Biosynthesis of the corrin macrocycle of coenzyme B12 in Pseudomonas denitrificans.

Studies with cell-free protein preparations from a series of recombinant strains of Pseudomonas denitrificans demonstrated that precorrin-3 is converted into a further trimethylated intermediate, named precorrin-3B, along the pathway to coenzyme B12. It was then shown that the part of the pathway from precorrin-3 (called precorrin-3A hereafter) to precorrin-6x involves three intermediates, precorrin-3B, precorrin-4, and precorrin-5. Precorrin-3B was isolated in its native (reduced) as well as its oxidized (factor-IIIB) states, and precorrin-4 was isolated in its oxidized form only (factor-IV). Both factors were in vitro precursors of precorrin-6x. The synthesis of precorrin-6x from precorrin-3A was shown to be catalyzed by four enzymes, CobG, CobJ, CobM, and CobF, intervening in this order. They were purified to homogeneity. CobG, which converts precorrin-3A to precorrin-3B, was found to be an iron-sulfur protein responsible for the oxidation known to occur between precorrin-3A and precorrin-6x, and CobJ, CobM, and CobF are the C-17, C-11, and C-1 methylases, respectively. The acetate fragment is extruded after precorrin-4 formation. This study combined with our recent structural studies on factor-IV (D. Thibaut, L. Debussche, D. Fréchet, F. Herman, M. Vuilhorgne, and F. Blanche, J. Chem. Soc. Chem. Commun. 1993:513-515, 1993) and precorrin-3B (L. Debussche, D. Thibaut, M. Danzer, F. Debu, D. Fréchet, F. Herman, F. Blanche, and M. Vuilhorgne, J. Chem. Soc. Chem. Commun. 1993:1100-1103, 1993) provides a first step-by-step picture of the sequence of the enzymatic reactions leading to the corrin ring in P. denitrificans.     

In vitro characterization of a plastid terminal oxidase (PTOX).

The plastid terminal oxidase (PTOX) encoded by the Arabidopsis IMMUTANS gene was expressed in Escherichia coli cells and its quinone/oxygen oxidoreductase activity monitored in isolated bacterial membranes using NADH as an electron donor. Specificity for plastoquinone was observed. Neither ubiquinone, duroquinone, phylloquinone nor benzoquinone could substitute for plastoquinone in this assay. However, duroquinol (fully reduced chemically) was an accepted substrate. Iron is also required and cannot be substituted by Cu(2+), Zn(2+) or Mn(2+). This plastoquinol oxidase activity is independent of temperature over the 15-40 degrees C range but increases with pH (from 5.5 to 9.0). Unlike higher plant mitochondrial alternative oxidases, to which PTOX shows sequence similarity (but also differences, especially in a putative quinone binding site and in cysteine conservation), PTOX activity does not appear to be regulated by pyruvate or any other tested sugar, nor by AMP. Its activity decreases, however, with increasing salt (NaCl or KCl) concentration. Various quinone analogues were tested for their inhibitory activity on PTOX. Pyrogallol analogues were found to be inhibitors, especially octyl gallate (I50 = 0.4 microM ) that appears far more potent than propyl gallate or gallic acid. Thus, octyl gallate is a useful inhibitor for future in vivo or in organello studies aimed at studying the roles of PTOX in chlororespiration and as a cofactor for carotenoid biosynthesis.     

A bifunctional protein from Pseudomonas denitrificans carries cobinamide kinase and cobinamide phosphate guanylyltransferase activities.

The two consecutive activities of the cobalamin biosynthetic pathway that catalyze the conversion of cobinamide to cobinamide phosphate (cobinamide kinase) and of cobinamide phosphate to GDP-cobinamide (cobinamide phosphate guanylytransferase) were shown to be carried by the same protein in Pseudomonas denitrificans. This bifunctional protein was purified to homogeneity by high-performance liquid chromatography of extracts of a recombinant strain of this microorganism, and the sequence of the first 10 amino acid residues at the N terminus was determined. Both activities were specific to the coenzyme forms of the corrinoid substrates and exhibited an optimum pH at 8.8. Both ATP and GTP were shown to be in vitro gamma-phosphate donors for cobinamide kinase. However, competition experiments demonstrated that ATP was the preferred substrate, a result that can be explained in terms of the kinetic properties of the enzyme. Labeling experiments established that the phosphate group of cobinamide phosphate is quantitatively retained as the inner phosphate of GDP-cobinamide during the guanylyltransferase reaction. The native protein had an apparent molecular weight of 40,000, as estimated by gel filtration, and consisted of two identical subunits of Mr 20,000, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This protein had an isoelectric point of 5.35 and contained a high-affinity GTP-binding site (Kaff.(GTP) = 0.22 microM). Binding of GTP onto this site resulted in a marked increase of the affinity of cobinamide kinase for cobinamide. This property and other kinetic properties may regulate the enzyme and prevent the accumulation of cobinamide phosphate.     

The final step in the biosynthesis of hydrogenobyrinic acid is catalyzed by the cobH gene product with precorrin-8x as the substrate.

The final enzymatic reaction in the conversion of precorrin-6x to hydrogenobyrinic acid by cell-free protein preparations from Pseudomonas denitrificans was shown to be inhibited by hydrogenobyrinic acid. Use was made of this property to prepare the last biosynthetic precursor of hydrogenobyrinic acid, named precorrin-8x. Double-labeling experiments, mass spectrometry, and UV-visible light spectroscopy studies established that precorrin-8x was at the oxidation level of a corrin and differed from precorrin-6x by two additional methyl groups (presumably at C-5 and C-15) and decarboxylation of the acetic acid side chain at C-12. Precorrin-8x was not a corrin but had the same mass as hydrogenobyrinic acid, thus showing that this latter compound is synthesized from the former by a rearrangement. The enzyme catalyzing this rearrangement was purified 80-fold to homogeneity from a recombinant strain of P. denitrificans, sequenced at its N terminus, and shown to be encoded by the cobH gene. It was identical to the previously described hydrogenobyrinic acid-binding protein (F. Blanche, D. Thibaut, D. Frechet, M. Vuilhorgne, J. Crouzet, B. Cameron, G. Müller, K. Hlineny, U. Traub-Eberhard, and M. Zboron, Angew. Chem. Int. Ed. Engl. 29:884-886, 1990). This enzyme had a Km of 0.91 +/- 0.04 microM and a Vmax of 230 nmol h-1 mg-1 at pH 7.7 and was competitively inhibited by hydrogenobyrinic acid with a Ki of 0.17 +/- 0.01 microM. It is proposed that the cobH gene product is a mutase which transfers the methyl group from C-11 to C-12.     

Purification and characterization of cobyrinic acid a,c-diamide synthase from Pseudomonas denitrificans.

Cobyrinic acid a,c-diamide synthase, which catalyzes the conversion of cobyrinic acid to cobyrinic acid a,c-diamide via the intermediate formation of cobyrinic acid c-monoamide, was purified 155-fold to homogeneity from extracts of a recombinant strain of Pseudomonas denitrificans by high-performance liquid chromatography. The enzyme has an apparent molecular weight of 86,000 and consists of two identical subunits of Mr 45,000, as estimated by gel electrophoresis under denaturing conditions. Stepwise Edman degradation provided the N-terminal sequence of the first 15 amino acids. Glutamine was shown to be the preferred amino group donor (Km = 20.3 microM), but it could be replaced by ammonia (Km = 12 mM). The reaction was ATP dependent and exhibited a broad optimum pH around 7.3. Km values for (CN,aq)cobyrinic acid, (aq)2cobyrinic acid, and (CN,aq)cobyrinic acid c-monoamide were 160, greater than or equal to 250, and 71 microM, respectively. Hydrogenobyrinic acid and hydrogenobyrinic acid c-monoamide were shown to be much better substrates, with Km values of 0.41 and 0.21 microM, respectively.     

Climate‐associated genetic variation in Fagus sylvatica and potential responses to climate change in the French Alps

Local adaptation patterns have been found in many plants and animals, highlighting the genetic heterogeneity of species along their range of distribution. In the next decades, global warming is predicted to induce a change in the selective pressures that drive this adaptive variation, forcing a reshuffling of the underlying adaptive allele distributions. For species with low dispersion capacity and long generation time such as trees, the rapidity of the change could impede the migration of beneficial alleles and lower their capacity to track the changing environment. Identifying the main selective pressures driving the adaptive genetic variation is thus necessary when investigating species capacity to respond to global warming. In this study, we investigate the adaptive landscape of Fagus sylvatica along a gradient of populations in the French Alps. Using a double‐digest restriction‐site‐associated DNA (ddRAD) sequencing approach, we identified 7,000 SNPs from 570 individuals across 36 different sites. A redundancy analysis (RDA)‐derived method allowed us to identify several SNPs that were strongly associated with climatic gradients; moreover, we defined the primary selective gradients along the natural populations of F. sylvatica in the Alps. Strong effects of elevation and humidity, which contrast north‐western and south‐eastern site, were found and were believed to be important drivers of genetic adaptation. Finally, simulations of future genetic landscapes that used these findings allowed identifying populations at risk for F. sylvatica in the Alps, which could be helpful for future management plans.