bfpD | GeneID:1238606 | Escherichia coli

AAC44043   BAA84843   NP_053070  

1. [ ] Crowther LJ, et al. (2005) "The ATPase activity of BfpD is greatly enhanced by zinc and allosteric interactions with other Bfp proteins." J Biol Chem. 280(26):24839-24848. PMID:15866879

Type IV pilus biogenesis, protein secretion, DNA transfer, and filamentous phage morphogenesis systems are thought to possess similar architectures and mechanisms. These multiprotein complexes include members of the PulE superfamily of putative NTPases that have extensive sequence similarity and probably similar functions as the energizers of macromolecular transport. We purified the PulE homologue BfpD of the enteropathogenic Escherichia coli bundle-forming pilus (BFP) biogenesis machine and characterized its ATPase activity, providing new insights into its mode of action. Numerous techniques revealed that BfpD forms hexamers in the presence of nucleotide. Hexameric BfpD displayed weak ATPase activity. We previously demonstrated that the N termini of membrane proteins BfpC and BfpE recruit BfpD to the cytoplasmic membrane. Here, we identified two BfpD-binding sites, BfpE(39-76) and BfpE(77-114), in the N terminus of BfpE using a yeast two-hybrid system. Isothermal titration calorimetry and protease sensitivity assays showed that hexameric BfpD-ATPgammaS binds to BfpE(77-114), whereas hexameric BfpD-ADP binds to BfpE(39-76). Interestingly, the N terminus of BfpC and BfpE(77-114) together increased the ATPase activity of hexameric BfpD over 1200-fold to a V(max) of 75.3 mumol of P(i) min(-1) mg(-1), which exceeds by over 1200-fold the activity of other PulE family members. This augmented activity occurred only in the presence of Zn(2+). We conclude that allosteric interactions between BfpD and BfpC and BfpE dramatically stimulate its ATPase activity. The differential nucleotide-dependent binding of hexameric BfpD to BfpE(39-76) and BfpE(77-114) suggests a model for the mechanism by which BfpD transduces mechanical energy to the biogenesis machine.

2. [ ] Tobe T, et al. (1999) "Complete DNA sequence and structural analysis of the enteropathogenic Escherichia coli adherence factor plasmid." Infect Immun. 67(10):5455-5462. PMID:10496929

The complete nucleotide sequence and organization of the enteropathogenic Escherichia coli (EPEC) adherence factor (EAF) plasmid of EPEC strain B171 (O111:NM) were determined. The EAF plasmid encodes two known virulence-related operons, the bfp operon, which is composed of genes necessary for biosynthesis of bundle-forming pili, and the bfpTVW (perABC) operon, composed of regulatory genes required for bfp transcription and also for transcriptional activation of the eae gene in the LEE pathogenicity island on the EPEC chromosome. The 69-kb EAF plasmid, henceforth designated pB171, contains, besides the bfp and bfpTVW (perABC) operons, potential virulence-associated genes, plasmid replication and maintenance genes, and many insertion sequence elements. Of the newly identified open reading frames (ORFs), two which comprise a single operon had the potential to encode proteins with high similarity to a C-terminal region of ToxB whose coding sequence is located on pO157, a large plasmid harbored by enterohemorrhagic E. coli. Another ORF, located between the bfp and bfpTVW operons, showed high similarity with trcA, a bfpT-regulated chaperone-like protein gene of EPEC. Two sites were found to be putative replication regions: one similar to RepFIIA of p307 or F, and the other similar to RepFIB of R100 (NR1). In addition, we identified a third region that contains plasmid maintenance genes. Insertion elements were scattered throughout the plasmid, indicating the mosaic nature of the EAF plasmid and suggesting evolutionary events by which virulence genes may have been obtained.

3. [ ] Sohel I, et al. (1996) "Enteropathogenic Escherichia coli: identification of a gene cluster coding for bundle-forming pilus morphogenesis." J Bacteriol. 178(9):2613-2628. PMID:8626330

Sequence flanking the bfpA locus on the enteroadherent factor plasmid of the enteropathogenic Escherichia coli (EPEC) strain B171-8 (O111:NM) was obtained to identify genes that might be required for bundle-forming pilus (BFP) biosynthesis. Deletion experiments led to the identification of a contiguous cluster of at least 12 open reading frames, including bfpA, that could direct the synthesis of a morphologically normal BFP filament. Within the bfp gene cluster, we identified open reading frames that share homology with other type IV pilus accessory genes and with genes required for transformation competence and protein secretion. Immediately upstream of the bfp gene cluster, we identified a potential replication origin including genes that are predicted to encode proteins homologous with replicase and resolvase. Restriction fragment length polymorphism analysis of DNA from six additional EPEC serotypes showed that the organization of the bfp gene cluster and its juxtaposition with a potential plasmid origin of replication are highly conserved features of the EPEC biotype.

4. [ ] Stone KD, et al. (1996) "A cluster of fourteen genes from enteropathogenic Escherichia coli is sufficient for the biogenesis of a type IV pilus." Mol Microbiol. 20(2):325-337. PMID:8733231

Enteropathogenic Escherichia coli (EPEC) adhere to epithelial cells in microcolonies, a pattern termed localized adherence (LA). LA is dependent upon the presence of 50-70 MDa plasmids, termed EPEC adherence factor (EAF) plasmids. Expression of an EAF plasmid-encoded type IV fimbria, the bundle-forming pilus (BFP), is associated with the LA phenotype. TnphoA insertions in bfpA, the gene encoding the major structural subunit of the BFP, abolish LA. While bfpA::TnphoA mutants cannot be complemented for LA by plasmids carrying the bfpA gene alone in trans, this work shows that they can be complemented by plasmids carrying the bfpA gene, as well as approximately 10 kb of downstream sequence, suggesting that such mutations have polar effects on downstream genes. The identification and characterization of a cluster of 13 genes immediately downstream of bfpA are described. The introduction into a laboratory Escherichia coli strain of a plasmid containing these 14 bfp gene cluster genes, along with pJPN14, a plasmid containing another fragment derived from the EAF plasmid, confers LA ability and BFP biogenesis. However, when a mutation is introduced into the last gene of the bfp cluster, neither LA nor BFP biogenesis is conferred. This work also provides evidence to show that the fragment cloned in pJPN14 encodes a factor(s) which results in increased levels of the pilin protein. Finally, it is shown that expression of the 14 genes in the bfp cluster from an IPTG-inducible promoter, in the absence of pJPN14, is sufficient to reconstitute BFP biogenesis in a laboratory E. coli strain, but is insufficient for LA. This is the first report demonstrating the reconstitution of a type IV pilus in a laboratory E. coli strain with a defined set of genes. The BFP system should prove to be a useful model for studying the molecular mechanisms of type IV pilus biogenesis.