An 8.9-kb segment with hydrogenase genes from the cyanobacterium Anabaena variabilis has been cloned and sequenced. The sequences show homology to the methyl-viologen-reducing hydrogenases from archaebacteria and, even more striking, to the NAD'-reducing enzymes from Alcaligenes eutrophus and Nocardia opaca as well as to the NADP' -dependent protein from Desulfovibrio fructosovorarzs. The cluster from A. variabilis contains genes coding for both the hydrogenase heterodimer (hoxH and hoxv and for the diaphorase moiety (hoxU and hoxfl described for the A. eurroplius enzyme. In A. variabilis the gene cluster is split by two open reading frames (between hoxY and hoxH and between hoxU and hoxl: respectively), and a probably non-coding 0.9-kb segment in an unusual way. The hoxH partial sequence from Anabaena 71 19 and Anucystis nidulan.7 was amplified by PCR. Using the labeled segment from A. 71 19 as probe, Southern analysis revealed homologous gene segments in the cyanobacteria A. 71 19, Anabaena cylindrica, Arzacystis nidulans and A. variabilis. The bidirectional hydrogenase from A. nidulans was purified and digests were sequenced. The amino acid sequences obtained showed partial identities to the amino acid sequences deduced from the DNA data of the 8.9-kb segment from A. variabilis. Therefore the 8.9-kb segment contains the genes coding for the bidirectional, reversible hydrogenase from cyanobacteria. Crude extracts from A. nidulans perform NAD(P)H-dependent H, evolution corroborating the molecular biological demonstration of the NAD(P)'.-dependent hydrogenase in cyanobacteria.
For the first time, the complete functional gene for isoprene synthase has been isolated from poplar (Populus alba x Populus tremula). The gene was quite similar to known limonene and other monoterpene synthases, but was found to specifically catalyze the formation of isoprene from the precursor dimethylallyl diphosphate with only a marginal activity for the formation of the monoterpene limonene from geranyl diphosphate as compared with limonene synthases. Omitting the part of the gene that putatively encoded the signal peptide necessary for transport into the chloroplast led to an enhanced rate of isoprene formation by the recombinant protein.
The emission rate of the volatile reactive compound isoprene, emitted predominantly by trees, must be known before the level of photo-oxidants produced during summer smog can be predicted reliably. The emission is dependent on plant species and local conditions, and these dependencies must be quantified to be included in any empirical algorithm for the calculation of isoprene production. Experimental measurements of isoprene emission rates are expensive, however, and existing data are scarce and fragmentary. To overcome these difficulties, it is promising to develop a numerical model capable of precisely calculating the isoprene emission by trees for diverse ecosystems, even under changing environmental conditions. A basic processbased biochemical isoprene emission model (BIM) has therefore been developed, which describes the enzymatic reactions in leaf chloroplasts leading to the formation of isoprene under varying environmental conditions (e.g. light intensity, temperature). Concentrations of the precursors of isoprene formation, 3-phosphoglyceric acid and glyceraldehyde 3-phosphate, are provided by a published light fleck photosynthesis model. Specific leaf and enzyme parameters were determined for the pedunculate oak (Quercus robur L.), so that the BIM is capable of calculating oak-specific isoprene emission rates as influenced by the leaf temperature and light intensity. High correlation was observed between isoprene emission rates calculated by the BIM and the diurnal isoprene emission rates of leaves measured under controlled environmental conditions. The BIM was even capable of describing changes in isoprene emission caused by midday depression of net photosynthesis.
The present work aimed to proof the functionality of the non-mevalonate pathway in cyanobacteria. It was intended to isolate the 1-deoxy-D-xylulose 5-phosphate (DXP) reductoisomerase gene (dxr), as this gene encodes the enzyme which catalyzes a pathway-specific, indicative step of this pathway. For this purpose, a segment of dxr was amplified from Synechococcus leopoliensis SAUG 1402-1 DNA via PCR using oligonucleotides for conserved regions. Subsequent hybridization screening of a genomic cosmid library of S. leopoliensis with the PCR segment led to the identification of a 26.5 kbp locus on which a dxr homologous gene and two adjacent open reading frames organized in one operon were localized by DNA sequencing. The functionality of the gene was demonstrated expressing the gene in Escherichia coli and using the purified gene product in a photometrical NADPH dependent test based on the substrate DXP generating system. While the content of one of the central intermediates of the isoprenoid biosynthesis (dimethylallyl diphosphate = DMADP) was significantly (P 9 9 0.001) increased in E. coli cells overexpressing the DXP synthase gene (dxs) of S. leopoliensis, overexpression of dxr does not lead to an elevated DMADP level. Since even in strains harboring an expression fusion of dxs the additional overexpression of dxr does not influence the DMADP content, it is concluded that Dxs but not Dxr catalyzes a rate limiting step of the non-mevalonate isoprenoid biosynthesis. ß
The heterotrophic nitrifier Pseudomonas putida aerobically oxidized ammonia to hydroxylamine, nitrite, and nitrate. Product formation was accompanied by a small but significant release of NO, whereas N2O evolution could not be detected under the assay conditions employed. The isolate reduced nitrate to nitrite and partially further to NO under anaerobic conditions. Aerobically grown cells utilized gamma-aminobutyrate as a carbon source and as a N-source by ammonification. The physiological experiments, in particular the inhibition pattern by C2H2, indicated that P. putida expressed an ammonia monooxigenase. DNA-hybridization with an amoA gene probe coding for the smaller subunit of the ammonia monooxigenase of Nitrosomonas europaea allowed us to identify, to clone, and to sequence a region with an open reading frame showing distinct sequence similarities to the amoA gene of autotrophic ammonia oxidizers.
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