Sequence properties of the 1,2-diacylglycerol 3-glucosyltransferase from Acholeplasma laidlawii membranes. Recognition of a large group of lipid glycosyltransferases in eubacteria and archaea.

Synthesis of the nonbilayer-prone alpha-monoglucosyldiacylglycerol (MGlcDAG) is crucial for bilayer packing properties and the lipid surface charge density in the membrane of Acholeplasma laidlawii. The gene for the responsible, membrane-bound glucosyltransferase (alMGS) (EC ) was sequenced and functionally cloned in Escherichia coli, yielding MGlcDAG in the recombinants. Similar amino acid sequences were encoded in the genomes of several Gram-positive bacteria (especially pathogens), thermophiles, archaea, and a few eukaryotes. All of these contained the typical EX(7)E catalytic motif of the CAZy family 4 of alpha-glycosyltransferases. The synthesis of MGlcDAG by a close sequence analog from Streptococcus pneumoniae (spMGS) was verified by polymerase chain reaction cloning, corroborating a connection between sequence and functional similarity for these proteins. However, alMGS and spMGS varied in dependence on anionic phospholipid activators phosphatidylglycerol and cardiolipin, suggesting certain regulatory differences. Fold predictions strongly indicated a similarity for alMGS (and spMGS) with the two-domain structure of the E. coli MurG cell envelope glycosyltransferase and several amphipathic membrane-binding segments in various proteins. On the basis of this structure, the alMGS sequence charge distribution, and anionic phospholipid dependence, a model for the bilayer surface binding and activity is proposed for this regulatory enzyme.

Different sequence patterns in signal peptides from mycoplasmas, other gram-positive bacteria, and Escherichia coli: a multivariate data analysis.

Signal peptides are essential N-terminal extensions in export proteins, and have a positively charged N-terminus, a hydrophobic central core, and a C-terminal cleavage region. They interact in a consecutive manner with different accessory proteins during the secretion process. Potential patterns or periodicity in the amino acid (aa) sequence were searched, using multivariate techniques, for a large number of signal peptides from mollicutes (mycoplasmas), other Gram-positive bacteria, and Escherichia coli. Mollicutes signal peptides were significantly different from the E. coli and Gram-positive ones by their N-terminal charge, peptide length, and especially, unique periodicities of side chain hydrophobicity and volumes. Their lipoprotein signal peptides were longer than for any other bacteria. Significant differences were also recorded between the other bacterial peptide groups. Specific aa patterns were more related within the signal peptides from several groups of secreted bacillus enzymes, than for all signal peptides from one bacillus species. In E. coli, signal peptides from proteins routed for the various destinations revealed significant and compartment-specific sequence patterns not evident by other methods. This was substantiated from a large number of signal peptide secretion mutants for the E. coli periplasmic space. It is proposed that the differences in aa patterns and side-chain properties are related to the secondary structure sidedness and topology of the signal peptides, and important for specific interactions during the secretion process.

Molecular epidemiology of Ornithobacterium rhinotracheale.

Ornithobacterium rhinotracheale is a recently described gram-negative rod-shaped bacterium associated with respiratory tract infections in poultry. In order to determine the molecular epidemiology of this bacterium, we characterized 55 O. rhinotracheale isolates from eight countries on four continents by multilocus enzyme electrophoresis (MLEE), repetitive sequence based-PCR (rep-PCR), and 16S rRNA gene sequencing. MLEE discriminated the O. rhinotracheale isolates into six electrophoretic types (ETs), of which only three ETs were recovered from domesticated poultry. The 16S rRNA gene sequence and rep-PCR analyses confirmed the results obtained by MLEE and indicated limited heterogeneity among isolates of O. rhinotracheale recovered from poultry. Taken together, the results of our analysis demonstrate that the majority of O. rhinotracheale isolates recovered from domesticated poultry throughout the world are represented by a small group of closely related clones and suggest that the bacterium was recently introduced to domesticated poultry from wild bird populations.