C-O bond formation by polyketide synthases.
(41/347)
Polyketide synthases (PKSs) assemble the polyketide carbon backbone by sequential decarboxylative condensation of acyl coenzyme A (CoA) precursors, and the C-C bond-forming step in this process is catalyzed by the beta-ketoacyl synthase (KS) domain or subunit. Genetic and biochemical characterization of the nonactin biosynthesis gene cluster from Streptomyces griseus revealed two KSs, NonJ and NonK, that are highly homologous to known KSs but catalyze sequential condensation of the acyl CoA substrates by forming C-O rather than C-C bonds. This chemistry can be used in PKS engineering to increase the scope and diversity of polyketide biosynthesis. (+info)
Crystal structures of transcription factor NusG in light of its nucleic acid- and protein-binding activities.
(42/347)
Microbial transcription modulator NusG interacts with RNA polymerase and termination factor rho, displaying striking functional homology to eukaryotic Spt5. The protein is also a translational regulator. We have determined crystal structures of Aquifex aeolicus NusG showing a modular design: an N-terminal RNP-like domain, a C-terminal element with a KOW sequence motif and a species-specific immunoglobulin-like fold. The structures reveal bona fide nucleic acid binding sites, and nucleic acid binding activities can be detected for NusG from three organisms and for the KOW element alone. A conserved KOW domain is defined as a new class of nucleic acid binding folds. This module is a close structural homolog of tudor protein-protein interaction motifs. Putative protein binding sites for the RNP and KOW domains can be deduced, which differ from the areas implicated in nucleic acid interactions. The results strongly argue that both protein and nucleic acid contacts are important for NusG's functions and that the factor can act as an adaptor mediating indirect protein-nucleic acid associations. (+info)
Control by A-factor of a metalloendopeptidase gene involved in aerial mycelium formation in Streptomyces griseus.
(43/347)
In Streptomyces griseus, A-factor (2-isocapryloyl-3R-hydroxymethyl-gamma-butyrolactone) switches on aerial mycelium formation and secondary metabolite biosynthesis. An A-factor-dependent transcriptional activator, AdpA, activates multiple genes required for morphological development and secondary metabolism in a programmed manner. A region upstream of a zinc-containing metalloendopeptidase gene (sgmA) was found among the DNA fragments that had been isolated as AdpA-binding sites. The primary product of sgmA consisted of N-terminal pre, N-terminal pro, mature, and C-terminal pro regions. sgmA was transcribed in an AdpA-dependent manner, and its transcription was markedly enhanced at the timing of aerial mycelium formation. AdpA bound two sites in the region upstream of the sgmA promoter; one was at about nucleotide position -60 (A site) with respect to the transcriptional start point of sgmA, and the other was at about position -260 (B site), as determined by DNase I footprinting. Transcriptional analysis with mutated promoters showed that the A site was essential for the switching on of sgmA transcription and that the B site was necessary for the marked enhancement of transcription at the timing of aerial mycelium formation. Disruption of the chromosomal sgmA gene resulted in a delay in aerial hypha formation by half a day. SgmA is therefore suggested to be associated with the programmed morphological development of Streptomyces, in which this peptidase, perhaps together with other hydrolytic enzymes, plays a role in the degradation of proteins in substrate hyphae for reuse in aerial hypha formation. (+info)
Genetic and biochemical characterization of EshA, a protein that forms large multimers and affects developmental processes in Streptomyces griseus.
(44/347)
The 52-kDa protein, EshA, whose expression is controlled developmentally, is produced during the late growth phase of Streptomyces spp. We found that disruption of the eshA gene, which encodes the EshA protein, abolishes the aerial mycelium formation and streptomycin production in Streptomyces griseus when grown on an agar plate. The eshA disruptant KO-390 demonstrated a reduced amount of expression of the transcriptional activator strR, thus accounting for the failure to produce streptomycin. KO-390 was found to accumulate deoxynucleoside triphosphates at high levels, including dGTP, at late growth phase. The accumulation of dGTP was a cause for the impaired ability of KO-390 to produce aerial mycelium, because the ability to form aerial mycelium was completely repaired by addition of decoyinine, an inhibitor of GMP synthetase. The accumulation of dNTP in KO-390 coincided with a reduced rate of DNA synthesis. The developmental time frame of these phenomena in KO-390 matched a burst of EshA expression in the wild-type strain. In contrast to S. griseus, the eshA disruption did not affect the ability for Streptomyces coelicolor to form aerial mycelium and did not result in the aberrant accumulation of dNTP accompanied by arrest of DNA synthesis, implying qualitative differences in addition to quantitative differences between the two EshA proteins. We propose that the S. griseus EshA protein somehow positively affects (or regulates) the replication of DNA in wild-type cells at late growth phase but leads to aberrant phenotypes in mutant cells due to the disturbed DNA replication. The EshA protein was found to exist as a multimer ( approximately 20-mers) creating a cubic-like structure with a diameter of 27 nm and located predominantly in cytoplasm. (+info)
Glutathione S-transferase isoenzymes from Streptomyces griseus.
(45/347)
An inducible, cytosolic glutathione S-transferase (GST) was purified from Streptomyces griseus. GST isoenzymes with pI values of 6.8 and 7.9 used standard GST substrates including 1-chloro-2,4-dinitrobenzene. GST had subunit and native M(r)s of 24 and 48, respectively, and the N-terminal sequence SMILXYWDIIRGLPAH. (+info)
Chromosomal arm replacement in Streptomyces griseus.
(46/347)
UV irradiation of Streptomyces griseus 2247 yielded a new chromosomal deletion mutant, MM9. Restriction and sequencing analysis revealed that homologous recombination between two similar lipoprotein-like open reading frames, which are located 450 and 250 kb from the left and right ends, respectively, caused chromosomal arm replacement. As a result, new 450-kb terminal inverted repeats (TIRs) were formed in place of the original 24-kb TIRs. Frequent homologous recombinations in Streptomyces strains suggest that telomere deletions can usually be repaired by recombinational DNA repair functioning between the intact and deleted TIR sequences on the same chromosome. (+info)
Transcriptional switch on of ssgA by A-factor, which is essential for spore septum formation in Streptomyces griseus.
(47/347)
A-factor (2-isocapryloyl-3R-hydroxymethyl-gamma-butyrolactone) triggers morphological development and secondary metabolism in Streptomyces griseus. A transcriptional activator (AdpA) in the A-factor regulatory cascade switches on a number of genes required for both processes. AdBS11 was identified in a library of the DNA fragments that are bound by AdpA and mapped upstream of ssgA, which is essential for septum formation in aerial hyphae. Gel mobility shift assays and DNase I footprinting revealed three AdpA-binding sites at nucleotide positions about -235 (site 1), -110 (site 2), and +60 (site 3) with respect to the transcriptional start point, p1, of ssgA. ssgA had two transcriptional start points, one starting at 124 nucleotides (p1) and the other starting at 79 nucleotides (p2) upstream of the start codon of ssgA. Of the three binding sites, only sites 1 and 2 were required for transcriptional activation of p1 and p2 by AdpA. The transcriptional switch on of ssgA required the extracytoplasmic function sigma factor, sigma(AdsA), in addition to AdpA. However, it was unlikely that sigma(AdsA) recognized the two ssgA promoters, since their -35 and -10 sequences were not similar to the promoter sequence motifs recognized by sigma(BldN), a sigma(AdsA) homologue of Streptomyces coelicolor A3(2). An ssgA disruptant formed aerial hyphae, but did not form spores, irrespective of the carbon source of the medium, which indicated that ssgA is a member of the whi genes. Transcriptional analysis of ssfR, located just upstream of ssgA and encoding an IclR-type transcriptional regulator, suggested that no read-through from ssfR into ssgA occurred, and ssgA was transcribed in the absence of ssfR. ssgA was thus found to be controlled by AdpA and not by SsfR to a detectable extent. SsfR appeared to regulate spore septum formation independently of SsgA or through interaction with SsgA in some unknown way, because an ssfR disruptant also showed a whi phenotype. (+info)
The protein complex composed of nickel-binding SrnQ and DNA binding motif-bearing SrnR of Streptomyces griseus represses sodF transcription in the presence of nickel.
(48/347)
Nickel-responsive transcriptional repression of sodF, which codes for iron- and zinc-containing superoxide dismutase of Streptomyces griseus, was mediated through an operator (-2 to +15) spanning over the 5' end (+1) of the transcript. Two open reading frames, SrnR (12,343 Da) and SrnQ (12,486 Da), with overlapping stop-start codons were identified downstream from sodF and found responsible for the repression of sodF. The deduced amino acid sequence of SrnR revealed a DNA binding motif and showed homology to the transcriptional regulators of ArsR family, whereas SrnQ did not show any similarity to any known proteins. When srnRQ DNA was maintained in trans in S. griseus on a multicopy plasmid, sodF transcription was highly repressed by nickel, but neither srnR nor srnQ alone showed the effect. Consistently, the sodF transcription of srnR-interrupted mutant was no longer repressed by nickel, which was complemented only with srnRQ DNA. Nickel-dependent binding of SrnR and SrnQ to the sodF operator DNA was observed only when the two proteins were provided together. The maximum protein-DNA interaction was shown when SrnR and SrnQ were present in one-to-one stoichiometric ratio. The two proteins appear to constitute an octamer composed of four subunits of each protein. SrnR directly interacted with SrnQ, and the protein interaction did not require nickel. The conformation of SrnQ was changed upon nickel binding, which was in the ratio of one Ni(2+) ion per protein molecule. A model is proposed in which SrnQ of the protein complex senses nickel and subsequently enhances the DNA binding activity of SrnR through the protein-protein interaction. (+info)