The hydroxyectoine gene cluster of the non-halophilic acidophile Acidiphilium cryptum.

Acidiphilium cryptum is an acidophilic, heterotrophic α-Proteobacterium which thrives in acidic, metal-rich environments (e.g. acid mine drainage). Recently, an ectABCDask gene cluster for biosynthesis of the compatible solutes ectoine and hydroxyectoine was detected in the genome sequence of A. cryptum JF-5. We were able to demonstrate that the type strain A. cryptum DSM 2389(T) is capable of synthesizing the compatible solute hydroxyectoine in response to moderate osmotic stress caused by sodium chloride and aluminium sulphate, respectively. Furthermore, we used the A. cryptum JF-5 sequence to amplify the ectABCDask gene cluster from strain DSM 2389(T) and achieved heterologous expression of the gene cluster in Escherichia coli. Hence, we could for the first time prove metabolic functionality of the genes responsible for hydroxyectoine biosynthesis in the acidophile A. cryptum. In addition, we present information on specific enzyme activity of A. cryptum DSM 2389(T) ectoine synthase (EctC) in vitro. In contrast to EctCs from halophilic microorganisms, the A. cryptum enzyme exhibits a higher isoelectric point, thus a lower acidity, and has maximum specific activity in the absence of sodium chloride.

Potassium transport in a halophilic member of the bacteria domain: identification and characterization of the K+ uptake systems TrkH and TrkI from Halomonas elongata DSM 2581T.

The halophilic bacterium Halomonas elongata accumulates K+, glutamate, and the compatible solute ectoine as osmoprotectants. By functional complementation of Escherichia coli mutants defective in K+ uptake, we cloned three genes that are required for K+ uptake in H. elongata. Two adjacent genes, named trkA (1,374 bp) and trkH (1,449 bp), were identified on an 8.5-kb DNA fragment, while a third gene, called trkI (1,479 bp), located at a different site in the H. elongata chromosome, was found on a second 8.5-kb fragment. The potential protein expressed by trkA is similar to the cytoplasmic NAD+/NADH binding protein TrkA from E. coli, which is required for the activity of the Trk K+ uptake system. The deduced amino acid sequences of trkH and trkI showed significant identity to the transmembrane protein of Trk transporters. K+ transport experiments with DeltatrkH and DeltatrkI mutants of H. elongata revealed that TrkI exhibits a Km value of 1.12 mM, while the TrkH system has a half-saturation constant of 3.36 mM. Strain KB12, relying on TrkH alone, accumulated K+ with a lower Vmax and required a higher K+ concentration for growth in highly saline medium than the wild type. Strain KB15, expressing only TrkI, showed the same phenotype and the same K+ transport kinetics as the wild type, proving that TrkI is the main K+ transport system in H. elongata. In the absence of both transporters TrkH and TrkI, K+ accumulation was not detectable. K+ transport was also abolished in a trkA deletion mutant, indicating that TrkI and TrkH depend on one type of TrkA protein. Reverse transcriptase PCR experiments and Northern hybridization analyses of the trkAH locus revealed cotranscription of trkAH as well as a monocistronic transcript with only trkA.