Jean Marie Francois - Academia.edu (original) (raw)

Papers by Jean Marie Francois

HAL (Le Centre pour la Communication Scientifique Directe), 2003

The cell wall integrity is mainly under the control of the Pkc1-MAP kinase pathway_8 Coordination... more The cell wall integrity is mainly under the control of the Pkc1-MAP kinase pathway_8 Coordination between cell wall biogenesis and cell proliferation _________________10 Knr4 as an element for the coordination between cell wall integrity and cell proliferation ____________________________________________________________11 BIOCHEMISTRY AND MOLECULAR ANALYSIS OF THE CELL WALL REPAIR MECHANISM ____________________________________________________________13 BIOTECHNOLOGICAL VALUES OF THE CELL WALL COMPONENTS __________15 Biotechnological values in traditional use of yeasts ____________________________15 Yeast flocculation and flotation in beverages _________________________________15 Yeast polysaccharides in winemaking_______________________________________15 Cell wall components as a benefit for human health ___________________________16 Animal Nutrition and Prevention against Mycotoxins _________________________16 Cell Wall Engineering ____________________________________________________17 Strategies to weaken the yeast cell wall ______________________________________17 Ideal target for antifungal agents ? _________________________________________17

BMC Molecular Biology, Oct 30, 2009

Background: Real-time RT-PCR is the recommended method for quantitative gene expression analysis.... more Background: Real-time RT-PCR is the recommended method for quantitative gene expression analysis. A compulsory step is the selection of good reference genes for normalization. A few genes often referred to as HouseKeeping Genes (HSK), such as ACT1, RDN18 or PDA1 are among the most commonly used, as their expression is assumed to remain unchanged over a wide range of conditions. Since this assumption is very unlikely, a geometric averaging of multiple, carefully selected internal control genes is now strongly recommended for normalization to avoid this problem of expression variation of single reference genes. The aim of this work was to search for a set of reference genes for reliable gene expression analysis in Saccharomyces cerevisiae. Results: From public microarray datasets, we selected potential reference genes whose expression remained apparently invariable during long-term growth on glucose. Using the algorithm geNorm, ALG9, TAF10, TFC1 and UBC6 turned out to be genes whose expression remained stable, independent of the growth conditions and the strain backgrounds tested in this study. We then showed that the geometric averaging of any subset of three genes among the six most stable genes resulted in very similar normalized data, which contrasted with inconsistent results among various biological samples when the normalization was performed with ACT1. Normalization with multiple selected genes was therefore applied to transcriptional analysis of genes involved in glycogen metabolism. We determined an induction ratio of 100-fold for GPH1 and 20-fold for GSY2 between the exponential phase and the diauxic shift on glucose. There was no induction of these two genes at this transition phase on galactose, although in both cases, the kinetics of glycogen accumulation was similar. In contrast, SGA1 expression was independent of the carbon source and increased by 3-fold in stationary phase. Conclusion: In this work, we provided a set of genes that are suitable reference genes for quantitative gene expression analysis by real-time RT-PCR in yeast biological samples covering a large panel of physiological states. In contrast, we invalidated and discourage the use of ACT1 as well as other commonly used reference genes (PDA1, TDH3, RDN18, etc) as internal controls for quantitative gene expression analysis in yeast.

Molecular Genetics and Genomics, Jun 22, 2004

Combinatorial control by the protein kinases PKA, PHO85 and SNF1 of transcriptional induction of ... more Combinatorial control by the protein kinases PKA, PHO85 and SNF1 of transcriptional induction of the Saccharomyces cerevisiae GSY2 gene at the diauxic shift Abstract Genes involved in storage carbohydrate metabolism are coordinately induced when yeast cells are subjected to conditions of stress, or when they exit the exponential growth phase on glucose. We show that the STress Responsive Elements (STREs) present in the promoter of GSY2 are essential for gene activation under conditions of stress, but dispensable for gene induction and glycogen accumulation at the diauxic shift on glucose. Using serial promoter deletion, we found that the latter induction could not be attributed to a single cis-regulatory sequence, and present evidence that this mechanism depends on combinatorial transcriptional control by signalling pathways involving the protein kinases Pho85, Snf1 and PKA. Two contiguous regions upstream of the GSY2 coding region are necessary for negative control by the cyclin-dependent protein kinase Pho85, one of which is a 14-bp G/C-rich sequence. Positive control by Snf1 is mediated by Mig1p, which acts indirectly on the distal part of the GSY2 promoter. The PKA pathway has the most pronounced effect on GSY2, since transcription of this gene is almost completely abolished in an ira1ira2 mutant strain in which PKA is hyperactive. The potent negative effect of PKA is dependent upon a branched pathway involving the transcription factors Msn2/Msn4p and Sok2p. The SOK2 branch was found to be effective only under conditions of high PKA activity, as in a ira1ira2 mutant, and this effect was independent of Msn2/4p. The Msn2/ 4p branch, on the other hand, positively controls GSY2 expression directly through the STREs, and indirectly via a factor that still remains to be discovered. In summary, this study shows that the transcription of GSY2 is regulated by several different signalling pathways which reflect the numerous factors that influence glycogen synthesis in yeast, and suggests that the PKA pathway must be deactivated to allow gene induction at the diauxic shift.

FEBS Letters, Jul 25, 2007

The lack of trehalose accumulation in most plant species has been partly attributed to the presen... more The lack of trehalose accumulation in most plant species has been partly attributed to the presence of an active treha-lase. Although trehalose synthesis enzymes are thought to be cytosolic, and previous studies have indicated that trehalase activity is extracellular, the exact location of the enzyme has not yet been established in plant cell. We present evidence that the yet uncharacterised full-length Arabidopsis trehalase is a plasma membrane-bound protein, probably anchored to the membrane through a predicted N-terminal membrane spanning domain. The full-length AtTRE1, when expressed in yeast can functionally substitute for the extracellularly active trehalase Ath1p, by sustaining the growth of an ath1 null mutant strain on trehalose and at pH 4.8. We further demonstrate that At-TRE1 expressed in yeast is plasma membrane-bound as in plant cell. In light of these findings, the regulation of plant cell endog-enous trehalose by trehalase is discussed.

Yeast, Oct 1, 1999

It has been shown that the so-called stationary phase GSY2 gene encoding glycogen synthase was in... more It has been shown that the so-called stationary phase GSY2 gene encoding glycogen synthase was induced as the cells left the exponential phase of growth, while glucose and all other nutrients were still plentiful in the medium (Parrou et al., 1999). Since this effect was essentially controlled at the transcriptional level, we looked for the cis-and transacting elements required for this specific growth-related genetic event. We demonstrated that mutations of the HAP2/3/4 binding site and of the two STress-Responsive cis-Elements (STRE) did not abolish the early induction of GSY2, although the latter mutation led to a 20-fold drop in the transcriptional activity of the promoter, as determined from lacZ gene fusions. Insertion of a DNA fragment (from 390 to 167 bp, relative to the ATG) of the promoter lacking the two STREs, upstream to the TATA box of a CYC1-lacZ fusion gene, allowed this reporter gene to be induced with a kinetic similar to that of GSY2-lacZ. Mutations in BCY1, which results in a hyperactive protein kinase A, did not alleviate the early induction, while causing a five-to 10-fold reduction in the transcriptional activity of GSY2. In addition, the repressive effect of protein kinase A was quantitatively conserved when both STREs were mutated in GSY2 promoter, indicating that the negative control of gene expression by the RAS-cAMP signalling pathway does not act solely through STREs. Taken together, these results are indicative of an active process that couples growth control to dynamic glucose consumption.

Applied and Environmental Microbiology, Feb 1, 2008

In the yeast Saccharomyces cerevisiae, the synthesis of endogenous trehalose is catalyzed by a tr... more In the yeast Saccharomyces cerevisiae, the synthesis of endogenous trehalose is catalyzed by a trehalose synthase complex, TPS, and its hydrolysis relies on a cytosolic/neutral trehalase encoded by NTH1. In this work, we showed that NTH2, a paralog of NTH1, encodes a functional trehalase that is implicated in trehalose mobilization. Yeast is also endowed with an acid trehalase encoded by ATH1 and an H ؉ /trehalose transporter encoded by AGT1, which can together sustain assimilation of exogenous trehalose. We showed that a tps1 mutant defective in the TPS catalytic subunit cultivated on trehalose, or on a dual source of carbon made of galactose and trehalose, accumulated high levels of intracellular trehalose by its Agt1p-mediated transport. The accumulated disaccharide was mobilized as soon as cells entered the stationary phase by a process requiring a coupling between its export and immediate extracellular hydrolysis by Ath1p. Compared to what is seen for classical growth conditions on glucose, this mobilization was rather unique, since it took place prior to that of glycogen, which was postponed until the late stationary phase. However, when the Ath1p-dependent mobilization of trehalose identified in this study was impaired, glycogen was mobilized earlier and faster, indicating a fine-tuning control in carbon storage management during periods of carbon and energy restriction.

ABSTRACTFlocculins are a family of glycosylated proteins that provide yeast cells with several pr... more ABSTRACTFlocculins are a family of glycosylated proteins that provide yeast cells with several properties such as biofilm formation, flocculation, invasive growth or formation of velum. These proteins are similarly organised with a N-terminal (adhesion) domain, a stalk-like central B-domain with several repeats and a C-terminal sequence carrying a cell wall anchor site. They also contain amyloid β-aggregation-prone sequences whose functional role is still unclear. In this work, we show that Flo11p differs from other flocculins by the presence of unique amyloid-forming sequences, whose the number is critical in the formation of adhesion nanodomains under a physical shear force. Using a genome editing approach to identify the function of domains in Flo11p phenotypes, we show that the formation of cellular aggregates whose density increases with the number of amyloid sequences cannot be attributed to a specific domain of Flo11p. The same is true for plastic adhesion and surface hydroph...

Journal of Bacteriology, 1999

The trehalose content in Saccharomyces cerevisiae can be significantly manipulated by including t... more The trehalose content in Saccharomyces cerevisiae can be significantly manipulated by including trehalose at an appropriate level in the growth medium. Its uptake is largely dependent on the expression of AGT1 , which encodes an α-glucoside transporter. The trehalose found in a tps1 mutant of trehalose synthase may therefore largely reflect its uptake from the enriched medium that was employed.

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Microbial cell (Graz, Austria), 2018

The yeast trehalose-6-phosphate synthase (Tps1) catalyzes the formation of trehalose-6-phosphate ... more The yeast trehalose-6-phosphate synthase (Tps1) catalyzes the formation of trehalose-6-phosphate (T6P) in trehalose synthesis. Besides, Tps1 plays a key role in carbon and energy homeostasis in this microbial cell, as shown by the well documented loss of ATP and hyper accumulation of sugar phosphates in response to glucose addition in a mutant defective in this protein. The inability of a mutant to cope with fermentable sugars is still a matter of debate. We reexamined this question through a quantitative analysis of the capability of homologues from different origins to complement phenotypic defects of this mutant. Our results allowed to classify this complementation in three groups. A first group enclosed of with that of as their expression in cells fully recovered wild type metabolic patterns and fermentation capacity in response to glucose. At the opposite was the group with homologues from the bacteria and , the plant and the insect whose metabolic profiles were comparable to t...

Biochemical Journal, 1992

When the temperature of exponential-phase cultures of Saccharomyces cerevisiae was abruptly raise... more When the temperature of exponential-phase cultures of Saccharomyces cerevisiae was abruptly raised from 28 to 40 degrees C, trehalose immediately accumulated, whereas the activities of trehalase and trehalose-6-phosphate synthase/trehalose-6-phosphate phosphatase complex increased after a lag period of about 10 min. Heat shock also induced a sudden rise in intracellular glucose, simultaneously with a decrease in the concentration of hexose phosphate and fructose 2,6-bisphosphate. The increase of trehalose-metabolizing enzymes, but not the accumulation of glucose and trehalose, was prevented by cycloheximide. Investigation of the kinetic properties of partially purified enzymes showed that both non-activated and cyclic AMP-dependent-protein-kinase-activated forms of trehalase are almost inactive in the absence of Ca2+ and that the concentration of free Ca2+ required for half-maximal activity increased with increasing temperature, being approx. 1 microM at 30 degrees C and 20 microM a...

Microbiology, 2000

Mutant strains of Saccharomyces cerevisiae defective in respiration have been reported to be unab... more Mutant strains of Saccharomyces cerevisiae defective in respiration have been reported to be unable to store glycogen, as revealed by the iodine-staining method. In this report, it is shown that in contrast to this claim, mitochondrial respiratory mutants accumulated even more glycogen than wild-type cells during the fermentative growth on glucose. However, as soon as glucose was exhausted in the medium, these mutants readily and completely mobilized their glycogen content, contrary to wild-type cells which only transiently degraded this polymer. The mobilization of glycogen was a specific trait resulting from a defect in mitochondrial function that could not be suppressed by mutations in the cAMP-and Pho85 protein kinase-dependent nutrientsensing pathways, and by other mutations which favour glycogen synthesis. To account for this mobilization, it was found that respiration-defective cells not only contained a less active glycogen synthase, but also a more active glycogen phosphorylase. Since glucose 6-phosphate (Glc6P) is a potent inhibitor of the phosphorylation and an activator of the dephosphorylation processes of glycogen synthase and glycogen phosphorylase, it is suggested that the drop in Glc6P observed at the onset of glucose depletion in respiration-deficient cells triggers this rapid and sustained glycogen mobilization. It is also proposed that this degradation provides the energy for the viability of respiratory mutants in glucose-starved medium.

The Journal of biological chemistry, Jan 26, 2015

Trehalose is a stable disaccharide commonly found in nature, from bacteria to fungi and plants. F... more Trehalose is a stable disaccharide commonly found in nature, from bacteria to fungi and plants. For the model yeast Saccharomyces cerevisiae, claims that trehalose is a stress protectant were based indirectly either on correlation between accumulation of trehalose and high resistance to various stresses or on stress hypersensitivity of mutants deleted for TPS1, which encodes the first enzyme in trehalose biosynthetic pathway. Our goal was to investigate more directly which one, between trehalose and/or the Tps1 protein, may serve yeast cells to withstand exposure to stress. By employing an original strategy that combined the use of mutant strains expressing catalytically inactive variants of Tps1, with MAL(+) yeast strains able to accumulate trehalose from an exogenous supply, we bring for the first time unbiased proof that trehalose does not protect yeast cells from dying and that the stress-protecting role of trehalose in this eukaryotic model was largely overestimated. Conversely...

Yeast, 1999

The dynamic responses of reserve carbohydrates with respect to shortage of either carbon or nitro... more The dynamic responses of reserve carbohydrates with respect to shortage of either carbon or nitrogen source was studied to obtain a sound basis for further investigations devoted to the characterization of mechanisms by which the yeast Saccharomyces cerevisiae can cope with nutrient limitation during growth. This study was carried out in well-controlled bioreactors which allow accurate monitoring of growth and frequent sampling without disturbing the culture. Under glucose limitation, genes involved in glycogen and trehalose biosynthesis (GLG1, GSY1, GSY2, GAC1, GLC3, TPS1), in their degradation (GPH1, NTH1), and the typical stress-responsive CTT1 gene were coordinately induced in parallel with glycogen, when the growth has left the pure exponential phase and while glucose was still plentiful in the medium. Trehalose accumulation was delayed until the diauxic shift, although TPS1 was induced much earlier, due to hydrolysis of trehalose by high trehalase activity. In contrast, under nitrogen limitation, both glycogen and trehalose began to accumulate at the precise time when the nitrogen source was exhausted from the medium, coincidentally with the transcriptional activation of genes involved in their metabolism. While this response to nitrogen starvation was likely mediated by the stress-responsive elements (STREs) in the promoter of these genes, we found that these elements were not responsible for the co-induction of genes involved in reserve carbohydrate metabolism during glucose limitation, since GLG1, which does not contain any STRE, was coordinately induced with GSY2 and TPS1.

Yeast, 1999

Molecular Systems Biology, 2010

Respiring Saccharomyces cerevisiae cells respond to a sudden increase in glucose concentration by... more Respiring Saccharomyces cerevisiae cells respond to a sudden increase in glucose concentration by a pronounced drop of their adenine nucleotide content ([ATP]+[ADP]+[AMP]=[AXP]). The unknown fate of ‘lost’ AXP nucleotides represented a long‐standing problem for the understanding of the yeast's physiological response to changing growth conditions. Transient accumulation of the purine salvage pathway intermediate, inosine, accounted for the apparent loss of adenine nucleotides. Conversion of AXPs into inosine was facilitated by AMP deaminase, Amd1, and IMP‐specific 5′‐nucleotidase, Isn1. Inosine recycling into the AXP pool was facilitated by purine nucleoside phosphorylase, Pnp1, and joint action of the phosphoribosyltransferases, Hpt1 and Xpt1. Analysis of changes in 24 intracellular metabolite pools during the respiro‐fermentative growth transition in wild‐type, amd1, isn1, and pnp1 strains revealed that only the amd1 mutant exhibited significant deviations from the wild‐type be...

Molecular Genetics and Genomics, 2004

Microbiology, 1997

It is well known that glycogen and trehalose accumulate in yeast under nutrient starvation or ent... more It is well known that glycogen and trehalose accumulate in yeast under nutrient starvation or entering into the stationary phase of growth, and that high levels of trehalose are found in heat-shocked cells. However, effects of various types of stress on trehalose, and especially on glycogen, are poorly documented. Taking into account that almost all genes encoding the enzymes involved in the metabolism of these two reserve carbohydrates contain between one and several copies of the stress-responsive element (STRE), an investigation was made of the possibility of a link between the potential transcriptional induction of these genes and the accumulation of glycogen and trehalose under different stress conditions. Using transcriptional fusions, it was found that all these genes were induced in a similar fashion, although to various extents, by temperature, osmotic and oxidative stresses. Experiments performed with an msn2/msn4 double mutant proved that the transcriptional induction of ...

Microbiology, 1998

A pma1-1 mutant of Saccharomyces cerevisiae with reduced H+-ATPase activity and the isogenic wild... more A pma1-1 mutant of Saccharomyces cerevisiae with reduced H+-ATPase activity and the isogenic wild-type strain accumulated high levels of trehalose in response to a temperature upshift to 40 éC and after addition of 10% ethanol, but only modest levels in response to a rapid drop in external pH and after addition of decanoic acid. There was, however, no correlation between the absolute levels of trehalose in the stressed cells and their viability. All these treatments induced a significant decrease in intracellular pH, and surprisingly, this decrease was very similar in both strains, indicating that intracellular acidification could not be the triggering mechanism for trehalose accumulation in response to stress. A careful investigation of metabolic parameters was carried out to explain how trehalose accumulated under the four different stress conditions tested. No single and common mechanism for trehalose accumulation could be put forward and the transcriptional activation of TPS1 wa...

Journal of Insect Physiology, 2010

Trehalose is an important disaccharide and a key regulation factor for the development of many or... more Trehalose is an important disaccharide and a key regulation factor for the development of many organisms, including plants, bacteria, fungi and insects. In order to study the trehalose synthesis pathway, a cDNA for a trehalose-6-phosphate synthase from Spodoptera exigua (SeTPS) was cloned which contained an open reading frame of 2481 nucleotides encoding a protein of 826 amino acids with a predicted molecular weight of 92.65kDa. The SeTPS genome has 12 exons and 11 introns. Northern blot and RT-PCR analyses showed that SeTPS mRNA was expressed in the fat body and in the ovary. Competitive RT-PCR revealed that SeTPS mRNA was expressed in the fat body at different developmental stages and was present at a high level in day 1 S. exigua pupae. The concentrations of trehalose and glucose in the hemolymph were determined by HPLC and showed that they varied at different developmental stages and were negatively correlated to each other. The survival rates of the insects injected with dsRNA corresponding to SeTPS gene reached 53.95%, 49.06%, 34.86% and 33.24% for 36, 48, 60 and 204h post-injection respectively which were significantly lower than those of the insects in three control groups. These findings provide new data on the tissue distribution, expression patterns and potential function of the trehalose-6-phosphate synthase gene.

FEMS Yeast Research, 2004

The purpose of this study was to explore the role of glycogen and trehalose in the ability of Sac... more The purpose of this study was to explore the role of glycogen and trehalose in the ability of Saccharomyces cerevisiae to respond to a sudden rise of the carbon flux. To this end, aerobic glucose-limited continuous cultures were challenged with a sudden increase of the dilution rate from 0.05 to 0.15 h À1. Under this condition, a rapid mobilization of glycogen and trehalose was observed which coincided with a transient burst of budding and a decrease of cell biomass. Experiments carried out with mutants defective in storage carbohydrates indicated a predominant role of glycogen in the adaptation to this perturbation. However, the real importance of trehalose in this response was veiled by the unexpected phenotypes harboured by the tps1 mutant, chosen for its inability to synthesize trehalose. First, the biomass yield of this mutant was 25% lower than that of the isogenic wild-type strain at dilution rate of 0.05 h À1 , and this difference was annulled when cultures were run at a higher dilution rate of 0.15 h À1. Second, the tps1 mutant was more effective to sustain the dilution rate shift-up, apparently because it had a faster glycolytic rate and an apparent higher capacity to consume glucose with oxidative phosphorylation than the wild type. Consequently, a tps1gsy1gsy2 mutant was able to adapt to the dilution rate shift-up after a long delay, likely because the detrimental effects from the absence of glycogen was compensated for by the tps1 mutation. Third, a glg1Dglg2D strain, defective in glycogen synthesis because of the lack of the glycogen initiation protein, recovered glycogen accumulation upon further deletion of TPS1. This recovery, however, required glycogen synthase. Finally, we demonstrated that the rapid breakdown of reserve carbohydrates triggered by the shift-up is merely due to changes in the concentrations of hexose-6-phosphate and UDPglucose, which are the main metabolic effectors of the rate-limiting enzymes of glycogen and trehalose pathways.

HAL (Le Centre pour la Communication Scientifique Directe), 2003

BMC Molecular Biology, Oct 30, 2009

Molecular Genetics and Genomics, Jun 22, 2004

FEBS Letters, Jul 25, 2007

Yeast, Oct 1, 1999

Applied and Environmental Microbiology, Feb 1, 2008

Journal of Bacteriology, 1999

$Research paper thumbnail of {"__content__"=>"Trehalose-6-phosphate promotes fermentation and glucose repression in .", "i"=>{"__content__"=>"Saccharomyces cerevisiae"}}$

Microbial cell (Graz, Austria), 2018

Biochemical Journal, 1992

Microbiology, 2000

The Journal of biological chemistry, Jan 26, 2015

Yeast, 1999

Molecular Systems Biology, 2010

Molecular Genetics and Genomics, 2004

Microbiology, 1997

Microbiology, 1998

Journal of Insect Physiology, 2010

FEMS Yeast Research, 2004