Functional analysis of the regulatory region adjacent to the cargB gene of Saccharomyces cerevisiae. Nucleotide sequence, gene fusion experiments and cis-dominant regulatory mutation analysis

Self-protective responses to norvaline-induced stress in a leucyl-tRNA synthetase editing-deficient yeast strain

The editing function of aminoacyl-tRNA synthetases (aaRSs) is indispensible for formation of the correct aminoacyl-tRNAs. Editing deficiency may lead to growth inhibition and the pathogenesis of various diseases. Herein, we confirmed that norvaline (Nva) but not isoleucine or valine is the major threat to the editing function of Saccharomyces cerevisiae leucyl-tRNA synthetase (ScLeuRS), both in vitro and in vivo. Nva could be misincorporated into the proteome of the LeuRS editing-deficient yeast strain (D419A/ScΔleuS), potentially resulting in dysfunctional protein folding and growth delay. Furthermore, the exploration of the Nva-induced intracellular stress response mechanism in D419A/ScΔleuS revealed that Hsp70 chaperones were markedly upregulated in response to the potential protein misfolding. Additionally, proline (Pro), glutamate (Glu) and glutamine (Gln), which may accumulate due to the conversion of Nva, collectively contributed to the reduction of reactive oxygen species (ROS) levels in Nva-treated D419A/ScΔleuS cells. In conclusion, our study highlights the significance of the editing function of LeuRS and provides clues for understanding the intracellular stress protective mechanisms that are triggered in aaRS editing-deficient organisms.

The role of ornithine aminotransferase in fruiting body formation of the mushroom Agaricus bisporus

The complete oat gene and cDNA from the commercial mushroom, Agaricus bisporus, encoding ornithine aminotransferase (OAT) was characterized. The gene encodes a 466 amino acid protein and provides the first fully reported homobasidiomycete OAT protein sequence. The gene is interrupted by ten introns, and no mitochondrial targeting motif was present pointing to a cytoplasmic localization. The function of the gene was demonstrated by complementation of a Saccharomyces cerevisiae mutant unable to utilize ornithine as a sole source of nitrogen with an A. bisporus oat cDNA construct. Northern analysis of the oat gene together with the pruA gene (encoding Delta(1)-pyrroline-5-carboxylate dehydrogenase) showed that transcripts of both genes were lower during the first stages of fruiting body development. The higher expression of the oat gene in later stages of development, suggests the importance of ornithine metabolism for the redistribution of metabolites in the developing mushroom. Hplc analysis of all amino acids revealed that ornithine levels increased during fruiting body development whereas proline levels fell.

Synergistic operation of the CAR2 (Ornithine transaminase) promoter elements in Saccharomyces cerevisiae

Dal82p binds to the UIS(ALL) sites of allophanate-induced genes of the allantoin-degradative pathway and functions synergistically with the GATA family Gln3p and Gat1p transcriptional activators that are responsible for nitrogen catabolite repression-sensitive gene expression. CAR2, which encodes the arginine-degradative enzyme ornithine transaminase, is not nitrogen catabolite repression sensitive, but its expression can be modestly induced by the allantoin pathway inducer. The dominant activators of CAR2 transcription have been thought to be the ArgR and Mcm1 factors, which mediate arginine-dependent induction. These observations prompted us to investigate the structure of the CAR2 promoter with the objectives of determining whether other transcription factors were required for CAR2 expression and, if so, of ascertaining their relative contributions to CAR2's expression and control. We show that Rap1p binds upstream of CAR2 and plays a central role in its induced expression irrespective of whether the inducer is arginine or the allantoin pathway inducer analogue oxalurate (OXLU). Our data also explain the early report that ornithine transaminase production is induced when cells are grown with urea. OXLU induction derives from the Dal82p binding site, which is immediately downstream of the Rap1p site, and Dal82p functions synergistically with Rap1p. This synergism is unlike all other known instances of Dal82p synergism, namely, that with the GATA family transcription activators Gln3p and Gat1p, which occurs only in the presence of an inducer. The observations reported suggest that CAR2 gene expression results from strong constitutive transcriptional activation mediated by Rap1p and Dal82p being balanced by the down regulation of an equally strong transcriptional repressor, Ume6p. This balance is then tipped in the direction of expression by the presence of the inducer. The formal structure of the CAR2 promoter and its operation closely follow the model proposed for CAR1.

Nitrogen catabolite repression in Saccharomyces cerevisiae

In Saccharomyces cerevisiae the expression of all known nitrogen catabolite pathways are regulated by four regulators known as Gln3, Gat1, Dal80, and Deh1. This is known as nitrogen catabolite repression (NCR). They bind to motifs in the promoter region to the consensus sequence 5'GATAA 3'. Gln3 and Gat1 act positively on gene expression whereas Dal80 and Deh1 act negatively. Expression of nitrogen catabolite pathway genes known to be regulated by these four regulators are glutamine, glutamate, proline, urea, arginine. GABA, and allantonie. In addition, the expression of the genes encoding the general amino acid permease and the ammonium permease are also regulated by these four regulatory proteins. Another group of genes whose expression is also regulated by Gln3, Gat1, Dal80, and Deh1 are some proteases, CPS1, PRB1, LAP1, and PEP4, responsible for the degradation of proteins into amino acids thereby providing a nitrogen source to the cell. In this review, all known promoter sequences related to expression of nitrogen catabolite pathways are discussed as well as other regulatory proteins. Overview of metabolic pathways and promotors are presented.

Isolation of the ornithine-delta-aminotransferase cDNA and effect of salt stress on its expression in Arabidopsis thaliana

To evaluate the relative importance of ornithine (Orn) as a precursor in proline (Pro) synthesis, we isolated and sequenced a cDNA encoding the Orn-delta-aminotransferase (delta-OAT) from Arabidopsis thaliana. The deduced amino acid sequence showed high homology with bacterial, yeast, mammalian, and plant sequences, and the N-terminal residues exhibited several common features with a mitochondrial transit peptide. Our results show that under both salt stress and normal conditions, delta-OAT activity and mRNA in young plantlets are slightly higher than in older plants. This appears to be related to the necessity to dispose of an easy recycling product, glutamate. Analysis of the expression of the gene revealed a close association with salt stress and Pro production. In young plantlets, free Pro content, Delta1-pyrroline-5-carboxylate synthase mRNA, delta-OAT activity, and delta-OAT mRNA were all increased by salt-stress treatment. These results suggest that for A. thaliana, the Orn pathway, together with the glutamate pathway, plays an important role in Pro accumulation during osmotic stress. Conversely, in 4-week-old A. thaliana plants, although free Pro level also increased under salt-stress conditions, the delta-OAT activity appeared to be unchanged and delta-OAT mRNA was not detectable. Delta1-pyrroline-5-carboxylate synthase mRNA was still induced at a similar level. Therefore, for the adult plants the free Pro increase seemed to be due to the activity of the enzymes of the glutamate pathway.

The phtE locus in the phaseolotoxin gene cluster has ORFs with homologies to genes encoding amino acid transferases, the AraC family of transcriptional factors, and fatty acid desaturases

A cluster of genes involved in the production of phaseolotoxin, a phytotoxin produced by Pseudomonas syringae pv. phaseolicola, contains eight (phtA through phtH) complementation groups (Y. X. Zhang, K. B. Rowley, and S. S. Patil, J. Bacteriol., 175:6451-6458, 1993). In this study, sequencing of the region encompassing the phtE locus revealed six putative open reading frames (ORFs), each preceded by a putative ribosomal binding site, and all oriented in the same direction. Reverse transcription-polymerase chain reaction suggested that the phtE locus is transcribed as one large (6.4 kb) transcript, indicating that the ORFs constitute an operon. Primer extension analysis showed that the transcript begins at a T, located 31 bp upstream of the ATG codon of ORF1. Comparison of the sequences of the putative ORFs with the sequences of known genes revealed that ORF3, encoding a protein containing 395 amino acids, has 55% similarity to the acetylornithine aminotransferase gene from Escherichia coli, and the ornithine aminotransferase genes from other organisms. A lysine residue that is a binding site for pyridoxal phosphate and an arginine residue that is a binding site for the alpha-carboxylate group of the substrate are conserved in ORF3. These data suggest that ORF3 encodes a protein involved in the biosynthesis of ornithine, a constituent of phaseolotoxin. ORF5, encoding a peptide of 378 amino acid residues, possesses a helix-turn-helix motif at the C-terminal end that is characteristic of the AraC family of transcriptional factors, and there is a possible leucine zipper at the N-terminal end of this peptide. ORF6, encoding a protein of 327 amino acids, has about 40% similarity with the fatty acid desaturase gene, desA, of Synechocystis Pcc6803 and considerable similarity with fatty acid desaturase genes from other organisms. ORF6 and desA show very similar hydropathy profiles and both contain a copper binding signature. Computer searches did not discover significant homologies in the data base for the other ORFs, but hydropathy analysis showed that all of them contain one to several hydrophobic domains, suggesting that the gene products of these ORFs may be membrane associated.

Molecular cloning and characterization of Drosophila ornithine aminotransferase gene

The cDNA encoding the Drosophila ananassae ornithine aminotransferase (OAT, EC 2.6.1.13) precursor has been cloned and characterized. The predicted OAT protein sequence is 433 amino acids long with a molecular mass of 47,352 Da and is highly homologous to a mammalian OAT, which is a mitochondrial matrix enzyme and is matured by processing of its amino terminal presequence peptide. The Drosophila OAT has characteristics of leader peptides present in mitochondrial proteins. Immunoblotting experiments using polyclonal antibodies against the partial sequence of the OAT protein revealed that the OAT monomer has a molecular mass of 44 kDa. These results suggest that the Drosophila OAT is also processed and localized in the mitochondria. Quantitation of the OAT mRNA and measurement of the OAT activity during fly development show that OAT is expressed at high levels in the fat body of the third instar larvae in both D. ananassae and D. melanogaster.

Gene MRP-L4, encoding mitochondrial ribosomal protein YmL4, is indispensable for proper non-respiratory cell functions in yeast

In order to characterize individual protein components of the mitochondrial (mt) ribosome for regulatory, functional and evolutionary studies, the yeast nuclear gene MRP-L4 (accession No. Z30582), coding for the mt ribosomal protein (MRP) YmL4, has been cloned using oligodeoxyribonucleotides (oligos) deduced from a partial amino acid (aa) sequence [Graack et al., FEBS Lett. 242 (1988) 4-8] as screening probes. MRP-L4 is located on chromosome XII and codes for a slightly basic protein of 319 aa. The first 14 aa have not been found in the mature protein, and putatively form a signal peptide that is cleaved off during or after mt import. YmL4 has an N terminus very rich in Pro residues, and at its C terminus contains four hydrophobic domains. YmL4 shows no significant sequence similarity to any other sequence from the databases. Gene disruption shows the MRP-L4 product to be indispensable for mt function in cells growing on non-fermentable carbon sources. In contrast to nearly all other MRPs investigated so far, gene disruption of MRP-L4 also affects growth of yeast cells on fermentable carbon sources, suggesting additional cytosolic and/or mt functions of YmL4 besides its involvement in mt protein biosynthesis.

Aminotransferases: demonstration of homology and division into evolutionary subgroups

A total of 150 amino acid sequences of vitamin B6-dependent enzymes are known to date, the largest contingent being furnished by the aminotransferases with 51 sequences of 14 different enzymes. All aminotransferase sequences were aligned by using algorithms for sequence comparison, hydropathy patterns and secondary structure predictions. The aminotransferases could be divided into four subgroups on the basis of their mutual structural relatedness. Subgroup I comprises aspartate, alanine, tyrosine, histidinol-phosphate, and phenylalanine aminotransferases; subgroup II acetylornithine, ornithine, omega-amino acid, 4-aminobutyrate and diaminopelargonate aminotransferases; subgroup III D-alanine and branched-chain amino acid aminotransferases, and subgroup IV serine and phosphoserine aminotransferases. (N-1) Profile analysis, a more stringent application of profile analysis [Gribskov, M., McLachlan, A. D. and Eisenberg, D. (1987) Proc. Natl Acad. Sci. USA 84, 4355-4358], established the homology among the enzymes of each subgroup as well as among all subgroups except subgroup III. However, similarity of active-site segments and the hydropathy patterns around invariant residues suggest that subgroup III, though most distantly related, might also be homologous with the other aminotransferases. On the basis of the comprehensive alignment, a new numbering of amino acid residues applicable to aminotransferases (AT) in general is proposed. In the multiply aligned sequences, only four out of a total of about 400 amino acid residues proved invariant in all 51 sequences, i.e. Gly(314AT)197, Asp/Glu(340AT)222, Lys(385AT)258 and Arg(562AT)386, the number not in parentheses corresponding to the structure of porcine cytosolic aspartate aminotransferase. Apparently, the aminotransferases constitute a group of homologous proteins which diverged into subgroups and, with some exceptions, into substrate-specific individual enzymes already in the universal ancestor cell.

Characterization of the DNA target site for the yeast ARGR regulatory complex, a sequence able to mediate repression or induction by arginine

We have determined the sequences and positions of the cis elements required for proper functioning of the ARG3 promoter and proper arginine-specific control. A TATA box located 100 nucleotides upstream of the transcription start was shown to be essential for ARG3 transcription. Two sequences involved in normal arginine-mediated repression lie immediately downstream of the TATA box: an essential one (arginine box 1 [AB1]) and a secondary one (arginine box 2 [AB2]). AB1 was defined by saturation mutagenesis and is an asymmetrical sequence. A stringently required CGPu motif in AB1 is conserved in all known target sites of C6 zinc cluster DNA-binding proteins, leading us to propose that AB1 is the binding site of ARGRII, another member of the C6 family. The palindromic AB2 sequence is suggested, on the basis of published data, to be the binding site of ARGRI, possibly in heterodimerization with MCM1. AB2 and AB1 correspond respectively to the 5' and 3' halves of two adjacent similar sequences of 29 bp that appear to constitute tandem operators. Indeed, mutations increasing the similarity of the other halves with AB1 and AB2 cause hyperrepression. To mediate repression, the operator must be located close to the transcription initiation region. It remains functional if the TATA box is moved downstream of it but becomes inoperative in repression when displaced to a far-upstream position where it mediates an arginine and ARGR-dependent induction of gene expression. The ability of the ARG3 operator to act either as an operator or as an upstream activator sequence, depending on its location, and the functional organization of the anabolic and catabolic arginine genes suggest a simple model for arginine regulation in which an activator complex can turn into a repressor when able to interfere sterically with the process of transcription initiation.

Characterization of the DNA target site for the yeast ARGR regulatory complex, a sequence able to mediate repression or induction by arginine

We have determined the sequences and positions of the cis elements required for proper functioning of the ARG3 promoter and proper arginine-specific control. A TATA box located 100 nucleotides upstream of the transcription start was shown to be essential for ARG3 transcription. Two sequences involved in normal arginine-mediated repression lie immediately downstream of the TATA box: an essential one (arginine box 1 [AB1]) and a secondary one (arginine box 2 [AB2]). AB1 was defined by saturation mutagenesis and is an asymmetrical sequence. A stringently required CGPu motif in AB1 is conserved in all known target sites of C6 zinc cluster DNA-binding proteins, leading us to propose that AB1 is the binding site of ARGRII, another member of the C6 family. The palindromic AB2 sequence is suggested, on the basis of published data, to be the binding site of ARGRI, possibly in heterodimerization with MCM1. AB2 and AB1 correspond respectively to the 5' and 3' halves of two adjacent similar sequences of 29 bp that appear to constitute tandem operators. Indeed, mutations increasing the similarity of the other halves with AB1 and AB2 cause hyperrepression. To mediate repression, the operator must be located close to the transcription initiation region. It remains functional if the TATA box is moved downstream of it but becomes inoperative in repression when displaced to a far-upstream position where it mediates an arginine and ARGR-dependent induction of gene expression. The ability of the ARG3 operator to act either as an operator or as an upstream activator sequence, depending on its location, and the functional organization of the anabolic and catabolic arginine genes suggest a simple model for arginine regulation in which an activator complex can turn into a repressor when able to interfere sterically with the process of transcription initiation.

Determination of the DNA-binding sequences of ARGR proteins to arginine anabolic and catabolic promoters

ARGRI, ARGRII, and ARGRIII proteins regulate the expression of arginine anabolic and catabolic genes. The integrity of these three proteins is required to observe the formation of a DNA-protein complex with the different promoters of arginine coregulated genes. A study of deletions and point mutations created in the 5' noncoding region of ARG3, ARG5,6, CAR1, and CAR2 genes shows that at least two regions, called BoxA and BoxB, are required for proper regulation of these genes by arginine and ARGR proteins. By gel retardation assay and DNase I footprinting analysis, we have determined precisely the target of the ARGR proteins. Sequences in and around BoxA are necessary for ARGR binding to these four promoters in vitro, whereas sequences in and around BoxB are clearly protected against DNase I digestion only for CAR1. Sequences present at BoxA and BoxB are well conserved among the four promoters. Moreover, pairing can occur between sequences at BoxA and BoxB which could lead to the creation of secondary structures in ARG3, ARG5,6, CAR1, and CAR2 promoters, favoring the binding of ARGR proteins in vivo.

Determination of the DNA-binding sequences of ARGR proteins to arginine anabolic and catabolic promoters

ARGRI, ARGRII, and ARGRIII proteins regulate the expression of arginine anabolic and catabolic genes. The integrity of these three proteins is required to observe the formation of a DNA-protein complex with the different promoters of arginine coregulated genes. A study of deletions and point mutations created in the 5' noncoding region of ARG3, ARG5,6, CAR1, and CAR2 genes shows that at least two regions, called BoxA and BoxB, are required for proper regulation of these genes by arginine and ARGR proteins. By gel retardation assay and DNase I footprinting analysis, we have determined precisely the target of the ARGR proteins. Sequences in and around BoxA are necessary for ARGR binding to these four promoters in vitro, whereas sequences in and around BoxB are clearly protected against DNase I digestion only for CAR1. Sequences present at BoxA and BoxB are well conserved among the four promoters. Moreover, pairing can occur between sequences at BoxA and BoxB which could lead to the creation of secondary structures in ARG3, ARG5,6, CAR1, and CAR2 promoters, favoring the binding of ARGR proteins in vivo.

Dissection of the bifunctional ARGRII protein involved in the regulation of arginine anabolic and catabolic pathways

ARGRII is a regulatory protein which regulates the arginine anabolic and catabolic pathways in combination with ARGRI and ARGRIII. We have investigated, by deletion analysis and fusion to LexA protein, the different domains of ARGRII protein. In contrast to other yeast regulatory proteins, 92% of ARGRII is necessary for its anabolic repression function and 80% is necessary for its catabolic activator function. We can define three domains in this protein: a putative DNA-binding domain containing a zinc finger motif, a region more involved in the repression activity located around the RNase-like sequence, and a large activation domain.

Dissection of the bifunctional ARGRII protein involved in the regulation of arginine anabolic and catabolic pathways

ARGRII is a regulatory protein which regulates the arginine anabolic and catabolic pathways in combination with ARGRI and ARGRIII. We have investigated, by deletion analysis and fusion to LexA protein, the different domains of ARGRII protein. In contrast to other yeast regulatory proteins, 92% of ARGRII is necessary for its anabolic repression function and 80% is necessary for its catabolic activator function. We can define three domains in this protein: a putative DNA-binding domain containing a zinc finger motif, a region more involved in the repression activity located around the RNase-like sequence, and a large activation domain.

Escherichia coli and Saccharomyces cerevisiae acetylornithine aminotransferase: evolutionary relationship with ornithine aminotransferase

Genes argD and ARG8, encoding the acetylornithine aminotransferase (ACOAT) subunit in Escherichia coli and Saccharomyces cerevisiae, respectively, have been cloned and sequenced. The deduced amino acid sequences show substantial similarity. Moreover, they resemble ornithine aminotransferase (OAT) sequences (i.e., those from yeast, rat and man); the observed similarities are statistically significant, indicating that the enzymes are homologous. However, in contrast to OATs, which appear to be substrate (i.e., ornithine)-specific, S. cerevisiae ACOAT transaminates ornithine about as efficiently as E. coli does. The evolutionary relationship between ACOATs and OATs is discussed in terms of substrate ambiguity.

Evolutionary relationships among aminotransferases. Tyrosine aminotransferase, histidinol-phosphate aminotransferase, and aspartate aminotransferase are homologous proteins

A data base was compiled containing the amino acid sequences of 12 aspartate aminotransferases and 11 other aminotransferases. A comparison of these sequences by a standard alignment method confirmed the previously reported homology of all aspartate aminotransferases and Escherichia coli tyrosine aminotransferase. However, no significant similarity between these proteins and any of the other aminotransferases was detected. A more rigorous analysis, focusing on short sequence segments rather than the total polypeptide chain, revealed that rat tyrosine aminotransferase and Saccharomyces cerevisiae and Escherichia coli histidinol-phosphate aminotransferase share several homologous sequence segments with aspartate aminotransferases. For comparison of the complete sequences, a multiple sequence editor was developed to display the whole set of amino acid sequences in parallel on a single work-sheet. The editor allows gaps in individual sequences or a set of sequences to be introduced and thus facilitates their parallel analysis and alignment. Several clusters of invariant residues at corresponding positions in the amino acid sequences became evident, clearly establishing that the cytosolic and the mitochondrial isoenzyme of vertebrate aspartate aminotransferase, E. coli aspartate aminotransferase, rat and E. coli tyrosine aminotransferase, and S. cerevisiae and E. coli histidinol-phosphate aminotransferase are homologous proteins. Only 12 amino acid residues out of a total of about 400 proved to be invariant in all sequences compared; they are either involved in the binding of pyridoxal 5'-phosphate and the substrate, or appear to be essential for the conformation of the enzymes.

At least two mutant alleles of ornithine delta-aminotransferase cause gyrate atrophy of the choroid and retina in Finns

Gyrate atrophy of the choroid and retina (GA) is an inherited chorioretinal degeneration caused by deficiency of ornithine delta-aminotransferase (OAT; L-ornithine: 2-oxo-acid aminotransferase; EC 2.6.1.13). GA is one of the "Finnish genetic diseases," a group of several rare monogenic disorders that occur with increased frequency in the Finnish population. Using a combination of RNase A protection, genomic cloning, and polymerase chain reaction amplification of genomic DNA, we found one of two missense mutant OAT alleles to be present in each of 16 Finnish GA pedigrees. The first mutation R180T, in which arginine-180 is replaced by threonine, was present in homozygous form in patients from two pedigrees. The second mutation L402P, in which leucine-402 is replaced by proline, was present in homozygous form in patients from 14 pedigrees. Neither mutation was present in 19 Finnish controls. L402P was not present in 18 non-Finnish GA patients but R180T was found in an American GA patient. We constructed full-length mutant cDNAs by amplifying patient cDNA with the polymerase chain reaction and cloning a restriction fragment containing the mutation into an otherwise normal human OAT cDNA. These mutant cDNAs were then expressed in CHO-K1 cells, which lack endogenous OAT. Both R180T and L402P inactivate OAT. These results show molecular heterogeneity in GA alleles even in the Finnish population.