A sampling of the yeast proteome.

In this study, we examined yeast proteins by two-dimensional (2D) gel electrophoresis and gathered quantitative information from about 1,400 spots. We found that there is an enormous range of protein abundance and, for identified spots, a good correlation between protein abundance, mRNA abundance, and codon bias. For each molecule of well-translated mRNA, there were about 4,000 molecules of protein. The relative abundance of proteins was measured in glucose and ethanol media. Protein turnover was examined and found to be insignificant for abundant proteins. Some phosphoproteins were identified. The behavior of proteins in differential centrifugation experiments was examined. Such experiments with 2D gels can give a global view of the yeast proteome.

Proteome studies of Saccharomyces cerevisiae: identification and characterization of abundant proteins.

Two-dimensional (2-D) gel electrophoresis can now be coupled with protein identification techniques and genome sequence information for direct detection, identification, and characterization of large numbers of proteins from microbial organisms. 2-D electrophoresis, and new protein identification techniques such as amino acid composition, are proteome research techniques in that they allow direct characterization of many proteins at the same time. Another new tool important for yeast proteome research is the Yeast Protein Database (YPD), which provides the sequence-derived protein properties needed for spot identification and tabulations of the currently known properties of the yeast proteins. Studies presented here extend the yeast 2-D protein map to 169 identified spots based upon the recent completion of the yeast genome sequence, and they show that methods of spot identification based on predicted isoelectric point, predicted molecular mass, and determination of partial amino acid composition from radiolabeled gels are powerful enough for the identification of at least 80% of the spots representing abundant proteins. Comparison of proteins predicted by YPD to be detectable on 2-D gels based on calculated molecular mass, isoelectric point and codon bias (a predictor of abundance) with proteins identified in this study suggests that many glycoproteins and integral membrane proteins are missing from the 2-D gel patterns. Using the 2-D gel map and the information available in YDP, 2-D gel experiments were analyzed to characterize the yeast proteins associated with: (i) an environmental change (heat shock), (ii) a temperature-sensitive mutation (the prp2 mRNA splicing mutant), (iii) a mutation affecting post-translational modification (N-terminal acetylation), and (iv) a purified subcellular fraction (the ribosomal proteins). The methods used here should allow future extension of these studies to many more proteins of the yeast proteome.

A Saccharomyces cerevisiae Internet protein resource now available.

The QUEST Protein Database Center is now making available two Saccharomyces cerevisiae protein databases via the Internet. The yeast electrophoretic protein database (YEPD) is a database of approximately one hundred protein identifications on two-dimensional gels. The yeast protein database (YPD) is a database of gene names and properties of over 3500 yeast proteins of known sequence. These databases can be accessed via a World-Wide Web (WWW) server (URL http:@siva.cshl.org). YPD is available via public ftp (isis.cshl.org) as well, in a spreadsheet format, and in ASCII format. When accessed via WWW, both of these databases have hypertext links to other biological data, such as the SWISS-PROT protein sequence database and the Saccharomyces Genome Database (SacchDB), and to each other.

Protein identifications for a Saccharomyces cerevisiae protein database.

The rapid progress in understanding the genes of the yeast Saccharomyces cerevisiae can be supplemented by two-dimensional (2-D) gel studies to understand global patterns of protein synthesis, protein modification, and protein degradation. The first step in building a protein database for yeast is to identify many of the spots on 2-D gels. We are using protein sequencing, overexpression of genes on high-copy number plasmids, and amino acid analysis to identify the proteins from 2-D gels of yeast. The amino acid analysis technique involves labeling yeast samples with different amino acids and using quantitative image analysis to determine the relative amino acid abundances. The observed amino acid abundances are then searched against the current database of 2600 known yeast protein sequences. At present about 90 proteins on our yeast maps have been identified, and the number is rising rapidly. With many known proteins on the map, it will soon be possible to use 2-D gel analysis to study regulatory pathways in normal and mutant yeast, with knowledge of many the protein products that respond to each genetic or environmental manipulation.

Early changes in protein synthesis induced by basic fibroblast growth factor, nerve growth factor, and epidermal growth factor in PC12 pheochromocytoma cells.

Nerve growth factor (NGF) and basic fibroblast growth factor (bFGF) stimulate neuronal differentiation, whereas epidermal growth factor (EGF) promotes only mitogenic responses in PC12 pheochromocytoma cells. The early changes in protein synthesis induced by bFGF, NGF, and EGF in these cells have been determined by two-dimensional PAGE of [35S]methionine-labeled proteins and computerized image analysis. The rate of synthesis of only 29 proteins (out of approximately 1500 identified) was found to be modulated during the first several hours of growth factor stimulation. Individually, 12 were affected by EGF, 23 were affected by bFGF, and 20 were affected by NGF. Eight of these were regulated by all three growth factors, while 10 proteins were commonly induced by bFGF and NGF, in accordance with the essentially identical morphological responses induced by these two factors. In addition, the effects of bFGF and NGF were about equally divided between increases and decreases in the rate of synthesis of individual proteins, whereas EGF caused significantly more positive (increased) responses. All proteins modulated by NGF or FGF alone were negative in their response and those induced by only EGF were positive. Of particular interest, the rate of synthesis of two proteins of 55 kDa and pI 5.45 and 5.50 was dramatically and transiently induced during the first 2 hr of bFGF and NGF treatment and was not affected by EGF. This study indicates that all three factors elicit early increases and decreases in the synthesis of a quite limited number of proteins and provides molecular evidence for the specificity of a differentiative vs. a proliferative growth factor-induced signaling pathway in these cells.

Complications associated with the use of an infusion pump during knee arthroscopy.

This is a report of four complications from the use of an automated arthroscopy pump in 283 patients undergoing knee arthroscopy. The first patient had extravasation of fluid into the thigh, requiring discontinuation of the procedure. The second patient developed a compartment syndrome of the leg, necessitating a four-compartment fasciotomy of the leg. The third patient developed severe fluid extravasation into the anterior thigh compartment. A limited fasciotomy of the anterior thigh compartment was performed. The fourth patient developed moderate extravasation into the anterior part of the thigh and groin, necessitating discontinuation of pump irrigation and conversion to gravity irrigation to complete a partial medial meniscectomy. During a 15-month period, a complication rate of 1.4% from fluid extravasation during knee arthroscopy was noted. This review represents our initial experience with the infusion pump. No cases of fluid extravasation have occurred subsequently during a 12-month period.

Screening a yeast promoter library leads to the isolation of the RP29/L32 and SNR17B/RPL37A divergent promoters and the discovery of a gene encoding ribosomal protein L37.

Two promoters (A7 and A23), isolated at random from the Saccharomyces cerevisiae genome by virtue of their capacity to activate transcription, are identical to known intergenic bidirectional promoters. Sequence analysis of the genomic DNA adjacent to the A7 promoter identified a split gene encoding ribosomal (r) protein L37, which is homologous to the tRNA-binding r-proteins, L35a (from human and rat) and L32 (from frogs).

Efficient translation of the UAG termination codon in Candida species.

Clinical isolates of the dimorphic fungus Candida albicans encode a tRNA that, in a cell-free translation system prepared from the yeast Saccharomyces cerevisiae, efficiently translates the amber (UAG) termination codon. Unusually, the efficiency of this UAG read-through in the heterologous cell-free system is not further enhanced by polyamines. The suppressor tRNA is also able to efficiently translate the UAG codon in the rabbit reticulocyte cell-free system and with efficiencies approaching 100% in a homologous (C. albicans) cell-free system. That the suppressor tRNA is nuclear-encoded is demonstrated by the lack of activity in purified C. albicans mitochondrial tRNAs. Finally, UAG suppressor tRNA activity is also demonstrated in three other pathogenic Candida species, C. parapsilosis, C. guillermondii and C. tropicalis. These results suggest that some, but not all, Candida species have evolved an unusual nuclear genetic code in which UAG is used as a sense codon.

Sequence analysis of the translational elongation factor 3 from Saccharomyces cerevisiae.

The gene YEF-3 encoding the elongation factor for protein synthesis in Saccharomyces cerevisiae is an essential gene as shown by one-step gene disruption and is located on chromosome XII as determined by orthogonal field alternation gel electrophoresis. The nucleotide sequence of the gene was determined from a sequential series of subclones generated from the YEF-3 gene cloned into bacteriophage M13. The HOMOL1 sequence and the RPG box, which are considered to be enhancer elements involved in coordinate regulation of transcription of the genes coding for yeast ribosomal proteins and protein synthesis factors, are found in the 5'-flanking region of the gene. A dyad symmetry that enables hairpin loop formation in the DNA molecule is found in the 3'-terminal at the termination site of transcription. An open reading frame of 3132 nucleotides codes for a deduced protein of 115,860 Da. A striking feature of the elongation factor 3 deduced polypeptide is the internal repeat of a region with approximately 200 amino acids which includes an ATP-binding site and shares similarity with some transport and drug-resistant proteins. Another characteristic is the presence of a highly charged C-terminal region composed of three basic polylysine blocks, suggesting interaction with RNA. The sequence supports the hypothesis that YEF-3 encodes a protein synthesis factor and suggests that its main role may be to transduce nucleoside triphosphate energy into mechanical energy for translocation during translation.

Properties of promoters cloned randomly from the Saccharomyces cerevisiae genome.

Promoters were isolated at random from the genome of Saccharomyces cerevisiae by using a plasmid that contains a divergently arrayed pair of promoterless reporter genes. A comprehensive library was constructed by inserting random (DNase I-generated) fragments into the intergenic region upstream from the reporter genes. Simple in vivo assays for either reporter gene product (alcohol dehydrogenase or beta-galactosidase) allowed the rapid identification of promoters from among these random fragments. Poly(dA-dT) homopolymer tracts were present in three of five randomly cloned promoters. With two exceptions, each RNA start site detected was 40 to 100 base pairs downstream from a TATA element. All of the randomly cloned promoters were capable of activating reporter gene transcription bidirectionally. Interestingly, one of the promoter fragments originated in a region of the S. cerevisiae rDNA spacer; regulated divergent transcription (presumably by RNA polymerase II) initiated in the same region.

A ribosome-associated inhibitor of in vitro nonsense suppression in [psi-] strains of yeast.

All classes of tRNA-mediated nonsense suppression are much more efficient in yeast cell-free lysates prepared from a [psi+] strain than in those prepared from an isogenic [psi-] strain. Mixed [psi+]/[psi-] lysates do not support efficient suppression. Fractionation of the [psi-] lysate demonstrated the presence of an inhibitor of in vitro suppression that is loosely associated with the 80 S ribosome. The data indicate that the inhibitor is a factor involved in the termination of translation in this simple eukaryote.

Isolation of the yeast gene encoding elongation factor 3 for protein synthesis.

The gene YEF-3 encoding the elongation factor 3 (EF-3) for peptide chain elongation in Saccharomyces cerevisiae has been isolated by immunoscreening of a yeast genomic library in the phage lambda gt11. The identity of the EF-3 gene was confirmed by several methods. First, a clone-encoded protein could affinity purify the antibody that specifically reacted with EF-3. Second, a recombinant fusion protein, which reacted with anti-beta-galactosidase antibody as well as with anti-EF-3 antibody, was found in the lysate of a positive clone lysogen. Third, the function of EF-3 in a yeast mutant in which the EF-3 activity is temperature-sensitive in an in vitro assay could be complemented by transformations. EF-3 protein was overproduced in a transformant which contained the EF-3 gene on a multicopy plasmid YEp-13. Southern blot analysis shows that YEF-3 is a single copy gene. The transcript unit as mapped by S1 nuclease mapping, is consistent with the size of the message determined by Northern blot analysis and shows no evidence of introns.

Effect of cell cycle position on thermotolerance in Saccharomyces cerevisiae.

We showed that the heat killing curve for exponentially growing Saccharomyces cerevisiae was biphasic. This suggests two populations of cells with different thermal killing characteristics. When exponentially growing cells separated into cell cycle-specific fractions via centrifugal elutriation were heat shocked, the fractions enriched in small unbudded cells showed greater resistance to heat killing than did other cell cycle fractions. Cells arrested as unbudded cells fell into two groups on the basis of thermotolerance. Sulfur-starved cells and the temperature-sensitive mutants cdc25, cdc33, and cdc35 arrested as unbudded cells were in a thermotolerant state. Alpha-factor-treated cells arrested in a thermosensitive state, as did the temperature-sensitive mutant cdc36 when grown at the restrictive temperature. cdc7, which arrested at the G1-S boundary, arrested in a thermosensitive state. Our results suggest that there is a subpopulation of unbudded cells in exponentially growing cultures that is in G0 and not in G1 and that some but not all methods which cause arrest as unbudded cells lead to arrest in G0 as opposed to G1. It has been shown previously that yeast cells acquire thermotolerance to a subsequent challenge at an otherwise lethal temperature during a preincubation at 36 degrees C. We showed that this acquisition of thermotolerance was corrected temporally with a transient increase in the percentage of unbudded cells during the preincubation at 36 degrees C. The results suggest a relationship between the heat shock phenomenon and the cell cycle in S. cerevisiae and relate thermotolerance to transient as well as to more prolonged residence in the G0 state.

Isolation and characterization of PRT1, a gene required for the initiation of protein biosynthesis in Saccharomyces cerevisiae.

We isolated a cloned DNA fragment containing PRT1, a gene required for the initiation of protein biosynthesis in Saccharomyces cerevisiae, by complementation of the temperature-sensitive prtl-1 mutation. The entire PRT1 gene is contained within a 3.2-kilobase-pair segment of the cloned DNA in YEp13 H1.2. Southern blot analysis demonstrated that PRT1 is a single copy gene which is transcribed into a 2.3-kilobase RNA. We determined the direction of transcription and mapped the 5' and 3' ends of the gene.

A novel suppressor tRNA from the dimorphic fungus Candida albicans.

Unfractionated tRNAs from a number of prokaryotes and eukaryotes were examined for their ability to promote termination codon readthrough in a cell-free system isolated from Saccharomyces cerevisiae. tRNA from the dimorphic fungus Candida albicans was found to have significant UGA and UAG readthrough activity and this activity was present in tRNA extracted from both the yeast and the hyphal phase of the fungus. Unusually the efficiency of readthrough activity in vitro was not affected by the [psi] determinant. C. albicans tRNA was fractionated by one-dimensional and two-dimensional gel electrophoresis and both readthrough activities appeared to be associated with a single species of tRNA.

Expression of the Drosophila 70,000 Dalton heat shock protein is translationally controlled in yeast.

Plasmid pPW229, containing the 2.25 kilobase transcribed sequence for the 70,000 Dalton heat shock protein of Drosophila, was integrated into plasmid CV13 and used to transform Saccharomyces cerevisiae. Upon a heat shock, at 41 degrees C for 20 min, a new 70,000 Dalton protein appeared in the transformants. This protein was not detected in transformants grown at 23 degrees C, nor in transformants carrying the hybrid plasmid from which the structural gene for the 70,000 Dalton protein had been deleted. RNA was isolated from transformants grown at 23 degrees C and from transformants heat shocked at 41 degrees C. RNA complementary to the Drosophila heat shock gene was present in the transformants, grown either at 23 degrees C or heat shocked. No complementary RNA was detected in yeast cells transformed with the hybrid plasmid from which the structural gene had been deleted. The Drosophila heat shock gene in yeast appears to be transcribed constitutively but translated only under heat shock conditions.

Identification of an altered elongation factor in temperature-sensitive mutant ts 7'-14 of Saccharomyces cerevisiae.

Postpolysomal extracts from wild-type (wt A364A) and temperature-sensitive (ts 7'-14) yeast cells were preincubated for short periods of time at the nonpermissive temperature (37-41 degrees C) prior to incubations for protein synthesis at 20 degrees C. Whereas wt A364A extracts were relatively unaffected by preincubation at the elevated temperature, mutant extracts lost their ability to translate exogenous natural mRNA and poly(U). Phe-tRNA synthetase and ribosomes from ts 7'-14 cells were not inactivated by preincubation at 37-41 degrees C, but a cytosolic component required for chain elongation, as measured by poly(U) translation, was extensively inactivated. The three elongation factors (EF-1, EF-2, and EF-3) required for chain elongation in yeast were resolved chromatographically. Only one factor, EF-3, was able to restore the poly(U)-translational activity of mutant extracts inactivated at the elevated temperature. Heat-inactivated yeast cytosols, which did not support protein synthesis with yeast ribosomes, were perfectly able to translate poly(U) with rat liver ribosomes, which require only EF-1 and EF-2. These and other experiments indicated that the genetically altered component in 7'-14 mutant cells is EF-3.

The effects of paromomycin on the fidelity of translation in a yeast cell-free system.

The effects of the aminoglycoside antibiotic paromomycin on the fidelity of translation of the synthetic template poly(U), and two natural mRNAs (rabbit globin mRNA and Brome Mosaic virus RNA), were examined in an mRNA-dependent cell-free system from the yeast Saccharomyces cerevisiae. At antibiotic concentrations that did not inhibit translation (100 microM) optimal mistranslation of all three templates was observed, with the effects declining at higher antibiotic concentrations. Synthesis of the opal termination read-through protein of rabbit beta-globin mRNA was induced by paromomycin, but only in lysates prepared from a [psi+] strain of yeast. The antibiotic did not induce detectable levels of either ochre or amber read-through, but did induce general misreading of Brome Mosaic virus RNA to the same degree in both [psi+] and [psi-] lysates. This misreading was enhanced by addition of the polyamine spermidine.