A yeast ribosomal protein gene whose intron is in the 5' leader

5' untranslated regions: the next regulatory sequence in yeast synthetic biology

When developing industrial biotechnology processes, Saccharomyces cerevisiae (baker's yeast or brewer's yeast) is a popular choice as a microbial host. Many tools have been developed in the fields of synthetic biology and metabolic engineering to introduce heterologous pathways and tune their expression in yeast. Such tools mainly focus on controlling transcription, whereas post-transcriptional regulation is often overlooked. Herein we discuss regulatory elements found in the 5' untranslated region (UTR) and their influence on protein synthesis. We provide not only an overall picture, but also a set of design rules on how to engineer a 5' UTR. The reader is also referred to currently available models that allow gene expression to be tuned predictably using different 5' UTRs.

A yeast intron as a translational terminator in a plasmid shuttle vector

Plasmid shuttle vectors that contain both prokaryotic (Escherichia coli) and eukaryotic origins of replication are routinely used in molecular biology since E. coli is generally the organism of choice for manipulation of recombinant DNA. Initial transformation of the shuttle vector into E. coli allows production of microgram quantities of DNA suitable for transformation of low-transformation-efficiency hosts. A shuttle/expression vector for the yeast Kluyveromyces lactis, pCWK1, allows recombinant protein fused to the killer toxin signal sequence to be secreted to the medium. The heterologous genes are transcribed under the control of the K. lactis LAC4 promoter, which is tightly regulated in K. lactis. However, in E. coli the LAC4 promoter functions constitutively, and as a result, uncontrolled transcription and translation of genes that are toxic in E. coli can result in cell death, and subsequent failure to recover intact E. coli transformants. We have constructed and tested a modified shuttle vector that contains a K. lactis ribosomal intron that acts as a translational terminator in E. coli, preventing or reducing the expression of recombinant proteins and avoiding toxicity. When transcribed in K. lactis, the intron is spliced from the mRNA allowing the translation of intact full-length, active recombinant gene product.

Glucose triggers different global responses in yeast, depending on the strength of the signal, and transiently stabilizes ribosomal protein mRNAs

Glucose exerts profound effects upon yeast physiology. In general, the effects of high glucose concentrations (>1%) upon Saccharomyces cerevisiae have been studied. In this paper, we have characterized the global responses of yeast cells to very low (0.01%), low (0.1%) and high glucose signals (1.0%) by transcript profiling. We show that yeast is more sensitive to very low glucose signals than was previously thought, and that yeast displays different responses to these different glucose signals. Genes involved in central metabolic pathways respond rapidly to very low glucose signals, whereas genes involved in the biogenesis of cytoplasmic ribosomes generally respond only to glucose concentrations of> 0.1%. We also show that cytoplasmic ribosomal protein mRNAs are transiently stabilized by glucose, indicating that both transcriptional and post-transcriptional mechanisms combine to accelerate the accumulation of ribosomal protein mRNAs. Presumably, this facilitates rapid ribosome biogenesis after exposure to glucose. However, our data indicate that yeast activates ribosome biogenesis only when sufficient glucose is available to make this metabolic investment worthwhile. In contrast, the regulation of metabolic functions in response to very low glucose signals presumably ensures that yeast can exploit even minute amounts of this preferred nutrient.

Cloning and characterisation of cDNA encoding the Trypanosoma brucei ribosomal protein L24

A cDNA encoding ribosomal protein L24 was amplified by PCR from the protozoan parasite, Trypanosoma brucei. The 621 nucleotide cDNA had an open reading frame of 375 nucleotides, predicting a highly basic protein of 125 aa. Database searches revealed 33-40% identity between the T. brucei RPL24 protein and several eukaryotic RPL24 homologues. Southern blot analysis indicated that the gene was present as a single copy, and a transcript of approximately 620 nucleotides was detected in procyclic forms of the parasite. Interestingly, T. brucei PRL24 is the smallest eukaryotic RPL24 protein described to date. It is also the most divergent of the known kinetoplastid ribosomal proteins.

Molecular characterization of a saline-soluble lectin from a parasitic fungus. Extensive sequence similarities between fungal lectins

It has been proposed that the interactions between several parasitic and pathogenic fungi and their hosts are mediated by soluble lectins present in the fungus. We have cloned and analyzed a gene encoding such a lectin (AOL) from the nematophagous fungus Arthrobotrys oligospora (deuteromycete). The deduced primary structure of the AOL gene displayed an extensive similarity (identity 46.3%) to that of a gene encoding a lectin (ABL) recently isolated from the mushroom Agaricus bisporus (basidiomycete), but not to any other fungal, microbial, plant or animal lectins. The similarities between AOL and ABL were further demonstrated by the observation that an antibody specific for AOL cross-reacted with ABL. Together with data showing that AOL has a binding specificity that is similar to that of ABL [Rosen, S., Bergström, J., Karlsson, K.-A. & Tunlid, A. (1996) Eur. J. Biochem. 238, 830-837], these results indicate that AOL and ABL are members of a novel family of saline soluble lectins present in fungi. Southern blots indicated that there is only one AOL gene in the genome encoding a subunit (monomer) of the lectin. The primary structure of AOL did not show the presence of a typical N-terminal signal sequence. Comparison of the deduced primary structure with the molecular mass of AOL as determined by electrospray mass spectrometry (16153 Da), indicated that AOL has an acetylated N-terminal but no other post-translational modifications, and that a minor isoform is formed by deamidation. Circular dichroism (CD) spectroscopy suggested that the secondary structure of AOL contains 34% beta-sheets, 21% alpha-helix, and 45% turns and coils.

The sequence of a 27 kb segment on the right arm of chromosome VII from Saccharomyces cerevisiae reveals MOL1, NAT2, RPL30B, RSR1, CYS4, PEM1/CHO2, NSR1 genes and ten new open reading frames

The DNA sequence of a 26,677 bp fragment from the right arm of chromosome VII from Saccharomyces cerevisiae reveals 18 open reading frames (ORFs) longer than 300 bp. Eight ORFs correspond to previously characterized genes. G6620 is the 3' end of the MOL1 gene coding for a polypeptide similar to stress-inducible proteins from Fusarium; G6630 is the NAT2 gene which encodes a methionine N-acetyltransferase; G6635 is the RPL30B gene coding for the ribosomal protein L30; G6658 is RSR1 encoding a ras-related protein; G6667 is CYS4, the gene for cystathionine beta-synthase; G6670 is identical to ORF2 located close to CYS4; G6673 is PEM1/CHO2 encoding a phosphatidylethanolamine methyltransferase; G7001 is the NSR1 gene coding for a nuclear signal recognition protein. G6664 shares significant homology with the ORF YKR076w from chromosome XI. The other nine ORFs show no significant homology to any protein sequence presently available in the public data bases.

The levels of yeast gluconeogenic mRNAs respond to environmental factors

The FBP1 and PCK1 genes encode the gluconeogenic enzymes fructose-1,6-bisphosphatase and phosphoenolpyruvate carboxykinase, respectively. In the yeast, Saccharomyces cerevisiae, the corresponding mRNAs are present at low levels during growth on glucose, but are present at elevated levels during growth on gluconeogenic carbon sources. We demonstrate that the levels of the FBP1 and PCK1 mRNAs are acutely sensitive to the addition of glucose to the medium and that the levels of these mRNAs decrease rapidly when glucose is added to the medium at a concentration of only 0.005%. At this concentration, glucose blocks FBP1 and PCK1 transcription, but has no effect on iso-1 cytochrome c (CYC1) mRNA levels. Glucose also increases the rate of degradation of the PCK1 mRNA approximately twofold, but only has a slight effect upon FBP1 mRNA turnover. We show that the levels of the FBP1 and PCK1 mRNAs are also sensitive to other environmental factors. The levels of these mRNAs decrease transiently in response to a decrease of the pH from pH 7.5 to pH 6.5 in the medium, or to a mild temperature shock (from 24 degrees C to 36 degrees C). The latter response appears to be mediated by accelerated mRNA decay.

The two genes encoding yeast ribosomal protein S8 reside on different chromosomes, and are closely linked to the hsp70 stress protein genes SSA3 and SSA4

A 7.4 kb segment of chromosome II was sequenced and analysed. This segment is part of the 25 kb insert of cosmid clone alpha 1004.10 which is located on the left arm of chromosome II. Sequence analysis revealed four open reading frames (ORFs), of which two had been characterized previously (SSA3, AAR2) and one was not identified. The other ORF was precisely 600 bp long and the deduced protein sequence predicted a very basic protein (pI = 11.1; molecular weight = 22.5 kDa). Evidence was found that the ORF is the S40 ribosomal protein gene (RPG) S8. Consensus splice signals were found in the 5' leader sequence and also potential RPG-specific sequences. Chromoblot analysis revealed a second copy of the S8 RPG on chromosome IV or VIII. This copy is also closely linked to an hsp70 protein gene, SSA4.

Characterization of cDNA clones encoding the human homologue of Saccharomyces cerevisiae ribosomal protein L30

We have isolated cDNA clones encoding the human homologue (hL30) of yeast ribosomal protein (r-protein) L30. The hL30 nucleotide (nt) sequence shows high homology to the yeast sequences and also to a partial Xenopus laevis sequence previously identified as an immunoglobulin heavy chain. The 5' end of hL30 is pyrimidine-rich, as is the case for most other mammalian r-protein mRNAs. The open reading frame consists of 157 codons with a C-terminal region that is different from corresponding regions of the yeast proteins. In several human tissue culture cells, the mRNA encoding hL30 is approx. 700 nt in length.

The Drosophila melanogaster ribosomal protein L17A-encoding gene

The structure and sequence of the gene encoding the Drosophila melanogaster homolog of the human and yeast large-subunit ribosomal protein L17A (rpL17A) is presented. The deduced amino acid (aa) sequence of 140 residues exhibits 87% and 77% identity to that of the human (140 aa) and yeast (137 aa) rpL17As, respectively. The D. melanogaster rpL17A gene is single copy and maps at 58F6-59A3, a chromosome region encompassing a previously characterized Minute locus, M(2)I. Despite this extensive homology in their protein products, the D. melanogaster and yeast rpL17A genes display different exon-intron structures, with the first D. melanogaster intron mapping within the 5'-untranslated mRNA leader. The rpL17A gene gives rise to a single 600-nucleotide transcript present throughout development, and is located close to another similarly expressed gene. The 5' end of the D. melanogaster rpL17A mRNA contains a polypyrimidine tract displayed by several mammalian rp genes and involved in translational control of their expression.

Structural determination of Saccharomyces cerevisiae rig gene and identification of its product as ribosomal protein S21

rig was originally isolated from a rat insulinoma-derived cDNA library. The 145 amino acid sequence of the rig protein is invariant in mammalian cDNAs. In this paper, we have isolated the cDNA and genomic clones for yeast (Saccharomyces cerevisiae) rig, determined their nucleotide sequences, and identified the gene product. The gene and the mRNA encode a basic protein of 142 amino acids which has 61.3% amino acid identity with mammalian rig protein. On two-dimensional gel electrophoresis, the in vitro transcription/translation product of yeast rig cDNA co-migrated with yeast ribosomal protein S21. These results led to the conclusion that yeast rig ribosomal protein S21 and to the determination of the previously unknown primary structure of yeast S21 protein. Unlike most ribosomal protein genes of S. cerevisiae, the gene exists as a single copy in a haploid set of the yeast genome and has no intron, locating at chromosome VII or XV.

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).

Intercistronic group III introns in polycistronic ribosomal protein operons of chloroplasts

A novel ribosomal protein operon in the Euglena gracilis chloroplast genome was characterized. It encodes the genes for ribosomal proteins S4 and S11 (rps4 and rps11). The coding region of the rps11 gene is interrupted by two introns of 107 and 100 bp. The introns belong to a distinct class known as group III introns. The major transcript from this operon was characterized as a fully spliced dicistronic rps4-rps11 mRNA by RNA blot analysis, primer extension sequencing, and cDNA cloning and sequencing. An additional 95 nucleotide (nt) group III intron was identified in the 123 nt rps4-rps11 intercistronic region. The identification of the intercistronic intron between the rps4 and rps11 genes was unexpected. Other RNA transcripts from regions of the genome that could potentially contain intercistronic introns were re-examined and two other intercistronic, group III introns were found. These are located in a large ribosomal protein operon between the genes for the ribosomal proteins L23 and L2, and between L14 and L5. There are at least 50 group III introns in the E. gracilis chloroplast genome. All but 6 are found in genes encoding protein components of the transcriptional and translational apparatus. The distribution of group III introns and the unusual location of intercistronic group III introns may reflect some aspect of gene expression, or provide some insight into the mechanism of their splicing.

A ribosomal protein gene family from Schizosaccharomyces pombe consisting of three active members

Recently, we have reported the isolation and characterization of a ribosomal protein gene from the fission yeast Schizosaccharomyces pombe. This gene was called K37. Here we describe the isolation of two genes which are related to the K37 gene. Sequence analysis of these genes revealed open reading frames encoding proteins which are almost identical to the ribosomal protein K37. Furthermore, all three genes are functional as determined by Northern analysis using transformed and wild type cells. The results indicate that S. pombe contains a ribosomal protein gene family, designated the K-family, consisting of three active members. The promoter regions of the three members are compared and several common motifes are identified which might serve as transcriptional activators in these genes.

Primary structures of five ribosomal proteins from the archaebacterium Halobacterium marismortui and their structural relationships to eubacterial and eukaryotic ribosomal proteins

The complete amino acid sequences of ribosomal proteins L9, L20, L21/22, L24 and L32 from the archaebacterium Halobacterium marismortui were determined. The comparison of the sequences of these proteins with those from other organisms revealed that proteins L21/22 and L24 are homologous to ribosomal protein Yrp29 from yeast and L19 from rat, respectively, and that H. marismortui L20 is homologous to L30 from eubacteria. H. marismortui ribosomal protein L9 showed sequence homology to both L29 from yeast and L15 from eubacteria. No homologous protein was found for H. marismortui L32. These results are discussed with respect to the phylogenetic relationship between eubacteria, archaebacteria and eukaryotes.

Sequence and structural features associated with translational initiator regions in yeast--a review

We have compared the translational initiator regions of 131 yeast genes. 95% utilize the first AUG from the 5' end of the message as the start codon for translation. Yeast leader regions in general are rich in adenine nucleotides (nt), have an average length of 52 nt, and are void of significant secondary structure. Sequences immediately adjacent to AUG start codons are preferred, however, the bias in nucleotide distribution (5'-A-YAA-UAAUGUCU-3') does not reflect a higher eukaryotic consensus (5'-CACCAUGG-3') with the exception of an adenine nucleotide preference at the -3 position. A minority of yeast mRNAs that contain AUG codons in the leader region that do not serve as the start codon for the primary gene product differ from the majority of mRNAs by one or more of these general properties. This analysis appears to indicate that basic features associated with yeast leader regions are consistent with a general mechanism of initiation of protein synthesis in eukaryotes, as proposed by the ribosomal 'scanning' model, but perhaps only basic features associated with ribosomal recognition of an AUG start codon are intact.

The yeast RNA gene products are essential for mRNA splicing in vitro

The yeast rna mutations (rna2-rna11) are a set of temperature-sensitive mutations that result in the accumulation of intron-containing mRNA precursors at the restrictive temperature. We have used the yeast in vitro splicing system to investigate the role of products of the RNA genes in mRNA splicing. We have tested the heat lability of the in vitro mRNA splicing reaction in extracts isolated from mutant and wild-type cells. Extracts isolated from seven of the nine rna mutants demonstrated heat lability in this assay, while most wild-type extracts were stable under the conditions utilized. We have also demonstrated that heat inactivation usually results in the specific loss of an exchangeable component by showing that most combinations of heat-inactivated extracts from different mutants complement one another. In three cases (rna2, rna5, and rna11), the linkage of the in vitro defect to the rna mutations was ascertained by a combination of reversion, tetrad, and in vitro complementation analyses. Furthermore, each heat-inactivated extract was capable of complementation by at least one fraction of the wild-type splicing system. Thus many of the RNA genes are likely to code for products directly involved in and essential for mRNA splicing.

Mutations in a yeast intron demonstrate the importance of specific conserved nucleotides for the two stages of nuclear mRNA splicing

Mutations were introduced at all positions of the internal conserved sequence (ICS) and at three positions in the 5' junction sequence of a Saccharomyces cerevisiae actin intron contained within an actin-thymidine kinase fusion gene. Stage I of splicing is reduced by changes at all these positions. C or A replacement at the fifth nucleotide of the 5' sequence reduces the fidelity of RNA cleavage at the 5' exon-intron junction and results in an accumulation of aberrant lariat intermediate. Stage II of splicing is affected by changes in the first and second residues of the 5' sequence and in the penultimate position of the ICS. An A to G transition at the branch point of the ICS causes a major accumulation of lariat intermediate.

The gene for yeast ribosomal protein S31 contains an intron in the leader sequence

Analysis of the primary structure of the gene for yeast ribosomal protein S31 revealed two unusual features. First, an intron of 312 nucleotides is located within the 5'-untranslated region. Second, the coding sequence for the known amino-terminal peptide of the protein starts 13 codons downstream of the ATG initiation codon, suggesting that S31 is synthesized as a precursor which undergoes post-translational processing to the mature protein. Primer extension analysis showed that transcription of the S31 gene starts at multiple sites. The 5'-flanking region of the gene contains several, previously described, conserved sequence elements that may play a role in the coordinate expression of yeast ribosomal protein genes.

Molecular cloning and analysis of cDNA sequences for two ribosomal proteins from Artemia. The coordinate expression of genes for ribosomal proteins and elongation factor 1 during embryogenesis of Artemia

The large subunit of eukaryotic ribosomes contains acidic phosphoproteins which are related to L7/L12 from Escherichia coli. In the brine shrimp Artemia these proteins are designated eL12 and eL12'. We have isolated cDNA clones for these proteins from a cDNA bank that was constructed by the use of size-fractionated poly(A)-rich RNA (8-10S fraction) from Artemia and a synthetic oligonucleotide as primer. Clones containing DNA sequences coding for eL12 and eL12 were characterized by hybrid-selected translation and DNA sequencing. The proteins eL12 and eL12' share an identical peptide of 22 amino acids at their carboxy termini whereas the remaining part of the protein shows little sequence homology. The nucleotide sequences show a different codon use for the amino acids in the common carboxy terminus, thereby excluding a common exon coding for this part of both proteins. Despite the differences in amino acid sequence in the major part of eL12 and eL12' the proteins have a considerable degree of homology on the basis of the distribution of hydrophobic and hydrophilic amino acids over the polypeptide chains, in agreement with a related folding and function of both proteins. Relative levels of mRNA coding for eL12, eL12' and elongation factor 1 alpha were determined during the development of Artemia from a dormant cyst to a nauplius. The data show a coordinate expression of the genes for EF-1 alpha and both ribosomal proteins, excluding a differential expression of the genes for these related ribosomal proteins during embryogenesis. Analysis of the gene copy number for eL12 and eL12' indicates the presence of a few genes for each protein.

Conserved sequences upstream of yeast ribosomal protein genes

Computer analysis has previously revealed the presence of a 12-nucleotide common sequence element (AACATCTGCATGACA; HOMOL1) in the upstream regions of several yeast ribosomal protein genes. By extending the sequence analysis of the 5'-flanking regions of a number of other ribosomal protein genes (including those encoding S10-1, S10-2, S33 and L16-2) we could establish that HOMOL1 occurs upstream of most but not all yeast ribosomal protein genes. Apart from HOMOL1 an additional conserved sequence (ACCCATACATTTA; RPG-box) was detected in front of nearly all yeast ribosomal protein genes, although in some cases it is present in the opposite orientation in the other strand. There seems to be no correlation between the occurrence of one box and that of the other. However when both boxes are present the RPG-box is always located 3' to the HOMOL1-sequence mostly at a distance of only a few nucleotides. A further one-to-one comparison of the upstream regions of several yeast ribosomal protein genes revealed extensive additional sequence homologies that are suggested to be involved in the coordinate control of ribosomal protein gene expression in yeast.