Regulation of biofilm formation and outer membrane protein expression in Vibrio cholerae by iron

Craig, Stephanie Anne

10 September 2012

Vibrio cholerae, a natural inhabitant of aquatic environments and the causative agent of the diarrheal disease cholerae, requires iron for survival. Since one of the key factors in the survival of V. cholerae in the environment is the formation of biofilms, we determined the effect of iron on this aspect of the pathogens lifestyle. Since wild type V. cholerae forms a much more robust biofilm in the presence of exogenous iron we tested mutants in iron transport and regulation and found that a mutation in the gene encoding an iron-regulated small RNA, RyhB, was clearly attenuated in the biofilm assay. We determined through microarray analysis that the ryhB mutant has altered regulation of genes involved in many systems that may be involved in biofilm formation including amino acid biosynthesis, the TCA cycle, motility and chemotaxis, and the expression of outer membrane proteins. Due to the pleiotropic regulatory effects of RyhB, it is unlikely that any one individual gene or system regulated by RyhB is the cause of the biofilm defect, but rather the sum effect of the regulatory changes is decreased biofilm formation. Additionally, we discovered that the outer membrane protein, OmpT, is positively regulated by iron and Fur. Generally, when Fur has acted as a positive regulator in previous studies, it has been ultimately shown to do so by negatively regulating the negative regulator, RyhB. However, the positive regulation of ompT by Fur is independent of RyhB. While CRP, a positive regulator of ompT expression, did not affect iron-dependent regulation of ompT, over-expression of the negative regulator ToxR abolishes the iron and Fur dependent regulation. Sequence analysis has revealed a possible Fur box approximately 70 base pairs upstream of the transcriptional start site in a region that overlaps both a ToxR binding site and a CRP binding site in the ompT promoter. We propose the model that in iron-replete environments under ToxR repressing conditions, such as when amino acids are limiting, Fur can further increase the expression of ompT. / text

Cholera--Genetic aspects

Cholera--Pathophysiology

Iron--Physiological effect

Biofilms

Membrane proteins

Development of a cloning system for gene expression in Pasteurella multocida

Jablonski, Lynn McGonagle

04 May 2006

To identify antigens unique to live Pasteurella multocida P1059, 10 week old specific pathogen-free (SPF) chickens were vaccinated three times with one of the following: viable cells from P. multocida P1059, 3865, 3866, or cells from formalin-killed strain PI059 or formalin-killed strain P1059 that were opsonized with antiserum directed against killed strain PI059 prior to immunization. Vaccinated birds were challenged with 1.5 x 10⁷ CFU of live strain P1059. Eight, 71, 86, and 50% of the birds that received live strains P1059, 3865, 3866 and killed strain P1059 (respectively), exhibited clinical signs of fowl cholera. Antisera directed against live strain PI059 recognized 23 proteins ranging from 14- to 92-kilodaltons (kDa); 20 of which were adsorbed by strain 3865. The molecular masses of the three remaining proteins were 25-, 30- and 43-kDa. A genomic library of strain P1059 was constructed using the plasmid vector pUC-19 and screened with antisera against live strain P1059; 12 out of 4,100 clones were recognized. The inserts of the plasmids from these clones ranged from 0.48- to 6.S-kilobases (kb) in length. Five of the 12 clones expressed proteins with molecular masses of 34-, 37-, 42-, 46- and 55-kDa. Escherichia coli CSR603(pOP43- 2G) and CSR603(pOP33-SF) expressed proteins recognized by antisera directed against live strain P1059. E. coli CSR603(pOP43-2G) expressed an epitope(s) which was recognized by antisera directed against strains 3865 and 3866. Conditions for transformation were optimized and attempts were made to create a shuttle vector in order to establish a cloning system for gene expression in P. multocida. The highest efficiency of transformation (1.25 x 10⁷ CFU/μg DNA) was obtained when 7.6 x 10¹⁰ cells of P. multocida R473 were electroporated at 12.5 kV cm⁻¹ for 10 ms with 5 ng of the plasmid, p VM109. Of the six strains tested, representing serogroups A, B, D and E, all were transformed successfully. Vectors including pBR322, pUC19, pJFF224-NX and pSP329 were unable to transform P. multocida. To create a shuttle vector for gene expression in P. multocida, a Pasteurella plasmid (pLAR-1) was cloned in both orientations into the BamH I site of pBR322. These plasmids, pLRBR-21 and pLRBR-67, had a transformation efficiency of 4.5 to 8 x 10⁴ CFU/μg of DNA in strain R473. Chromosomal DNA containing the Brucella abortus copper-zinc superoxide dismutase gene was cloned into the Cla I site of pLRBR-21. The 1.8-kb fragment encoding a 42-kDa Pasteurella protein was cloned into an additional unique site (Nru 1) of pLRBR-21 to determine if this plasmid was a viable shuttle vector for gene expression in P. multocida. / Ph. D.

LD5655.V856 1993.J335

Chicken cholera -- Genetic aspects

Chicken cholera -- Immunological aspects

Pasteurella multocida -- Genetics