TcpM: a novel relaxase that mediates transfer of large conjugative plasmids from Clostridium perfringens

Conjugative transfer of toxin and antibiotic resistance plasmids in Clostridium perfringens is mediated by the tcp conjugation locus. Surprisingly, neither a relaxase gene nor an origin of transfer (oriT) has been identified on these plasmids, which are typified by the 47 kb tetracycline resistance plasmid pCW3. The tcpM gene (previously called intP) encodes a potential tyrosine recombinase that was postulated to be an atypical relaxase. Mutagenesis and complementation studies showed that TcpM was required for wild‐type transfer of pCW3 and that a tyrosine residue, Y259, was essential for TcpM activity, which was consistent with the need for a relaxase‐mediated hydrophilic attack at the oriT site. Other catalytic residues conserved in tyrosine recombinases were not required for TcpM activity, suggesting that TcpM was not a site‐specific recombinase. Mobilization studies led to the identification of the oriT site, which was located in the 391 bp intergenic region upstream of tcpM. The oriT site was localized to a 150 bp region, and gel mobility shift studies showed that TcpM could bind to this region. Based on these studies we postulate that conjugative transfer of pCW3 involves the atypical relaxase TcpM binding to and processing the oriT site to initiate plasmid transfer.     

Binary toxin production in Clostridium difficile is regulated by CdtR, a LytTR family response regulator

Clostridium difficile binary toxin (CDT) is an actin-specific ADP-ribosyltransferase that is produced by various C. difficile isolates, including the "hypervirulent" NAP1/027 epidemic strains. In contrast to the two major toxins from C. difficile, toxin A and toxin B, little is known about the role of CDT in virulence or how C. difficile regulates its production. In this study we have shown that in addition to the cdtA and cdtB toxin structural genes, a functional cdt locus contains a third gene, here designated cdtR, which is predicted to encode a response regulator. By introducing functional binary toxin genes into cdtR(+) and cdtR-negative strains of C. difficile, it was established that the CdtR protein was required for optimal expression of binary toxin. Significantly increased expression of functional binary toxin was observed in the presence of a functional cdtR gene; an internal deletion within cdtR resulted in a reduction in binary toxin production to basal levels. Strains that did not carry intact cdtAB genes or cdtAB pseudogenes also did not have cdtR, with the entire cdt locus, or CdtLoc, being replaced by a conserved 68-bp sequence. These studies have shown for the first time that binary toxin production is subject to strict regulatory control by the response regulator CdtR, which is a member of the LytTR family of response regulators and is related to the AgrA protein from Staphylococcus aureus.     

The Quantification of Representative Sequences pipeline for amplicon sequencing: case study on within‐population ITS1 sequence variation in a microparasite infecting Daphnia

Next generation sequencing (NGS) platforms are replacing traditional molecular biology protocols like cloning and Sanger sequencing. However, accuracy of NGS platforms has rarely been measured when quantifying relative frequencies of genotypes or taxa within populations. Here we developed a new bioinformatic pipeline (QRS) that pools similar sequence variants and estimates their frequencies in NGS data sets from populations or communities. We tested whether the estimated frequency of representative sequences, generated by 454 amplicon sequencing, differs significantly from that obtained by Sanger sequencing of cloned PCR products. This was performed by analysing sequence variation of the highly variable first internal transcribed spacer (ITS1) of the ichthyosporean Caullerya mesnili, a microparasite of cladocerans of the genus Daphnia. This analysis also serves as a case example of the usage of this pipeline to study within‐population variation. Additionally, a public Illumina data set was used to validate the pipeline on community‐level data. Overall, there was a good correspondence in absolute frequencies of C. mesnili ITS1 sequences obtained from Sanger and 454 platforms. Furthermore, analyses of molecular variance (amova ) revealed that population structure of C. mesnili differs across lakes and years independently of the sequencing platform. Our results support not only the usefulness of amplicon sequencing data for studies of within‐population structure but also the successful application of the QRS pipeline on Illumina‐generated data. The QRS pipeline is freely available together with its documentation under GNU Public Licence version 3 at http://code.google.com/p/quantification-representative-sequences .     

A new Late Miocene ovibovine-like bovid (Bovidae,Mammalia) from the Kassandra Peninsula (Chalkidiki,Northern Greece) and implications to the phylogeography of the group

A new Late Miocene bovid, Urmiatherium kassandriensis sp. nov., from Northern Greece is described. The material comes from the Fourka locality in the Kassandra Peninsula (Chalkidiki), and the included fauna is estimated to be of Vallesian age. The two preserved crania represent a medium-sized taxon with short, conical horn cores, a flat cranial roof (consisting of the posterior part of the frontals, parietal and occipital), thick and porous frontals and pneumatized short parietals, an extremely thick basioccipital with voluminous posterior tuberosities and accessory articular facets for the atlas. The specialized atlanto-occipital joint recalls Pleistocene and extant ovibovines, but the braincase structure as a whole and the horn core features closely match Late Miocene ovibovine-like taxa, especially Plesiaddax and even more Urmiatherium. Nevertheless, the Kassandra bovid differs from representatives of both genera in the simpler horn core morphology and external brain anatomy. Urmiatherium is known to appear first in China and Iran at about 7.8 Ma, whereas its westernmost appearance on Samos Island (Greece) is dated much later. The presence of Urmiatherium kassandriensis sp. nov. in N. Greece suggests a farther west and earlier (Vallesian at least) first appearance of the genus. This would justify a basic geographic and phylogenetic split of Urmiatherium into two main Turolian lineages: a central-eastern Asian one leading to the sister species U. polaki and U. intermedium and a western one leading to U. rugosifrons.     

DNA binding properties of TnpX indicate that different synapses are formed in the excision and integration of the Tn4451 family

Site-specific recombination is an important mechanism for genetic exchange. Insertional recombination mediated by the recently delineated large resolvase or serine recombinase proteins is unique within the resolvase family as integration was thought to be a reaction catalysed only by members of the integrase or tyrosine recombinase family of site-specific recombinases. The large resolvase TnpX is a serine recombinase that is responsible for the movement of the Tn4451/3 family of chloramphenicol resistance elements, which are found within two genera of the medically important clostridia. Deletion analysis of TnpX showed that the last 110 amino acids (aa) of TnpX, which comprise a cysteine rich region, were not essential for its biological function and that a region required for DNA binding was located between aa 493-597. Purified TnpX was shown to bind to the ends of the element and to the joint of the circular intermediate with high affinity but, most unusually, to bind to its target sites with a considerably lower affinity. Therefore, it was concluded that the resolvase-like excision and insertion reactions mediated by TnpX were distinct processes even though the same serine recombinase mechanism was involved. TnpX is the first large serine recombinase in which differential binding to its transposon and target sites has been demonstrated.     

Calcium regulation by thermo- and osmosensing transient receptor potential vanilloid channels (TRPVs) in human conjunctival epithelial cells

Transient receptor potential vanilloid (TRPV) channels respond to polymodal stresses to induce pain, inflammation and tissue fibrosis. In this study, we probed for their functional expression in human conjunctival epithelial (HCjE) cells and ex vivo human conjunctivas. Notably, patients suffering from dry eye syndrome experience the same type of symptomology induced by TRPV channel activation in other ocular tissues. TRPV gene and protein expression were determined by RT-PCR and immunohistochemistry in HCjE cells and human conjunctivas (body donors). The planar patch-clamp technique was used to record nonselective cation channel currents. Ca(2+) transients were monitored in fura-2 loaded cells. Cultivated HCjE cells and human conjunctiva express TRPV1, TRPV2, and TRPV4 mRNA. TRPV1 and TRPV4 localization was identified in human conjunctiva. Whereas the TRPV1 agonist capsaicin (CAP) (5-20 μM) -induced Ca(2+) transients were blocked by capsazepine (CPZ) (10 μM), the TRPV4 activator 4α-PDD (10 μM) -induced Ca(2+) increases were reduced by ruthenium-red (RuR) (20 μM). Different heating (<40°C or >43°C) led to Ca(2+) increases, which were also reduced by RuR. Hypotonic challenges of either 25 or 50% induced Ca(2+) transients and nonselective cation channel currents. In conclusion, conjunctiva express TRPV1, TRPV2, and TRPV4 channels which may provide novel drug targets for dry eye therapeutics. Their usage may have fewer side effects than those currently encountered with less selective drugs.     

Ultrafast Energy Transfer in the Metal Nanoparticles-Graphene Nanodisks-Quantum Dots Hybrid Systems

Plasmonics - Hybrid nanocomposites can offer a wide range of opportunities to control the light-matter interaction and electromagnetic energy flow at the nanoscale, leading to exotic optoelectronic...     

Utility of the Clostridial Site-Specific Recombinase TnpX To Clone Toxic-Product-Encoding Genes and Selectively Remove Genomic DNA Fragments

TnpX is a site-specific recombinase responsible for the excision and insertion of the transposons Tn4451 and Tn4453 in Clostridium perfringens and Clostridium difficile, respectively. Here, we exploit phenotypic features of TnpX to facilitate genetic mutagenesis and complementation studies. Genetic manipulation of bacteria often relies on the use of antibiotic resistance genes; however, a limited number are available for use in the clostridia. The ability of TnpX to recognize and excise specific DNA fragments was exploited here as the basis of an antibiotic resistance marker recycling system, specifically to remove antibiotic resistance genes from plasmids in Escherichia coli and from marked chromosomal C. perfringens mutants. This methodology enabled the construction of a C. perfringens plc virR double mutant by allowing the removal and subsequent reuse of the same resistance gene to construct a second mutation. Genetic complementation can be challenging when the gene of interest encodes a product toxic to E. coli. We show that TnpX represses expression from its own promoter, P_attCI, which can be exploited to facilitate the cloning of recalcitrant genes in E. coli for subsequent expression in the heterologous host C. perfringens. Importantly, this technology expands the repertoire of tools available for the genetic manipulation of the clostridia.     

tISCpe8, an IS1595-Family Lincomycin Resistance Element Located on a Conjugative Plasmid in Clostridium perfringens

Clostridium perfringens is a normal gastrointestinal organism that is a reservoir for antibiotic resistance genes and can potentially act as a source from which mobile elements and their associated resistance determinants can be transferred to other bacterial pathogens. Lincomycin resistance in C. perfringens is common and is usually encoded by erm genes that confer macrolide-lincosamide-streptogramin B resistance. In this study we identified strains that are lincomycin resistant but erythromycin sensitive and showed that the lincomycin resistance determinant was plasmid borne and could be transferred to other C. perfringens isolates by conjugation. The plasmid, pJIR2774, is the first conjugative C. perfringens R-plasmid to be identified that does not confer tetracycline resistance. Further analysis showed that resistance was encoded by the lnuP gene, which encoded a putative lincosamide nucleotidyltransferase and was located on tISCpe8, a functional transposable genetic element that was a member of the IS1595 family of transposon-like insertion sequences. This element had significant similarity to the mobilizable lincomycin resistance element tISSag10 from Streptococcus agalactiae. Like tISSag10, tISCpe8 carries a functional origin of transfer within the resistance gene, allowing the element to be mobilized by the conjugative transposon Tn916. The similarity of these elements and the finding that they both contain an oriT-like region support the hypothesis that conjugation may result in the movement of DNA modules that are not obviously mobile since they are not linked to conjugation or mobilization functions. This process likely plays a significant role in bacterial adaptation and evolution.There has been increasing concern about the emergence of multiply antibiotic-resistant strains of many common bacterial pathogens. The development of multiple resistance phenotypes has already led to compromises in the ability to successfully treat infected patients and to increased treatment costs (15). The emergence of resistant bacteria is often the result of excessive or inappropriate use of antibiotics and the ability of antibiotic resistance genes to be transferred from resistant to susceptible bacteria, either within a bacterial species, between different species within the same genus, or between different genera (14). Different types of mobile genetic elements, including conjugative plasmids, conjugative transposons, mobilizable plasmids, mobilizable transposons, nonconjugative plasmids, and integrons, may contain the resistance genes (14). All of these elements have the ability to mediate the transfer of resistance genes within and between bacterial cells, either independently or cooperatively, which has significant implications for the transfer and evolution of antibiotic resistance, particularly in pathogenic bacterial species.Clostridium perfringens is a normal gastrointestinal organism that causes food poisoning, necrotic enteritis, and gas gangrene (29). It is a proven reservoir for antibiotic resistance determinants. For example, the catP chloramphenicol resistance determinant, which is located on the Tn4451/Tn4453 family of integrative mobilizable elements in C. perfringens and Clostridium difficile, has been detected in clinical isolates of Neisseria meningitidis (20, 23, 41). Similarly, genetically related variants of the macrolide-lincosamide-streptogramin B (MLS) resistance determinant Erm(B) from C. perfringens have been found in Enterococcus faecalis, Streptococcus agalactiae, and C. difficile (19). It is likely that the C. perfringens determinant is the progenitor of the C. difficile determinant (18, 19, 44). Significantly, both determinants can be transferred into recipient cells by conjugation, although the processes are different (12, 19, 43). The pathogenic clostridia also carry other uncharacterized MLS resistance determinants and can potentially act as a source from which these resistance determinants may be transferred to other bacterial pathogens (10, 18).Lincomycin belongs to the lincosamide group of antibiotics, which also includes clindamycin. The spectrum of activity of lincosamides predominantly encompasses gram-positive bacteria, and these antimicrobial agents are often used for treatment of infections caused by anaerobic bacteria (45). These antibiotics inhibit protein synthesis by blocking the peptidyltransferase site of the 23S rRNA component of the 50S subunit of the bacterial ribosome (17). Although cross-resistance to MLS antibiotics most commonly involves N6 dimethylation of the A2058 residue of 23S rRNA and is catalyzed by an erm-encoded rRNA methyltransferase (24, 34, 47), specific resistance to the lincosamides is the result of modification and inactivation by a lincosamide nucleotidyltransferase encoded by members of the lnu (previously lin) gene family (5, 34, 45). This type of resistance gene is found in staphylococci and streptococci, where it is often located on plasmids or transposons (5, 45).Lincomycin resistance in C. perfringens is relatively common, but it is usually conferred as MLS resistance by erm(B) or erm(Q) genes (10, 11). Recent studies have shown that there has been an increase in lincomycin resistance in C. perfringens strains isolated from chickens in Belgium (28). The researchers reported two strains that conferred resistance to lincomycin and carried the lnu(A) or lnu(B) gene, the first such strains reported for C. perfringens.In the current study we analyzed several multiply antibiotic-resistant isolates of C. perfringens and identified strains that were lincomycin resistant but were susceptible to erythromycin. We characterized these isolates and their lincomycin resistance determinant(s) and showed that resistance could be transferred to other C. perfringens isolates. Detailed analysis of the lincomycin-resistant strain 95-949 showed that resistance was encoded by the lnuP gene, which was located on a transposable genetic element, tISCpe8, that was located on a conjugative plasmid, pJIR2774. This plasmid is the first conjugative C. perfringens R-plasmid to be identified that does not confer tetracycline resistance.     

From Jumbo to Dumbo: Cranial Shape Changes in Elephants and Hippos During Phyletic Dwarfing

Members of the mammalian families Elephantidae and Hippopotamidae (extant and extinct elephants and hippos) include extinct dwarf species that display up to 98% decrease in body size compared to probable ancestral sources. In addition to differences in body mass, skulls of these species consistently display distinctive morphological changes, including major reduction of pneumatised areas in dwarf elephants and shortened muzzles in dwarf hippos. Here we build on previous studies of island dwarf species by conducting a geometric morphometric analysis of skull morphology and allometry in target taxa, living and extinct, and elaborate on the relation between skull size and body size. Our analysis indicates that skull size and body size within terrestrial placental mammals scale almost isometrically (PGLS major axis slope 0.906). Furthermore, skull shape in dwarf species differed from both their ancestors and the juveniles of extant species. In insular dwarf hippos, the skull was subject to considerable anatomical reorganisation in response to distinct selection pressures affecting early ontogeny (the “island syndrome”). By contrast, skull shape in adult insular dwarf elephants can be explained well by allometric effects; selection on size may thus have been the main driver of skull shape in dwarf elephants. We suggest that a tightly constrained growth trajectory, without major anatomical reorganization of the skull, allowed for flexible adaptations to changing environments and was one of the factors underlying the evolutionary success of insular dwarf elephants.