The authors previously reported that interspecific stimulatory events between Streptomyces species for antibiotic production and/or morphological differentiation mediated by putative diffusible metabolites take place at a high frequency. This paper reports the isolation and characterization of a substance produced by Streptomyces griseus that stimulates the growth and development of Streptomyces tanashiensis. The substance was purified from the culture supernatant of S. griseus by using anion-exchange chromatography, gel filtration chromatography and reverse-phase HPLC. FAB-MS and NMR analyses of the purified preparation indicated the substance to be desferrioxamine E (synonym: nocardamine), a siderophore that is widely produced by Streptomyces species and related organisms. Similar stimulatory effects on the growth and development of S. tanashiensis were exerted by desferrioxamine E produced by another actinomycete strain, but not by other siderophores tested, including ferrichrome and nocobactin and free ferric ion. An exogenous supply of desferrioxamine E stimulated secondary metabolite formation and/or morphological differentiation in various actinomycete strains. Disruption of the desferrioxamine biosynthesis gene cluster in Streptomyces coelicolor A3(2) abolished the production of desferrioxamine E and the activity to stimulate the growth and differentiation of S. tanashiensis. The S. coelicolor mutant showed impaired growth and development on Bennett's/ glucose agar medium, but it was rescued by the exogenous supply of desferrioxamine E. These results indicate that desferrioxamines play an important role in streptomycete physiology. Similar to several pathogenic bacteria and fungi, S. tanashiensis may be defective in the production of siderophores; however, it can utilize the siderophores excreted by other organisms.
In previous studies, human dental pulp stem cells (hDPSCs) were mainly isolated from adults. In this present study, we characterized hDPSCs isolated from an earlier developmental stage to evaluate the potential usage of these cells for tissue-regenerative therapy. hDPSCs isolated at the crown-completed stage showed a higher proliferation rate than those isolated at a later stage. When the cells from either group were cultured in medium promoting differentiation toward cells of the osteo/odontoblastic lineage, both became alkaline-phosphatase-positive, produced calcified matrix, and were also capable of forming dentin-like matrix on scaffolds in vivo. However, during long-term passage, these cells underwent a change in morphology and lost their differentiation ability. The results of a DNA array experiment showed that the expression of several genes, such as WNT16, was markedly changed with an increasing number of passages, which might have caused the loss of their characteristics as hDPSCs.
Enzymological Characterization of EpoA, a Laccase-Like Phenol Oxidase Produced by Streptomyces griseus
Laccase is an enzyme that catalyzes the oxidation of phenolic compounds by coupling the reduction of oxygen to water. While many laccases have been identified in plant and fungal species, enzymes of prokaryotic origin are poorly known. Here we report the enzymological characterization of EpoA, a laccase-like extracytoplasmic phenol oxidase produced by Streptomyces griseus. EpoA was expressed and purified with an Escherichia coli host-vector system as a recombinant protein fused with a C-terminal histidine-tag (rEpoA). Physicochemical analyses showed that rEpoA comprises a stable homotrimer containing all three types of copper (types 1-3). Various known laccase substrates were oxidized by rEpoA, while neither syringaldazine nor guaiacol served as substrates. Among the substrates examined, rEpoA most effectively oxidized N,N-dimethyl-p-phenylenediamine sulphate with a Km value of 0.42 mM. Several metal chelators caused marked inhibition of rEpoA activity, implying the presence of a metal center essential for the oxidase activity. The pH and temperature optima of rEpoA were 6.5 and 40 degrees C, respectively. The enzyme retained 40% activity after preincubation at 70 degrees C for 60 min. EpoA-like activities were detected in cell extracts of 8/40 environmental actinomycetes strains, which suggests that similar oxidases are widely distributed among this group of bacteria.
The amf gene cluster was previously identified as a regulator for the onset of aerial-mycelium formation in Streptomyces griseus. The nucleotide sequences of amf and its counterparts in other species revealed a conserved gene organization consisting of five open reading frames. A nonsense mutation in amfS, encoding a 43-aminoacid peptide, caused significant blocking of aerial-mycelium formation and streptomycin production, suggesting its role as a regulatory molecule. Extracellular-complementation tests for the aerial-mycelium-deficient phenotype of the amfS mutant demonstrated that AmfS was secreted by the wild-type strain. A null mutation in amfBA, encoding HlyB-like membrane translocators, abolished the extracellular AmfS activity without affecting the wild-type morphology, which suggests that AmfBA is involved not in production but in export of AmfS. A synthetic C-terminal octapeptide partially induced aerial-mycelium formation in the amfS mutant, which suggests that an AmfS derivative, but not AmfS itself, serves as an extracellular morphogen.
X-ray fluorescence spectrometry of asteroid 25143 Itokawa was performed by the x-ray spectrometer onboard Hayabusa during the first touchdown on 19 November 2005. We selected those data observed during relatively enhanced solar activity and determined average elemental mass ratios of Mg/Si = 0.78 +/- 0.09 and Al/Si = 0.07 +/- 0.03. Our preliminary results suggest that Itokawa has a composition consistent with that of ordinary chondrites, but primitive achondrites cannot be ruled out. Among ordinary chondrites, LL- or L-chondrites appear to be more likely than H-chondrites. No substantial regional difference was found on the asteroid surface, indicating its homogeneity in composition.
Exogenous addition of copper stimulates cellular differentiation inStreptomyces spp. Several lines of evidence suggested a parallel correlation between the stimulatory effect of copper and phenol-oxidizing enzyme activities in Streptomyces griseus. Here a novel extracytoplasmic phenol oxidase (EpoA) associated with cellular development of this organism was identified and characterized. EpoA activity, examined by an in-gel stain procedure with N,N'-dimethyl-p-phenylenediamine sulfate as a substrate, was repressed by glucose and induced by copper supplied in the medium. The enzyme activity was abolished and markedly reduced in the mutants for A-factor biosynthesis and amfR, respectively, which suggested that the activity of the enzyme depends on those essential regulators for morphogenesis in S. griseus. EpoA protein was purified to homogeneity and the N-terminal amino acid sequence was determined. A homologous sequence identified in the genomic database of Streptomyces coelicolorA3(2) was used as a probe to clone the complete epoA gene of S. griseus. The deduced amino acid sequence of EpoA revealed that the mature protein with a molecular mass of 34 kDa was preceded by a signal peptide consisting of 34 aa, consistent with EpoA being a secreted enzyme. EpoA was predicted to be a laccase-type oxidase by not only the sequence similarity, but its substrate selectivity, oxidizing not tyrosine but dihydroxyphenylalanine (DOPA) to generate melanin pigment. Introduction of epoA on a plasmid partially restored both the EpoA activity and aerial mycelium productivity in an A-factor-deficient mutant. Exogenous supplementation of a substance synthesized by purified EpoA from DOPA stimulated cellular differentiation in S. griseus and several other species. Ultrafiltration indicated that the molecular mass of the putative stimulant synthesized by EpoA is between 500 and 1000 Da.
A methanogenic bioreactor that utilized wastepaper was developed and operated at 55°C. Microbial community structure analysis showed the presence of a group of clostridia that specifically occurred during the period of high fermentation efficiency. To isolate the effective cellulose digester, the sludge that exhibited high fermentation efficiency was inoculated into a synthetic medium that contained cellulose powder as the sole carbon source and was successively cultivated. A comprehensive 16S rRNA gene sequencing study revealed that the enriched culture contained various clostridia that had diverse phylogenetic positions. The microorganisms were further enriched by successive cultivation with filter paper as the substrate, as well as the bait carrier. A resultant isolate, strain EBR45 ؍( Clostridium sp. strain NBRC101661), was a new member of the order Clostridiales phylogenetically and physiologically related to Clostridium thermocellum and Clostridium straminisolvens. Specific PCR-based monitoring demonstrated that strain EBR45 specifically occurred during the high fermentation efficiency period in the original methanogenic sludge. Strain EBR45 effectively digested office paper in its pure cultivation system with a synthetic medium.Waste utilization is a major concern in energy development and environmental improvement. In this regard, various attempts have been made to develop effective microbial digestion systems (6). We study the application of thermophilic methane fermentation in the reduction and utilization of municipal solid wastes. Although the operation of a thermophilic reactor consumes more electrical energy than that by a mesophilic reactor, it enables effective degradation of substrates and production of methane in a short fermentation period (1). We expect that the fermentation will contribute to the rapid and efficient processing of municipal solid wastes in urban districts. In Tokyo, half of the combustible waste consists of paper (22). Recently, utilization of the markedly increasing amount of shredded office paper has become a matter of great concern; it is nonrecyclable because shredded cellulose fiber is not suited for papermaking.Conversion of cellulose to methane is mediated by four microbial populations: cellulolytic microbes, noncellulolytic saccharolytic microbes, syntrophic hydrogen-generating bacteria, and methane-producing members of the domain Archaea (2). Generally, the initial hydrolysis is the rate-limiting step in microbial conversion; the efficiency of cellulose degradation markedly affects the methane formation activity in the methanogenic microbial system (2, 11, 15). Therefore, characterization of the cellulose-digesting microbial population is important for the development of efficient fermentation systems. This paper describes the isolation and characterization of a Clostridium sp. that effectively degrades cellulosic wastes. We operated a methanogenic bioreactor that primarily digested office paper and detected the presence of a group of effective cellulose-digesting ...
The SEC1 gene of yeast Saccharomyces cerevisiae was cloned by complementing the temperature-sensitive mutation of sec1-1 at 37 degrees C, and its nucleotide sequence was determined. SEC1 is a single copy gene and encodes a protein of 724 amino acids and 83,490 daltons with a predicted pI value of 6.11. Hydrophobicity plotting showed no clearly hydrophobic regions suggesting a soluble nature for the protein. Amino acid sequence comparisons revealed no obvious homologies with the proteins in the SWISSPROT databank. Two consensus sequence for the cdc2 encoded protein kinase recognition site were revealed within Sec1p. The codon usage suggests a low expression level for SEC1. The 5' non-translated region contains two TATA-like sequences at -52 and -215 nucleotides from the translation start site. Two potential regulatory sequences for DNA binding proteins were found in the non-coding 5' region: a HAP2/HAP3 consensus recognition sequence at nucleotide-154 and a BAF1 consensus recognition sequence at nucleotide-136. The SEC1 specific probe detected a 2400 nucleotides long transcript, which was in reasonable agreement with the 2172 nucleotides long open reading frame.
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