A pH-Sensitive Function and Phenotype: Evidence that EutH Facilitates Diffusion of Uncharged Ethanolamine in Salmonella enterica

The eutH gene is part of an operon that allows Salmonella enterica to use ethanolamine as a sole source of nitrogen, carbon, and energy. Although the sequence of EutH suggests a role in transport, eutH mutants use ethanolamine normally under standard conditions (pH 7.0). These mutants fail to use ethanolamine at a low pH. Evidence is presented that protonated ethanolamine (Eth(0)) does not enter cells, while uncharged ethanolamine (Eth(0)) diffuses freely across the membrane. The external concentration of Eth(0) varies with the pH (pK = 9.5). At pH 7.0, the standard ethanolamine concentration (41 mM) provides enough Eth(0) for an influx rate that can support growth with or without EutH. When a lowered pH and/or ethanolamine concentration reduced the Eth(0) concentration below 25 μM, EutH was needed to facilitate diffusion. EutH(+) cells grew normally at Eth(0) concentrations above 3 μM, close to the Km (9 μM) of the first degradative enzyme, ethanolamine ammonia lyase. It is suggested that EutH facilitates diffusion of Eth(0). As predicted for a transporter, EutH contributed to the toxicity of ethanolamine seen under some conditions; furthermore, fusion of EutH to fluorescent Yfp protein provided evidence that EutH is a membrane protein

The X-chromosome and susceptibility to ankylosing spondylitis

OBJECTIVE: Ankylosing spondylitis (AS) affects 0.25-1.0% of the population, and its etiology is incompletely understood. Susceptibility to this highly familial disease (lambda(s) = 58) is primarily genetically determined. There is a significant sex bias in AS, and there are differences in recurrence risk to the offspring of affected mothers and fathers, suggesting that there may be an X-linked recessive effect. We undertook an X-chromosome linkage study to determine any contribution of the X-chromosome to AS susceptibility. METHODS: A linkage study of the X-chromosome using 234 affected sibling pairs was performed to investigate this hypothesis. RESULTS: No linkage of the X-chromosome with susceptibility to AS was found. Model-free multipoint linkage analysis strongly excluded any significant genetic contribution (lambda > or = 1.5) to AS susceptibility encoded on the X-chromosome (logarithm of odds [LOD] <-2.0). Smaller genetic effects (lambda > or = 1.3) were also found to be unlikely (LOD <-1.0). CONCLUSION: The sex bias in AS is not explained by X-chromosome-encoded genetic effects. The disease model best explaining the sex bias in occurrence and transmission of AS is a polygenic model with a higher susceptibility threshold in females