Inorganic Polyphosphate and Physiological Properties of Saccharomyces cerevisiae Yeast Overexpressing Ppn2.

The effect of the yeast endopolyphosphatase Ppn2 overproduction on the metabolism of inorganic polyphosphates in Saccharomyces cerevisiae yeast was studied. Expression of the PPN2 gene under control of the strong constitutive promoter of glyceraldehyde 3-phosphate dehydrogenase gene (PKG1) led to a significant increase in the endopolyphosphatase activity stimulated by cobalt/zinc ions. This activity was present in both soluble and membrane subcellular fractions; it was higher toward long-chain polyphosphates and could be stimulated by ADP. The content of short-chain polyphosphates in the cells of the overexpressing strain was ~2.5 times higher compared to the parent strain. The cells overexpressing Ppn2 were more resistant to peroxide and alkali. The role of short-chain polyphosphates in the adaptation to these stress factors is discussed.

[L-asparaginases of extremophilic microorganisms in biomedicine]. / L-asparaginazy ékstremofil'nykh mikroorganizmov v biomeditsine.

L-asparaginase is extensively used in the treatment of acute lymphoblastic leukemia and several other lymphoproliferative diseases. In addition to its biomedical application, L-asparaginase is also of prospective use in food industry to reduce the formation of acrylamide, which is classified as probably neurotoxic and carcinogenic to human, and in biosensors for determination of L-asparagine level in medicine and food chemistry. The importance of L-asparaginases in different fields, disadvantages of commercial ferments, and the fact that they are widespread in nature stimuli the search for biobetter L-asparaginases from new producing microorganisms. In this regard, extremofile microorganisms exhibit unique physiological properties such as thermal stability, adaptability to extreme cold conditions, salt and pH tolerance and so provide one of the most valuable sources for novel L-asparaginases. The present review summarizes the recent results on studying the structural, functional, physicochemical and kinetic properties, stability of extremophilic L-asparaginases in comparison with their mesophilic homologues.

S-glutathionylation of human glyceraldehyde-3-phosphate dehydrogenase and possible role of Cys152-Cys156 disulfide bridge in the active site of the protein.

BACKGROUND: We previously showed that glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is S-glutathionylated in the presence of H2O2 and GSH. S-glutathionylation was shown to result in the formation of a disulfide bridge in the active site of the protein. In the present work, the possible biological significance of the disulfide bridge was investigated. METHODS: Human recombinant GAPDH with the mutation C156S (hGAPDH_C156S) was obtained to prevent the formation of the disulfide bridge. Properties of S-glutathionylated hGAPDH_C156S were studied in comparison with those of the wild-type protein hGAPDH. RESULTS: S-glutathionylation of hGAPDH and hGAPDH_C156S results in the reversible inactivation of the proteins. In both cases, the modification results in corresponding mixed disulfides between the catalytic Cys152 and GSH. In the case of hGAPDH, the mixed disulfide breaks down yielding Cys152-Cys156 disulfide bridge in the active site. In hGAPDH_C156S, the mixed disulfide is stable. Differential scanning calorimetry method showed that S-glutathionylation leads to destabilization of hGAPDH molecule, but does not affect significantly hGAPDH_C156S. Reactivation of S-glutathionylated hGAPDH in the presence of GSH and glutaredoxin 1 is approximately two-fold more efficient compared to that of hGAPDH_C156S. CONCLUSIONS: S-glutathionylation induces the formation of Cys152-Cys156 disulfide bond in the active site of hGAPDH, which results in structural changes of the protein molecule. Cys156 is important for reactivation of S-glutathionylated GAPDH by glutaredoxin 1. GENERAL SIGNIFICANCE: The described mechanism may be important for interaction between GAPDH and other proteins and ligands, involved in cell signaling.

Isolation of recombinant human untagged glyceraldehyde-3-phosphate dehydrogenase from E. coli producer strain.

The goal of the present work was expression of human glyceraldehyde-3-phosphate dehydrogenase (hGAPDH) without additional tag constructions in E. coli cells and elaboration of the procedure for purification of untagged hGAPDH from the extract of the producer cells. We present a simple method for purification of untagged hGAPDH including ammonium sulfate fractionation and gel filtration on a G-100 Sephadex column. The method allows isolation of 2 mg of pure hGAPDH from 600 ml of cell culture (7 g of the cell biomass). The specific activity of the freshly purified hGAPDH constitutes 117 ± 5 µmol NADH/min per mg protein (pH 9.0, 22 °C), which is close to the specific activity of rabbit muscle glyceraldehyde-3-phosphate dehydrogenase determined under the same conditions and several times exceeds the specific activity of his-tagged GAPDH preparations. The high enzymatic activity suggests that the recombinant enzyme retains its native structure. The described procedure may be useful for researchers who need a preparation of native hGAPDH without admixture of misfolded forms for their investigations.

[Suppression of telomerase activity leukemic cells by mutant forms of Rhodospirillum rubrum L-asparaginase]. / Podavlenie aktivnosti telomerazy leikoznykh kletok mutantymi formami L-asparaginazy Rhodospirillum rubrum.

The active and stable mutant forms of short chain cytoplasmic L-asparaginase type I of Rhodospirillum rubrum (RrA): RrA+N17, D60K, F61L, RrA+N17, A64V, E67K, RrA+N17, E149R, V150P, RrAE149R, V150P and RrAE149R, V150P, F151T were obtained by the method of site-directed mutagenesis. It is established that variants RrA-N17, E149R, V150P, F151T and RrАE149R, V150P are capable to reduce an expression hTERT subunit of telomerase and, hence, activity of telomeres in Jurkat cells, but not in cellular lysates. During too time, L-asparaginases of Escherichia coli, Erwinia carotovora and Wolinella succinogenes, mutant forms RrА+N17, D60K, F61L and RrА+N17, A64V, E67K do not suppress of telomerase activity. The assumption of existence in structure RrA of areas (amino acids residues in the position 146-164, 1-17, 60-67) which are responsible for suppression of telomerase activity is made. The received results show that antineoplastic activity of some variants RrA is connected both with reduction of concentration of free L-asparagine, and with expression suppression of hTERT telomerase subunit, that opens new prospects for antineoplastic therapy.

Genomics and Biochemistry of Saccharomyces cerevisiae Wine Yeast Strains.

Saccharomyces yeasts have been used for millennia for the production of beer, wine, bread, and other fermented products. Long-term "unconscious" selection and domestication led to the selection of hundreds of strains with desired production traits having significant phenotypic and genetic differences from their wild ancestors. This review summarizes the results of recent research in deciphering the genomes of wine Saccharomyces strains, the use of comparative genomics methods to study the mechanisms of yeast genome evolution under conditions of artificial selection, and the use of genomic and postgenomic approaches to identify the molecular nature of the important characteristics of commercial wine strains of Saccharomyces. Succinctly, data concerning metagenomics of microbial communities of grapes and wine and the dynamics of yeast and bacterial flora in the course of winemaking is provided. A separate section is devoted to an overview of the physiological, genetic, and biochemical features of sherry yeast strains used to produce biologically aged wines. The goal of the review is to convince the reader of the efficacy of new genomic and postgenomic technologies as tools for developing strategies for targeted selection and creation of new strains using "classical" and modern techniques for improving winemaking technology.

Polyphosphates and Polyphosphatase Activity in the Yeast Saccharomyces cerevisiae during Overexpression of the DDP1 Gene.

The effects of overexpression of yeast diphosphoinositol polyphosphate phosphohydrolase (DDP1) having endopolyphosphatase activity on inorganic polyphosphate metabolism in Saccharomyces cerevisiae were studied. The endopolyphosphatase activity in the transformed strain significantly increased compared to the parent strain. This activity was observed with polyphosphates of different chain length, being suppressed by 2 mM tripolyphosphate or ATP. The content of acid-soluble and acid-insoluble polyphosphates under DDP1 overexpression decreased by 9 and 28%, respectively. The average chain length of salt-soluble and alkali-soluble fractions did not change in the overexpressing strain, and that of acid-soluble polyphosphate increased under phosphate excess. At the initial stage of polyphosphate recovery after phosphorus starvation, the chain length of the acid-soluble fraction in transformed cells was lower compared to the recipient strain. This observation suggests the complex nature of DDP1 involvement in the regulation of polyphosphate content and chain length in yeasts.

[Recombinant cephalosporin-acid synthesase: optimisation of expression in E.coli cells, immobilisation and application for biocatalytic cefazolin synthesis].

Cephalosporin acid synthetase (CASA) is responsible for specific to synthesis of cephalosporin-acids, its expression in Escherichia coli cells is accompanied by accumulation of unprocessed insoluble precursor. In order to optimize conditions of recombinant CASA production we have studied the effects of several parameters of strain cultivation, including growth media composition, temperature, and inoculation dose. Also plasmids for production of CASA variants with the signal sequence of Erwinia carotovora L-asparaginase (ansCASA) and "leaderless" CASA were created in search of more efficient expression constructs. Removal of the N-terminal secretion signal sequence reduced the production of functionally active CASA more than 10-fold and inhibited strain growth. Insertion of the L-asparaginase signal sequence increased the specific enzyme activity in the resultant recombinant strain. The ansCASA producing strain was used to develop the method of immobilization of the recombinant enzyme on an epoxy-activated macroporous acrylic support. The resultant biocatalyst performed effective synthesis of cefazolin from 3-[(5-methyl-1,3,4-thiadiazol-2-il)-thiomethyl]-7- aminocephalosporanic acid (MMTD-7-ACA) and methyl ester of 1(H)-tetrazolilacetic acid (МETzAA), under mild conditions a transformation level of MMTD-7-ACA to cefazolin of 95% is reached.

[Cephalosporin-Acid Synthetase of Escherichia coli Strain VKPM B-10182: Genomic Context, Gene Identification, Producer Strain Production].

An enzyme of cephalosporin-acid synthetase produced by the E. coli strain VKPM B-10182 has specificity for the synthesis of ß-lactam antibiotics of the cephalosporin acids class (cefazolin, cefalotin, cefezole etc.). A comparison of the previously determined genomic sequence of E. coli VKPM B-10182 with a genome of the parent E. coli strain ATCC 9637 was performed. Multiple mutations indicating the long selection history of the strain were detected, including mutations in the genes of RNase and ß-lactamases that could enhance the level of enzyme synthesis and reduce the degree of degradation of the synthesized cephalosporin acids. The CASA gene--a direct homolog of the penicillin G-acylase gene--was identified by bioinformatics methods. The homology of the gene was confirmed by gene cloning and the expression and determination of its enzymatic activity in the reaction of cefazolin synthesis. The CASA gene was isolated and cloned into the original expression vector, resulting in an effective E. coli BL2l(DE3) pMD0107 strain producing CASA.

[Bacterial recombinant L-asparaginases: properties, structure and anti-proliferative activity].

For more than 40 years L-asparaginases are used in combined therapy of acute lymphoblastic leukemia in children and the range of tumors sensitive to these enzymes constantly extends. This review summarizes results of studies aimed at creation of new systems for heterological expression of bacterial L-asparaginases as Erwinia carotovora (EwA), Helicobacter pylori (HpA), Yersinia pseudotuberculosis (YpA) and Rhodospirillum rubrum (RrA); special attention is paid to isolation of purified enzymes and their crystallization, modification by chitosan/polyethylene, physicochemical, kinetic and structural properties characterization, and the study of the cytotoxic or anti-proliferative activity of new recombinant L-asparaginases on cell cultures in vitro. The resultant recombinant L-asparaginases (EwA, YpA, HpA и RrA) exhibit reasonable cytotoxic action on the human leukemia cells comparable to the pharmacologically available L-asparaginase EcA and represent practical interest in respect to creation, on their basis, new effective antineoplastic remedies. Further prospects of researches on bacterial L-asparaginases are associated with development of analogs of Rhodospirillum rubrum L-asparaginase (RrA) by means of directed changes of the protein structure using genetic engineering, development of chito-PEGylation for receiving L-asparaginase preparations with improved pharmacokinetic characteristics.

PPX1 gene overexpression has no influence on polyphosphates in Saccharomyces cerevisiae.

The role of exopolyphosphatase PPX1 in polyphosphate metabolism in yeasts has been studied in strains of Saccharomyces cerevisiae with inactivated PPX1 and PPN1 genes transformed by the expression vector carrying the yeast PPX1 gene. Exopolyphosphatase activity in transformant strains increased 90- and 40-fold compared to the ΔPPX1 and ΔPPN1 strains, respectively. The purified recombinant exopolyphosphatase PPX1 was similar to the PPX1 of wild strains in its substrate specificity and requirement for divalent metal cations. It was more active with tripolyphosphate and low molecular mass polyphosphates than with high molecular mass polyphosphates and required Mg2+ for its activity. The high level of recombinant PPX1 expression caused no decrease in polyphosphate content in the cells of the transformant. This fact suggests the restricted role of PPX1 in polyphosphate metabolism in yeasts.

Comparative gene expression profiling reveals key changes in expression levels of cephalosporin C biosynthesis and transport genes between low and high-producing strains of Acremonium chrysogenum.

Transcript levels of several key genes responsible for cephalosporin C (CPC) biosynthesis and transport have been determined using qPCR analysis of Acremonium chrysogenum strains differing more than 100-fold in the levels of CPC production. The expression of genes involved in the final steps of CPC production was significantly increased in the high-producing RNCM F-4081D strain compared to the wild-type ATCC 11550 strain. Different dynamics in the course of cultivation was observed for the genes known to be involved in the transport of CPC intermediates between subcellular compartments. Overall, comparative expression analysis showed balanced and fine-tuned expression of the genes responsible for CPC biosynthesis and transport in the genetically selected A. chrysogenum RNCM F-4081D strain, reflecting its capacity to overcome known CPC biosynthesis "bottlenecks" and produce CPC of high yield and purity.

Polyphosphates and exopolyphosphatase activities in the yeast Saccharomyces cerevisiae under overexpression of homologous and heterologous PPN1 genes.

The role of exopolyphosphatase PPN1 in polyphosphate metabolism in fungi has been studied in strains of Saccharomyces cerevisiae transformed by the yeast PPN1 gene and its ortholog of the fungus Acremonium chrysogenum producing cephalosporin C. The PPN1 genes were expressed under a strong constitutive promoter of the gene of glycerol aldehyde-triphosphate dehydrogenase of S. cerevisiae in the vector pMB1. The yeast strain with inactivated PPN1 gene was transformed by the above vectors containing the PPN1 genes of S. cerevisiae and A. chrysogenum. Exopolyphosphatase activity in the transformant with the yeast PPN1 increased 28- and 11-fold compared to the mutant and parent PPN1 strains. The amount of polyphosphate in this transformant decreased threefold. Neither the increase in exopolyphosphatase activity nor the decrease in polyphosphate content was observed in the transformant with the orthologous PPN1 gene of A. chrysogenum, suggesting the absence of the active form of PPN1 in this transformant.

Foot and mouth disease virus polyepitope protein produced in bacteria and plants induces protective immunity in guinea pigs.

The goal of this project was to develop an alternative foot and mouth disease (FMD) vaccine candidate based on a recombinant protein consisting of efficient viral epitopes. A recombinant gene was designed that encodes B-cell epitopes of proteins VP1 and VP4 and T-cell epitopes of proteins 2C and 3D. The polyepitope protein (H-PE) was produced in E. coli bacteria or in N. benthamiana plants using a phytovirus expression system. The methods of extraction and purification of H-PE proteins from bacteria and plants were developed. Immunization of guinea pigs with the purified H-PE proteins induced an efficient immune response against foot and mouth disease virus (FMDV) serotype O/Taiwan/99 and protection against the disease. The polyepitope protein H-PE can be used as a basis for developing a new recombinant vaccine against FMD.

Purification and immobilization of recombinant variants of Brevundimonas diminuta glutaryl-7-aminocephalosporanic acid acylase expressed in Escherichia coli cells.

Modified chitin-binding domain (ChBD) from Bacillus circulans chitinase A1 with W42F mutation in chitin-binding site was genetically fused to different positions within alpha-subunit of glutaryl-7-aminocephalosporanic acid acylase (GLA) gene. Hybrid proteins were efficiently expressed in E. coli cells as soluble, enzymatically active and correctly processed holoenzymes. ChBD-GLA fusions were easily affinity purified on chitin column by changing the salt concentration of binding and elution buffer. The developed one-step affinity purification procedure is thus a promising approach for scaled-up isolation of GLA variants for preparation of industrial biocatalysts as well as for structure-functional studies.

The use of viral vectors to produce hepatitis B virus core particles in plants.

The expression and assembly of the hepatitis B virus (HBV) nucleocapsid protein (HBcAg) were investigated in plants using viral vectors. Constructs based on either Potato virus X (PVX) or Cowpea mosaic virus (CPMV) containing the sequence of HBcAg were able to infect the appropriate host plants and remained genetically stable during infection. Analysis of HBcAg expression revealed that the protein can self-assemble into core-like particles and that the assembled material could be partially purified by differential centrifugation. Thus, the use of viral vectors can be considered a practical method for rapid production of assembled HBcAg particles in plants. This approach provides a means whereby a variety of chimaeric particles can be assessed quickly and cheaply for various diagnostic and vaccine applications.

Isolation and characterization of CspBI, a novel NotI isoschizomer from Corynebacterium species B recognizing 5'-GC/GGCCGC-3'.

Sixty-seven bacterial strains were surveyed for the presence of type II restriction endonucleases, especially concerning super-rare-cutting enzymes. Fourteen strains were found to contain specific enzymes. One of them CspBI from Corynebacterium species B was purified and characterized as an isoschizomer of NotI, which recognizes the palindromic octanucleotide sequence 5'-GC/GGCCGC-3' and cleaves at the position shown by the arrow. A comparison between the cleavage patterns on different DNAs, obtained with partially purified endonucleases from other detected producents including some strains of Corynebacterium, Cellulomonas and Rhizobium has shown that these enzymes do not belong to super-rare-cutting restriction endonucleases.

An optical biosensor study of the interaction parameters and role of hydrophobic tails of cytochrome P450 2B4, b5 and NADPH-flavoprotein in complex formation.

The real-time interactions of membrane proteins - cytochrome P450 2B4, NADPH cytochrome P450 reductase and cytochrome b5 - were studied by use of an optical biosensor system. The association and dissociation rate constants for the individual complexes were measured and the affinities of the redox partners for each other were estimated. The association rate constants of these complexes were found to be close to the diffusion limit and their dissociation rate constants were in the order of 1s-1. A dominant role of the interaction of the membraneous hydrophobic fragments in the formation of productive electron transferring complexes between the proteins was demonstrated.

Host cell properties and external pH affect proinsulin production by Saccharomyces yeast.

The expression of a hybrid gene encoding an alpha-factor prepro leader peptide-miniproinsulin (MPI) fusion [MPI is the same as the LysArg human insulin precursor described by Thim et al. (1986)] was tested in a series of isogenic yeast strains to investigate the influence of some genetic and physiological factors on heterologous production in yeast. We found that: (i) an MF alpha 1 gene disruption in haploid cells, as well as MF alpha 1 gene product expression in diploid cells, do not affect the MPI secretion level; (ii) under conditions of exogenous leucine availability, MPI production is hindered by leucine auxotrophy (a leu2 mutation); (iii) rho- mutations increase the per-cell MPI yield approximately three-fold; (iv) the MPI yield is apparently dependent on the pH of the culture medium: the higher the external pH, the larger the per-cell MPI yield.

Hybrid hepatitis B virus nucleocapsid bearing an immunodominant region from hepatitis B virus surface antigen.

A hepatitis B core antigen (HBcAg) gene bearing the 39-amino-acid-long domain A of hepatitis B surface antigen (HBsAg) within the HBcAg immunodominant loop has been constructed and expressed in Escherichia coli. Chimeric capsids demonstrated HBs but not HBc antigenicity and elicited in mice B-cell and T-cell responses against native HBcAg and HBsAg.