Human Clostridium difficile infection: inhibition of NHE3 and microbiota profile.

Clostridium difficile infection (CDI) is principally responsible for hospital acquired, antibiotic-induced diarrhea and colitis and represents a significant financial burden on our healthcare system. Little is known about C. difficile proliferation requirements, and a better understanding of these parameters is critical for development of new therapeutic targets. In cell lines, C. difficile toxin B has been shown to inhibit Na(+)/H(+) exchanger 3 (NHE3) and loss of NHE3 in mice results in an altered intestinal environment coupled with a transformed gut microbiota composition. However, this has yet to be established in vivo in humans. We hypothesize that C. difficile toxin inhibits NHE3, resulting in alteration of the intestinal environment and gut microbiota. Our results demonstrate that CDI patient biopsy specimens have decreased NHE3 expression and CDI stool has elevated Na(+) and is more alkaline compared with stool from healthy individuals. CDI stool microbiota have increased Bacteroidetes and Proteobacteria and decreased Firmicutes phyla compared with healthy subjects. In vitro, C. difficile grows optimally in the presence of elevated Na(+) and alkaline pH, conditions that correlate to changes observed in CDI patients. To confirm that inhibition of NHE3 was specific to C. difficile, human intestinal organoids (HIOs) were injected with C. difficile or healthy and CDI stool supernatant. Injection of C. difficile and CDI stool decreased NHE3 mRNA and protein expression compared with healthy stool and control HIOs. Together these data demonstrate that C. difficile inhibits NHE3 in vivo, which creates an altered environment favored by C. difficile.

Sourcing and using stem cell lines for radiation research: Potential, challenges and good stem cell culture practice.

PURPOSE: Exposition of best practice in management and experimental use of human stem cell lines in radiobiological research. This paper outlines the key challenges to be addressed by radiobiologists wishing to use human pluripotent stem cell (hPSC) lines in their research including human embryonic stem cell (hESC) lines and human induced pluirpotency stem (hiPSC) lines. It emphasises the importance of guidance already established for cell culture in general and outlines some further considerations specific to the culture of human pluripotent stem cell lines which may impact on the interpretation of data from radiobiological studies using these cells. Fundamental standards include obtaining cells from bona fide suppliers with suitable quality controls, screening cell lines to ensure absence of mycoplasma and authentication of cell lines by DNA profiling. For hESC and hiPSC lines, it is particularly important to recognise the significance of phenotypic and genetic stability and this paper will address approaches to reduce their impact. Quality assured banking of these two types of stem cell lines will facilitate reliable supply of quality controlled cells that can provide standardisation between laboratories and in the same laboratory over time. CONCLUSIONS: hPSC lines could play an important role in future radiobiological research providing certain fundamental principles of good stem cell culture practice are adopted at the outset of such work.