Lisa M. Cooper scite author profile

Enterotoxigenic Escherichia coli (ETEC) is the most common cause of food and water-borne E. coli-mediated human diarrhoea worldwide. The incidence in developing countries is estimated at 650 million cases per year, resulting in 800 000 deaths, primarily in children under the age of five. ETEC is also the most common cause of diarrhoea among travellers, including the military, from industrialized nations to less developed countries. In addition, ETEC is a major pathogen of animals, being responsible for scours in cattle and neonatal and postweaning diarrhoea in pigs and resulting in significant financial losses. Studies on the pathogenesis of ETEC infections have concentrated on the plasmid-encoded heat-stable and heat-labile enterotoxins and on the plasmid-encoded antigenically variable colonization factors. Relatively little work has been carried out on chromosomally encoded virulence factors. Here, we review the known virulence factors of ETEC and highlight the future for combating this major disease.

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A conserved extended signal peptide region directs posttranslational protein translocation via a novel mechanism

Desvaux

Scott-Tucker

Turner

et al. 2007

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Members of the type V secretion family are among the most prevalent secreted proteins in Gramnegative bacteria. A subset of this family, including Pet, the prototypical member of the Enterobacteriaceae serine proteases, possess unusual signal peptides which can be divided into five regions termed N1 (charged), H1 (hydrophobic), N2, H2 and C (cleavage site) domains. The N1 and H1 regions, which the authors have named the extended signal peptide region (ESPR), demonstrate remarkable conservation. In contrast, the N2, H2 and C regions show significant variability, and are reminiscent of typical Sec-dependent signal sequences. Despite several investigations, the function of the ESPR remains obscure. Here, it is shown that proteins possessing the ESPR are translocated in a posttranslational fashion. The presence of the ESPR severely impairs inner membrane translocation. Mutational analysis suggests that the ESPR delays inner membrane translocation by adopting a particular conformation, or by interacting with a cytoplasmic or inner membrane co-factor, prior to inner membrane translocation.

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The unusual extended signal peptide region of the type V secretion system is phylogenetically restricted

Desvaux

Cooper

Filenko

et al. 2006

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The plasmid encoded toxin, Pet, is a prototypical member of the serine protease autotransporters of the Enterobacteriaceae. In addition to the passenger and beta-domains typical of autotransporters, in silico predictions indicate that Pet possesses an unusually long N-terminal signal sequence. The signal sequence can be divided into five regions termed N1 (charged), H1 (hydrophobic), N2, H2 and C (cleavage site) domains. The N1 and H1 regions, which we have termed the extended signal peptide region, demonstrate remarkable conservation. In contrast, the N2, H2 and C regions demonstrate significant variability and are reminiscent of typical Sec-dependent signal sequences. Despite several investigations, the function of the extended signal peptide region remains obscure and surprisingly it has not been proven that the extended signal peptide region is actually synthesized as part of the signal sequence. Here, we demonstrate that the extended signal peptide region is present only in Gram-negative bacterial proteins originating from the classes Beta- and Gammaproteobacteria, and more particularly only in proteins secreted via the Type V secretion pathway: autotransporters, TpsA exoproteins of the two-partner system and trimeric autotransporters. In vitro approaches demonstrate that the DNA region encoding the extended signal peptide region is transcribed and translated.

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A tale of two DUSP27s: proposed resolution for the naming of distinct dual-specificity phosphatases

Cooper

Waddell

2020

American Journal of Physiology-Cell Physiology

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Fam83d modulates MAP kinase and AKT signaling and is induced during neurogenic skeletal muscle atrophy

Cooper

Hanson

Kavanagh

et al. 2020

Cellular Signalling

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Lisa M. Cooper

Weapons of mass destruction: virulence factors of the global killer EnterotoxigenicEscherichia coli

A conserved extended signal peptide region directs posttranslational protein translocation via a novel mechanism

The unusual extended signal peptide region of the type V secretion system is phylogenetically restricted

A tale of two DUSP27s: proposed resolution for the naming of distinct dual-specificity phosphatases

Fam83d modulates MAP kinase and AKT signaling and is induced during neurogenic skeletal muscle atrophy

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