Temperature-regulated heterogeneous extracellular matrix gene expression defines biofilm morphology in Clostridium perfringens.

Cells in biofilms dynamically adapt to surrounding environmental conditions, which alters biofilm architecture. The obligate anaerobic pathogen Clostridium perfringens shows different biofilm structures in different temperatures. Here we find that the temperature-regulated production of extracellular polymeric substance (EPS) is necessary for morphological changes in biofilms. We identify BsaA proteins as an EPS matrix necessary for pellicle biofilm formation at lower temperature and find that extracellularly secreted BsaA protein forms filamentous polymers. We show that sipW-bsaA operon expression is bimodal, and the EPS-producing population size is increased at a lower temperature. This heterogeneous expression of the EPS gene requires a two-component system. We find that EPS-producing cells cover EPS-nonproducing cells attaching to the bottom surface. In the deletion mutant of pilA2, encoding a type IV pilin, the EPS gene expression is ON in the whole population. This heterogeneity is further regulated by the cleavage of the pilA2 mRNA by RNase Y, causing temperature-responsive EPS expression in biofilms. As temperature is an environmental cue, C. perfringens may modulate EPS expression to induce morphological changes in biofilm structure as a strategy for adapting to interhost and external environments.

Super-Agrobacterium ver. 4: Improving the Transformation Frequencies and Genetic Engineering Possibilities for Crop Plants.

Agrobacterium tumefaciens has been utilized for both transient and stable transformations of plants. These transformation methods have been used in fields such as breeding GM crops, protein production in plant cells, and the functional analysis of genes. However, some plants have significantly lower transient gene transfer and stable transformation rates, creating a technical barrier that needs to be resolved. In this study, Super-Agrobacterium was updated to ver. 4 by introducing both the ACC deaminase (acdS) and GABA transaminase (gabT) genes, whose resultant enzymes degrade ACC, the ethylene precursor, and GABA, respectively. A. tumefaciens strain GV2260, which is similar to other major strains (EHA105, GV3101, LBA4404, and MP90), was used in this study. The abilities of the Super-Agrobacterium ver. 4 were evaluated in Erianthus ravennae, Solanum lycopersicum "Micro-Tom," Nicotiana benthamiana, and S. torvum. Super-Agrobacterium ver. 4 showed the highest T-DNA transfer (transient transformation) frequencies in E. ravennae and S. lycopersicum, but not in N. benthamiana and S. torvum. In tomato, Super-Agrobacterium ver. 4 increased the stable transformation rate by 3.6-fold compared to the original GV2260 strain. Super-Agrobacterium ver. 4 enables reduction of the amount of time and labor required for transformations by approximately 72%, and is therefore a more effective and powerful tool for plant genetic engineering and functional analysis, than the previously developed strains. As our system has a plasmid containing the acdS and gabT genes, it could be used in combination with other major strains such as EHA105, EHA101, LBA4404, MP90, and AGL1. Super-Agrobacterium ver. 4, could thus possibly be a breakthrough application for improving basic plant science research methods.

An Agrobacterium tumefaciens Strain with Gamma-Aminobutyric Acid Transaminase Activity Shows an Enhanced Genetic Transformation Ability in Plants.

Agrobacterium tumefaciens has the unique ability to mediate inter-kingdom DNA transfer, and for this reason, it has been utilized for plant genetic engineering. To increase the transformation frequency in plant genetic engineering, we focused on gamma-aminobutyric acid (GABA), which is a negative factor in the Agrobacterium-plant interaction. Recent studies have shown contradictory results regarding the effects of GABA on vir gene expression, leading to the speculation that GABA inhibits T-DNA transfer. In this study, we examined the effect of GABA on T-DNA transfer using a tomato line with a low GABA content. Compared with the control, the T-DNA transfer frequency was increased in the low-GABA tomato line, indicating that GABA inhibits T-DNA transfer. Therefore, we bred a new A. tumefaciens strain with GABA transaminase activity and the ability to degrade GABA. The A. tumefaciens strain exhibited increased T-DNA transfer in two tomato cultivars and Erianthus arundinacues and an increased frequency of stable transformation in tomato.

Immunoactive Clostridial Membrane Vesicle Production Is Regulated by a Sporulation Factor.

Recently, many Gram-positive bacteria as well as Gram-negative bacteria have been reported to produce membrane vesicles (MVs), but little is known regarding the regulators involved in MV formation. We found that a Gram-positive anaerobic pathogen, Clostridium perfringens, produces MVs predominantly containing membrane proteins and cell wall components. These MVs stimulated proinflammatory cytokine production in mouse macrophage-like cells. We suggested that MVs induced interleukin-6 production through the Toll-like receptor 2 (TLR2) signaling pathway. Thus, the MV could have a role in the bacterium-host interaction and bacterial infection pathogenesis. Moreover, we found that the sporulation master regulator gene spo0A was required for vesiculogenesis. A conserved, phosphorylated aspartate residue of Spo0A was indispensable for MV production, suggesting that the phosphorylation of Spo0A triggers MV production. Multiple orphan sensor kinases necessary for sporulation were also required to maximize MV production. These findings imply that C. perfringens actively produces immunoactive MVs in response to the environment changing, as recognized by membrane-spanning sensor kinases and by modulating the phosphorylation level of Spo0A.

Role of RNase Y in Clostridium perfringens mRNA Decay and Processing.

RNase Y is a major endoribonuclease that plays a crucial role in mRNA degradation and processing. We study the role of RNase Y in the Gram-positive anaerobic pathogen Clostridium perfringens, which until now has not been well understood. Our study implies an important role for RNase Y-mediated RNA degradation and processing in virulence gene expression and the physiological development of the organism. We began by constructing an RNase Y conditional knockdown strain in order to observe the importance of RNase Y on growth and virulence. Our resulting transcriptome analysis shows that RNase Y affects the expression of many genes, including toxin-producing genes. We provide data to show that RNase Y depletion repressed several toxin genes in C. perfringens and involved the virR-virS two-component system. We also observe evidence that RNase Y is indispensable for processing and stabilizing the transcripts of colA (encoding a major toxin collagenase) and pilA2 (encoding a major pilin component of the type IV pili). Posttranscriptional regulation of colA is known to be mediated by cleavage in the 5' untranslated region (5'UTR), and we observe that RNase Y depletion diminishes colA 5'UTR processing. We show that RNase Y is also involved in the posttranscriptional stabilization of pilA2 mRNA, which is thought to be important for host cell adherence and biofilm formation. IMPORTANCE: RNases have important roles in RNA degradation and turnover in all organisms. C. perfringens is a Gram-positive anaerobic spore-forming bacterial pathogen that produces numerous extracellular enzymes and toxins, and it is linked to digestive disorders and disease. A highly conserved endoribonuclease, RNase Y, affects the expression of hundreds of genes, including toxin genes, and studying these effects is useful for understanding C. perfringens specifically and RNases generally. Moreover, RNase Y is involved in processing specific transcripts, and we observed that this processing in C. perfringens results in the stabilization of mRNAs encoding a toxin and bacterial extracellular apparatus pili. Our study shows that RNase activity is associated with gene expression, helping to determine the growth, proliferation, and virulence of C. perfringens.

The 2016 Kumamoto earthquake sequence.

Beginning in April 2016, a series of shallow, moderate to large earthquakes with associated strong aftershocks struck the Kumamoto area of Kyushu, SW Japan. An Mj 7.3 mainshock occurred on 16 April 2016, close to the epicenter of an Mj 6.5 foreshock that occurred about 28 hours earlier. The intense seismicity released the accumulated elastic energy by right-lateral strike slip, mainly along two known, active faults. The mainshock rupture propagated along multiple fault segments with different geometries. The faulting style is reasonably consistent with regional deformation observed on geologic timescales and with the stress field estimated from seismic observations. One striking feature of this sequence is intense seismic activity, including a dynamically triggered earthquake in the Oita region. Following the mainshock rupture, postseismic deformation has been observed, as well as expansion of the seismicity front toward the southwest and northwest.

A sporulation factor is involved in the morphological change of Clostridium perfringens biofilms in response to temperature.

Biofilm formation has been associated with bacterial pathogenesis, such as nosocomial and chronic infections, as the resistance of biofilms to environmental stresses has increased. Clostridium perfringens is a Gram-positive spore-forming anaerobic pathogen. This organism survives antibiotic treatment through the formation of biofilms or spores, but the environmental and regulatory factors involved in the biofilm formation remain unclear. Here, we observed that temperature regulates C. perfringens biofilm morphology. At 37°C, C. perfringens adhered to the substrate surface and formed a flat, thin biofilm, herein referred to as adhered biofilm. However, at 25°C, this bacterium did not adhere and produced a threadlike extracellular matrix, forming a viscous, thick biofilm, herein referred to as pellicle biofilm. Pellicle biofilm formation requires the sporulation master regulator, Spo0A, and the toxin regulator, CtrAB, and is enhanced in the absence of the global repressor, AbrB. These transcriptional regulator genes are regulated by each other and temperature. Adhered-biofilm formation requires AbrB and pilA2, which encodes a component of type IV pili (TFP). TFP expression was activated at 37°C and regulated through Spo0A, AbrB, and CtrAB. These results indicate that the morphology of C. perfringens biofilm is dependent on temperature through the differential production of extracellular matrix and the activity of TFP. Moreover, pellicle biofilm formation is involved in sporulation and toxin production. Here, we demonstrated that clostridial biofilm formation is closely associated with sporulation and that the morphological change of the biofilms could play an important role in the pathogenesis of this organism.

SP10 infectivity is aborted after bacteriophage SP10 infection induces nonA transcription on the prophage SPß region of the Bacillus subtilis genome.

Bacteria have developed various strategies for phage resistance. Infection with phage induces the transcription of part of the phage resistance gene, but the regulatory mechanisms of such transcription remain largely unknown. The phage resistance gene nonA is located on the SPß prophage region of the Bacillus subtilis Marburg strain genome. The nonA transcript was detected at the late stage of SP10 infection but is undetectable in noninfected cells. The nonA transcript was detected after the induction of the sigma factor Orf199-Orf200 (σ(Orf199-200)), when sigma factors encoded in the SP10 genome were expressed from a xylose-inducible plasmid. Thus, the SP10 sigma factor is an activator of a set of SP10 genes and nonA. The nonA gene encodes a 72-amino-acid protein with a transmembrane motif and has no significant homology with any protein in any database. NonA overexpression halted cell growth and reduced the efficiency of B. subtilis colony formation and respiration activity. In addition, SP10 virion protein synthesis was inhibited in the nonA(+) strain, and SP10 virion particles were scarce in it. These results indicate that NonA is a novel protein that can abort SP10 infection, and its transcription was regulated by SP10 sigma factor.

Increased 1-aminocyclopropane-1-carboxylate deaminase activity enhances Agrobacterium tumefaciens-mediated gene delivery into plant cells.

Agrobacterium-mediated transformation is a useful tool for the genetic modification in plants, although its efficiency is low for several plant species. Agrobacterium-mediated transformation has three major steps in laboratory-controlled experiments: the delivery of T-DNA into plant cells, the selection of transformed plant cells, and the regeneration of whole plants from the selected cells. Each of these steps must be optimized to improve the efficiency of Agrobacterium-mediated plant transformation. It has been reported that increasing the number of cells transformed by T-DNA delivery can improve the frequency of stable transformation. Previously, we demonstrated that a reduction in ethylene production by plant cells during cocultivation with A. tumefaciens-expressing 1-aminocyclopropane-1-carboxylic acid (ACC) deaminase resulted in increased T-DNA delivery into the plant cells. In this study, to further improve T-DNA delivery by A. tumefaciens, we modified the expression cassette of the ACC deaminase gene using vir gene promoter sequences. The ACC deaminase gene driven by the virD1 promoter was expressed at a higher level, resulting in a higher ACC deaminase activity in this A. tumefaciens strain than in the strain with the lac promoter used in a previous study. The newly developed A. tumefaciens strain improves the delivery of T-DNA into Solanum lycopersicum (tomato) and Erianthus ravennae plants and thus may be a powerful tool for the Agrobacterium-mediated genetic engineering of plants.

Structural requirement in Clostridium perfringens collagenase mRNA 5' leader sequence for translational induction through small RNA-mRNA base pairing.

The Gram-positive anaerobic bacterium Clostridium perfringens is pathogenic to humans and animals, and the production of its toxins is strictly regulated during the exponential phase. We recently found that the 5' leader sequence of the colA transcript encoding collagenase, which is a major toxin of this organism, is processed and stabilized in the presence of the small RNA VR-RNA. The primary colA 5'-untranslated region (5'UTR) forms a long stem-loop structure containing an internal bulge and masks its own ribosomal binding site. Here we found that VR-RNA directly regulates colA expression through base pairing with colA mRNA in vivo. However, when the internal bulge structure was closed by point mutations in colA mRNA, translation ceased despite the presence of VR-RNA. In addition, a mutation disrupting the colA stem-loop structure induced mRNA processing and ColA-FLAG translational activation in the absence of VR-RNA, indicating that the stem-loop and internal bulge structure of the colA 5' leader sequence is important for regulation by VR-RNA. On the other hand, processing was required for maximal ColA expression but was not essential for VR-RNA-dependent colA regulation. Finally, colA processing and translational activation were induced at a high temperature without VR-RNA. These results suggest that inhibition of the colA 5' leader structure through base pairing is the primary role of VR-RNA in colA regulation and that the colA 5' leader structure is a possible thermosensor.

[Estimating elapsed time of brain hemorrhage using computed tomography value-based parameters].

We measured the time-dependent change of computed tomography (CT) values for a blood sample in a syringe during 20 days expecting that the (average, maximum) CT values may be used to estimate the elapsed time after hemorrhage. The average CT value (CT(ave)) rapidly increased for the first 50 min. The maximum CT value (CT(max)) increased step by step to take the largest value (82.4 HU) one day later, and subsequently the CT(max) decreased slowly to become 72.0 HU 20 days later. We conclude that the rapid increase of the CT(ave) at the beginning is due to the fibrin generation, the increase of the CT(max) is a result of the formation of the fibrin net, and the subsequent decrease of CT(max) is caused by fibrinolysis. Tentative experimental formula for the time-dependent CT(max) change at each increasing stage and decreasing stage are given to estimate the elapsed time after hemorrhage.

Crystal structure of Hfq from Bacillus subtilis in complex with SELEX-derived RNA aptamer: insight into RNA-binding properties of bacterial Hfq.

Bacterial Hfq is a protein that plays an important role in the regulation of genes in cooperation with sRNAs. Escherichia coli Hfq (EcHfq) has two or more sites that bind RNA(s) including U-rich and/or the poly(A) tail of mRNA. However, functional and structural information about Bacillus subtilis Hfq (BsHfq) including the RNA sequences that specifically bind to it remain unknown. Here, we describe RNA aptamers including fragment (AG)(3)A that are recognized by BsHfq and crystal structures of the BsHfq-(AG)(3)A complex at 2.2 Å resolution. Mutational and structural studies revealed that the RNA fragment binds to the distal site, one of the two binding sites on Hfq, and identified amino acid residues that are critical for sequence-specific interactions between BsHfq and (AG)(3)A. In particular, R32 appears to interact with G bases in (AG)(3)A. Poly(A) also binds to the distal site of EcHfq, but the overall RNA structure and protein-RNA interaction patterns engaged in the R32 residues of BsHfq-(AG)(3)A differ from those of EcHfq-poly(A). These findings provide novel insight into how the Hfq homologue recognizes RNA.

A novel toxin regulator, the CPE1446-CPE1447 protein heteromeric complex, controls toxin genes in Clostridium perfringens.

Clostridium perfringens is a Gram-positive anaerobic spore-forming bacterium that is widespread in environmental soil and sewage, as well as in animal intestines. It is also a causative agent of diseases in humans and other animals, and it produces numerous extracellular enzymes and toxins. Although these toxins have been characterized in detail, regulators of toxin genes are less well understood. The present study identified CPE1447 and CPE1446 as novel regulators of toxin gene expression. CPE1447 and CPE1446 are cotranscribed as an operon, and the encoded proteins have a helix-turn-helix (HTH) motif at the N termini of their amino acid sequences, suggesting that CPE1447 and CPE1446 control the target genes as transcriptional regulators. The expression of several genes encoding toxins was changed in both a CPE1446 mutant and a CPE1447-CPE1446 deletion mutant. Complementation of CPE1446 and CPE1447 revealed that CPE1447 and CPE1446 coordinately regulate their target genes. CPE1447 protein was coprecipitated with His-tagged CPE1446 protein, indicating that the CPE1447 and CPE1446 proteins form a stable complex in C. perfringens under their native conditions. Although the small RNA that regulates several genes under the VirR/VirS two-component system (VR-RNA) positively affected CPE1447-CPE1446 mRNA expression, it did not control expression of the CPE1447-CPE1446 regulon, demonstrating that CPE1447 and CPE1446 regulate a different set of toxin genes from the VirR/VirS-VR-RNA cascade.

Secretion of biologically-active human interferon-ß by Bacillus subtilis.

Human interferon-ß (hIFN-ß) was used as a heterologous model protein to investigate the effects of the Bacillus subtilis AmyE propeptide and co-expression of PrsA in enhancing the secretion of heterologous proteins in B. subtilis. Secretion and activity of hIFN-ß with AmyE propeptide increased by more than four-fold compared to that without AmyE propeptide. Moreover, under conditions of co-expressed PrsA, the secretion production and activity of hIFN-ß with AmyE propeptide increased by more than 1.5-fold. AmyE propeptide and co-expression of PrsA thus have an additive effect on enhancing the production of the hIFN-ß in B. subtilis.

Constituents of the green tea seeds of Camellia sinensis.

Green tea (Camellia sinensis) leaves are known to contain active ingredients such as catechins and caffeine, and are widely useful materials. Recently, green tea flowers also have been in the spotlight. However, little attention has been paid to the tea seeds. In this work, the constituents of green tea seeds and green tea leaves were compared. Caffeine was found in the seeds, whereas catechins (usually obtained from green tea leaves) were not observed. Next, we investigated the constituents of hexane extracts and methanol extracts of green tea seeds. We found that the hexane extracts contained high amounts of oleic glyceride (79.9%) in addition to linoleic glyceride (20%). We confirmed the structures of these glycerides by NMR spectroscopy and by synthesis from a fatty acid and glycerol. The methanol extract was found to contain naringenin glucosides by mass spectrometry and NMR spectroscopic analysis.

Propeptide of Bacillus subtilis amylase enhances extracellular production of human interferon-α in Bacillus subtilis.

The Gram-positive bacterium, Bacillus subtilis and related species are widely used industrially as hosts for producing enzymes. These species possess a high potential to produce secreted proteins into the culture medium. Nevertheless, the secretion of heterologous proteins by these species is frequently inefficient. In this study, the human interferon-α2b (hIFN-α2b) was used as a heterologous model protein, to investigate the effect of B. subtilis AmyE propeptide in enhancing the secretion of heterologous proteins in B. subtilis. We found that the secretion production and activity of hIFN-α2b with AmyE propeptide increased by more than threefold, compared to that without AmyE propeptide. The maximum amount of secreted hIFN-α2b with propeptide was 14.8 ± 0.6 µg ml⁻¹. In addition, the pro-hIFN-α2b bioactivity reached 5.4 ± 0.5 x 107 U mg⁻¹, which is roughly the same level as that of the non-propeptide hIFN-α2b. These results indicated that AmyE propeptide enhanced the secretion of the hIFN-α2b protein from B. subtilis. This study provides a useful method to enhance the extracellular production of heterologous proteins in B. subtilis.

Effects of depletion of RNA-binding protein Tex on the expression of toxin genes in Clostridium perfringens.

Tex was originally identified in Bordetella pertussis, where it serves as a transcriptional regulator of toxin genes. However, the Tex of Streptococcus pneumoniae has no regulatory function in the expression of the pneumococcal major toxin pneumolysin. Here, we identified the CPE2168 gene as Tex in Clostridium perfringens, and examined the roles of Tex in toxin gene expression. We found that the deletion mutant for Tex does not affect growth, but the mRNA levels of three hyaluronidase genes (nagH, nagJ, and nagL) and an exo-sialidase (nanJ) were reduced to less than 50% as compared to the parent strain, C. perfringens strain 13. On the other hand, Tex did not affect the expression of proteases, enterotoxins, hemolysins, either of two hyaluronidase genes (nagI and nagK), an exo-sialidase (nanI), or adhesins. Moreover, purified Tex bound to the 5'-portion of target gene mRNAs. Based on these results, we propose that Tex positively regulates the gene expression of a set of toxin genes in C. perfringens.

Modified method for automatic exposure control in pediatric brain CT-application of the standard deviation value method by use of patient's age and head size.

We examined the optimum conditions for pediatric brain CT scans. CT controls the X-ray transit dose using tube current alteration called automatic exposure control (AEC) to adjust the standard deviation (SD) value for each scanning region, and it also reduces exposure. If the SD value is inappropriate, children may be exposed to increased radiation. Therefore we acquired images of 500 children from the server, and examined the most suitable SD value for each age using the data of their SD value and age. X-ray transit control with AEC was influenced by scan position and the age of a child. We enabled accurate scanning and decreased radiation exposure by adjusting AEC to the age and the cephalic volume of each child. As a result, reduction of the X-ray exposure by up to 31.2% per slice in tube current alteration was possible using a suitable SD value for each age. On the other hand, it was possible to reduce X-ray exposure by up to 67.9% per slice with the scan technique that used age and corrected cephalic volume without adjusting AEC. Using the tube current alteration protocol for each age with the data of the SD value or cephalic volume in CT, we can more easily conduct scans of children under optimal conditions.

Stabilization of Clostridium perfringens collagenase mRNA by VR-RNA-dependent cleavage in 5' leader sequence.

The small RNA (sRNA), VR-RNA that is directly regulated by the VirR/VirS two-component system, regulates many genes including toxin genes such as collagenase (colA) and phospholipase C (plc) in Clostridium perfringens. Although the VR-RNA 3' region is sufficient to regulate the colA and plc genes, the molecular mechanism of toxin gene regulation by VR-RNA remains unclear. Here, we found that colA mRNA is cleaved at position -79 and -78 from the A of the first codon (ATG) in the presence of VR-RNA. The processed transcripts were stable compared with longer intact transcripts. On the other hand, colA mRNA was labile in a VR-RNA-deficient strain, and processed transcripts were undetectable. The stability and processing of colA mRNA were restored by transformation of the 3' region of VR-RNA-expression vector. The 3' region of VR-RNA and colA mRNA had significant complementation and interacted in vitro. These results show that VR-RNA base pairs with colA mRNA and induces cleavage in the 5' untranslated region (UTR) of colA mRNA, which leads to the stabilization of colA mRNA and the activation of colA expression.

Enhanced extracellular production of heterologous proteins in Bacillus subtilis by deleting the C-terminal region of the SecA secretory machinery.

In this study, we examined the effects of modifying the C-terminal region of the SecA protein on the production of heterologous proteins in Bacillus subtilis. SecA was selected as a candidate among the components of the Sec system due to its ability to interact directly with both the precursors and membrane translocases. A phylogenetic comparison demonstrated that the C-terminal region is not well conserved among eubacterial SecA proteins. The deletion of the 61 amino acids at the C-terminal region led to an 83% increase in extracellular alkaliphilic Bacillus sp. thermostable alkaline cellulase (Egl-237) activity. Moreover, the productivity of human interferon α (hIFN-α2b) was increased by 2.2-fold compared to the wild-type SecA, by deletion of these 61 amino acids. We indicated that the deletion of the C-terminal domain (CTD) of SecA enhanced the secretion of two different heterologous protein, Egl-237 and hIFN-α2b. This study provides a useful method to enhance the extracellular production of heterologous proteins in B. subtilis.