Ureaplasma diversum protein interaction networks: evidence of horizontal gene transfer and evolution of reduced genomes among Mollicutes.

Ureaplasma diversum is a member of the Mollicutes class responsible for urogenital tract infection in cattle and small ruminants. Studies indicate that the process of horizontal gene transfer, the exchange of genetic material among different species, has a crucial role in mollicute evolution, affecting the group's characteristic genomic reduction process and simplification of metabolic pathways. Using bioinformatics tools and the STRING database of known and predicted protein interactions, we constructed the protein-protein interaction network of U. diversum and compared it with the networks of other members of the Mollicutes class. We also investigated horizontal gene transfer events in subnetworks of interest involved in purine and pyrimidine metabolism and urease function, chosen because of their intrinsic importance for host colonization and virulence. We identified horizontal gene transfer events among Mollicutes and from Ureaplasma to Staphylococcus aureus and Corynebacterium, bacterial groups that colonize the urogenital niche. The overall tendency of genome reduction and simplification in the Mollicutes is echoed in their protein interaction networks, which tend to be more generalized and less selective. Our data suggest that the process was permitted (or enabled) by an increase in host dependence and the available gene repertoire in the urogenital tract shared via horizontal gene transfer.

Highly divergent Mollicutes symbionts coexist in the scorpion Androctonus australis.

Androctonus australis is one of the most ubiquitous and common scorpion species in desert and arid lands from North Africa to India and it has an important ecological role and social impact. The bacterial community associated to this arachnid is unknown and we aimed to dissect its species composition in the gut, gonads, and venom gland. A 16S rRNA gene culture-independent diversity analysis revealed, among six other taxonomic groups (Firmicutes, Betaproteobacteria, Gammaproteobacteria, Flavobacteria, Actinobacteria, and Cyanobacteria), a dominance of Mollicutes phylotypes recorded both in the digestive tract and the gonads. These related Mollicutes include two Spiroplasma phylotypes (12.5% of DGGE bands and 15% of clones), and a new Mycoplasma cluster (80% of clones) showing 16S rRNA sequence identities of 95 and 93% with Mollicutes detected in the Mexican scorpions Centruroides limpidus and Vaejovis smithi, respectively. Such scorpion-associated Mollicutes form a new lineage that share a distant ancestor with Mycoplasma hominis. The observed host specificity with the apparent phylogenetic divergence suggests a relatively long co-evolution of these symbionts with the scorpion hosts. From the ecological point of view, such association may play a beneficial role for the host fitness, especially during dormancy or molt periods.

Mycoplasma hominis in Cuban Trichomonas vaginalis isolates: association with parasite genetic polymorphism.

Trichomonas vaginalis can be naturally infected with intracellular Mycoplasma hominis. This bacterial infection may have implications for trichomonal virulence and disease pathogenesis. The objective of the study was to report the presence of M. hominis in Cuban T. vaginalis isolates and to describe the association between the phenotype M. hominis infected with RAPD genetic polymorphism of T. vaginalis. The Random Amplified Polymorphic DNA (RAPD) technique was used to determine genetic differences among 40 isolates of T. vaginalis using a panel of 30 random primers and these genetic data were correlated with the infection of isolates with M. hominis. The trees drawn based on RAPD data showed no relations with metronidazole susceptibility and significantly association with the presence of M. hominis (P=0.043), which demonstrates the existence of concordance between the genetic relatedness and the presence of M. hominis in T. vaginalis isolates. This result could point to a predisposition of T. vaginalis for the bacterial enters and/or survival.

Detection of multiple mycoplasma infection in cell cultures by PCR.

A total of 301 cell cultures from 15 laboratories were monitored for mycoplasma (Mollicutes) using PCR and culture methodology. The infection was detected in the cell culture collection of 12 laboratories. PCR for Mollicutes detected these bacteria in 93 (30.9%) samples. Although the infection was confirmed by culture for 69 (22.9%) samples, PCR with generic primers did not detect the infection in five (5.4%). Mycoplasma species were identified with specific primers in 91 (30.2%) of the 98 samples (32.6%) considered to be infected. Mycoplasma hyorhinis was detected in 63.3% of the infected samples, M. arginini in 59.2%, Acholeplasma laidlawii in 20.4%, M. fermentans in 14.3%, M. orale in 11.2%, and M. salivarium in 8.2%. Sixty (61.2%) samples were co-infected with more than one mycoplasma species. M. hyorhinis and M. arginini were the microorganisms most frequently found in combination, having been detected in 30 (30.6%) samples and other associations including up to four species were detected in 30 other samples. Failure of the treatments used to eliminate mycoplasmas from cell cultures might be explained by the occurrence of these multiple infections. The present results indicate that the sharing of non-certified cells among laboratories may disseminate mycoplasma in cell cultures.

Detection of multiple mycoplasma infection in cell cultures by PCR

A total of 301 cell cultures from 15 laboratories were monitored for mycoplasma (Mollicutes) using PCR and culture methodology. The infection was detected in the cell culture collection of 12 laboratories. PCR for Mollicutes detected these bacteria in 93 (30.9 percent) samples. Although the infection was confirmed by culture for 69 (22.9 percent) samples, PCR with generic primers did not detect the infection in five (5.4 percent). Mycoplasma species were identified with specific primers in 91 (30.2 percent) of the 98 samples (32.6 percent) considered to be infected. Mycoplasma hyorhinis was detected in 63.3 percent of the infected samples, M. arginini in 59.2 percent, Acholeplasma laidlawii in 20.4 percent, M. fermentans in 14.3 percent, M. orale in 11.2 percent, and M. salivarium in 8.2 percent. Sixty (61.2 percent) samples were co-infected with more than one mycoplasma species. M. hyorhinis and M. arginini were the microorganisms most frequently found in combination, having been detected in 30 (30.6 percent) samples and other associations including up to four species were detected in 30 other samples. Failure of the treatments used to eliminate mycoplasmas from cell cultures might be explained by the occurrence of these multiple infections. The present results indicate that the sharing of non-certified cells among laboratories may disseminate mycoplasma in cell cultures.