鸡白痢沙门氏菌生物被膜形成相关基因rpoE的鉴定

【目的】通过鸡白痢沙门氏菌基因表达和缺失株生物特性的测定,鉴定其生物被膜形成的相关σ因子。【方法】利用结晶紫染色定量法测定沙门氏菌生物被膜形成能力;通过触酶试验测定rpo S活性,确定rpo S基因依赖性和非依赖性生物被膜形成株;利用建立的荧光定量PCR方法比较rpo S基因非依赖株在指数期和生物被膜形成期6个σ因子的基因表达差异;运用Red同源重组系统构建所鉴定σ因子基因缺失株,并测定野生株和基因缺失株对于环境应激的抵抗力差异。【结果】鸡白痢沙门氏菌S6702能够形成生物被膜,触酶试验阴性,确定S6702为rpo S基因非依赖性生物被膜形成株;荧光定量PCR检测显示,培养4-24 h后S6702中rpo E基因表达量最高;与野生株相比,Δrpo S缺失株保留了生物被膜形成能力,而Δrpo E缺失株不能形成生物被膜。rpo S和rpo E基因缺失株对于环境应激的抵抗力均显著降低。【结论】在rpo S基因非依赖性生物被膜形成株中,rpo E基因为参与生物被膜形成调控的σ因子之一,这一发现可用于进一步研究沙门氏菌生物被膜形成的调控机制。     

肠炎沙门氏菌鸡源株ompR 基因缺失株的构建及生物学特性与亲本株的比较

【目的】为了探讨ompR基因在肠炎沙门氏菌生物被膜形成及毒力中的作用。【方法】以肠炎沙门氏菌作为母本,运用自杀性载体pGMB151构建了ompR基因缺失株,结晶紫染色法和扫描电镜观察测定缺失株的生物被膜形成能力,细胞的吸附和侵入及小鼠攻毒试验测定缺失株的毒力。【结果】RT-PCR和蛋白表达证明了ompR基因缺失株构建成功;该缺失株不表达纤维素和菌毛,不形成生物被膜;上皮细胞吸附和侵入试验表明缺失株与野生株具有相同的吸附和侵入率;BALB/c鼠腹腔感染性试验表明,缺失株的半数致死量为106.67CFU,而野生株的半数致死量小于2 CFU。【结论】ompR基因既是肠炎沙门氏菌生物膜形成的调控基因,又是重要的毒力基因。     

Identification of the genes involved in Riemerella anatipestifer biofilm formation by random transposon mutagenesis

Riemerella anatipestifer causes epizootics of infectious disease in poultry that result in serious economic losses to the duck industry. Our previous studies have shown that some strains of R. anatipestifer can form a biofilm, and this may explain the intriguing persistence of R. anatipestifer on duck farms post infection. In this study we used strain CH3, a strong producer of biofilm, to construct a library of random Tn4351 transposon mutants in order to investigate the genetic basis of biofilm formation by R. anatipestifer on abiotic surfaces. A total of 2,520 mutants were obtained and 39 of them showed a reduction in biofilm formation of 47%-98% using crystal violet staining. Genetic characterization of the mutants led to the identification of 33 genes. Of these, 29 genes are associated with information storage and processing, as well as basic cellular processes and metabolism; the function of the other four genes is currently unknown. In addition, a mutant strain BF19, in which biofilm formation was reduced by 98% following insertion of the Tn4351 transposon at the dihydrodipicolinate synthase (dhdps) gene, was complemented with a shuttle plasmid pCP-dhdps. The complemented mutant strain was restored to give 92.6% of the biofilm formation of the wild-type strain CH3, which indicates that the dhdp gene is associated with biofilm formation. It is inferred that such complementation applies also to other mutant strains. Furthermore, some biological characteristics of biofilm-defective mutants were investigated, indicating that the genes deleted in the mutant strains function in the biofilm formation of R. anatipestifer. Deletion of either gene will stall the biofilm formation at a specific stage thus preventing further biofilm development. In addition, the tested biofilm-defective mutants had different adherence capacity to Vero cells. This study will help us to understand the molecular mechanisms of biofilm development by R. anatipestifer and to study the pathogenesis of R. anatipestifer further.     

aroA and aroD mutations influence biofilm formation in Salmonella Enteritidis

aro mutants of Salmonella enterica are frequently used as live vaccines for the oral vaccination of domestic animals. Interestingly, besides their auxotrophy, they appear to be of reduced resistance to the components of innate immune response due to a defect in outer membrane and/or cell wall integrity. Because different extracellular structures associated with the cell wall or outer membrane are involved in biofilm formation, we were interested in the ability of aroA and aroD mutants of S . Enteritidis to adhere to solid surfaces. We found that aroA and aroD mutants did not adhere to solid surfaces although they bind Congo red and produced d -mannose and d -glucose capsular polysaccharides in the same amounts as the wild-type strain. However, the aro mutants exhibited a decreased production of cellulose, N -acetyl- d -glucosamine or N -acetylneuraminic acid containing capsular polysaccharide and fimbriae which explains their inability to form biofilms. aroA and aroD containing plasmids complemented all the defects of the aro mutants. Beside its attenuation for different hosts, the loss of ability to form biofilm is an additional interesting characteristic of aro mutants.     

Transfer of a conjugative transposon, Tn5397 in a model oral biofilm

A tetracycline resistance profile was established from a microcosm dental plaque in a constant depth film fermenter. The fermenter was inoculated with a Bacillus subtilis strain which contained the conjugative transposon, Tn5397, which confers tetracycline resistance upon its host. After 6 hour and 24 hour the tetracycline resistance profile of the biofilm was redetermined and a tetracycline resistant Streptococcus species was isolated. A molecular analysis of this strain confirmed that Tn5397 was present in the genomic DNA of the isolate. These data represent the first report, to our knowledge, of intergeneric transfer of a conjugative transposon in a mixed species biofilm and demonstrates the ability of conjugative transposons to disseminate antibiotic resistance genes in a mixed species environment.     

A Streptococcus uberis transposon mutant screen reveals a negative role for LiaR homologue in biofilm formation

Deinococcus spp are among the most radiation‐resistant micro‐organisms that have been discovered. They show remarkable resistance to a range of damage caused by ionizing radiation, desiccation, UV radiation and oxidizing agents. Traditionally, Escherichia coli and Saccharomyces cerevisiae have been the two platforms of choice for engineering micro‐organisms for biotechnological applications, because they are well understood and easy to work with. However, in recent years, researchers have begun using Deinococcus spp in biotechnologies and bioremediation due to their specific ability to grow and express novel engineered functions. More recently, the sequencing of several Deinococcus spp and comparative genomic analysis have provided new insight into the potential of this genus. Features such as the accumulation of genes encoding cell cleaning systems that eliminate organic and inorganic cell toxic components are widespread among Deinococcus spp. Other features such as the ability to degrade and metabolize sugars and polymeric sugars make Deinococcus spp. an attractive alternative for use in industrial biotechnology.     

Synergism in biofilm formation between Salmonella enteritidis and a nitrogen-fixing strain of Klebsiella pneumoniae

A laboratory reactor, which simulates biofilm formation in water pipes, was used to study interactions in biofilm formation between a nitrogen-fixing strain of Klebsiella pneumoniae and Salmonella enteritidis. The level of attachment of Salm. enteritidis was higher in the binary biofilm than in the single species biofilm. In the initial colonization phase the binary biofilm contained a much higher proportion of metabolically active cells than in single species biofilms formed by either Salm. enteritidis or Kl. pneumoniae. When a pulse of Salm. enteritidis was passed over an already established biofilm of Kl. pneumoniae it rapidly became integrated into the biofilm, from where it was subsequently released into the water column, along with Kl. pneumoniae. Klebsiella pneumoniae fixed nitrogen in the presence of Salm. enteritidis in both types of biofilm.     

Transposon mutagenesis of nuclear photosynthetic genes in Zea mays

The discovery of a new maize (Zea mays L.) transposon system, Mutator, and the cloning of the 1.4 kilobase transposon, Mul, have made feasible the isolation of nuclear photosynthetic genes which are recognized only by their mutant phenotype. Mutant maize plants which express a high chlorophyll fluorescent (hcf) phenotype due to a defect in the electron transport or photophosphorylation apparatus have been isolated following mutagenesis with an active Mutator stock. The affected genes and their products in these mutants are inaccessible to classical methods of analysis. However, mutagenesis with the Mutator transposon makes it possible to isolate these genes.Although the PSII-deficient mutant hcf3 has been thoroughly studied by classical photo-biological methods, the nature of the lesion which results in the observed phenotype has not been established. A Mutator-induced allele of hcf3 has been isolated. A fragment of genomic DNA has been identified which is homologous to Mul and co-segregates with the mutant phenotype. This fragment is expected to contain a portion of the hcf3 locus which will be used to clone the normal gene. Direct study of the gene can provide insight into the nature and function of its polypeptide product.This approach can be used to study any photosynthetic gene which has been interrupted by a transposon. The isolation of more than 100 different chemically-induced hcf mutants, most of which can not be fully characterized using classical means, indicates the wealth of information which can be obtained using a transposon tagging technique.     

Salmonella enteritidis temperature-sensitive mutants protect mice against challenge with virulent Salmonella strains of different serotypes

The protection conferred by temperature-sensitive mutants of Salmonella enteritidis against different wild-type Salmonella serotypes was investigated. Oral immunization with the single temperature-sensitive mutant E/1/3 or with a temperature-sensitive thymine-requiring double mutant (E/1/3T) conferred: (i) significant protection against the homologous wild-type Salmonella strains; (ii) significant cross-protection toward high challenge doses of S. typhimurium. Significant antibody levels against homologous lipopolysaccharide and against homologous and heterologous protein antigens were detected in sera from immunized mice. Moreover, a wide range of protein antigens from different Salmonella O serotypes were recognized by sera from immunized animals. Besides, primed lymphocytes from E/1/3 immunized mice recognized Salmonella antigens from different serotypes. Taken together, these results indicate that temperature-sensitive mutants of S. enteritidis are good candidates for the construction of live vaccines against Salmonella.