A phylogenomic and molecular markers based taxonomic framework for members of the order Entomoplasmatales: proposal for an emended order Mycoplasmatales containing the family Spiroplasmataceae and emended family Mycoplasmataceae comprised of six genera.

The "Spiroplasma cluster" is a taxonomically heterogeneous assemblage within the phylum Tenericutes encompassing different Entomoplasmatales species as well as the genus Mycoplasma, type genus of the order Mycoplasmatales. Within this cluster, the family Entomoplasmataceae contains two non-cohesive genera Entomoplasma and Mesoplasma with their members exhibiting extensive polyphyletic branching; additionally, the genus Mycoplasma is also embedded within this family. Genome sequences are now available for all 19 Entomoplasmataceae species with validly published names, as well as 6 of the 7 species from the genus Mycoplasma. With the aim of developing a reliable phylogenetic and taxonomic framework for the family Entomoplasmataceae, exhaustive phylogenetic and comparative genomic studies were carried out on these genome sequences. Phylogenetic trees were constructed based on concatenated sequences of 121 core proteins for this cluster, 67 conserved proteins shared with the phylum Firmicutes, 40 ribosomal proteins, three major subunits of RNA polymerase (RpoA, B and C) by different means and also for the 16S rRNA gene sequences. The interspecies relationships as well as different species groups observed in these trees were identical and robustly resolved. In all of these trees, members of the genera Mesoplasma and Entomoplasma formed three and two distinct clades, respectively, which were interspersed among the members of the other genus. The observed species groupings in the phylogenetic trees are independently strongly supported by our identification of 103 novel molecular markers or synapomorphies in the forms of conserved signature indels and conserved signature proteins, which are uniquely shared by the members of different observed species clades. To account for the different observed species clades, we are proposing a division of the genus Mesoplasma into an emended genus Mesoplasma and two new genera Tullyiplasma gen. nov. and Edwardiiplasma gen. nov. Likewise, to recognize the distinct species groupings of Entomoplasma, we are proposing its division into an emended genus Entomoplasma and a new genus Williamsoniiplasma gen. nov. Lastly, to rectify the long-existing taxonomic anomaly caused by the presence of genus Mycoplasma (order Mycoplasmatales) within the Entomoplasmatales, we are proposing an emendation of the family Mycoplasmataceae to include both Entomoplasmataceae plus Mycoplasma species and an emendation of the order Mycoplasmatales, which now comprises of the emended family Mycoplasmataceae and the family Spiroplasmataceae. The taxonomic reclassifications proposed here accurately reflect the species relationships within this group of Tenericutes and they should lead to a better understanding of their biological and pathogenic characteristics.

The mysterious orphans of Mycoplasmataceae.

BACKGROUND: The length of a protein sequence is largely determined by its function. In certain species, it may be also affected by additional factors, such as growth temperature or acidity. In 2002, it was shown that in the bacterium Escherichia coli and in the archaeon Archaeoglobus fulgidus, protein sequences with no homologs were, on average, shorter than those with homologs (BMC Evol Biol 2:20, 2002). It is now generally accepted that in bacterial and archaeal genomes the distributions of protein length are different between sequences with and without homologs. In this study, we examine this postulate by conducting a comprehensive analysis of all annotated prokaryotic genomes and by focusing on certain exceptions. RESULTS: We compared the distribution of lengths of "having homologs proteins" (HHPs) and "non-having homologs proteins" (orphans or ORFans) in all currently completely sequenced and COG-annotated prokaryotic genomes. As expected, the HHPs and ORFans have strikingly different length distributions in almost all genomes. As previously established, the HHPs, indeed are, on average, longer than the ORFans, and the length distributions for the ORFans have a relatively narrow peak, in contrast to the HHPs, whose lengths spread over a wider range of values. However, about thirty genomes do not obey these rules. Practically all genomes of Mycoplasma and Ureaplasma have atypical ORFans distributions, with the mean lengths of ORFan larger than the mean lengths of HHPs. These genera constitute over 80 % of atypical genomes. CONCLUSIONS: We confirmed on a ubiquitous set of genomes that the previous observation of HHPs and ORFans have different gene length distributions. We also showed that Mycoplasmataceae genomes have very distinctive distributions of ORFans lengths. We offer several possible biological explanations of this phenomenon, such as an adaptation to Mycoplasmataceae's ecological niche, specifically its "quiet" co-existence with host organisms, resulting in long ABC transporters.

Development and clinical application of an InvaderPlus® assay for the detection of genital mycoplasmas.

We developed a PCR-based assay involving Invader® technology for detection of the genital mycoplasmas of Mycoplasma genitalium, Mycoplasma hominis, Ureaplasma urealyticum, and Ureaplasma parvum. We compared its performance with that of a PCR-microtiter plate hybridization assay, which we developed previously, in detecting genital mycoplasmas in first-voided urine (FVU) specimens from men with non-gonococcal urethritis. The tests targeting each of the genital mycoplasmas were specific for the respective species and could detect as few as 10 copies of the plasmids containing the target genes of each of the genital mycoplasmas per reaction. The assay using the InvaderPlus® method (InvaderPlus® assay) showed very similar performance to that of the PCR-microtiter plate hybridization assay for detecting the genital mycoplasmas in the FVU specimens. In addition, the PCR and endonuclease reaction in the InvaderPlus® assay were carried out simultaneously in one procedure, thus simplifying the assay, leading to time- and labor-savings and a decrease in the risk of specimen contamination. The InvaderPlus® assay could be useful in diagnosing genitourinary tract infections caused by the genital mycoplasmas.

Phylogenomics of "Candidatus Hepatoplasma crinochetorum," a lineage of mollicutes associated with noninsect arthropods.

Bacterial gut communities of arthropods are highly diverse and tightly related to host feeding habits. However, our understanding of the origin and role of the symbionts is often hindered by the lack of genetic information. "Candidatus Hepatoplasma crinochetorum" is a Mollicutes symbiont found in the midgut glands of terrestrial isopods. The only available nucleotide sequence for this symbiont is a partial 16S rRNA gene sequence. Here, we present the 657,101 bp assembled genome of Candidatus Hepatoplasma crinochetorum isolated from the terrestrial isopod Armadillidium vulgare. While previous 16S rRNA gene-based analyses have provided inconclusive results regarding the phylogenetic position of Candidatus Hepatoplasma crinochetorum within Mollicutes, we performed a phylogenomic analysis of 127 Mollicutes orthologous genes which confidently branches the species as a sister group to the Hominis group of Mycoplasma. Several genome properties of Candidatus Hepatoplasma crinochetorum are also highlighted compared with other Mollicutes genomes, including adjacent tryptophan tRNA genes, which further our understanding of the evolutionary dynamics of these genes in Mollicutes, and the presence of a probably inactivated CRISPR/Cas system, which constitutes a testimony of past interactions between Candidatus Hepatoplasma crinochetorum and mobile genetic elements, despite their current lack in this streamlined genome. Overall, the availability of the complete genome sequence of Candidatus Hepatoplasma crinochetorum paves the way for further investigation of its ecology and evolution.

Evaluation of Seeplex® STD6 ACE Detection kit for the diagnosis of six bacterial sexually transmitted infections.

Traditionally, the diagnosis of bacterial sexually transmitted infection (STI) has been dependent on the isolation of the causative pathogens by culturing endocervical or urethral swab specimens on selective media. While such procedures typically provide excellent diagnostic accuracy, they are often time-consuming and expensive. A multiplex polymerase chain reaction (PCR) assay, based on a semi-automated detection system, was evaluated for the detection of six STI causative organisms. The Seeplex(®) STD6 ACE (auto-capillary electrophoresis) Detection assay employed six pairs of dual priming oligonucleotide (DPO™) primers specifically targeted to unique genes of Chlamydia trachomatis, Neisseria gonorrhoeae, Mycoplasma genitalium, Ureaplasma urealyticum, Mycoplasma hominis, and Trichomonas vaginalis. A total of 739 specimens (304 cervical swabs and 435 urine samples) collected for 4 months were tested, and results were compared to those obtained with a combined monoplex PCR. The concordance between the multiplex PCR and monoplex PCR assay was 100% for both sensitivity and specificity. We also tested for the presence of two pathogenic bacteria (C. trachomatis and N. gonorrhoeae) and compared the results obtained with the multiplex PCR and BD ProbeTec duplex strand displacement amplification (SDA). The results of the multiplex PCR and duplex SDA were 99.7% concordant for C. trachomatis and 100% concordant for N. gonorrhoeae. The multiplex PCR assay using the Seeplex(®) STD6 ACE Detection kit proved to be a novel cost-effective and fast diagnostic tool with high sensitivity and specificity for the simultaneous detection of six STI pathogens.

RNA polymerase beta subunit (rpoB) gene and the 16S-23S rRNA intergenic transcribed spacer region (ITS) as complementary molecular markers in addition to the 16S rRNA gene for phylogenetic analysis and identification of the species of the family Mycoplasmataceae.

Conventional classification of the species in the family Mycoplasmataceae is mainly based on phenotypic criteria, which are complicated, can be difficult to measure, and have the potential to be hampered by phenotypic deviations among the isolates. The number of biochemical reactions suitable for phenotypic characterization of the Mycoplasmataceae is also very limited and therefore the strategy for the final identification of the Mycoplasmataceae species is based on comparative serological results. However, serological testing of the Mycoplasmataceae species requires a performance panel of hyperimmune sera which contains anti-serum to each known species of the family, a high level of technical expertise, and can only be properly performed by mycoplasma-reference laboratories. In addition, the existence of uncultivated and fastidious Mycoplasmataceae species/isolates in clinical materials significantly complicates, or even makes impossible, the application of conventional bacteriological tests. The analysis of available genetic markers is an additional approach for the primary identification and phylogenetic classification of cultivable species and uncultivable or fastidious organisms in standard microbiological laboratories. The partial nucleotide sequences of the RNA polymerase ß-subunit gene (rpoB) and the 16S-23S rRNA intergenic transcribed spacer (ITS) were determined for all known type strains and the available non-type strains of the Mycoplasmataceae species. In addition to the available 16S rRNA gene data, the ITS and rpoB sequences were used to infer phylogenetic relationships among these species and to enable identification of the Mycoplasmataceae isolates to the species level. The comparison of the ITS and rpoB phylogenetic trees with the 16S rRNA reference phylogenetic tree revealed a similar clustering patterns for the Mycoplasmataceae species, with minor discrepancies for a few species that demonstrated higher divergence of their ITS and rpoB in comparison to their neighbor species. Overall, our results demonstrated that the ITS and rpoB gene could be useful complementary phylogenetic markers to infer phylogenetic relationships among the Mycoplasmataceae species and provide useful background information for the choice of appropriate metabolic and serological tests for the final classification of isolates. In summary, three-target sequence analysis, which includes the ITS, rpoB, and 16S rRNA genes, was demonstrated to be a reliable and useful taxonomic tool for the species differentiation within the family Mycoplasmataceae based on their phylogenetic relatedness and pairwise sequence similarities. We believe that this approach might also become a valuable tool for routine analysis and primary identification of new isolates in medical and veterinary microbiological laboratories.

Host-specificity of environmentally transmitted Mycoplasma-like isopod symbionts.

Mycoplasms are known as pathogens of economic and medical interest in plants, animals and man. Here, we show a positive correlation between the presence of Mycoplasma-like symbionts in their isopod hosts and survivorship on low-quality food. Most isopods that survived feeding on a cellulose-based low-quality diet for 90 days harboured 'Candidatus Hepatoplasma' in their midgut glands, while those that died within 90 days mostly either harboured no or other bacterial symbionts. We detected 'Candidatus Hepatoplasma' in all but one of the examined species of terrestrial isopods from different habitats and locations, suggesting an evolutionarily ancient association between terrestrial isopods and their Mycoplasma-like symbionts. Phylogenetic analyses clustered symbionts from different populations of the same isopod species together, and clearly distinguished between symbionts of different isopod species, indicating host-specificity of 'Candidatus Hepatoplasma', although a previous study provided evidence for environmental symbiont transmission. Nonetheless, horizontal exchange of symbionts between species may have been possible in evolutionary earlier stages, as suggested by only limited congruency of phylogenetic trees of hosts and symbionts. Another symbiont, 'Candidatus Hepatincola porcellionum', was only detected in midgut glands of the most terrestrial tribe of isopods (Crinocheta), suggesting an evolutionarily younger host-symbiont association. This symbiont proved to be negatively correlated with host longevity, even on high-quality food.

"Candidatus hepatoplasma crinochetorum," a new, stalk-forming lineage of Mollicutes colonizing the midgut glands of a terrestrial isopod.

Uncultivated bacteria that densely colonize the midgut glands (hepatopancreas) of the terrestrial isopod Porcellio scaber (Crustacea: Isopoda) were identified by cloning and sequencing of their 16S rRNA genes. Phylogenetic analysis revealed that these symbionts represent a novel lineage of the Mollicutes and are only distantly related (<82% sequence identity) to members of the Mycoplasmatales and Entomoplasmatales. Fluorescence in situ hybridization with a specific oligonucleotide probe confirmed that the amplified 16S rRNA gene sequences indeed originated from a homogeneous population of symbionts intimately associated with the epithelial surface of the hepatopancreas. The same probe also detected morphotypically identical symbionts in other crinochete isopods. Scanning and transmission electron microscopy revealed uniform spherical bacterial cells without a cell wall, sometimes interacting with the microvilli of the brush border by means of stalk-like cytoplasmic appendages, which also appeared to be involved in cell division through budding. Based on the isolated phylogenetic position and unique cytological properties, the provisional name "Candidatus Hepatoplasma crinochetorum" is proposed for this new taxon of Mollicutes colonizing the hepatopancreas of P. scaber.

Classification of eubacteria based on their complete genome: where does Mycoplasmataceae belong?

The amino acid compositions of 11 Gram-positive and 12 Gram-negative eubacteria were determined from their complete genomes. They were classified into two groups, 'S-type' represented by Staphylococcus aureus and 'E-type' represented by Escherichia coli, based on their patterns of amino acid compositions determined from the complete genome. These two groups were characterized by their concentrations of Arg, Ala and Lys. Mycoplasmas, which lack a cell wall, belonged to the 'S-type', while Gram-positive mycobacteria belonged to the 'E-type'. Rickettsia prowazekii, Borrelia burgdorferi, Campylobacter jejuni and Helicobacter pylori, which are Gram-negative, belong to the 'S-type'. The classification into two groups based on their amino acid compositions determined from the complete genome was independent of Gram staining. In addition, the amino acid composition based on the plasmid resembled that based on the parent complete genome.

Comparison of multiplex PCR assay with culture for detection of genital mycoplasmas.

Ureaplasma, spp. Mycoplasma genitalium, and Mycoplasma hominis are associated with infection of the genitourinary tract, reproductive failure, and neonatal morbidity and mortality. We have developed a multiplex PCR for the detection of these Mycoplasmatales in a single amplification reaction. The analytical sensitivities of this assay were 10.8, 10.8, and 8.8 CFU for each organism, respectively. This multiplex PCR was compared to culture on 26 cervical swabs, 2 vaginal swabs, 4 female urine specimens, 49 semen samples, 2 male urine specimens, and 1 nonspecified sample. A total of 21 specimens were culture positive (25%); 17 of these were PCR positive. An additional 11 specimens were PCR positive but culture negative. Of the 21 culture-positive specimens, 17 (81%) grew Ureaplasma spp. and 4 (19%) grew Mycoplasma spp. Of the 28 PCR-positive specimens, Ureaplasma spp. was detected in 23 (82%), M. hominis was detected in 3 (11%), and both were detected in 2 (7%). In a confirmatory analysis, all samples were tested by amplification of a second target of the ureaplasma genome. True-positive cases were defined as a positive result by culture or by both amplification assays. The multiplex PCR detected organisms in 26 of the 30 true-positive specimens, as well as in 2 other specimens. Based on a 36% prevalence of infection, the sensitivity, specificity, and positive and negative predictive values of multiplex PCR analyses were 87, 96, 94, and 93%, respectively. Multiplex PCR offers a rapid, sensitive, and easy method to detect genital mycoplasmas.

In vitro development of resistance to enrofloxacin, erythromycin, tylosin, tiamulin and oxytetracycline in Mycoplasma gallisepticum, Mycoplasma iowae and Mycoplasma synoviae.

The in vitro emergence of resistance to enrofloxacin, erythromycin, tylosin, tiamulin, and oxytetracycline in three avian Mycoplasma species, Mycoplasma gallisepticum, Mycoplasma synoviae and Mycoplasma iowae was studied. Mutants were selected stepwise and their MICs were determined after 10 passages in subinhibitory concentrations of antibiotic. High-level resistance to erythromycin and tylosin developed within 2-6 passages in the three Mycoplasma species. Resistance to enrofloxacin developed more gradually. No resistance to tiamulin or oxytetracycline could be evidenced in M. gallisepticum or M. synoviae after 10 passages whereas, resistant mutants were obtained with M. iowae. Cross-sensitivity tests performed on mutants demonstrated that mycoplasmas made resistant to tylosin were also resistant to erythromycin, whereas mutants made resistant to erythromycin were not always resistant to tylosin. Some M. iowae tiamulin-resistant mutants were also resistant to both macrolide antibiotics. Enrofloxacin and oxytetracycline did not induce any cross-resistance to the other antibiotics tested. These results show that Mycoplasma resistance to macrolides can be quickly selected in vitro, and thus, providing that similar results could be obtained under field conditions, that development of resistance to these antibiotics in vivo might also be a relatively frequent event.

Characterization of the mycoplasmalike organism associated with witches'-broom disease of lime and proposition of a Candidatus taxon for the organism, "Candidatus phytoplasma aurantifolia".

Witches'-broom disease of small-fruited acid lime (WBDL) is a severe disease caused by a mycoplasmalike organism (MLO) in the Sultanate of Oman and the United Arab Emirates. The WBDL MLO was characterized by studying its genome size, the sequences of its 16S ribosomal DNA and the 16S-23S ribosomal DNA spacer region, and hybridization profiles obtained by using WBDL MLO-specific probes. The size of the WBDL MLO genome is 720 kbp. Genomic similarities with the MLOs of sunhemp, sesame, and alfalfa phyllodies were demonstrated, and we found that the WBDL MLO belongs to the sunhemp phyllody phylogenetic subgroup.

Pulsed-field electrophoresis indicates larger-than-expected sizes for mycoplasma genomes.

The sizes of large DNA fragments produced from genomes of members of the Mycoplasmataceae by digestion with restriction endonucleases having infrequent (1 to 3) cleavage sites within the genome were estimated from their mobility in contour-clamped homogeneous electric field (CHEF) agarose gel electrophoresis by comparison with yeast chromosomal DNA markers. The estimates of total genome size for 7 strains of 6 species ranged from approximately 900 kilo base pairs (kb) for Ureaplasma urealyticum 960T to 1330 kb for M. mycoides subsp. mycoides, GC-1176. The values derived from this new method are considerably higher than those of approximately 500 Mdaltons or 750 kb previously reported for genome sizes in members of the Mycoplasmataceae.