolve. Handling andsequencing of large numbers of samples require an increasedlevel of automation in order to obtain high throughput andconsistent quality. Improved performance has lead to thesequencing of numerous microbial genomes and a few genomes fromhigher eukaryotes and the benefits of comparing sequences bothwithin and between species are now becoming apparent. Thisthesis describes both the development of automated purificationmethods for DNA, mainly sequencing products, and a comparativesequencing project. The initially developed purification technique is dedicatedto single stranded DNA containing vector specific sequences,exemplified by sequencing products. Specific capture probescoupled to paramagnetic beads together with stabilizing modularprobes hybridize to the single stranded target. After washing,the purified DNA can be released using water. When sequencingproducts are purified they can be directly loaded onto acapillary sequencer after elution. Since this approach isspecific it can be applied to multiplex sequencing products.Different probe sets are used for each sequencing product andthe purifications are performed iteratively. The second purification approach, which can be applied to anumber of different targets, involves biotinylated PCR productsor sequencing products that are captured using streptavidinbeads. This has been described previously, buthere theinteraction between streptavidin and biotin can be disruptedwithout denaturing the streptavidin, enabling the re-use of thebeads. The relatively mild elution conditions also enable therelease of sensitive biotinylated molecules. Another project described in this thesis is the comparativesequencing of the 40 kbcagpathogenicity island (PAI) in fourHelicobacter pyloristrains. The results included thediscovery of a novel gene, present in approximately half of theSwedish strains tested. In addition, one of the strainscontained a major rearrangement dividing thecagPAI into two parts. Further, information about thevariability of different genes could be obtained. Keywords:DNA sequencing, DNA purification, automation,solid-phase, streptavidin, biotin, modular probes,Helicobacter pylori,cagPAI. / <p>NR 20140805</p>

DNA sequencing

DNA purification

automation

solid-phase

streptavidin

biotin

modular probes

Helicobacter pylori

cag PAI

Strategies for de novo DNA sequencing

Blomstergren, Anna

January 2003

<p>The development of improved sequencing technologies hasenabled the field of genomics to evolve. Handling andsequencing of large numbers of samples require an increasedlevel of automation in order to obtain high throughput andconsistent quality. Improved performance has lead to thesequencing of numerous microbial genomes and a few genomes fromhigher eukaryotes and the benefits of comparing sequences bothwithin and between species are now becoming apparent. Thisthesis describes both the development of automated purificationmethods for DNA, mainly sequencing products, and a comparativesequencing project.</p><p>The initially developed purification technique is dedicatedto single stranded DNA containing vector specific sequences,exemplified by sequencing products. Specific capture probescoupled to paramagnetic beads together with stabilizing modularprobes hybridize to the single stranded target. After washing,the purified DNA can be released using water. When sequencingproducts are purified they can be directly loaded onto acapillary sequencer after elution. Since this approach isspecific it can be applied to multiplex sequencing products.Different probe sets are used for each sequencing product andthe purifications are performed iteratively.</p><p>The second purification approach, which can be applied to anumber of different targets, involves biotinylated PCR productsor sequencing products that are captured using streptavidinbeads. This has been described previously, buthere theinteraction between streptavidin and biotin can be disruptedwithout denaturing the streptavidin, enabling the re-use of thebeads. The relatively mild elution conditions also enable therelease of sensitive biotinylated molecules.</p><p>Another project described in this thesis is the comparativesequencing of the 40 kb<i>cag</i>pathogenicity island (PAI) in four<i>Helicobacter pylori</i>strains. The results included thediscovery of a novel gene, present in approximately half of theSwedish strains tested. In addition, one of the strainscontained a major rearrangement dividing the<i>cag</i>PAI into two parts. Further, information about thevariability of different genes could be obtained.</p><p><b>Keywords:</b>DNA sequencing, DNA purification, automation,solid-phase, streptavidin, biotin, modular probes,<i>Helicobacter pylori</i>,<i>cag</i>PAI.</p>

DNA sequencing

DNA purification

automation

solid-phase

streptavidin

biotin

modular probes

Helicobacter pylori

cag PAI

Molecular Tools for Nucleic Acid Analysis

O'Meara, Deirdre

January 2001

Nucleic acid technology has assumed an essential role invarious areas ofin vitrodiagnostics ranging from infectious diseasediagnosis to human genetics. An important requirement of suchmolecular methods is that they achieve high sensitivity andspecificity with a fast turnaround time in a cost-effectivemanner. To this end, in this thesis we have focused on thedevelopment of sensitive nucleic acid strategies thatfacilitate automation and high-throughput analysis. The success of nucleic acid diagnostics in the clinicalsetting depends heavily on the method used for purification ofthe nucleic acid target from biological samples. Here we havefocused on developing strategies for hybridisation capture ofsuch templates. Using biosensor technology we observed that thehybridisation efficiency could be improved using contiguousoligonucleotide probes which acted co-operatively. Byimmobilising one of the probes and annealing the second probein solution, we achieved a marked increase in target capturedue to a base stacking effect between nicked oligonucleotidesand/or due to the opening up of secondary structure. Suchco-operatively interacting modular probes were then combinedwith bio-magnetic bead technology to develop a capture systemfor the extraction of hepatitis C RNA from serum. Viral capturewith such co-operatively interacting probes extracted 2-foldmore target as capture with only a single probe achieving asimilar sensitivity to the conventional extraction protocol. Ananalogous strategy was designed to enrich for sequencingproducts prior to gel electrophoresis removing sequencingreagents and template DNA which interfere with the separationand detection of sequencing ladders, especially in the case ofcapillary gel electrophoresis. This protocol facilitates highthroughput clean-up of cycle sequencing reactions resulting inaccurate sequence data at a low cost, which is a pre-requisitefor large-scale genome sequencing products. Currently, a large effort is directed towards differentialsequencing to identify mutations or polymorphisms both in theclinical laboratory and in medical genetics. Inexpensive, highthroughput methods are therefore required to rapidly screen atarget nucleic acid for sequence based changes. In the clinicalsetting, sequence analysis of human immunodeficiency virus(HIV-1) is used to determine the presence of drug resistancemutations. Here we describe a bioluminometric pyrosequencingapproach to rapidly screen for the presence of drug resistancemutations in the protease gene of HIV-1. This sequencingstrategy can analyse the protease gene of HIV-1 from eightpatients in less than an hour and such non-gel based approachesshould be useful in the future in a clinical setting for rapid,robust mutation detection. Microarray technology facilitates large-scalemutation/polymorphism detection and here we developed amicroarray based single nucleotide polymorphism (SNP)genotyping strategy based on apyrase mediated allele specificextension (AMASE). AMASE exploits the fact that mismatchedprimers exhibit slower reaction kinetics than perfectly matchedprimers by including a nucleotide degrading enzyme (apyrase)which results in degradation of the nucleotides before themismatched primer can be extended. We have successfully typed200 genotypes (14% were incorrect without apyrase) by AMASEwhich cluster into three distinct groups representing the threepossible genotypes. In the future, AMASE on DNA microarraysshould facilitate association studies where an accuracy&gt;99%is required. <b>Keywords:</b>nucleic acid capture, modular probes,biosensor, bio-magnetic separation, hepatitis C, sequencing,pyrosequencing, mutation detection, HIV-1, drug resistance,SNP, allele-specific extension, apyrase, genotyping.

nucleic acid capture

modular probes

biosensor

bio-magnetic separation

hepatitis C

sequencing

pyrosequencing

mutation detection

HIV-1

drug resistance

SNP

allele-specific extension

apyrase

genotyping.

Molecular Tools for Nucleic Acid Analysis

O'Meara, Deirdre

January 2001

<p>Nucleic acid technology has assumed an essential role invarious areas of<i>in vitro</i>diagnostics ranging from infectious diseasediagnosis to human genetics. An important requirement of suchmolecular methods is that they achieve high sensitivity andspecificity with a fast turnaround time in a cost-effectivemanner. To this end, in this thesis we have focused on thedevelopment of sensitive nucleic acid strategies thatfacilitate automation and high-throughput analysis.</p><p>The success of nucleic acid diagnostics in the clinicalsetting depends heavily on the method used for purification ofthe nucleic acid target from biological samples. Here we havefocused on developing strategies for hybridisation capture ofsuch templates. Using biosensor technology we observed that thehybridisation efficiency could be improved using contiguousoligonucleotide probes which acted co-operatively. Byimmobilising one of the probes and annealing the second probein solution, we achieved a marked increase in target capturedue to a base stacking effect between nicked oligonucleotidesand/or due to the opening up of secondary structure. Suchco-operatively interacting modular probes were then combinedwith bio-magnetic bead technology to develop a capture systemfor the extraction of hepatitis C RNA from serum. Viral capturewith such co-operatively interacting probes extracted 2-foldmore target as capture with only a single probe achieving asimilar sensitivity to the conventional extraction protocol. Ananalogous strategy was designed to enrich for sequencingproducts prior to gel electrophoresis removing sequencingreagents and template DNA which interfere with the separationand detection of sequencing ladders, especially in the case ofcapillary gel electrophoresis. This protocol facilitates highthroughput clean-up of cycle sequencing reactions resulting inaccurate sequence data at a low cost, which is a pre-requisitefor large-scale genome sequencing products.</p><p>Currently, a large effort is directed towards differentialsequencing to identify mutations or polymorphisms both in theclinical laboratory and in medical genetics. Inexpensive, highthroughput methods are therefore required to rapidly screen atarget nucleic acid for sequence based changes. In the clinicalsetting, sequence analysis of human immunodeficiency virus(HIV-1) is used to determine the presence of drug resistancemutations. Here we describe a bioluminometric pyrosequencingapproach to rapidly screen for the presence of drug resistancemutations in the protease gene of HIV-1. This sequencingstrategy can analyse the protease gene of HIV-1 from eightpatients in less than an hour and such non-gel based approachesshould be useful in the future in a clinical setting for rapid,robust mutation detection.</p><p>Microarray technology facilitates large-scalemutation/polymorphism detection and here we developed amicroarray based single nucleotide polymorphism (SNP)genotyping strategy based on apyrase mediated allele specificextension (AMASE). AMASE exploits the fact that mismatchedprimers exhibit slower reaction kinetics than perfectly matchedprimers by including a nucleotide degrading enzyme (apyrase)which results in degradation of the nucleotides before themismatched primer can be extended. We have successfully typed200 genotypes (14% were incorrect without apyrase) by AMASEwhich cluster into three distinct groups representing the threepossible genotypes. In the future, AMASE on DNA microarraysshould facilitate association studies where an accuracy>99%is required.</p><p><b>Keywords:</b>nucleic acid capture, modular probes,biosensor, bio-magnetic separation, hepatitis C, sequencing,pyrosequencing, mutation detection, HIV-1, drug resistance,SNP, allele-specific extension, apyrase, genotyping.</p>

nucleic acid capture

modular probes

biosensor

bio-magnetic separation

hepatitis C

sequencing

pyrosequencing

mutation detection

HIV-1

drug resistance

SNP

allele-specific extension

apyrase

genotyping.