Dysbindin engages in c-Jun N-terminal kinase activity and cytoskeletal organization

A number of reports have provided genetic evidence for an association between the DTNBP1 gene (coding dysbindin) and schizophrenia. In addition, sandy mice, which harbor a deletion in the DTNBP1 gene and lack dysbindin, display behavioral abnormalities suggestive of an association with schizophrenia. However, the mechanism by which the loss of dysbindin induces schizophrenia-like behaviors remains unclear. Here, we report that small interfering RNA-mediated knockdown of dysbindin resulted in the aberrant organization of actin cytoskeleton in SH-SY5Y cells. Furthermore, we show that morphological abnormalities of the actin cytoskeleton were similarly observed in growth cones of cultured hippocampal neurons derived from sandy mice. Moreover, we report a significant correlation between dysbindin expression level and the phosphorylation level of c-Jun N-terminal kinase (JNK), which is implicated in the regulation of cytoskeletal organization. These findings suggest that dysbindin plays a key role in coordinating JNK signaling and actin cytoskeleton required for neural development.     

Microbial Populations Responsive to Denitrification-Inducing Conditions in Rice Paddy Soil,as Revealed by Comparative 16S rRNA Gene Analysis

Rice paddy soil has been shown to have strong denitrifying activity. However, the microbial populations responsible for nitrate respiration and denitrification have not been well characterized. In this study, we performed a clone library analysis of >1,000 clones of the nearly full-length 16S rRNA gene to characterize bacterial community structure in rice paddy soil. We also identified potential key players in nitrate respiration and denitrification by comparing the community structures of soils with strong denitrifying activity to those of soils without denitrifying activity. Clone library analysis showed that bacteria belonging to the phylum Firmicutes, including a unique Symbiobacterium clade, dominated the clones obtained in this study. Using the template match method, several operational taxonomic units (OTUs), most belonging to the orders Burkholderiales and Rhodocyclales, were identified as OTUs that were specifically enriched in the sample with strong denitrifying activity. Almost one-half of these OTUs were classified in the genus Herbaspirillum and appeared >10-fold more frequently in the soils with strong denitrifying activity than in the soils without denitrifying activity. Therefore, OTUs related to Herbaspirillum are potential key players in nitrate respiration and denitrification under the conditions used.Rice is one of the most important agronomic plants in the world (20). More than 135 million ha are used for rice cultivation worldwide, 88% of which consists of paddy fields (i.e., flooded fields) (16). Since rice paddy soil has limited available oxygen, various anaerobic biochemical processes can occur, including methane production, Mn⁴⁺ and Fe³⁺ reduction, nitrate respiration, and denitrification.Denitrification is a microbial respiratory process during which soluble nitrogen oxides (NO₃⁻ and NO₂⁻) are reduced to gaseous products (NO, N₂O, and N₂) (14, 43). Reduction of nitrate (NO₃⁻) to nitrite (NO₂⁻) is part of the denitrification process; however, this reaction can also be performed by nondenitrifiers. Reduction of nitrate to nitrite as an end product is called nitrate respiration (43). The emission of N₂O from rice paddy soils is less than that from upland crop fields (2), which is probably due to complete nitrate-nitrite reduction to N₂, since rice paddy soil is known to have strong denitrifying activity (28). However, the microbes responsible for denitrification in rice paddy soil are not well known.Denitrifying ability is sporadically distributed among taxonomically diverse groups of bacteria, as well as some archaea and fungi (14, 33, 43). Therefore, it is difficult to identify denitrifying organisms based only on their 16S rRNA gene sequences (33). However, culture-independent 16S rRNA gene analysis can be used to identify microbial populations responsive to denitrification-inducing conditions if they are properly differentiated from background populations. The 16S rRNA gene can provide taxonomic information about organisms which cannot be obtained from analyses targeting nitrite reductase genes (nirS and nirK) alone (34).One approach to differentiate functionally active populations from background populations is to use stable-isotope probing (SIP) (35). SIP was previously used to identify succinate-assimilating bacterial populations under denitrifying conditions in rice paddy soil, using nitrate and succinate as the electron acceptor and donor, respectively (37). Although SIP analysis can provide solid evidence that links function with taxonomy, it requires assimilation of isotopically labeled substrates. This may limit the application of SIP in studies of dissimilatory processes, such as nitrate respiration and denitrification. For example, previous SIP studies targeted bacteria assimilating ¹³C-labeled acetate, methanol, or succinate under denitrifying conditions (13, 30, 37).Another approach is to detect specifically enriched microbial populations under certain conditions by comparative analysis of 16S rRNA gene sequences (9). This approach does not necessarily require addition of isotopically labeled substrates and therefore has the potential to identify microbes performing dissimilatory processes. Furthermore, the community structure of the total population can also be elucidated in this manner (10, 25, 36). However, the usefulness of comparative analysis of 16S rRNA gene sequences has not been thoroughly tested. In addition, this approach has not been used to study nitrate respirators and denitrifiers.Consequently, the objectives of this study were (i) to characterize the soil bacterial population in rice paddy soil by clone library analysis of >1,000 clones of the nearly full-length 16S rRNA gene and (ii) to identify active bacterial populations under denitrification-inducing conditions by comparing clone libraries.     

Genome Sequence of the Lager Brewing Yeast, an Interspecies Hybrid

This work presents the genome sequencing of the lager brewing yeast (Saccharomyces pastorianus) Weihenstephan 34/70, a strain widely used in lager beer brewing. The 25 Mb genome comprises two nuclear sub-genomes originating from Saccharomyces cerevisiae and Saccharomyces bayanus and one circular mitochondrial genome originating from S. bayanus. Thirty-six different types of chromosomes were found including eight chromosomes with translocations between the two sub-genomes, whose breakpoints are within the orthologous open reading frames. Several gene loci responsible for typical lager brewing yeast characteristics such as maltotriose uptake and sulfite production have been increased in number by chromosomal rearrangements. Despite an overall high degree of conservation of the synteny with S. cerevisiae and S. bayanus, the syntenies were not well conserved in the sub-telomeric regions that contain lager brewing yeast characteristic and specific genes. Deletion of larger chromosomal regions, a massive unilateral decrease of the ribosomal DNA cluster and bilateral truncations of over 60 genes reflect a post-hybridization evolution process. Truncations and deletions of less efficient maltose and maltotriose uptake genes may indicate the result of adaptation to brewing. The genome sequence of this interspecies hybrid yeast provides a new tool for better understanding of lager brewing yeast behavior in industrial beer production.Key words: Saccharomyces pastorianus, beer, genome, interspecies hybrid, larger yeast     

The roles of ASK family proteins in stress responses and diseases

The aim of palliative chemotherapy is to increase survival whilst maintaining maximum quality of life for the individual concerned. Although we are still continuing to explore the optimum use of traditional chemotherapy agents, the introduction of targeted therapies has significantly broadened the therapeutic options. Interestingly, the results from current trials put the underlying biological concept often into a new, less favorable perspective. Recent data suggested that altered pathways underlie cancer, and not just altered genes. Thus, an effective therapeutic agent will sometimes have to target downstream parts of a signaling pathway or physiological effects rather than individual genes. In addition, over the past few years increasing evidence has suggested that solid tumors represent a very heterogeneous group of cells with different susceptibility to cancer therapy. Thus, since therapeutic concepts and pathophysiological understanding are continuously evolving a combination of current concepts in tumor therapy and tumor biology is needed. This review aims to present current problems of cancer therapy by highlighting exemplary results from recent clinical trials with colorectal and pancreatic cancer patients and to discuss the current understanding of the underlying reasons.     

Complete Genome Sequence of the Wild-Type Commensal Escherichia coli Strain SE15, Belonging to Phylogenetic Group B2

Escherichia coli SE15 (O150:H5) is a human commensal bacterium recently isolated from feces of a healthy adult and classified into E. coli phylogenetic group B2, which includes the majority of extraintestinal pathogenic E. coli. Here, we report the finished and annotated genome sequence of this organism.The complete genome sequence of Escherichia coli SE15 was determined using a combination of 2-kb and 40-kb Sanger libraries and 454 pyrosequencing. We generated 57,600 sequences (ABI 3730xl sequencers) and three sequencing runs (GS20 sequencers). The 454 pyrosequencing reads were first assembled using the Newbler assembler software (4). A hybrid assembly of 454 and Sanger reads was performed using the Phred-Phrap-Consed program (1). Remaining gaps between contigs were closed by direct sequencing of clones. Prediction and annotation of protein-coding genes were performed as described previously (6).The genome of E. coli SE15 consists of a circular 4,717,338-bp chromosome containing 4,338 predicted protein-coding genes and a 122-kb plasmid (pSE15) encoding 150 protein-coding genes. From the multilocus sequence typing analysis based on the nucleotide sequences of seven housekeeping genes (adk, fumC, gyrB, icd, mdh, purA, and recA), SE15 was found to belong to E. coli reference collection group B2. In the chromosome, two prophage regions and seven integrative elements are found. Of the predicted protein-coding genes, we could assign 2,883 (64%) to known functions, 1,528 (34%) as conserved hypothetical genes and 77 (2%) as novel hypothetical genes. Of the predicted protein-coding genes on the chromosome, 3,735 (86%) are common to three uropathogenic E. coli (UPEC) genomes (CFT073, UTI89, and 536) and 263 (6%) are not identified in any of the three UPEC genomes. The 263 genes include 7 genes for the phosphoenolpyruvate:sugar phosphotransferase system involved in the uptake of carbohydrates, reflecting the adaptation of SE15 to a commensal lifestyle in the intestinal tract. pSE15 shares 121 genes (81%) with a 114-kb plasmid (GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"CP000244","term_id":"91075696","term_text":"CP000244"}}CP000244) of UPEC UTI89, indicating that both plasmids are derived from the same origin.The chromosome contains six large segments (LSs; >30 kb) designated LSs I to VI, three of which overlap one prophage region and two integrative elements. Each of the six LSs is located at the same locus as at least one of the pathogenicity islands (PAIs) or other insertion regions in the three UPEC genomes. LS II (ECSF_1824 to ECSF_1835) and three PAIs (PAI IV_UTI89, PAI IV₅₃₆, and HPI_CFT073) are located at the same loci in each chromosome and share the ybt operon encoding the yersiniabactin iron acquisition system, indicating that the ancestral E. coli of group B2 strains may have acquired the ybt genes. LS III (ECSF_1852 to ECSF_1897), PAI VI_UTI89, PAI VI₅₃₆, and PAI_CFT073-asnW are located at the same loci in each chromosome. The three PAIs contain the pks island encoding multiple nonribosomal peptide synthases and polyketide synthases, whereas LS III in SE15 completely lacks the pks island. The commensal E. coli strain ED1a also lacks the pks island (8), but the commensal E. coli strain Nissle 1917 has the pks island (5). These data suggest that the presence of the pks island may not be common among intestinal commensal strains in group B2. LS V (ECSF_2770 to ECSF_2794) is almost identical to PAI V_UTI89, which contains the genes cluster for a type II secretion system (gsp), group II capsule synthesis (kps), and polysialic acid synthesis (neu). The neu operon between the kpsFEDUCS and kpsMT genes in PAI V_UTI89 is responsible for K1 capsule biosynthesis, and this region between the kpsFEDUCS and kpsMT genes is highly variable in E. coli (9). The corresponding region (ECSF_2777 to ECSF_2781) in LS V encodes genes different from those in the neu operon in PAI V_UTI89; differs from the corresponding regions of the CFT073 (K2 serotype), 536 (K15 serotype), and APEC O1 (K1 serotype) strains; and shows no homology with any sequence in public databases.SE15 lacks many virulence-related genes, whereas UPEC encodes virulence-related factors, including fimbrial adhesins, toxins, capsule, and serum resistance and iron uptake systems. The three UPEC strains have the genes encoding P fimbriae (pap), S fimbriae (sfa/foc), Auf fimbriae (auf), and type 1 fimbriae (fim), whereas SE15 contains only the fim genes and lacked the pap, sfa/foc, and auf genes. Amino acid replacements in FimH located at the tip of type 1 fimbriae produce a shift from a commensal-associated trimannose binding phenotype to a urinary tract infection-associated monomannose binding phenotype (7). The other sequenced B2 strains (three UPEC strains, APEC O1, LF82, and ED1a) have Ser-70 and Asn-78 residues in FimH, whereas SE15 has Asn-70 and Ser-78 residues that are conserved in intestinal E. coli strains. Of the seven chaperon-usher fimbrial operons in SE15, six (fim, yad, yde, yeh, yfc, and yqi) are conserved in the three UPEC genomes. The one remaining fimbrial operon (ECSF_0163 to ECSF_0166) is specific to SE15. The GC content (42%) of this 5-kb fimbrial region is lower than the average GC content (51%) of the chromosome. UPEC strains contain a greater number of iron acquisition systems than do commensal strains, which may be a consequence of their adaptation to the iron-limiting urinary tract environment (3). SE15 also contains iron uptake system genes encoding siderophore enterobactin, siderophore yersiniabactin, iron transporter (sit), and heme (chu) systems but lacks genes for siderophore salmochelin, siderophore aerobactin, and novel siderophore (ireA), which are encoded by PAIs of UPEC strains. Furthermore, SE15 lacks genes encoding alpha-hemolysin and cytotoxic necrotizing factor, which are known toxins encoded by PAIs of UPEC strains.It has been pointed out that extraintestinal pathogenic E. coli (ExPEC) virulence factors identified in commensal strains of group B2 may facilitate colonization of the human gut and thus act as fitness factors for commensal E. coli stains (2). SE15 contains fewer known ExPEC virulence-associated genes than other known commensal strains (ED1a and Nissle 1917) in group B2, suggesting that ExPEC virulence-related genes in the SE15 genome may be necessary for this commensal microorganism to colonize the human gut.     

Protection of Macaques with Diverse MHC Genotypes against a Heterologous SIV by Vaccination with a Deglycosylated Live-Attenuated SIV

HIV vaccine development has been hampered by issues such as undefined correlates of protection and extensive diversity of HIV. We addressed these issues using a previously established SIV-macaque model in which SIV mutants with deletions of multiple gp120 N-glycans function as potent live attenuated vaccines to induce near-sterile immunity against the parental pathogenic SIVmac239. In this study, we investigated the protective efficacy of these mutants against a highly pathogenic heterologous SIVsmE543-3 delivered intravenously to rhesus macaques with diverse MHC genotypes. All 11 vaccinated macaques contained the acute-phase infection with blood viral loads below the level of detection between 4 and 10 weeks postchallenge (pc), following a transient but marginal peak of viral replication at 2 weeks in only half of the challenged animals. In the chronic phase, seven vaccinees contained viral replication for over 80 weeks pc, while four did not. Neutralizing antibodies against challenge virus were not detected. Although overall levels of SIV specific T cell responses did not correlate with containment of acute and chronic viral replication, a critical role of cellular responses in the containment of viral replication was suggested. Emergence of viruses with altered fitness due to recombination between the vaccine and challenge viruses and increased gp120 glycosylation was linked to the failure to control SIV. These results demonstrate the induction of effective protective immune responses in a significant number of animals against heterologous virus by infection with deglycosylated attenuated SIV mutants in macaques with highly diverse MHC background. These findings suggest that broad HIV cross clade protection is possible, even in hosts with diverse genetic backgrounds. In summary, results of this study indicate that deglycosylated live-attenuated vaccines may provide a platform for the elucidation of correlates of protection needed for a successful HIV vaccine against diverse isolates.