Quantification of the 16S-23S rRNA internal transcribed spacers of Burkholderia xenovorans strain LB400 using real-time PCR in soil samples.

This study establishes a new real-time PCR assay (using SYBR Green™ detection) for the identification and the direct quantification of specific individual Burkholderia xenovorans strain LB400 from DNA samples of soil and sediment. Specific primers were designed to amplify a 190-bp fragment of the 16S-23S rRNA internal transcribed spacers (ITS) from LB400. The specificity of primers was evaluated using 21 strains. The detection limit of the real-time PCR was analysed on soil samples inoculated with LB400 and was of 6 copies (10(5)  CFU g(-1) of dry sample). The 16S-23S rRNA ITS primers developed in this work for rapid quantification of LB400 were validated. The assay allowed the quantification of LB400 as pure strain and among the indigenous microbial community in samples of soil and sediment (105-day experiment).

Decontamination of a polychlorinated biphenyls-contaminated soil by phytoremediation-assisted bioaugmentation.

A 70 day pot experiment was conducted for the cleaning-up of a PCBs-contaminated soil (104 mg kg(-1) soil DW) using bioaugmentation with Burkholderia xenovorans LB400 (LB400) assisted or not by the use of tall fescue (Festuca arundinacea). The total cultivable bacteria of the soil were higher with the presence of plants. Real-time PCR showed that LB400 (targeting 16S-23S rRNA ITS) survived with abundance related to total bacteria (targeting 16S rRNA) being higher with fescue (up to a factor of three). Bioaugmentation had a positive effect on fescue biomass and more specifically on roots (by a factor of three). PCB dissipation (sum of congeners 28, 52, 101, 118, 153, 180) averaged 13 % (bioaugmented-planted) up to 32 % (non bioaugmented-planted), without any significant difference between treatments. Basically our results demonstrated that indigenous bacteria were able to dissipate PCBs (26.2 % dissipation). PCB dissipation was not related to the abundance of LB400 or to the total bacterial counts. Bioaugmentation or fescue altered the structure of the bacterial community of the soil, not the combination of both. Principal component analysis showed that bioaugmentation tended to improve the control of the process (lower variability in PCB dissipation). Opposite to that bioaugmentation increased the variability of the structure of the bacterial community.

Activation of two different resistance mechanisms in Saccharomyces cerevisiae upon exposure to octanoic and decanoic acids.

Medium-chain fatty acids (octanoic and decanoic acids) are well known as fermentation inhibitors. During must fermentation, the toxicity of these fatty acids is enhanced by ethanol and low pH, which favors their entrance in the cell, resulting in a decrease of internal pH. We present here the characterization of the mechanisms involved in the establishment of the resistance to these fatty acids. The analysis of the transcriptome response to the exposure to octanoic and decanoic acids revealed that two partially overlapping mechanisms are activated; both responses share many genes with an oxidative stress response, but some key genes were activated differentially. The transcriptome response to octanoic acid stress can be described mainly as a weak acid response, and it involves Pdr12p as the main transporter. The phenotypic analysis of knocked-out strains confirmed the role of the Pdr12p transporter under the control of WAR1 but also revealed the involvement of the Tpo1p major facilitator superfamily proteins (MFS) transporter in octanoic acid expulsion. In contrast, the resistance to decanoic acid is composite. It also involves the transporter Tpo1p and includes the activation of several genes of the beta-oxidation pathway and ethyl ester synthesis. Indeed, the induction of FAA1 and EEB1, coding for a long-chain fatty acyl coenzyme A synthetase and an alcohol acyltransferase, respectively, suggests a detoxification pathway through the production of decanoate ethyl ester. These results are confirmed by the sensitivity of strains bearing deletions for the transcription factors encoded by PDR1, STB5, OAF1, and PIP2 genes.

Molecular typing of wine yeast strains Saccharomyces bayanus var. uvarum using microsatellite markers.

The Saccharomyces bayanus var. uvarum yeasts are associated with spontaneous fermentation of must. Some strains were shown to be enological yeasts of interest in different winemaking processes. The molecular typing of S. bayanus var. uvarum at the strain level has become significant for wine microbiologists. Four microsatellite loci were defined from the exploration of genomic DNA sequence of S. bayanus var. uvarum. The 40 strains studied were homozygote for the locus considered. The discriminating capacity of the microsatellite method was found to be equal to that of karyotypes analysis. Links between 37 indigenous strains with the same geographic origin could be established through the analysis of microsatellite patterns. The analysis of microsatellite polymorphism is a reliable method for wine S. bayanus var. uvarum strains and their hybrids with Saccharomyces cerevisiae identification in taxonomic, ecological studies and winemaking applications.

Allosteric regulation of carbamoylphosphate synthetase-aspartate transcarbamylase multifunctional protein of Saccharomyces cerevisiae: selection, mapping and identification of missense mutations define three regions involved in feedback inhibition by UTP.

The positive screening procedure previously described was used in order to select, clone and characterize mutants defective in negative feedback control by UTP of the yeast carbamoylphosphate synthetase-aspartate transcarbamylase protein (CPSase-ATCase). The selection procedure was improved by adding a general mapping method for dominant mutations in order to avoid sequencing the whole URA2 allele (7 kb). All 16 mutants obtained carry missense mutations leading to single amino acid replacements: five of them are located in the CPSase domain while the other 11 are in the ATCase domain. In these 16 mutants, ATCase is no longer inhibited by UTP although CPSase retains full sensitivity to the effector, suggesting that the regulation of the two activities involve distinct mechanisms. Amino acid replacements in the ATCase domain were located on a three-dimensional model structure of the yeast ATCase domain. They are clustered in two regions of this domain which must be directly involved in the feedback process.

Remediation of sediment and water contaminated by copper in small-scaled constructed wetlands: effect of bioaugmentation and phytoextraction.

The use of plants and microorganisms to mitigate sediment contaminated by copper was studied in microcosms that mimic the functioning of a stormwater basin (SWB) connected to vineyard watershed. The impact of phytoremediation and bioaugmentation with siderophore-producing bacteria on the fate of Cu was studied in two contrasted (batch vs. semi-continuous) hydraulic regimes. The fate of copper was characterised following its discharge at the outlet of the microcosms, its pore water concentration in the sediment, the assessment of its bioaccessible fraction in the rhizosphere and the measurement of its content in plant tissues. Physico-chemical (pH, redox potential) and biological parameters (total heterotrophic bacteria) were also monitored. As expected, the results showed a clear impact of the hydraulic regime on the redox potential and thus on the pore water concentration of Cu. Copper in pore water was also dependent on the frequency of Cu-polluted water discharges. Repeated bioaugmentation increased the total heterotrophic microflora as well as the Cu bioaccessibility in the rhizosphere and increased the amount of Cu extracted by Phragmites australis by a factor of ~2. Sugar beet pulp, used as a filter to avoid copper flushing, retained 20% of outcoming Cu and led to an overall retention of Cu higher than 94% when arranged at the outlet of microcosms. Bioaugmentation clearly improved the phytoextraction rate of Cu in a small-scaled SWB designed to mimic the functioning of a full-size SWB connected to vineyard watershed. Highlights: Cu phytoextraction in constructed wetlands much depends on the hydraulic regime and on the frequency of Cu-polluted water discharges. Cu phytoextraction increases with time and plant density. Cu bioaccessibility can be increased by bioaugmentation with siderophore-producing bacteria.

Effect of pyoverdine supply on cadmium and nickel complexation and phytoavailability in hydroponics.

Siderophores are chelators with a high selectivity for Fe(III) and a good affinity for divalent metals, including Cd(II) and Ni(II). Inoculation with siderophore-producing bacteria (SPB) has thus been proposed as an alternative to chelator supply in phytoremediation. Accurate assessments of the potential of this association require a dissection of the interaction of siderophores with metals at the soil-root interface. This study focuses on pyoverdine (Pvd), the main siderophore produced by Pseudomonas aeruginosa. We first assessed the ability of Pvd to coordinate Ni(II). The stability constant of Pvd-Ni(II) (log K (L'Ni) = 10.9) was found to be higher than that of Pvd-Cd(II) (log K (L'Cd) = 8.2). We then investigated the effect of a direct supply of Pvd on the mobilization, speciation, and phytoavailability of Cd and Ni in hydroponics. When supplied at a concentration of 50 µM, Pvd selectively promoted Ni mobilization from smectite. It decreased plant Ni and Cd contents and the free ionic fractions of these two metals, consistent with the free ion activity model. Pvd had a more pronounced effect for Ni than for Cd, as predicted from its coordination properties. Inoculation with P. aeruginosa had a similar effect on Ni phytoavailability to the direct supply of Pvd.

Contrasting effects of pyoverdine on the phytoextraction of Cu and Cd in a calcareous soil.

Enhanced metal phytoextraction by the use of siderophore-producing bacteria (SPB) has received a lot of attention in the past decade. Bacterial siderophores are able to bind a wide range of metals other than iron and thus should enhance their phytoavailability in contaminated matrices. However, the impact of bacterial siderophores in the soil-plant transfer of metals is not yet fully elucidated, as underlined by the opposing results reported in the literature regarding the efficiency of coupling phytoextraction with bioaugmentation by SPB. The present study focuses on one bacterial siderophore, the pyoverdine (Pvd), produced by Pseudomonas aeruginosa. The coordination properties of Pvd towards Cd(II) and Cu(II) were determined and the effect of Pvd supply was assessed on (i) the mobility (CaCl2 extractions), (ii) the phytoavailability (DGT measurements) and (iii) the phytoextraction of Cd and Cu, in a calcareous soil. The stability constant of Pvd-Cu (KL'Cu=10(20.1)) was found much higher than that of Pvd-Cd (KL'Cd=10(8.2)). The major finding was the agreement observed between Pvd coordination properties and Pvd impact on metals phytoextraction. Pyoverdine, supplied at 250 µmol kg(-1) soil, enhanced the mobility, the phytoavailability and the phytoextraction of Cu while the fate of Cd was not affected. All these results were compared to those reported for chelate-assisted phytoextraction. Their relevance in using SPB for phytoremediation is discussed.

Herbicide mitigation in microcosms simulating stormwater basins subject to polluted water inputs.

Non-point source pollution as a result of wine-growing activity is of high concern. Stormwater basins (SWB) found downstream of vineyard watersheds could show a potential for the mitigation of runoff water containing herbicides. In this study, mitigation of vinery-used herbicides was studied in microcosms with a very similar functioning to that recorded in SWB. Mitigation efficiency of glyphosate, diuron and 3,4-dichloroaniline (3,4-DCA) was investigated by taking into account hydraulic flow rate, mitigation duration, bioaugmentation and plant addition. Mitigation efficiency measured in water ranged from 63.0% for diuron to 84.2% for 3,4-DCA and to 99.8% for glyphosate. Water-storage duration in the SWB and time between water supplies were shown to be the most influential factors on the mitigation efficiency. Six hours water-storage duration allowed an efficient sorption of herbicides and their degradation by indigenous microorganisms in 5 weeks. Neither bioaugmentation nor plant addition had a significant effect on herbicide mitigation. Our results show that this type of SWB are potentially relevant for the mitigation of these herbicides stemming from wine-growing activity, providing a long enough hydraulic retention time.

Genetic analysis of yeast strains lacking negative feedback control: a one-step method for positive selection and cloning of carbamoylphosphate synthetase-aspartate transcarbamoylase mutants unable to respond to UTP.

We have undertaken an in vivo genetic approach to the analysis of negative feedback control by uridine triphosphate (UTP) of the yeast carbamoylphosphate synthetase-aspartate transcarbamoylase multifunctional protein (CPSase-ATCase). Using an analog of uracil, 5-fluorouracil, we have constructed a screening system leading, in one step, to selection and cloning of a functional aspartate transcarbamoylase that is defective in negative feedback control by UTP. Due to the nature of the screen, spontaneous or UV-induced mutants could be recovered. Well-characterized cloned mutants have been sequenced and reveal one or two modifications in single codons leading to single amino acid replacements. These amino acid changes occurred either in the CPSase or ATCase domains, abolishing their sensitivity to regulation but not their catalytic activities. Hence the regulatory and catalytic sites are distinct. With the same screening system, it may also be possible to enlarge the scope of the molecular study of the feedback processes to include equivalent proteins in fungi as well as higher eukaryotes.

Predominance of Saccharomyces uvarum during spontaneous alcoholic fermentation, for three consecutive years, in an Alsatian winery.

AIMS: The purpose of this study was to determine the origin of the yeasts involved in the spontaneous alcoholic fermentation of an Alsatian wine. METHODS AND RESULTS: During three successive years, must was collected at different stages of the winemaking process and fermented in the laboratory or in the cellar. Saccharomyces yeasts were sampled at the beginning and at the end of the fermentations. Saccharomyces cerevisiae clones were genetically characterized by inter-delta PCR. Non-S. cerevisiae clones were identified as Saccharomyces uvarum by PCR-RFLP on MET2 gene and characterized at the strain level by karyotyping. The composition of the Saccharomyces population in the vineyard, after crushing and in the vat was analyzed. This led to three main results. First, the vineyard Saccharomyces population was rather homogeneous. Second, new non-resident strains had appeared in the must during the winemaking process. Finally, the yeast population in the vat only consisted in S. uvarum strains. CONCLUSION: This 3-year study has enabled us to show the involvement of indigenous S. uvarum in the alcoholic fermentation. SIGNIFICANCE AND IMPACT OF THE STUDY: This study gives a first insight into the polymorphism of S. uvarum strains involved in a spontaneous alcoholic fermentation.

As in Saccharomyces cerevisiae, aspartate transcarbamoylase is assembled on a multifunctional protein including a dihydroorotase-like cryptic domain in Schizosaccharomyces pombe.

The organisation of the URA1 gene of Schizosaccharomyces pombe was determined from the entire cDNA cloned by the transformation of an ATCase-deficient strain of Saccharomyces cerevisiae. The URA1 gene encodes the bifunctional protein GLNase/CPSase-ATCase which catalyses the first two steps of the pyrimidine biosynthesis pathway. The complete nucleotide sequence of the URA1 cDNA was elucidated and the deduced amino-acid sequence was used to define four domains in the protein; three functional domains, corresponding to GLNase (glutamine amidotransferase), CPSase (carbamoylphosphate synthetase) and ATCase (aspartate transcarbamoylase) activities, and one cryptic DHOase (dihydroorotase) domain. Genetic investigations confirmed that both GLNase/CPSase and ATCase activities are carried out by the same polypeptide. They are also both feedback-inhibited by UTP (uridine triphosphate). Its organization and regulation indicate that the S. pombe URA1 gene product appears very similar to the S. cerevisiae URA2 gene product.