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Single-molecule real-time sequencing

Single-molecule real-time (SMRT) sequencing is a third-generation DNA sequencing technology developed by Pacific Biosciences that enables the real-time monitoring of individual DNA polymerase molecules as they incorporate fluorescently labeled nucleotides into a growing DNA strand within nanoscale zero-mode waveguides (ZMWs), generating long continuous reads typically averaging 10–16 kb in length. This method, introduced in 2009, operates without PCR amplification, thereby avoiding associated biases and allowing direct detection of epigenetic modifications like DNA methylation through variations in polymerase kinetics. By confining the reaction to the observation volume of ZMWs on a chip called a SMRT Cell, which contains thousands of parallel sequencing sites, SMRT sequencing achieves high-throughput analysis of single molecules, producing raw reads with an error rate of 11–15% that can be corrected to over 99% accuracy via circular consensus sequencing (CCS) using SMRTbell adapters. The core principle of SMRT sequencing relies on sequencing-by-synthesis, where a DNA polymerase bound to a template in a ZMW incorporates phospholinked , each labeled with a distinct that is excited and detected only when the nucleotide is held in the detection zone, followed by cleavage of the fluorophore for continuous . This detection captures the natural of , including interpulse durations between nucleotide incorporations, which reveal base modifications without additional enzymatic treatments. Over time, the has evolved from the original PacBio RS system to advanced platforms like the and Revio systems, increasing read lengths up to 20 kb or more, throughput to millions of reads per run, and applications in . Key advantages of SMRT sequencing over second-generation methods, such as Illumina's short-read platforms, include its ability to span repetitive genomic regions, resolve structural variants, haplotype phasing, and full-length transcript isoform identification, making it particularly valuable for complex genomes like those of humans or . Despite higher per-base costs and initial error rates, the long reads reduce the need for extensive computational and enable comprehensive epigenetic profiling in a single experiment. Applications span constitutional genetics for diagnosing disorders like , reproductive genomics for preimplantation testing, oncology for detecting fusion genes in cancers such as , and for microbial community analysis, including full viral genomes like and HCV. Recent advancements, including high-fidelity (HiFi) reads combining long length with Q20+ accuracy, have further expanded its utility in population-scale sequencing projects and .

Overview

Core principles

Single-molecule real-time (SMRT) sequencing is a third-generation DNA sequencing technology that enables the direct observation of DNA synthesis by a single molecule, allowing for the identification of incorporated in without the need for . At its core, the method relies on polymerase-mediated, template-directed synthesis, where a highly processive incorporates deoxyribonucleoside triphosphates (dNTPs) into a growing DNA strand complementary to the immobilized template. This process mimics natural but is monitored continuously to capture the temporal sequence of base additions, producing long reads that can span thousands of bases. The key innovation in SMRT sequencing lies in the use of fluorescently labeled, phospholinked nucleotides, which consist of four distinct dNTPs (dATP, dCTP, dGTP, dTTP) each conjugated to a different fluorophore attached to the terminal (γ) phosphate. Upon binding to the polymerase active site and incorporation into the DNA strand, the phospholinked fluorophore is cleaved and released, generating a brief burst of fluorescence specific to the nucleotide type. This reversible termination is avoided by the phosphate linkage, which minimizes steric hindrance and allows uninterrupted synthesis, enabling continuous sequencing-by-synthesis at the single-molecule level. The distinct emission spectra of the fluorophores permit real-time base calling by distinguishing the color and timing of each incorporation event. In the basic workflow, a single-stranded DNA template is immobilized at the bottom of a confined volume, such as a zero-mode waveguide, to isolate the reaction and reduce background from unbound . A is then bound to the template, and the phospholinked are provided in the reaction mixture, where synthesis proceeds under constant illumination and imaging. The pulses are detected and recorded over time, yielding raw sequence data that reflects the natural kinetics of polymerization, including potential insights into pauses or secondary structures.

Key advantages and limitations

Single-molecule real-time (SMRT) sequencing offers several key advantages over traditional short-read sequencing technologies. One primary benefit is its ability to generate long reads, with high-fidelity (HiFi) reads typically 15,000 to 20,000 base pairs in length (up to 25,000 base pairs), enabling the resolution of complex genomic regions such as repetitive sequences and structural variants that are challenging for short-read methods. Additionally, SMRT sequencing facilitates direct detection of epigenetic modifications, such as (5mC) in CpG contexts, by analyzing kinetic variations in activity during native , eliminating the need for conversion and preserving modification information without amplification artifacts. Despite these strengths, SMRT sequencing has notable limitations. Raw reads exhibit higher error rates of 11–15%, primarily due to random insertions, deletions, and substitutions, necessitating computational corrections or deeper coverage for reliable results. Throughput, while improved, remains lower compared to short-read platforms, producing up to 120 billion bases (120 ) per SMRT Cell on the Revio system as of 2024. Historically, per-base costs were higher (e.g., $0.40–$0.80 per million bases in the mid-2010s), but improvements in instrumentation like the Revio have reduced this to approximately $0.004 per million bases as of 2024. In comparison to short-read sequencing platforms like Illumina, SMRT excels in applications requiring the spanning of repeats and accurate identification of structural variants, where long reads provide superior contiguity and phasing. However, it lags in overall speed and scale for routine single-nucleotide variant calling in simple genomes, where short-read methods offer faster turnaround and higher data output at lower costs. Accuracy in SMRT sequencing has been significantly improved through circular consensus sequencing, where the polymerase performs multiple passes over a circularized DNA template to generate HiFi reads with over 99% accuracy, balancing length and precision for downstream analyses.

Technology

Template preparation

Template preparation for single-molecule real-time (SMRT) sequencing involves creating specialized SMRTbell libraries, which are circularized DNA templates designed to enable continuous polymerase-mediated synthesis and multiple passes over the same molecule for high-accuracy reads. The process emphasizes minimal bias and preservation of native DNA features, starting with high-molecular-weight input DNA that is fragmented into long inserts, typically 10-20 kb, to support extended read lengths. This preparation is distinct from amplification-based methods used in other sequencing technologies, as it relies on direct ligation without PCR to maintain epigenetic modifications and sequence integrity. The initial step is DNA fragmentation, achieved through mechanical shearing to generate fragments in the desired size range. Common methods include using the Covaris g-TUBE or Megaruptor 3 systems, with protocols targeting a size distribution mode of 15-20 kb for applications like de novo assembly, ensuring fragments remain double-stranded and suitable for downstream ligation. For example, shearing 5 μg of genomic DNA at 83.3 ng/μL in elution buffer with a two-cycle process on the Megaruptor 3 yields fragments optimized for long-insert libraries. Following fragmentation, end repair and A-tailing prepare the blunt ends for adapter attachment, minimizing damage and bias. Hairpin adapter ligation forms the core of SMRTbell template creation, where phosphorylated single-stranded adapters are ligated to both ends of the double-stranded DNA insert, resulting in a dumbbell-shaped with single-stranded hairpins flanking the insert. This circularization allows to bind the hairpins and repeatedly traverse the insert during sequencing, enabling consensus generation from multiple subreads. The ligation reaction typically uses a T4 master mix at 20°C for 1 hour, with a 32.5-fold excess of adapters (e.g., 0.5 μM concentration) to ensure efficient joining, followed by treatment to remove unligated linear molecules. Size selection is critical to enrich for long inserts and remove short fragments or adapters, favoring molecules in the 10-20 range to maximize read length and yield. Automated systems like the BluePippin or PippinHT are preferred, using gel cassettes with size cutoffs (e.g., 10-50 ) to isolate target fragments, achieving recoveries of 20-50% depending on input quality. Alternatively, followed by extraction can be employed for manual size selection, particularly for inserts around 15-18 in high-fidelity (HiFi) library preparations. Multiple AMPure PB bead cleanups (0.40X-0.45X ratios) further refine the library by removing small products below 1.5 . To preserve native base modifications such as methylation, the entire workflow avoids PCR amplification, which could introduce biases or alter epigenetic marks; instead, it uses low-bias mechanical shearing and direct ligation methods that maintain the original DNA composition. This approach requires high-quality, high-molecular-weight input to achieve sufficient library yield without enzymatic bias. Quantification via fluorometric methods like Qubit or PicoGreen is essential post-preparation; for size analysis, concentrations should be below 60 ng/μL, and loading concentrations are calculated in pM (e.g., 25-50 pM) using the Binding Calculator based on insert size. Preparation protocols vary by input type to accommodate different starting materials while adhering to concentration guidelines of 1-5 μg total DNA for most libraries. For genomic DNA, 5 μg of high-molecular-weight (>50 kb) material is recommended, sheared to 10-20 kb for whole-genome sequencing. Plasmid DNA follows similar shearing and ligation but benefits from validated protocols for large inserts up to 20 kb. Amplicons, typically >250 bp and derived from PCR-free sources when possible, require end repair if damaged and size selection to match sheared fragment distributions, with inputs of 1-2.4 μg for 5-10 kb targets. Across all types, gentle handling—avoiding vortexing, excessive heat, or freeze-thaw cycles—is crucial to prevent degradation. Current protocols, such as SMRTbell Prep Kit 3.0 (as of 2025), streamline these steps for higher efficiency.

Phospholinked nucleotides

In single-molecule real-time (SMRT) sequencing, phospholinked nucleotides serve as the core reagents for real-time base detection during DNA synthesis. These are synthetic deoxynucleoside triphosphates (dNTPs) modified such that a fluorescent dye is covalently attached to the γ-phosphate (terminal phosphate) of the triphosphate chain via a short linker, typically an aminohexyl group, rather than to the nucleobase. This phosphate-linked design minimizes steric interference with base pairing and hydrogen bonding in the polymerase active site, allowing natural incorporation into the growing DNA strand. Upon incorporation, the DNA polymerase cleaves the α-β phosphodiester bond, releasing pyrophosphate conjugated to the fluorophore and linker, thereby producing an unmodified phosphodiester backbone in the synthesized DNA. Each of the four canonical —A, C, G, and T—is labeled with a distinct , such as derivatives, emitting unique wavelengths (e.g., green for T, yellow for C, red for A, and orange for G). This color-coding enables direct identification of the incorporated base from the emitted light pulse. Critically, the remains quenched until the binds in the , where it is held for milliseconds during incorporation, producing a detectable pulse; unbound diffuse rapidly, yielding only brief, low-intensity signals that are filtered out. This transient signaling allows continuous, monitoring of without pausing for washing or deblocking steps, distinguishing SMRT from other sequencing-by-synthesis methods. The from these is observed within zero-mode waveguides to confine the excitation volume for single-molecule resolution. SMRT sequencing relies on engineered variants of the φ29 DNA polymerase, a family B known for its exceptional processivity (synthesizing tens of kilobases without dissociating) and low error rate (approximately 10⁻⁵ to 10⁻⁶). Wild-type φ29 tolerates some modifications, but proprietary mutants developed by enhance compatibility with phospholinked labels by reducing sensitivity to the added bulk and charge on the chain, while preserving high synthesis rates (up to 100 bases per second). These modifications, including mutations in the thumb and domains, improve incorporation kinetics and overall sequencing yield. The chemistry of phospholinked has evolved to boost performance and simplify calling. Initial implementations on early PacBio systems employed two-color schemes, where pairs of shared fluorophores and were distinguished by pulse characteristics like duration or intensity. Later advancements, such as the P6-C4 chemistry introduced in , adopted four independent colors with photo-protected , enabling unambiguous, one-to-one -to-color mapping, higher throughput, and reduced ambiguity in complex sequences. These iterative improvements, including optimized linkers and stability, have enhanced signal-to-noise ratios and fidelity across platform generations. As of 2025, the chemistry has further evolved with SPRQ and the forthcoming SPRQ-Nx, enhancing performance on newer platforms while retaining the phospholinked nucleotide principle.

Zero-mode waveguides

Zero-mode waveguides (ZMWs) represent a foundational nanoscale optical confinement technology in single-molecule real-time (SMRT) sequencing, designed to enable the isolated observation of individual biomolecular reactions amid high-concentration solutions. These structures consist of cylindrical apertures, approximately 100 nm in diameter, etched into a thin metal film—typically aluminum—deposited atop a transparent silica substrate. The subwavelength dimensions of the apertures prevent propagating light modes, generating instead a tightly confined evanescent field that extends only 20–30 nm into the well from the illumination side, thereby restricting the effective observation volume to a diffraction-limited region at the waveguide bottom. In the context of SMRT sequencing, the polymerase-DNA complex is immobilized at the base of each ZMW through a biotin-streptavidin linkage, positioning the within the illuminated volume while excess fluorescently labeled remain excluded from this zone due to the shallow . This selective illumination reduces background from unbound molecules in the bulk solution, allowing detection of nucleotide incorporations as transient color-specific pulses without the need for washing steps or molecular dilution. Such functionality supports physiological reaction conditions and high-throughput parallelization essential for sequencing applications. ZMWs are arrayed at high densities on SMRT cells, with configurations scaling to millions of waveguides per chip; for example, early systems like the RS II featured around 150,000 ZMWs, while the series increased this to one million, and advanced platforms such as the accommodate up to eight million for enhanced data output. The fabrication of ZMWs leverages semiconductor processing techniques to achieve precise, uniform arrays suitable for optical detection. This involves to define the nanopattern on a resist-coated , followed by metal , lift-off, and to form the cladding and open the apertures, ensuring minimal variation in well dimensions across the chip for consistent signal quality.

Signal detection and base calling

In single-molecule real-time (SMRT) sequencing, fluorescence signals generated by the incorporation of phospholinked within zero-mode waveguides (ZMWs) are captured using high-speed complementary metal-oxide-semiconductor () sensors. These sensors image the emission pulses from active ZMWs in , typically at frame rates ranging from 30 to 75 frames per second, enabling parallel monitoring of thousands of sequencing reactions without the need for amplification or washing steps. Base calling in SMRT systems relies on kinetic analysis of the fluorescence pulses to determine the sequence of incorporated nucleotides. Key parameters include pulse width (duration of the fluorescence signal), brightness (intensity of the emitted light), and interpulse duration (time between consecutive pulses), which reflect the polymerase's incorporation kinetics and help distinguish bases. Initial base calling is performed using proprietary software such as SMRT Link, which processes raw movie files to generate subreads. High-fidelity (HiFi) reads are produced through circular sequencing (CCS), where the repeatedly traverses the circular SMRTbell template, yielding multiple subreads (typically 20-30x coverage) from the same molecule. These subreads are aligned and consensus-corrected using algorithms like those in the CCS tool (v3.0.0 or later), resulting in reads with predicted accuracies exceeding Q30 (99.9% per base). Errors in raw subreads often arise from stalling (prolonged interpulse durations) or misincorporation events, particularly in homopolymeric regions or near base modifications. These are mitigated during HiFi generation by models, such as DeepConsensus, which leverage neural networks to refine calls and improve accuracy beyond traditional methods.

Platforms and evolution

Early systems (RS and RS II)

The PacBio RS, the inaugural commercial platform for single-molecule real-time (SMRT) sequencing, was introduced in late 2010 as a beta system, with full commercialization following in 2011. It utilized SMRT Cells containing approximately 75,000 zero-mode waveguides (ZMWs) to enable parallel sequencing of individual DNA molecules. With the initial C1 chemistry, the system produced average read lengths of around 1,500 base pairs, emphasizing proof-of-concept demonstrations for de novo genome assembly using long reads to resolve repetitive regions that challenged short-read technologies. In April 2013, Pacific Biosciences released the upgraded PacBio RS II system, which doubled the active ZMWs to 150,000 per SMRT Cell, enhancing parallelization and overall throughput. The RS II incorporated an improved and introduced the P4-C2 chemistry, yielding average read lengths exceeding 5,000 base pairs and enabling the generation of reads up to 10 or longer in many cases. These advancements supported more efficient sequencing of complex genomes, with typical run times of 2-3 hours per SMRT Cell and data outputs of 0.75-1.5 Gb per cell. Early milestones with the RS platform included the first hybrid de novo assemblies of bacterial genomes, where long SMRT reads were error-corrected using short-read data to produce high-quality, contiguous assemblies for organisms like . The inherent kinetic signatures in SMRT sequencing also facilitated pioneering epigenetic mapping, allowing direct detection of DNA base modifications such as without conversion, as demonstrated in initial studies on synthetic and bacterial templates.

Sequel series

The Sequel system, introduced by in 2015, represented a significant scale-up in SMRT sequencing capacity compared to prior platforms, featuring SMRT Cells with 1 million zero-mode waveguides (ZMWs) to enable higher throughput through diffusion-based loading of complexes. This design supported chemistry versions from v2 to v4, allowing for extended movie acquisition times of up to 10 hours, which facilitated the generation of longer subreads typically ranging from 10 to 18 kb in mean length. Typical output per run reached approximately 5-10 Gb of raw data, making it suitable for targeted genomic applications and assembly projects requiring moderate coverage. Building on this foundation, the Sequel II system, launched in 2019, incorporated enhanced optics and onboard computing to process denser arrays, utilizing SMRT 8M technology with 8 million ZMWs and approximately 1 million active ZMWs per cell for improved signal detection efficiency. This upgrade standardized the production of highly accurate circular consensus (HiFi) reads, achieving >99% accuracy through multiple passes over SMRTbell templates, and delivered up to 100 Gb of HiFi output per SMRT Cell in optimized runs. The system's integration of advanced reagent kits and software enabled flexible run times of 12 to 30 hours, supporting diverse library types while reducing overall project costs by approximately eightfold relative to earlier generations. In 2021, released the IIe as a cost-optimized variant of the II, maintaining comparable performance metrics including 8 million ZMWs and HiFi yields of up to 100 Gb per SMRT Cell, but with streamlined hardware to lower acquisition and operational expenses for labs. Key innovations across the series included on-instrument processing capabilities, such as direct generation of HiFi reads via circular consensus sequencing algorithms, which increased by minimizing post-run computational demands and enabling higher loading utilization. Additionally, seamless integration with SMRT Link software version 10 and later provided end-to-end workflow management, from run monitoring to automated base calling and variant detection, enhancing accessibility for broader scientific adoption.

Revio and recent advancements

The Revio system, launched by PacBio in , represents a significant leap in single-molecule real-time (SMRT) sequencing , featuring high-density SMRT cells with 25 million zero-mode waveguides (ZMWs) per cell and the capacity to process up to four cells in parallel for a total of 100 million ZMWs. This configuration, combined with SPRQ chemistry and enhanced adaptive loading protocols that optimize immobilization efficiency, enables outputs of up to 480 Gb of high-fidelity (HiFi) data per run, with typical HiFi read lengths surpassing 20 kb to support comprehensive and variant detection. Improved loading strategies reduce variability in ZMW occupancy, ensuring more consistent utilization across the cell surface, which is critical for high-throughput applications like population-scale . In 2025, the Sequel II CNDx variant advanced clinical adoption by securing Class III medical device approval from China's (NMPA) through a with Berry Genomics, marking the world's first regulatory clearance for a long-read sequencer in clinical diagnostics. This approval, paired with Berry Genomics' assay, enables end-to-end detection of single-nucleotide variants, insertions/deletions, and structural variants in a single test, emphasizing regulatory pathways tailored to long-read technologies for diseases requiring precise genomic characterization. PacBio's roadmap, outlined for 2025 and beyond, focuses on fabricating ultra-high-density SMRT cells using 300 mm wafers to achieve petabase-scale throughput, potentially enabling sub-$300 sequencing through reusable cells and multi-run capabilities per cell. This initiative builds on nanofabrication advances to increase ZMW density beyond current levels, supporting massive cohort studies; for instance, recent publications from the Research Program have leveraged HiFi sequencing to identify millions of structural variants across diverse populations, revealing novel disease associations previously obscured by short-read methods. In 2024, PacBio introduced the benchtop system, a compact platform designed for smaller labs, delivering up to 60 Gb of HiFi data per run with read lengths of 15-20 kb, powered by SMRT technology and supporting flexible run times including rapid modes for targeted applications. Recent advancements in SMRT sequencing include AI-driven base calling via DeepConsensus, a transformer-based model that corrects raw subreads by modeling gaps and alignments, reducing error rates by over 40% compared to prior consensus methods and boosting Q30+ HiFi yield. Complementary innovations in chemistry, such as SPRQ-Nx, enable two- to four-hour run times for select high-speed modes optimized for shorter inserts or targeted sequencing on the system, enhancing workflow efficiency in time-sensitive clinical and research settings.

Performance characteristics

Read length and accuracy

In single-molecule real-time (SMRT) sequencing, raw subreads typically range from 10 to 20 in length, reflecting the processive synthesis by the on linear templates before stalling or dissociation. These subread lengths enable initial capture of repetitive genomic regions, though individual subreads alone are insufficient for resolving structures exceeding 10 due to fragmentation and errors. High-fidelity (HiFi) reads, generated through circular sequencing (CCS) of SMRTbell templates, achieve average lengths of 15 to 25 kb, allowing reliable spanning of repeats larger than 10 kb and facilitating assembly of complex genomes. The template circularization via hairpin adapters permits multiple passes of the over the same , typically 10 to 20 iterations, yielding a that combines subread data for enhanced length and reliability. Raw subread accuracy is approximately 90% (equivalent to a Q10 Phred score), characterized by random insertion-deletion and substitution errors arising from polymerase kinetics and signal noise. In contrast, HiFi reads exceed 99.9% accuracy (Q30 or higher), rivaling short-read and Sanger sequencing, through the averaging of multiple subreads in CCS; this represents a substantial improvement over unpolished raw PacBio assemblies, where error correction via short-read polishing is often required for comparable precision. Key factors influencing these metrics include the high processivity of engineered DNA polymerases, such as variants of Phi29, which sustain synthesis for tens of kilobases, and the circular template design that enables repeated traversal without reloading. Consensus accuracy in HiFi sequencing follows an exponential decay model for error rate, approximated as \epsilon \approx e^{-n}, where n is the coverage depth from subread passes (e.g., 20x depth achieves Q20+ or better, with errors reduced by orders of magnitude). Recent benchmarks as of 2025 demonstrate HiFi reads' utility in full human genome phasing, as evidenced by the All of Us Research Program's analysis of diverse cohorts, where HiFi reads enabled haplotype-resolved variant detection across challenging regions like segmental duplications.

Throughput and cost efficiency

Single-molecule real-time (SMRT) sequencing platforms have demonstrated substantial improvements in throughput over successive generations, enabling larger-scale genomic projects. The early PacBio RS system typically yielded approximately 1 Gb per run using a single SMRT cell with 75,000 zero-mode waveguides (ZMWs). Subsequent upgrades in the RS II increased this to around 5 Gb per run through enhanced chemistry and polymerase efficiency, while the Sequel system further scaled output to 5-8 Gb per SMRT cell by expanding ZMW density to 1 million. The Sequel II platform advanced this to 50-60 Gb per run with a single SMRT cell, and the current Revio system achieves 100-120 Gb per SMRT cell, supporting up to 480 Gb per run across four cells in 24-hour operations. Projections for future high-throughput systems in development anticipate exceeding 1 Tb per run by leveraging higher ZMW densities and optimized multi-use SMRT cells to approach short-read scale, as discussed in 2025 R&D presentations. Cost efficiency in SMRT sequencing has declined dramatically from early systems, where costs exceeded $1 per Gb due to limited yields and higher reagent demands, to approximately $0.01-0.05 per Gb for high-fidelity (HiFi) reads as of November 2025 on the Revio platform with SPRQ chemistry. In October 2025, PacBio announced the SPRQ-Nx chemistry for Revio, enabling multiple runs per SMRT cell and further reducing costs, with beta testing beginning in November 2025 and full availability in 2026; this supports sub-$300 whole human genomes at 20x coverage at scale. Key factors include SMRT cell pricing, which ranges from $1,000 to $2,000 per cell, and overall run consumables costing around $1,500-1,800 for a full Revio setup. These reductions stem from increased output per cell and reusable designs in newer chemistries like SPRQ-Nx. Operational efficiency metrics further enhance SMRT sequencing's viability, with Revio achieving over 50% utilization across active ZMWs through adaptive loading protocols that optimize distribution. Run times vary from 2-10 hours in early systems to 12-30 hours on Revio, balancing yield with minimal hands-on intervention. Compared to short-read technologies, SMRT remains more expensive for uniform high-coverage applications but offers superior cost-effectiveness for complex genomes requiring long reads to resolve structural variants and repetitive regions.

Applications

Genomics and structural variant detection

Single-molecule real-time (SMRT) sequencing has revolutionized de novo genome assembly by producing long, high-fidelity reads that span repetitive regions, enabling the construction of highly contiguous assemblies. In bacterial genomes, SMRT sequencing facilitates non-hybrid de novo assemblies from a single long-insert library, achieving contig N50 values exceeding 10 Mb and closing gaps that short-read methods cannot resolve. For instance, hybrid approaches combining SMRT reads with short-read data have produced complete, closed bacterial genomes from complex microbiomes, demonstrating the technology's ability to resolve circular chromosomes and plasmids without manual intervention. In human genomes, SMRT sequencing supports the generation of chromosome-scale assemblies, with contig N50s reaching hundreds of megabases, which is essential for capturing structural complexity missed by fragmented short-read assemblies. A key strength of SMRT sequencing in lies in its capacity for haplotype phasing, which separates maternal and paternal copies to reveal inherited genetic variations. By leveraging circular sequencing to produce high-fidelity (HiFi) reads up to 20 in length, SMRT enables fully phased assemblies without parental data, achieving over 99% phasing accuracy across the . This approach has been used to phase multi-kilobase regions in de novo assemblies, providing insights into compound heterozygosity and rare variants that influence disease risk. In diploid genomes, SMRT-based phasing outperforms short-read methods by resolving heterozygous variants in repetitive contexts, such as segmental duplications, with minimal error rates. SMRT sequencing excels in detecting structural variants (SVs), including insertions and deletions larger than 50 bp, inversions, and translocations, by aligning long reads across breakpoints that short-read technologies fragment. These variants, which account for a significant portion of genetic diversity, are identified with high sensitivity using SMRT's ability to span entire SV events in a single read, reducing false positives from alignment artifacts. For example, SMRT has resolved complex SVs in clinical samples, such as large deletions associated with genetic disorders, by providing full-length sequence context. In population studies, HiFi reads from SMRT sequencing have improved SV calling accuracy to over 95% for events up to megabases in size, enabling the cataloging of novel rearrangements. The 2025 All of Us Research Program analysis exemplifies SMRT's impact on large-scale SV discovery, where HiFi sequencing of over 200 diverse samples identified 273 novel SVs not captured in short-read data, including population-specific insertions and translocations overlapping hundreds of medically relevant genes. This population-scale effort highlighted SMRT's role in uncovering underrepresented variants in non-European ancestries. Such findings underscore SMRT's utility in equitable , revealing SVs linked to health disparities. SMRT sequencing addresses longstanding challenges in repeat resolution, particularly for tandem repeats and centromeric regions that confound short-read assemblies. Long HiFi reads traverse expansive repetitive arrays, phasing alleles through highly identical sequences like alpha satellites in centromeres, which span megabases. For centromeres, SMRT has enabled the complete of higher-order repeat structures, revealing evolutionary variations across populations that were previously inaccessible. This resolution extends to tandem repeats exceeding 100 kb, where SMRT accurately reconstructs unit copy numbers and orientations, filling gaps in reference genomes. In human pangenome projects, SMRT sequencing with HiFi reads has been instrumental for assembling diverse haplotypes from underrepresented populations, creating non-linear references that better represent global . The Human Pangenome Reference Consortium's efforts utilized SMRT to produce 94 phased haplotypes from 47 individuals, achieving contig N50s over 25 Mb and incorporating SVs from diverse ancestries. Recent initiatives, such as the first human pangenome and South Korea's national pangenome, relied on SMRT for resolving population-specific repeats and SVs, enhancing variant interpretation in precision medicine. These projects demonstrate SMRT's scalability for inclusive genomic references.

Epigenetics and methylation analysis

Single-molecule real-time (SMRT) sequencing enables direct detection of epigenetic modifications by monitoring alterations in DNA polymerase kinetics during base incorporation. Modified bases, such as 5-methylcytosine (5mC), induce delays in the polymerase progression, which are quantified through interpulse duration (IPD) ratios—the time intervals between consecutive fluorescence pulses corresponding to nucleotide incorporations. For instance, 5mC typically slows incorporation rates, resulting in elevated IPD values at the modified site and often at positions up to six bases downstream, allowing inference of modification status without bisulfite conversion or other chemical treatments. SMRT sequencing covers a range of epigenetic marks, including N6-methyladenine (6mA), 5mC, and (5hmC), by analyzing these kinetic signatures integrated with sequence data. Detection accuracy exceeds 90% for CpG sites when using high-fidelity circular consensus sequencing () reads, particularly with deep learning-based models that deconvolute subtle kinetic variations in complex eukaryotic genomes. This approach benefits from the platform's ability to generate long reads, providing single-molecule resolution and phasing of modifications over extended genomic regions. In applications, SMRT sequencing has facilitated genome-wide methylation mapping in eukaryotes and comprehensive profiling of bacterial epigenomes, revealing motifs like 5'-GGCC-3' for 5mC in microbial genomes. Tools such as PacBio's pbccs software perform kinetic variant calling by computing IPD ratios alongside consensus sequences, enabling integrated epigenetic and genomic analysis. Recent 2025 advancements, including licensed models, enhance detection of 5hmC, hemimethylation, and 6mA during standard HiFi runs, supporting studies on disease-associated like those in hemoglobinopathies.

Clinical and diagnostic uses

Single-molecule real-time (SMRT) sequencing has emerged as a valuable in prenatal and carrier screening, particularly for detecting complex hemoglobinopathies such as and . In a 2025 population-based screening initiative in , , SMRT sequencing enabled the identification of rare like Hb O-Arab and Hb D-Punjab through high-fidelity long reads, facilitating preconception detection and reducing the risk of affected in high-prevalence regions. Similarly, targeted long-read SMRT approaches have been applied in preimplantation for α-thalassemia, allowing simultaneous detection of deletions and point mutations in a single reaction without requiring samples, as demonstrated in a July 2025 study. These applications leverage SMRT's ability to resolve repeat expansions and structural variants that short-read methods often miss, improving diagnostic accuracy in prenatal diagnostics. In oncology, SMRT sequencing supports the analysis of tumor structural variants (SVs) and patterns, enhancing liquid biopsy capabilities for non-invasive cancer monitoring. Long-read SMRT has enabled the detection of extended cell-free DNA (cfDNA) fragments exceeding 500 base pairs, which are enriched in euchromatic regions and provide insights into tumor heterogeneity and status, as shown in an October 2025 on cfDNA fragmentomics. This approach facilitates direct analysis from plasma samples, aiding in the identification of cancer-specific epigenetic signatures and predicting responses by resolving complex SVs that influence expression. For instance, PacBio's HiFi sequencing, with its >99% accuracy, has been integrated into cancer workflows to detect rare variants in liquid biopsies with high , supporting personalized decisions. A key regulatory milestone occurred in November 2025 when China's (NMPA) granted Class III medical device approval to the Sequel II CNDx system, developed by Berry Genomics in partnership with PacBio, marking the world's first clinical approval for long-read SMRT sequencing. This approval specifically validates HiFi-based testing, enabling routine clinical use for diagnostics and paving the way for broader adoption of SMRT in precision medicine across . Despite these advances, clinical implementation of SMRT sequencing faces challenges in standardization and regulatory compliance, particularly under FDA and CLIA frameworks. A U.S. District Court vacated the FDA's 2024 rule on Laboratory Developed Tests (LDTs) in March 2025, with the FDA rescinding it on September 19, 2025, and reverting to pre-2024 oversight under CLIA without additional phased requirements. Additionally, integration into hybrid workflows combining SMRT long reads with short-read sequencing demands standardized bioinformatics pipelines to ensure reproducibility, as highlighted by ongoing efforts from the (AMP) to modernize CLIA guidelines amid concerns over disrupted access to innovative diagnostics. These hurdles underscore the need for collaborative initiatives to harmonize protocols and demonstrate clinical utility.

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