Chemisry

DNA sequencing by synthesis (SBS) offers a robust platform to decipher nucleic acid sequences. Recently, we reported a single-molecule nanopore-based SBS strategy that accurately distinguishes four bases by electronically detecting and differentiating four different polymer tags attached to the 5′-phosphate of the nucleotides during their incorporation into a growing DNA strand catalyzed by DNA po-lymerase. Further developing this approach, we report here the use of nucleotides tagged at the terminal phosphate with oligonucleotide-based polymers to perform nanopore SBS on an α-hemolysin nanopore array platform. We designed and synthesized several polymer-tagged nucleotides using tags that produce different electrical current blockade levels and verified they are active sub-strates for DNA polymerase. A highly processive DNA polymerase was conjugated to the nanopore, and the conjugates were com-plexed with primer/template DNA and inserted into lipid bilayers over individually addressable electrodes of the nanopore chip. When an incoming complementary-tagged nucleotide forms a tight ternary complex with the primer/template and polymerase, the tag enters the pore, and the current blockade level is measured. The levels displayed by the four nucleotides tagged with four different polymers captured in the nanopore in such ternary complexes were clearly dis-tinguishable and sequence-specific, enabling continuous sequence determination during the polymerase reaction. Thus, real-time single-molecule electronic DNA sequencing data with single-base resolution were obtained. The use of these polymer-tagged nucleotides, combined with polymerase tethering to nanopores and multiplexed nanopore sensors, should lead to new high-throughput sequencing methods. single-molecule sequencing | nanopore | DNA sequencing by synthesis | polymer-tagged nucleotides | chip array T he importance of DNA sequencing has increased dramatically from its inception four decades ago. It is recognized as a crucial technology for most areas of biology and medicine and as the underpinning for the new paradigm of personalized and precision medicine. Information on individuals' genomes and epigenomes can help reveal their propensity for disease, clinical prognosis, and response to therapeutics, but routine application of genome se-quencing in medicine will require comprehensive data delivered in a timely and cost-effective manner (1). Although 35 years of technological advances have improved sequence throughput and have reduced costs exponentially, genome analysis still takes several days and thousands of dollars to complete (1, 2). To realize the potential of personalized medicine fully, the speed and cost of sequencing must be brought down another order of magnitude while increasing sequencing accuracy and read length. Single-molecule approaches are thought to be essential to meet these requirements and offer the additional benefit of eliminating amplification bias (3, 4). Although optical methods for single-molecule sequencing have been achieved and commercialized, the most successful, Pacific Biosciences' single molecule real-time (SMRT) sequencing by synthesis (SBS) approach, requires expensive instrumentation and the use of fluorescently tagged nucleotides (4, 5). In the last two decades, there has been great interest in taking advantage of nanopores, naturally occurring or solid-state ion channels, for polymer characterization and distinguishing the bases of DNA in a low-cost, rapid, single-molecule manner (6–9). Three nanopore sequencing approaches have been pursued: strand se-quencing in which the bases of DNA are identified as they pass sequentially through a nanopore (6, 7), exonuclease-based nanopore Significance Efficient cost-effective single-molecule sequencing platforms will facilitate deciphering complete genome sequences, determining haplotypes, and identifying alternatively spliced mRNAs. We demonstrate a single-molecule nanopore-based sequencing by synthesis approach that accurately distinguishes four DNA bases by electronically detecting and differentiating four different polymer tags attached to the terminal phosphate of the nucleotides during their incorporation into a growing DNA strand in the polymerase reaction. With nanopore detection, the distinct polymer tags are much easier to differentiate than natural nucleotides. After tag release, growing DNA chains consist of natural nucleotides allowing long reads. Sequencing is realized on an electronic chip containing an array of independently addressable electrodes, each with a single polymerase–nanopore complex, potentially offering the high throughput required for precision medicine.