Your search keyword '"Akeson M"' showing total 19 results

1. Advances in nanopore direct RNA sequencing.

Author

Jain M, Abu-Shumays R, Olsen HE, and Akeson M

Subjects

Base Sequence, High-Throughput Nucleotide Sequencing, RNA genetics, Sequence Analysis, RNA, Nanopore Sequencing, Nanopores

Published

2022

2. Nanopore ReCappable sequencing maps SARS-CoV-2 5' capping sites and provides new insights into the structure of sgRNAs.

Author

Ugolini C, Mulroney L, Leger A, Castelli M, Criscuolo E, Williamson MK, Davidson AD, Almuqrin A, Giambruno R, Jain M, Frigè G, Olsen H, Tzertzinis G, Schildkraut I, Wulf MG, Corrêa IR, Ettwiller L, Clementi N, Clementi M, Mancini N, Birney E, Akeson M, Nicassio F, Matthews DA, and Leonardi T

Subjects

Genome, Viral genetics, Humans, RNA Caps, RNA, Viral genetics, RNA, Viral metabolism, SARS-CoV-2 genetics, COVID-19 genetics, Nanopores

Abstract

The SARS-CoV-2 virus has a complex transcriptome characterised by multiple, nested subgenomic RNAsused to express structural and accessory proteins. Long-read sequencing technologies such as nanopore direct RNA sequencing can recover full-length transcripts, greatly simplifying the assembly of structurally complex RNAs. However, these techniques do not detect the 5' cap, thus preventing reliable identification and quantification of full-length, coding transcript models. Here we used Nanopore ReCappable Sequencing (NRCeq), a new technique that can identify capped full-length RNAs, to assemble a complete annotation of SARS-CoV-2 sgRNAs and annotate the location of capping sites across the viral genome. We obtained robust estimates of sgRNA expression across cell lines and viral isolates and identified novel canonical and non-canonical sgRNAs, including one that uses a previously un-annotated leader-to-body junction site. The data generated in this work constitute a useful resource for the scientific community and provide important insights into the mechanisms that regulate the transcription of SARS-CoV-2 sgRNAs., (© The Author(s) 2022. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2022

3. Synthesis of modified nucleotide polymers by the poly(U) polymerase Cid1: application to direct RNA sequencing on nanopores.

Author

Vo JM, Mulroney L, Quick-Cleveland J, Jain M, Akeson M, and Ares M Jr

Subjects

Nucleotidyltransferases genetics, Polynucleotide Adenylyltransferase genetics, Schizosaccharomyces pombe Proteins genetics, Nanopores, Nucleotides chemistry, Nucleotidyltransferases metabolism, Polymers chemistry, Polynucleotide Adenylyltransferase metabolism, Saccharomyces cerevisiae enzymology, Schizosaccharomyces enzymology, Schizosaccharomyces pombe Proteins metabolism, Sequence Analysis, RNA methods

Abstract

Understanding transcriptomes requires documenting the structures, modifications, and abundances of RNAs as well as their proximity to other molecules. The methods that make this possible depend critically on enzymes (including mutant derivatives) that act on nucleic acids for capturing and sequencing RNA. We tested two 3' nucleotidyl transferases, Saccharomyces cerevisiae poly(A) polymerase and Schizosaccharomyces pombe Cid1, for the ability to add base and sugar modified rNTPs to free RNA 3' ends, eventually focusing on Cid1. Although unable to polymerize ΨTP or 1meΨTP, Cid1 can use 5meUTP and 4thioUTP. Surprisingly, Cid1 can use inosine triphosphate to add poly(I) to the 3' ends of a wide variety of RNA molecules. Most poly(A) mRNAs efficiently acquire a uniform tract of about 50 inosine residues from Cid1, whereas non-poly(A) RNAs acquire longer, more heterogeneous tails. Here we test these activities for use in direct RNA sequencing on nanopores, and find that Cid1-mediated poly(I)-tailing permits detection and quantification of both mRNAs and non-poly(A) RNAs simultaneously, as well as enabling the analysis of nascent RNAs associated with RNA polymerase II. Poly(I) produces a different current trace than poly(A), enabling recognition of native RNA 3' end sequence lost by in vitro poly(A) addition. Addition of poly(I) by Cid1 offers a broadly useful alternative to poly(A) capture for direct RNA sequencing on nanopores., (© 2021 Vo et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2021

4. Direct Nanopore Sequencing of Individual Full Length tRNA Strands.

Author

Thomas NK, Poodari VC, Jain M, Olsen HE, Akeson M, and Abu-Shumays RL

Subjects

Escherichia coli genetics, High-Throughput Nucleotide Sequencing, Humans, Nucleotides, Nanopore Sequencing, Nanopores

Abstract

We describe a method for direct tRNA sequencing using the Oxford Nanopore MinION. The principal technical advance is custom adapters that facilitate end-to-end sequencing of individual transfer RNA (tRNA) molecules at subnanometer precision. A second advance is a nanopore sequencing pipeline optimized for tRNA. We tested this method using purified E. coli tRNA fMet , tRNA Lys , and tRNA Phe samples. 76-92% of individual aligned tRNA sequence reads were full length. As a proof of concept, we showed that nanopore sequencing detected all 43 expected isoacceptors in total E. coli MRE600 tRNA as well as isodecoders that further define that tRNA population. Alignment-based comparisons between the three purified tRNAs and their synthetic controls revealed systematic nucleotide miscalls that were diagnostic of known modifications. Systematic miscalls were also observed proximal to known modifications in total E. coli tRNA alignments, including a highly conserved pseudouridine in the T loop. This work highlights the potential of nanopore direct tRNA sequencing as well as improvements needed to implement tRNA sequencing for human healthcare applications.

Published

2021

5. Unfolding and Translocation of Proteins Through an Alpha-Hemolysin Nanopore by ClpXP.

Author

Nivala J, Mulroney L, Luan Q, Abu-Shumays R, and Akeson M

Subjects

Protein Transport, Endopeptidase Clp metabolism, Hemolysin Proteins chemistry, Hemolysin Proteins metabolism, Lipid Bilayers metabolism, Nanopores, Protein Unfolding

Abstract

Proteins present a significant challenge for nanopore-based sequence analysis. This is partly due to their stable tertiary structures that must be unfolded for linear translocation, and the absence of regular charge density. To address these challenges, here we describe how ClpXP, an ATP-dependent protein unfoldase, can be harnessed to unfold and processively translocate multi-domain protein substrates through an alpha-hemolysin nanopore sensor. This process results in ionic current patterns that are diagnostic of protein sequence and structure at the single-molecule level.

Published

2021

6. Reading canonical and modified nucleobases in 16S ribosomal RNA using nanopore native RNA sequencing.

Author

Smith AM, Jain M, Mulroney L, Garalde DR, and Akeson M

Subjects

Escherichia coli genetics, RNA, Bacterial genetics, Nanopores, RNA, Ribosomal, 16S genetics, Sequence Analysis, RNA methods

Abstract

The ribosome small subunit is expressed in all living cells. It performs numerous essential functions during translation, including formation of the initiation complex and proofreading of base-pairs between mRNA codons and tRNA anticodons. The core constituent of the small ribosomal subunit is a ~1.5 kb RNA strand in prokaryotes (16S rRNA) and a homologous ~1.8 kb RNA strand in eukaryotes (18S rRNA). Traditional sequencing-by-synthesis (SBS) of rRNA genes or rRNA cDNA copies has achieved wide use as a 'molecular chronometer' for phylogenetic studies, and as a tool for identifying infectious organisms in the clinic. However, epigenetic modifications on rRNA are erased by SBS methods. Here we describe direct MinION nanopore sequencing of individual, full-length 16S rRNA absent reverse transcription or amplification. As little as 5 picograms (~10 attomole) of purified E. coli 16S rRNA was detected in 4.5 micrograms of total human RNA. Nanopore ionic current traces that deviated from canonical patterns revealed conserved E. coli 16S rRNA 7-methylguanosine and pseudouridine modifications, and a 7-methylguanosine modification that confers aminoglycoside resistance to some pathological E. coli strains., Competing Interests: MA holds options in Oxford Nanopore Technologies (ONT). MA is a paid consultant to ONT. MA is an inventor on 11 University of California patents licensed to ONT (6,267,872, 6,465,193, 6,746,594, 6,936,433, 7,060,50, 8,500,982, 8,679,747, 9,481,908, 9,797,013, 10,059,988, and 10,081,835). DRG, who contributed to each facet of the paper, is an employee of Oxford Nanopore Technologies. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Published

2019

7. Mapping DNA methylation with high-throughput nanopore sequencing.

Author

Rand AC, Jain M, Eizenga JM, Musselman-Brown A, Olsen HE, Akeson M, and Paten B

Subjects

5-Methylcytosine analysis, Escherichia coli genetics, Genome, Bacterial, High-Throughput Nucleotide Sequencing instrumentation, Markov Chains, Models, Genetic, 5-Methylcytosine metabolism, DNA Methylation, High-Throughput Nucleotide Sequencing methods, Nanopores

Abstract

DNA chemical modifications regulate genomic function. We present a framework for mapping cytosine and adenosine methylation with the Oxford Nanopore Technologies MinION using this nanopore sequencer's ionic current signal. We map three cytosine variants and two adenine variants. The results show that our model is sensitive enough to detect changes in genomic DNA methylation levels as a function of growth phase in Escherichia coli.

Published

2017

8. The Oxford Nanopore MinION: delivery of nanopore sequencing to the genomics community.

Author

Jain M, Olsen HE, Paten B, and Akeson M

Subjects

Aneuploidy, Computational Biology instrumentation, DNA analysis, DNA genetics, Genomics instrumentation, High-Throughput Nucleotide Sequencing instrumentation, Humans, Reproducibility of Results, Algorithms, Computational Biology methods, Genomics methods, High-Throughput Nucleotide Sequencing methods, Nanopores

Abstract

Nanopore DNA strand sequencing has emerged as a competitive, portable technology. Reads exceeding 150 kilobases have been achieved, as have in-field detection and analysis of clinical pathogens. We summarize key technical features of the Oxford Nanopore MinION, the dominant platform currently available. We then discuss pioneering applications executed by the genomics community.

Published

2016

9. Three decades of nanopore sequencing.

Author

Deamer D, Akeson M, and Branton D

Subjects

DNA chemistry, Conductometry trends, DNA genetics, High-Throughput Nucleotide Sequencing trends, Lipid Bilayers chemistry, Nanopores ultrastructure, Sequence Analysis, DNA trends

Published

2016

10. Improved data analysis for the MinION nanopore sequencer.

Author

Jain M, Fiddes IT, Miga KH, Olsen HE, Paten B, and Akeson M

Subjects

Algorithms, Gene Dosage, Humans, Neoplasms genetics, High-Throughput Nucleotide Sequencing methods, Nanopores

Abstract

Speed, single-base sensitivity and long read lengths make nanopores a promising technology for high-throughput sequencing. We evaluated and optimized the performance of the MinION nanopore sequencer using M13 genomic DNA and used expectation maximization to obtain robust maximum-likelihood estimates for insertion, deletion and substitution error rates (4.9%, 7.8% and 5.1%, respectively). Over 99% of high-quality 2D MinION reads mapped to the reference at a mean identity of 85%. We present a single-nucleotide-variant detection tool that uses maximum-likelihood parameter estimates and marginalization over many possible read alignments to achieve precision and recall of up to 99%. By pairing our high-confidence alignment strategy with long MinION reads, we resolved the copy number for a cancer-testis gene family (CT47) within an unresolved region of human chromosome Xq24.

Published

2015

11. Discrimination among protein variants using an unfoldase-coupled nanopore.

Author

Nivala J, Mulroney L, Li G, Schreiber J, and Akeson M

Subjects

ATPases Associated with Diverse Cellular Activities, Adenosine Triphosphatases metabolism, Endopeptidase Clp metabolism, Escherichia coli Proteins metabolism, Models, Molecular, Molecular Chaperones metabolism, Point Mutation, Protein Stability, Protein Structure, Tertiary, Proteolysis, Nanopores, Nanotechnology instrumentation, Protein Engineering, Protein Unfolding, Proteins chemistry, Proteins genetics

Abstract

Previously we showed that the protein unfoldase ClpX could facilitate translocation of individual proteins through the α-hemolysin nanopore. This results in ionic current fluctuations that correlate with unfolding and passage of intact protein strands through the pore lumen. It is plausible that this technology could be used to identify protein domains and structural modifications at the single-molecule level that arise from subtle changes in primary amino acid sequence (e.g., point mutations). As a test, we engineered proteins bearing well-characterized domains connected in series along an ∼700 amino acid strand. Point mutations in a titin immunoglobulin domain (titin I27) and point mutations, proteolytic cleavage, and rearrangement of beta-strands in green fluorescent protein (GFP), caused ionic current pattern changes for single strands predicted by bulk phase and force spectroscopy experiments. Among these variants, individual proteins could be classified at 86-99% accuracy using standard machine learning tools. We conclude that a ClpXP-nanopore device can discriminate among distinct protein domains, and that sequence-dependent variations within those domains are detectable.

Published

2014

12. Nanopores discriminate among five C5-cytosine variants in DNA.

Author

Wescoe ZL, Schreiber J, and Akeson M

Subjects

Cytosine analogs & derivatives, Cytosine chemistry, DNA chemistry, DNA-Directed DNA Polymerase chemistry, DNA-Directed DNA Polymerase metabolism, Molecular Structure, Cytosine metabolism, DNA metabolism, Nanopores

Abstract

Individual DNA molecules can be read at single nucleotide precision using nanopores coupled to processive enzymes. Discrimination among the four canonical bases has been achieved, as has discrimination among cytosine, 5-methylcytosine (mC), and 5-hydroxymethylcytosine (hmC). Two additional modified cytosine bases, 5-carboxylcytosine (caC) and 5-formylcytosine (fC), are produced during enzymatic conversion of hmC to cytosine in mammalian cells. Thus, an accurate picture of the cytosine epigenetic status in target cells should also include these C5-cytosine variants. In the present study, we used a patch clamp amplifier to acquire ionic current traces caused by phi29 DNA polymerase-controlled translocation of DNA templates through the M2MspA pore. Decision boundaries based on three consecutive ionic current states were implemented to call mC, hmC, caC, fC, or cytosine at CG dinucleotides in ∼4400 individual DNA molecules. We found that the percentage of correct base calls for single pass reads ranged from 91.6% to 98.3%. This accuracy depended upon the identity of nearest neighbor bases surrounding the CG dinucleotide.

Published

2014

13. Error rates for nanopore discrimination among cytosine, methylcytosine, and hydroxymethylcytosine along individual DNA strands.

Author

Schreiber J, Wescoe ZL, Abu-Shumays R, Vivian JT, Baatar B, Karplus K, and Akeson M

Subjects

5-Methylcytosine chemistry, Cytosine chemistry, Research Design, 5-Methylcytosine isolation & purification, Cytosine analogs & derivatives, Cytosine isolation & purification, DNA analysis, DNA Methylation genetics, Epigenomics methods, Nanopores

Abstract

Cytosine, 5-methylcytosine, and 5-hydroxymethylcytosine were identified during translocation of single DNA template strands through a modified Mycobacterium smegmatis porin A (M2MspA) nanopore under control of phi29 DNA polymerase. This identification was based on three consecutive ionic current states that correspond to passage of modified or unmodified CG dinucleotides and their immediate neighbors through the nanopore limiting aperture. To establish quality scores for these calls, we examined ~3,300 translocation events for 48 distinct DNA constructs. Each experiment analyzed a mixture of cytosine-, 5-methylcytosine-, and 5-hydroxymethylcytosine-bearing DNA strands that contained a marker that independently established the correct cytosine methylation status at the target CG of each molecule tested. To calculate error rates for these calls, we established decision boundaries using a variety of machine-learning methods. These error rates depended upon the identity of the bases immediately 5' and 3' of the targeted CG dinucleotide, and ranged from 1.7% to 12.2% for a single-pass read. We estimate that Q40 values (0.01% error rates) for methylation status calls could be achieved by reading single molecules 5-19 times depending upon sequence context.

Published

2013

14. Unfoldase-mediated protein translocation through an α-hemolysin nanopore.

Author

Nivala J, Marks DB, and Akeson M

Subjects

ATPases Associated with Diverse Cellular Activities, Biotechnology, Lipid Bilayers chemistry, Lipid Bilayers metabolism, Models, Molecular, Protein Transport, Adenosine Triphosphatases chemistry, Adenosine Triphosphatases metabolism, Endopeptidase Clp chemistry, Endopeptidase Clp metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Hemolysin Proteins chemistry, Hemolysin Proteins metabolism, Molecular Chaperones chemistry, Molecular Chaperones metabolism, Nanopores, Protein Unfolding

Abstract

Using nanopores to sequence biopolymers was proposed more than a decade ago. Recent advances in enzyme-based control of DNA translocation and in DNA nucleotide resolution using modified biological pores have satisfied two technical requirements of a functional nanopore DNA sequencing device. Nanopore sequencing of proteins was also envisioned. Although proteins have been shown to move through nanopores, a technique to unfold proteins for processive translocation has yet to be demonstrated. Here we describe controlled unfolding and translocation of proteins through the α-hemolysin (α-HL) pore using the AAA+ unfoldase ClpX. Sequence-dependent features of individual engineered proteins were detected during translocation. These results demonstrate that molecular motors can reproducibly drive proteins through a model nanopore--a feature required for protein sequence analysis using this single-molecule technology.

Published

2013

15. Direct observation of translocation in individual DNA polymerase complexes.

Author

Dahl JM, Mai AH, Cherf GM, Jetha NN, Garalde DR, Marziali A, Akeson M, Wang H, and Lieberman KR

Subjects

ATP-Binding Cassette Transporters chemistry, ATP-Binding Cassette Transporters metabolism, Catalytic Domain physiology, DNA, Viral metabolism, DNA-Directed DNA Polymerase chemical synthesis, Diphosphates metabolism, Enzyme Activation physiology, Exonucleases metabolism, Hemolysin Proteins chemistry, Hemolysin Proteins metabolism, Inverted Repeat Sequences genetics, Molecular Motor Proteins physiology, Nucleic Acid Conformation, Bacillus Phages enzymology, Bacillus Phages genetics, DNA Replication physiology, DNA-Directed DNA Polymerase genetics, DNA-Directed DNA Polymerase metabolism, Nanopores

Abstract

Complexes of phi29 DNA polymerase and DNA fluctuate on the millisecond time scale between two ionic current amplitude states when captured atop the α-hemolysin nanopore in an applied field. The lower amplitude state is stabilized by complementary dNTP and thus corresponds to complexes in the post-translocation state. We have demonstrated that in the upper amplitude state, the DNA is displaced by a distance of one nucleotide from the post-translocation state. We propose that the upper amplitude state corresponds to complexes in the pre-translocation state. Force exerted on the template strand biases the complexes toward the pre-translocation state. Based on the results of voltage and dNTP titrations, we concluded through mathematical modeling that complementary dNTP binds only to the post-translocation state, and we estimated the binding affinity. The equilibrium between the two states is influenced by active site-proximal DNA sequences. Consistent with the assignment of the upper amplitude state as the pre-translocation state, a DNA substrate that favors the pre-translocation state in complexes on the nanopore is a superior substrate in bulk phase for pyrophosphorolysis. There is also a correlation between DNA sequences that bias complexes toward the pre-translocation state and the rate of exonucleolysis in bulk phase, suggesting that during DNA synthesis the pathway for transfer of the primer strand from the polymerase to exonuclease active site initiates in the pre-translocation state.

Published

2012

16. Automated forward and reverse ratcheting of DNA in a nanopore at 5-Å precision.

Author

Cherf GM, Lieberman KR, Rashid H, Lam CE, Karplus K, and Akeson M

Subjects

DNA Replication genetics, DNA-Directed DNA Polymerase chemistry, DNA-Directed DNA Polymerase genetics, Hemolysin Proteins chemistry, Nucleotides chemistry, Nucleotides genetics, High-Throughput Nucleotide Sequencing instrumentation, High-Throughput Nucleotide Sequencing methods, Nanopores

Abstract

An emerging DNA sequencing technique uses protein or solid-state pores to analyze individual strands as they are driven in single-file order past a nanoscale sensor. However, uncontrolled electrophoresis of DNA through these nanopores is too fast for accurate base reads. Here, we describe forward and reverse ratcheting of DNA templates through the α-hemolysin nanopore controlled by phi29 DNA polymerase without the need for active voltage control. DNA strands were ratcheted through the pore at median rates of 2.5-40 nucleotides per second and were examined at one nucleotide spatial precision in real time. Up to 500 molecules were processed at ∼130 molecules per hour through one pore. The probability of a registry error (an insertion or deletion) at individual positions during one pass along the template strand ranged from 10% to 24.5% without optimization. This strategy facilitates multiple reads of individual strands and is transferable to other nanopore devices for implementation of DNA sequence analysis.

Published

2012

17. Distinct complexes of DNA polymerase I (Klenow fragment) for base and sugar discrimination during nucleotide substrate selection.

Author

Garalde DR, Simon CA, Dahl JM, Wang H, Akeson M, and Lieberman KR

Subjects

Algorithms, Biophysics methods, DNA chemistry, DNA Polymerase I metabolism, Electrophysiology, Escherichia coli enzymology, Fluorescence Resonance Energy Transfer methods, Kinetics, Models, Statistical, Nanotechnology methods, Nucleotides chemistry, Oligonucleotides chemistry, Protein Binding, Substrate Specificity, DNA Polymerase I chemistry, Nanopores

Abstract

During each catalytic cycle, DNA polymerases select deoxyribonucleoside triphosphate (dNTP) substrates complementary to a templating base with high fidelity from a pool that includes noncomplementary dNTPs and both complementary and noncomplementary ribonucleoside triphosphates (rNTPs). The Klenow fragment of Escherichia coli DNA polymerase I (KF) achieves this through a series of conformational transitions that precede the chemical step of phosphodiester bond formation. Kinetic evidence from fluorescence and FRET experiments indicates that discrimination of the base and sugar moieties of the incoming nucleotide occurs in distinct, sequential steps during the selection pathway. Here we show that KF-DNA complexes formed with complementary rNTPs or with noncomplementary nucleotides can be distinguished on the basis of their properties when captured in an electric field atop the α-hemolysin nanopore. The average nanopore dwell time of KF-DNA complexes increased as a function of complementary rNTP concentration. The increase was less than that promoted by complementary dNTP, indicating that the rNTP complexes are more stable than KF-DNA binary complexes but less stable than KF-DNA-dNTP ternary complexes. KF-DNA-rNTP complexes could also be distinguished from KF-DNA-dNTP complexes on the basis of ionic current amplitude. In contrast to complementary rNTPs, noncomplementary dNTPs and rNTPs diminished the average nanopore dwell time of KF-DNA complexes in a concentration-dependent manner, suggesting that binding of a noncomplementary nucleotide keeps the KF-DNA complex in a less stable state. These results imply that nucleotide selection proceeds through a series of complexes of increasing stability in which substrates with the correct moiety promote the forward transitions.

Published

2011

18. Processive replication of single DNA molecules in a nanopore catalyzed by phi29 DNA polymerase.

Author

Lieberman KR, Cherf GM, Doody MJ, Olasagasti F, Kolodji Y, and Akeson M

Subjects

Catalysis, DNA Replication, Models, Biological, Substrate Specificity, DNA-Directed DNA Polymerase chemistry, Nanopores, Viral Proteins chemistry

Abstract

Coupling nucleic acid processing enzymes to nanoscale pores allows controlled movement of individual DNA or RNA strands that is reported as an ionic current/time series. Hundreds of individual enzyme complexes can be examined in single-file order at high bandwidth and spatial resolution. The bacteriophage phi29 DNA polymerase (phi29 DNAP) is an attractive candidate for this technology, due to its remarkable processivity and high affinity for DNA substrates. Here we show that phi29 DNAP-DNA complexes are stable when captured in an electric field across the α-hemolysin nanopore. DNA substrates were activated for replication at the nanopore orifice by exploiting the 3'-5' exonuclease activity of wild-type phi29 DNAP to excise a 3'-H terminal residue, yielding a primer strand 3'-OH. In the presence of deoxynucleoside triphosphates, DNA synthesis was initiated, allowing real-time detection of numerous sequential nucleotide additions that was limited only by DNA template length. Translocation of phi29 DNAP along DNA substrates was observed in real time at Ångstrom-scale precision as the template strand was drawn through the nanopore lumen during replication.

Published

2010

19. Replication of individual DNA molecules under electronic control using a protein nanopore.

Author

Olasagasti F, Lieberman KR, Benner S, Cherf GM, Dahl JM, Deamer DW, and Akeson M

Subjects

Bacterial Proteins, DNA chemistry, DNA Polymerase I chemistry, DNA Polymerase I metabolism, DNA-Directed DNA Polymerase chemistry, DNA-Directed DNA Polymerase metabolism, Electromagnetic Fields, Hemolysin Proteins chemistry, Models, Molecular, Oligonucleotides chemistry, Oligonucleotides metabolism, DNA metabolism, DNA Replication, Electrophoresis, Nanopores, Nanotechnology methods

Abstract

Nanopores can be used to analyse DNA by monitoring ion currents as individual strands are captured and driven through the pore in single file by an applied voltage. Here, we show that serial replication of individual DNA templates can be achieved by DNA polymerases held at the α-haemolysin nanopore orifice. Replication is blocked in the bulk phase, and is initiated only after the DNA is captured by the nanopore. We used this method, in concert with active voltage control, to observe DNA replication catalysed by bacteriophage T7 DNA polymerase (T7DNAP) and by the Klenow fragment of DNA polymerase I (KF). T7DNAP advanced on a DNA template against an 80-mV load applied across the nanopore, and single nucleotide additions were measured on the millisecond timescale for hundreds of individual DNA molecules in series. Replication by KF was not observed when this enzyme was held on top of the nanopore orifice at an applied potential of 80 mV. Sequential nucleotide additions by KF were observed upon applying controlled voltage reversals.

Published

2010