Intron/exon structure of the chicken pyruvate kinase gene

The chicken pyruvate kinase gene is interrupted by at least ten introns, including nine introns within the coding region. We compare the structure of this gene with the three-dimensional protein structure of the homologous cat muscle enzyme. The introns are not randomly placed--they divide the coding sequence into fairly uniformly sized pieces encoding discrete elements of secondary structure. The introns tend to fall at interruptions between stretches of alpha-helix or beta-sheet residues, and each of the six exons that contribute to the barrel-shaped central domain include one or two repeats of a simple unit, an alpha-helix plus a beta strand. This structure suggests that introns were not inserted into a previously uninterrupted coding sequence, but instead are products of the evolution of the first pyruvate kinase gene. We have found some sequence homology between a segment of pyruvate kinase and the structurally homologous mononucleotide binding fold of alcohol dehydrogenase. The superposition of these two regions aligns an intron from the maize alcohol dehydrogenase gene four nucleotides from an intron in the chicken pyruvate kinase gene.     

The dihydrolipoyltransacetylase component of the pyruvate dehydrogenase complex from Azotobacter vinelandii. Molecular cloning and sequence analysis

The gene encoding the dihydrolipoyltransacetylase component (E2) of the pyruvate dehydrogenase complex from Azotobacter vinelandii has been cloned in Escherichia coli. A plasmid containing a 2.8-kbp insert of A. vinelandii chromosomal DNA was obtained and its nucleotide sequence determined. The gene comprises 1911 base pairs, 637 codons excluding the initiation codon GUG and stop codon UGA. It is preceded by the gene encoding the pyruvate dehydrogenase component (E1) of pyruvate dehydrogenase complex and by an intercistronic region of 11 base pairs containing a good ribosome binding site. The gene is followed downstream by a strong terminating sequence. The relative molecular mass (64913), amino acid composition and N-terminal sequence are in good agreement with information obtained from studies on the purified enzyme. Approximately the first half of the gene codes for the lipoyl domain. Three very homologous sequences are present, which are translated in three almost identical units, alternated with non-homologous regions which are very rich in alanyl and prolyl residues. The N-terminus of the catalytic domain is sited at residue 381. Between the lipoyl domain and the catalytic domain, a region of about 50 residues is found containing many charged amino acid residues. This region is characterized as a hinge region and is involved in the binding of the pyruvate dehydrogenase and lipoamide dehydrogenase components. The homology with the dihydrolipoyltransacetylase from E. coli is high: 50% amino acid residues are identical.     

Complete nucleotide and deduced amino acid sequences of rat L-type pyruvate kinase

Four overlapping cDNA clones for L-type pyruvate kinase (PK-L) were isolated from carbohydrate-induced rat liver cDNA libraries. They contained all the coding sequence of the enzyme from the 7th codon and the entire 3'-untranslated extension up to the poly(A) tail. The sequence of the first 7 codons and that of the 5'-untranslated region were determined by primer extension. The analyzed PK-L mRNA has 19 5'-untranslated bases, 1629 coding bases and 1281 3'-untranslated bases without the poly(A) tail; it corresponds to the heavier, 3.2 kb species of the L-type mRNAs. The codons for the phosphorylatable site are located at the 5'-end of the messenger. The unusually long 3'-untranslated extension contains a repetitive element complementary to the 'brain-specific' identifier sequence described by Sutcliffe et al. [(1982) Proc. Natl. Acad. Sci. USA 79, 4942-4946].     

The pyruvate dehydrogenase complex of Escherichia coli K12. Nucleotide sequence encoding the pyruvate dehydrogenase component

The nucleotide sequence of a 3780-base-pair segment of DNA containing the aceE gene encoding the pyruvate dehydrogenase component (E1) of the pyruvate dehydrogenase complex of Escherichia coli, has been determined by the dideoxy chain-termination method. The aceE structural gene comprises 2655 base pairs (885 codons, excluding the initiation codon AUG), it is preceded by a good ribosome binding site and several potential RNA polymerase binding sites. Its polarity and location in the restriction map of the corresponding segment of DNA are consistent with it being the proximal gene in the ace operon, as defined in previous genetic and post-infection labelling studies. The relative molecular mass (99474), composition (885 amino acids), amino-terminal residue and carboxy-terminal sequence predicted from the nucleotide sequence are in excellent agreement with published information obtained from studies with the purified pyruvate dehydrogenase component (E1). The nucleotide sequence also contains a second gene (gene A) situated upstream of the aceE gene. It appears to be an independent gene containing 708 base pairs (236 codons) and encoding a weakly expressed product (protein A; Mr = 27049) of unknown function.     

A novel GDP-dependent pyruvate kinase isozyme from Toxoplasma gondii localizes to both the apicoplast and the mitochondrion

We previously reported a cytosolic pyruvate kinase (EC 2.7.1.40) from Toxoplasma gondii (TgPyKI) that differs from most eukaryotic pyruvate kinases in being regulated by glucose 6-phosphate rather than fructose 1,6-diphosphate. Another putative pyruvate kinase (TgPyKII) was identified from parasite genome, which exhibits 32% amino acid sequence identity to TgPyKI and retains pyruvate kinase signature motifs and amino acids essential for substrate binding and catalysis. Whereas TgPyKI is most closely related to plant/algal enzymes, phylogenetic analysis suggests a proteobacterial origin for TgPyKII. Enzymatic characterization of recombinant TgPyKII shows a high pH optimum at 8.5, and a preference for GDP as a phosphate recipient. Catalytic activity is independent of K+, and no allosteric or regulatory effects were observed in the presence of fructose 1,6-diphosphate, fructose 2,6-diphosphate, glucose 6-phosphate, ribose 5-phosphate, AMP, or ATP. Unlike TgPyKI, native TgPyKII activity was exclusively associated with the membranous fraction of a T. gondii tachyzoite lysate. TgPyKII possesses a long N-terminal extension containing five putative start codons before the conserved region and localizes to both apicoplast and mitochondrion by immunofluorescence assay using native antibody and fluorescent protein fusion to the N-terminal extension. Further deletional and site-directed mutagenesis suggests that a translation product from 1st Met is responsible for the localization to the apicoplast, whereas one from 3rd Met is for the mitochondrion. This is the first study of a potential mitochondrial pyruvate kinase in any system.     

Promoter and nucleotide sequences of the Zymomonas mobilis pyruvate decarboxylase.

DNA sequence analysis showed that pyruvate decarboxylase (one of the most abundant proteins in Zymomonas mobilis) contains 559 amino acids. The promoter for the gene encoding pyruvate decarboxylase was not recognized by Escherichia coli, although the cloned gene was expressed at relatively high levels under the control of alternative promoters. The promoter region did not contain sequences which could be identified as being homologous to the generalized promoter structure for E. coli. Hydropathy plots for the amino acid sequence indicated that pyruvate decarboxylase contains a large number of hydrophobic domains which may contribute to the thermal stability of this enzyme.     

Initiation of translation can occur only in a restricted region of the CYC1 mRNA of Saccharomyces cerevisiae.

The steady-state levels and half-lives of CYC1 mRNAs were estimated in a series of mutant strains of Saccharomyces cerevisiae containing (i) TAA nonsense codons, (ii) ATG initiator codons, or (iii) the sequence ATA ATG ACT TAA (denoted ATG-TAA) at various positions along the CYC1 gene, which encodes iso-1-cytochrome c. These mutational alterations were made in backgrounds lacking all internal in-frame and out-of-frame ATG triplets or containing only one ATG initiator codon at the normal position. The results revealed a "sensitive" region encompassing approximately the first half of the CYC1 mRNA, in which nonsense codons caused Upf1-dependent degradation. This result and the stability of CYC1 mRNAs lacking all ATG triplets, as well as other results, suggested that degradation occurs unless elements associated with this sensitive region are covered with 80S ribosomes, 40S ribosomal subunits, or ribonucleoprotein particle proteins. While elongation by 80S ribosomes could be prematurely terminated by TAA codons, the scanning of 40S ribosomal units could not be terminated solely by TAA codons but could be disrupted by the ATG-TAA sequence, which caused the formation and subsequent prompt release of 80S ribosomes. The ATG-TAA sequence caused degradation of the CYC1 mRNA only when it was in the region spanning nucleotide positions -27 to +37 but not in the remaining 3' distal region, suggesting that translation could initiate only in this restricted initiation region. CYC1 mRNA distribution on polyribosomes confirmed that only ATG codons within the initiation region were translated at high efficiency. This initiation region was not entirely dependent on the distance from the 5' cap site and was not obviously dependent on the short-range secondary structure but may simply reflect an open structural requirement for initiation of translation of the CYC1 mRNA.     

Definition of the carbohydrate response element of the rat S14 gene. Evidence for a common factor required for carbohydrate regulation of hepatic genes.

The 5'-flanking region of the S14 gene from -4316 to +18 contains regulatory sequences responsible for activation of promoter activity in response to elevated carbohydrate metabolism in primary hepatocytes. To map these sequences, a series of constructs containing various internal deletions of the S14 5'-flanking sequence were assayed in primary hepatocytes. The region from -1601 to -1395 was found to be essential for this response. Comparison of the sequence of this S14 region to a region of the L-type pyruvate kinase gene that has been shown to mediate carbohydrate regulation (Thompson, K. S., and Towle, H. C. (1991) J. Biol. Chem. 266, 8679-8682) revealed a segment with 9 out of 10 identity. In both cases, this conserved sequence aligned with a DNase I footprint formed with hepatic nuclear extract. Oligonucleotides (approximately 30 base pairs) from either S14 or pyruvate kinase genes containing the conserved element bound to a hepatic nuclear factor(s) that gave identical complexes by mobility shift assay. Furthermore, these two oligonucleotides cross-competed for binding to the nuclear factor(s), suggesting that a common factor(s) binds to this conserved element. Reinsertion of the S14 oligonucleotide into an unresponsive S14 promoter construct restored the carbohydrate control. Moreover, this oligonucleotide could confer a glucose response when fused to a heterologous promoter. Thus, the S14 segment from -1457 to -1428 is a carbohydrate response element essential for the binding of nuclear factor(s) regulated by increased carbohydrate metabolism. This factor(s) may be common to the carbohydrate regulation of the S14 and pyruvate kinase genes.     

The M1- and M2-type isozymes of rat pyruvate kinase are produced from the same gene by alternative RNA splicing

The complete nucleotide sequences of rat M1- and M2-type pyruvate kinase mRNAs were determined by sequencing the cDNAs and by analyses of S1 nuclease mapping and primer extension. The sequences have an identical molecular size of about 2220 nucleotides excluding a poly(A) tail and include 1593-nucleotide coding region. Their nucleotide sequences are identical except for 160-nucleotide sequences within the coding regions. The amino acid sequences of the M1- and M2-type subunits deduced from the cDNA sequences differ by only 45 residues within domain C, which constitutes the main region responsible for intersubunit contact. The sequence of this region of the M2-type shows higher homology than that of the M1-type with the corresponding sequence of the L-type. Since the M2- and L-types are allosteric enzymes, unlike to the M1-type, the residues common to the M2- and L-types, but not the M1-type may be important for mediating the allosteric properties. Genomic clones encoding both M1- and M2-type isozyme mRNAs were isolated. By partial sequence analysis of a clone lambda MPK37 four exons were identified, of which two adjacent exons coded the M1- and M2-specific sequences, respectively. The two remaining exons present downstream coded amino acids common to the two isozymes. Thus, we conclude that the M1- and M2-type isozymes of pyruvate kinase are produced from the same gene probably by alternative RNA splicing.     

Complete amino acid sequence of rat L-type pyruvate kinase deduced from the cDNA sequence

cDNA clones, containing the entire coding region of rat L-type pyruvate kinase, were isolated and their nucleotide sequences were determined by the dideoxy-chain-termination method. The predicted coding region, which spans 543 amino acids, established the complete amino acid sequence of the L-type isozyme of pyruvate kinase for the first time. The deduced amino acid sequence of the L type has one phosphorylation site in its amino terminus and shows about 68% and 48% homologies with M1-type pyruvate kinase of chicken and yeast pyruvate kinase respectively. Domain A exhibits higher homology than domains B and C. The residues in the active site of the L-type enzyme of rats, lying between domains B and A2, are rather different from those of the M1-type enzyme of chickens, but other residues constituting the active site are identical with those of the chicken M1 type except for one amino acid substitution.     

Complete nucleotide sequence of the chicken alpha A-crystallin gene and its 5' flanking region

The chicken alpha A-crystallin gene and 2.6 kb of its 5' flanking sequence have been isolated and characterized by electron microscopy and sequencing. The structural gene is 4.5 kb long and contains two introns, each approx. 1 kb in length. The first intron divides codons 63 and 64, and the second intron divides codons 104 and 105, as in rodents. There is little indication that the insert exon of rodents (an alternatively spliced sequence) is present in complete form in the chicken alpha A-crystallin gene; small stretches of similarity to this sequence were found throughout the gene. The 5' flanking sequence of the chicken alpha A-crystallin gene shows considerable sequence similarity with other mammalian alpha B-crystallin genes. In addition, one consensus sequence (GCAGCATGCCCTCCTAG) present in the 5' flanking region of the chicken alpha A-crystallin gene was found in the 5' flanking region of most reported crystallin genes.     

Protein folding within the cell is influenced by controlled rates of polypeptide elongation.

Previous studies have proposed that specific translational pauses have evolved to promote protein folding inside the cell by temporally separating the folding of specific regions of some polypeptide chains during their synthesis. Here we show that this is the case for a bifunctional protein in Saccharomyces cerevisiae. The yeast TRP3 gene contains a translational pause comprising ten contiguous non-preferred codons within its second functional domain (indoleglycerol phosphate synthase). Site-directed mutagenesis was used to remove this translational pause by increasing the codon bias of the region without changing the amino acid sequence of the protein (to create the gene TRP3pr: pause replaced). The TRP3pr gene was able to complement a trp3:: URA3 null mutation in yeast. No significant differences in the doubling times of TRP3 or TRP3pr yeast transformants were observed during growth at 25 degrees C, 30 degrees C or 37 degrees C, or in the presence of sublethal concentrations of the analogue, 5-methyltryptophan. However, further analysis of TRP3 and TRP3pr transformants revealed that the removal of the translational pause causes a 1.5-fold decrease in indoleglycerol phosphate synthase activity per TRP3 mRNA. This observation which is statistically significant (P < 0.05) and reproducible, suggests that translational pausing promotes the correct intracellular folding of the TRP3 protein.     

The nucleotide sequence and transcript map of the herpes simplex virus thymidine kinase gene

This paper presents the nucleotide sequence of the Herpes Simplex Virus thymidine kinase (tk) gene. The position on the DNA sequence corresponding to the 5' and 3' termini of tk messenger RNA have been mapped. The mRNA termini are separated by slightly more than 1,300 nucleotides. The same 2,300 nucleotide segment of tk coding strand DNA is fully protected from S1 nuclease digestion when hybridized to tk mRNA. The location and size of the mRNA-coding segment corresponds to a region of the viral DNA that is essential for tk gene expression in microinjected frog oocytes. The nucleotide sequence of the HSV tk gene exhibits an open translational reading frame of 376 codons that extends from the methionine codon most proximal to the 5' terminus of tk mRNA to a UGA stop codon approximately 70 nucleotides from the poly-A addition site. The results of these experiments indicate that the tk gene is not interrupted by intervening DNA sequences, and that certain oligonucleotide sequences adjacent to the termini of the tk gene are homologous to similarly positioned sequences common to structural genes of eukaryotic cells.