Rudi J. Planta

The list of cytoplasmic ribosomal proteins of Saccharomyces cerevisiae.

Screening of the complete genome sequence from the yeast Saccharomyces cerevisiae has enabled us to compile a complete list of the genes encoding cytoplasmic ribosomal proteins in this organism.

High-copy-number integration into the ribosomal DNA of Saccharomyces cerevisiae: a new vector for high-level expression

Yeast vectors suitable for high-level expression of heterologous proteins should combine a high copy number with a high mitotic stability under non-selective conditions. Since high stability can best be assured by integration of the vector into chromosomal DNA we have set out to design a vector that is able to integrate into the yeast genome in a large number of copies. The rDNA locus appeared to be an attractive target for such multiple integration since it encompasses 100-200 tandemly repeated units. Plasmids containing several kb of rDNA for targeted homologous recombination, as well as the deficient LEU2-d selection marker were constructed and, after transformation into yeast, tested for both copy number and stability. One of these plasmids, designated pMIRY2 (for multiple integration into ribosomal DNA in yeast), was found to be present in 100-200 copies per cell by restriction analysis. The pMIRY2 transformants retained 80-100% of the plasmid copies over a period of 70 generations of growth in batch culture under non-selective conditions. To explore the potential of pMIRY2 as an expression vector we have inserted the homologous genes for phosphoglycerate kinase (PGK) and Mn2+-dependent superoxide dismutase (SOD) as well as the heterologous genes for thaumatin from Thaumatococcus danielli (under the GAPDH promoter), into this plasmid and analyzed the yield of the various proteins. Under optimized conditions the level of PGK in cells transformed with pMIRY2-PGK was about 50% of total soluble protein. The yield of thaumatin in the pMIRY2-thaumatin transformants exceeded by about a factor of 100 the level of thaumatin observed in transformants carrying only a single thaumatin gene integrated at the TRP1 locus in chromosome IV.

FUNCTIONAL ANALYSIS OF TRANSCRIBED SPACERS OF YEAST RIBOSOMAL DNA

Making use of an rDNA unit, containing oligonucleotide tags in both the 17S and 26S rRNA gene, we have analyzed the effect of various deletions in the External Transcribed Spacer (ETS) and in one of the Internal Transcribed Spacers 1 (ITS1) on the process of ribosome formation in yeast. By following the fate of the tagged transcripts of this rDNA unit in vivo by Northern hybridization we found that deleting various parts of the ETS prevents the accumulation of tagged 17S rRNA and its assembly into 40S subunits, but not the formation of 60S subunits. Deleting the central region of ITS1, including a processing site that is used in an early stage of the maturation process, was also found to prevent the accumulation of functional 49 S subunits, whereas no effect on the formation of 60S subunits was detected. The implications of these findings for yeast pre‐rRNA processing are discussed.

Ribosomal precursor particles from yeast.

Abstract Ribosomal precursor particles were extracted from the yeast Saccharomyces carlsbergensis and analysed. After a brief labelling of yeast protoplasts with 3 H-uridine, three basic ribonucleoprotein components were detected, sedimenting at approx. 90S, 66S and 43S in sucrose gradients containing magnesium. The 90S particles contained the 37S ribosomal precursor RNA as a major component and a small though variable amount of 29S ribosomal precursor RNA. The 66S and 43S particles contained 29S and 18S ribosomal precursor RNA, respectively. Kinetic data indicate a precursor-product relationship between the 90S particles and the two other ribonucleoprotein components, consistent with the conversion: 90S → 66S + 43S. The 90S and 66S preribosomes appeared to be present exclusively in the nucleus, whereas the 43S particles were mainly present in the cytoplasmic fraction. Apparently, the final maturation step in the formation of the 40S ribosomal subunits takes place in the cytoplasm. The 90S and 66S precursor particles have a relatively higher ratio of protein to RNA than the mature large ribosomal subunits, as judged from their buoyant densities in CsCl gradients. This finding suggests that also in a primitive eukaryotic organism, like yeast, ribosome maturation involves, in addition to a decrease in the size of the RNA components, an even stronger decrease in the amount of associated protein. In contrast, the 43S particles appeared to have the same buoyant density as the 40S ribosomal subunits.

The course of the assembly of ribosomal subunits in yeast.

The course of the assembly of the various ribosomal proteins of yeast into ribosomal particles has been studied by following the incorporation of radioactive individual protein species in cytoplasmic ribosomal particles after pulse-labelling of yeast protoplasts with tritiated amino acids. The pool of ribosomal proteins is small relative to the rate of ribosomal protein synthesis, and, therefore, does not affect essentially the appearance of labelled ribosomal proteins on the ribosomal particles. From the labelling kinetics of individual protein species it can be concluded that a number of ribosomal proteins of the 60 S subunit (L6, L7, L8, L9, L11, L15, L16, L23, L24, L30, L32, L36, L40, L41, L42, L44 and L45) associate with the ribonucleoprotein particles at a relatively late stage of the ribosomal maturation process. The same was found to be true for a number of proteins of the 40 S ribosomal subunit (S10, S27, S31, S32, S33 and S34). Several members (L7, L9, L24 and L30) of the late associating group of 60-S subunit proteins were found to be absent from a nuclear 66 S precursor ribosomal fraction. These results indicate that incorporation of these proteins into the ribosomal particles takes place in the cytoplasm at a late stage of the ribosomal maturation process.

Osmostress‐induced changes in yeast gene expression

When Saccharomyces cerevisiae cells are exposed to high concentrations of NaCI, they show reduced viability, methionine uptake and protein biosynthesis. Cells can acquire tolerance against a severe salt shock (up to 1.4 M NaCI) by a previous treatment with 0.7 M NaCI, but not by a previous heat shock. Two‐dimensional analysis of [3H]‐leucine‐labelled proteins from salt‐shocked cells (0.7 M NaCt) revealed the elevated rate of synthesis of nine proteins, among which were the heat‐shock proteins hsp12 and hsp26. Northern analysis using gene‐specific probes confirmed the identity of the latter proteins and, in addition, demonstrated the induction of glycerol‐3‐phos‐phate dehydrogenase gene expression. The synthesis of the same set of proteins is induced or enhanced upon exposure of cells to 0.8 M sucrose, although not as dramatically as in an iso‐osmolar NaCI concentration (0.7 M).

The human alpha-amylase multigene family consists of haplotypes with variable numbers of genes.

Polymorphic amylase protein patterns have suggested the presence in the human genome of various haplotypes encoding these allozymes. To investigate the genomic organization of the human alpha-amylase genes, we isolated the pertinent genes from a cosmid library constructed of DNA from an individual expressing three different salivary amylase allozymes. From the restriction maps of the overlapping cosmids and a comparison of these maps with the restriction enzyme patterns of DNA from the donor and family members, we were able to identify two haplotypes consisting of very different numbers of salivary amylase genes. The short haplotype contains two pancreatic genes (AMY2A and AMY2B) and one salivary amylase gene (AMY1C), arranged in the order 2B-2A-1C, encompassing a total length of approximately 100 kb. The long haplotype spans about 300 kb and contains six additional genes arranged in two repeats, each one consisting of two salivary amylase genes (AMY1A and AMY1B) and a pseudogene lacking the first three exons (AMYP1). The order of the amylase genes within the repeat is 1A-1B-P1. All genes are in a head-to-tail orientation except AMY1B, which has the reverse orientation with respect to the other genes. Analysis of somatic cell hybrids confirmed the presence of these short and long haplotypes. Furthermore, we present evidence for the existence of additional haplotypes in the human population and propose a general model for the evolution of the human alpha-amylase multigene family. A general designation 2B-2A-(1A-1B-P)n-1C can describe these haplotypes, n being 0 and 2 for the short and the long haplotypes presented in this paper, respectively.

Specific binding of TUF factor to upstream activation sites of yeast ribosomal protein genes.

Transcription activation of yeast ribosomal protein genes is mediated through homologous, 12‐nucleotide‐long and, in general, duplicated upstream promoter elements (HOMOL1 and RPG, referred to as UASrpg). As shown previously, a yeast protein factor, TUF, interacts specifically with these conserved boxes in the 5′‐flanking sequences of the elongation factor genes TEF1 and TEF2 and the ribosomal protein gene RP51A. We have now extended our studies of TUF‐UASrpg binding by analysing–using footprinting and gel electrophoretic retardation techniques–the genes encoding the ribosomal proteins L25, rp28 (both copy genes), S24 + L46 and S33. Most, but not all, conserved sequence elements occurring in front of these genes, turned out to represent binding sites for the same factor, TUF. The two functionally important boxes that are found in a tandem arrangement (a characteristic of many rp genes) upstream of the L25 gene are indistinguishable in their factor binding specificity. Large differences were shown to exist in the affinity of the TUF factor for the various individual boxes and in the half‐life of the protein‐DNA complexes. No binding cooperativity could be demonstrated on adjacent sites on L25 or RP51A promoters. Based on binding data, the UASrpg sequence ACACCCATACAT appears to be the one recognized most efficiently by the TUF factor. Previously, no conserved box was found in front of the gene encoding S33. Nevertheless, complex formation with the protein fraction used was observed in the upstream region of the S33 gene. Competition experiments disclosed the existence of an additional binding component, distinct from TUF. This component may possibly regulate a subset of genes for the translational apparatus.

3'-End formation of transcripts from the yeast rRNA operon.

Deletion analysis of artificial rRNA minigenes transformed into Saccharomyces cerevisiae revealed that a 110 bp long fragment corresponding to positions ‐36 to +74 relative to the 3′‐end of the 26S rRNA gene, is both necessary and sufficient for obtaining transcripts whose 3′‐termini are identical to those of 26S and 37S (pre‐)rRNA. These termini are produced via processing of longer transcripts because in an rna 82.1 mutant the majority of the minigene transcripts extend further downstream. Since the rna 82.1 mutation inactivates an endonuclease involved in the 3′‐processing of 5S pre‐rRNA it is concluded that the maturation of 37S‐ and that of 5S pre‐rRNA requires a common factor. Comparison of the spacer sequences between Saccharomyces carlsbergensis, Saccharomyces rosei and Hansenula wingei revealed several conserved sequence blocks within the region between +10 and +55. These conserved sequence tracts, which are part of a longer region showing dyad symmetry, are supposed to be involved in the interaction with the processing component(s). Deletion of the sequences required for the formation of the 3′‐ends of 26S rRNA and 37S pre‐rRNA revealed a putative terminator for transcription by RNA polymerase I situated at position +210. This site maps within a DNA fragment that also contains the enhancing element for rDNA transcription by RNA polymerase I.

The investigation of the ribosomal RNA sites in yeast DNA by the hybridization technique

Abstract By the hybridization technique of Gillespie and Spiegelman , the fraction of Saccharomyces carlsbergensis DNA complementary to homologous ribosomal RNA (rRNA) was found to be 1.9 % corresponding to a relatively high number of rRNA cistrons on yeast DNA. Possible contributions to this high hybridization percentage by contaminating messenger RNA (mRNA) or by contaminating mitochondrial nucleic acids could be excluded. The formed yeast rRNA-DNA hybrid proved to have a high thermal stability and a narrow melting range, demonstrating its great homogeneity. The two rRNA components (17 S and 26 S), purified by disc-gel electrophoresis, showed considerable cross-hybridization, indicating that the base sequences of the two RNA components are very similar.