Tackling pollution by organic farming is capable of increasing fortified foods.

The global pollution stage is poisoning the biosphere and causing global temperatures to rise, necessitating a drastic change in the way man is dealing with nature. One change that may produce many beneficial effects on the biosphere and human health is the use of specific organic farming to produce food in a more integrated way in nature and to increase the capacity of man's own response. Despite many experts' opinion another way to deal with environmental contamination is possible: organic farming, which can increase man's ability to fortify foods. After more than 20 years working under this discipline, Bodegas Dagon is able to achieve the highest stilbenes concentrations (as resveratrol). Versus 14.3 mg/l, "Bodegas Dagón" wines contain resveratrol (HPLC and UV-spectroscopy) up to 1611.73 ± 72.66 mg/l, standing as world's potentially healthiest wine reported to date.

Alternative transcription initiation sites generate two LCA1 Ca2+-ATPase mRNA transcripts in tomato roots.

The tomato LCA1 gene encodes a Ca2+-ATPase and gives rise to two major mRNA transcripts and two distinct protein products of different size in tomato roots. The basis of the transcript size difference was investigated to assess whether the mRNA transcripts encoded distinct protein products. Primer extension and S1 nuclease analysis identified two transcription initiation sites at -72 and -1392 from the start of translation. RNA gel blot analysis of poly(A)+ RNA isolated from phosphate-starved tomato roots using probes designed to domains of the 5'-untranslated region (UTR) or the full-length LCA1 cDNA identified mRNAs of 4.7 and 3.6 kb, corresponding to mRNA originating from transcription initiation sites -1392 and -72, respectively. Screening of a cDNA library derived from phosphate-starved tomato roots yielded three cDNA clones, LCA1A, LCA1B and LCA1C (3.6, 4.5 and 5.1 kb respectively). These cDNAs contain full-length LCA1 mRNA sequence derived from each transcription initiation site, with LCA1C additionally containing an intron of 0.6 kb. Sequence analysis indicated 100% identity between the three size classes of cDNA clones except for the differential 5'-UTR and the unspliced intron. Overall, the results indicate that the two major LCA1 mRNA transcripts are derived by differential transcription initiation and that two of the mRNAs may encode identical protein products, while a third mRNA may correspond to a non-functional truncated protein.

A proposal for nomenclature of aldehyde dehydrogenases in Saccharomyces cerevisiae and characterization of the stress-inducible ALD2 and ALD3 genes.

The complete sequencing of the genome of Saccharomyces cerevisiae indicated that this organism contains five genes encoding aldehyde dehydrogenases. YOR374w and YER073w correspond to the mitochondrial isoforms and we propose as gene names ALD4 and ALD5, respectively. YPL061w has been described as the cytoplasmic constitutive isoform and named ALD6. We characterize here the tandem-repeated ORFs YMR170c and YMR169c as the cytoplasmic stress-inducible isoforms, with gene names ALD2 and ALD3, respectively. The expression of ALD2 and ALD3 is dependent on the general-stress transcription factors Msn2,4 but independent of the HOG MAP kinase pathway. ALD3 is induced by a variety of stresses, including osmotic shock, heat shock, glucose exhaustion, oxidative stress and drugs. ALD2 is only induced by osmotic stress and glucose exhaustion. A double null mutant, ald2 ald3, exhibited unchanged sensitivity to any of the above stresses. The only phenotype detected in this mutant was a reduced growth rate in ethanol medium as compared to the wild type.

The yeast inositol monophosphatase is a lithium- and sodium-sensitive enzyme encoded by a non-essential gene pair.

Inositol monophosphatases (IMPases) are lithium-sensitive enzymes that participate in the inositol cycle of calcium signalling and in inositol biosynthesis. Two open reading frames (YHR046c and YDR287w) with homology to animal and plant IMPases are present in the yeast genome. The two recombinant purified proteins were shown to catalyse inositol-1-phosphate hydrolysis sensitive to lithium and sodium. A double gene disruption had no apparent growth defect and was not auxotroph for inositol. Therefore, lithium effects in yeast cannot be explained by inhibition of IMPases and inositol depletion, as suggested for animal systems. Overexpression of yeast IMPases increased lithium and sodium tolerance and reduced the intracellular accumulation of lithium. This phenotype was blocked by a null mutation in the cation-extrusion ATPase encoded by the ENA1/PMR2A gene, but it was not affected by inositol supplementation. As overexpression of IMPases increased intracellular free Ca2+, it is suggested that yeast IMPases are limiting for the optimal operation of the inositol cycle of calcium signalling, which modulates the Ena1 cation-extrusion ATPase.

A major isoform of the maize plasma membrane H(+)-ATPase: characterization and induction by auxin in coleoptiles.

The plasma membrane (PM) H(+)-ATPase has been proposed to play important transport and regulatory roles in plant physiology, including its participation in auxin-induced acidification in coleoptile segments. This enzyme is encoded by a family of genes differing in tissue distribution, regulation, and expression level. A major expressed isoform of the maize PM H(+)-ATPase (MHA2) has been characterized. RNA gel blot analysis indicated that MHA2 is expressed in all maize organs, with highest levels being in the roots. In situ hybridization of sections from maize seedlings indicated enriched expression of MHA2 in stomatal guard cells, phloem cells, and root epidermal cells. MHA2 mRNA was induced threefold when nonvascular parts of the coleoptile segments were treated with auxin. This induction correlates with auxin-triggered proton extrusion by the same part of the segments. The PM H(+)-ATPase in the vascular bundies does not contribute significantly to auxin-induced acidification, is not regulated by auxin, and masks the auxin effect in extracts of whole coleoptile segments. We conclude that auxin-induced acidification in coleoptile segments most often occurs in the nonvascular tissue and is mediated, at least in part, by increased levels of MHA2.

Tandem transcription termination sites in the dnaN gene of Escherichia coli.

The dnaN gene of Escherichia coli encodes the beta-subunit of DNA polymerase III and maps between the dnaA and recF genes. We demonstrated previously that dnaN and recF constitute a transcriptional unit under control of the dnaN promoters. However, the recF gene has its own promoter region located in the middle of the dnaN structural gene. In this report, we use S1 mapping of mRNAs, transcriptional and translational fusions to the galK and lacZ genes, and in vitro mutagenesis to identify and characterize three tandem transcription termination sites responsible for transcriptional polarity in the dnaN-recF operon. These sites are located in the dnaN gene, downstream from the recF promoter region. Cumulatively, they terminate about 80% of the untranslated transcripts started at the recF promoters. As expected, they do not reduce transcription coming from the dnaN promoters unless dnaN translation was prematurely disrupted by the presence of a nonsense codon. The particular arrangement of regulatory elements (promoters and terminators) in the dnaN-recF region provides an exceptional in vivo system to confirm the latent termination site model of transcriptional polarity. In addition, our results contribute to the understanding of the complex regulation of the dnaA, dnaN, and recF genes. We propose that these three genes constitute an operon and that the terminators described in this work could be used to reduce expression of the distal genes of the operon under circumstances in which the dnaN translation happens to be slowed down.

Positive and negative regulatory elements in the dnaA-dnaN-recF operon of Escherichia coli.

The recF gene of E coli lies within a cluster of genes which play essential roles in DNA replication; the gene order is dnaA dnaN recF gyrB. Each of these genes has its own promoters which, with the exception of dnaA promoters, reside entirely within the translated region of the respective preceding gene. In this report, we analyze the effect of the dnaA and dnaN promoters on recF expression by translational fusions between recF and the lacZ reporter gene. Our results indicate that recF is a distal gene of the dnaA operon, and support the previous proposal that dnaN and recF constitute a transcriptional unit under control of the dnaN promoters. They also suggest that dnaA, dnaN and recF are predominantly expressed from the same mRNA although transcriptional and/or post-transcriptional mechanisms should be specifically involved in lowering expression of the recF gene. Recently, we have localized 3 tandem transcription termination sites in the second half of the dnaN gene, downstream from the recF promoters. Neither of them shows the typical features of simple terminators and apparently they do not work in a minimal system of in vitro transcription. In this report, we present evidence that only one of them is dependent on the Rho protein. Although the operon structure allows coordinate expression of dnaA, dnaN and recF, the presence of internal promoters (the dnaN and recF promoters), which appear to be inducible by DNA damage, and intracistronic terminators, whose activity is inversely proportional to the efficiency of translation, permits expression of individual genes to be independently regulated in response to altered growth conditions.