BACKGROUND Infectious diseases are still one of the greatest threats to human health,and the etiology of 20%of cases of clinical fever is unknown;therefore,rapid identification of pathogens is highly important.Traditi...BACKGROUND Infectious diseases are still one of the greatest threats to human health,and the etiology of 20%of cases of clinical fever is unknown;therefore,rapid identification of pathogens is highly important.Traditional culture methods are only able to detect a limited number of pathogens and are time-consuming;serologic detection has window periods,false-positive and false-negative problems;and nucleic acid molecular detection methods can detect several known pathogens only once.Three-generation nanopore sequencing technology provides new options for identifying pathogens.CASE SUMMARY Case 1:The patient was admitted to the hospital with abdominal pain for three days and cessation of defecation for five days,accompanied by cough and sputum.Nanopore sequencing of the drainage fluid revealed the presence of orallike bacteria,leading to a clinical diagnosis of bronchopleural fistula.Cefoperazone sodium sulbactam treatment was effective.Case 2:The patient was admitted to the hospital with fever and headache,and CT revealed lung inflammation.Antibiotic treatment for Streptococcus pneumoniae,identified through nanopore sequencing of cerebrospinal fluid,was effective.Case 3:The patient was admitted to our hospital with intermittent fever and an enlarged neck mass that had persisted for more than six months.Despite antibacterial treatment,her symptoms worsened.The nanopore sequencing results indicate that voriconazole treatment is effective for Aspergillus brookii.The patient was diagnosed with mixed cell type classical Hodgkin's lymphoma with infection.CONCLUSION Three-generation nanopore sequencing technology allows for rapid and accurate detection of pathogens in human infectious diseases.展开更多
Objective:To surveill emerging variants by nanopore technology-based genome sequencing in different COVID-19 waves in Sri Lanka and to examine the association with the sample characteristics,and vaccination status.Met...Objective:To surveill emerging variants by nanopore technology-based genome sequencing in different COVID-19 waves in Sri Lanka and to examine the association with the sample characteristics,and vaccination status.Methods:The study analyzed 207 RNA positive swab samples received to sequence laboratory during different waves.The N gene cut-off threshold of less than 30 was considered as the major inclusion criteria.Viral RNA was extracted,and elutes were subjected to nanopore sequencing.All the sequencing data were uploaded in the publicly accessible database,GISAID.Results:The Omicron,Delta and Alpha variants accounted for 58%,22%and 4%of the variants throughout the period.Less than 1%were Kappa variant and 16%of the study samples remained unassigned.Omicron variant was circulated among all age groups and in all the provinces.Ct value and variants assigned percentage was 100%in Ct values of 10-15 while only 45%assigned Ct value over 25.Conclusions:The present study examined the emergence,prevalence,and distribution of SARS-CoV-2 variants locally and has shown that nanopore technology-based genome sequencing enables whole genome sequencing in a low resource setting country.展开更多
Infectious diseases are an enormous public health burden and a growing threat to human health worldwide.Emerging or classic recurrent pathogens,or pathogens with resistant traits,challenge our ability to diagnose and ...Infectious diseases are an enormous public health burden and a growing threat to human health worldwide.Emerging or classic recurrent pathogens,or pathogens with resistant traits,challenge our ability to diagnose and control infectious diseases.Nanopore sequencing technology has the potential to enhance our ability to diagnose,interrogate,and track infectious diseases due to the unrestricted read length and system portability.This review focuses on the application of nanopore sequencing technology in the clinical diagnosis of infectious diseases and includes the following:(i)a brief introduction to nanopore sequencing technology and Oxford Nanopore Technologies(ONT)sequencing platforms;(ii)strategies for nanopore-based sequencing technologies;and(iii)applications of nanopore sequencing technology in monitoring emerging pathogenic microorganisms,molecular detection of clinically relevant drug-resistance genes,and characterization of disease-related microbial communities.Finally,we discuss the current challenges,potential opportunities,and future outlook for applying nanopore sequencing technology in the diagnosis of infectious diseases.展开更多
Infectious diseases are a great threat to human health.Rapid and accurate detection of pathogens is important in the diagnosis and treatment of infectious diseases.Metagenomics next-generation sequencing(mNGS)is an un...Infectious diseases are a great threat to human health.Rapid and accurate detection of pathogens is important in the diagnosis and treatment of infectious diseases.Metagenomics next-generation sequencing(mNGS)is an unbiased and comprehensive approach for detecting all RNA and DNA in a sample.With the development of sequencing and bioinformatics technologies,mNGS is moving from research to clinical application,which opens a new avenue for pathogen detection.Numerous studies have revealed good potential for the clinical application of mNGS in infectious diseases,especially in difficult-to-detect,rare,and novel pathogens.However,there are several hurdles in the clinical application of mNGS,such as:(1)lack of universal workflow validation and quality assurance;(2)insensitivity to high-host background and low-biomass samples;and(3)lack of standardized instructions for mass data analysis and report interpretation.Therefore,a complete understanding of this new technology will help promote the clinical application of mNGS to infectious diseases.This review briefly introduces the history of next-generation sequencing,mainstream sequencing platforms,and mNGS workflow,and discusses the clinical applications of mNGS to infectious diseases and its advantages and disadvantages.展开更多
Environmental pollution and the spread of pathogenic microorganisms pose a significant threat to the health of humans and the planet.Thus,understanding and detecting microorganisms is crucial for maintaining a healthy...Environmental pollution and the spread of pathogenic microorganisms pose a significant threat to the health of humans and the planet.Thus,understanding and detecting microorganisms is crucial for maintaining a healthy living environment.Nanopore sequencing is a single-molecule detection method developed in the 1990s that has revolutionized various research fields.It offers several advantages over traditional sequencing methods,including low cost,label-free,time-saving detection speed,long sequencing reading,real-time monitoring,convenient carrying,and other significant advantages.In this review,we summarize the technical principles and characteristics of nanopore sequencing and discuss its applications in amplicon sequencing,metagenome sequencing,and whole-genome sequencing of environmental microorganisms,as well as its in situ application under some special circumstances.We also analyze the advantages and challenges of nanopore sequencing in microbiology research.Overall,nanopore sequencing has the potential to greatly enhance the detection and understanding of microorganisms in environmental research,but further developments are needed to overcome the current challenges.展开更多
Single molecular real-time(SMRT)sequencing,also called third-generation sequencing,is a novel sequencing technique capable of generating extremely long contiguous sequence reads.While conventional short-read sequencin...Single molecular real-time(SMRT)sequencing,also called third-generation sequencing,is a novel sequencing technique capable of generating extremely long contiguous sequence reads.While conventional short-read sequencing cannot evaluate the linkage of nucleotide substitutions distant from one another,SMRT sequencing can directly demonstrate linkage of nucleotide changes over a span of more than 20 kbp,and thus can be applied to directly examine the haplotypes of viruses or bacteria whose genome structures are changing in real time.In addition,an error correction method(circular consensus sequencing)has been established and repeated sequencing of a single-molecule DNA template can result in extremely high accuracy.The advantages of long read sequencing enable accurate determination of the haplotypes of individual viral clones.SMRT sequencing has been applied in various studies of viral genomes including determination of the full-length contiguous genome sequence of hepatitis C virus(HCV),targeted deep sequencing of the HCV NS5A gene,and assessment of heterogeneity among viral populations.Recently,the emergence of multi-drug resistant HCV viruses has become a significant clinical issue and has been also demonstrated using SMRT sequencing.In this review,we introduce the novel third-generation PacBio RSII/Sequel systems,compare them with conventional next-generation sequencers,and summarize previous studies in which SMRT sequencing technology has been applied for HCV genome analysis.We also refer to another long-read sequencing platform,nanopore sequencing technology,and discuss the advantages,limitations and future perspectives in using these thirdgeneration sequencers for HCV genome analysis.展开更多
The DNA sequencing technology has achieved a leapfrog development in recent years. As a new generation of the DNA sequencing technology, nanopore sequenc- ing has shown a broad application prospect and attracted vast ...The DNA sequencing technology has achieved a leapfrog development in recent years. As a new generation of the DNA sequencing technology, nanopore sequenc- ing has shown a broad application prospect and attracted vast research interests since it was proposed. In the present study, the dynamics of the electric-driven translocation of a homopolymer through a nanopore is investigated by the dissipative particle dynam- ics (DPD), in which the homopolymer is modeled as a worm-like chain (WLC). The DPD simulations show that the polymer chain undergoes conformation changes during the translocation process. The different structures of the polymer in the translocation process, i.e., single-file, double folded, and partially folded, and the induced current block- ades are analyzed. It is found that the current blockades have different magnitudes due to the polymer molecules traversing the pore with different folding conformations. The nanoscale vortices caused by the concentration polarization layers (CPLs) in the vicinity of the sheet are also studied. The results indicate that the translocation of the polymer has the effect of eliminating the vortices in the polyelectrolyte solution. These findings are expected to provide the theoretical guide for improving the nanopore sequencing tech- nique.展开更多
The pearl oyster Pinctada fucata martensii is an economically valuable shellfish that is cultured for seawater pearl pro-duction,which mainly depends on oyster growth.However,the growth mechanisms of the pearl oyster ...The pearl oyster Pinctada fucata martensii is an economically valuable shellfish that is cultured for seawater pearl pro-duction,which mainly depends on oyster growth.However,the growth mechanisms of the pearl oyster are still poorly understood.In this study,oysters were grouped with relative growth rate,including fast-growing(FG)group and slow-growing(SG)group.Oxford Nanopore Technologies(ONT)long-read sequencing was applied to investigate the molecular mechanisms involved in the growth of this species.Five alternative splicing(AS)types were analyzed in both FG and SG groups,which include alternative 3’splice site,alternative 5’splice site,exon skipping,intron retention,and mutually exclusive exon.Transcriptome analysis showed that four of five different AS events(excluding mutually exclusive exons)occurred more frequently in FG than in SG oysters,and the five main AS types exhibited different characteristics.The AS events that were detected may be involved in growth,and the difference in ex-pression of AS events between FG and SG oysters may be involved in the mechanism underlying the difference in growth.Fifty dif-ferentially expressed genes(DEGs)were identified between the FG and SG oysters.The results showed that 40 genes were signifi-cantly up-regulated in FG oysters,while 10 genes were significantly down-regulated in SG oyster.Several genes related to nutrient metabolism,shell formation,and immunity were more highly expressed in FG oysters than in SG oysters.In summary,FG oysters exhibited higher metabolic and biomineralization activities and had a more powerful immune system than SG oysters.These results provide insight into the growth of P.f.martensii that can be used to improve breeding programs.展开更多
As one of the most powerful tools in biomedical research,DNA sequencing not only has been improving its productivity at an exponential growth rate but has also been evolving into a new layout of technological territor...As one of the most powerful tools in biomedical research,DNA sequencing not only has been improving its productivity at an exponential growth rate but has also been evolving into a new layout of technological territories toward engineering and physical disciplines over the past three decades.In this technical review,we look into technical characteristics of the next-generation sequencers and provide insights into their future development and applications.We envisage that some of the emerging platforms are capable of supporting the USD1000 genome and USD100 genome goals if given a few years for technical maturation.We also suggest that scientists from China should play an active role in this campaign that will have a profound impact on both scientific research and societal healthcare systems.展开更多
With the rapid development of medicine,the studies of genes have become increasingly concerned by more people and being the contend of a great of researches.The next generation sequencing with its own advantages has b...With the rapid development of medicine,the studies of genes have become increasingly concerned by more people and being the contend of a great of researches.The next generation sequencing with its own advantages has been widely used in gene research nowadays.It has almost replaced the traditional sequencing methods(such as Sanger sequencing method),and played an important role in a variety of complex disease researches,including breast cancer.The next generation sequencing technology has the advantages of high speed,high throughput and high accuracy.It has been widely used in various cancers(such as prostate cancer,lung cancer,pancreatic cancer,liver cancer,etc.),especially in breast cancer.Moreover,the use of the next generation sequencing technology to make DNA sequence analysis and risk prediction has made a great contribution to the research of breast cancer.We will focus on the application of whole genome sequencing,exon sequencing and targeted gene sequencing in breast cancer gene research.展开更多
基金Supported by Research and Development Funding for Medical and Health Institutions,No.2021YL007.
文摘BACKGROUND Infectious diseases are still one of the greatest threats to human health,and the etiology of 20%of cases of clinical fever is unknown;therefore,rapid identification of pathogens is highly important.Traditional culture methods are only able to detect a limited number of pathogens and are time-consuming;serologic detection has window periods,false-positive and false-negative problems;and nucleic acid molecular detection methods can detect several known pathogens only once.Three-generation nanopore sequencing technology provides new options for identifying pathogens.CASE SUMMARY Case 1:The patient was admitted to the hospital with abdominal pain for three days and cessation of defecation for five days,accompanied by cough and sputum.Nanopore sequencing of the drainage fluid revealed the presence of orallike bacteria,leading to a clinical diagnosis of bronchopleural fistula.Cefoperazone sodium sulbactam treatment was effective.Case 2:The patient was admitted to the hospital with fever and headache,and CT revealed lung inflammation.Antibiotic treatment for Streptococcus pneumoniae,identified through nanopore sequencing of cerebrospinal fluid,was effective.Case 3:The patient was admitted to our hospital with intermittent fever and an enlarged neck mass that had persisted for more than six months.Despite antibacterial treatment,her symptoms worsened.The nanopore sequencing results indicate that voriconazole treatment is effective for Aspergillus brookii.The patient was diagnosed with mixed cell type classical Hodgkin's lymphoma with infection.CONCLUSION Three-generation nanopore sequencing technology allows for rapid and accurate detection of pathogens in human infectious diseases.
文摘Objective:To surveill emerging variants by nanopore technology-based genome sequencing in different COVID-19 waves in Sri Lanka and to examine the association with the sample characteristics,and vaccination status.Methods:The study analyzed 207 RNA positive swab samples received to sequence laboratory during different waves.The N gene cut-off threshold of less than 30 was considered as the major inclusion criteria.Viral RNA was extracted,and elutes were subjected to nanopore sequencing.All the sequencing data were uploaded in the publicly accessible database,GISAID.Results:The Omicron,Delta and Alpha variants accounted for 58%,22%and 4%of the variants throughout the period.Less than 1%were Kappa variant and 16%of the study samples remained unassigned.Omicron variant was circulated among all age groups and in all the provinces.Ct value and variants assigned percentage was 100%in Ct values of 10-15 while only 45%assigned Ct value over 25.Conclusions:The present study examined the emergence,prevalence,and distribution of SARS-CoV-2 variants locally and has shown that nanopore technology-based genome sequencing enables whole genome sequencing in a low resource setting country.
基金supported by CAMS Innovation Fund for Medical Sciences (CIFMS)[2021-I2M-1-038]
文摘Infectious diseases are an enormous public health burden and a growing threat to human health worldwide.Emerging or classic recurrent pathogens,or pathogens with resistant traits,challenge our ability to diagnose and control infectious diseases.Nanopore sequencing technology has the potential to enhance our ability to diagnose,interrogate,and track infectious diseases due to the unrestricted read length and system portability.This review focuses on the application of nanopore sequencing technology in the clinical diagnosis of infectious diseases and includes the following:(i)a brief introduction to nanopore sequencing technology and Oxford Nanopore Technologies(ONT)sequencing platforms;(ii)strategies for nanopore-based sequencing technologies;and(iii)applications of nanopore sequencing technology in monitoring emerging pathogenic microorganisms,molecular detection of clinically relevant drug-resistance genes,and characterization of disease-related microbial communities.Finally,we discuss the current challenges,potential opportunities,and future outlook for applying nanopore sequencing technology in the diagnosis of infectious diseases.
基金supported by the Medicine and Health,Science and Technology Plan Project of Zhejiang(Nos.2020KY1009 and 2021KY387)the Jinhua Science and Technology Planning Project Social Development Key Project(No.2021-3-072),China.
文摘Infectious diseases are a great threat to human health.Rapid and accurate detection of pathogens is important in the diagnosis and treatment of infectious diseases.Metagenomics next-generation sequencing(mNGS)is an unbiased and comprehensive approach for detecting all RNA and DNA in a sample.With the development of sequencing and bioinformatics technologies,mNGS is moving from research to clinical application,which opens a new avenue for pathogen detection.Numerous studies have revealed good potential for the clinical application of mNGS in infectious diseases,especially in difficult-to-detect,rare,and novel pathogens.However,there are several hurdles in the clinical application of mNGS,such as:(1)lack of universal workflow validation and quality assurance;(2)insensitivity to high-host background and low-biomass samples;and(3)lack of standardized instructions for mass data analysis and report interpretation.Therefore,a complete understanding of this new technology will help promote the clinical application of mNGS to infectious diseases.This review briefly introduces the history of next-generation sequencing,mainstream sequencing platforms,and mNGS workflow,and discusses the clinical applications of mNGS to infectious diseases and its advantages and disadvantages.
基金grateful to the financial support from the National Natural Science Foundation of China(Nos.22025407,21974144)Institute of Chemistry,Chinese Academy of Sciences。
文摘Environmental pollution and the spread of pathogenic microorganisms pose a significant threat to the health of humans and the planet.Thus,understanding and detecting microorganisms is crucial for maintaining a healthy living environment.Nanopore sequencing is a single-molecule detection method developed in the 1990s that has revolutionized various research fields.It offers several advantages over traditional sequencing methods,including low cost,label-free,time-saving detection speed,long sequencing reading,real-time monitoring,convenient carrying,and other significant advantages.In this review,we summarize the technical principles and characteristics of nanopore sequencing and discuss its applications in amplicon sequencing,metagenome sequencing,and whole-genome sequencing of environmental microorganisms,as well as its in situ application under some special circumstances.We also analyze the advantages and challenges of nanopore sequencing in microbiology research.Overall,nanopore sequencing has the potential to greatly enhance the detection and understanding of microorganisms in environmental research,but further developments are needed to overcome the current challenges.
文摘Single molecular real-time(SMRT)sequencing,also called third-generation sequencing,is a novel sequencing technique capable of generating extremely long contiguous sequence reads.While conventional short-read sequencing cannot evaluate the linkage of nucleotide substitutions distant from one another,SMRT sequencing can directly demonstrate linkage of nucleotide changes over a span of more than 20 kbp,and thus can be applied to directly examine the haplotypes of viruses or bacteria whose genome structures are changing in real time.In addition,an error correction method(circular consensus sequencing)has been established and repeated sequencing of a single-molecule DNA template can result in extremely high accuracy.The advantages of long read sequencing enable accurate determination of the haplotypes of individual viral clones.SMRT sequencing has been applied in various studies of viral genomes including determination of the full-length contiguous genome sequence of hepatitis C virus(HCV),targeted deep sequencing of the HCV NS5A gene,and assessment of heterogeneity among viral populations.Recently,the emergence of multi-drug resistant HCV viruses has become a significant clinical issue and has been also demonstrated using SMRT sequencing.In this review,we introduce the novel third-generation PacBio RSII/Sequel systems,compare them with conventional next-generation sequencers,and summarize previous studies in which SMRT sequencing technology has been applied for HCV genome analysis.We also refer to another long-read sequencing platform,nanopore sequencing technology,and discuss the advantages,limitations and future perspectives in using these thirdgeneration sequencers for HCV genome analysis.
基金supported by the National Natural Science Foundation of China(Nos.11272197 and11372175)the Innovation Program of Shanghai Municipality Education Commission,China(No.14ZZ095)
文摘The DNA sequencing technology has achieved a leapfrog development in recent years. As a new generation of the DNA sequencing technology, nanopore sequenc- ing has shown a broad application prospect and attracted vast research interests since it was proposed. In the present study, the dynamics of the electric-driven translocation of a homopolymer through a nanopore is investigated by the dissipative particle dynam- ics (DPD), in which the homopolymer is modeled as a worm-like chain (WLC). The DPD simulations show that the polymer chain undergoes conformation changes during the translocation process. The different structures of the polymer in the translocation process, i.e., single-file, double folded, and partially folded, and the induced current block- ades are analyzed. It is found that the current blockades have different magnitudes due to the polymer molecules traversing the pore with different folding conformations. The nanoscale vortices caused by the concentration polarization layers (CPLs) in the vicinity of the sheet are also studied. The results indicate that the translocation of the polymer has the effect of eliminating the vortices in the polyelectrolyte solution. These findings are expected to provide the theoretical guide for improving the nanopore sequencing tech- nique.
基金supported by the Earmarked Fund for the China Agriculture Research System(No.CARS-49)the Science and Technology Planning Project of Guang-dong Province,China(No.No2020B1212060058).
文摘The pearl oyster Pinctada fucata martensii is an economically valuable shellfish that is cultured for seawater pearl pro-duction,which mainly depends on oyster growth.However,the growth mechanisms of the pearl oyster are still poorly understood.In this study,oysters were grouped with relative growth rate,including fast-growing(FG)group and slow-growing(SG)group.Oxford Nanopore Technologies(ONT)long-read sequencing was applied to investigate the molecular mechanisms involved in the growth of this species.Five alternative splicing(AS)types were analyzed in both FG and SG groups,which include alternative 3’splice site,alternative 5’splice site,exon skipping,intron retention,and mutually exclusive exon.Transcriptome analysis showed that four of five different AS events(excluding mutually exclusive exons)occurred more frequently in FG than in SG oysters,and the five main AS types exhibited different characteristics.The AS events that were detected may be involved in growth,and the difference in ex-pression of AS events between FG and SG oysters may be involved in the mechanism underlying the difference in growth.Fifty dif-ferentially expressed genes(DEGs)were identified between the FG and SG oysters.The results showed that 40 genes were signifi-cantly up-regulated in FG oysters,while 10 genes were significantly down-regulated in SG oyster.Several genes related to nutrient metabolism,shell formation,and immunity were more highly expressed in FG oysters than in SG oysters.In summary,FG oysters exhibited higher metabolic and biomineralization activities and had a more powerful immune system than SG oysters.These results provide insight into the growth of P.f.martensii that can be used to improve breeding programs.
基金supported by the Chinese Academy of Sciences Scientific Research Equipment (Grant No YZ200823)
文摘As one of the most powerful tools in biomedical research,DNA sequencing not only has been improving its productivity at an exponential growth rate but has also been evolving into a new layout of technological territories toward engineering and physical disciplines over the past three decades.In this technical review,we look into technical characteristics of the next-generation sequencers and provide insights into their future development and applications.We envisage that some of the emerging platforms are capable of supporting the USD1000 genome and USD100 genome goals if given a few years for technical maturation.We also suggest that scientists from China should play an active role in this campaign that will have a profound impact on both scientific research and societal healthcare systems.
文摘With the rapid development of medicine,the studies of genes have become increasingly concerned by more people and being the contend of a great of researches.The next generation sequencing with its own advantages has been widely used in gene research nowadays.It has almost replaced the traditional sequencing methods(such as Sanger sequencing method),and played an important role in a variety of complex disease researches,including breast cancer.The next generation sequencing technology has the advantages of high speed,high throughput and high accuracy.It has been widely used in various cancers(such as prostate cancer,lung cancer,pancreatic cancer,liver cancer,etc.),especially in breast cancer.Moreover,the use of the next generation sequencing technology to make DNA sequence analysis and risk prediction has made a great contribution to the research of breast cancer.We will focus on the application of whole genome sequencing,exon sequencing and targeted gene sequencing in breast cancer gene research.