Gastrointestinal digestion is of major importance in the bioavailability of angiotensin I converting enzyme (ACE) inhibitory peptides, bioactive peptides with possible antihypertensive effects. In this study, the conditions of in vitro gastrointestinal digestion leading to the formation and degradation of ACE inhibitory peptides were investigated for pea and whey protein. In batch experiments, the digestion simulating the physiological conditions sufficed to achieve the highest ACE inhibitory activity, with IC(50) values of 0.076 mg/mL for pea and 0.048 mg/mL for whey protein. The degree of proteolysis did not correlate with the ACE inhibitory activity and was always higher for pea than whey. In a semicontinuous model of gastrointestinal digestion, response surface methodology studied the influence of temperature and incubation time in both the stomach and small intestine phases on the ACE inhibitory activity and degree of proteolysis. For pea protein, a linear model for the degree of proteolysis and a quadratic model for the ACE inhibitory activity could be constituted. Within the model, a maximal degree of proteolysis was observed at the highest temperature and the longest incubation time in the small intestine phase, while maximal ACE inhibitory activity was obtained at the longest incubation times in the stomach and small intestine phase. These results show that ACE inhibitory activity of pea and whey hydrolysates can be controlled by the conditions of in vitro gastrointestinal digestion.
An environmentally representative stagnant-water model was developed to monitor the growth dynamics of Legionella pneumophila. This model was evaluated for three distinct water treatments: untreated tap water, heat-treated tap water, and heat-treated tap water supplemented with Pseudomonas putida, a known biofilm-forming bacterium. Bringing heat-treated tap water after subsequent cooling into contact with a densely formed untreated biofilm was found to promote the number of L. pneumophila by 4 log units within the biofilm, while the use of untreated water only sustained the L. pneumophila levels. Subsequent colonization of the water phase by L. pneumophila was noticed in the heat-treated stagnant-water models, with concentrations as high as 1 x 10(10) mip gene copies L(-1) stagnant water. Denaturing gradient gel electrophoresis in combination with clustering analysis of the prokaryotic community in the water phase and in the biofilm phase suggests that the different water treatments induced different communities. Moreover, boosts of L. pneumophila arising from heat treatment of water were accompanied by shifts to a more diverse eukaryotic community. Stimulated growth of L. pneumophila after heating of the water may explain the rapid recolonization of L. pneumophila in water systems. These results highlight the need for additional or alternative measures to heat treatment of water in order to prevent or abate potential outbreaks of L. pneumophila.
Legionella pneumophila, a micro-organism encountered in aquatic environments, can cause serious intracellular infections among humans. Since the bacterium is ubiquitous in aquatic habitats, it appears to be impossible to prevent L. pneumophila from entering man-made water systems. However, many questions concerning the survival and/or growth in the environment, the partners and opponents of L. pneumophila remain unanswered. This review focuses on the factors governing the ecology of L. pneumophila, since there is considerable divergence and even contradiction in literature on its environmental requirements. A key question to be resolved is the discrepancy between the fastidious nature of L. pneumophila in axenic cultures (e.g. 400 mg l )1 L L -cysteine and 250 mg l )1 ferric iron) and the nutritionally poor environments in which it is commonly detected. It is assumed that dense microbial communities, as occurring in sediments and biofilms -but not likely in surface and drinking water, -can provide the necessary growth requirements for L. pneumophila. However, most of the studies concerning L. pneumophila have led to the general opinion that the organism can only multiply in the aquatic environment as a parasite in certain protozoa. The discovery of the non-classical siderophore legiobactin also indicates that the iron requirement for survival and autonomous growth is not as high as has been assumed. It thus appears that in order to control Legionella in the environment, focus should be on the eradication of microbial hotspots in which L. pneumophila resides.
Aims: To compare the sensitivities of two nested PCR assays for the detection of Legionella pneumophila to each other and to the plate counting technique (ISO 11731) in a wide range of aquatic samples. Methods and Results:The nested PCR assay with the primer set LEG 225-LEG 858 revealed 56% of the 46 analysed aquatic samples as being positive for Legionella spp., while the primer set JFP-JRP yielded 98% positive samples. The detection was confirmed by sequencing the PCR products. These results are considerably higher than the result obtained with the plate counting technique (41%), indicating the higher sensitivity of PCR-based diagnostic methods. As the PCR assay with the LEG 225-LEG 858 primer set resulted in a lower number of positive samples, it is considered not sensitive enough for aquatic samples. Similar results for the respective primer sets were obtained for the detection of the species L. pneumophila, responsible for 90% of all human Legionella infections, in the aquatic samples analysed. Both microbial community analysis by PCR-denaturing gradient gel electrophoresis and the analysis of biotic and abiotic water quality parameters revealed no relation between L. pneumophila-positive and -negative samples and the physico-chemical and bacteriological characteristics of the aquatic samples. Conclusions:The results show the additional value of the PCR assay with the JFP-JRP primer set compared with the plate counting technique, as well as its applicability in a wide range of aquatic samples. Significance and Impact of the Study: This study shows the importance of comparing different primer sets for nested PCR assays for the detection of L. pneumophila in aquatic samples, as well as the lower sensitivity of the widely accepted plate counting technique (ISO 11731).
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