致肾盂肾炎大肠杆菌的毒力因子和调控

致肾盂肾炎大肠杆菌引起人的尿路感染,它的毒力因子包括表面毒力因子和分泌毒力因子两大类。表面毒力因子包括菌毛、鞭毛、黏附素和多糖类物质,主要在细菌的侵染过程中起作用。分泌毒力因子主要是溶血素、细胞毒性坏死因子等毒素蛋白,主要对宿主细胞产生毒力作用。本文简要综述致肾盂肾炎大肠杆菌毒力因子分泌所需要的5种分泌机制,并论及毒力因子的宏观调控和影响毒力调控的因素。     

动物源产肠毒素大肠杆菌(ETEC)黏附素研究进展

动物源产肠毒素大肠杆菌(enterotoxigenic Escherichia coli,ETEC)是引起动物(尤其是幼龄动物)腹泻的主要病原菌。已知黏附素和肠毒素是ETEC中两种重要的毒力因子,在致病性中两者缺一不可。其中黏附素结合到宿主易感肠上皮细胞是ETEC感染的第一步,也是最重要的关键步骤。动物源ETEC的菌毛黏附素主要包括K88、K99、987P、F18、F17和F41等。人们从20世纪60年代就开始了ETEC菌毛黏附素的相关研究,包括菌毛的基因、结构组成、生物合成、菌毛表达的调控机制以及黏附素和宿主受体相互作用等,这些研究基础有助于我们深入了解ETEC病原菌的感染机理;并且在疾病诊断和新疫苗的开发中具有重大意义。     

肺炎克雷伯菌菌毛粘附素克隆表达及其对体外培养细胞的粘附活性

摘要：【目的】肺炎克雷伯菌(K.pn)与宿主细胞的粘附是致病的首要条件,粘附过程主要通过菌毛粘附素MrkD蛋白介导。为了进一步分析MrkD蛋白与宿主细胞间的粘附机制,进一步确定MrkD蛋白的粘附阻断作用。【方法】构建肺炎克雷伯菌菌毛粘附素融合蛋白原核表达质粒pGEX-4T-mrkD,转入大肠杆菌BL21,优化诱导表达条件,表达产物经亲和层析纯化、凝血酶切除融合蛋白GST标签后,进行SDS-PAGE和Western blot鉴定。激光共聚焦显微镜定位MrkD蛋白在宿主细胞上的结合部位;通过粘附活性试验与粘附动力学实验研究了MrkD蛋白的生物活性。【结果】实验得到了分子量为35 kDa的MrkD蛋白,定位了MrkD蛋白在宿主细胞上的结合部位,并证明了MrkD蛋白可以显著影响肺炎克雷伯菌对宿主细胞的粘附力。【结论】本试验首次证实了MrkD蛋白的粘附阻断作用并观察到了其与宿主细胞的作用位点,为研究肺炎克雷伯菌的致病机制,寻找粘附素功能表位奠定了基础。     

产肠毒素性大肠杆菌K88菌毛装配

K88菌毛介导产肠毒索性大肠杆菌在小肠上皮细胞的粘附,是引起新生仔猪腹泻的主要致病因子之一.菌毛的合成与装配是由fae操纵子调控的,fae操纵子包含10个基,faeA-fae J,其中有些基因表达菌毛装配所需的各种结构蛋白、分子伴侣和调控因子.菌毛的装配过程是由fae操纵子调控,通过分子伴侣,锚定蛋白的相互协同作用完成,组装成结构蛋白的多聚体.继阐明K88菌毛装配调控机理之后,K88菌毛在非毒素源性大肠杆菌及其它原核生物中装配也取得成功,同时菌毛结构蛋白在真核生物中组装也取得了很大进展.     

大肠杆菌K88ac菌毛操纵子fae全基因的克隆、表达及生物学活性初步研究

目的：在体外克隆和表达猪肠产毒性大肠杆菌（ETEC）K88ae菌毛操纵子,触结构基因,并检测重组菌毛的相关生物学活性。方法：利用长PCR技术以猪ETECK88ae株C83902基因组DNA为模板扩增编码K88菌毛操纵子触基因,克隆入表达质粒载体pBR322,构建和筛选重组质粒pBR322-fae,转化至不含任何菌毛的大肠杆菌EP株;电镜观察重组菌表面菌毛表达情况;用热抽提法提纯表达的重组菌毛;用纯化菌毛免疫小鼠制备高效价抗血清;用SDS-PAGE和Western blot检测重组菌毛的抗原性,用细胞黏附和黏附抑制试验检测其生物学活性。结果和结论：在电镜下观察到重组菌表面大量表达K88ae菌毛,该重组菌与兔抗K88ae菌毛单因子阳性血清、鼠抗K88ac菌毛单克隆抗体均产生凝集反应;纯化菌毛经SDS-PAGE,结构单位菌毛呈单一的相对分子质量约26×10^3的蛋白条带;纯化菌毛免疫小鼠后可制备出高效价的鼠抗血清,玻板凝集试验和Western blot结果表明体外表达的K88ae菌毛具有与K88ae野生菌毛相同的抗原性;猪小肠上皮细胞系黏附和黏附抑制实验结果表明重组EP菌和野生菌株一样具有较强的黏附猪小肠上皮细胞系的能力,而且提纯重组菌毛制备出的鼠抗血清能有效抑制上述重组菌或野生菌株对猪小肠上皮细胞系的黏附结合。     

F-RNA噬菌体YM1肠道宿主分析

【背景】F-RNA噬菌体近年来常被作为水环境中诺如病毒污染的指示物。本课题组前期以大肠杆菌ATCC700891^T为宿主,从人便样中筛选出一株F-RNA噬菌体YM1,其与大肠杆菌噬菌体MS2亲缘关系最近,MS2宿主通常为含有性菌毛的雄性大肠杆菌。【目的】探索F-RNA噬菌体与其肠道宿主及诺如病毒之间的互作关系,筛选YM1的肠道宿主。【方法】采用选择性培养基筛选YM1阳性便样中的大肠杆菌并进行YM1侵染验证,结合16S rRNA基因扩增子测序分析YM1接种前后便样中的差异性菌群种类,对YM1阳性便样中潜在的YM1肠道宿主进行分析。【结果】筛选到351个大肠杆菌菌株,YM1侵染结果表明这些大肠杆菌均不是YM1的宿主;16S rRNA基因扩增子测序分析差异性菌种显示,Enterobacter sp. (OTU144)和Enterobacter sp. (OTU11)这2株肠杆菌属细菌的相对丰度在YM1感染后发生显著性的降低,表明该2种细菌可能为YM1的潜在肠道宿主。【结论】YM1具有严格的宿主特异性,便样中大肠杆菌并非YM1的肠道宿主,同时发现了2种YM1的潜在宿主,为进一步筛选分离YM1的肠道宿主提供了方向和依据。     

沙门氏菌Ⅰ型菌毛研究进展

据WHO估计,全球每年有数十亿人患食源性疾病,其中由沙门氏菌感染引起的死亡就超过23万人.在沙门氏菌众多的毒力因子中,菌毛在该病原体感染过程中发挥了不可或缺的作用.菌毛(又称纤毛)是细菌表面的丝状蛋白附属物,是细菌对宿主细胞产生作用和造成感染的关键因子.其中,Ⅰ型菌毛是肠杆菌科成员(包括沙门氏菌)中最常见的菌毛之一,对...     

丝状真菌基因表达系统研究的现状及展望

利用大肠杆菌和酵母作为宿主菌生产外源蛋白有不少已发展到工业规模,但其存在的缺陷表明它们并不总是生产外源蛋白的理想宿主。大肠杆菌大量合成的外源蛋白大多以包涵体形式存在于细胞内,且不能对真核蛋白进行糖基化等翻译后加工,所以大肠杆菌作为表达宿主很难直接得到有活性的真核蛋白;酵母合成的蛋白虽然可以外泌,但其产量普遍低,并且酵母对外源蛋白的修饰模式与高等真核生物的差别较大。丝状真菌作为生产外源蛋白的宿主可弥补细菌和酵母的不足。首先,丝状真菌具有很强的外泌蛋白能力。其次,丝状真菌能对合成的真核蛋白较正确地进…     

嗜热真菌纤维素酶的CBD与海栖热袍菌的纤维素酶融合表达

将嗜热真菌毛壳菌纤维素酶Cel7A的纤维素结合结构域编码区与极端嗜热厌氧菌海栖热袍菌的纤维素酶CelB基因进行融合, 构建重组质粒pHsh-CBD-CelB, 并在大肠杆菌中表达。对融合蛋白进行纯化, 通过热处理和离子交换层析, 纯化到的融合蛋白SDS-PAGE 电泳图谱显示为单一条带。对融合蛋白的特性研究, 结果表明融合蛋白降解CMC的最适反应温度为90°C, 结晶纤维素吸附实验表明该融合蛋白具有结合结晶纤维素的能力, 并且融合蛋白降解CMC与结晶纤维素的能力得到提高。     

蛋白质聚集的形成与调控机制

大肠杆菌是外源蛋白质的首选表达系统,但蛋白质易被宿主细胞蛋白酶降解或聚集形成包含体。包含体与淀粉样蛋白纤维的形成过程相似,都依赖于特异性氨基酸序列的分子间相互作用。因此,淀粉样蛋白质抗聚集的方法也可用于防止细菌表达蛋白质的聚集。另外,基于序列的新型方法也能调节蛋白质聚集。     

Curli fibers are required for development of biofilm architecture in Escherichia coli K-12 and enhance bacterial adherence to human uroepithelial cells

Sessile bacteria show phenotypical, biochemical, and morphological differences from their planktonic counterparts. Curli, extracellular structures important for biofilm formation, are only produced at temperatures below 30 C in Escherichia coli K-12 strains. In this report, we show that E. coli K-12 can produce curli at 37 C when grown as a biofilm community. The curli-expressing strain formed more biofilms on polyurethane sheets than the curli-deficient strain under growth temperatures of both 25 C and 37 C. Curli are required for the formation of a three-dimensional mature biofilm, with characteristic water channels and pillars of bacteria. Observations by electron microscopy revealed the presence at the surfaces of the curli-deficient mutant in biofilm of flagella and type I pili. A wild-type curli-expressing E. coli strain significantly adhered to several lines of human uroepithelial cells, more so than an isogenic curlideficient strain. The finding that curli are expressed at 37 C in biofilm and enhance bacterial adherence to mammalian host cells suggests an important role for curli in pathogenesis.     

Promiscuous Cross-seeding between Bacterial Amyloids Promotes Interspecies Biofilms

Amyloids are highly aggregated proteinaceous fibers historically associated with neurodegenerative conditions including Alzheimers, Parkinsons, and prion-based encephalopathies. Polymerization of amyloidogenic proteins into ordered fibers can be accelerated by preformed amyloid aggregates derived from the same protein in a process called seeding. Seeding of disease-associated amyloids and prions is highly specific and cross-seeding is usually limited or prevented. Here we describe the first study on the cross-seeding potential of bacterial functional amyloids. Curli are produced on the surface of many Gram-negative bacteria where they facilitate surface attachment and biofilm development. Curli fibers are composed of the major subunit CsgA and the nucleator CsgB, which templates CsgA into fibers. Our results showed that curli subunit homologs from Escherichia coli, Salmonella typhimurium LT2, and Citrobacter koseri were able to cross-seed in vitro. The polymerization of Escherichia coli CsgA was also accelerated by fibers derived from a distant homolog in Shewanella oneidensis that shares less than 30% identity in primary sequence. Cross-seeding of curli proteins was also observed in mixed colony biofilms with E. coli and S. typhimurium. CsgA was secreted from E. coli csgB− mutants assembled into fibers on adjacent S. typhimurium that presented CsgB on its surfaces. Similarly, CsgA was secreted by S. typhimurium csgB− mutants formed curli on CsgB-presenting E. coli. This interspecies curli assembly enhanced bacterial attachment to agar surfaces and supported pellicle biofilm formation. Collectively, this work suggests that the seeding specificity among curli homologs is relaxed and that heterogeneous curli fibers can facilitate multispecies biofilm development.     

CsgE is a curli secretion specificity factor that prevents amyloid fibre aggregation

Curli are extracellular amyloid fibres produced by Escherichia coli that are critical for biofilm formation and adhesion to biotic and abiotic surfaces. CsgA and CsgB are the major and minor curli subunits, respectively, while CsgE, CsgF and CsgG direct the extracellular localization and assembly of curli subunits into fibres. The secretion and stability of CsgA and CsgB are dependent on the outer membrane lipoprotein CsgG. Here, we identified functional interactions between CsgG and CsgE during curli secretion. We discovered that CsgG overexpression restored curli production to a csgE strain under curli-inducing conditions. In antibiotic sensitivity and protein secretion assays, CsgG expression alone allowed translocation of erythromycin and small periplasmic proteins across the outer membrane. Coexpression of CsgE with CsgG blocked non-specific protein and antibiotic passage across the outer membrane. However, CsgE did not block secretion of proteins containing a 22-amino-acid putative outer membrane secretion signal of CsgA (A22). Finally, using purified proteins, we found that CsgE prohibited the self-assembly of CsgA into amyloid fibres. Collectively, these data indicate that CsgE provides substrate specificity to the curli secretion pore CsgG, and acts directly on the secretion substrate CsgA to prevent premature subunit assembly.     

Curli provide the template for understanding controlled amyloid propagation

The uncontrolled formation of amyloid fibers is the hallmark of more than twenty human diseases. In contrast to disease-associated amyloids, which are the products of protein misfolding, E. coli assembles functional amyloid fibers called curli on its surface using an elegant biogenesis machine. Composed of a major subunit, CsgA, and a minor subunit, CsgB, curli play important roles in host cell adhesion, long-term survival and other bacterial community behaviors. Assembly of curli fibers is a template-directed conversion process where membrane-tethered CsgB initiates CsgA polymerization. The CsgA amyloid core is composed of five imperfect repeating units. In a series of in vivo and in vitro experiments, we determined the sequence and structural determinants that guide the initiation and propagation of CsgA polymers. The CsgA N- and C-terminal repeating units govern its polymerization and responsiveness to CsgB. Specifically, conserved glutamine and asparagine residues present in the CsgA N- and C-terminal repeating units are required for CsgB-mediated nucleation and efficient self-assembly.     

Curli fimbria production among Escherichia coli strains isolated from children with diarrhea and healthy children

E. coli curli fimbria are produced during starvation and at room temperature. In the study curli synthesis among E. coli strains isolated from children with diarrhea and healthy children was investigated at human body temperature and in the variable atmosphere conditions: aerobic, supplemented with CO2 and anaerobic. The ability of curli synthesis was estimated using qualitative and quantitative methods basing on Congo red binding by curli. Curli production of all E. coli strains examined was observed at temperature 37 degrees C during anaerobic cultivation, confirming their role in colonization of intestinal mucosa.     

The Bacterial Amyloid Curli Is Associated with Urinary Source Bloodstream Infection

Urinary tract infections are the most common cause of E. coli bloodstream infections (BSI) but the mechanism of bloodstream invasion is poorly understood. Some clinical isolates have been observed to shield themselves with extracellular amyloid fibers called curli at physiologic temperature. We hypothesize that curli fiber assembly at 37°C promotes bacteremic progression by urinary E. coli strains. Curli expression by cultured E. coli isolates from bacteriuric patients in the presence and absence of bacteremia were compared using Western blotting following amyloid fiber disruption with hexafluoroisopropanol. At 37°C, urinary isolates from bacteremic patients were more likely to express curli than those from non-bacteremic patients [16/22 (73%) vs. 7/21 (33%); p = 0.01]. No significant difference in curli expression was observed at 30°C [86% (19/22) vs. 76% (16/21); p = 0.5]. Isolates were clonally diverse between patients, indicating that this phenotype is distributed across multiple lineages. Most same-patient urine and blood isolates were highly related, consistent with direct invasion of urinary bacteria into the bloodstream. 37°C curli expression was associated with bacteremic progression of urinary E. coli isolates in this population. These findings suggest new future diagnostic and virulence-targeting therapeutic approaches.     

Community behavior and amyloid-associated phenotypes among a panel of uropathogenic E. coli

Uropathogenic Escherichia coli (UPEC) are the major causative agents of urinary tract infection and engage in a coordinated genetic and molecular cascade to colonize the urinary tract. Disrupting the assembly and/or function of virulence factors and bacterial biofilms has emerged as an attractive target for the development of new therapeutic strategies to prevent and treat urinary tract infection, particularly in the era of increasing antibiotic resistance among human pathogens. UPEC vary widely in their genetic and molecular phenotypes and more data are needed to understand the features that distinguish isolates as more or less virulent and as more robust biofilm formers or poor biofilm formers. Curli are extracellular functional amyloid fibers produced by E. coli that contribute to pathogenesis and influence the host response during urinary tract infection (UTI). We have examined the production of curli and curli-associated phenotypes including biofilm formation among a specific panel of human clinical UPEC that has been studied extensively in the mouse model of UTI. Motility, curli production, and curli-associated biofilm formation attached to plastic were the most prevalent behaviors, shared by most clinical isolates. We discuss these results in the context on the previously reported behavior and phenotypes of these isolates in the murine cystitis model in vivo.     

Dimethyl sulfoxide and ethanol elicit increased amyloid biogenesis and amyloid-integrated biofilm formation in Escherichia coli

Escherichia coli directs the assembly of functional amyloid fibers termed "curli" that mediate adhesion and biofilm formation. We discovered that E. coli exhibits a tunable and selective increase in curli protein expression and fiber assembly in response to moderate concentrations of dimethyl sulfoxide (DMSO) and ethanol. Furthermore, the molecular alterations resulted in dramatic functional phenotypes associated with community behavior, including (i) cellular agglutination in broth, (ii) altered colony morphology, and (iii) increased biofilm formation. Solid-state nuclear magnetic resonance (NMR) spectra of intact pellicles formed in the presence of [(13)C(2)]DMSO confirmed that DMSO was not being transformed and utilized directly for metabolism. Collectively, the chemically induced phenotypes emphasize the plasticity of E. coli's response to environmental stimuli to enhance amyloid production and amyloid-integrated biofilm formation. The data also support our developing model of the extracellular matrix as an organized assembly of polymeric components, including amyloid fibers, in which composition relates to bacterial physiology and community function.     

Role of fibronectin in curli-mediated internalization

Curli fibers of Escherichia coli mediate internalization of bacteria by eukaryotic cells. As curli fibers bind fibronectin with high affinity, the role of fibronectin in the uptake process was studied. The experiments presented here support the involvement of fibronectin in internalization of bacteria. Furthermore, a peptide containing the RGD motif, responsible for interaction of fibronectin with cellular integrins, can strongly inhibit curli-mediated internalization. The ability of curli fibers to bind fibronectin can therefore be linked to virulence.