A Novel Putrescine Importer Required for Type 1 Pili-driven Surface Motility Induced by Extracellular Putrescine in Escherichia coli K-12

Kurihara, Shin; Suzuki, Hideyuki; Oshida, Mayu; Benno, Yoshimi

doi:10.1074/jbc.m110.176032

Cited by 49 publications

(52 citation statements)

References 37 publications

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“…They are present in all living cells. In bacteria, polyamines are involved in a variety of functions, including intercellular signaling, stress resistance, and RNA and protein synthesis, as well as motility and virulence (5)(6)(7)(8)(9)(10)(11)(12)(13). Some polyamines have also been shown to play an essential role in biofilm formation, i.e., putrescine in Yersinia pestis (14) and Escherichia coli (15), spermidine in Bacillus subtilis (16), and norspermidine in Vibrio cholerae (17).…”

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Effects of Norspermidine and Spermidine on Biofilm Formation by Potentially Pathogenic Escherichia coli and Salmonella enterica Wild-Type Strains

Nesse

Berg

Vestby

2015

Appl Environ Microbiol

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Polyamines are present in all living cells. In bacteria, polyamines are involved in a variety of functions, including biofilm formation, thus indicating that polyamines may have potential in the control of unwanted biofilm. In the present study, the effects of the polyamines norspermidine and spermidine on biofilms of 10 potentially pathogenic wild-type strains of Escherichia coli serotype O103:H2, Salmonella enterica subsp. enterica serovar Typhimurium, and S. enterica serovar Agona were investigated. We found that exogenously supplied norspermidine and spermidine did not mediate disassembly of preformed biofilm of any of the E. coli and S. enterica strains. However, the polyamines did affect biofilm production. Interestingly, the two species reacted differently to the polyamines. Both polyamines reduced the amount of biofilm formed by E. coli but tended to increase biofilm formation by S. enterica. Whether the effects observed were due to the polyamines specifically targeting biofilm formation, being toxic for the cells, or maybe a combination of the two, is not known. However, there were no indications that the effect was mediated through binding to exopolysaccharides, as earlier suggested for E. coli. Our results indicate that norspermidine and spermidine do not have potential as inhibitors of S. enterica biofilm. Furthermore, we found that the commercial polyamines used contributed to the higher pH of the test medium. Failure to acknowledge and control this important phenomenon may lead to misinterpretation of the results.T he ability to form complex multicellular communities such as biofilms has been linked to persistence and survival of pathogens in food and feed processing environments (1-3). Due to the increased biocide tolerance of bacteria in biofilms, finding molecules that can control biofilm attracts considerable interest (4). Recent publications have indicated that certain polyamines may possess such properties.Polyamines are small aliphatic hydrocarbon molecules with quaternary nitrogen groups that have a net positive charge at physiological pH. They are present in all living cells. In bacteria, polyamines are involved in a variety of functions, including intercellular signaling, stress resistance, and RNA and protein synthesis, as well as motility and virulence (5-13). Some polyamines have also been shown to play an essential role in biofilm formation, i.e., putrescine in Yersinia pestis (14) and Escherichia coli (15), spermidine in Bacillus subtilis (16), and norspermidine in Vibrio cholerae (17). Burell et al. suggested that a role in biofilm formation may be an ancient physiological function of polyamines in bacteria (16).In addition to de novo polyamine synthesis systems, bacteria have transport systems that allow uptake of extracellular polyamines. Interestingly, exogenous spermidine has been reported to inhibit biofilm formation by Vibrio cholerae (18) and Neisseria gonorrhoeae (19). Kolkodin-Gal et al. reported that Bacillus subtilis produced biofilm disassembly factors, one of which was ...

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confidence: 99%

Effects of Norspermidine and Spermidine on Biofilm Formation by Potentially Pathogenic Escherichia coli and Salmonella enterica Wild-Type Strains

Nesse

Berg

Vestby

2015

Appl Environ Microbiol

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“…Although the expressions of the regulatory mechanisms of E. coli putrescine importers have not been investigated under this experimental condition, E. coli has at least four such importers that may be used selectively, depending on growth conditions. Under the conditions used in our experiments, PlaP may function as the main putrescine importer (10). PlaP is a homologue (63% identity) of PuuP, although the affinity of PuuP for putrescine is much higher than that of PlaP.…”

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confidence: 99%

“…PlaP was characterized as a low-affinity putrescine importer, and the ⌬plaP ⌬potABCD ⌬speAB ⌬speC E. coli strain did not exhibit surface motility on a plate containing putrescine, while the plaP ϩ ⌬potABCD ⌬speAB ⌬speC strain exhibited surface motility on the plate (10). The incorporation of 14 C-labeled putrescine was also significantly decreased in the ⌬plaP strain even when genes encoding other putrescine importers were not disrupted (10). Although the expressions of the regulatory mechanisms of E. coli putrescine importers have not been investigated under this experimental condition, E. coli has at least four such importers that may be used selectively, depending on growth conditions.…”

Section: Figmentioning

confidence: 99%

“…Recently, we reported that PlaP (previously named YeeF) was considered to function as a sensor for extracellular putrescine (10). PlaP was characterized as a low-affinity putrescine importer, and the ⌬plaP ⌬potABCD ⌬speAB ⌬speC E. coli strain did not exhibit surface motility on a plate containing putrescine, while the plaP ϩ ⌬potABCD ⌬speAB ⌬speC strain exhibited surface motility on the plate (10). The incorporation of 14 C-labeled putrescine was also significantly decreased in the ⌬plaP strain even when genes encoding other putrescine importers were not disrupted (10).…”

Section: Figmentioning

confidence: 99%

“…Of these reported three polyamine importers, only PuuP has been found to be essential for E. coli growth on minimal medium with putrescine as the sole carbon or nitrogen source (11). PlaP (previously named YeeF) was recently discovered and shows a low affinity for putrescine but is essential for the surface motility response induced by extracellular putrescine (10).…”

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Mechanism for Regulation of the Putrescine Utilization Pathway by the Transcription Factor PuuR in Escherichia coli K-12

et al. 2012

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bIn Escherichia coli, putrescine is metabolized to succinate for use as a carbon and nitrogen source by the putrescine utilization pathway (Puu pathway). One gene in the puu gene cluster encodes a transcription factor, PuuR, which has a helix-turn-helix DNA-binding motif. DNA microarray analysis of an E. coli puuR mutant, in which three amino acid residues in the helix-turnhelix DNA binding motif of PuuR were mutated to alanine to eliminate DNA binding of PuuR, suggested that PuuR is a negative regulator of puu genes. Results of gel shift and DNase I footprint analyses suggested that PuuR binds to the promoter regions of puuA and puuD. The binding of wild-type PuuR to a DNA probe containing PuuR recognition sites was diminished with increasing putrescine concentrations in vitro. These results suggest that PuuR regulates the intracellular putrescine concentration by the transcriptional regulation of genes in the Puu pathway, including puuR itself. The puu gene cluster is found in E. coli and closely related enterobacteria, but this gene cluster is uncommon in other bacterial groups. E. coli and related enterobacteria may have gained the Puu pathway as an adaptation for survival in the mammalian intestine, an environment in which polyamines exist at relatively high concentrations.

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Diamines for Bio‐Based Materials

Becker

Wittmann

2016

Industrial Biotechnology

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A Novel Putrescine Importer Required for Type 1 Pili-driven Surface Motility Induced by Extracellular Putrescine in Escherichia coli K-12

Cited by 49 publications

References 37 publications

Effects of Norspermidine and Spermidine on Biofilm Formation by Potentially Pathogenic Escherichia coli and Salmonella enterica Wild-Type Strains

Effects of Norspermidine and Spermidine on Biofilm Formation by Potentially Pathogenic Escherichia coli and Salmonella enterica Wild-Type Strains

Mechanism for Regulation of the Putrescine Utilization Pathway by the Transcription Factor PuuR in Escherichia coli K-12

Diamines for Bio‐Based Materials

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