Isolation of a Pseudomonas monteilli strain with a novel phosphotriesterase.

A Pseudomonas monteilli strain (designated C11) that uses the phosphotriester coroxon as its sole phosphorus source has been isolated. Native PAGE and activity staining identified a single isozyme with significant phosphotriesterase activity in the soluble fraction of the cell. This phosphotriesterase could hydrolyse both coumaphos and coroxon. The hydrolysis product of coroxon, diethylphosphate, and the thion analogue, coumaphos, could not serve as phosphorus sources when added to the growth medium. The majority of the phosphotriesterase and phosphatase activity was contained in the soluble fraction of the cell. Phosphatase activity was inhibited by vanadate as well as by dialysis against the metal chelator, EDTA. Phosphotriesterase activity was not affected by either vanadate or dialysis with EDTA or 1,10-phenanthroline. Phosphotriesterase activity was regulated by the amounts of both phosphate and coroxon in the medium, whereas total phosphatase activity was regulated by phosphate but not coroxon. A lack of hybridisation using a probe against the opd (organophosphate degradation) gene encoding a phosphotriesterase from Flavobacterium sp. ATCC27551 against bulk DNA from P. monteilli C11 suggested that this strain does not contain opd. The work presented here indicates the presence of a novel phosphotriesterase in P. monteilli C11.

Optimal replication and the importance of experimental design for gel-based quantitative proteomics.

Quantitative proteomic studies, based on two-dimensional gel electrophoresis, are commonly used to find proteins that are differentially expressed between samples or groups of samples. These proteins are of interest as potential diagnostic or prognostic biomarkers, or as proteins associated with a trait. The complexity of proteomic data poses many challenges, so while experiments may reveal proteins that are differentially expressed, these are often not significant when subjected to rigorous statistical analysis. However, this can be addressed through appropriate experimental design. A good experimental design considers the impact of different sources of variation, both analytical and biological, on the statistical importance of the results. The design should address the number of samples that must be analyzed and the number of replicate gels per sample, in the context of a particular minimum difference that one is seeking to achieve. In this study, we explore the ways to improve the quality of protein expression data from 2-DE gels, and describe an approach for defining the number of samples required and the number of gels per sample. It has been developed for the simplest of situations, two groups of samples with variation at two levels: between samples and between gels. This approach will also be useful as a guide for more complex designs involving more than two groups of samples. We describe some Internet-accessible tools that can assist in the design of proteomic studies.

Identification of an opd (organophosphate degradation) gene in an Agrobacterium isolate.

We isolated a bacterial strain, Agrobacterium radiobacter P230, which can hydrolyze a wide range of organophosphate (OP) insecticides. A gene encoding a protein involved in OP hydrolysis was cloned from A. radiobacter P230 and sequenced. This gene (called opdA) had sequence similarity to opd, a gene previously shown to encode an OP-hydrolyzing enzyme in Flavobacterium sp. strain ATCC 27551 and Brevundimonas diminuta MG. Insertional mutation of the opdA gene produced a strain lacking the ability to hydrolyze OPs, suggesting that this is the only gene encoding an OP-hydrolyzing enzyme in A. radiobacter P230. The OPH and OpdA proteins, encoded by opd and opdA, respectively, were overexpressed and purified as maltose-binding proteins, and the maltose-binding protein moiety was cleaved and removed. Neither protein was able to hydrolyze the aliphatic OP malathion. The kinetics of the two proteins for diethyl OPs were comparable. For dimethyl OPs, OpdA had a higher k(cat) than OPH. It was also capable of hydrolyzing the dimethyl OPs phosmet and fenthion, which were not hydrolyzed at detectable levels by OPH.