Jean-Claude Hubert

Arsenite Oxidase aox Genes from a Metal-Resistant β-Proteobacterium

The beta-proteobacterial strain ULPAs1, isolated from an arsenic-contaminated environment, is able to efficiently oxidize arsenite [As(III)] to arsenate [As(V)]. Mutagenesis with a lacZ-based reporter transposon yielded two knockout derivatives deficient in arsenite oxidation. Sequence analysis of the DNA flanking the transposon insertions in the two mutants identified two adjacent open reading frames, named aoxA and aoxB, as well as a putative promoter upstream of the aoxA gene. Reverse transcription-PCR data indicated that these genes are organized in an operonic structure. The proteins encoded by aoxA and aoxB share 64 and 72% identity with the small Rieske subunit and the large subunit of the purified and crystallized arsenite oxidase of Alcaligenes faecalis, respectively (P. J. Ellis, T. Conrads, R. Hille, and P. Kuhn, Structure [Cambridge] 9:125-132, 2001). Importantly, almost all amino acids involved in cofactor interactions in both subunits of the A. faecalis enzyme were conserved in the corresponding sequences of strain ULPAs1. An additional Tat (twin-arginine translocation) signal peptide sequence was detected at the N terminus of the protein encoded by aoxA, strongly suggesting that the Tat pathway is involved in the translocation of the arsenite oxidase to its known periplasmic location.

Oxidation of arsenite to arsenate by a bacterium isolated from an aquatic environment.

Arsenic is ubiquitous in the biosphere and frequently reported to be an environmental pollutant. Global cycling of arsenic is affected by microorganisms. This paper describes a new bacterial strain which is able to efficiently oxidize arsenite (As[III]) into arsenate (As[V]) in liquid medium. The rate of the transformation depends on the cell density. Arsenic species were separated by high performance liquid chromatography (HPLC) and quantified by inductively coupled plasma-atomic emission spectrometry (ICP-AES). The strain also exhibits high minimum inhibitory concentrations (MICs) for As[III] (6.65 mM (500 mg L-1)) and other heavy metals, such as cadmium (1.42 mM (160 mg L-1)) or lead (1.20 mM (250 mg L-1)). Partial identification of the strain revealed a chemoorganotrophic, Gram-negative and motile rod. The results presented here demonstrate that this strain could represent a good candidate for arsenic remediation in heavily polluted sites.

Lactobacillus paraplantarum sp. nov., a new species related to Lactobacillus plantarum

Four strains of facultatively heterofermentative lactobacilli isolated from beer and human feces have physiological characteristics similar to those of Lactobacillus plantarum. Unlike 66% of the L. plantarum strains tested (F. Bringel, M.-C. Curk, and J.-C. Hubert, Int. J. Syst. Bacteriol. 46:588-594, 1996), these strains do not catabolize alpha-methyl-D-mannoside. However, because they exhibit little DNA relatedness to L. plantarum and Lactobacillus pentosus, these four strains were classified as members of a new species, Lactobacillus paraplantarum; strain CNRZ 1885 (= CIP 104668) is the type strain.

Adsorption of several actinide (Th, U) and lanthanide (La, Eu, Yb) ions by Mycobacterium smegmatis

Adsorption measurements of several actinide [thorium (Th), uranium (U)] and lanthanide [lanthanum (La), europium (Eu), ytterbium (Yb)] cations by Mycobacterium smegmatis showed that sorption kinetics followed a three-phase pattern. For 5% (w/w) bacterial suspensions at pH 1, maximum cation biosorption per gram dry biomass corresponded to 170 μmol Th4+ and 187 μmol UOinf2sup2+. Adsorption of all cations studied obeyed the Brunauer-Emmett-Teller isotherm, which assumes multilayer binding at constant energy. Plots for the Scatchard model showed the existence of at least two types of cation complexation site, with strong and weak affinity and negative cooperation. Th4+ was preferentially adsorbed with respect to the other cations, although all species appeared to compete for the same sites independently of bacterial viability. Adsorption of these cations was accompanied by partial release of magnesium from the cell wall, indicating that exchange reactions occurred at magnesium (Mg)-bonding sites.

Apatite genesis: A biologically induced or biologically controlled mineral formation process?

Abstract Apatite formation from organic matter (ribonucleic acid) and calcium carbonate (cuttlebone) requires intervention of microorganisms. We have attempted to characterize this mineral formation process by locating the alkaline phosphatase and the crystals formed. Alkaline phosphatase, which is important for the liberation of the necessary components, was localized in the periplasmic space of Providencia rettgeri in the same manner as in Escherichia coli. Accordingly, the release of inorganic phosphate and the formation of apatite may occur at this site. However, electron microscope observations revealed the presence of extracellular apatite; moreover, apatite particles that were formed with or without bacteria (with alkaline phosphatase from hydrolyzed ribonucleic acid as phosphorus source) were closely similar in size and appearance. The formation of apatite can thus be qualified as biologically induced mineralization. Nevertheless, a bacterial cell can also act as a nucleator for apatite crystalliz...

Characterization of Lactobacilli by Southern-Type Hybridization with a Lactobacillus plantarum pyrDFE Probe

Lactobacillus plantarum, Lactobacillus pentosus, and Lactobacillus paraplantarum (M.-C. Curk, J.-C. Hubert, and F. Bringel, Int. J. Syst. Bacteriol. 46:595-598, 1996) can hardly be distinguished on the basis of their phenotypes. Unlike L. plantarum and L. paraplantarum, L. pentosus ferments glycerol and xylose but not melezitose. We identified two L. pentosus strains (CNRZ 1538 and CNRZ 1544) which ferment glycerol and melezitose but not xylose. alpha-Methyl-D-mannoside was fermented by 66% of the L. plantarum strains tested but not by L. paraplantarum strains. In this paper we describe a simple method to identify L. plantarum, L. pentosus, and L. paraplantarum. This method is based on nonradioactive Southern-type hybridization between BglI DNA digests of the lactobacilli tested and a DNA probe (L. plantarum pyrDFE genes from strain CCM 1904). A total of 68 lactobacilli were classified into five groups on the basis of the bands detected. Two groups contained L. plantarum strains; one of these groups contained 31 strains, including the type strain, and was characterized by bands at 7, 4, and 1 kb, and the other group contained strain LP 85-2 and was characterized by bands at 5 and 1.1 kb. Only one band (a band at around 7 kb) was detected in the strains belonging to the L. pentosus group, and two bands (at 4 and 1 kb) were found in the strains belonging to the L. paraplantarum group. No hybridization was detected in the last group, which contained Lactobacillus casei, Lactobacillus coryniformis, Lactobacillus paracasei, Lactobacillus brevis, Lactobacillus delbrueckii, and Lactobacillus leichmannii strains.

Optimized transformation by electroporation ofLactobacillus plantarum strains with plasmid vectors

SummaryWhole cell transformation ofLactobacillus plantarum CCM 1904 by electroporation was optimized. Pulse duration and electric field strength were shown to be important parameters: the optimum conditions were 12.5 kV/cm, a time-constant of 10 ms for an exponential decay waveform and 6.7 kV/cm applied during 2.5 ms for a square waveform. Transformation efficiency was increased if cells were cultivated on medium containing sorbitol and harvested during their early exponential growth phase: 8 × 10−4 transformants/μg pGK12 DNA per viable cell were obtained, with a survival rate of 10%–30% Cryotreatment by several freeze-and-thaw cycles decreased transformant yields. Transformation efficiency with different plasmids was studied and plasmid pGK12 was found to transformL. plantarum the most efficiently. Transformation by electroporation ofL. plantarum is strain dependent. The best results were obtained withL. plantarum NCIB 7220, giving 5 × 106 transformants/gmg plasmid pGK12 DNA.

Characterization, cloning, curing, and distribution in lactic acid bacteria of pLP1, a plasmid from Lactobacillus plantarum CCM 1904 and its use in shuttle vector construction.

A small 2.1-kb plasmid called pLP1 was extracted from Lactobacillus plantarum CCM 1904 (ATCC 8014) and cloned into the Escherichia coli pUC19 plasmid. As determined by DNA-DNA Southern hybridization with a pLP1-radioactively labeled probe, other lactic acid bacteria such as L. curvatus, L. sake, Carnobacterium, and Leuconostoc mesenteroides harbor pLP1-related plasmids. Shuttle vectors based on the pLP1 replicon were constructed by inserting the erythromycin-resistance gene from pVA891 into the various pUC19-pLP1 constructions. pLP1-based shuttle vector transformation efficiencies (TE) by electroporation were compared to TE of a broad-host-range plasmid pGK12 in different lactobacilli strains. Expression of the pUC19-pLP1 plasmids in Escherichia coli maxicells showed that pLP1 encodes for a 37,000 MW protein which can act in trans allowing the replication of plasmids in which this protein is truncated. The pLP1-based shuttle vectors producing this protein replicate in lactobacilli and also in Bacillus subtilis. A pLP1-free strain was obtained by incompatibility with a pLP1-based shuttle vector introduced in L. plantarum CCM 1904 by electroporation. The absence of pLP1 has no incidence on the strain phenotype suggesting that pLP1 is not essential for the strain in our laboratory conditions.

Structure of the Saccharomyces cerevisiae URA4 gene encoding dihydroorotase

SummaryThe URA4 gene of Saccharomyces cerevisiae, coding for the third enzyme of the pyrimidine pathway, has been cloned through phenotypic complementation of a ura4 mutant of S. cerevisiae. Subcloning of an original 9 kb DNA fragment, carrying the yeast URA4 gene, allowed us to localize the gene on a 2 kb ClaI-BamHI fragment. The sequence of the URA4 structural gene and surrounding DNA was determined by the dideoxynucleotide chain termination method. The URA4 gene encodes a dihydroorotase subunit of calculated molecular weight 40600. S1 nuclease mapping indicated that transcription of URA4 is initiated at four major start sites located at positions-42,-30,-22 and-18. A set of potentially significant sequences was identified in the 5′ OH non-coding region of the gene. The deduced amino acid sequence of dihydroorotase was examined and compared with homologous amino acid sequences of Salmonella typhimurium, Escherichia coli and Drosophila melanogaster. S. cerevisiae dihydroorotase shows 40% homology with the S. typhimurium and E. coli enzymes and 23% homology with the D. melanogaster enzyme. A potential active site has been predicted for dihydroorotase from these comparisons.

Cloning and restriction mapping of the yeastURA2 gene coding for the carbamyl phosphate synthetase aspartate-transcarbamylase complex

SummaryTwo yeast DNA pools inserted in an hybridEscherichia coli-yeast vector pFL1 were used to transformE. coli and yeast aspartate-transcarbamylase-less strains to prototrophy. From the first pool — aBamHI yeast DNA digest — a 6.4 kbBamHI fragment was recovered that gave good complementation of theE. coli auxotrophy but poor complementation of the yeast auxotrophy. From the second pool — a partialSau3A yeast DNA digest — five independent plasmids complementing eitherE. coli, yeast, or both were recovered. Each of the five plasmids possessed sequences in common with the 6.4 kbBamHI fragment. One of these plasmids, which complemented the twoURA2 activities in yeast and which produced a carbamyl-phosphate synthetase, aspartate-transcarbamylase complex sensitive to UTP feedback inhibition contained the fullURA2 gene. A restriction map of theURA2 gene has been constructed and seven different consecutive segments have been recloned in pBR322 to measure their hybridization withURA2 messenger RNA, allowing us to estimate the limits of the gene.