Functional Screening of the Cronobacter sakazakii BAA-894 Genome reveals a role for ProP (ESA_02131) in carnitine uptake.

Cronobacter sakazakii is a neonatal pathogen responsible for up to 80% of fatalities in infected infants. Low birth weight infants and neonates infected with C. sakazakii suffer necrotizing enterocolitis, bacteraemia and meningitis. The mode of transmission most often associated with infection is powdered infant formula (PIF) which, with an aw of ∼0.2, is too low to allow most microorganisms to persist. Survival of C. sakazakii in environments subject to extreme hyperosmotic stress has previously been attributed to the uptake of compatible solutes including proline and betaine. Herein, we report the construction and screening of a C. sakazakii genome bank and the identification of ProP (ESA_02131) as a carnitine uptake system.

The role of the Cronobacter sakazakii ProP C-terminal coiled coil domain in osmotolerance.

BACKGROUND: We investigate the role of the C-terminal coiled coil of the secondary proline porter ProP in contributing to Cronobacter sakazakii osmotolerance. FINDINGS: The extended C-terminal domain of ProP1 (encoded by ESA_02131) was spliced onto the truncated C-terminal end of ProP2 (encoded by ESA_01706); creating a chimeric protein (ProPc) which exhibits increased osmotolerance relative to the wild type. CONCLUSIONS: It appears that the C-terminal coiled coil domain tunes ProP at low osmolality, whereas ProP transporters lacking the coiled coil domain are more active at a higher osmolality range.

Analysis of the role of the Cronobacter sakazakii ProP homologues in osmotolerance.

Bacteria respond to elevated osmolality by the accumulation of a range of low molecular weight molecules, known as compatible solutes (owing to their compatibility with the cells' normal physiology at high internal concentrations). The neonatal pathogen Cronobacter sakazakii is uniquely osmotolerant, surviving in powdered infant formula (PIF) which typically has a water activity (aw) of 0.2 - inhospitable to most micro-organisms. Mortality rates of up to 80% in infected infants have been recorded making C. sakazakii a serious cause for concern. In silico analysis of the C. sakazakii BAA-894 genome revealed seven copies of the osmolyte uptake system ProP. Herein, we test the physiological role of each of these homologues following heterologous expression against an osmosensitive Escherichia coli host.

Cronobacter sakazakii: stress survival and virulence potential in an opportunistic foodborne pathogen.

A characteristic feature of the opportunistic foodborne pathogen Cronobacter sakazakii is its ability to survive in extremely arid environments, such as powdered infant formula, making it a dangerous opportunistic pathogen of individuals of all age groups, especially infants and neonates. Herein, we provide a brief overview of the pathogen; clinical manifestations, environmental reservoirs and our current understanding of stress response mechanisms and virulence factors which allow it to cause disease.

A single point mutation in the listerial betL σ(A)-dependent promoter leads to improved osmo- and chill-tolerance and a morphological shift at elevated osmolarity.

Betaine uptake in Listeria monocytogenes is mediated by three independent transport systems, the simplest of which in genetic terms is the secondary transporter BetL. Using a random mutagenesis approach, based on the E. coli XL1 Red mutator strain, we identified a single point mutation in a putative promoter region upstream of the BetL coding region which leads to a significant increase in betL transcript levels under osmo- and chill-stress conditions and a concomitant increase in stress tolerance. Furthermore, the mutation appears to counter the heretofore unreported "twisted" cell morphology observed for L. monocytogenes grown at elevated osmolarities in tryptone soy broth.

Acinetobacter baumannii: an emerging opportunistic pathogen.

Acinetobacter baumannii is an opportunistic bacterial pathogen primarily associated with hospital-acquired infections. The recent increase in incidence, largely associated with infected combat troops returning from conflict zones, coupled with a dramatic increase in the incidence of multidrug-resistant (MDR) strains, has significantly raised the profile of this emerging opportunistic pathogen. Herein, we provide an overview of the pathogen, discuss some of the major factors that have led to its clinical prominence and outline some of the novel therapeutic strategies currently in development.

An in silico analysis of osmotolerance in the emerging gastrointestinal pathogen Cronobacter sakazakii.

Up to 80% of infants infected with Cronobacter sakazakii die within days of birth, making this emerging gastrointestinal pathogen a serious cause for concern. The mode of transmission most often associated with C. sakazakii infection is powdered infant formula (PIF), which typically has a water activity (aw) of ca 0.2--inhospitable to most bacterial pathogens. In the current study a comparative genomic approach was used to investigate the distinctive ability of this pathogen to survive and persist in such low aW conditions. A comprehensive review of the mechanisms involved in bacterial osmoadaptation was followed by an exhaustive homology transfer based approach to identify putative osmotolerance loci in the C. sakazakii genome. In total 53 osmotoleance loci were identified, including both hyper- and hypo-osmotic stress response systems, helping to construct a concise overview of the C. sakazakii osmotolerance response. Interestingly, while C. sakazakii contains homologues of all the principal osmotolerance loci of Escherichia coli; a key difference is that C. sakazakii contains multiple copies of certain osmotolerance loci; including seven copies of the E. coli proP homologue and two copies of OpuC--a multi component carnitine uptake system associated with Listeria monocytogenes and which has also been found to transport other compatible solutes such as glycine betaine, proline, ectoine and choline. Furthermore, the osmotic stress response of C. sakazakii appears to be regulated at the transcriptional, translational and post-translational levels, with RpoS most likely functioning as the global transcriptional regulator of the osmotolerance response.