A New Borrelia Species Defined by Multilocus Sequence Analysis of Housekeeping Genes

Analysis of Lyme borreliosis (LB) spirochetes, using a novel multilocus sequence analysis scheme, revealed that OspA serotype 4 strains (a rodent-associated ecotype) of Borrelia garinii were sufficiently genetically distinct from bird-associated B. garinii strains to deserve species status. We suggest that OspA serotype 4 strains be raised to species status and named Borrelia bavariensis sp. nov. The rooted phylogenetic trees provide novel insights into the evolutionary history of LB spirochetes.Multilocus sequence typing (MLST) and multilocus sequence analysis (MLSA) have been shown to be powerful and pragmatic molecular methods for typing large numbers of microbial strains for population genetics studies, delineation of species, and assignment of strains to defined bacterial species (4, 13, 27, 40, 44). To date, MLST/MLSA schemes have been applied only to a few vector-borne microbial populations (1, 6, 30, 37, 40, 41, 47).Lyme borreliosis (LB) spirochetes comprise a diverse group of zoonotic bacteria which are transmitted among vertebrate hosts by ixodid (hard) ticks. The most common agents of human LB are Borrelia burgdorferi (sensu stricto), Borrelia afzelii, Borrelia garinii, Borrelia lusitaniae, and Borrelia spielmanii (7, 8, 12, 35). To date, 15 species have been named within the group of LB spirochetes (6, 31, 32, 37, 38, 41). While several of these LB species have been delineated using whole DNA-DNA hybridization (3, 20, 33), most ecological or epidemiological studies have been using single loci (5, 9-11, 29, 34, 36, 38, 42, 51, 53). Although some of these loci have been convenient for species assignment of strains or to address particular epidemiological questions, they may be unsuitable to resolve evolutionary relationships among LB species, because it is not possible to define any outgroup. For example, both the 5S-23S intergenic spacer (5S-23S IGS) and the gene encoding the outer surface protein A (ospA) are present only in LB spirochete genomes (36, 43). The advantage of using appropriate housekeeping genes of LB group spirochetes is that phylogenetic trees can be rooted with sequences of relapsing fever spirochetes. This renders the data amenable to detailed evolutionary studies of LB spirochetes.LB group spirochetes differ remarkably in their patterns and levels of host association, which are likely to affect their population structures (22, 24, 46, 48). Of the three main Eurasian Borrelia species, B. afzelii is adapted to rodents, whereas B. valaisiana and most strains of B. garinii are maintained by birds (12, 15, 16, 23, 26, 45). However, B. garinii OspA serotype 4 strains in Europe have been shown to be transmitted by rodents (17, 18) and, therefore, constitute a distinct ecotype within B. garinii. These strains have also been associated with high pathogenicity in humans, and their finer-scale geographical distribution seems highly focal (10, 34, 52, 53).In this study, we analyzed the intra- and interspecific phylogenetic relationships of B. burgdorferi, B. afzelii, B. garinii, B. valaisiana, B. lusitaniae, B. bissettii, and B. spielmanii by means of a novel MLSA scheme based on chromosomal housekeeping genes (30, 48).     

Complete Genome Sequence of the Ethanol Producer Zymomonas mobilis NCIMB 11163

Zymomonas mobilis is an ethanol-producing alphaproteobacterium currently considered a major candidate organism for bioethanol production. Here we report the finished and annotated genome sequence of Z. mobilis subsp. mobilis strain NCIMB 11163, a British ale-infecting isolate. This is the first Z. mobilis strain whose genome, chromosomal and plasmid, is presented in its entirety.Zymomonas mobilis is a bacterium vigorously studied as a platform organism for bioethanol production in North America and other parts of the world. Z. mobilis converts sugars such as glucose or sucrose into ethanol and carbon dioxide to almost theoretical yields and to rates higher than those of yeasts (17). Genetically engineered strains that ferment pentoses in addition to naturally utilized hexoses also hold great promise for use in lignocellulosic biomass degradations (5, 22). Besides ethanol, Z. mobilis can produce other high-value chemicals such as sorbitol, levan, or phenylacetylcarbinol and has attracted interest for its unusual membrane steroid content (11). Lastly, Zymomonas is regarded as a safe organism and is even used for medicinal purposes (12, 20), which further facilitates its employment in large-scale biotechnological endeavors.The chromosomal sequence of the Z. mobilis subsp. mobilis industrial strain ATCC 31821 (ZM4) was recently published (19). Here we announce the first entire genome sequence of a Z. mobilis subsp. mobilis strain, that of the United Kingdom-originating strain NCIMB 11163 (B70) (20). Total DNA from NCIMB 11163 (16) was used for whole-genome shotgun sequencing at the U.S. DOE Joint Genome Institute. For this, an 8.7-kb DNA library and 454 and Solexa reads were used (http://www.jgi.doe.gov). Draft assemblies were based on 8,551 Sanger reads and 454 pyrosequencing to 20× coverage, whereas the Phred/Phrap/Consed software package was used for sequence assembly and quality assessment (6, 7, 9; http://www.phrap.com). After the shotgun stage, reads were assembled with parallel Phrap (High Performance Software, LLC), and misassemblies were corrected with Dupfinisher (10) or transposon bombing of bridging clones (Epicentre Biotechnologies, Madison, WI). A total of 144 primer walk reactions, five transposon bomb libraries, 53 PCR end reads, and two PCR shatter libraries were necessary to close gaps, resolve repetitive regions, and raise the quality of the finished sequence. The completed genome sequence of NCIMB 11163 was based on 11,048 reads, with an error rate of less than 6 bp out of 100,000 bp.Open reading frame prediction and annotation were performed using Prodigal (http://compbio.ornl.gov/prodigal/) and BLAST (1); tRNAscan-SE and RNAmmer (14, 15) were used for tRNA and rRNA recognition, respectively. Functional assignment of genes was performed by searching translated open reading frames against sequences in the SPTR (TrEMBL) (2), Pfam (8), TIGRFAMs (18), COG (21), and KEGG (13) databases.Z. mobilis NCIMB 11163 contains a single, circular chromosome of 2,124,771 bp and three plasmids, p11163_1, p11163_2, and p11163_3 of 53,380 bp, 40,818 bp, and 4,551 bp, respectively. The overall GC content of the chromosome is 46.83%, whereas those of the plasmids are 42.32%, 43.80%, and 36.37%, respectively. The entire genome of NCIMB 11163 contains 1,884 protein-encoding genes and 51 tRNA and nine rRNA genes, which are chromosomally located.The chromosome of NCIMB 11163 is 68,355 bp larger than that of ZM4 (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"NC_006526","term_id":"283856168","term_text":"NC_006526"}}NC_006526) (19) and colinear at its largest part with that of ZM4 (genome structure comparisons were performed using ACT) (3). It bears several unique regions, among which are two genomic islands of ca. 25 and 79 kb, with no detectable nucleotide homology to same-species sequences and high regional similarity to chromosomal stretches of Paracoccus denitrificans PD1222 (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"CP000489.1","term_id":"119372524","term_text":"CP000489.1"}}CP000489.1), Xanthobacter autotrophicus Py2 (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"CP000781.1","term_id":"154158043","term_text":"CP000781.1"}}CP000781.1), and Gluconacetobacter diazotrophicus PAl 5 (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"CP001189.1","term_id":"209529865","term_text":"CP001189.1"}}CP001189.1). Genome plasticity in NCIMB 11163 is further indicated by the presence of a type IV secretion system on the 79-kb island, syntenous to the Agrobacterium tumefaciens Ti (IncRh1) conjugal trb system (4), and also by multiple transposase and phage-related genes.In plasmids, housekeeping genes implicated in replication, active partitioning, and plasmid addiction are recognized, as well as genes involved in metabolism, transport, regulation, transposition, and DNA modification. Most notably, p11163_1 bears an arsenical resistance operon inserted in a type II secretion locus, whereas p11163_2, otherwise homologous to the 41-kb ZM4 plasmid (GenBank accession number {"type":"entrez-nucleotide","attrs":{"text":"AY057845","term_id":"26983909","term_text":"AY057845"}}AY057845), harbors a unique ca. 12-kb CRISPR insertion that interrupts nucleotide colinearity with the aforementioned replicon.     

Integrative and Sequence Characteristics of a Novel Genetic Element,ICE6013, in Staphylococcus aureus

A survey of chromosomal variation in the ST239 clonal group of methicillin-resistant Staphylococcus aureus (MRSA) revealed a novel genetic element, ICE6013. The element is 13,354 bp in length, excluding a 6,551-bp Tn552 insertion. ICE6013 is flanked by 3-bp direct repeats and is demarcated by 8-bp imperfect inverted repeats. The element was present in 6 of 15 genome-sequenced S. aureus strains, and it was detected using genetic markers in 19 of 44 diverse MRSA and methicillin-susceptible strains and in all 111 ST239 strains tested. Low integration site specificity was discerned. Multiple chromosomal copies and the presence of extrachromosomal circular forms of ICE6013 were detected in various strains. The circular forms included 3-bp coupling sequences, located between the 8-bp ends of the element, that corresponded to the 3-bp direct repeats flanking the chromosomal forms. ICE6013 is predicted to encode 15 open reading frames, including an IS30-like DDE transposase in place of a Tyr/Ser recombinase and homologs of gram-positive bacterial conjugation components. Further sequence analyses indicated that ICE6013 is more closely related to ICEBs1 from Bacillus subtilis than to the only other potential integrative conjugative element known from S. aureus, Tn5801. Evidence of recombination between ICE6013 elements is also presented. In summary, ICE6013 is the first member of a new family of active, integrative genetic elements that are widely dispersed within S. aureus strains.ST239 is a globally distributed clonal group of methicillin-resistant Staphylococcus aureus (MRSA). Currently, ST239 is a major cause of MRSA infections in Asian hospitals (5, 18, 25, 37, 45, 64, 74). Pulsed-field gel electrophoresis has detected extensive chromosomal variation in local ST239 populations (3, 24, 52, 72). As ST239 has geographically spread and diversified, its variants have been given more than a dozen different names (20, 22, 24, 25, 49, 52, 61, 67, 68, 73), which reflects their clinical significance in various locales. The molecular basis for the ecological success of ST239 is unclear, but virulence-associated traits such as enhanced biofilm development and epidemiological characteristics such as a propensity to cause device-associated bacteremia and pulmonary infections have been highlighted (3, 19, 27, 54).Multilocus genetic investigations of the ST239 chromosome revealed that it is a hybrid with estimated parental contributions of approximately 20% and 80% from distantly related ST30- and ST8-like parents, respectively (58). Unusual for naturally isolated bacteria was the finding that these parental contributions were large chromosomal replacements rather than a patchwork of localized recombinations. It was postulated that conjugation might be responsible for the natural transfer of hundreds of kilobases of contiguous chromosomal DNA that resulted in ST239 (58). Recent genomic investigations have presented evidence that large chromosomal replacements also occur within Streptococcus agalactiae strains and that they can be mimicked with laboratory conjugation experiments (12). Importantly, conjugative transfer frequencies in S. agalactiae were found to be highest near three genomic islands (12), two of which were identified as being integrative conjugative elements (ICEs) (13).ICEs and conjugative transposons are synonyms and refer to genetic elements that are maintained by integration into a replicon and are transmitted by self-encoded conjugation functions (56). ICEs abound in the genomes of S. agalactiae (11), but only one potential ICE has been identified in staphylococci to date: Tn5801 was discovered through the genomic sequencing of S. aureus strain Mu50 (46). Tn5801 is most similar to a truncated genetic element, CW459tet(M), from Clostridium perfringens (57). Both Tn5801 and CW459tet(M) have Tyr recombinases, regulatory genes, and tetM modules that are similar to those of the prototypical gram-positive conjugative transposon, Tn916. Moreover, both Tn5801 and CW459tet(M) integrate into the same locus, guaA, at a nearly identical 11-bp sequence. Although the conjugative transfer module of CW459tet(M) is deleted (57), the conjugative transfer module of Tn5801 is similar to that of Tn916.We suspected that ST239 strains might carry novel accessory genes that contribute to their chromosomal variation and ecological success. To explore this possibility, we conducted a survey of chromosomal variation in ST239 using a PCR scanning approach. We report the discovery and partial characterization of a novel genetic element, ICE6013, that resulted from the survey.     

A Commensal Gone Bad: Complete Genome Sequence of the Prototypical Enterotoxigenic Escherichia coli Strain H10407

In most cases, Escherichia coli exists as a harmless commensal organism, but it may on occasion cause intestinal and/or extraintestinal disease. Enterotoxigenic E. coli (ETEC) is the predominant cause of E. coli-mediated diarrhea in the developing world and is responsible for a significant portion of pediatric deaths. In this study, we determined the complete genomic sequence of E. coli {"type":"entrez-nucleotide","attrs":{"text":"H10407","term_id":"875229","term_text":"H10407"}}H10407, a prototypical strain of enterotoxigenic E. coli, which reproducibly elicits diarrhea in human volunteer studies. We performed genomic and phylogenetic comparisons with other E. coli strains, revealing that the chromosome is closely related to that of the nonpathogenic commensal strain E. coli HS and to those of the laboratory strains E. coli K-12 and C. Furthermore, these analyses demonstrated that there were no chromosomally encoded factors unique to any sequenced ETEC strains. Comparison of the E. coli {"type":"entrez-nucleotide","attrs":{"text":"H10407","term_id":"875229","term_text":"H10407"}}H10407 plasmids with those from several ETEC strains revealed that the plasmids had a mosaic structure but that several loci were conserved among ETEC strains. This study provides a genetic context for the vast amount of experimental and epidemiological data that have been published.Current dogma suggests the Gram-negative motile bacterium Escherichia coli colonizes the infant gut within hours of birth and establishes itself as the predominant facultative anaerobe of the colon for the remainder of life (3, 59). While the majority of E. coli strains maintain this harmless existence, some strains have adopted a pathogenic lifestyle. Contemporary tenets suggest that pathogenic strains of E. coli have acquired genetic elements that encode virulence factors and enable the organism to cause disease (12). The large repertoire of virulence factors enables E. coli to cause a variety of clinical manifestations, including intestinal infections mediating diarrhea and extraintestinal infections, such as urinary tract infections, septicemia, and meningitis. Based on clinical manifestation of disease, the repertoire of virulence factors, epidemiology, and phylogenetic profiles, the strains causing intestinal infections can be divided into six separate pathotypes, viz., enteroaggregative E. coli (EAEC), enteroinvasive E. coli (EIEC), enteropathogenic E. coli (EPEC), enterohemorrhagic E. coli (EHEC), diffuse adhering E. coli (DAEC), and enterotoxigenic E. coli (ETEC) (33, 35, 39).ETEC is responsible for the majority of E. coli-mediated cases of human diarrhea worldwide. It is particularly prevalent among children in developing countries, where sanitation and clean supplies of drinking water are inadequate, and in travelers to such regions. It is estimated that there are 200 million incidences of ETEC infection annually, resulting in hundreds of thousands of deaths in children under the age of 5 (55, 64). The essential determinants of ETEC virulence are traditionally considered to be colonization of the host small-intestinal epithelium via plasmid-encoded colonization factors (CFs) and subsequent release of plasmid-encoded heat-stable (ST) and/or heat-labile (LT) enterotoxins that induce a net secretory state leading to profuse watery diarrhea (20, 62). More recently, additional plasmid-encoded factors have been implicated in the pathogenesis of ETEC, namely, the EatA serine protease autotransporter (SPATE) and the EtpA protein, which acts as an intermediate in the adhesion between bacterial flagella and host cells (23, 32, 42, 46). Furthermore, a number of chromosomal factors are thought to be involved in virulence, e.g., the invasin Tia; the TibA adhesin/invasin; and LeoA, a GTPase with unknown function (14, 21, 22). E. coli {"type":"entrez-nucleotide","attrs":{"text":"H10407","term_id":"875229","term_text":"H10407"}}H10407 is considered a prototypical ETEC strain; it expresses colonization factor antigen 1 (CFA/I) and the heat-stable and heat labile toxins. Loss of a 94.8-kb plasmid encoding CFA/I and a gene for ST enterotoxin from E. coli strain {"type":"entrez-nucleotide","attrs":{"text":"H10407","term_id":"875229","term_text":"H10407"}}H10407 leads to reduced ability to cause diarrhea (17).Here, we report the complete genome sequence and virulence factor repertoire of the prototypical ETEC strain {"type":"entrez-nucleotide","attrs":{"text":"H10407","term_id":"875229","term_text":"H10407"}}H10407 and the nucleotide sequence and gene repertoire of the plasmids from ETEC strain E1392/75, and we describe a novel conserved secretion system associated with the sequenced ETEC strains.     

Agrobacterium tumefaciens Type IV Secretion Protein VirB3 Is an Inner Membrane Protein and Requires VirB4, VirB7, and VirB8 for Stabilization

Agrobacterium tumefaciens VirB proteins assemble a type IV secretion apparatus and a T-pilus for secretion of DNA and proteins into plant cells. The pilin-like protein VirB3, a membrane protein of unknown topology, is required for the assembly of the T-pilus and for T-DNA secretion. Using PhoA and green fluorescent protein (GFP) as periplasmic and cytoplasmic reporters, respectively, we demonstrate that VirB3 contains two membrane-spanning domains and that both the N and C termini of the protein reside in the cytoplasm. Fusion proteins with GFP at the N or C terminus of VirB3 were fluorescent and, like VirB3, localized to a cell pole. Biochemical fractionation studies demonstrated that VirB3 proteins encoded by three Ti plasmids, the octopine Ti plasmid pTiA6NC, the supervirulent plasmid pTiBo542, and the nopaline Ti plasmid pTiC58, are inner membrane proteins and that VirB4 has no effect on membrane localization of pTiA6NC-encoded VirB3 (pTiA6NC VirB3). The pTiA6NC and pTiBo542 VirB2 pilins, like VirB3, localized to the inner membrane. The pTiC58 VirB4 protein was earlier found to be essential for stabilization of VirB3. Stabilization of pTiA6NC VirB3 requires not only VirB4 but also two additional VirB proteins, VirB7 and VirB8. A binary interaction between VirB3 and VirB4/VirB7/VirB8 is not sufficient for VirB3 stabilization. We hypothesize that bacteria use selective proteolysis as a mechanism to prevent assembly of unproductive precursor complexes under conditions that do not favor assembly of large macromolecular structures.Bacteria use type IV secretion (T4S) to deliver macromolecules to prokaryotes and eukaryotes (12). Animal and human pathogens deliver proteins to their eukaryotic hosts to affect cellular processes causing disease. The plant-pathogenic bacterium Agrobacterium tumefaciens delivers both proteins and DNA to plants and other eukaryotes. DNA delivered by Agrobacterium directs constitutive synthesis of phytohormones in a transformed plant cell, promoting cancerous growth (56). The Ptl toxin of Bordetella pertussis modifies G proteins by ADP-ribosylation, affecting intracellular cell signaling, and CagA of Helicobacter pylori disrupts epithelial cell polarity by inhibiting PAR1 kinase activity (37, 44, 47). T4S is ancestrally related to bacterial conjugation, a mechanism used by bacteria for interbacterial plasmid transfer, enabling them to acquire novel genes for antibiotic resistance, degradation of organic molecules, toxin production, and other virulence traits (29).The VirD4/VirB family of proteins, found conserved in many alphaproteobacteria, mediates T4S (12). The Ti plasmid-encoded Agrobacterium T4S system requires VirD4 and 11 VirB proteins, VirB1 to VirB11, for efficient DNA transfer (7, 54). The membrane and membrane-associated VirB proteins assemble a macromolecular structure at the cell membrane to promote substrate transfer (12). The octopine Ti plasmid pTiA6NC-encoded VirB6 to VirB11 proteins assemble the T4S apparatus at a cell pole (34, 35, 39). The VirD4 coupling protein targets the VirE2 substrate protein to the cell pole (4). A recent study found that the nopaline Ti plasmid pTiC58 T4S system (T4SS) and its substrates form a helical array around the cell circumference (1). Structural studies using Escherichia coli conjugative plasmid pKM101-encoded VirB homologues showed that TraN (VirB7), TraO (VirB9), and TraF (VirB10) form the core complex and that TraF forms a channel at the outer membrane (11, 23). The Agrobacterium VirB proteins assemble a T-pilus, an appendage composed primarily of VirB2, with VirB5 and VirB7 as its minor constituents (38, 40, 41, 48, 50, 55). VirB3, a homolog of the pilin-like TraL protein encoded in E. coli plasmids, is postulated to function in T-pilus assembly (52). Three ATP-utilizing proteins, VirB4, VirB11, and VirD4, supply energy for substrate translocation (3, 9, 34).The membrane topology of all the VirB proteins, except for VirB3, was determined by analyses of random phoA insertion mutants, targeted phoA fusions, and targeted bla fusions (6, 14, 15, 21, 22, 31, 35, 53). phoA and bla, which encode alkaline phosphatase and β-lactamase, respectively, serve as excellent markers for periplasmic proteins, as they are enzymatically active only when targeted to the cell periplasm (8, 30). Green fluorescent protein (GFP) is an ideal cytoplasmic marker because it fluoresces only when located in the cytoplasm (19, 20). When GFP is targeted to the periplasm through fusion with a membrane-spanning domain (MSD), it fails to fold properly and does not fluoresce.The prevailing view, based on in silico analysis, is that VirB3 is a bitopic membrane protein with a periplasmic C terminus. No phoA-positive insertions in virB3, however, were identified in two random mutagenesis studies of the virB operon (6, 15). The small size of VirB3, a polypeptide of 108 amino acids (aa), could be a contributing factor to the negative findings. Yet several PhoA-positive insertions in two smaller VirB proteins, VirB2 (74-aa mature peptide) and VirB7 (41-aa mature peptide), were successfully obtained in both studies. Therefore, the negative findings may also be indicative of the presence of a small periplasmic domain in VirB3. Biochemical studies showed that the nopaline Ti plasmid pTiC58-encoded VirB3 protein (pTiC58 VirB3) associates with the bacterial outer membrane, while VirB2 associates with both the inner and outer membranes (52). The pTiC58 VirB4 protein is required for localization of VirB3 to the outer membrane (33). VirB4 is also required for VirB3 stability (33, 55). A low level of VirB3 accumulated in a nonpolar pTiC58 virB6 deletion mutant; however, addition of virB6 in trans did not restore the level of the protein, even though it restored tumorigenicity (27). VirB3 participates in the formation of protein complexes with the T-pilus proteins VirB2 and VirB5 (55).Homologues of VirB3 are found in many alphaproteobacteria with a T4SS. While most VirB3 homologues are small proteins, several recently identified homologues are fusions of VirB3 and the immediate downstream protein VirB4 (5, 10, 24). These fusion homologs, which include Actinobacillus MagB03 (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAG24434","term_id":"10880920","term_text":"AAG24434"}}AAG24434), Campylobacter CmgB3/4 ({"type":"entrez-protein","attrs":{"text":"EAQ71805","term_id":"87248841","term_text":"EAQ71805"}}EAQ71805), Yersinia pseudotuberculosis TriC ({"type":"entrez-protein","attrs":{"text":"CAF25448","term_id":"51591645","term_text":"CAF25448"}}CAF25448), Citrobacter koseri PilX3-4 ({"type":"entrez-protein","attrs":{"text":"ABV12046","term_id":"157082368","term_text":"ABV12046"}}ABV12046), and Klebsiella pneumoniae PilX3-4 ({"type":"entrez-protein","attrs":{"text":"BAF49490","term_id":"134048868","term_text":"BAF49490"}}BAF49490), have VirB3 at the N terminus and VirB4 at the C terminus. Agrobacterium VirB4 is an integral membrane protein with a cytoplasmic N terminus (14). Its homologues are expected to have a similar topology. The prevailing view that pTi VirB3 has a periplasmic C terminus is inconsistent with the cytoplasmic location of the N terminus of VirB4 in the VirB3-VirB4 fusion protein homologues.In this study, we report the membrane topology of Agrobacterium VirB3 and demonstrate that the C terminus of the protein resides in the cytoplasm. We also demonstrate that VirB3 is an inner membrane protein, not an outer membrane protein as previously reported (52). The octopine Ti plasmid pTiA6NC VirB4 protein does not affect membrane localization of VirB3 but does stabilize VirB3. VirB4, however, is not sufficient for pTiA6NC VirB3 stabilization. Two additional proteins, VirB7 and VirB8, are required for the stabilization of pTiA6NC VirB3.     

Characterization of the Transposase Encoded by IS256, the Prototype of a Major Family of Bacterial Insertion Sequence Elements

IS256 is the founding member of the IS256 family of insertion sequence (IS) elements. These elements encode a poorly characterized transposase, which features a conserved DDE catalytic motif and produces circular IS intermediates. Here, we characterized the IS256 transposase as a DNA-binding protein and obtained insight into the subdomain organization and functional properties of this prototype enzyme of IS256 family transposases. Recombinant forms of the transposase were shown to bind specifically to inverted repeats present in the IS256 noncoding regions. A DNA-binding domain was identified in the N-terminal part of the transposase, and a mutagenesis study targeting conserved amino acid residues in this region revealed a putative helix-turn-helix structure as a key element involved in DNA binding. Furthermore, we obtained evidence to suggest that the terminal nucleotides of IS256 are critically involved in IS circularization. Although small deletions at both ends reduced the formation of IS circles, changes at the left-hand IS256 terminus proved to be significantly more detrimental to circle production. Taken together, the data lead us to suggest that the IS256 transposase-mediated circularization reaction preferentially starts with a sequence-specific first-strand cleavage at the left-hand IS terminus.IS256 is an insertion sequence widespread in the genomes of multiresistant enterococci and staphylococci (3). The element, which is 1,324 bp in size, consists of a single open reading frame encoding a transposase protein flanked by noncoding regions (NCRs) harboring imperfect inverted repeats (IRs) (see Fig. ​Fig.1A).1A). IS256 occurs in multiple free copies in its host genomes but is also known to form the ends of composite transposon Tn4001 conferring aminoglycoside resistance (29). In Staphylococcus epidermidis, IS256 has been identified as a typical marker of hospital-acquired multiresistant and biofilm-forming clones causing opportunistic infections in immunocompromised patients (11, 20-22, 26, 34). The element has been shown to trigger heterogeneous biofilm expression by reversible transposition into biofilm-associated genes and regulators (4, 5, 19, 49, 56). Also, IS256 has the capacity to influence antibiotic resistance, either by insertion into regulatory genes or by modulating antibiotic resistance gene expression through formation of strong hybrid promoters resulting from transposition into the neighborhood of antibiotic resistance genes (6, 18, 31, 32). Finally, multiple genomic IS256 copies may serve as crossover points for homologous recombination events and thereby play an important role in genome flexibility, adaptation, and evolution of staphylococcal and enterococcal genomes (29, 42, 55).Open in a separate windowFIG. 1.IS256 transposase binding to IS termini. (A) Genetic organization of IS256. The transposase gene (tnp) is flanked by NCRs that harbor imperfect IRs (IR_L and IR_R) at the ends of the element. The nucleotide sequence of the IRs is indicated by uppercase boldface letters, with nucleotide numbering referring to GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"M18086","term_id":"152946","term_text":"M18086"}}M18086. Insertion of IS256 into the S. epidermidis icaC gene on plasmid pIL2 (27) is shown, and black boxes mark the 8-bp target site duplications (TSDs) generated upon transposition of the element. Black bars at the top indicate localizations of DNA fragments used in the EMSAs presented in panels B to D. (B to D) EMSAs of purified IS256 transposase protein (CBP-Tnp) with various IS256-specific DNA fragments. A 15.5 nM concentration of an IS terminus (left)-carrying DNA fragment (B) or an IS terminus (right)-carrying DNA-fragment (C), as well as an interal IS256 fragment (D), were used with increasing amounts of protein. All experiments were performed in the presence of unspecific competitor [50 μg of poly(dI-dC) ml⁻¹]. Molar ratios between DNA and protein comprised a range of 1:3 (50 nM CBP-Tnp) to 1:52 (800 nM CBP-Tnp).Given its important biological role, it is surprising that very little is known about the molecular function of IS256 and its lifestyle. Empirical analyses of IS256 insertion sites in various bacterial genomes and loci did not reveal nucleotide sequence specificity for target site selection (3, 29, 56). Typically, IS256 generates 8- or 9-bp target site duplications (TSDs) upon transposition that are caused by staggered nicks of the target DNA and refill of the resulting gaps by the host repair system (43). In the course of phase variation events, IS256 TSDs can be completely removed, with the original host sequence being restored (56). Such precise IS256 excisions are caused by an illegitimate recombination event that requires fully intact TSDs but no functional IS256 transposase (14). IS256 transposition itself was found to involve the formation of double-stranded circular IS256 molecules in which the insertion sequence (IS) ends abut, bridged by a few base pairs of host DNA originating from the original insertion site (27, 39). IS256 circle formation is a strictly transposase-dependent process and IS circles are regarded as transposition intermediates which are likely to be relinearized during transposition. However, details of the transposition reaction, including circle formation, putative relinearization, target site selection, and insertion of the element are far from being understood at the molecular level. We experimentally addressed here, for the first time for a bacterial transposase of the IS256 family, the DNA-binding properties of this protein. We identified a DNA-binding domain in the N-terminal region of the protein. The domain contains a putative classical helix-turn-helix (HTH) motif that is demonstrated to be involved in sequence-specific interactions of the IS256 transposase with the IRs present in the NCRs of the element. Moreover, we suggest a role for the terminal nucleotides of the IS256 nucleotide sequence in first-strand cleavage and subsequent circularization of the element.     

Application of Multilocus Sequence Typing To Study the Genetic Structure of Megaplasmids in Medicago-Nodulating Rhizobia

A multilocus sequence typing (MLST) analysis was used to examine the genetic structure and diversity within the two large extrachromosomal replicons in Medicago-nodulating rhizobia (Sinorhizobium meliloti and Sinorhizobium medicae). The allelic diversity within these replicons was high compared to the reported diversity within the corresponding chromosomes of the same strains (P. van Berkum et al., J. Bacteriol. 188:5570-5577, 2006). Also, there was strong localized linkage disequilibrium (LD) between certain pSymA loci: e.g., nodC and nifD. Although both of these observations could be explained by positive (or diversifying) selection by plant hosts, results of tests for positive selection did not provide consistent support for this hypothesis. The strong LD observed between the nodC and nifD genes could also be explained by their close proximity on the pSymA replicon. Evidence was obtained that some nodC alleles had a history of intragenic recombination, while other alleles of this locus had a history of intergenic recombination. Both types of recombination were associated with a decline in symbiotic competence with Medicago sativa as the host plant. The combined observations of LD between the nodC and nifD genes and intragenic recombination within one of these loci indicate that the symbiotic gene region on the pSymA plasmid has evolved as a clonal segment, which has been laterally transferred within the natural populations.Plants of the genus Medicago are legumes that often benefit from a mutualistic symbiosis with rhizobia. The most agriculturally significant species of rhizobia that nodulate these plants are Sinorhizobium meliloti (9) and Sinorhizobium medicae (22). Previously reported population genetic analyses of these bacteria have focused on the study of how allelic variants at multiple loci are distributed within and among natural populations (2, 3, 10, 26, 31, 32). This was also the focus of the present study, but it was extended by examining more loci in many more strains of both species of Sinorhizobium coupled with an analysis having a range of symbiotic genotypes. One goal was to determine if there were any obvious correlations between the megaplasmid genotypes observed and their symbiotic competence. A second goal was to determine if selection by their host plants may have influenced the evolution of their symbiotic relationships.The genes for symbiosis reside on the extrachromosomal replicons pSymA (1,354,226 nucleotides [nt]) and pSMED02 (1,245,408 nt) in the genomes of S. meliloti Rm1021 and S. medicae WSM419, respectively (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AE006469","term_id":"25168258","term_text":"AE006469"}}AE006469 and {"type":"entrez-nucleotide","attrs":{"text":"CP000740","term_id":"150031715","term_text":"CP000740"}}CP000740, respectively). Besides these two plasmids, these two strains each harbor one other large extrachromosomal replicon, pSymB (1,683,333 nt) and pSMED01 (1,570,951 nt), respectively (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AL591985","term_id":"30407151","term_text":"AL591985"}}AL591985 and {"type":"entrez-nucleotide","attrs":{"text":"CP000739","term_id":"150030273","term_text":"CP000739"}}CP000739, respectively).Multilocus sequence typing (MLST) (16) is a form of genomic indexing that is commonly used to study the population genetic structure and phylogenetic relatedness within diverse groups of bacteria. In this method, nucleotide sequences of a fixed set of common loci are obtained from a collection of strains, and polymorphic sites among these sequences are used to derive an allelic profile or sequence type (ST) for each genome. Comparisons of the resulting data can be used to infer phylogenetic relationships among the organisms in the sample population, and they also can be used to infer how evolutionary processes, such as recombination and selection, have shaped the genetic structure of the population. For example, levels of intergenic recombination among chromosomal genes in natural populations of Neisseria meningitidis reportedly are relatively high, while corresponding levels within populations of Staphylococcus aureus were low (28). Depending on the specific pairs of loci examined, the levels of linkage disequilibrium (LD) (a lack of intergenic recombination) among several chromosomally carried core genes of S. meliloti were reported to be generally moderate to high (26).The MLST approach has been used to confirm that the chromosomes of S. meliloti and S. medicae are sexually isolated (2, 3, 31) and to provide evidence that horizontal gene transfer (HGT) does occur between the symbiotic megaplasmids of these species (3, 32). It has also been used to demonstrate that levels of intergenic recombination, as indicated by linkage disequilibrium, differ between the three replicons of S. meliloti (26). Levels of intergenic recombination within the pSymB replicons of these strains are generally high, unlike the chromosomes and pSymA replicons within the same strains (26). Bailly et al. (3) hypothesized that the region of the pSymA plasmid that contains the nodulation (nod) genes is frequently transferred in natural populations. They also suggested that selective pressures from the host plant may have influenced both nod gene diversity and patterns of polymorphism across the entire nod gene region.In the present study, multilocus allelic variation of the two megaplasmids was examined among 231 Medicago-nodulating rhizobia that originated primarily from southwest Asia (10). Previously, 91 different chromosomal sequence types (STs) were identified among the same strains from sequence variation in 10 loci (31). This collection of strains had earlier been divided into two closely related groups based on results of multilocus enzyme electrophoresis (10), and this result was subsequently cited in support of separating the Medicago-nodulating rhizobia into the two species S. meliloti and S. medicae (22).The objectives of this study were (i) to use MLST to examine the genetic relationships within and among the large extrachromosomal replicons in S. meliloti and S. medicae, (ii) to estimate levels of intergenic and intragenic recombination in these replicons, (iii) to evaluate the nitrogen-fixing competence of representative symbiotic genotypes with Medicago sativa, and (iv) to determine whether positive (or diversifying) selection may have influenced the genetic structure of the megaplasmids.     

Heterologous Expression of Tulip Petal Plasma Membrane Aquaporins in Pichia pastoris for Water Channel Analysis

Water channels formed by aquaporins (AQPs) play an important role in the control of water homeostasis in individual cells and in multicellular organisms. Plasma membrane intrinsic proteins (PIPs) constitute a subclass of plant AQPs. TgPIP2;1 and TgPIP2;2 from tulip petals are members of the PIP family. In this study, we overexpressed TgPIP2;1 and TgPIP2;2 in Pichia pastoris and monitored their water channel activity (WCA) either by an in vivo spheroplast-bursting assay performed after hypo-osmotic shock or by growth assay. Osmolarity, pH, and inhibitors of AQPs, protein kinases (PKs), and protein phosphatases (PPs) affect the WCA of heterologous AQPs in this expression system. The WCA of TgPIP2;2-expressing spheroplasts was affected by inhibitors of PKs and PPs, which indicates that the water channel of this homologue is regulated by phosphorylation in P. pastoris. From the results reported herein, we suggest that P. pastoris can be employed as a heterologous expression system to assay the WCA of PIPs and to monitor the AQP-mediated channel gating mechanism, and it can be developed to screen inhibitors/effectors of PIPs.The movement of water across cell membranes has long been thought to occur by free diffusion through the lipid bilayer. However, the discovery of the membrane protein CHIP28 in red blood cells has suggested the involvement of protein channels (29), and it is now well established that transmembrane water permeability is facilitated by aquaporins (AQPs), water channel proteins that are found in bacteria, fungi, plants, and animals (1, 7, 13, 24). AQPs contain six transmembrane α-helices and five connecting loops, and both the N and C termini are located in the cytosol. The monomers assemble into tetrameric complexes, with each monomer forming an individual water channel (11, 14, 24, 33). Apart from the exceptions of AQP11 and AQP12 from mice, as described by K. Ishibashi (15), AQPs have two signature Asn-Pro-Ala motifs, which are located in the second intracellular and the fifth extracellular loops, B and E.While 13 different AQPs have been identified in mammals (16), more than 33 AQP homologues have been discovered in plants (6, 17, 30). Plant AQPs fall into four subclasses: (i) the plasma membrane (PM) intrinsic proteins (PIPs), which are localized in the PM; (ii) the tonoplast intrinsic proteins (TIPs), which are localized in the vacuolar membranes; (iii) the nodulin-26-like intrinsic proteins; and (iv) the small basic intrinsic proteins (24). In Arabidopsis and maize, there are 13 PIPs, which can be divided further into two subfamilies, PIP1 and PIP2 (6, 17).The functions and mechanisms of regulation of plant AQPs have been extensively investigated (7, 13, 18, 24). There have been several reports on the water channel activity (WCA) of specific AQPs and their regulation by protein phosphorylation (3, 4, 8, 12, 18, 25, 32, 33). It has been shown that the WCA of the PIP2 member SoPIP2;1 from spinach is regulated by phosphorylation at two Ser residues (19, 33).The physiologically interesting temperature-dependent opening and closing of tulip (Tulipa gesneriana) petals occur concomitantly with water transport and are regulated by reversible phosphorylation of an undefined PIP (4, 5). Recently, four PIP homologues were isolated from tulip petals, and their WCAs have been analyzed by heterologous expression in Xenopus laevis oocytes (3). It has been shown that the tulip PIP TgPIP2;2 (DDBJ/EMBL/GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AB305617","term_id":"196259707","term_text":"AB305617"}}AB305617) is ubiquitously expressed in all organs of the tulip and that TgPIP2;2 is the most likely of the TgPIP homologues to be modulated by the reversible phosphorylation that regulates transcellular water transport and mediates petal opening and closing (3, 4). However, while the members of the PIP2 subfamily are characterized as water channels (6), TgPIP2;1 (DDBJ/EMBL/GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AB305616","term_id":"196259705","term_text":"AB305616"}}AB305616) shows no significant WCA in the oocyte expression system (3). There is growing interest in research on AQPs due to their crucial roles in the physiology of plants and animals (1, 16, 21-24, 26-28, 36). The assay of AQP channel activity is usually performed using either a X. laevis oocyte expression system (29) or a stopped-flow light-scattering spectrophotometer (35), both of which are not widely available. Furthermore, the complexity of these methods and requirement of expertise limit their high-throughput applications. In contrast, a Pichia pastoris expression system is simple to use, inexpensive, and feasible and can be used in high-throughput applications. Although a P. pastoris expression system has been shown to assay the WCA of a TIP (9), extensive research is necessary with other AQPs such as PIPs or AQPs present in intragranular membranes to establish whether this assay system can be used to characterize a water channel and study its regulation mechanisms. With this in view, in the study reported herein, TgPIP2;1 and TgPIP2;2 have been heterologously expressed in P. pastoris, and their WCAs have been assayed. The effects of several factors, such as osmolarity, pH, and inhibitors of protein kinases (PKs) and protein phosphatases (PPs), on the WCA of the recombinant P. pastoris have been investigated. Based on the results, we demonstrate that the P. pastoris heterologous expression system can be used to rapidly characterize PIP channels, to monitor the effects of mutations, and to score the effects of inhibitors and abiotic factors.     

Genome Sequence of Lactobacillus crispatus ST1

Lactobacillus crispatus is a common member of the beneficial microbiota present in the vertebrate gastrointestinal and human genitourinary tracts. Here, we report the genome sequence of L. crispatus ST1, a chicken isolate displaying strong adherence to vaginal epithelial cells.Lactobacillus crispatus can persist in the vertebrate gastrointestinal tract and is among the most prevalent species of the Lactobacillus-dominated human vaginal microbiota (2, 9, 13, 14). It belongs to the so-called acidophilus group (3), which has attracted interest because some of its species are important factors in the production of fermented foods (12) and some can, at least transiently, colonize the human host (2, 9, 13, 14). Moreover, some specific strains, mainly L. acidophilus NCFM and L. johnsonii NCC 533, have received prominence as intestinal-health-promoting microbes (4). Although the genomes of seven members of the acidophilus complex have been sequenced to date (12), the genome sequences of L. crispatus and other predominant lactobacillar species in the urogenital flora have mostly remained obscure. Vaginal lactobacilli can have an important role in controlling the health of the host (2, 14). They can, for example, positively influence and stabilize the host''s vaginal microbiota via the production of compounds that are acidic or exert a direct inhibiting action toward pathogenic bacteria (2, 14). In addition to the antimicrobial compounds, the competitive exclusion of pathogens is another mechanism by which the host''s microbiota can be balanced (2). L. crispatus ST1 was originally isolated from the crop of a chicken, and PCR profiling of L. crispatus isolates has verified it to be an abundant colonizer of the chicken crop (6, 8). It also displays a strong protein-dependent adhesion to the epithelial cells of the human vagina and has been shown to inhibit the adhesion of avian pathogenic Escherichia coli (6, 7).The genome was sequenced (18× coverage) using a 454 pyrosequencer with GS FLX chemistry (Roche). The contig order was confirmed and gaps were filled by sequencing PCR fragments from the genomic DNA template using ABI 3730 and Big Dye chemistry (Applied Biosystems). Genomic data were processed using the Staden Package (11) and gsAssembler (Roche). Coding sequences (CDSs) were predicted using Glimmer3 (5) followed by manual curation of the start sites. The remaining intergenic regions were reanalyzed for missed CDSs by using BlastX (1). Annotation transfer was performed based on a BlastP search, followed by Blannotator analysis using default settings (http://ekhidna.biocenter.helsinki.fi/poxo/blannotator) and manual verification. Orthologous groups between the different lactobacillar proteomes were identified using OrthoMCL (10).The genome of L. crispatus ST1 consists of a single circular chromosome 2.04 Mbp in size, with an overall G+C content of 37%, without any plasmids. There are 64 tRNA genes, 4 rRNA operons, and 2 CRISPR loci. Out of the 2,024 predicted CDSs, a putative function was assigned to 77%, whereas 10% of the CDSs were annotated as conserved and 13% as novel. Based on the orthologous grouping, 302 (15%) of the CDSs encoded by ST1 have no detectable homologs in any of the Lactobacillus proteomes published to date.     

Genome Sequence of the Fleming Strain of Micrococcus luteus,a Simple Free-Living Actinobacterium

Micrococcus luteus (NCTC2665, “Fleming strain”) has one of the smallest genomes of free-living actinobacteria sequenced to date, comprising a single circular chromosome of 2,501,097 bp (G+C content, 73%) predicted to encode 2,403 proteins. The genome shows extensive synteny with that of the closely related organism, Kocuria rhizophila, from which it was taxonomically separated relatively recently. Despite its small size, the genome harbors 73 insertion sequence (IS) elements, almost all of which are closely related to elements found in other actinobacteria. An IS element is inserted into the rrs gene of one of only two rrn operons found in M. luteus. The genome encodes only four sigma factors and 14 response regulators, a finding indicative of adaptation to a rather strict ecological niche (mammalian skin). The high sensitivity of M. luteus to β-lactam antibiotics may result from the presence of a reduced set of penicillin-binding proteins and the absence of a wblC gene, which plays an important role in the antibiotic resistance in other actinobacteria. Consistent with the restricted range of compounds it can use as a sole source of carbon for energy and growth, M. luteus has a minimal complement of genes concerned with carbohydrate transport and metabolism and its inability to utilize glucose as a sole carbon source may be due to the apparent absence of a gene encoding glucokinase. Uniquely among characterized bacteria, M. luteus appears to be able to metabolize glycogen only via trehalose and to make trehalose only via glycogen. It has very few genes associated with secondary metabolism. In contrast to most other actinobacteria, M. luteus encodes only one resuscitation-promoting factor (Rpf) required for emergence from dormancy, and its complement of other dormancy-related proteins is also much reduced. M. luteus is capable of long-chain alkene biosynthesis, which is of interest for advanced biofuel production; a three-gene cluster essential for this metabolism has been identified in the genome.Micrococcus luteus, the type species of the genus Micrococcus (family Micrococcaceae, order Actinomycetales) (117), is an obligate aerobe. Three biovars have been distinguished (138). Its simple, coccoid morphology delayed the recognition of its relationship to actinomycetes, which are typically morphologically more complex. In the currently accepted phylogenetic tree of the actinobacteria, Micrococcus clusters with Arthrobacter and Renibacterium. Some other coccoid actinobacteria originally also called Micrococcus, but reclassified into four new genera (Kocuria, Nesterenkonia, Kytococcus, and Dermacoccus), are more distant relatives (121). The genus Micrococcus now includes only five species: M. luteus, M. lylae, M. antarcticus, M. endophyticus, and M. flavus (20, 69, 70, 121).We report here the genome sequence of Micrococcus luteus NCTC2665 (DSM 20030^T), a strain of historical interest, since Fleming used it to demonstrate bacteriolytic activity (due to lysozyme) in a variety of body tissues and secretions (29, 30), leading to its designation as Micrococcus lysodeikticus until its taxonomic status was clarified in 1972 (59). M. luteus has been used in a number of scientific contexts. The ease with which its cell wall could be removed made it a favored source of bacterial cell membranes and protoplasts for investigations in bioenergetics (28, 34, 89, 93). Because of the exceptionally high GC content of its DNA, M. luteus was used to investigate the relationship between codon usage and tRNA representation in bacterial genomes (51, 52, 61). Although it does not form endospores, M. luteus can enter a profoundly dormant state, which could explain why it may routinely be isolated from amber (39). Dormancy has been convincingly demonstrated under laboratory conditions (53-55, 83), and a secreted protein (Rpf) with muralytic activity is involved in the process of resuscitation (81, 82, 84, 85, 87, 125, 133).Micrococci are also of biotechnological interest. In addition to the extensive exploitation of these and related organisms by the pharmaceutical industry for testing and assaying compounds for antibacterial activity, micrococci can synthesize long-chain alkenes (1, 2, 127). They are also potentially useful for ore dressing and bioremediation applications, since they are able to concentrate heavy metals from low-grade ores (26, 66, 67, 116).Given its intrinsic historical and biological importance, and its biotechnological potential, it is perhaps surprising that the genome sequence of M. luteus was not determined previously (130). We consider here the strikingly small genome sequence in these contexts and also in relation to the morphological simplicity of M. luteus compared to many of its actinobacterial relatives, which include important pathogens as well as developmentally complex, antibiotic-producing bacteria with some of the largest bacterial genomes.     

VP23R of Infectious Spleen and Kidney Necrosis Virus Mediates Formation of Virus-Mock Basement Membrane To Provide Attaching Sites for Lymphatic Endothelial Cells

Putative open reading frames (ORFs) encoding laminin-like proteins are found in all members of the genus Megalocytivirus, family Iridoviridae. This is the first study that identified the VP23R protein encoded by ORF23R of the infectious spleen and kidney necrosis virus (ISKNV), a member of these genes of megalocytiviruses. The VP23R mRNA covering the ISKNV genomic coordinates 19547 to 22273 was transcribed ahead of the major capsid protein. Immunofluorescence analysis demonstrated that VP23R was expressed on the plasma membrane of the ISKNV-infected cells and could not be a viral envelope protein. Residues 292 to 576 of VP23R are homologous to the laminin γ1III2-6 fragment, which covers the nidogen-binding site. An immunoprecipitation assay showed that VP23R could interact with nidogen-1, and immunohistochemistry showed that nidogen-1 was localized on the outer membrane of the infected cells. Electron microscopy showed that a virus-mock basement membrane (VMBM) was formed on the surface of the infected cells and a layer of endothelial cells (ECs) was attached to the VMBM. The VMBM contained VP23R and nidogen-1 but not collagen IV. The attached ECs were identified as lymphatic endothelial cells (LECs), which have unique feature of overlapping intercellular junctions and can be stained by immunohistochemistry using an antibody against a specific lymphatic marker, Prox-1. Such infection signs have never been described in viruses. Elucidating the functions of LECs attached to the surface of the infected cells may be useful for studies on the pathogenic mechanisms of megalocytiviruses and may also be important for studies on lymphangiogenesis and basement membrane functions.Basement membrane (BM), a dense and sheetlike structure that is always associated with cells, is a very important specialized form of extracellular matrix (31, 67). BMs mediate tissue compartmentalization and provide structural support to the epithelium, endothelium, peripheral nerve axons, fat cells, and muscle cells, as well as structural and functional foundations of the vasculature (25, 31, 52). BM is also an important regulator of cell behaviors, such as adhesion, migration, proliferation, and differentiation. BMs are highly cross-linked and insoluble materials. They are highly complex and are made up of more than 50 known components (31, 54). Although the molecular composition of BMs is unique in each tissue, their basic structures are similar. Even if many more isoforms exist in different species, the major BM proteins and their receptors are conserved from Caenorhabditis elegans to mammals. BM consists of a layer of laminin polymer, a layer of type IV collagen network, and the nidogen protein, which acts as a cross-linker of these two networks. Other BM components, such as perlecan and fibulin, interact with the laminin polymer and the type IV collagen network to organize a functional BM on the basolateral aspect of the cells (31, 45, 52).The components of BM are able to self-assemble and form a sheetlike structure, and laminin is the key molecule in this process (50). Laminin protein consists of three different chains (α, β, and γ), which comprise a cross-shaped molecular structure with three short amino-terminal arms and a long carboxyl-terminal triple-helical arm (58, 68). The three short arms of this cross-shaped structure can interact with each other in the presence of calcium. Through the binding of globular G domain at the carboxyl-terminal end of the α chain to the cell receptors (e.g., integrins and dystroglycans), laminin self-assembles into polygonal lattices on cell surfaces. This process initiates BM self-assembly (15, 21, 25, 38, 65, 66). To date, 17 laminin isoforms have been observed in different tissues (51). Among them, laminin-1, the crux of early embryonic BM assembly, has been well studied. Laminin-1 consists of α1, β1, and γ1 chains and can interact with nidogen-1 with high affinity through a laminin-type epidermal growth factor-like (LE) module, γ1III4, within the domain III of the γ1 chain (1, 42). The heptapeptide “NIDPNAV” within the γ1III4 motif of laminin-1 is essential for the interaction between laminin-1 and nidogen-1 (41, 46). Blocking the interactions between laminin-1 and nidogen-1 leads to the disruption of BMs. This indicates that the formation of laminin/nidogen complex is essential for BM assembly and stability (30, 61). Nidogen-1, also called entactin-1, is a dumbbell-shaped sulfated 150-kDa glycoprotein consisted of three domains (G1, G2, and G3) (12). By interacting with collagen IV through its G2 domain and binding with laminin γ1 chain through its G3 domain, nidogen-1 bridges the layers of the laminin network and the collagen IV network to construct the fundamental structure of BMs (48). Collagen IV is a triple-helical trimer composed of three α chains. Through the hexamer formation of the carboxyl-terminal globular non-collagenous-1 (NC1) domain of each α chain, two collagen IV proteins assemble into a dimer. Dimers of collagen IV connect with each other via their amino-terminal 7S domains and self-assemble into a network (24, 27, 31, 32). Six kinds of α chains of collagen IV have been identified in mammals. Among them, α1 and α2 chains are the most abundant forms of collagen IV found in all BMs (19, 23). They commonly form a collagen IV molecule with a α1 and α2 ratio of 2:1 (31, 35).Iridoviruses infect invertebrates and poikilothermic vertebrates, including insects, fish, amphibians, and reptiles. These viruses are a group of icosahedral cytoplasmic DNA viruses with circularly permuted and terminally redundant DNA genomes (6, 8, 9, 10, 57, 62). The family Iridoviridae has been subdivided into five genera: Iridovirus, Chloriridovirus, Ranavirus, Lymphocystisvirus, and Megalocystivirus (7). The genus Megalocystivirus, characterized by the ability to cause swelling of the infected cells, is one group of the most harmful viruses to cultured fish (7, 26, 29). Infectious spleen and kidney necrosis virus (ISKNV), the causative agent of a disease that causes high mortality rates in farmed mandarin fish, Siniperca chuatsi, and large-mouth bass, Micropterus salmoides, is regarded as the type species of Megalocystivirus (7). Similar to infection caused by other members of the Megalocystivirus, fish ISKNV infection is characterized by cell hypertrophy in the spleen, kidney, cranial connective tissue, and endocardium (16, 17). Aside from mandarin fish and large-mouth bass, ISKNV-like virus can also be detected in the tissues of more than 60 marine and freshwater fishes (14, 28, 59, 64). The entire genome of ISKNV has been sequenced, and the organization of open reading frames (ORFs) of ISKNV was analyzed by using DNASTAR Omiga 2.0 and Genescan (18). The ISKNV genome is about 110 kbp and contains 125 putative ORFs (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"AF371960","term_id":"19773610","term_text":"AF371960"}}AF371960).Putative ORFs, encoding viral proteins containing a fragment homologous to laminin and a putative transmembrane fragment, were found in all of the sequenced genomes of the members of Megalocystivirus. These ORFs include ORF23R of ISKNV (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAL98747","term_id":"19773633","term_text":"AAL98747"}}AAL98747), laminin-like protein gene of olive flounder iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAT76907","term_id":"50404491","term_text":"AAT76907"}}AAT76907), ORF2 of sea perch iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAV51313","term_id":"55418187","term_text":"AAV51313"}}AAV51313), predicted laminin-type epidermal growth factor-like protein of large yellow croaker iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"ABI32391","term_id":"113200502","term_text":"ABI32391"}}ABI32391), an unknown gene of red sea bream iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAQ07956","term_id":"33324323","term_text":"AAQ07956"}}AAQ07956), ORF2 of rock bream iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAN86692","term_id":"60458808","term_text":"AAN86692"}}AAN86692), and laminin-type epidermal growth factor-like protein of orange-spotted grouper iridovirus (GenBank accession no. {"type":"entrez-protein","attrs":{"text":"AAX82335","term_id":"62421215","term_text":"AAX82335"}}AAX82335). These putative proteins are highly homologous to each other in amino acid sequence (65 to 99% identity). However, the functions of these proteins have never been identified. This is the first study to identify that the VP23R protein encoded by ORF23R of ISKNV is a plasma membrane-localized viral protein. In addition, we discovered a new function of VP23R in a unique pathological phenomenon of virus infection: the attachment of lymphatic endothelial cells (LECs) to the infected cells. Nidogen-1 assisted VP23R in the construction of a BM-like structure, providing an attachment site for LECs. This unique pathological phenomenon has never been found in viruses and is an attractive direction for studies of pathogenic mechanisms of megalocystiviruses. Moreover, studies on the unique profiles of the virus-mock BM can help us learn more about the functions of BM components and the mechanisms of lymphangiogenesis.     

Genome Sequence of Lentisphaera araneosa HTCC2155T,the Type Species of the Order Lentisphaerales in the Phylum Lentisphaerae

Information on the genome content of deeply branching phyla with very few cultured members is invaluable for expanding understanding of microbial evolution. Lentisphaera araneosa HTCC2155^T was isolated from the Oregon coast using dilution-to-extinction culturing. It is a marine heterotroph found in surface and mesopelagic waters in both the Pacific and Atlantic oceans and has the unusual property of producing a net-like matrix of secreted exopolysaccharide. Here we present the genome sequence of L. araneosa HTCC2155^T, importantly, one of only two sequenced members of the phylum Lentisphaerae.The phylum Lentisphaerae was designated in 2004 with five isolated organisms, of which two were characterized and served as the basis for the designation of two novel orders (2). The phylum is most closely related to Verrucomicrobia, Chlamydiae, Planctomycetes, and the candidate division OP3; these phyla make up a recently designated monophyletic superphylum, PVC (11, 15). Within the phylum Lentisphaerae, clone sequences have been obtained from a variety of environments (2 [and references therein], 16). Isolated from surface waters off the Oregon coast by dilution-to-extinction culturing (3, 13), two organisms with identical 16S rRNA gene sequences were named Lentisphaera araneosa and make up the order Lentisphaerales (2). Here we present the genome sequence of the type strain, L. araneosa HTCC2155^T.L. araneosa HTCC2155^T was isolated from seawater samples collected at 10 m using low-nutrient heterotrophic medium (2). The genome sequence was determined by shotgun sequencing at the J. Craig Venter Institute as part of the Moore Foundation Microbial Genome Sequencing Project (http://www.moore.org/microgenome). This draft unclosed genome, consisting of 81 contigs ({"type":"entrez-nucleotide-range","attrs":{"text":"ABCK01000001 to ABCK01000081","start_term":"ABCK01000001","end_term":"ABCK01000081","start_term_id":"149141017","end_term_id":"149136170"}}ABCK01000001 to ABCK01000081), was analyzed with the GenDB program (7) at the Center for Genome Research and Biocomputing at Oregon State University, similarly to Previous analyses (9, 10) and through the Joint Genome Institute IMG/M website (http://img.jgi.doe.gov/cgi-bin/pub/main.cgi) (5). The draft genome comprises 5,173 open reading frames (ORFs), 6,023,180 bases, with a G+C content of 40.95%. Forty-nine percent of these ORFs have predicted functions. The genome is predicted to contain 55 tRNA genes, 5 5S rRNA genes, 3 16S rRNA genes, and 1 23S rRNA gene. There are putative genes for a complete tricarboxylic acid cycle, glycolysis, the pentose phosphate pathway, and amino acid synthesis.Notably, the L. araneosa genome contains 267 putative sulfatases. Since the primary described role of sulfatases is liberating sulfur from sulfate esters during sulfate deprivation (reference 14 and references therein), such a quantity of these genes in this organism is surprising, given the abundance of sulfate in marine environments. The genome of the marine planctomycete Pirellula sp. strain 1 contained 110 putative sulfatases which the authors hypothesized were involved in sulfur scavenging from marine snow (4).L. araneosa was so named because the exopolysaccharide (EPS) secreted during growth forms a web-like matrix between cells. The genome contains several putative genes connected with EPS production—22 predicted glycosyltransferases, several of which are located two genes downstream from putative UDP-N-acetylglucosamine 2-epimerases (epsC homologs) in eps gene cluster-like configurations (12, 14). EPS production has been connected to psychrotolerance in several strains (1, 6, 8) and with increased pressure (6). The highest relative abundances of L. araneosa were measured in upper mesopelagic waters off the Oregon coast and at the Bermuda Atlantic Time Series station (2). We hypothesize that predicted EPS production genes confer increased fitness on L. araneosa in mid-ocean environments by stimulating the formation of aggregates (“marine snow”) or by interfering with predation.