Epimerization of chenodeoxycholic acid to ursodeoxycholic acid by Clostridium baratii isolated from human feces

Several H2-producing fermentative anaerobic bacteria including Clostridium, Klebsiella and Fusobacteria degraded octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine (HMX) (36 microM) to formaldehyde (HCHO) and nitrous oxide (N2O) with rates ranging from 5 to 190 nmol h(-1)g [dry weight] of cells(-1). Among these strains, C. bifermentans strain HAW-1 grew and transformed HMX rapidly with the detection of the two key intermediates the mononitroso product and methylenedinitramine. Its cellular extract alone did not seem to degrade HMX appreciably, but degraded much faster in the presence of H2, NADH or NADPH. The disappearance of HMX was concurrent with the release of nitrite without the formation of the nitroso derivative(s). Results suggest that two types of enzymes were involved in HMX metabolism: one for denitration and the second for reduction to the nitroso derivative(s).     

Efficient somatic gene targeting in the lymphoid human cell line DG75

Among the different approaches used to define the function of a protein of interest, alteration and/or deletion of its encoding gene is the most direct strategy. Homologous recombination between the chromosomal gene locus and an appropriately designed targeting vector results in an alteration or knockout of the gene of interest. Homologous recombination is easily performed in yeast or in murine embryonic stem cells, but is cumbersome in more differentiated and diploid somatic cell lines. Here we describe an efficient method for targeting both alleles of a complex human gene locus in DG75 cells, a cell line of lymphoid origin. The experimental approach included a conditional knockout strategy with three genotypic markers, which greatly facilitated the generation and phenotypic identification of targeted recombinant cells. The vector was designed such that it could be reused for two consecutive rounds of recombination to target both alleles. The human DG75 cell line appears similar to the chicken DT40 pre B-cell line, which supports efficient homologous recombination. Therefore, the DG75 cell line is a favorable addition to the limited number of cell lines amenable to gene targeting and should prove useful for studying gene function through targeted gene alteration or deletion in human somatic cells.     

The innate immunity of a marine red alga involves oxylipins from both the eicosanoid and octadecanoid pathways

The oxygenated derivatives of fatty acids, known as oxylipins, are pivotal signaling molecules in animals and terrestrial plants. In animal systems, eicosanoids regulate cell differentiation, immune responses, and homeostasis. In contrast, terrestrial plants use derivatives of C18 and C16 fatty acids as developmental or defense hormones. Marine algae have emerged early in the evolution of eukaryotes as several distinct phyla, independent from the animal and green-plant lineages. The occurrence of oxylipins of the eicosanoid family is well documented in marine red algae, but their biological roles remain an enigma. Here we address the hypothesis that they are involved with the defense mechanisms of the red alga Chondrus crispus. By investigating its association with a green algal endophyte Acrochaete operculata, which becomes invasive in the diploid generation of this red alga, we showed that (1) when challenged by pathogen extracts, the resistant haploid phase of C. crispus produced both C20 and C18 oxylipins, (2) elicitation with pathogen extracts or methyl jasmonate activated the metabolism of C20 and C18 polyunsaturated fatty acids to generate hydroperoxides and cyclopentenones such as prostaglandins and jasmonates, and (3) C20 and C18 hydroperoxides as well as methyl jasmonate did induce shikimate dehydrogenase and Phe ammonialyase activities in C. crispus and conferred an induced resistance to the diploid phase, while inhibitors of fatty acid oxidation reduced the natural resistance of the haploid generation. The dual nature of oxylipin metabolism in this alga suggests that early eukaryotes featured both animal- (eicosanoids) and plant-like (octadecanoids) oxylipins as essential components of innate immunity mechanisms.     

Characterization and functional identification of a novel plant 4,5-extradiol dioxygenase involved in betalain pigment biosynthesis in Portulaca grandiflora

Betalains are pigments that replace anthocyanins in the majority of families of the plant order Caryophyllales. Betalamic acid is the common chromophore of betalains. The key enzyme of the betalain biosynthetic pathway is an extradiol dioxygenase that opens the cyclic ring of dihydroxy-phenylalanine (DOPA) between carbons 4 and 5, thus producing an unstable seco-DOPA that rearranges nonenzymatically to betalamic acid. A gene for a 4,5-DOPA-dioxygenase has already been isolated from the fungus Amanita muscaria, but no homolog was ever found in plants. To identify the plant gene, we constructed subtractive libraries between different colored phenotypes of isogenic lines of Portulaca grandiflora (Portulacaceae) and between different stages of flower bud formation. Using in silico analysis of differentially expressed cDNAs, we identified a candidate showing strong homology at the level of translated protein with the LigB domain present in several bacterial extradiol 4,5-dioxygenases. The gene was expressed only in colored flower petals. The function of this gene in the betalain biosynthetic pathway was confirmed by biolistic genetic complementation in white petals of P. grandiflora genotypes lacking the gene for color formation. This gene named DODA is the first characterized member of a novel family of plant dioxygenases phylogenetically distinct from Amanita sp. DOPA-dioxygenase. Homologs of DODA are present not only in betalain-producing plants but also, albeit with some changes near the catalytic site, in other angiosperms and in the bryophyte Physcomitrella patens. These homologs are part of a novel conserved plant gene family probably involved in aromatic compound metabolism.     

Influence of the ionic strength on the heat-induced aggregation of the globular protein beta-lactoglobulin at pH 7

The influence of the ionic strength on the structure of beta-lactoglobulin aggregates formed after heating at pH 7 has been studied using static and dynamic light scattering. The native protein depletion has been monitored using size exclusion chromatography. Above a critical association concentration (CAC) well-defined clusters are formed containing about 100 monomers. The CAC increases with decreasing ionic strength. The so-called primary aggregates associate to form self similar semi-flexible aggregates with a large scale structure that is only weakly dependent on the ionic strength. The local density of the aggregates increases with increasing ionic strength. At a critical gel concentration, Cg, the size of the aggregates diverges. Cg decreases from 100 g/l without added salt to 1 g/l at 0.4M NaCl. For C > Cg the system gels except at high ionic strength close to Cg where the gels collapse under gravity and a precipitate is formed.     

AKIN<Emphasis Type="Italic">β</Emphasis>3, a plant specific SnRK1 protein,is lacking domains present in yeast and mammals non-catalytic <Emphasis Type="Italic">β</Emphasis>-subunits

The SNF1/AMPK/SnRK1 heterotrimeric kinase complex is involved in the adaptation of cellular metabolism in response to diverse stresses in yeast, mammals and plants. Following a model proposed in yeast, the kinase targets are likely to bind the complex via the non-catalytic -subunits. These proteins currently identified in yeast, mammals and plants present a common structure with two conserved interacting domains named Kinase Interacting Sequence (KIS) and Association with SNF1 Complex (ASC), and a highly variable N-terminal domain. In this paper we describe the characterisation of AKIN3, a novel protein related to AKIN subunits of Arabidopsis thaliana, containing a truncated KIS domain and no N-terminal extension. Interestingly the missing region of the KIS domain corresponds to the glycogen-binding domain (-GBD) identified in the mammalian AMPK1. In spite of its unusual features, AKIN3 complements the yeast sip1sip2gal83 mutant. Moreover, interactions between AKIN3 and other AKIN complex subunits from A. thaliana were detected by two-hybrid experiments and in vitro binding assays. Taken together these data demonstrate that AKIN3 is a -type subunit. A search for -type subunits revealed the existence of 3-type proteins in other plant species. Furthermore, we suggest that the AKIN3-type subunits could be plant specific since no related sequences have been found in any of the other completely sequenced genomes. These data suggest the existence of novel SnRK1 complexes including AKIN3-type subunits, involved in several functions among which some could be plant specific.     

Isolation of Pea Thioredoxin f Precursor Protein and Characterization of its Biochemical Properties

Like many other soluble chloroplastic enzymes, thioredoxin f is nuclear-encoded and expressed as a precursor protein. After synthesis in the cytosol, it is imported into the chloroplast with subsequent cleavage of the transit sequence in the stroma. We report the expression and the partial purification of the recombinant precursor thioredoxin f protein. The prethioredoxin f was found to be located essentially in the insoluble Echerichia coli fraction, but could be renatured after urea treatment followed by dialysis. The renatured protein was active in the dithiothreitol- and thioredoxin-dependent activation of NADP malate dehydrogenase and also of fructose bisphosphatase and in the ferredoxin-thioredoxin-dependent fructose bisphosphatase activation. These data are discussed in relation with the known properties of mature thioredoxin f.