Cell wall polysaccharides released during the alcoholic fermentation by Schizosaccharomyces pombe and S. japonicus: quantification and characterization.

The present work demonstrates that yeasts belonging to the Schizosaccharomyces genus release a high quantity of polysaccharides of cell wall origin starting from the onset of the alcoholic fermentation. By the end of the alcoholic fermentation, all of the Schizosaccharomyces yeast strains released a quantity of polysaccharides approximately 3-7 times higher than that released by a commercial Saccharomyces cerevisiae yeast strain under the same fermentative conditions of synthetic juice. A higher content of polysaccharide was found in media fermented by Schizosaccharomyces japonicus with respect to that of Schizosaccharomyces pombe. Some of the strains evaluated were also able to produce high levels of pyruvic acid, which has been shown to be an important compound for color stability of wine. The presence of strains with different malic acid consumption patterns along with high polysaccharide release would enable production of naturally modified wines with enhanced mouth feel and reduced acidity. The chemical analysis of the released polysaccharides demonstrated divergence between the two yeast species S. pombe and S. japonicus. A different mannose/galactose ratio and a different percentage of proteins was observed on the polysaccharides released by S. pombe as compared to S. japonicus. Analysis of the proteins released in the media revealed the presence of a glycoprotein with a molecular size around 32-33 kDa only for the species S. japonicus. Mass spectrometry analysis of carbohydrate moieties showed similar proportions among the N-glycan chains released in the media by both yeast species but differences between the two species were also observed. These observations suggest a possible role of rapid MALDI-TOF screening of N-glycans compositional fingerprint as a taxonomic tool for this genus. Polysaccharides release in the media, in particular galactomannoproteins in significant amounts, could make these yeasts particularly interesting also for the industrial production of exogenous polysaccharide preparations.

Use of non-Saccharomyces wine yeasts as novel sources of mannoproteins in wine.

Eight non-Saccharomyces wine strains, previously selected for their ability to modulate the final concentrations of various volatile compounds and to persist with Saccharomyces cerevisiae in mixed inocula fermentations of grape juice, have been analyzed in the present work to test their ability to release mannoproteins. The eight strains were members of different genera originally isolated from grape: Hansensiaspora osmophila, Lachancea thermotolerans, Metschnikowia pulcherrima, Pichia fermentans, Saccharomycodes ludwigii, Starmerella bacillaris, Torulaspora delbrueckii and Zygosaccharomyces florentinus. A synthetic polysaccharide-free grape juice, was used to characterize the mannoproteins released during the alcoholic fermentation. Mannoproteins profiles were characterized by gel electrophoresis and carbohydrate composition was analyzed both by HPLC and by mass spectrometry. The eight non-Saccharomyces yeasts demonstrated a higher capacity to release polysaccharides compared to S. cerevisiae. The proteins released by the eight yeast strains showed a wide variety of protein sizes, ranging from 25 kDa to greater than 250 kDa. The mass spectrometric profile of the N-glycans ranged from 1600 to 4000 Da and was characteristic for each strain. Detailed investigation of the degree of polymerization of released N-glycans revealed variable composition from 8 to 15 units of monosaccharides.

The HXT1 gene product of Saccharomyces cerevisiae is a new member of the family of hexose transporters.

Two novel genes affecting hexose transport in the yeast Saccharomyces cerevisiae have been identified. The gene HXT1 (hexose transport), isolated from plasmid pSC7, was sequenced and found to encode a hydrophobic protein which is highly homologous to the large family of sugar transporter proteins from eucaryotes and procaryotes. Multicopy expression of the HXT1 gene restored high-affinity glucose transport to the snf3 mutant, which is deficient in a significant proportion of high-affinity glucose transport. HXT1 was unable to complement the snf3 growth defect in low copy number. The HXT1 protein was found to contain 12 putative membrane-spanning domains with a central hydrophilic domain and hydrophilic N- and C-terminal domains. The HXT1 protein is 69% identical to GAL2 and 66% identical to HXT2, and all three proteins were found to have a putative leucine zipper motif at a consensus location in membrane-spanning domain 2. Disruption of the HXT1 gene resulted in loss of a portion of high-affinity glucose and mannose transport, and wild-type levels of transport required both the HXT1 and SNF3 genes. Unexpectedly, expression of beta-galactosidase activity by using a fusion of the lacZ gene to the HXT1 promoter in a multicopy plasmid was maximal during lag and early exponential phases of growth, decreasing approximately 100-fold upon further entry into exponential growth. Deletion analysis of pSC7 revealed the presence of another gene (called ORF2) capable of suppressing the snf3 null mutant phenotype by restoring high-affinity glucose transport and increased low-affinity transport.

The HXT2 gene of Saccharomyces cerevisiae is required for high-affinity glucose transport.

The HXT2 gene of the yeast Saccharomyces cerevisiae was identified on the basis of its ability to complement the defect in glucose transport of a snf3 mutant when present on the multicopy plasmid pSC2. Analysis of the DNA sequence of HXT2 revealed an open reading frame of 541 codons, capable of encoding a protein of Mr 59,840. The predicted protein displayed high sequence and structural homology to a large family of procaryotic and eucaryotic sugar transporters. These proteins have 12 highly hydrophobic regions that could form transmembrane domains; the spacing of these putative transmembrane domains is also highly conserved. Several amino acid motifs characteristic of this sugar transporter family are also present in the HXT2 protein. An hxt2 null mutant strain lacked a significant component of high-affinity glucose transport when under derepressing (low-glucose) conditions. However, the hxt2 null mutation did not incur a major growth defect on glucose-containing media. Genetic and biochemical analyses suggest that wild-type levels of high-affinity glucose transport require the products of both the HXT2 and SNF3 genes; these genes are not linked. Low-stringency Southern blot analysis revealed a number of other sequences that cross-hybridize with HXT2, suggesting that S. cerevisiae possesses a large family of sugar transporter genes.

Mutations in the pho80 gene confer permeability to 5'-mononucleotides in Saccharomyces cerevisiae.

Yeast mutants permeable to dTMP (tup) were selected and two new complementation groups (tup5 and tup7) were identified. Assay of the levels of both acid and alkaline phosphatase in cells grown under either repressing (5 mM PO4(-3) or derepressing (0.03 mM PO4(-3) conditions indicated that, in general, tup mutations cause cells to be defective in their regulation of phosphatase synthesis. In addition, three of the tup mutations (tup1, tup4 and tup7) displayed markedly elevated rates of inorganic phosphate transport. The tup7 locus was found to be tightly centromere-linked on the right arm of chromosome XV, and was shown to be allelic with the pho80 regulatory locus on the basis of both genetic and biochemical criteria. Analysis of other mutations known to affect phosphatase levels (pho) indicated that some also conferred permeability to dTMP. Possible allelic relationships between tup genes and certain of these pho mutations are discussed. Regardless of the culture conditions, wild-type strains were not permeable to dTMP; in contrast, it was found in the course of this work that normal yeast cells were permeable to dUMP and that dUMP permeability was regulated by the concentration of inorganic phosphate present in the medium used to grow the cells. Thus, permeability to 5'-mononucleotides appears to be under coordinate control with phosphatase synthesis.

Dominant and recessive suppressors that restore glucose transport in a yeast snf3 mutant.

The SNF3 gene of Saccharomyces cerevisiae encodes a high-affinity glucose transporter that is homologous to mammalian glucose transporters. To identify genes that are functionally related to SNF3, we selected for suppressors that remedy the growth defect of snf3 mutants on low concentrations of glucose or fructose. We recovered 38 recessive mutations that fall into a single complementation group, designated rgt1 (restores glucose transport). The rgt1 mutations suppress a snf3 null mutation and are not linked to snf3. A naturally occurring rgt1 allele was identified in a laboratory strain. We also selected five dominant suppressors. At least two are tightly linked to one another and are designated RGT2. The RGT2 locus was mapped 38 cM from SNF3 on chromosome IV. Kinetic analysis of glucose uptake showed that the rgt1 and RGT2 suppressors restore glucose-repressible high-affinity glucose transport in a snf3 mutant. These mutations identify genes that may regulate or encode additional glucose transport proteins.

High-copy suppression of glucose transport defects by HXT4 and regulatory elements in the promoters of the HXT genes in Saccharomyces cerevisiae.

HXT4, a new member of the hexose transporter (HXT) family in Saccharomyces cerevisiae was identified by its ability to suppress the snf3 mutation in multicopy. Multicopy HXT4 increases both high and low affinity glucose transport in snf3 strains and increases low and high transport in wild-type strains. Characterization of HXT4 led to the discovery of a new class of multicopy suppressors of glucose transport defects: regulatory elements in the promoters of the HXT genes. We have designated these sequences DDSEs (DNA sequence dependent suppressing element). Multicopy HXT4 and DDSEs in the HXT1, HXT2, HXT3 and HXT4 promoters were found to restore growth to snf3 and grr1 strains on low glucose media. The DDSE in the HXT4 promoter was refined to a 340-bp sequence 450 bp upstream of the HXT4 translational start. This region was found to contain an 183-amino acid open reading frame. Extensive analysis indicates that the DNA sequence itself and not the encoded protein is responsible for suppression. The promoters of SNF3 and of other glycolytic genes examined did not suppress snf3 in multicopy. Suppression of snf3 by DDSE is dependent on the presence of either HXT2 or HXT3.

Altered regulatory responses to glucose are associated with a glucose transport defect in grr1 mutants of Saccharomyces cerevisiae.

The GRR1 gene of Saccharomyces cerevisiae affects glucose repression, cell morphology, divalent cation transport and other processes. We present a kinetic analysis showing that the grr1 mutant is also defective in high affinity glucose transport. In combination with a mutation in SNF3, a member of the glucose transporter gene family, grr1 strikingly impairs growth on glucose. These findings suggest that GRR1 and SNF3 affect glucose transport by distinct pathways. The mutation rgt1-1, a suppressor of snf3, restores both glucose transport and glucose repression to a grr1 mutant, but does not remedy the morphological defect. We suggest that GRR1 affects the glucose sensing process and that the association between transport and regulation may reflect the involvement of a transporter in glucose sensing.

Adherence to Universal (barrier) Precautions during interventions on critically ill and injured emergency department patients.

In a study undertaken to determine compliance with Universal Precautions, we observed 129 personnel performing 1,274 interventions on 151 consecutive critically ill and injured patients in an emergency department setting in July 1988. Barrier precautions were fully adhered to 44.0% of the time. During interventions in patients with profuse bleeding, adherence was only 19.5% in contrast to 44.7% for those who were not bleeding. Adherence was 56.4% during minor interventions but only 16.7% during major procedures. Adherence rates varied among health care providers: residents, 58%; emergency staff physicians, 38%; consultant physicians, 43%; emergency nursing staff, 44%; paramedics, 8%; radiology technicians, 14%; and housekeeping, 91%. In a follow up questionnaire that ascertained reasons for lack of compliance, 47% of providers indicated that there was not always sufficient time to put on protective material, 33% felt that precautions interfered with skillful performance of procedures, and 23% stated that materials were uncomfortable. Only 2.7% felt that Universal Precautions did not work. Since there is no proven postexposure prophylaxis for human immunodeficiency virus, Universal Precautions must be rigorously followed until such time as they are shown not to be effective or an alternate approach is developed. Strategies to improve compliance and improvements in barrier technology need to be developed.

DDSE: downstream targets of the SNF3 signal transduction pathway.

Mutations in the yeast SNF3 gene affect glucose sensing and snf3 mutants show defective growth on glucose. DNA sequence dependent suppressing elements (DDSEs) are regions located in the promoters of yeast glucose transporter (HXT) genes that when present in high copy suppress the snf3 growth defect. Here we provide evidence that the multicopy DDSE suppression is due to the titration of the Rgt1p transcriptional repressor. The DDSE region from HXT4 was found to function as a UAS sequence rendering a UAS(gal)-less LacZ gene fused to the GAL1 promoter responsive to glucose induction. Expression mediated by the UAS(DDSE) was dependent upon the presence of Snf3p. Expression was elevated to a high level in an rgt1 mutant in the absence of Snf3p suggesting that this DDSE region contains binding sites for the Rgt1p transcriptional repressor/activator. The UAS(DDSE) led to expression in a grr1 mutant background, which confers a defect in inactivation of Rgt1p, as predicted from the model. The presence of tandem repeats of the putative Rgt1p binding site gave results similar to those of the DDSE, suggesting that loss of repression is due to the presence of Rgt1p footprint in the multicopy DDSE.

The C-terminal domain of Snf3p mediates glucose-responsive signal transduction in Saccharomyces cerevisiae.

The SNF3 protein is composed of distinct cytoplasmic and integral-membrane domains and functions as a low glucose sensor required for the expression of hexose transporters (the HXT genes) in Saccharomyces. We report herein that the C-terminal domain, when expressed independently of the integral membrane domain, leads to glucose-independent expression of HXT2 on gluconeogenic carbon sources. The C-terminal-domain-induced expression of Hxt2p is reduced in a SNF3 wild-type strain, suggesting that Snf3p competes with this C-terminal peptide for interacting downstream elements. The probable active site for the signal transducing interaction was mapped to either of the redundant 17 of 23 amino acid sequences found in this C-terminal domain.

Direct profiling of the yeast dynamics in wine fermentations.

We present a method to directly characterize the yeast diversity present in wine fermentations by employing denaturing gradient gel electrophoresis (DGGE) of polymerase chain reaction (PCR)-amplified 26S ribosomal RNA (rRNA) genes. PCR-DGGE of a portion of the 26S rRNA gene was shown to distinguish most yeast genera associated with the production of wine. With this method the microbial dynamics in several model wine fermentations were profiled. PCR-DGGE provided a qualitative assessment of the yeast diversity in these fermentations accurately identifying populations as low as 1000 cells ml(-1). PCR-DGGE represents an attractive alternative to traditional plating schemes for analysis of the microbial successions inherent in the fermentation of wine.

The anatomy of the pelvis in the exstrophy complex.

We compared computerized tomography scans of the pelvis of twenty-four patients who had exstrophy of the bladder with scans of age-matched controls in order to analyze the pelvic deformity that accompanies the variably severe manifestations of this condition. The patients who had classic exstrophy of the bladder were found to have a mean of 12 degrees of external rotation of the posterior aspect of the pelvis on each side, retroversion of the acetabula, a mean additional 18 degrees of external rotation and 30 per cent shortening of the pubic rami, and progressive diastasis of the symphysis pubis. The foot-progression angle demonstrated 20 to 30 degrees of external rotation beyond the normal limits seen in early childhood, but this improved with age. The patients who had exstrophy of the cloaca and the bladder not only had all of these pelvic deformities to a greater degree but also had asymmetry of measured parameters between the right and left sides of the pelvis, malformation of the sacro-iliac joints, and occasional dislocation of the hip. An understanding of the pelvic anatomy that accompanies exstrophy is essential when corrective approaches are planned. Such an understanding will improve the rate of success of both closure of the bladder and control of urinary continence postoperatively.

Jarcho-Levin syndrome: report on a long-term follow-up of an untreated patient.

Jarcho-Levin syndrome is a genetically transmitted rare entity characterized by multiple vertebral and rib anomalies. The multilevel skeletal involvement causes short stature, neck and thoracic cage deformities, and restrictive lung disease that is usually the cause of early death. The authors describe a 33-year follow-up of a patient with this syndrome who represents, to their best knowledge, the longest survival of a patient with this entity.

ACL reconstruction in children with open physes.

Nine male patients with wide open physes who underwent intra-articular anterior cruciate ligament (ACL) reconstruction using semitendinosus and gracilis tendon grafts passed through the tibial physis and over the top of the femoral condyles were retrospectively reviewed at an average follow-up of 39 months (range: 24 to 72 months). Five patients underwent reconstruction < 6 weeks following injury (range: 11 days to 41 days); the other four underwent reconstruction 2, 3, 5, and 24 months following injury. Seven patients had excellent results and fully returned to their sport. Mean Lysholm score in these patients was 99 (range: 95 to 100), and the mean maximum KT-1000 difference (available for six patients) was 2.8 mm (range: 0 to 5.5 mm). Four of six intact grafts had a mean maximum KT-1000 difference < or = 3.5 mm. Two grafts ruptured and were considered failures (one complete rupture at 10 months and one partial rupture at 3 years). Postoperative height increase averaged 10.7 cm (range: 4 to 22.9 cm). No patient had a clinically significant leg-length discrepancy, angular deformity, or radiographic evidence of physeal injury.

Transient gene expression in HEK293 cells: peptone addition posttransfection improves recombinant protein synthesis.

Gene expression by large-scale transfection of mammalian cells is becoming an established technology for the fast production of milligram and even gram amounts of recombinant proteins (r-proteins). However, efforts are still needed to optimize production parameters in order to maximize volumetric productivities while maintaining product quality. In this study, transfection efficiency and volumetric productivity following transient gene expression in HEK293 cells were evaluated using green fluorescent protein (GFP) and human placental secreted alkaline phosphatase (SEAP) as reporter genes. We show that a single pulse of peptones (protein hydrolysates) to the cultures performed in a low serum (1%, v/v) and in serum-free medium results in a significant increase in volumetric protein productivity. Sixteen peptones from different sources were tested and almost all of them showed a positive effect on r-protein production. This effect, however, is time- and concentration-dependent. By using Tryptone N1 (a casein peptone, TN1) to feed the cultures at 24 h posttransfection (hpt), a 2-fold increase in volumetric SEAP productivity was obtained 5 days posttransfection. This effect was shown to be equal to that obtained when the culture was fed with a supplementary 4% (v/v) of serum. The positive effect of TN1 on protein production was also demonstrated with Tie2 protein ectodomain produced in serum-free medium. HPLC analysis of amino acids consumption/production during control batch and TN1 pulse culture showed some major differences in amino acid metabolism when using TN1 pulse. Asparagine, glycine, histidine, threonine, leucine, and valine show accumulation in the medium over the cultivation period instead of being consumed as observed in unfed sample (except for asparagine, which remained unchanged). Isoleucine, tyrosine, methionine, and phenylalanine all remained unchanged or slightly fluctuated in TN1-fed culture after the feeding pulse, while they were all steadily consumed in the control run. The relative abundance of SEAP's mRNA suggests that the improvement in protein yield results both from an increase of the translational activity and transcription efficiency. Further understanding of mechanisms by which amino acids/peptides regulate transcriptional and translational machinery in mammalian cells should facilitate the design of new strategies for the improvement of r-protein production by large-scale transfection.

High-affinity glucose transport in Saccharomyces cerevisiae is under general glucose repression control.

Saccharomyces cerevisiae mutants defective in growth on low glucose concentration (lgn mutants) were isolated and screened for abnormal glucose transport. Nine complementation groups were identified, falling into two broad groups: those unable to significantly derepress high-affinity (low-Km) glucose uptake (lgn1, lgn4, lgn5, lgn7, and lgn8), and those with elevated repressed levels of high-affinity uptake that either derepress to normal or near normal levels of high-affinity uptake with loss of low-affinity transport (lgn2 and lgn3) or derepress only slightly, appearing to have an intermediate yet constitutive level of high-affinity transport (lgn6 and lgn9). Further analysis of the lgn mutations revealed pleiotropic phenotypes most consistent with the true defect being in regulation or expression of glucose repression and derepression. The kinetics of glucose uptake in strains carrying known mutations preventing derepression of glucose-repressible functions (snf1, snf2, snf4, and snf6) demonstrated that three of these mutations (snf1, snf4, and snf6) were similarly defective in derepression of high-affinity glucose uptake. The snf2 and snf5 mutations had no apparent effect on glucose uptake. Two mutations resulting in constitutive expression of glucose-repressible functions, cid1 and reg1, resulted in constitutive expression of high-affinity glucose uptake. These data support the conclusion that high-affinity glucose uptake in Saccharomyces cerevisiae is under general glucose repression control. The implications of other properties of these mutants are discussed.

Derepression of high-affinity glucose uptake requires a functional secretory system in Saccharomyces cerevisiae.

The expression of high-affinity glucose uptake in Saccharomyces cerevisiae strains carrying conditional mutations conferring a block of secretion and cell surface growth (sec) revealed a requirement for a functional secretory pathway for derepression of carrier activity. Thus, in strains carrying the sec1-1, sec4-2, sec7-1, sec14-3, or sec17-1 mutation, no high-affinity carrier activity was expressed after a shift to derepressing glucose concentrations at the nonpermissive temperature. In the case of sec18-1, however, derepression of carrier activity did occur at both the permissive and nonpermissive temperature, but not to the same extent as found in the wild-type strain, suggesting that SEC18 function may not be essential for expression of carrier activity. In sec1-1, accumulation of high-affinity carrier activity (or a component thereof) in presecretory vesicles during incubation at the nonpermissive temperature was demonstrated. The presence of a high glucose concentration in the medium did not affect transfer of that accumulated carrier function to the cell surface. Carrier function did not accumulate in strains carrying the other sec mutations. Analysis of the stability of high-affinity carrier activity at 37 degrees C demonstrated rapid and unexpected loss of carrier activity not affected by the presence of glucose in the medium. Thus, blockage of cell surface growth seems to affect turnover rates of hexose carrier activities.

Thymidine 5'-monophosphate-requiring mutants of Saccharomyces cerevisiae are deficient in thymidylate synthetase.

Thymidylate synthetase activity was measured in crude extracts of the yeast Saccharomyces cerevisiae by a sensitive radiochemical assay. Spontaneous non-conditional mutants auxotrophic for thymidine 5'-monophosphate (tmp1) lacked detectable thymidylate synthetase activity in cell-free extracts. In contrast, the parent strains (tup1, -2, or -4), which were permeable to thymidine 5'-monophosphate, contained levels of activity similar to those found in wild-type cells. Specific activity of thymidylate synthetase in crude extracts of normal cells or of cells carrying tup mutations was essentially unaffected by the ploidy or mating type of the cells, by the medium used for growth, by the respiratory capacity of the cells, by concentrations of exogenous thymidine 5'-monophosphate as high as 50 mug/ml, or by subsequent removal of thymidine 5'-monophosphate from the medium. Extracts of a strain bearing the temperature-sensitive cell division cycle mutation cdc21 lacked detectable thymidylate synthetase activity under all conditions tested. Its parent and another mutant (cdc8), which arrests with the same terminal phenotype under restrictive conditions, had normal levels of the enzyme. Cells of a temperature-sensitive thymidine 5'-monophosphate auxotroph arrested with a morphology identical to the cdc21 strain at the nonpermissive temperature and contained demonstrably thermolabile thymidylate synthetase activity. Tetrad analysis and the properties of revertants showed that the thymidylate synthetase defects were a consequence of the same mutation causing, in the auxotrophs, a requirement for thymidine 5'-monophosphate and, in the conditional mutants, temperature sensitivity. Complementation tests indicated that tmp1 and cdc21 are the same locus. These results identify tmp1 as the structural gene for yeast thymidylate synthetase.

Exogenous dTMP utilization by a novel tup mutant of Saccharomyces cerevisiae.

The rate and extent of entry of dTMP were measured in strains of Saccharomyces cerevisiae carrying two new tup mutations (tup5 and tup7) and most of the other tup mutations which have been reported previously by others. The tup7 mutation allowed dramatically greater accumulation of dTMP than any of the other mutations tested. Specific labeling of DNA by [CH3-3H]dTMP, fate of the dTMP pool inside of the cells, and degradation of the dTMP in the culture medium were investigated in strains carrying the tup7 mutation. The extracellular dTMP was not appreciably degraded, and that accumulated intracellularly was readily phosphorylated to dTDP and dTTP. Under optimum labeling conditions, 60 to 80% of the total thymidylate residues in newly synthesized DNA were derived from the exogenously provided dTMP, even in the absence of a block in de novo dTMP biosynthesis. An apparent Km for entry of 2 mM dTMP was found. The tup7 mutation increased permeability to dTMP (and some other 5'-mononucleotides), but did not affect uptake of nucleosides and purine and pyrimidine bases. Uptake of dTMP could be almost completely inhibited by moderate concentrations of Pi. These findings and other observations suggest that entry of dTMP in strains carrying the tup7 mutation is mediated by a permease whose function in normal cells is the transport of Pi.