Wild-type and feedback-resistant phosphoribosyl pyrophosphate synthetases from Bacillus amyloliquefaciens: purification, characterization, and application to increase purine nucleoside production.

Bacillus strains are used for the industrial production of the purine nucleosides inosine and guanosine, which are raw materials for the synthesis of the flavor enhancers disodium inosinate and disodium guanylate. An important precursor of purine nucleosides is 5-phospho-α-D: -ribosyl-1-pyrophosphate, which is synthesized by phosphoribosyl pyrophosphate synthetase (PRS, EC 2.7.6.1). Class I PRSs are widespread in bacteria and mammals, are highly conserved among different organisms, and are negatively regulated by two end products of purine biosynthesis, adenosine 5'-diphosphate (ADP) and guanosine 5'-diphosphate (GDP). The D52H, N114S, and L129I mutations in the human PRS isozyme I (PRS1) have been reported to cause uric acid overproduction and gout due to allosteric deregulation and enzyme superactivity. In this study, to find feedback-resistant Bacillus amyloliquefaciens PRS, the influence of the D58H, N120S, and L135I mutations (corresponding to the D52H, N114S, and L129I mutations in PRS1, respectively) on PRS enzymatic properties has been studied. Recombinant histidine-tagged wild-type PRS and three mutant PRSs were expressed in Escherichia coli, purified, and characterized. The N120S and L135I mutations were found to release the enzyme from ADP and GDP inhibition and significantly increase its sensitivity to inorganic phosphate (P(i)) activation. In contrast, PRS with the D58H mutation exhibited nearly identical sensitivity to ADP and GDP as the wild-type protein and had a notably greater P(i) requirement for activation. The N120S and L135I mutations improved B. amyloliquefaciens and Bacillus subtilis purine nucleoside-producing strains.

Completion of the mapping of transcription start sites for the five-gene block subgenomic RNAs of Beet yellows Closterovirus and identification of putative subgenomic promoters.

In the positive-sense RNA genome of Beet yellows Closterovirus (BYV), the 3'-terminal open reading frames (ORFs) 2-8 are expressed as a nested set of subgenomic (sg) RNAs. ORFs 2-6, coding for the structural and movement proteins, form a 'five-gene block' conserved in closteroviruses. We mapped the 5'-end of the ORF 4 sgRNA, which encodes the p64 protein, at adenosine-11169 in the BYV genome. This completes the mapping of the transcription start sites for the five-gene block sgRNAs of BYV. Computer-assisted analysis of the sequences upstream of BYV ORFs 2, 3, 4, 5, and 6 revealed two conserved motifs, which might constitute the subgenomic promoter elements. These motifs are conserved in the equivalent positions upstream of three orthologous genes of Citrus tristeza Closterovirus and two orthologous genes of Beet yellow stunt Closterovirus.

The yicM (nepI) gene of Escherichia coli encodes a major facilitator superfamily protein involved in efflux of purine ribonucleosides.

The yicM gene of Escherichia coli was found by selection for resistance to 6-mercaptopurine. Translation and transcription initiation sites of yicM were determined. Overexpression of yicM increased resistance of sensitive cells to inosine and guanosine, decreased E. coli growth rate in medium containing these ribonucleosides as the sole carbon source, led to inosine accumulation by the E. coli strain deficient in purine nucleoside phosphorylase and enhanced the rate of inosine excretion by an inosine-producing strain. These results suggest that yicM encodes a purine ribonucleoside exporter and we have accordingly renamed it nepI (for 'nucleoside efflux permease-inosine').

Identification and characterization of the new gene rhtA involved in threonine and homoserine efflux in Escherichia coli.

The rhtA gene known as the ybiF ORF in the genome of Escherichia coli was identified as a new gene involved in threonine and homoserine efflux. This gene encodes a highly hydrophobic membrane protein that contains 10 predicted transmembrane segments. The rhtA23 mutation, which is an A-for-G substitution at position -1 in relation to the ATG start codon, increases the expression level of the rhtA gene. The overexpression of rhtA gene results in resistance to inhibitory concentrations of homoserine, threonine and a variety of other amino acids and amino acid analogues, reduced threonine and homoserine accumulation in resistant cells and increased production of threonine, homoserine, lysine and proline by the respective producing strains. The RhtA protein belongs to a vast family of transporters. The genome of E. coli contains at least 10 paralogues of RhtA. Phylogenetic analysis indicates that a common ancestor of living organisms contained several RhtA homologues.

Ultrastructural localization and epitope mapping of the methyltransferase-like and helicase-like proteins of Beet yellows virus.

Monoclonal antibodies (MAbs) specific to the methyltransferase (MT) and helicase (HEL) domains of the closterovirus Beet yellows virus (BYV) were used for immunogold labelling of ultrathin sections of virus-infected Tetragonia expansa plants. MAbs 4A2 and 4A5 from the MT panel, and 1C4 from the HEL panel, specifically labelled distinct closterovirus-induced membranous structures, the 'BYV-type vesicles', thus suggesting that the closterovirus MT-like and HEL-like proteins co-localize in these structures. Probing of the MT and HEL MAbs with synthetic octapeptides spanning the sequences of the recombinant MT and HEL fragments that had been used as immunogens showed that 4A5 and 4A2 recognized a single epitope, SRLLENET (aa 686-692 in the BYV 1a protein), and 1C4 reacted with the DDPF epitope (aa 2493-2496). These epitopes apparently reside on the exposed parts of the membrane-associated molecules of the closterovirus MT-like and HEL-like proteins. Two other epitopes determined for the MT MAbs that were nonreactive in the immunogold labelling, namely TMVTPGEL (aa 750-757; MAbs 3C5, 4B4 and 4C5) and SREQLVEA (aa 806-813; MAb 2A4), are possibly buried in the MT domain fold or shielded by membranes or other proteins involved in the viral replicative complex.