STP1, a gene involved in pre-tRNA processing, encodes a nuclear protein containing zinc finger motifs

Patrolling the nucleus: inner nuclear membrane-associated degradation

Protein quality control and transport are important for the integrity of organelles such as the endoplasmic reticulum, but it is largely unknown how protein homeostasis is regulated at the nuclear envelope (NE) despite the connection between NE protein function and human disease. Elucidating mechanisms that regulate the NE proteome is key to understanding nuclear processes such as gene expression, DNA replication and repair as NE components, particularly proteins at the inner nuclear membrane (INM), are involved in the maintenance of nuclear structure, nuclear positioning and chromosome organization. Nuclear pore complexes control the entry and exit of proteins in and out of the nucleus, restricting movement across the nuclear membrane based on protein size, or the size of the extraluminal-facing domain of a transmembrane protein, providing one level of INM proteome regulation. Research in budding yeast has identified a protein quality control system that targets mislocalized and misfolded proteins at the INM. Here, we review what is known about INM-associated degradation, including recent evidence suggesting that it not only targets mislocalized or misfolded proteins, but also contributes to homeostasis of resident INM proteins.

Saccharomyces cerevisiae S288C genome annotation: a working hypothesis

The S. cerevisiae genome is the most well-characterized eukaryotic genome and one of the simplest in terms of identifying open reading frames (ORFs), yet its primary annotation has been updated continually in the decade since its initial release in 1996 (Goffeau et al., 1996). The Saccharomyces Genome Database (SGD; www.yeastgenome.org) (Hirschman et al., 2006), the community-designated repository for this reference genome, strives to ensure that the S. cerevisiae annotation is as accurate and useful as possible. At SGD, the S. cerevisiae genome sequence and annotation are treated as a working hypothesis, which must be repeatedly tested and refined. In this paper, in celebration of the tenth anniversary of the completion of the S. cerevisiae genome sequence, we discuss the ways in which the S. cerevisiae sequence and annotation have changed, consider the multiple sources of experimental and comparative data on which these changes are based, and describe our methods for evaluating, incorporating and documenting these new data.

Transcriptional profiling of extracellular amino acid sensing in Saccharomyces cerevisiae and the role of Stp1p and Stp2p

S. cerevisiae responds to the presence of amino acids in the environment through the membrane-bound complex SPS, by altering transcription of several genes. Global transcription analysis shows that 46 genes are induced by L-citrulline. Under the given conditions there appears to be only one pathway for induction with L-citrulline, and this pathway is completely dependent on the SPS component, Ssy1p, and either of the transcription factors, Stp1p and Stp2p. Besides the effects on amino acid permease genes, an ssy1 and an stp1 stp2 mutant exhibit a number of other transcriptional phenotypes, such as increased expression of genes subject to nitrogen catabolite repression and genes involved in stress response. A group of genes involved in the upper part of the glycolysis, including those encoding hexose transporters Hxt4p, Hxt5p, Hxt6p, Hxt7p, hexokinase Hxk1p, glyceraldehyde 3-phosphate dehydrogenase Tdh1p and glucokinase (Glk1p), shows increased transcription levels in either or both of the mutants. Also, most of the structural genes involved in trehalose and glycogen synthesis and a few genes in the glyoxylate cycle and the pentose phosphate pathway are derepressed in the ssy1 and stp1 stp2 strains.

Regulation of expression of the amino acid transporter gene BAP3 in Saccharomyces cerevisiae

The BAP3 gene of Saccharomyces cerevisiae encodes a protein with a high similarity to the BAP2 gene product, a high-affinity permease for branched-chain amino acids. In this paper, we show that, like BAP2, the expression of the BAP3 gene in S. cerevisiae is induced by the addition of branched-chain amino acids to the medium. Unexpectedly, most other naturally occurring L-amino acids found in proteins (with the exception of proline, lysine, arginine and histidine) have the same effect on the expression of BAP3. The induction of BAP3 expression appears to be dependent on Stp1p, a nuclear protein, previously shown to be involved in pre-tRNA maturation and also required for the expression of BAP2, as induction is no longer observed in an stp1 - mutant. The transcriptional regulator Leu3p is not involved in the induction of BAP3 expression, but may act as a repressor of BAP3 expression in the absence of leucine, as can be inferred from a transcriptional analysis in a Deltaleu3 mutant. By extensive deletion analysis of the BAP3 promoter fused to a GUS reporter, as well as by fusions of different parts of the BAP3 promoter to a LacZ reporter, we have found that a portion of the BAP3 promoter from - 418 to - 392 relative to the ATG start codon is both necessary and sufficient for the Stp1p-dependent induction of BAP3 expression by (most) amino acids. We have therefore named this sequence UASaa (amino acid-dependent upstream activator sequence). Neither Stp1p nor Leu3p appear to bind to the UASaa, at least in vitro, as judged from gel retardation assays. Sequences similar to the UASaa can be found in the promoters of BAP2, PTR2 and TAT1; genes that, like BAP3, encode permeases inducible by amino acids, suggesting that amino acid induction of all these genes is exerted via a common mechanism.

Preparation of magnetic immobilized metal affinity separation media and its use in the isolation of proteins

A new method of pseudobiospecific protein isolation is developed and tested, which employs both metal affinity and magnetism as the basis for isolation. The chelating group iminodiacetic acid (IDA) has been coupled to the surface of magnetic agarose, and when charged with metal ions (Cu2+ or Zn2+) is capable of binding model proteins which display metal affinity, and of separating protein mixtures. Magnetic properties of the medium facilitated the batch recovery of the adsorbent, as losses are minimized by concentrating and retaining the separation medium with the aid of a magnet. Model proteins were used to characterize protein adsorption, capacity, and stability of IDA magnetic agarose. Recovery from a cell lysate was demonstrated by protein isolation from extracts of E. coli containing a target protein. Overall, this study effectively illustrates the engineering of separation media which combine several desired properties for the development of a new branch of metal affinity-based bioseparation.

Mutations in five loci affecting GAP1-independent uptake of neutral amino acids in yeast

In order to identify genes involved in uptake of isoleucine, leucine and valine in Saccharomyces cerevisiae we isolated mutants that, on a complex medium, were sensitive to an inhibitor of the biosynthesis of the branched-chain amino acids. Mutants that in a secondary screen showed reduced uptake of isoleucine, leucine and valine when growing in synthetic complete medium were further characterized. Genetic analysis identified five loci, named ssy1 through ssy5. ssy2 corresponds to the previously characterized bap1 mutation, which we recently have found to be allelic to stp1. ssy1, ssy3 and ssy5 exhibit a reduced uptake of phenylalanine, methionine and threonine, as well. Furthermore, they are resistant to several neutral amino acid analogs. ssy4 only affects uptake of few neutral amino acids and is as sensitive as the wild type to the amino acid analogs tested. It was previously found that a C-terminal truncation of 29 codons of BAP2, which encodes a branched-chain amino acid permease, results in increased uptake of the branched-chain amino acids. We find epistasis of the C-terminally truncated BAP2 gene over the ssy4 mutation, while the other ssy mutations are epistatic over the truncated BAP2 gene. SSY1, SSY3 and SSY5 were cloned from a low-copy genomic library by complementation of the mutants. The SSY3 gene and the SSY5 gene show no significant homology to any sequence in the databases. SSY1 is a member of the major family of genes encoding amino acid permeases in yeast. We discuss possible roles of Ssy1p in amino acid uptake.

Los1p, involved in yeast pre-tRNA splicing, positively regulates members of the SOL gene family

To understand the role of Los1p in pre-tRNA splicing, we sought los1 multicopy suppressors. We found SOL1 that suppresses both point and null LOS1 mutations. Since, when fused to the Ga14p DNA-binding domain, Los1p activates transcription, we tested whether Los1p regulates SOL1. We found that las1 mutants have depleted levels of SOL1 mRNA and Sol1p. Thus, LOS1 appears to positively regulate SOL1. SOL1 belongs to a multigene family with at least two additional members, SOL2 and SOL3. Sol proteins have extensive similarity to an unusual group of glucose-6-phosphate dehydrogenases. As the similarities are restricted to areas separate from the catalytic domain, these G6PDs may have more than one function. The SOL family appears to be unessential since cells with a triple disruption of all three SOL genes are viable. SOL gene disruptions negatively affect tRNA-mediated nonsense suppression and the severity increases with the number of mutant SOL genes. However, tRNA levels do not vary with either multicopy SOL genes or with SOL disruptions. Therefore, the Sol proteins affect tRNA expression/ function at steps other than transcription or splicing. We propose that LOS1 regulates gene products involved in tRNA expression/function as well as pre-tRNA splicing.

CPEB is a specificity factor that mediates cytoplasmic polyadenylation during Xenopus oocyte maturation

The translational activation of several maternal mRNAs during Xenopus oocyte maturation is stimulated by cytoplasmic poly(A) elongation, which requires the uridine-rich cytoplasmic polyadenylation element (CPE) and the hexanucleotide AAUAAA. Here, we have enriched a CPE-binding protein (CPEB) by single-step RNA affinity chromatography, have obtained a CPEB cDNA, and have assessed the role of CPEB in cytoplasmic polyadenylation. The 62 kDa CPEB contains two RNA recognition motifs, and within this region, it is 62% identical to orb, an oocyte-specific RNA-binding protein from Drosophila. CPEB mRNA and protein are abundant in oocytes and are not detected in embryos beyond the gastrula stage. During oocyte maturation, CPEB is phosphorylated at a time that corresponds with the induction of polyadenylation. Immunodepletion of CPEB from polyadenylation-proficient egg extracts renders them incapable of adenylating exogenous RNA. Partial restoration of polyadenylation in depleted extracts is achieved by the addition of CPEB, thus demonstrating that this protein is required for cytoplasmic polyadenylation.

Intron excision from tRNA precursors by plant splicing endonuclease requires unique features of the mature tRNA domain

It has been proposed that yeast and Xenopus splicing endonucleases initially recognize features in the mature tRNA domain common to all tRNA species and that the sequence and structure of the intron are only minor determinants of splice-site selection. In accordance with this postulation, we show that yeast endonuclease splices heterologous pre-tRNA(Tyr) species from vertebrates and plants which differ in their mature domains and intron secondary structures. In contrast, wheat germ splicing endonuclease displays a pronounced preference for homologous pre-tRNA species; an extensive study of heterologous substrates revealed that neither yeast pre-tRNA species specific for leucine, serine, phenylalanine and tyrosine nor human and Xenopus pre-tRNA(Tyr) species were spliced. In order to identify the elements essential for pre-tRNA splicing in plants, we constructed chimeric genes coding for tRNA precursors with a plant intron secondary structure and with mature tRNA(Tyr) domains from yeast and Xenopus, respectively. The chimeric pre-tRNA comprising the mature tRNA(Tyr) domain from Xenopus was spliced efficiently in wheat germ extract, whereas the chimeric construct containing the mature tRNA(Tyr) domain from yeast was not spliced at all. These data indicate that intron secondary structure contributes to the specificity of plant splicing endonuclease and that unique features of the mature tRNA domain play a dominant role in enzyme-substrate recognition. We further investigated the influence of specific nucleotides in the mature domain on splicing by generating a number of mutated pre-tRNA species. Our results suggest that nucleotides located in the D stem, i.e. in the center of the pre-tRNA molecule, are recognition points for plant splicing endonuclease.