Characterization of the Adhesin of
            <i>Escherichia coli</i>
            F18 Fimbriae

Smeds, Andrèas; Hemmann, Karin; Jakava-Viljanen, Miia; Pelkonen, Sinikka; Imberechts, Hein; Palva, Airi

doi:10.1128/iai.69.12.7941-7945.2001

Cited by 49 publications

(48 citation statements)

References 13 publications

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“…In the case of F18 fibrillae, the major subunit FedA is assembled into a helix containing two subunits per turn (123). Minor fimbrial subunits have been implicated in the adherence of F18 fimbriae and AF/R1 fimbriae (48,148,307). However, in the case of F4 and F5 fimbriae, minor subunits are dispensable for adherence (22,303,304), and the major fimbrial subunits (FaeG and FanC) have been implicated in determining the binding activity of their respective adhesins (21,156,250).…”

Section: The -Fimbriae: Flexible Fibrillaementioning

confidence: 99%

“…7). The -fimbriae (FUP cluster 6) (367) comprise usher proteins required for the assembly of the F4 fimbrial antigen (K88 fimbriae) (FaeD) (20,22,224,245,315,316,338), the F5 fimbrial antigen (K99 fimbriae) (FanD) (1, 20, 149, 151, 247, [275][276][277]303), and the F18 fimbrial antigen (F107 fimbriae) (FedB) (147,148,307) found in porcine and bovine isolates of enterotoxigenic E. coli (51,362). Furthermore, this group includes adherence factor/rabbit 1 (AF/R1) fimbriae (AfrB) (48), an uncharacterized operon of E. coli (CshB), the locus for diffuse adherence (LdaD) of atypical enteropathogenic E. coli (294), plasmid-encoded fimbriae (PefC) of S. enterica serotype Typhimurium (96,218), and an intestinal colonization factor of rabbit enteropathogenic E. coli (RalD) (2).…”

Section: The -Fimbriae: Flexible Fibrillaementioning

confidence: 99%

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Evolution of the Chaperone/Usher Assembly Pathway: Fimbrial Classification Goes Greek

Nuccio

Bäumler

2007

Microbiol Mol Biol Rev

293

456

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SUMMARY Many Proteobacteria use the chaperone/usher pathway to assemble proteinaceous filaments on the bacterial surface. These filaments can curl into fimbrial or nonfimbrial surface structures (e.g., a capsule or spore coat). This article reviews the phylogeny of operons belonging to the chaperone/usher assembly class to explore the utility of establishing a scheme for subdividing them into clades of phylogenetically related gene clusters. Based on usher amino acid sequence comparisons, our analysis shows that the chaperone/usher assembly class is subdivided into six major phylogenetic clades, which we have termed α-, β-, γ-, κ-, π-, and σ-fimbriae. Members of each clade share related operon structures and encode fimbrial subunits with similar protein domains. The proposed classification system offers a simple and convenient method for assigning newly discovered chaperone/usher systems to one of the six major phylogenetic groups.

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Section: The -Fimbriae: Flexible Fibrillaementioning

confidence: 99%

Section: The -Fimbriae: Flexible Fibrillaementioning

confidence: 99%

Evolution of the Chaperone/Usher Assembly Pathway: Fimbrial Classification Goes Greek

Nuccio

Bäumler

2007

Microbiol Mol Biol Rev

293

456

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“…The functionality of this approach has been recently demonstrated with model systems (9,10,25). Regarding the adhesin of F18 fimbriae, we have shown that E. coli strains carrying this fimbrial type adhere to porcine intestinal epithelial cells via the FedF protein (42). Furthermore, we have recently mapped the receptor binding region of FedF, to be used as a putative surface antigen in lactic acid bacteria (LAB), between amino acid (aa) residues 60 and 109 of FedF (43).…”

mentioning

confidence: 99%

Receptor Binding Domain ofEscherichia coliF18 Fimbrial Adhesin FedF Can Be both Efficiently Secreted and Surface Displayed in a Functional Form inLactococcus lactis

Lindholm

Smeds

Palva

2004

Appl Environ Microbiol

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“…Two additional genes from the fed gene cluster, fedE and fedF, have been described as essential for fimbrial adhesion and fimbrial length [11]. However, until now it can not to evaluate F18 adhesive function in regard to either of the two gene products [12].…”

mentioning

confidence: 99%

Cloning and Expression of Genes Encoding F107-C and K88-1NT Fimbrial Proteins of Enterotoxigenic Escherichia coli from Piglets

et al. 2013

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We cloned two genes coding F107-C and K88-1NT fimbrial subunits from strains E. coli C and 1NT isolated from Thua Thien Hue province, Vietnam. The mature peptide of faeG gene from strain E. coli 1NT (called faeG-1NT) is 100 % similarity with faeG gene, while the CDS of fedA gene from strain C (called fedA-C) has a similarity of 97 % with the fedA gene. Expression of the faeG-1NT and fedA-C genes in E. coli BL21 Star TM (DE3) produced proteins of *31 and 22 kDa, respectively. The effect of IPTG concentration on the K88-1NT and F107-C fimbriae production was investigated. The results showed that 0.5 mM IPTG is suitable for higher expression of K88-1NT subunit, while 0.75 mM IPTG strongly stimulated expression of F107-C subunit. The optimal induction time for expression was also examined. Generally, highest expression of K88-1NT subunit occurred after 6 h of induction, while that of F107-C subunit is after 14 h.

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Characterization of the Adhesin of Escherichia coli F18 Fimbriae

Cited by 49 publications

References 13 publications

Evolution of the Chaperone/Usher Assembly Pathway: Fimbrial Classification Goes Greek

Evolution of the Chaperone/Usher Assembly Pathway: Fimbrial Classification Goes Greek

Receptor Binding Domain ofEscherichia coliF18 Fimbrial Adhesin FedF Can Be both Efficiently Secreted and Surface Displayed in a Functional Form inLactococcus lactis

Cloning and Expression of Genes Encoding F107-C and K88-1NT Fimbrial Proteins of Enterotoxigenic Escherichia coli from Piglets

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