Siderophore production in Azotobacter vinelandii in response to Fe‐, Mo‐ and V‐limitation

Azotobacter vinelandii is a terrestrial diazotroph well studied for its siderophore production capacity and its role as a model nitrogen fixer. In addition to Fe, A. vinelandii siderophores are used for the acquisition of the nitrogenase co‐factors Mo and V. However, regulation of siderophore production by Mo‐ and V‐limitation has been difficult to confirm and knowledge of the full suite of siderophores synthesized by this organism has only recently become available. Using this new information, we conducted an extensive study of siderophore production in N₂‐fixing A. vinelandii under a variety of trace metal conditions. Our results show that under Fe‐limitation the production of all siderophores increases, while under Mo‐limitation only catechol siderophore production is increased, with the strongest response seen in protochelin. We also find that the newly discovered A. vinelandii siderophore vibrioferrin is almost completely repressed under Mo‐ and V‐limitation. An examination of the potential nitrogen ‘cost’ of siderophore production reveals that investments in siderophore N can represent as much as 35% of fixed N, with substantial differences between cultures using the Mo‐ as opposed to the less efficient V‐nitrogenase.     

Macroinvertebrate community traits and nitrate removal in stream sediments

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Lost in the hybridisation vortex: high-elevation <Emphasis Type="Italic">Senecio hercynicus</Emphasis> (Compositae,Senecioneae) is genetically swamped by its congener <Emphasis Type="Italic">S. ovatus</Emphasis> in the Bavarian Forest National Park (SE Germany)

Hybridisation is an important evolutionary process. The investigation of hybridisation along elevational gradients, with their steep abiotic and biotic clines, provides insight into the adaptation and maintenance of species in adjacent habitats. The rare Senecio hercynicus and its spreading congener S. ovatus are vertically vicariant species that show hybridisation in their range overlaps. In the present study, we used AFLP fingerprinting of 689 individuals from 38 populations to analyse population structure and introgression patterns along four elevational transects (650–1350 m) in the Bavarian Forest National Park, Gemany. Subsequently, we searched for loci putatively under divergent selection that may maintain ‘pure’ species despite hybrid formation by identifying taxon-specific alleles. A maximum-likelihood based hybrid index shows that the overall genetic differentiation among all populations was very low with a vanishingly small number of pure parental individuals. Almost 75% of the investigated individuals were classified as backcrosses towards S. ovatus. The highest S. hercynicus ancestry was found in the uppermost populations of two transects. Further, we found seven taxon-specific alleles being under divergent selection that correlated with climatic variables and deviating from neutral introgression. According to our results, hybridisation of S. ovatus and S. hercynicus has reached an advanced state of genetic swamping and there seems to be no driving force that is strong enough to keep both species as different lineages. Rather, S. ovatus appears to benefit through putatively adaptive introgression.     

Uric Acid Accumulation in an Arabidopsis Urate Oxidase Mutant Impairs Seedling Establishment by Blocking Peroxisome Maintenance

Purine nucleotides can be fully catabolized by plants to recycle nutrients. We have isolated a urate oxidase (uox) mutant of Arabidopsis thaliana that accumulates uric acid in all tissues, especially in the developing embryo. The mutant displays a reduced germination rate and is unable to establish autotrophic growth due to severe inhibition of cotyledon development and nutrient mobilization from the lipid reserves in the cotyledons. The uox mutant phenotype is suppressed in a xanthine dehydrogenase (xdh) uox double mutant, demonstrating that the underlying cause is not the defective purine base catabolism, or the lack of UOX per se, but the elevated uric acid concentration in the embryo. Remarkably, xanthine accumulates to similar levels in the xdh mutant without toxicity. This is paralleled in humans, where hyperuricemia is associated with many diseases whereas xanthinuria is asymptomatic. Searching for the molecular cause of uric acid toxicity, we discovered a local defect of peroxisomes (glyoxysomes) mostly confined to the cotyledons of the mature embryos, which resulted in the accumulation of free fatty acids in dry seeds. The peroxisomal defect explains the developmental phenotypes of the uox mutant, drawing a novel link between uric acid and peroxisome function, which may be relevant beyond plants.     

Cytoplasmic thioredoxin reductase is essential for embryogenesis but dispensable for cardiac development

Two distinct thioredoxin/thioredoxin reductase systems are present in the cytosol and the mitochondria of mammalian cells. Thioredoxins (Txn), the main substrates of thioredoxin reductases (Txnrd), are involved in numerous physiological processes, including cell-cell communication, redox metabolism, proliferation, and apoptosis. To investigate the individual contribution of mitochondrial (Txnrd2) and cytoplasmic (Txnrd1) thioredoxin reductases in vivo, we generated a mouse strain with a conditionally targeted deletion of Txnrd1. We show here that the ubiquitous Cre-mediated inactivation of Txnrd1 leads to early embryonic lethality. Homozygous mutant embryos display severe growth retardation and fail to turn. In accordance with the observed growth impairment in vivo, Txnrd1-deficient embryonic fibroblasts do not proliferate in vitro. In contrast, ex vivo-cultured embryonic Txnrd1-deficient cardiomyocytes are not affected, and mice with a heart-specific inactivation of Txnrd1 develop normally and appear healthy. Our results indicate that Txnrd1 plays an essential role during embryogenesis in most developing tissues except the heart.     

Cisplatin mediates selective downstream hydrolytic cleavage of Met-(Gly)(n)-His segments (n=1,2) in methionine- and histidine-containing peptides: the role of ammine loss trans to the initial Pt-S(Met) anchor in facilitating amide hydrolysis

The pH- and time-dependent reactions of the antitumor drug cisplatin, cis-[PtCl(2)(NH(3))(2)], with the methionine- and histidine-containing pentapeptides Ac-Met-Gly-His-Gly-Gly-OH, Ac-Met-Gly-Gly-His-Gly-OH and Ac-Gly-Met-Gly-His-Gly-OH (Gly=glycyl, Met=L-methionyl, His=L-histidyl) at 313K have been investigated by high performance liquid chromatography, mass spectrometry and nuclear magnetic resonance. Cisplatin mediates a rapid "downstream" hydrolytic cleavage of the Met-Gly amide bond in weakly acid solution (pH < or =5) for all three peptides, leading to release of H-Gly-His-Gly-Gly-OH, H-Gly-Gly-His-Gly-OH and H-Gly-His-Gly-OH, respectively, and formation of kappa(2)S,N(M) chelate complexes of the methionine-containing residuals Ac-Met-OH or Ac-Gly-Met-OH. An alternative reaction pathway affords tridentate kappa(3)S,N(M),N(imidazole) macrochelates of the original pentapeptide following ammine loss. The downstream cleavage pathway is competitive with the likewise cisplatin-mediated upstream cleavage of the Ac-Gly linkage in the pentapeptide Ac-Gly-Met-Gly-His-Gly-OH. This leads to formation of both the kappa(3)S,N(M),N(G1) complex of H-Gly-Met-Gly-His-Gly-OH due to upstream cleavage and the analogous tridentate complex for H-Gly-Met-OH due to initial downstream loss of H-Gly-His-Gly-OH followed by upstream loss of acetic acid. As downstream cleavage is not observed for Ac-(Gly)(2)-Met-(Gly)(2)-OH under similar conditions, it may be concluded that rapid histidine imidazole substitution of the ammine ligand in trans-position to an anchoring methionine S atom must assist hydrolytic cleavage of the Met-Gly amide bond.