Sensitivity of staphylococci to fatty acids: novel inactivation of linolenic acid by serum

Lacey, R. W.; Lord, Vicki L.

doi:10.1099/00222615-14-1-41

Cited by 60 publications

(31 citation statements)

References 15 publications

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“…aureus. 12 Strains from the SCBU, where survival on hands was presumably important, were not more resistant than those from elsewhere, or than controls, by the methods we used. Others have also found only a narrow range of sensitivity of staphylococci to skin fatty acids.…”

Section: Discussionmentioning

confidence: 83%

Resistance to desiccation and skin fatty acids in outbreak strains of methicillin-resistant Staphylococcus aureus

Farrington

Brenwald

Haines

et al. 1992

Journal of Medical Microbiology

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Summary.Resistance to desiccation and to skin fatty acids was measured in three groups of methicillin-resistant Staphylococcus auras (MRSA) strains and a group of control strains. Organisms from a large outbreak on a special care baby unit (SCBU), where MRSA had been isolated from staff hands but not from the environment, were significantly more sensitive to drying than strains from a burns unit where extensive environmental contamination had been demonstrated. MRSA from other wards, in the same hospital but not associated with large outbreaks, gave heterogeneous results. Fatty-acid resistance, determined by an agar dilution method, was not associated with strain origin. Some epidemic strains of MRSA were relatively sensitive to desiccation, and the abilities of such strains to spread widely on a SCBU by the hand-borne route could not be explained by enhanced resistance to skin fatty acids.

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Section: Discussionmentioning

confidence: 83%

Resistance to desiccation and skin fatty acids in outbreak strains of methicillin-resistant Staphylococcus aureus

Farrington

Brenwald

Haines

et al. 1992

Journal of Medical Microbiology

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“…The carotenoid protects S. aureus from oxidative stress by scavenging radicals (42). Staphyloxanthin may also provide resistance to other stresses like desiccation and light exposure (43,44). Previous field and laboratory studies on photoinactivation of Enterococcus spp.…”

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confidence: 99%

Staphylococcus aureus Strain Newman Photoinactivation and Cellular Response to Sunlight Exposure

McClary

Sassoubre

Boehm

2017

Appl Environ Microbiol

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Sunlight influences microbial water quality of surface waters. Previous studies have investigated photoinactivation mechanisms and cellular photostress responses of fecal indicator bacteria (FIB), including Escherichia coli and enterococci, but further work is needed to characterize photostress responses of bacterial pathogens. Here we investigate the photoinactivation of Staphylococcus aureus (strain Newman), a pigmented, waterborne pathogen of emerging concern. We measured photodecay using standard culture-based assays and cellular membrane integrity and investigated photostress response by measuring the relative number of mRNA transcripts of select oxidative stress, DNA repair, and metabolism genes. Photoinactivation experiments were performed in both oxic and anoxic systems to further investigate the role of oxygen-mediated and non-oxygen-mediated photoinactivation mechanisms. S. aureus lost culturability much faster in oxic systems than in anoxic systems, indicating an important role for oxygen in photodecay mechanisms. S. aureus cell membranes were damaged by sunlight exposure in anoxic systems but not in oxic systems, as measured by cell membrane permeability to propidium iodide. After sunlight exposure, S. aureus increased expression of a gene coding for methionine sulfoxide reductase after 12 h of sunlight exposure in the oxic system and after 6 h of sunlight exposure in the anoxic system, suggesting that methionine sulfoxide reductase is an important enzyme for defense against both oxygen-dependent and oxygen-independent photostresses. This research highlights the importance of oxygen in bacterial photoinactivation in environmentally relevant systems and the complexity of the bacterial photostress response with respect to cell structure and transcriptional regulation.IMPORTANCE Staphylococcus aureus is a pathogenic bacterium that causes gastrointestinal, respiratory, and skin infections. In severe cases, S. aureus infection can lead to life-threatening diseases, including pneumonia and sepsis. Cases of communityacquired S. aureus infection have been increasing in recent years, pointing to the importance of considering S. aureus transmission pathways outside the hospital environment. Associations have been observed between recreational water contact and staphylococcal skin infections, suggesting that recreational waters may be an important environmental transmission pathway for S. aureus. However, prediction of human health risk in recreational waters is hindered by incomplete knowledge of pathogen sources, fate, and transport in this environment. This study is an in-depth investigation of the inactivation of a representative strain of S. aureus by sunlight exposure, one of the most important factors controlling the fate of microbial contaminants in clear waters, which will improve our ability to predict water quality changes and human health risk in recreational waters.KEYWORDS Staphylococcus aureus, coastal waters, enterococci, fecal indicator bacteria, photoinactivation

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“…Pathogens that failed to show inhibition by either category of FA included Pseudomonas aeruginosa and Escherichia coli (Zheng et al 2005) and Listeria monocytogenes (Reiner et al 1986). (Gutteridge et al 1974;Butcher et al 1976;Altenbern 1977b;Kondo and Kanai 1977;Heczko et al 1979;Lacey and Lord 1981;Knapp and Melly 1986;Rohrer et al 1986;Hogan et al 1988;Thompson et al 1990;Ababouch et al 1992;Wang and Johnson 1992;Thompson et al 1994;Petrone et al 1998;Sun et al 2003) C18:3 Kabara et al 1972;Raychowdhury et al 1985;Reiner et al 1986;Mbandi et al 2004;Zheng et al 2005)** Note: When the lipid number fails to distinguish between similar FA, common names of fatty acids are given in parentheses.…”

Section: Comparison 4 Polyunsaturated Versusmentioning

confidence: 97%

“…In pooled data from 20 of 22 studies, most comparisons showed greater pathogen inhibition by omega-3 FA than by omega-6 FA (Figure 4c). Two studies, excluded from Figure 4c because they did not provide the exact identification of pathogen strains, also showed stronger bacterial inhibition by omega-3 FA (Heczko et al 1979;Lacey and Lord 1981). Heczko et al showed that of 242 strains of Staphylococcus aureus, most strains were sensitive to the omega-3 linolenic acid (C18:3) at a minimum concentration of 0.19 mmol/L while most strains were inhibited by the omega-6 linoleic acid at a minimum concentration of 6.25 mmol/L (Heczko et al 1979).…”

Section: Comparison 2 Short-and Medium-chain Saturated Fatty Acids Vmentioning

confidence: 97%

“…Additional anti-inflammatory effects of shorter-chain FA occur because these FA are ligands for G-protein receptors that tend to elicit anti-inflammatory signaling functions (Cavaglieri et al 2003;Hamer et al 2008). Galbraith et al 1971;Salanitro and Wegener 1971;Kabara et al 1972;Fay and Farias 1975;Altenbern 1977a;Miller et al 1977;Beuchat 1980;Lacey and Lord 1981;Hogan et al 1988;van der Kooij and Hijnen 1988;Ababouch et al 1992;Wang and Johnson 1992;Wang et al 1993;Petschow et al 1996;Petrone et al 1998;Sprong et al 1999;Bergsson et al 2001;Sprong et al 2001;Bergsson et al 2002;Lee et al 2002;Marounek et al 2003;…”

Section: Comparison 2 Short-and Medium-chain Saturated Fatty Acids Vmentioning

confidence: 97%

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Nutrient Signaling: Evolutionary Origins of the Immune-Modulating Effects of Dietary Fat

Alcock

Franklin

Kuzawa

2012

The Quarterly Review of Biology

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Many dietary fatty acids (FA) have potent effects on inflammation, which is not only energetically costly, but also contributes to a range of chronic diseases. This presents an evolutionary paradox: Why should the host initiate a costly and damaging response to commonly encountered nutrients? We propose that the immune system has evolved a capacity to modify expenditure on inflammation to compensate for the effects of dietary FA on gut microorganisms. In a comprehensive literature review, we show that the body preferentially upregulates inflammation in response to saturated FA that promote harmful microbes. In contrast, the host opften reduces inflammation in response to the many unsaturated FA with antimicrobial properties. Our model is supported by contrasts involving shorter-chain FA and omega-3 FA, but with less consistent evidence for trans fats, which are a recent addition to the human diet. Our findings support the idea that the vertebrate immune system has evolved a capacity to detect diet-driven shipfts in the composition of gut microbiota from the profile of FA consumed and to calibrate the costs of inflammation in response to these cues. We conclude by extending the nutrient signaling model to other nutrients, and consider implications for drug discovery and public health.

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Sensitivity of staphylococci to fatty acids: novel inactivation of linolenic acid by serum

Cited by 60 publications

References 15 publications

Resistance to desiccation and skin fatty acids in outbreak strains of methicillin-resistant Staphylococcus aureus

Resistance to desiccation and skin fatty acids in outbreak strains of methicillin-resistant Staphylococcus aureus

Staphylococcus aureus Strain Newman Photoinactivation and Cellular Response to Sunlight Exposure

Nutrient Signaling: Evolutionary Origins of the Immune-Modulating Effects of Dietary Fat

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