3D map distribution of metallic nanoparticles in whole cells using MeV ion microscopy

In this work, a new tool was developed, the MORIA program that readily translates Rutherford backscattering spectrometry (RBS) output data into visual information, creating a display of the distribution of elements in a true three-dimensional (3D) environment. The program methodology is illustrated with the analysis of yeast Saccharomyces cerevisiae cells, exposed to copper oxide nanoparticles (CuO-NP) and HeLa cells in the presence of gold nanoparticles (Au-NP), using different beam species, energies and nuclear microscopy systems. Results demonstrate that for both cell types, the NP internalization can be clearly perceived. The 3D models of the distribution of CuO-NP in S. cerevisiae cells indicate the nonuniform distribution of NP in the cellular environment and a relevant confinement of CuO-NP to the cell wall. This suggests the impenetrability of certain cellular organelles or compartments for NP. By contrast, using a high-resolution ion beam system, discretized agglomerates of Au-NP were visualized inside the HeLa cell. This is consistent with the mechanism of entry of these NPs in the cellular space by endocytosis enclosed in endosomal vesicles. This approach shows RBS to be a powerful imaging technique assigning to nuclear microscopy unparalleled potential to assess nanoparticle distribution inside the cellular volume.

A quantitative proteomic approach to highlight Phragmites sp. adaptation mechanisms to chemical stress induced by a textile dyeing pollutant

Phragmites sp. is present worldwide in treatment wetlands though the mechanisms involved in the phytoremediation remain unclear. In this study a quantitative proteomic approach was used to study the prompt response and adaptation of Phragmites to the textile dyeing pollutant, Acid Orange 7 (AO7). Previously, it was demonstrated that AO7 could be successfully removed from wastewater and mineralized in a constructed wetland planted with Phragmites sp. This azo dye is readily taken up by roots and transported to the plant aerial part by the xylem. Phragmites leaf samples were collected from a pilot scale vertical flow constructed wetland after 0.25, 3.25 and 24.25h exposure to AO7 (400mgL^-1) immediately after a watering cycle used as control. Leaf soluble protein extraction yielded an average of 1560 proteins in a broad pI range (pH3-10) by two-dimensional gel electrophoresis. A time course comparative analysis of leaf proteome revealed that 40 proteins had a differential abundance compared to control (p<0.05) within a 3.25h period. After 24.25h in contact with AO7, leaf proteome was similar to control. Adaptation to AO7 involved proteins related with cellular signalling (calreticulin, Ras-related protein Rab11D and 20S proteasome), energy production and conversion (adenosine triphosphate synthase beta subunit) carbohydrate transport and metabolism (phosphoglucose isomerase, fructose-bisphosphate aldolase, monodehydroascorbate reductase, frutockinase-1 and Hypothetical protein POPTR_0003s12000g and the Uncharacterized protein LOC100272772) and photosynthesis (sedoheptulose-1,7-bisphosphatase and ferredoxin-NADP⁺ reductase). Therefore, the quantitative proteomic approach used in this work indicates that mechanisms associated with stress cell signalling, energy production, carbohydrate transport and metabolism as well as proteins related with photosynthesis are key players in the initial chemical stress response in the phytoremediation process of AO7.

The Pht1;9 and Pht1;8 transporters mediate inorganic phosphate acquisition by the Arabidopsis thaliana root during phosphorus starvation

• The activation of high-affinity root transport systems is the best-conserved strategy employed by plants to cope with low inorganic phosphate (Pi) availability, a role traditionally assigned to Pi transporters of the Pht1 family, whose respective contributions to Pi acquisition remain unclear. • To characterize the Arabidopsis thaliana Pht1;9 transporter, we combined heterologous functional expression in yeast with expression/subcellular localization studies and reverse genetics approaches in planta. Double Pht1;9/Pht1;8 silencing lines were also generated to gain insight into the role of the closest Pht1;9 homolog. • Pht1;9 encodes a functional plasma membrane-localized transporter that mediates high-affinity Pi/H⁺ symport activity in yeast and is highly induced in Pi-starved Arabidopsis roots. Null pht1;9 alleles exhibit exacerbated responses to prolonged Pi limitation and enhanced tolerance to arsenate exposure, whereas Pht1;9 overexpression induces the opposite phenotypes. Strikingly, Pht1;9/Pht1;8 silencing lines display more pronounced defects than the pht1;9 mutants. • Pi and arsenic plant content analyses confirmed a role of Pht1;9 in Pi acquisition during Pi starvation and arsenate uptake at the root-soil interface. Although not affecting plant internal Pi repartition, Pht1;9 activity influences the overall Arabidopsis Pi status. Finally, our results indicate that both the Pht1;9 and Pht1;8 transporters function in sustaining plant Pi supply on environmental Pi depletion.

The Pht1;9 and Pht1;8 transporters mediate inorganic phosphate acquisition by the Arabidopsis thaliana root during phosphorus starvation

• The activation of high-affinity root transport systems is the best-conserved strategy employed by plants to cope with low inorganic phosphate (Pi) availability, a role traditionally assigned to Pi transporters of the Pht1 family, whose respective contributions to Pi acquisition remain unclear. • To characterize the Arabidopsis thaliana Pht1;9 transporter, we combined heterologous functional expression in yeast with expression/subcellular localization studies and reverse genetics approaches in planta. Double Pht1;9/Pht1;8 silencing lines were also generated to gain insight into the role of the closest Pht1;9 homolog. • Pht1;9 encodes a functional plasma membrane-localized transporter that mediates high-affinity Pi/H⁺ symport activity in yeast and is highly induced in Pi-starved Arabidopsis roots. Null pht1;9 alleles exhibit exacerbated responses to prolonged Pi limitation and enhanced tolerance to arsenate exposure, whereas Pht1;9 overexpression induces the opposite phenotypes. Strikingly, Pht1;9/Pht1;8 silencing lines display more pronounced defects than the pht1;9 mutants. • Pi and arsenic plant content analyses confirmed a role of Pht1;9 in Pi acquisition during Pi starvation and arsenate uptake at the root-soil interface. Although not affecting plant internal Pi repartition, Pht1;9 activity influences the overall Arabidopsis Pi status. Finally, our results indicate that both the Pht1;9 and Pht1;8 transporters function in sustaining plant Pi supply on environmental Pi depletion.

Qualitative modelling and formal verification of the FLR1 gene mancozeb response in Saccharomyces cerevisiae

BACKGROUND

Qualitative models allow understanding the relation between the structure and the dynamics of gene regulatory networks. The dynamical properties of these models can be automatically analysed by means of formal verification methods, like model checking. This facilitates the model-validation process and the test of new hypotheses to reconcile model predictions with the experimental data.

RESULTS

The authors report in this study the qualitative modelling and simulation of the transcriptional regulatory network controlling the response of the model eukaryote Saccharomyces cerevisiae to the agricultural fungicide mancozeb. The model allowed the analysis of the regulation level and activity of the components of the gene mancozeb-induced network controlling the transcriptional activation of the FLR1 gene, which is proposed to confer multidrug resistance through its putative role as a drug eflux pump. Formal verification analysis of the network allowed us to confront model predictions with the experimental data and to assess the model robustness to parameter ordering and gene deletion.

CONCLUSIONS

This analysis enabled us to better understand the mechanisms regulating the FLR1 gene mancozeb response and confirmed the need of a new transcription factor for the full transcriptional activation of YAP1. The result is a computable model of the FLR1 gene response to mancozeb, permitting a quick and cost-effective test of hypotheses prior to experimental validation.

Cloning, expression, purification, crystallization and preliminary structure determination of glucose-1-phosphate uridylyltransferase (UgpG) from Sphingomonas elodea ATCC 31461 bound to glucose-1-phosphate

The cloning, expression, purification, crystallization and preliminary crystallographic analysis of glucose-1-phosphate uridylyltransferase (UgpG) from Sphingomonas elodea ATCC 31461 bound to glucose-1-phosphate are reported. Diffraction data sets were obtained from seven crystal forms in five different space groups, with highest resolutions ranging from 4.20 to 2.65 A. The phase problem was solved for a P2(1) crystal form using multiple isomorphous replacement with anomalous scattering from an osmium derivative and a SeMet derivative. The best native crystal in space group P2(1) has unit-cell parameters a = 105.5, b = 85.7, c = 151.8 A, beta = 105.2 degrees . Model building and refinement are currently under way.

Saccharomyces cerevisiae adaptation to weak acids involves the transcription factor Haa1p and Haa1p-regulated genes

The understanding of the molecular mechanisms that may contribute to counteract the deleterious effects of organic acids as fungistatic agents is essential to guide suitable preservation strategies. In this work, we show that the recently identified transcription factor Haa1p is required for a more rapid adaptation of a yeast cell population to several weak acid food preservatives. Maximal protection is exerted against the short-chain length acetic or propionic acids. The transcription of nine Haa1p-target genes, many of which are predicted to encode membrane proteins of unknown or poorly characterized function, is activated under weak acid stress. The Haa1-regulated genes required for a more rapid yeast adaptation to weak acids include TPO2 and TPO3, encoding two predicted plasma membrane multidrug transporters of the major facilitator superfamily, and YGP1, encoding a poorly characterized cell wall glycoprotein. The acetic acid-induced prolongation of the lag phase of unadapted cell populations lacking HAA1 or TPO3, compared with wild-type population, was correlated with the level of the acid accumulated into the stressed cells.

Adaptative responses in yeast to the herbicide 2-methyl-4-chlorophenoxyacetic acid at the level of intracellular pH homeostasis

AIMS

The objective of this work was to examine adaptative responses occurring in Saccharomyces cerevisiae following exposure to the herbicide 2-methyl-4-chlorophenoxyacetic acid (MCPA).

METHODS AND RESULTS

The exposure of a yeast cell population to MCPA concentrations of moderate toxicity led to a period of latency before eventual resumption of inhibited growth. During this period of adaptation, the plasma membrane (PM) H+-ATPase was activated, in coordination with the decrease of intracellular pH (pHi), cell viability and average cell volume. The in vivo activation of this ATPase was demonstrated either by assaying PM-ATPase activity in membrane suspensions extracted from cells grown in the presence or absence of MCPA or by measuring the in vivo H+-pumping activity in the same cells. The PM-H+-ATPase activation could not be attributed to transcriptional activation of the encoding genes PMA1 and PMA2.

CONCLUSIONS

The activity of PM-H+-ATPase was stimulated and the internal cell volume decreased during yeast adaptation to growth under MCPA stress. Based on the values estimated for the pHi, we hypothesize that these cell responses may contribute to the restoration of pHi homeostasis during recovery from MCPA stress.

SIGNIFICANCE AND IMPACT OF THE STUDY

This work is a contribution to the understanding of the toxic effects of the herbicide MCPA and of physiological mechanisms underlying adaptation to MCPA, in the eukaryotic model S. cerevisiae. Results may be useful to elucidate the adaptation mechanisms to this xenobiotic compound in more complex and experimentally less-accessible eukaryotes. They also provide indications to assist the use of yeast cells as a bioassay system to assess the toxicity of phenoxyacetic acid herbicides and of other lipophilic xenobiotics, aiming at reducing the use of animals in toxicity testing.

Activation and significance of vacuolar H+-ATPase in Saccharomyces cerevisiae adaptation and resistance to the herbicide 2,4-dichlorophenoxyacetic acid

The stimulation of the activity of the H(+)-ATPase present in the vacuolar membrane (V-ATPase) of Saccharomyces cerevisiae is here described in response to a moderate stress induced by 2,4-dichlorophenoxyacetic acid (2,4-D). This in vivo activation (up to 5-fold) took place essentially during the adaptation period, preceding cell division under herbicide stress, in coordination with a marked activation of plasma membrane H(+)-ATPase (PM-ATPase) (up to 30-fold) and the decrease of intracellular and vacuolar pH values, suggesting that activation may be triggered by acidification. Single deletion of VMA1 and genes encoding other V-ATPase subunits led to a more extended period of adaptation and to slower growth under 2,4-D stress. Results suggest that a functional V-ATPase is required to counteract, more rapidly and efficiently, the dissipation of the physiological H(+)-gradient across vacuolar membrane registered during 2,4-D adaptation.

Cloning and sequence analysis of the ces10 gene encoding a Sphingomonas paucimobilis esterase

The ces10 gene of the gellan gum-producing strain Sphingomonas paucimobilis ATCC 31461 was cloned and sequenced. Multi-sequence alignment of the deduced protein indicated that Ces10 belongs to the serine hydrolase family with a potential catalytic triad comprising Ser(153) (within the G-X-S-X-G consensus sequence), His(75) and Asp(125). The mixed block results obtained following pattern search and the low identities detected in a BLAST analysis indicate that Ces10 is significantly different from other characterised bacterial esterases/lipases. Nevertheless, the Ces10 amino acid sequence showed 45% similarity with Rhodococcus sp. heroin esterase and 48% with Bacillus subtilis p-nitrobenzyl esterase. Ces10, with a predicted molecular mass of 30,641 Da, was overproduced in Escherichia coli and purified to homogeneity in a histidine-tagged form. Enzyme assays using p-nitrophenyl-esters (p-NP-esters) with different acyl chain-lengths as the substrate confirmed the anticipated esterase activity. Ces10 exhibited a marked preference for short-chain fatty acids, yielding the highest activity with p-NP-propionate (optimal pH 7.4, optimal temperature 37 degrees C).

Toxicity of chlorinated phenoxyacetic acid herbicides in the experimental eukaryotic model Saccharomyces cerevisiae: role of pH and of growth phase and size of the yeast cell population

The inhibitory effect of the herbicides 2-methyl-4-chlorophenoxyacetic acid (MCPA) and 2,4-dichlorophenoxyacetic acid (2,4-D) in Saccharomyces cerevisiae growth is strongly dependent on medium pH (range 2.5-6.5). Consistent with the concept that the toxic form is the liposoluble undissociated form, at values close to their pK(a) (3.07 and 2.73, respectively) the toxicity is high, decreasing with the increase of external pH. In addition, the toxicity of identical concentrations of the undissociated acid form is pH independent, as observed with 2,4-dichlorophenol (2,4-DCP), an intermediate of 2,4-D degradation. Consequently, at pH values above 3.5 (approximately one unit higher than 2,4-D pK(a)), 2,4-DCP becomes more toxic than the original herbicide. A dose-dependent inhibition of growth kinetics and increased duration of growth latency is observed following sudden exposure of an unadapted yeast cell population to the presence of the herbicides. This contrasts with the effect of 2,4-DCP, which essentially affects growth kinetics. Experimental evidences suggest that the acid herbicides toxicity is not exclusively dependent on the liposolubility of the toxic form, as may essentially be the case of 2,4-DCP. An unadapted yeast cell population at the early stationary-phase of growth under nutrient limitation is significantly more resistant to short-term herbicide induced death than an exponential-phase population. Consequently, the duration of growth latency is reduced, as observed with the increase of the size of the herbicide stressed population. However, these physiological parameters have no significant effect either on growth kinetics, following growth resumption under herbicide stress, or on the growth curve of yeast cells previously adapted to the herbicides, indicating that their role is exerted at the level of cell adaptation.

Characterization of the ugpG gene encoding a UDP-glucose pyrophosphorylase from the gellan gum producer Sphingomonas paucimobilis ATCC 31461

The ugpGgene, which codes for a UDP-glucose pyrophosphorylase (UGP) (or glucose-1-phosphate uridylyltransferase; EC 2.7.7.9) in Sphingomonas paucimobilis ATCC 31461, was cloned and sequenced. This industrial strain produces the exopolysaccharide gellan, a new commercial gelling agent, and the ugpG gene may convert glucose-1-phosphate into UDP-glucose in the gellan biosynthetic pathway. The ugpG gene is capable of restoring the capacity of an Escherichia coli galU mutant to grow on galactose by functional complementation of its deficiency for UDP-glucose pyrophosphorylase activity. As expected, the predicted gene product shows strong homology to UDP-glucose pyrophosphorylases from several bacterial species. The N-terminal region of UgpG exhibits the motif GXGTRXLPXTK, which is highly conserved among bacterial XDP-sugar pyrophosphorylases, and a lysine residue (K(192)) is located within a VEKP motif predicted to be essential for substrate binding or catalysis. UgpG was purified to homogeneity as a heterologous fusion protein from crude cell extracts prepared from IPTG-induced cells of E. coli, using affinity chromatography. Under denaturing conditions, the fusion protein S-UgpG-His(6) migrated with an estimated molecular mass of 36 kDa [corresponding to the predicted molecular mass of native UgpG (31.2 kDa) plus 5 kDa for the S and histidine tags). Kinetic analysis of UgpG in the reverse reaction (pyrophosphorolysis) showed a typical Michaelis-Menten substrate saturation pattern. The apparent K(m) and V(max) values estimated for UDP-glucose were 7.5 microM and 1275 micromol/min/g.

Gellan gum biosynthesis in Sphingomonas paucimobilis ATCC 31461: genes, enzymes and exopolysaccharide production engineering

The commercial gelling agent, gellan, is an extracellular polysaccharide (EPS) produced by Sphingomonas paucimobilis ATCC 31461. In recent years, significant progress in understanding the relationship between gellan structure and properties and elucidation of the biosynthesis and engineering of this recent product of biotechnology has been made. This review focuses on recent advances in this field. Emphasis is given to identification and characterization of genes and enzymes involved, or predicted to be involved, in the gellan biosynthetic pathway, at the level of synthesis of sugar-activated precursors, of the repeat unit assembly and of gellan polymerization and export. Identification of several genes, biochemical characterization of the encoded enzymes and elucidation of crucial steps of the gellan pathway indicate that possibilities now exist for exerting control over gellan production at any of the three levels of its biosynthesis. However, a better knowledge of the poorly understood steps and of the bottlenecks and regulation of the pathway, the characterization of the composition, structure and functional properties of gellan-like polymers produced either by the industrial strain under different culture conditions or by mutants are still required for eventual success of the metabolic engineering of gellan production.

Biochemical characterization of the beta-1,4-glucuronosyltransferase GelK in the gellan gum-producing strain Sphingomonas paucimobilis A.T.C.C. 31461

Biosynthesis of bacterial polysaccharide-repeat units proceeds by sequential transfer of sugars, from the appropriate sugar donor to an activated lipid carrier, by committed glycosyltransferases (GTs). Few studies on the mechanism of action for this type of GT are available. Sphingomonas paucimobilis A.T.C.C. 31461 produces the industrially important polysaccharide gellan gum. We have cloned the gelK gene from S. paucimobilis A.T.C.C. 31461. GelK belongs to family 1 of the GT classification [Campbell, Davies, Bulone, Henrissat (1997) Biochem. J. 326, 929-939]. Sequence similarity studies suggest that GelK consists of two protein modules corresponding to the -NH(2) and -CO(2)H halves, the latter possibly harbouring the GT activity. The gelK gene and the open reading frames coding for the -NH(2) (GelK(NH2)) and -CO(2)H (GelK(COOH)) halves were overexpressed in Escherichia coli. GelK and GelK(NH2) were present in both the soluble and membrane fractions of E. coli, whereas GelK(COOH) was only present in the soluble fraction. GelK catalysed the transfer of [(14)C]glucuronic acid from UDP-[(14)C]glucuronic acid into a glycolipid extracted from S. paucimobilis or E. coli, even in the presence of EDTA, and the radioactive sugar was released from the glycolipid by beta-1,4-glucuronidase. GelK was not able to use synthetic glucosyl derivatives as acceptors, indicating that the PP(i)-lipid moiety is needed for enzymic activity. Recombinant GelK(NH2) and GelK(COOH) did not show detectable activity. Based on the biochemical characteristics of GelK and on sequence similarities with N-acetylglucosaminyltransferase, we propose that GT families 1 and 28 form a superfamily.

Resistance and adaptation to quinidine in Saccharomyces cerevisiae: role of QDR1 (YIL120w), encoding a plasma membrane transporter of the major facilitator superfamily required for multidrug resistance

As predicted based on structural considerations, we show results indicating that the member of the major facilitator superfamily encoded by Saccharomyces cerevisiae open reading frame YIL120w is a multidrug resistance determinant. Yil120wp was implicated in yeast resistance to ketoconazole and quinidine, but not to the stereoisomer quinine; the gene was thus named QDR1. Qdr1p was proved to alleviate the deleterious effects of quinidine, revealed by the loss of cell viability following sudden exposure of the unadapted yeast population to the drug, and to allow the earlier eventual resumption of exponential growth under quinidine stress. However, QDR1 gene expression had no detectable effect on the susceptibility of yeast cells previously adapted to quinidine. Fluorescence microscopy observation of the distribution of the Qdr1-green fluorescent protein fusion protein in living yeast cells indicated that Qdr1p is a plasma membrane protein. We also show experimental evidence indicating that yeast adaptation to growth with quinidine involves the induction of active expulsion of the drug from preloaded cells, despite the fact that this antiarrhythmic and antimalarial quinoline ring-containing drug is not present in the yeast natural environment. However, we were not able to prove that Qdr1p is directly implicated in this export. Results clearly suggest that there are other unidentified quinidine resistance mechanisms that can be used in the absence of QDR1.

Mechanisms underlying the acquisition of resistance to octanoic-acid-induced-death following exposure of Saccharomyces cerevisiae to mild stress imposed by octanoic acid or ethanol

Acquisition of resistance to lethal concentrations of octanoic acid was induced in cells of Saccharomyces cerevisiae grown in the presence of sublethal concentrations of this lipophilic acid or following rapid exposure (1 h) of unadapted yeast cells to mild stress imposed by the same acid. Experimental evidence indicated that the referred adaptation involved de novo protein synthesis, presumably due to the rapid induction of a plasma membrane transporter which mediates the active efflux of octanoate out of the cell. Rapid exposure of cells to mild ethanol stress also led to increased resistance to lethal concentrations of octanoic acid. This cross-resistance to octanoic-acid-induced death was below the level of resistance induced by mild octanoic acid stress and did not involve induction of the active expulsion of octanoate out of the cell. However, the rapid exposure of yeast cells to octanoic acid or ethanol led to the activation of plasma membrane H+-ATPase. The physiological role of the two stress responses examined during the present study, namely, the active efflux of octanoate specifically induced by octanoic acid and the stimulation of plasma membrane H+-ATPase activity, is discussed.

The activity of plasma membrane H(+)-ATPase is strongly stimulated during Saccharomyces cerevisiae adaptation to growth under high copper stress, accompanying intracellular acidification

For the adaptation of cells of Saccharomyces cerevisiae, a period of latency is necessary before exponential growth is resumed in a medium supplemented with a highly inhibitory concentration of copper. In this work, we have examined some physiological responses occurring during this period of adaptation. The results revealed that plasma membrane H(+)-ATPase (PM-ATPase) activity is strongly stimulated (up to 24-fold) during copper-induced latency in growth medium with glucose, reaching maximal levels when the cells were about to start inhibited exponential growth. This in vivo activation of the ATPase activity by copper was accompanied by the stimulation of the H(+)-pumping activity of the enzyme in vivo and was essentially due to the increase of the apparent V(max) for MgATP. Although the exact molecular basis of the reported plasma membrane ATPase activation was not clarified, no increase in the mRNA levels from the encoding genes PMA1 and PMA2 was apparently detected during copper-induced latency. The physiological response reported here may allow the cells to cope with copper-induced lipid peroxidation and consequent decrease in plasma membrane lipid ordering and increase in the non-specific permeability to protons. The consequences of these copper deleterious effects were revealed by the decrease of the intracellular pH (pH(i)) of the yeast population, from approximately pH(i) 6 to pH(i) 5, during copper-induced latency in growth medium at pH 4.3. The time-dependent patterns of plasma membrane ATPase activation and of the decrease of pH(i) during the period of adaptation to growth with copper correlate, suggesting that the regulation of this membrane enzyme activity may be triggered by intracellular acidification. Consistent with this idea, when exponential growth under copper stress was resumed and the pH(i) of the yeast population recovered up to physiological values, plasma membrane ATPase activity simultaneously decreased from the highly stimulated level attained during the adaptation period of latency.

Transcriptional activation of FLR1 gene during Saccharomyces cerevisiae adaptation to growth with benomyl: role of Yap1p and Pdr3p

The adaptation of Saccharomyces cerevisiae to growth in the presence of the antimitotic fungicide benomyl involves the dramatic activation of FLR1 transcription, taking place during benomyl-induced latency following sudden exposure to the fungicide. FLR1 gene encodes a plasma membrane transporter of the major facilitator superfamily (MFS) conferring resistance to multiple drugs, in particular to benomyl. FLR1 activation is completely abolished in a mutant devoided of YAP1 gene being exerted by Yap1p either directly or via Pdr3p. YAP1 gene was proved to be a determinant of benomyl resistance; the duration of the adaptation period preceding cell division under benomyl stress was longer for the Deltayap1 population, presumably due to the abolishment of FLR1 activation during latency. Although benomyl resistance mediated by Yap1p is reduced in a FLR1 deletion mutant, results also indicate that Yap1p may have other target genes that confer benomyl resistance in yeast.

Expression of the AZR1 gene (ORF YGR224w), encoding a plasma membrane transporter of the major facilitator superfamily, is required for adaptation to acetic acid and resistance to azoles in Saccharomyces cerevisiae

In this work, we report results on the functional analysis of Saccharomyces cerevisiae ORF YGR224w, predicted to code for an integral membrane protein, with 14 potential transmembrane segments, belonging to the major facilitator superfamily (MFS) of transporters which are required for multiple-drug resistance (MDR). This MFS-MDR homologue is required for yeast adaptation to high stress imposed by low-chain organic acids, in particular by acetic acid, and for resistance to azoles, especially to ketoconazole and fluconazole; the encoding gene was thus named the AZR1 gene. These conclusions were based on the higher susceptibility to these compounds of an azr1Delta deletion mutant strain compared with the wild-type and on the increased resistance of both azr1Delta and wild-type strains upon increased expression of the AZR1 gene from a centromeric plasmid clone. AZR1 gene expression reduces the duration of acetic acid-induced latency, although the growth kinetics of adapted cells under acetic acid stress is apparently independent of AZR1 expression level. Fluorescence microscopy observation of the distribution of the Azr1-GFP fusion protein in yeast living cells indicated that Azr1 is a plasma membrane protein. Studies carried out to gain some understanding of how this plasma membrane putative transporter facilitates yeast adaptation to acetic acid did not implicate Azr1p in the alteration of acetic acid accumulation into the cell through the active efflux of acetate.

Glucose does not activate the plasma-membrane-bound H+-ATPase but affects pmaA transcript abundance in Aspergillus nidulans

The addition of glucose to starved cells of Aspergillus nidulans increased the abundance of the pmaA transcript only transiently (15 min) and to a very low degree (1.3-fold), but strongly decreased its abundance during further incubation. This down-regulation was CreA (carbon catabolite repressor protein)-dependent. Glucose failed to stimulate the plasma membrane (PM)-ATPase activity of A. nidulans, whereas under the same experimental conditions the activity of the enzyme from Saccharomyces cerevisiae was enhanced four-fold within 5-10 min following glucose addition. Glucose stimulated the PM-ATPase of Neurospora crassa only 1.3-fold. Sequence comparison of the C-terminal end of the PM-ATPase from S. cerevisiae, N. crassa, A. nidulans, Fusarium sporotrichoides and Penicillium simplicissimum showed that the two regulatory sites necessary for glucose stimulation in S. cerevisiae are conserved in N. crassa and F. sporotrichoides but not in A. nidulans and P. simplicissimum, and their presence therefore does not correlate with glucose stimulation. We conclude that, in contrast to S. cerevisiae, which has become a paradigm of fungal glucose metabolism, glucose does not up-regulate the activity of the plasma membrane ATPase in the filamentous fungi examined.

Enzymes leading to the nucleotide sugar precursors for exopolysaccharide synthesis in Burkholderia cepacia

Based on the chemical composition of the exopolysaccharide produced by the cystic fibrosis bacterial isolate Burkholderia cepacia IST408, we postulated and confirmed, based on the specificity of enzymes detected in crude cell-free extracts, the pathway leading to the presumptive activated sugar precursors: UDP-D-glucose, UDP-D-galactose, UDP-D-glucuronic acid, GDP-D-mannose, and GDP-D-rhamnose. Results also suggest that regulation of the expression of the mucoid phenotype in B. cepacia does not occur at the level of synthesis of any of these enzymes.

Identification of the Pseudomonas aeruginosa glmM gene, encoding phosphoglucosamine mutase

A search for a potential algC homologue within the Pseudomonas aeruginosa PAO1 genome database has revealed an open reading frame (ORF) of unknown function, ORF540 in contig 54 (July 1999 Pseudomonas genome release), that theoretically coded for a 445-amino-acid-residue polypeptide (I. M. Tavares, J. H. Leitão, A. M. Fialho, and I. Sá-Correia, Res. Microbiol. 150:105-116, 1999). The product of this gene is here identified as the phosphoglucosamine mutase (GlmM) which catalyzes the conversion of glucosamine-6-phosphate to glucosamine-1-phosphate, an essential step in the formation of the cell wall precursor UDP-N-acetylglucosamine. The P. aeruginosa gene has been cloned into expression vectors and shown to restore normal peptidoglycan biosynthesis and cell growth of a glmM Escherichia coli mutant strain. The GlmM enzyme from P. aeruginosa has been overproduced to high levels and purified to homogeneity in a six-histidine-tagged form. Beside its phosphoglucosamine mutase activity, the P. aeruginosa enzyme is shown to exhibit phosphomannomutase and phosphoglucomutase activities, which represent about 20 and 2% of its GlmM activity, respectively.

Structural study of the exopolysaccharide produced by a clinical isolate of Burkholderia cepacia

The primary structure of the exopolysaccharide produced by a clinical isolate of the bacterium Burkholderia cepacia was studied by means of methylation analysis, selective degradation, NMR spectroscopy, and electrospray mass spectrometry. The resulting data showed that the parent repeating unit of the exopolysaccharide is a highly branched heptasaccharide with the following structure: Two acetyl groups are present per repeating unit, as noncarbohydrate substituents.

Identification of the pgmG gene, encoding a bifunctional protein with phosphoglucomutase and phosphomannomutase activities, in the gellan gum-producing strain Sphingomonas paucimobilis ATCC 31461

The pgmG gene of Sphingomonas paucimobilis ATCC 31461, the industrial gellan gum-producing strain, was cloned and sequenced. It encodes a 50,059-Da polypeptide that has phosphoglucomutase (PGM) and phosphomannomutase (PMM) activities and is 37 to 59% identical to other bifunctional proteins with PGM and PMM activities from gram-negative species, including Pseudomonas aeruginosa AlgC. Purified PgmG protein showed a marked preference for glucose-1-phosphate (G1P); the catalytic efficiency was about 50-fold higher for G1P than it was for mannose-1-phosphate (M1P). The estimated apparent K(m) values for G1P and M1P were high, 0.33 and 1.27 mM, respectively. The pgmG gene allowed the recovery of alginate biosynthetic ability in a P. aeruginosa mutant with a defective algC gene. This result indicates that PgmG protein can convert mannose-6-phosphate into M1P in the initial steps of alginate biosynthesis and, together with other results, suggests that PgmG may convert glucose-6-phosphate into G1P in the gellan pathway.

Modification of plasma membrane lipid order and H+-ATPase activity as part of the response of Saccharomyces cerevisiae to cultivation under mild and high copper stress

Plasma membrane lipid disorganization takes place in cells of Saccharomyces cerevisiae grown under copper stress, as shown by fluorescence anisotropy measurements with the lipid reporter probe 1,6-diphenyl-1,3,5-hexatriene. The extent of plasma membrane disorganization, presumably due to copper-induced lipid peroxidation, was discontinuous when measured in cells grown in media supplemented with different concentrations of CuSO4. Results suggested the existence of adaptive mechanisms that cells employ to protect themselves against the deleterious effects of copper. The adaptive mechanisms examined in this study included the coordinate increase in the activities of Cu,Zn-superoxide dismutase (up to five-fold), glutathione reductase (up to 1.7-fold), and plasma membrane H+-ATPase (up to three-fold). These enzyme activities showed maximal levels in cells grown with copper supplied at intermediate concentrations, within the range that allowed growth. Significantly, at these concentrations, plasma membrane disorganization did not increase when increasing amounts of CuSO4 were supplied. However, at copper concentrations close to the maximal that allowed growth, the capacity of the yeast cell response to cope with the deleterious effects of copper was exceeded; plasma membrane lipid organization and plasma-membrane-bound H+-ATPase activity drastically declined in response to the increased levels of copper stress and the consequences on growth kinetics were even more severe. Our results clearly suggest that modification of plasma membrane H+-ATPase activity is either part of or the result of the global response of yeast to mild or high copper stress.

Molecular typing and exopolysaccharide biosynthesis of Burkholderia cepacia isolates from a Portuguese cystic fibrosis center

This work describes the first epidemiological survey of Burkholderia cepacia involved in pulmonary infections among the Portuguese population with cystic fibrosis (CF) who attended the major CF treatment Center in Lisbon at Sta. Maria Hospital from 1995 to the end of 1997. The characterization of the genomic relatedness of the isolates was based on the analysis of their ribopatterns (with EcoRI) followed by construction of a ribotype-based phylogenetic tree. This study was complemented with macrorestriction fragment analysis by pulsed-field gel electrophoresis. After optimization of the solid growth medium, we found that exopolysaccharide (EPS) production by B. cepacia CF isolates is not as rare a phenomenon as was thought before; indeed, 70% of the isolates examined were EPS producers.

FLR1 gene (ORF YBR008c) is required for benomyl and methotrexate resistance in Saccharomyces cerevisiae and its benomyl-induced expression is dependent on pdr3 transcriptional regulator

In this work we report the disruption of a Saccharomyces cerevisiae ORF YBR008c (FLR1 gene) within the context of EUROFAN (EUROpean Functional Analysis Network) six-pack programme, using a PCR-mediated gene replacement protocol as well as the results of the basic phenotypic analysis of a deletant strain and the construction of a disruption cassette for inactivation of this gene in any yeast strain. We also show results extending the knowledge of the range of compounds to which FLR1 gene confers resistance to the antimitotic systemic benzimidazole fungicide benomyl and the antitumor agent methotrexate, reinforcing the concept that the FLR1 gene is a multidrug resistance (MDR) determinant. Our conclusions were based on the higher susceptibility to these compounds of flr1Delta compared with wild-type and on the increased resistance of both flr1Delta and wild-type strains upon increased expression of FLR1 gene from a centromeric plasmid clone. The present study also provides, for the first time, evidence that the adaptation of yeast cells to growth in the presence of benomyl involves the dramatic activation of FLR1 gene expression during benomyl-induced latency (up to 400-fold). Results obtained using a FLR1-lacZ fusion in a plasmid indicate that the activation of FLR1 expression in benomyl-stressed cells is under the control of the transcriptional regulator Pdr3p. Indeed, PDR3 deletion severely reduces benomyl-induced activation of FLR1 gene expression (by 85%), while the homologous Pdr1p transcription factor is apparently not involved in this activation.

Pattern of changes in the activity of enzymes of GDP-D-mannuronic acid synthesis and in the level of transcription of algA, algC and algD genes accompanying the loss and emergence of mucoidy in Pseudomonas aeruginosa

The low activity levels of the four GDP-D-mannuronic acid-forming enzymes, even in highly alginate-producing strains of Pseudomonas aeruginosa, have made it difficult to compare enzyme activities accompanying the loss/acquisition of mucoidy. Using optimized conditions, we compared the specific activity of these enzymes in three different mucoid P. aeruginosa cystic fibrosis isolates, in their nonmucoid spontaneous variants, and in mucoid variants that emerged during extended incubation of these nonmucoid forms in acetamide broth. A correlation was established between the promptness of emergence of the mucoid forms and the differing sensitivity to nutrient-limitation-induced death of the nonmucoid compared with the isogenic mucoid population. Consistent with the undetectable levels of algD mRNA in nonmucoid forms and with the concept that the step catalyzed by the algD-encoded GDP-mannose dehydrogenase (GMD) is a key step in control of the alginate pathway, GMD activity was undetectable or showed negligible values in nonmucoid variants and correlated with alginate production. However, phosphomannose isomerase (PMI), phosphomannomutase (PMM), and GDP-mannose pyrophosphorylase (GMP) activities in the nonmucoid forms were only slightly (40-70%) below the values in the mucoid forms. Nevertheless, no transcripts homologous to algA (encoding a bifunctional enzyme that possesses both PMI and GMP activities) were detected in the nonmucoid form, and the levels of algC (encoding PMM) transcripts, although detectable in the nonmucoid variants, were, in general, much higher in the mucoid forms. These apparently intriguing observations were cleared up by the identification of two algA functional homologues in P. aeruginosa, recently reported by others, and by the identification of one algC homologue, in contig225 of the PAO1 genome sequence, defining a polypeptide with a deduced amino acid sequence that showed significant homology with that of enzymes of the phosphohexomutase family found in databases. Results are also consistent with the requirement of PMI, GMP and PMM activities for the supply of GDP-D-mannose to (at least) A-band lipopolysaccharide synthesis, while GMD channels this precursor into the alginate pathway.

Comparative effects of Saccharomyces cerevisiae cultivation under copper stress on the activity and kinetic parameters of plasma-membrane-bound H(+)-ATPases PMA1 and PMA2

The major yeast plasma membrane H(+)-ATPase is encoded by the essential PMA1 gene. The PMA2 gene encodes an H(+)-ATPase that is functionally interchangeable with the one encoded by PMA1, but it is expressed at a much lower level than the PMA1 gene and it is not essential. Using genetically manipulated strains of Saccharomyces cerevisiae that exclusively synthesize PMA1 ATPase or PMA2 ATPase under control of the PMA1 promoter, we found that yeast cultivation under mild copper stress leads to a similar activation of PMA2 and PMA1 isoforms. At high inhibitory copper concentrations (close to the maximum that allowed growth), ATPase activity was reduced from maximal levels; this decrease in activity was less important for PMA2 ATPase than for PMA1 ATPase. The higher tolerance to high copper stress of the artificial strain synthesizing PMA2 ATPase exclusively, as compared to that synthesizing solely PMA1 ATPase, correlated both with the lower sensitivity of PMA2 ATPase to the deleterious effects of copper in vivo and with its higher apparent affinity for MgATP, and suggests that plasma membrane H(+)-ATPase activity plays a role in yeast tolerance to copper.

Activation of the H+-ATPase in the plasma membrane of cells of Saccharomyces cerevisiae grown under mild copper stress

Cells of Saccharomyces cerevisiae exhibited a more active plasma membrane H+-ATPase during growth in media supplemented with CuSO4 concentrations equal to or below 1 mM than did cells cultivated in the absence of copper stress. Maximal specific activities were found with 0.5 mM CuSO4. ATPase activity declined when cells were grown with higher concentrations up to 1.5 mM (the maximal concentration that allowed growth), probably due to severe disorganization of plasma membrane. Cu2+-induced maximal activation was reflected in an increase of Vmax (approximately threefold) and in the slight decrease of the Km for MgATP (from 0.93 +/- 0.13 to 0.65 +/- 0.16 mM). The expression of the gene encoding the essential plasma membrane ATPase (PMA1) was reduced with a dose-dependent pattern in cells grown with Inhibitory concentrations of copper, while the weakly expressed PMA2 gene promoter was moderately more efficient in cells cultivated under mild copper stress (1.5-fold maximal activation). ATPase was activated by copper despite the slightly lower content of ATPase protein in the plasma membrane of Cu2+-grown cells and the powerful inhibitory effect of Cu2+ in vitro.

Modification of Saccharomyces cerevisiae thermotolerance following rapid exposure to acid stress

Thermotolerance was induced in cells of Saccharomyces cerevisiae YPH499 pre-exposed, during 10 min and in the presence of glucose, to a mild acid-stress with HCl at pH 3.5. Thermotolerance was not induced in cells exposed to a severe acid stress by 50 mM acetic acid at pH 3.5, or HCl at pH 2.5 or pH 2.0. Yeast cells pre-incubated under glucose starvation were found to be more tolerant to a lethal heat stress than cells pre-incubated in glucose-supplemented media, despite the pH value of the media (range 2.0-6.5) and the type of acidulant used (HCl or acetic acid). Moreover, the high thermotolerance exhibited by cells pre-incubated at pH 6.5 for 10 min under glucose starvation was not significantly modified by the acidification of the pre-incubation medium. Results are discussed based on the effect that glucose and a mild or severe acid stress have on plasma membrane H+-ATPase activity and on cytosolic pH values, estimated in a previous work.

In vivo activation of yeast plasma membrane H+-ATPase by ethanol: effect on the kinetic parameters and involvement of the carboxyl-terminus regulatory domain

The in vivo activation of Saccharomyces cerevisiae plasma membrane H+-ATPase by ethanol was observed during ethanol-stressed cultivation or following the rapid incubation of cells with ethanol (6% (v/v)). Ethanol activated both the basal and the glucose-activated forms of the enzyme being the H+-ATPase fully activated by glucose (5% (w/v)) still additionally activable by ethanol. The kinetic parameters of ethanol-activated and non-activated H+-ATPase were calculated based directly on Michaëlis-Menten equation (with MgATP concentrations in the range 0. 16-8.18 mM and 7.5 mM of free Mg2+); the rectangular hyperbolic function was solved using iterative procedures. Ethanol-induced stimulation of plasma membrane H+-ATPase activity was associated to the increase of Vmax whereas the Km for MgATP increased. Results obtained with mutants constructed and used in previous studies envisaging the analysis of the molecular mechanisms underlying plasma membrane ATPase activation by glucose, external acidification and nitrogen starvation, suggested that the carboxyl-terminus (C-terminus) regulatory domain may also be involved in the in vivo activation by ethanol.

The H(+)-ATPase in the plasma membrane of Saccharomyces cerevisiae is activated during growth latency in octanoic acid-supplemented medium accompanying the decrease in intracellular pH and cell viability

Saccharomyces cerevisiae plasma membrane H(+)-ATPase activity was stimulated during octanoic acid-induced latency, reaching maximal values at the early stages of exponential growth. The time-dependent pattern of ATPase activation correlated with the decrease of cytosolic pH (pHi). The cell population used as inoculum exhibited a significant heterogeneity of pHi, and the fall of pHi correlated with the loss of cell viability as determined by plate counts. When exponential growth started, only a fraction of the initial population was still viable, consistent with the role of the physiology and number of viable cells in the inoculum in the duration of latency under acid stress.

Megaplasmids in Thermus oshimai isolates from two widely separated geographical areas: restriction fragment profiling and DNA homology

Megaplasmid DNA was detected in ten isolates belonging to the recently described thermophilic eubacterial species Thermus oshimai and isolated from hot springs in Portugal (eight isolates) and Iceland (two isolates). The estimated size of the large plasmids purified from T. oshimai SPS-18 from S. Pedro do Sul, Portugal, and from isolate JK-91 from Hveragerdhi-Hengill, Iceland, was 214 and 275 kb, respectively. No sequence homologous to isolate SPS-18 megaplasmid is present in chromosomal DNA as indicated by Southern hybridization analysis. Overall examination of the HindIII fragment profiles of megaplasmid DNAs purified from isolates from the same geographical area gave similar but not always identical restriction profiles on agarose gels. Restriction fragment length polymorphism (RFLP) was higher for megaplasmids present in isolates purified from the Portuguese and Icelandic isolates than for megaplasmids from the same hot spring. Megaplasmid RFLP correlated with previous results obtained on the polymorphism of macrorestriction patterns of whole genomic DNA and with the RFLP of co-resident small plasmid DNA that was found in one half of the isolates examined. The 16-kb HindIII-HindIII fragment from isolate SPS-18 megaplasmid showed DNA-DNA homology with restriction fragments of similar size generated by the large plasmids present in all the other isolates, even in those from hot springs of widely separated geographical areas. This suggests a high degree of sequence conservation in T. oshimai megaplasmids.

Comparative genomic analysis of isolates belonging to the six species of the genus Thermus using pulsed-field gel electrophoresis and ribotyping

Fifty isolates belonging to the six validly described species of the genus Thermus (T. aquaticus, T. filiformis, T. thermophilus, T. scotoductus, T. brockianus, and T. oshimai) isolated from hot springs of different geographical areas were compared using macrorestriction analysis of genomic DNA and ribotyping. With the exception of presumed clones, the macrorestriction patterns of isolates obtained with EcoRI or NdeI were distinct. However, isolates belonging to the same species exhibited similar profiles particularly when they were isolated from the same hot spring. The estimated genomic size of strains of the Thermus spp. varied between approximately 1.8 and 2.5 Mbp. Ribotyping with BamHI and HindIII produced 30 and 35 distinct ribotypes, respectively. In spite of the variability of the hybridization patterns produced, the ribotypes obtained for isolates belonging to the same species also shared, in general, several fragments of identical size, and these fragments were similar when isolates originated from the same spring.

Effect of extracellular acidification on the activity of plasma membrane ATPase and on the cytosolic and vacuolar pH of Saccharomyces cerevisiae

The rapid in vivo activation of Saccharomyces cerevisiae plasma membrane H+-ATPase that has been attributed to medium acidification from pH 6.5 to pH 3.5 is not caused by the low pH itself but is induced by the weak organic acid (succinic) used as the acidulant. The activation induced by 50 mM succinic acid at pH 3.5 occurred in both the presence or absence of glucose. Activation at pH 3.5 was also induced by acetic acid and it was maximal at 50 mM concentration. To investigate the role of plasma membrane ATPase activation in pH homeostasis, the internal pH (cytosolic and vacuolar) of yeast cells incubated in media at pH 6.5 or at pH 3.5, acidified either with HCl or acetic acid, were compared by using in vivo (31)P-NMR. Despite plasma membrane ATPase activation by acetic acid, the decrease in cytosolic pH caused by external acidification was much more important when the permeant acetic acid was used instead of HCl as the acidulant. The supplementation of the incubation medium at pH 3.5 with glucose led to higher cytosolic pH values, consistent with the observed in vivo activation of plasma membrane ATPase by glucose. At the external pH value of 6.5 the vacuole was maintained at a mildly acidic pH (around 6) while the cytosol was at about neutral pH; however, when cytoplasmic pH decreased due to external acidification, vacuolar pH accompanied that decrease. Vacuolar pH reached 5.4-5.5 during incubation with HCI and dropped sharply to values below 4.4 in cells incubated with acetic acid. These results indicate that the vacuole also plays a role in homeostasis of the intracellular pH.

HySP26 gene transcription is strongly induced during Saccharomyces cerevisiae growth at low pH

During exponential growth of Saccharomyces cerevisiae at the inhibitory pH 2.5, the transcription of the major small-heat-shock-protein-encoding gene HSP26 was strongly induced while at the optimal pH 5.0, the mRNA levels from the HSP26 gene were undetectable. When yeast cells entered the stationary phase of growth at pH 5.0, transcription was dramatically enhanced and the level of the HSP26 transcripts reached similar values in stationary cells grown at optimal or inhibitory low pH.

Effects of low temperatures (9-33 degrees C) and pH (3.3-5.7) in the loss of Saccharomyces cerevisiae viability by combining lethal concentrations of ethanol with octanoic and decanoic acids

Octanoic and decanoic acids increase the rate of loss of Saccharomyces cerevisiae viability caused by lethal concentrations of ethanol, the specific death rate being an exponential function of the acid concentration. The highly liposoluble decanoic acid is the most effective. The fatty acids deleterious effect increases at pH below pKa (4.9) mainly due to the increase of the undissociated form concentration. The temperature effects (range 9 33 degrees C; at pH 3.9) on the kinetics of the toxin(s)-induced death suggest that the deleterious action of ethanol, octanoic acid and decanoic acid have the same biological target sites, probably related to transport processes across membranes, particularly the plasma membrane. In fact, the enthalpies of activation of octanoic acid- and decanoic acid-enhanced-ethanol-induced death were similar and close to the enthalpy of activation of ethanol-induced death. This average value (delta H++ = 11.4 +/- 2.7 kcal/mol) is of the order of magnitude of that of solute transport across plasma membranes. Results clearly suggest the important contribution of octanoic and decanoic acids, combined with ethanol, in the loss of yeast viability at the last steps of industrial ethanolic fermentations, particularly those carried out at low or intermediate temperatures. They also support the combination of lipophilic acids with low pH in food preservation.

Emergence of Cu(++)-tolerant mutants defective in gellan synthesis in Cu(++)-stressed cultures of Sphingomonas paucimobilis

Cells defective in gellan synthesis appeared during cultivation of the gellan gum-producing strain Sphingomonas paucimobilis R40 with inhibitory concentrations of copper, supplied as CuCl2. The percentage of less mucoid colonial variants dramatically increased with the increase in Cu++ supplementation, reaching 85% of total viable cells at the maximal concentration for growth. Results reported in this work indicate that emergence of colonial variants defective in gellan synthesis results from Cu(++)-induced mutation and the growth advantage of these mutants in Cu(++)-stressed cultures. In fact, DNA homologous recombination strongly increased with the increase in copper supplementation as indicated by the regeneration of kanamycin-resistant cells of R40 harbouring plasmid pBX404-7, which carries two non-overlapping truncated genes derived from a gene conferring kanamycin resistance. The four major groups of colonial mutants that emerged from Cu(++)-stressed cultures of R40 exhibited reduced growth rate and biomass yield in the absence of Cu++ stress and produced decreased levels of exopolysac-charide (EPS) which yielded solutions of lower or negligible viscosity. The level of increased Cu++ tolerance of these mutants, assessed by the inhibitory effect of Cu++ on growth, correlated with the degree of loss of the ability to secrete high-molecular-mass EPS. Consistent with the growth advantage of gellan-defective mutants in Cu(++)-stressed cultures, the non-producing strain RP10, spontaneously obtained during extended cultivation of R40, also exhibited a higher tolerance to Cu++. In addition, its non-mucoid phenotype was stably maintained during Cu(++)-stressed cultivation despite the stimulation of homologous recombination by Cu++.

Oxygen-dependent upregulation of transcription of alginate genes algA, algC and algD in Pseudomonas aeruginosa

The mRNA levels of algA, algC and algD genes increased, coordinately, in cells of the highly mucoid Pseudomonas aeruginosa 8821M grown under increasing dissolved oxygen tensions (DOT) of up to 70% of air saturation. These genes encode the bifunctional protein with phosphomannose isomerase (PMI) and GDP-mannose pyrophosphorylase (GMP) activities (algA), the phosphomannomutase (PMM) (algC) and the GDP-mannose dehydrogenase (GMD) (algD). These four enzyme activities are necessary for the synthesis of GDP-mannuronic acid, which is the activated sugar precursor for alginate polymerization. For growth-limiting DOT--lower than 10% of air saturation--the increase in mRNA levels of algA, algC and algD with oxygen concentration was accompanied by a strong increase in the activity of the encoded enzymes and the consequent increase in alginate synthesis. However, and despite the upregulation of alginate gene transcription by DOT above 10% of air saturation, the activities of the encoded enzymes either maintained (GMP and GMD) or decreased (PMI and PMM) their levels at high oxygen tensions, leading to a slight decrease in alginate synthesis. This has previously been attributed to the oxidative inactivation of alginate enzymes, particularly of PMM and PMI activities.