Effect of a T81A mutation at the subunit interface on catalytic properties of alkaline phosphatase from Escherichia coli.

Although alkaline phosphatase (APase) from Escherichia coli crystallizes as a symmetric dimer, it displays deviations from Michaelis-Menten kinetics supported by a model describing a dimeric enzyme with conformationally and kinetically non-equivalent subunits. The proposed model, explaining the mechanism of substrate hydrolysis, encompasses a conformational change mediated by subunit interactions [S. Orhanovic, M. Pavela-Vrancic, Eur. J. Biochem. 270 (2003) 4356-4364]. The significance of interactions at the subunit interface and the involvement of the beta-pleated sheet stretching from underneath the active site to the subunit surface, in the catalytic mechanism, has been probed by site-directed mutagenesis. The mutant APase, carrying alanine in place of Thr81, was analyzed in comparison to the wild-type protein. The T81A mutation, introduced at the subunit interface, significantly affected the protein kinetic properties, emphasizing the importance of subunit interactions in the catalytic process.

The recA gene from Streptomyces rimosus R6: sequence and expression in Escherichia coli.

The recA gene from Streptomyces rimusus encodes a 376-amino acids polypeptide (M(r) 39,702) that is one of the largest bacterial RecA proteins observed. Detailed analyses of the Streptomyces RecA proteins showed that all possess an additional and unique C-terminal, rich in lysines and alanines, which can form an additional terminal alpha helix. Expression of the S. rimosus RecA protein in Escherichia coli FR333 (delta recA306) was demonstrated using antibodies raised against E. coli RecA protein; expression was possible only from the S. rimosus promoter. A Streptomyces-E. coli-like promoter sequence (TTGACA-18bp-TCTTAT) was found in the A+ T-rich region 135-165 base pairs upstream from the initiation codon and was related to Bacillus subtilis DNA damage-inducible promoters.

Direct transfer of plasmid DNA between Streptomyces spp. and E. coli by electroduction.

We describe a simple and reliable method which allows the direct transfer of shuttle plasmids between Streptomyces spp. and E. coli. The method is based on the fact that plasmid DNA molecules can be released or taken up from cells under conditions of electroporation. When a suspension of a plasmid-containing Streptomyces spp. is mixed with electroporation-competent E. coli and submitted to an electric pulse, plasmid DNA transfer to the E. coli recipient takes place. Two different Streptomyces spp. (S. lividans TK23, or TK24 and S. rimosus 554w) were effective donors, and the method was successfully employed to transfer four different bifunctional vectors (pPM801, pFD666, pRL270X and pZG5) varying in size from 5.2-14.4 kb, to E. coli. This provides a convenient method for the analysis of Streptomycete transformants.

Protein tyrosine phosphorylation in streptomycetes.

Using phosphotyrosine-specific antibodies, we demonstrate that in several Streptomyces spp. a variety of proteins are phosphorylated on tyrosine residues. Tyrosine phosphorylation was found in a number of Streptomyces species including Streptomyces lividans, Streptomyces hygroscopicus and Streptomyces lavendulae. Each species exhibited a unique pattern of protein tyrosine phosphorylation. Moreover, the patterns of tyrosine phosphorylation varied during the growth phase and were also influenced by culture conditions. We suggest that metabolic shifts during the complex growth cycle of these filamentous bacteria, and possibly secondary metabolic pathways, may be controlled by the action of protein tyrosine kinases and phosphatases, as has been demonstrated in signal transduction pathways in eukaryotic organisms.

Detection of an A-factor-responsive protein that binds to the upstream activation sequence of strR, a regulatory gene for streptomycin biosynthesis in Streptomyces griseus.

DNA-binding assays using mobility shift polyacrylamide gel electrophoresis revealed the presence of a protein that specifically bound to a restriction fragment -288 to -191 bp upstream from the transcriptional start point of strR, a regulatory gene for streptomycin biosynthesis in Streptomyces griseus. The binding site corresponded to an upstream activation sequence predicted from the results of in vivo promoter assays. The binding was greatly enhanced by 5 mM Mg2+. This binding was detected with the protein source only from the wild-type strain and not from an A-factor-deficient mutant strain. The exogenous supplementation of A-factor to the A-factor-deficient mutant strain caused the appearance of the protein in the DNA-binding assay. A synthetic nucleotide 52 bp in length (region from -293 to -242), which was synthesized on the basis of data obtained from both retardation assays with dissected DNA fragments and in vivo promoter assays, was retarded by the A-factor-dependent protein. In addition to this A-factor-dependent protein, at least three proteins with different recognition site affinities capable of binding to the upstream region of the strR promoter were detected. The binding of one of these proteins to both sides of the upstream activation sequence bound by the A-factor-dependent protein was completely abolished in the presence of ATP and Mg2+ in the incubation mixture. The region bound by these proteins showed anomalous electrophoretic mobility, like that of a bent DNA molecule, which is probably caused by the presence of many blocks consisting of A and T. The region bound by these proteins was found to be transcribed in the orientation opposite to that of strR.

Identification of an A-factor-dependent promoter in the streptomycin biosynthetic gene cluster of Streptomyces griseus.

A-factor (2-isocapryloyl-3R-hydroxymethyl-gamma-butyrolactone) is a microbial hormone controlling streptomycin (Sm) production, Sm resistance and sporulation in Streptomyces griseus. In order to identify A-factor-dependent promoters in the Sm biosynthetic gene cluster, a new promoter-probe plasmid with a low copy number was constructed by using an extremely thermostable malate dehydrogenase gene as the reporter. Of the three promoters in the Sm production region that includes strR, aphD and strB, only the promoter of strR, which codes for a putative regulatory protein, was found to be directly controlled by A-factor. This was also confirmed by S1 nuclease mapping. The region essential for its A-factor-dependence was determined to be located 430-330 base pairs upstream of the transcriptional start point. Increase in the copy number of the strR promoter region did not lead to a corresponding increase in the total promoter activity, probably due to titration of a putative activator which binds to the enhancer-like region and controls the expression of the strR promoter. This putative activator is apparently distinct from the A-factor-receptor protein. The aphD gene, which encodes the major Sm resistance determinant, Sm-6-phosphotransferase, was transcribed mainly by read-through from the A-factor-dependent strR promoter; this accounts for the prompt induction of Sm resistance by A-factor.

Structural instability of a bifunctional plasmid pZG1 and single-stranded DNA formation in Streptomyces.

Structural instability of a hybrid plasmid pZG1, consisting of Escherichia coli pBR322 and Streptomyces pIJ350 plasmids, has been studied in Streptomyces. After transformation of S. lividans 1326 and S. rimsus R6 protoplasts with pZG1, transformants harbored the intact pZG1 and various deleted plasmid forms. The pattern of deleted plasmids varied with the transformant colony age and changed upon subcultivation. The presence of intact pZG1 in at least a part of the Streptomyces colonies indicated that the plasmid was capable of replicating in the transformants and that deletion events occurred after at least one round of replication. Less instability of pZG1 in S. rimosus R6 was observed when this strain was transformed with the DNA isolated from the same strain. pZG1 and its various derivatives were found in S. lividans 1326 and S. rimosus R6 as double- and single-stranded DNA molecules. Structural instability of pZG1 could therefore be due at least in part to the presence of single-stranded DNA.