腹泻仔猪大肠埃希菌分离株ST4214的全基因组测序分析

分析腹泻仔猪大肠埃希菌(E.coli)分离株血清型、毒力因子及耐药基因。

本课题组前期研究从腹泻仔猪粪便样本中分离到64株E.coli, 本研究取其中含有毒力因子最多的1株进行全基因组测序分析。

E.coli分离株基因组序列为5.5 Mb, 预测蛋白质编码序列数为5 743, 与已知致病菌E.coli O145的基因重合率较低, 为64.53%。经多位点序列分型分析, 确定分离株为E.coli ST4214, 血清型为O3∶H45。与病原菌O157∶H7、O145∶H28和O104∶H4的毒力基因比较表明: 4株菌共同含有的毒力基因为354个, E.coli ST4214含有64种独特的毒力基因、编码鞭毛蛋白、Ⅳ型分泌蛋白、Ⅱ型分泌蛋白、溶血素、菌毛、肠毒素、荚膜多糖相关蛋白质。耐药基因E.coli分离株含有氨基香豆素抗性基因、磺胺类耐药基因、β-内酰胺抗性基因、多粘菌素耐药基因、肽抗生素抗性基因和抗生素耐药基因外排泵等多重耐药基因。

腹泻仔猪E.coli ST4214分离株是一株新菌株, 具有较多毒力因子及耐药基因, 可能与仔猪腹泻发病相关。

     

基于16S rRNA高通量测序技术分析福州地区慢传输型便秘患者肠道菌群的变化

运用16S rRNA高通量测序技术分析福州地区慢传输型便秘(STC)患者肠道菌群变化的特征。

纳入60例STC患者和健康志愿者20例, 留取新鲜粪便样本, 冰块运送至实验室并存放于-80度冰箱, 应用16S rRNA高通量测序技术, 分析各组肠道菌群的生物多样性与结构组成。

测序后共得到1 702 004 524条有效序列, 样本序列平均有效长度为414.1 bp, 总样本平均序列条数为2 127 505.7条。与对照组比较, STC患者肠道菌群丰度指数Ace指数、Chao指数和肠道菌群多样性指数Shannon指数下降(P < 0.05), 肠道菌群多样性指数Simpson指数显著升高(P < 0.05)。在门水平上, STC组以拟杆菌门、放线菌门为主, 正常对照组以厚壁菌门为主。在属水平上, STC组以拟杆菌属(Bacteroides)、肠杆菌科(Enterobacteriaceae)、丹毒杆菌属(Erysipelatoclostridium)、巨单胞菌属(Megamonas)为主, 正常对照组以乳酸杆菌属(Lactobacillus)、双歧杆菌属(Bifidobacterium)、布劳特菌属(Blautia)为主。

STC患者肠道菌群发生紊乱, 表现为丰度及多样性下降, 菌群结构发生改变, 可能与慢传输型便秘的发生发展有关。

     

辽宁省食源性副溶血性弧菌毒力基因、血清分型及耐药性分析

研究辽宁省2017-2020年市售水产品及其制品中分离的158株副溶血性弧菌的毒力基因、血清分型和耐药性, 为食源性疾病的暴发和散发进行评估和预警。

采用多重荧光定量PCR技术对毒力基因tlh、tdh和trh进行检测, 同时检测血清分型; 采用肉汤稀释法测定副溶血性弧菌MIC值并分析其耐药性。

158株副溶血性弧菌中均携带tlh基因, 携带tdh基因的菌株2株, 携带trh基因的菌株2株, 同时携带tdh基因和trh基因的菌株1株; 158株中67株血清型为O2(含K不分型), 39株为O3(含K不分型), 携带tdh和trh毒力基因的菌株血清型均为O3;副溶血性弧菌122株(77.22%)对头孢唑啉耐药, 36株(22.78%)对头孢西丁耐药, 30株(18.99%)对氨苄西林耐药, 18株菌呈现耐受2类及以上的多重耐药性。携带毒力基因的5株副溶血性弧菌对头孢唑啉均耐药。

大多数食源性副溶血性弧菌不携带毒力基因, O2血清型(42.41%)是辽宁省食源性副溶血性弧菌的主要血清型, 其次为O3(24.68%); 副溶血性弧菌对头孢唑啉显著耐药, 少数菌表现出多重耐药, 提示应继续加强水产品及其生食制品中副溶血性弧菌的致病性和耐药性监测。

     

急性脑卒中患者肠道菌群研究

通过粪便标本检测急性脑卒中患者肠道菌群变化情况, 探讨急性脑卒中患者肠道菌群结构。

通过高通量二代测序技术对10例健康者(对照组)及10例急性脑卒中患者(疾病组)粪便样本进行菌群结构测序分析。

与对照组比较, 急性脑卒中患者粪便样本中物种OTU信息量显著增加(P < 0.01), 菌群多样性指数(Shannon)和物种均一度指数(Evenness)也有所增加但差异无统计学意义(均P > 0.05)。门水平上, 疾病组患者肠道Bacteroidetes数量较对照组显著增加, Firmicutes数量显著减少(均P < 0.05)。属水平上, 疾病组患者肠道Bacteroides、Bilophila、Butyricimonas比例较对照组显著升高, 而Collinsella、Coprococcus、Clostridium等比例较对照组显著降低(均P < 0.05)。

急性脑卒中患者肠道菌群结构与健康人存在显著差异。

     

基于高通量测序分析哮喘小鼠呼吸道菌群的变化

通过高通量测序分析哮喘模型小鼠呼吸道菌群的变化情况。

将12只SPF级BALB/c雄性小鼠随机分为对照组和模型组, 每组6只。采用卵清蛋白致敏方法建立哮喘小鼠模型后, 进行支气管组织切片病理学观察, ELISA法检测血清IgE水平, 测定肺指数, 采集咽拭子后提取DNA行高通量测序分析。

与对照组比较, 模型组小鼠血清IgE水平明显升高(P < 0.05), 肺指数明显上升(P < 0.05), 可见支气管上皮粘膜有水肿, 少量淋巴细胞浸润, 平滑肌增生。模型组小鼠呼吸道菌群与对照组比较, 菌种丰度升高, 厚壁菌门较对照组减少(P < 0.05), 放线菌门和变形菌门增多(P < 0.05), 菌群结构有明显差异。

哮喘小鼠存在呼吸道微生态菌群失衡。

     

圈养食叶猴的肠道菌群特征

充分认识圈养食叶猴的肠道菌群组成特征, 为饲养管理方法的改进提供参考依据。

通过MiSeq高通量测序平台对3个物种的19个个体[黑叶猴(n=5)、川金丝猴(n=9)和西非黑白疣猴(n=5)]的肠道菌群16S rRNA V4-V5区进行测序和分析。

食叶猴肠道菌群以厚壁菌门和拟杆菌门为优势菌门, 瘤胃菌科、普氏菌科、理研菌科和毛螺菌科为优势菌科, 普氏菌属、密螺旋体属和瘤胃球菌属为优势菌属; 食叶猴物种间肠道菌群组成存在显著差异, 肠道菌群按照宿主物种聚类, 而不受环境因素的影响。

宿主物种是决定肠道微生物组成的重要因素, 食叶猴肠道菌群特征反映了宿主对其食性的适应。

     

不同程度颅脑疾病患者肠道菌群分析

检测不同程度颅脑疾病患者肠道菌群分布情况, 探讨患者肠道菌群分布与疾病的关系, 为该类患者的治疗提供参考。

通过MiSeq PE2x300 bp高通量测序技术对21例重度颅脑损伤患者(G1组, GCS≤8分)和14例轻度颅脑损伤患者(G2组, GCS > 8分)粪便样本中细菌的16S rRNA基因V3-V4可变区进行定性分析, 并对两组患者肠道菌群进行生物学分类比较、多样性分析和组间物种差异分析。

两组患者肠道菌群多样性差异无统计学意义(均P > 0.05)。G1组患者肠道厌氧球菌属(Anaerococcus)、埃希菌-志贺菌属(Escherichia-Shigella)、链球菌属(Streptococcus)、肠球菌属(Enterococcus)、棒状杆菌属(Corynebacterium)数量高于G2组(均P < 0.05)。

颅脑疾病患者肠道菌群紊乱, 其肠道菌群丰度及多样性显著下降, 有害菌数量升高, 有益菌数量下降。

     

红茶对2型糖尿病小鼠肠道菌群分布的影响

探讨红茶对2型糖尿病（T2DM）小鼠肠道菌群分布的影响,为研究红茶在代谢性疾病的辅助治疗机制提供参考。

构建 T2DM小鼠模型,将其随机分为模型组（T2DM组）和茶水饲喂组（T2DM_T组）,取健康小鼠作为对照组（Control组）,每组各15只。实验终点收集3组小鼠粪便进行宏基因组测序,分析组间菌群差异;同时进行肝脏组织形态学检查,观察组织病理学改变。

与Control组和T2DM组相比,T2DM_T组拟杆菌门（F = 21.056,P＜0.001）、邓肯氏菌属（F = 13.330,P = 0.001）、乳杆菌属（F = 36.546,P＜0.001）和粘液乳杆菌属（F = 43.813,P＜0.001）的相对丰度增加,担子菌门（F = 8.676,P = 0.005）、Muribaculum（F = 8.151,P = 0.006）和肠球菌属（F = 4.271,P = 0.040）的相对丰度降低。与T2DM组小鼠相比,T2DM_T组小鼠肝细胞排列较为紧密,细胞空泡变性程度有所减弱。

红茶在一定范围内能调节T2DM模型小鼠肠道菌群结构和相对丰度,红茶水喂饲可减缓造模所致的T2DM小鼠肝脏细胞的损伤,其具体作用机制值得深入研究和探讨。

     

双歧杆菌乳杆菌三联活菌片对幽门螺杆菌根治后消化道不良反应的改善作用

探讨加用双歧杆菌乳杆菌三联活菌片对临床四联疗法根除幽门螺杆菌(H.pylori)过程中患者消化道不良反应的改善作用。

选择2019年1月至2020年1月在昆明医科大学第二附属医院门诊就诊的100例H.pylori感染患者, 分为益生菌组和正常组, 各50例。全部患者通过四联疗法根除H.pylori后, 益生菌组患者继续加用双歧杆菌乳杆菌三联活菌片治疗, 对结果进行分析。

2组患者使用含有铋剂的四联疗法根除H.pylori后效果满意。益生菌组患者不良反应发生率低于正常组(25.5% vs 47.5%;χ²=11.023, P=0.001)。

益生菌可减轻四联疗法根除H.pylori后消化道不良反应, 根除H.pylori过程中加用益生菌的时机尚待进一步探讨。

     

MALDI-TOF MS在快速检测碳青霉烯类耐药肺炎克雷伯菌及其同源性分析中的应用

利用基质辅助激光解吸电离飞行时间质谱(MALDI-TOF MS)筛选碳青霉烯类耐药肺炎克雷伯菌(CRKp)特异性峰, 并进行同源性分析。

收集30株CRKp临床分离株, 采用法国梅里埃VITEK 2 Compact分析仪进行细菌鉴定和药敏试验、利用改良碳青霉烯灭活试验(mCIM)检测碳青霉烯酶; 利用MALDI-TOF MS技术筛选CRKp菌株特异性峰, 采用MALDI-TOF MS进行同源性分析, 多位点序列分型(MLST)方法作为验证。

30株CRKp株mCIM均为阳性, 其中24株含有共同特异性峰, 特异性达到80%, 符合区分阈值。蛋白质质量峰聚类分析显示, 30株CRKp株分为三大簇, 同时MLST结果表明, ST11/A型为27株、ST15/B型为2株, 而ST2193/D型仅有1株。

MALDI-TOF MS在CRKp鉴定中具有精准、快速的优点。MALDI-TOF MS能够有效进行CRKp同源性分析, 并应用于院内感染流行暴发的监测。

     

Selection Analysis Identifies Clusters of Unusual Mutational Changes in Omicron Lineage BA.1 That Likely Impact Spike Function

Among the 30 nonsynonymous nucleotide substitutions in the Omicron S-gene are 13 that have only rarely been seen in other SARS-CoV-2 sequences. These mutations cluster within three functionally important regions of the S-gene at sites that will likely impact (1) interactions between subunits of the Spike trimer and the predisposition of subunits to shift from down to up configurations, (2) interactions of Spike with ACE2 receptors, and (3) the priming of Spike for membrane fusion. We show here that, based on both the rarity of these 13 mutations in intrapatient sequencing reads and patterns of selection at the codon sites where the mutations occur in SARS-CoV-2 and related sarbecoviruses, prior to the emergence of Omicron the mutations would have been predicted to decrease the fitness of any virus within which they occurred. We further propose that the mutations in each of the three clusters therefore cooperatively interact to both mitigate their individual fitness costs, and, in combination with other mutations, adaptively alter the function of Spike. Given the evident epidemic growth advantages of Omicron overall previously known SARS-CoV-2 lineages, it is crucial to determine both how such complex and highly adaptive mutation constellations were assembled within the Omicron S-gene, and why, despite unprecedented global genomic surveillance efforts, the early stages of this assembly process went completely undetected.     

Genomic Perspectives on the Emerging SARS-CoV-2 Omicron Variant

A new variant of concern for SARS-CoV-2,Omicron(B.1.1.529),was designated by the World Health Organization on November 26,2021.This study analyzed the viral genome sequencing data of 108 samples collected from patients infected with Omicron.First,we found that the enrichment efficiency of viral nucleic acids was reduced due to mutations in the region where the primers anneal to.Second,the Omicron variant possesses an excessive number of mutations compared to other variants circulating at the sam...     

输入病毒导致的十起本土疫情首例病例新冠病毒基因特征分析

2020年4月中国阻断湖北省武汉市新冠肺炎疫情传播后,中国国内报道了多起由境外输入导致的本土聚集性新冠肺炎疫情。为分析引起聚集性疫情的输入性新型冠状病毒(SARS-CoV-2)的基因组特征,本研究对2020年4-11月份十起输入相关本土疫情首例病例的SARS-CoV-2全基因组基因特征进行分析,系统阐述了相关SARS-CoV-2的全基因组和氨基酸变异特征。结果显示,与武汉参考株相比,十起本土聚集性疫情首例病例的SARS-CoV-2核苷酸突变中位数为10个(8个-26个),氨基酸突变的中位数为6个(4个-16个),且刺突(spike,S)蛋白只有D614G一个氨基酸发生突变。除分支位点外,10条SARS-CoV-2全基因组序列的65个核苷酸突变位点以及35个氨基酸突变仅出现1-2次,呈现随机性。全基因组分析表明,这十起本土疫情的首例病例基因组按照中国分型法可划分为4个型,按照Pangolin分型法可划分为7个型,与我国2020年1-3月份武汉流行的毒株属于不同基因型,不是本土SARS-CoV-2的持续传播。与2020年9-12月英国和南非变异株属于不同基因型,无相关性。本文系统分析了2020年由输入病毒导致的十起本土疫情首例病例的SARS-CoV-2核苷酸与氨基酸变异特征,为我国新冠防控策略的制定以及后续新冠疫情的溯源提供了参考依据。     

严重急性呼吸综合征冠状病毒2变异体对全球疫情防控的影响分析

由严重急性呼吸综合征冠状病毒2（SARS-CoV-2）引起的新型冠状病毒肺炎（COVID-19，简称新冠肺炎）的出现，对国际公众健康构成了严重威胁，伴随COVID-19大流行而来的是SARS-CoV-2基因组的不断突变，尤其是受关注的变异体（variants of concern，VOCs）给全球COVID-19疫情防控带来了挑战。本文综述了SARS-CoV-2的突变情况和现阶段主要流行的VOCs的特征，总结了现有及潜在的COVID-19预防、诊断和治疗手段，并通过分析SARS-CoV-2变异体对全球COVID-19疫情防控措施的影响，提出合理的建议，以期为今后可能爆发的大范围流行病的防控提供理论依据。     

Genomic and epidemiological characteristics of SARS-CoV-2 in Africa

Since late 2019, the coronavirus disease 2019 (COVID-19) outbreak, caused by SARS-CoV-2, has rapidly evolved to become a global pandemic. Each country was affected but with a varying number of infected cases and mortality rates. Africa was hit late by the pandemic but the number of cases rose sharply. In this study, we investigated 224 SARS-CoV-2 genome sequences from the Global Initiative on Sharing Avian Influenza Data (GISAID) in the early part of the outbreak, of which 69 were from Africa. We analyzed a total of 550 mutations by comparing them with the reference SARS-CoV-2 sequence from Wuhan. We classified the mutations observed based on country and region, and afterwards analyzed common and unique mutations on the African continent as a whole. Correlation analyses showed that the duo variants ORF1ab/RdRp 4715L and S protein 614G variants, which are strongly linked to fatality rate, were not significantly and positively correlated with fatality rates (r = -0.03757, P = 0.5331 and r = -0.2876, P = 0.6389, respectively), although increased number of cases correlated with number of deaths (r = 0.997, P = 0.0002). Furthermore, most cases in Africa were mainly imported from American and European countries, except one isolate with no mutation and was similar to the original isolate from Wuhan. Moreover, unique mutations specific to countries were identified in the early phase of the outbreak but these mutations were not regional-specific. There were common mutations in all isolates across the continent as well as similar isolate-specific mutations in different regions. Our findings suggest that mutation is rapid in SARS-CoV-2 in Africa and although these mutations spread across the continent, the duo variants could not possibly be the sole cause of COVID-19 deaths in Africa in the early phase of the outbreak.     

Genotyping coronavirus SARS-CoV-2: methods and implications

The emerging global infectious COVID-19 disease by novel Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) presents critical threats to global public health and the economy since it was identified in late December 2019 in China. The virus has gone through various pathways of evolution. To understand the evolution and transmission of SARS-CoV-2, genotyping of virus isolates is of great importance. This study presents an accurate method for effectively genotyping SARS-CoV-2 viruses using complete genomes. The method employs the multiple sequence alignments of the genome isolates with the SARS-CoV-2 reference genome. The single-nucleotide polymorphism (SNP) genotypes are then measured by Jaccard distances to track the relationship of virus isolates. The genotyping analysis of SARS-CoV-2 isolates from the globe reveals that specific multiple mutations are the predominated mutation type during the current epidemic. The proposed method serves an effective tool for monitoring and tracking the epidemic of pathogenic viruses in their global and local genetic variations. The genotyping analysis shows that the genes encoding the S proteins and RNA polymerase, RNA primase, and nucleoprotein, undergo frequent mutations. These mutations are critical for vaccine development in disease control.     

SARS-CoV-2 VOCs,Mutational diversity and clinical outcome: Are they modulating drug efficacy by altered binding strength?

The global COVID-19 pandemic continues due to emerging Severe Acute Respiratory syndrome coronavirus 2 (SARS-CoV-2) variants of concern (VOC). Here, we performed comprehensive analysis of in-house sequenced SARS-CoV-2 genome mutations dynamics in the patients infected with the VOCs - Delta and Omicron, within Recovered and Mortality patients. Statistical analysis highlighted significant mutations - T4685A, N4992N, and G5063S in RdRp; T19R in NTD spike; K444N and N532H in RBD spike, associated with Delta mortality. Mutations, T19I in NTD spike, Q493R and N440K in the RBD spike were significantly associated with Omicron mortality. We performed molecular docking for possible effect of significant mutations on the binding of Remdesivir. We found that Remdesivir showed less binding efficacy with the mutant Spike protein of both Delta and Omicron mortality compared to recovered patients. This indicates that mortality associated mutations could have a modulatory effect on drug binding which could be associated with disease outcome.     

Evidence for a mouse origin of the SARS-CoV-2 Omicron variant

The rapid accumulation of mutations in the SARS-CoV-2 Omicron variant that enabled its outbreak raises questions as to whether its proximal origin occurred in humans or another mammalian host. Here, we identified 45 point mutations that Omicron acquired since divergence from the B.1.1 lineage. We found that the Omicron spike protein sequence was subjected to stronger positive selection than that of any reported SARS-CoV-2 variants known to evolve persistently in human hosts, suggesting a possibility of host-jumping. The molecular spectrum of mutations (i.e., the relative frequency of the 12 types of base substitutions) acquired by the progenitor of Omicron was significantly different from the spectrum for viruses that evolved in human patients but resembled the spectra associated with virus evolution in a mouse cellular environment. Furthermore, mutations in the Omicron spike protein significantly overlapped with SARS-CoV-2 mutations known to promote adaptation to mouse hosts, particularly through enhanced spike protein binding affinity for the mouse cell entry receptor. Collectively, our results suggest that the progenitor of Omicron jumped from humans to mice, rapidly accumulated mutations conducive to infecting that host, then jumped back into humans, indicating an inter-species evolutionary trajectory for the Omicron outbreak.     

COVID-19: Omicron – the latest,the least virulent,but probably not the last variant of concern of SARS-CoV-2

The Omicron variant rapidly became the dominant SARS-CoV-2 strain in South Africa and elsewhere. This review explores whether this rise was due to an increased transmission of the variant or its escape from population immunity by an extensively mutated spike protein. The mutations affected the structure of the spike protein leading to the loss of neutralization by most, but not all, therapeutic monoclonal antibodies. Omicron also shows substantial immune escape from serum antibodies in convalescent patients and vaccinees. A booster immunization increased, however, the titre and breadth of antiviral antibody response. The cellular immune response against Omicron was largely preserved explaining a satisfying protection of boosted vaccinees against severe infections. Clinicians observed less severe infection with Omicron, but other scientists warned that this must not necessarily reflect less intrinsic virulence. However, in animal experiments with mice and hamsters, Omicron infections also displayed a lesser virulence than previous VOCs and lung functions were less compromised. Cell biologists demonstrated that Omicron differs from Delta by preferring the endocytic pathway for cell entry over fusion with the plasma membrane which might explain Omicron’s distinct replication along the respiratory tract compared with Delta. Omicron represents a distinct evolutionary lineage that deviated from the mainstream of evolving SARS-CoV-2 already in mid-2020 raising questions about where it circulated before getting widespread in December 2021. The role of Omicron for the future trajectory of the COVID-19 pandemic is discussed.     

Humoral and Cellular Immune Responses of COVID-19 vaccines against SARS-Cov-2 Omicron variant: a systemic review

Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) has undergone multiple mutations since its emergence, and its latest variant, Omicron (B.1.1.529), is the most contagious variant of concern (VOC) which poses a major and imminent threat to public health. Since firstly reported by World Health Organization (WHO) in November 2021, Omicron variant has been spreading rapidly and has become the dominant variant in many countries worldwide. Omicron is the most mutated variant so far, containing 60 mutations in its genome, including 37 mutations in the S-protein. Since all current COVID-19 vaccines in use were developed based on ancestral SARS-CoV-2 strains, whether they are protective against Omicron is a critical question which has been the center of study currently. In this article, we systemically reviewed the studies regarding the effectiveness of 2- or 3-dose vaccines delivered in either homologous or heterologous manner. The humoral and cellular immune responses elicited by various vaccine regimens to protect against Omicron variant are discussed. Current understanding of the molecular basis underlying immune escape of Omicron was also analyzed. These studies indicate that two doses of vaccination are insufficient to elicit neutralizing antibody responses against Omicron variant. Nevertheless, Omicron-specific humoral immune responses can be enhanced by booster dose of almost all type vaccines in certain degree, and heterologous vaccination strategy may represent a better choice than homogenous regimens. Intriguingly, results of studies indicate that all current vaccines are still able to elicit robust T cell response against Omicron. Future focus should be the development of Omicron variant vaccine, which may induce potent humoral as well as cellular immune responses simultaneously against all known variants of the SARS-CoV-2 virus.