大肠杆菌F18菌株敏感和抵抗基因型仔猪十二指肠基因表达谱差异分析

文章运用Agilent 双标记表达谱芯片, 基于已建立的苏太猪大肠杆菌F18菌株敏感性和抗性型全同胞配对个体, 分析十二指肠组织基因表达谱差异, 旨在筛选导致仔猪断奶后腹泻和水肿病发生的大肠杆菌F18菌株受体相关基因, 探讨造成大肠杆菌病抗性和敏感性资源家系抗性差异的分子生物学机理。研究结果显示, 以Fold change绝对值大于2倍进行筛选, 在敏感型(GG基因型)对抗性型(AA基因型)配对组中, 差异基因共13个, 其中上调6个, 下调7个, 在以敏感型(AG基因型)对抗性型(AA基因型)配对组中, 共筛选出差异基因6个, 其中上调4个, 下调2个。经GO分析发现差异基因的生物学过程主要涉及免疫应答、胞外区修饰(如糖基化)、细胞黏附、信号转导等。通路发现大肠杆菌F18菌株抵抗性和敏感性差异基因主要涉及糖脂合成代谢以及炎症免疫相关通路, 经芯片筛选出的相关基因的功能还需进一步的研究验证。     

猪a1-岩藻糖转移酶基因(FUT1)M857位点遗传变异分析

肠毒素大肠杆菌 (ETEC) F18是引起仔猪断奶后水肿和腹泻病的主要病原菌, a-1岩藻糖转移酶(FUT1)基因是ECEC F18侵染猪小肠的受体蛋白基因。利用PCR-RFLP方法检测了1个野猪以及20个中外家猪猪种(群)共696个个体在FUT1基因开放阅读框架的857核苷酸位点的遗传变异, 结果表明: 在所有猪种中, 均未检测到抗性的AA型纯合子, 在外来猪种杜洛克和约克夏、国内猪种临高猪和杂交猪种中检测到AG型杂合子, 外来猪种中的皮特兰、长白猪以及除临高猪外的所有国内猪种和野猪均表现为极端的单态分布, 只有易感的GG基因型。研究结果提示, 中国地方猪种不具备抵抗ETEC F18大肠杆菌的遗传基础, 与外来猪种确实存在差异, 这种差异可能与各自不同的起源有关, ETEC F18抗性基因可能起源于欧洲野猪; 并推测猪种的生长速度与ETEC F18大肠杆菌病的发生具有密切的关系。     

华东地区致初生仔猪腹泻大肠杆菌的O血清型和毒力因子

从江苏、江西、安徽等7个省疑似黄、白痢直肠棉拭及病死猪的十二指肠和肠系膜淋巴结中分离鉴定出339株病原性大肠杆菌。经O血清型鉴定,除77株未能定型、41株自凝外,测定出221个分离株的O血清型,这些分离株覆盖了64个血清型,以O107、O101、O20、O93、O11和O149为主,共99株,占定型菌株的44.80%。这些血清型与已报道的常见血清型间存在一定差异。运用黏附素单抗对以上菌株进行F4、F5、F6、F18、F41　5种黏附素检测,共97个分离株表达黏附素(28061%),而表达两种和3种黏附素的菌株分别有22株和8株,它们分别占表达黏附素菌株的22.68%和8.25%,其中单独表达F4、F6、F5+F41黏附素菌株分别有18、30、15株,分别占表达黏附素菌株的18.56%、30.93%和15.46%;同时运用多重PCR对其中145个分离株进行毒素基因(Sta、STb、LT、SLT2e)的检测,拥有Sta和STb毒素基因的菌株分别占检测菌株的51.72%和3724%。F6、F4、F5+F41和Sta、STb为该地区致初生仔猪腹泻大肠杆菌常见的毒力因子。     

大肠杆菌F18菌毛操纵子全基因克隆、表达及生物学活性

利用PCR技术以猪产肠毒素大肠杆菌F18标准菌株107/86和2134P基因组DNA为模板成功地扩增出编码F18ab和F18ac完整菌毛操纵子fed基因。将它们分别克隆入表达质粒载体pET-22b( ),结合酶切和核苷酸序列分析证明了PCR预期扩增产物的正确性。然后将克隆的重组载体DNA转化至大肠杆菌BL21(DE3),构建和筛选出分别含F18ab和F18ac完整fed基因的重组菌,经过IPTG诱导表达,在电镜下观察到上述两种重组菌能分别大量表达F18ab和F18ac菌毛。用热抽提法提纯其诱导表达的F18ab和F18ac菌毛,经SDS-PAGE电泳和考马斯亮蓝染色发现提纯后菌毛获单一分子量约为15kDa蛋白条带,免疫家兔后制备出高效价的兔抗血清,玻板凝集试验和Western blot结果表明:体外诱导表达的F18ab和F18ac菌毛具有和野生F18菌毛相同的抗原性。用表达F18ab和F18ac菌毛的上述2株重组菌分别进行小肠上皮细胞体外吸附试验和吸附抑制试验,结果表明:2株重组菌和野生菌株一样具有较强的粘附易感仔猪小肠上皮细胞的能力,而用表达F18ab和F18ac重组菌提纯的菌毛制备出兔抗血清都能有效地抑制上述重组菌或野生菌株对易感仔猪小肠上皮细胞的吸附结合。     

大肠杆菌F4在3个品种猪中的黏附模式

大肠杆菌F4是引起仔猪断奶前腹泻的一种主要细菌,F4黏附于小肠上皮细胞是其致病的前提。小肠上皮细胞的F4受体是由常染色体上的基因编码的,如果无受体,仔猪表现为大肠杆菌抗性。为了研究黏附的遗传机制,本实验利用大白、长白、松辽黑猪的小肠刷状缘细胞与F4ab、F4ac、F4ad进行离体黏附实验,结果发现3品种(系)猪之间黏附情况存在显著差别(P<0.01),松辽黑猪以非黏附型为主,而长白猪中黏附型比例较高,在同一品种猪内,3种菌株的黏附比例在松辽黑猪内和大白猪内有极显著差异,但在长白猪中无显著差异。从3种细菌与刷状缘的黏附模式来看,F4ab、F4ac和F4ad分别有3种不同的受体,它们可能是由3个不同的基因座编码的。     

粤北地区仔猪腹泻大肠杆菌分离鉴定及耐药性分析

为了解粤北地区规模化猪场仔猪腹泻大肠杆菌耐药情况,为该病防控提供用药参考,对来自6个规模化猪场疑似仔猪大肠杆菌引起的腹泻粪便和肠道内容物进行了大肠杆菌分离鉴定,对分离鉴定的40株大肠杆菌进行了药敏试验。结果表明,分离菌株对22种受试药物均产生不同程度耐药性,强力霉素和四环素耐药菌株比例最高,达到97.5%,其次是复方新诺明、庆大霉素、氯霉素和红霉素耐药菌株达到80%以上。敏感性最高的药物为丁胺卡那霉素,其次是头孢西丁,敏感菌株比例分别为85%和84.5%。试验菌株均产生不同程度多重耐药性,最少为4重耐药性,10重及以上耐药性菌株比例达到80%以上。研究表明,粤北地区仔猪腹泻大肠杆菌耐药性严重,要重视药敏监测,以指导合理选用药物防控该病。     

猪源大肠杆菌F18菌毛的体外表达和抗原特性

【目的】揭示从仔猪腹泻和/或水肿病猪体内分离到的fedA+大肠杆菌所携带的毒力因子、F18菌毛在体外表达及其抗原变异情况。【方法】利用凝集试验测定O血清型,PCR方法检测毒力基因,单克隆抗体分析F18菌毛抗原特性。【结果】在75个fedA+分离株中,有62株测定出其O血清型,覆盖8种血清型,以O107和O139为主(74.2%);estI、estII、elt、stx-2e、astA、orfA、irp2、fyuA、ler和eaeA基因在这75个菌株中的检出率分别为64.0%、46.7%、28.0%、62.7%、26.7%、9.3%、9.3%、9.3%、1.3%和1.3%,其中仅拥有stx-2e基因的菌株有19株,同时拥有estI/estII/stx-2e基因的菌株有20株。单抗鉴定结果显示,在33株体外表达F18菌毛的菌株中,21株(63.6%)被鉴定为F18ac变体,2株(6.1%)被鉴定为F18ab变体,其余10株(30.3%)仅跟F18"a"因子单抗反应,而不跟F18"b"、"c"因子单抗反应。间接ELISA显示,11株单抗至少识别F18菌毛的6个表位,其中"a"因子至少有3个表位,"b"因子至少有2个表位,"c"因子至少有1个表位。【结论】在猪源菌株中,F18ab菌毛在体外表达率较低;F18ac菌毛在体外表达率较高,主要与肠毒素和O107血清型相关,同时我国存在F18菌毛的抗原变异。     

猪源大肠杆菌F18菌毛的体外表达和抗原特性

摘要:【目的】揭示从仔猪腹泻和/或水肿病猪体内分离到的fedA + 大肠杆菌所携带的毒力因子、F18菌毛在体外表达及其抗原变异情况。【方法】利用凝集试验测定O 血清型,PCR方法检测毒力基因,单克隆抗体分析F18菌毛抗原特性。【结果】在75个fedA + 分离株中,有62株测定出其O血清型,覆盖8种血清型,以O107和O139为主(74.2%) ;estI、estII、elt、stx-2e、astA、orfA、irp2、fyuA、ler和eaeA基因在这75个菌株中的检出率分别为64.0%、46.7%、28.0%、62.7%、26.7%、9.3%、9.3%、9.3%、1.3%和1.3%,其中仅拥有stx-2e基因的菌株有19株,同时拥有estI/estII/stx-2e基因的菌株有20株。单抗鉴定结果显示,在33株体外表达F18菌毛的菌株中,21株(63.6%)被鉴定为F18ac变体,2株(6.1%) 被鉴定为F18ab变体,其余10株(30.3%)仅跟F18“a”因子单抗反应,而不跟F18“b”、“c”因子单抗反应。间接ELISA显示,11株单抗至 少识别F18菌毛的6个表位,其中“a”因子至少有3个表位,“b”因子至少有2个表位,“c”因子至少有1个表位。【结论】在猪源菌株中,F18ab菌毛在体外表达率较低;F18ac菌毛在体外表达率较高,主要与肠毒素和O107血清型相关,同时我国存在F18菌毛的抗原变异。     

猪RegIIIγ在小肠表达的特征及细胞类型

RegⅢγ是一种新型的抗菌肽,主要在哺乳动物的肠道和皮肤表达,具有抗菌、抗炎、调节免疫反应和促进细胞增殖等生理功能。为了解猪RegⅢγ在肠道的表达特点,我们通过荧光定量PCR、蛋白质免疫印迹和免疫组化分别确定了猪RegⅢγmRNA和蛋白在仔猪肠道的表达水平以及在肠道表达的细胞类型。结果表明RegⅢγmRNA和蛋白质在十二指肠、空肠和回肠三个部位的表达水平无明显差异;除mRNA水平在断奶后有一个明显下降外,mRNA和蛋白质表达水平呈现随着周龄的增加而升高的趋势。免疫组化分析表明RegⅢγ蛋白主要在肠粘膜吸收性上皮细胞和Paneth细胞内表达。     

表达ST1-LTB-a-b融合蛋白基因工程菌株的构建及其免疫原性分析

采用分子生物学技术构建了含有ST1-LTB-a-b融合基因的重组菌株BL21(DE3)(pETST3LTBab), SDS-PAGE和 Western blotting分析表明ST1-LTB-a-b融合基因在大肠杆菌中得到了高效表达, 融合蛋白分子量约为110 kD; 20 L发酵罐培养得到的最佳诱导条件为: 重组菌株以1%接种量、5 L/min通气量培养3 h后加终浓度为0.03 mol/L的乳糖诱导, 通气量升至12.5 L/min继续培养6 h, 表达量占菌体总蛋白的38.53%; 表达的ST1-LTB-a-b融合蛋白无毒性但具有免疫原性, 可以抵抗大肠杆菌和产气荚膜梭菌的感染; 构建的重组菌株BL21(DE3)(pETST3LTBab)有望作为预防仔猪腹泻基因工程疫苗的候选生产菌株。     

Genetic variation in exon 10 of the BPI gene is associated with Escherichia coli F18 susceptibility in Sutai piglets

Our aim was to investigate the effect of the porcine bactericidal/permeability-increasing protein (BPI) on the susceptibility to enterotoxigenic Escherichia coli F18 (ETEC F18). Specifically, we wanted to determine whether the HpaII restriction polymorphism in exon 10 of BPI mediates susceptibility to ETEC F18. Thirty verified ETEC F18-resistant and thirty susceptible Sutai (Duroc × Taihu) piglets were identified using the receptor binding assay. Exon 10 of the BPI gene produced the AA, BB, and AB genotypes after HpaII digestion. The genotype distribution among ETEC F18-resistant piglets was significantly different from that among susceptible piglets. Among piglets with the AA genotype, 90% were ETEC F18-resistant; this percentage of resistant piglets was significantly higher than the percentage of resistant piglets with the AB (57.1%) and BB genotypes (17.4%). There was high expression only in the tissues of the duodenum and jejunum, wherein the expression levels in the ETEC F18-resistant group were significantly higher than those in the susceptible group (P < 0.05). The average expression levels in individuals with the AA genotype were significantly higher than those in individuals with the AB or BB genotype (P < 0.05), while the results of Western blot show the same evidences as real time PCR. These results indicate that the upregulation of porcine BPI gene expression in the small intestines plays a direct role in resistance to ETEC F18 infection. The AA genotype for the HpaII site in exon 10 of the porcine BPI gene was demonstrated to be an anti-ETEC F18 marker and could be used for selective breeding to enhance ETEC F18 resistance.     

Study on the age-dependent tissue expression of FUT1 gene in porcine and its relationship to E. coli F18 receptor

Escherichia coli (E. coli) that produces adhesin F18 is the main pathogen responsible for porcine post-weaning diarrhea and edema disease. The receptor for E. coli F18 has not been described in pigs, however the alpha (1,2)-fucosyltransferase (FUT1) gene on chromosome 6 has been proposed as a candidate. The objective of this study, therefore, was to investigate the relationship between FUT1 gene expression and E. coli F18 receptor in Sutai pigs of different ages (8-, 18-, 30- and 35-day-old). FUT1 gene expression was detected in 11 pig tissues with the highest level in lung, and expressed consistently at the four time points. In most tissues, FUT1 gene expression levels decreased from days 8 to 18, then continually increased on days 30 and 35, with expression around weaning time higher than that on day 8. Gene ontology and pathway analysis showed that FUT1 was involved in 32 biological processes, mainly those integral to the membrane, or involved in glycosylation, as well as regulation of binding, interestingly participating in three pathways related to glycosphingolipid biosynthesis. From this analysis and the high linkage disequilibrium between the FUT1 gene and the E. coli F18 receptor locus, we can speculate that higher expression of the FUT1 gene in small intestine is beneficial to the formation of receptors to the E. coli F18 strain and is related to the sensitivity to the pathogen.     

Cloning and analysis of the sfrB (sex factor repression) gene of Escherichia coli K-12.

The sfrB gene of Escherichia coli K-12 and the rfaH gene of Salmonella typhimurium LT2 are homologous, controlling expression of the tra operon of F and the rfa genes for lipopolysaccharide synthesis. We have determined a restriction map of the 19-kilobase ColE1 plasmid pLC14-28 which carries the sfrB gene of E. coli. After partial Sau3A digestion of pLC14-28, we cloned a 2.5-kilobase DNA fragment into the BamHI site of pBR322 to form pKZ17. pKZ17 complemented mutants of the sfrB gene of E. coli and the rfaH gene of S. typhimurium for defects of both the F tra operon and the rfa genes. pKZ17 in minicells determines an 18-kilodalton protein not determined by pBR322. A Tn5 insertion into the sfrB gene causes loss of complementing activity and loss of the 18-kilodalton protein in minicells, indicating that this protein is the sfrB gene product. These data indicate that the sfrB gene product is a regulatory element, since the single gene product elicits the expression of genes for many products for F expression and lipopolysaccharide synthesis.     

Preferential binding of the neutrophil cytoplasmic granule-derived bactericidal/permeability increasing protein to target bacteria. Implications and use as a means of purification

The specificity of the basic bactericidal/permeability increasing protein (BPI) of polymorphonuclear leukocytes (PMN) for gram-negative bacteria is attributable to its strong attraction for the negatively charged envelope LPS. The antibacterial activity of PMN homogenates or extracts toward Escherichia coli corresponds to their BPI content and is blocked by anti-BPI IgG, suggesting that BPI action is unaffected by the presence of other PMN proteins. To test if BPI is preferentially bound to E. coli when other antibacterial proteins are present, we have measured binding in buffered (pH 7.5) balanced salts solution of [125I] human BPI to E. coli J5 in the presence and absence of other human PMN granule proteins. BPI binding is saturable with an apparent K = 23 nM and 2.2 million binding sites/cell. While binding of [125I] human BPI is competitively inhibited by human or rabbit BPI, it is only weakly inhibited by myeloperoxidase, lysozyme, or cathepsin G. In contrast, myeloperoxidase binding to E. coli is strongly inhibited by BPI. Moreover, incubation of E. coli with crude extracts of PMN or CML spleen results in near quantitative binding of BPI, identified by silver staining and immunoblotting after SDS-PAGE of the washed E. coli pellet, without recognizable binding of other leukocyte proteins (greater than 98% of added total protein is recovered in supernatant). After addition of 200 mM MgCl2, approximately 80% of bound BPI is released as fully active and pure protein (as judged by SDS-PAGE and HPLC). Thus the selective and reversible binding of BPI in crude PMN extracts to target bacteria provides a one-step "affinity" purification procedure.     

Genetic exchange between Escherichia coli strains in the mouse intestine

Germ-free mice contaminated with selected Escherichia coli strains were used for experiments designed to demonstrate gene transfer and recombinant formation in vivo. The well-characterized conjugation system of E. coli K-12 was examined in these experiments. Contamination of germ-free mice with a polyauxotrophic F(-) strain followed by the addition of isogenic Hfr, F', or F(+) strains resulted in the appearance of all recombinant classes at frequencies that would be expected from an in vitro mating experiment. Inheritance of unselected donor markers occurred at frequencies that were dependent on linkage relationships established in experiments in vitro. The presence of Lactobacillus had no influence on gene transfer and recombinant formation in an F' x F(-) in vivo mating. The R factor ROR-1 was transferred from E. coli strain M7-18 to an E. coli F(-) strain in the mouse intestine.     

Ovocalyxin-36 and other LBP/BPI/PLUNC-like proteins as molecular actors of the mechanisms of the avian egg natural defences

The chicken egg possesses physical and chemical barriers to protect the embryo from pathogens. OCX-36 (ovocalyxin-36) was suggested to be a 36?kDa eggshell-specific protein that is secreted by the regions of the oviduct responsible for eggshell formation. Its expression is strongly up-regulated during shell calcification. This protein was also detected in vitelline membrane and expressed in gut tissues. Analysis of the OCX-36 protein sequence revealed that OCX-36 is related to the BPI (bactericidal permeability-increasing proteins)/LBP [LPS (lipopolysaccharide)-binding proteins]/PLUNC (palate, lung and nasal epithelium clone) superfamily, and that there are strong similarities between the exon/intron organization of the mammalian LBP/BPI and the avian OCX-36 genes. A recent study revealed that OCX-36 originates from a tandem duplication of an ancestral BPI/LBP/PLUNC gene, after the divergence of birds and mammals. Its antimicrobial activity was recently investigated and it was shown that OCX-36 binds to LPS from Escherichia coli. High-throughput methodologies have led to the identification of approximately 1000 new egg proteins. Among these are LBP/BPI proteins that might play a role in the natural defences of the egg to protect the embryo during its development in the external milieu, and may function to keep the table egg free of pathogens. The function of these BPI-like molecules is the subject of intense research to characterize their putative LPS-binding properties and antimicrobial activity.