The elimination of the yeast [PSI+] prion by guanidine hydrochloride is the result of Hsp104 inactivation.

In the yeast Saccharomyces cerevisiae, Sup35p (eRF3), a subunit of the translation termination complex, can take up a prion-like, self-propagating conformation giving rise to the non-Mendelian [PSI+] determinant. The replication of [PSI+] prion seeds can be readily blocked by growth in the presence of low concentrations of guanidine hydrochloride (GdnHCl), leading to the generation of prion-free [psi-] cells. Here, we provide evidence that GdnHCl blocks seed replication in vivo by inactivation of the molecular chaperone Hsp104. Although growth in the presence of GdnHCl causes a modest increase in HSP104 expression (20-90%), this is not sufficient to explain prion curing. Rather, we show that GdnHCl inhibits two different Hsp104-dependent cellular processes, namely the acquisition of thermotolerance and the refolding of thermally denatured luciferase. The inhibitory effects of GdnHCl protein refolding are partially suppressed by elevating the endogenous cellular levels of Hsp104 using a constitutive promoter. The kinetics of GdnHCl-induced [PSI+] curing could be mimicked by co-expression of an ATPase-negative dominant HSP104 mutant in an otherwise wild-type [PSI+] strain. We suggest that GdnHCl inactivates the ATPase activity of Hsp104, leading to a block in the replication of [PSI+] seeds.

SUT1 is a putative Zn[II]2Cys6-transcription factor whose upregulation enhances both sterol uptake and synthesis in aerobically growing Saccharomyces cerevisiae cells.

Budding yeast Saccharomyces cerevisiae is a facultative anaerobe whose growth upon oxygen starvation depends on its capacity to import exogenously supplied sterols, whereas the cells are not permeable to these molecules when grown aerobically. Few genes have been identified as being involved in sterol uptake. A higher SUT1 gene dosage leads to a modest, but significant, increase in sterol uptake under aerobic conditions. Based on sequence and physiological data, SUT1 is a hypoxic gene negatively regulated when the cells are grown in the presence of oxygen. We replaced the SUT1 promoter with the constitutive PMA1 gene promoter in order to enhance its transcription. We observed that sterol uptake was then comparable with that obtained with a sterol importing hem1 mutant, although the heme status of the strain was not modified in a process which still occurs when the cells are not growing. Unexpectedly, SUT1 constitutive expression led to a parallel significant increase in endogenous sterol biosynthesis. Moreover, here we present new data showing that the structurally related YPR009 gene (SUT2) is a functional homologue of SUT1, and that both gene products may represent two novel yeast regulatory proteins involved in sterol uptake.

Sterol uptake in Saccharomyces cerevisiae heme auxotrophic mutants is affected by ergosterol and oleate but not by palmitoleate or by sterol esterification.

The relationship between sterol uptake and heme competence in two yeast strains impaired in heme synthesis, namely, G204 and H12-6A, was analyzed. To evaluate heme availability, a heterologous 17alpha-hydroxylase cytochrome P-450 cDNA (P-450c17) was expressed in these strains, and its activity was measured in vivo. Heme deficiency in G204 led to accumulation of squalene and lethality. The heterologous cytochrome P-450 was inactive in this strain. The leaky H12-6A strain presented a slightly modified sterol content compared to that for the wild type, and the P-450c17 recovered partial activity. By analyzing sterol transfer on nongrowing cells, it was shown that the cells were permeable toward exogenous cholesterol when they were depleted of endogenous sterols, which was the case for G204 but not for H12-6A. It was concluded that the fully blocked heme mutant (G204) replenishes its diminishing endogenous sterol levels during growth by replacement with sterol from the outside medium. Endogenous sterol biosynthesis appears to be the primary factor capable of excluding exogenous sterol. Oleate but not palmitoleate was identified as a component that reduced but did not prevent sterol transfer. Sterol transfer was only slightly affected by a lack of esterification. It is described herein how avoidance of the potential cytotoxicity of the early intermediates of the mevalonate pathway could be achieved by a secondary heme mutation in erg auxotrophs.

Screening and diagnosis for gestational diabetes mellitus among Chippewa women in northern Minnesota.

We reviewed prenatal records of Chippewa women residing on two Minnesota reservations to define the incidence of gestational diabetes mellitus (GDM) and to describe the screening and diagnosis practices for GDM according to National Diabetes Data Group Criteria. Of the 554 pregnancies included in the study, six (1%) involved women with preexisting diabetes mellitus and 32 (5.8%) with GDM. In 24 (4.3%) of the pregnancies, the women were misclassified as having GDM. Women completed screening and/or testing during 450 (82%) of the pregnancies-by 32 weeks gestation for 401 (73%). This is of 548 pregnancies that could potentially have involved GDM. Women with incomplete screening and/or testing were older and of higher parity than those who completed negative screening and/or testing (p<0.05). Chippewa Indian women in northern Minnesota experienced GDM at rates higher than most other U.S. populations. Screening rates for GDM were high, but some high-risk women were not screened. Programs targeting high-risk women for timely and accurate diagnosis of GDM are needed in this primary care setting.

RTM1: a member of a new family of telomeric repeated genes in yeast.

We have isolated a new yeast gene called RTM1 whose overexpression confers resistance to the toxicity of molasses. The RTM1 gene encodes a hydrophobic 34-kD protein that contains seven potential transmembrane-spanning segments. Analysis of a series of industrial strains shows that the sequence is present in multiple copies and in variable locations in the genome. RTM loci are always physically associated with SUC telomeric loci. The SUC-RTM sequences are located between X and Y' subtelomeric sequences at chromosome ends. Surprisingly RTM sequences are not detected in the laboratory strain X2180. The lack of this sequence is associated with the absence of any SUC telomeric gene previously described. This observation raises the question of the origin of this nonessential gene. The particular subtelomeric position might explain the SUC-RTM sequence amplification observed in the genome of yeasts used in industrial biomass or ethanol production with molasses as substrate. This SUC-RTM sequence dispersion seems to be a good example of genomic rearrangement playing a role in evolution and environmental adaptation in these industrial yeasts.