Cloning of murine SeGpx cDNA and synthesis of mutated GPx proteins in Escherichia coli.

Glutathione peroxidase (GPx) of mammalian cells and Escherichia coli formate dehydrogenase both contain a selenocysteine (SeCys) in their amino acid (aa) sequence. In these two enzymes, this aa is encoded by a UGA codon, which is usually a stop codon for protein synthesis. We constructed plasmids to test the synthesis of GPx in E. coli. These constructions permitted high-level production of GPx mutants, where the SeCys codon was replaced by cysteine (UGC, UGU) or serine (UCA) codons, but synthesis of selenoprotein could not be detected: our data suggest that signals used for the recognition of the UGA codon as a SeCys codon are not conserved between E. coli and mammalian cells.     

Fat transfer and energetics during lactation in the hooded seal: the roles of tissue lipoprotein lipase in milk fat secretion and pup blubber deposition

Hooded seals (Cystophora cristata) lactate for 3.6 days during which females simultaneously fast and transfer large amounts of energy to their pups through fat-rich milk. Pups grow rapidly, principally due to blubber deposition. Lipoprotein lipase (LPL), the primary enzyme responsible for tissue uptake of triglyceride fatty acids, may strongly influence both maternal milk fat secretion and pup blubber deposition. We measured the energetic costs of lactation (using hydrogen isotope dilution, ³H₂0), milk composition, prolactin, and LPL activity (post-heparin plasma LPL [PH LPL], blubber, mammary gland and milk; U) in six females. PH LPL and blubber LPL were measured in their pups. Females depleted 216.3 MJ · day⁻¹ of body energy and fat accounted for 59% of maternal mass loss and 90% of postpartum body energy loss, but maternal body composition changed little. Maternal blubber LPL was negligible (0.0–0.2 U), while mammary LPL was elevated (1.8–2.5 U) and was paralleled by changes in prolactin. Estimated total mammary LPL activity was high (up to 20,000 U · animal⁻¹) effectively favoring the mammary gland for lipid uptake. Levels of total blubber LPL in pups increased seven-fold over lactation. Pups with higher PH LPL at birth had greater relative growth rates (P = 0.025). Pups with greater blubber stores and total blubber LPL activity had elevated rates of fat deposition (P = 0.035). Accepted: 4 May 1999     

Cloning and Sequencing of Cytochrome P450 1A Complementary DNA in Eel (Anguilla japonica)

Cytochrome P450 1A (CYP1A) complementary DNA was isolated from eel (Anguilla japonica) liver treated with 3-methylcholanthrene. The cDNA contained a 5′ untranslated region of 163 bp, an open reading flame of 1560 bp coding for 519 amino acids and a stop codon, and a 3′ untranslated region of 1730 bp. The predicted molecular weight was approximately 58.4 kDa. The deduced amino acid sequence exhibited identities with reported CYP1A sequences of 80% for rainbow trout, 79% for scup, 76% for plaice and butterfly fish, and 74% for toadfish. When compared with mammalian CYP proteins, the eel CYP1A was more similar to CYP1A1 (54%–56%) than to CYP1A2 (49%–52%). Northern and Southern blot analyses showed two distinct bands, suggesting the existence of another 3-methylcholanthrene-inducible CYP1A gene in eel. Received December 19, 1998; accepted February 18, 1999     

Unusual mammalian usage of TGA stop codons reveals that sequence conservation need not imply purifying selection

The assumption that conservation of sequence implies the action of purifying selection is central to diverse methodologies to infer functional importance. GC-biased gene conversion (gBGC), a meiotic mismatch repair bias strongly favouring GC over AT, can in principle mimic the action of selection, this being thought to be especially important in mammals. As mutation is GC→AT biased, to demonstrate that gBGC does indeed cause false signals requires evidence that an AT-rich residue is selectively optimal compared to its more GC-rich allele, while showing also that the GC-rich alternative is conserved. We propose that mammalian stop codon evolution provides a robust test case. Although in most taxa TAA is the optimal stop codon, TGA is both abundant and conserved in mammalian genomes. We show that this mammalian exceptionalism is well explained by gBGC mimicking purifying selection and that TAA is the selectively optimal codon. Supportive of gBGC, we observe (i) TGA usage trends are consistent at the focal stop codon and elsewhere (in UTR sequences); (ii) that higher TGA usage and higher TAA→TGA substitution rates are predicted by a high recombination rate; and (iii) across species the difference in TAA <-> TGA substitution rates between GC-rich and GC-poor genes is largest in genomes that possess higher between-gene GC variation. TAA optimality is supported both by enrichment in highly expressed genes and trends associated with effective population size. High TGA usage and high TAA→TGA rates in mammals are thus consistent with gBGC’s predicted ability to “drive” deleterious mutations and supports the hypothesis that sequence conservation need not be indicative of purifying selection. A general trend for GC-rich trinucleotides to reside at frequencies far above their mutational equilibrium in high recombining domains supports the generality of these results.

Is sequence conservation a sign of purifying selection and hence functional importance? This analysis of why mammals use and conserve the most error-prone stop codon suggests not, consistent with GC-biased gene conversion’s predicted ability to “drive” deleterious mutations and supporting the hypothesis that sequence conservation need not be indicative of purifying selection.     

Identification of a novel Japanese flounder (<Emphasis Type="Italic">Paralichthys olivaceus</Emphasis>) CC chemokine gene and an analysis of its function

A cDNA of Japanese flounder (Paralichthys olivaceus) CC chemokine designated as Paol-SCYA104 was cloned and sequenced. The cDNA contains an opening reading frame of 315 nucleotides encoding 104 amino acid residues. The full gene was cloned and sequenced from a BAC library. It has a length of approximately 750 bp from the start codon to the stop codon and is composed of four exons and three introns. Four cysteine residues are conserved in the same positions as those of mammalian and fish CC chemokines. Paol-SCYA104 gene was expressed in several organs, including peripheral blood leukocytes (PBLs), head kidney, trunk kidney, and spleen. The recombinant Paol-SCYA104 was expressed in Escherichia coli and the expressed protein was partially purified. The recombinant Paol-SCYA104 was able to attract Japanese flounder PBLs in a microchemotaxis chamber. On the other hand, a negative control, the fraction of the control cells carrying an expression vector lacking the Paol-SCYA104 cDNA, did not show chemotactic activity. These results indicate that Paol-SCYA104 probably acts as a CC chemokine.     

Organization of the lipoprotein lipase gene of red sea bream Pagrus major

Lipoprotein lipase (LPL) is a key enzyme of lipid deposition and metabolism. To investigate the mechanism of lipid deposition in fish, as a first step, we have characterized the LPL gene of a marine teleost red sea bream Pagrus major by cDNA and genomic structure analysis. The red sea bream LPL gene encodes 511 amino acids and spans approximately 6.3 kb of the genome. The coding region is organized into ten exons and nine introns. In comparison with the LPL of other animals, the deduced amino acid sequence shows a high degree of similarity with a conservation of functional domains, e.g. catalytic triad, N-glycosylation sites, lipid and heparin binding regions. The 1.1 kb of 5′ flanking region contains two CCAAT, sequences homologous to Oct-I site and response elements for hormones including glucocorticoid, insulin and thyroid hormone. The results of the present study will facilitate further study of the function and regulation of the LPL in non-mammalian vertebrates.     

中华鲟及六种淡水养殖鱼类脂蛋白脂酶和肝脂酶基因克隆及系统进化分析

为了研究鱼类脂蛋白脂酶(1iportein lipase,LPL)、肝脂酶(hepatic lipase,HL)基因结构、功能及分子系统关系,作者克隆了中华鲟(Acipenser sinensis)、鲢(Hypophthalmichthys molitrix)、鳙(Aristichthys nobilis)、草鱼(Ctenopharyngodon idellus)、鲮鱼(Cirrhinus molitorella)、尼罗罗非鱼(Oreochromis niloticus)和斑鳢(Channa maculata)的LPL和HL基因cDNA核心序列,并推测了其相应氨基酸序列.同时,还应用5'RACE和3'RACE技术分别扩增中华鲟、鲢肝脏LPL基因与中华鲟肝脏HL基因cDNA全序列.序列同源性分析表明,LPL和HL氨基酸序列分别在哺乳类动物、鸟类、鱼类中相对保守.与已知的脊椎动物内皮脂酶(endothelial lipase,EL)和胰脂酶(pancreatic 1ipase,PL)氨基酸序列构建系统进化树,发现LPL、HL、EL与PL同属脂肪酶家族,四者聚集成一有根树.     

Molecular characterization of hemoglobin alpha-D chains from Geochelone carbonaria and Geochelone denticulata land turtles

In order to help elucidate the evolution of alpha-globins, the complete cDNA and amino acid sequences of Geochelone carbonaria and Geochelone denticulata land turtles alpha-D chains have been described. In G. carbonaria, the cDNA is 539 bp with ATG start codon located at position 46, TGA stop codon at position 469 and AATAAA polyadenylation signal at position 520. In G. denticulata, the cDNA is 536 bp with ATG start codon located at position 46, TGA stop codon at position 469 and AATAAA polyadenylation signal at position 517. Both cDNAs codify 141 amino acid residues, differing from each other in only four amino acid residues. When comparing with human Hb alpha-chain, alterations in important regions can be noted: alpha110 Ala-Gly, alpha114 Pro-Gly, alpha117 Phe-Tyr and alpha122 His-Gln. There is a high homology between the amino acids of these turtles when compared with chicken alpha-D chains, progressively decreasing when compared with human, crocodile, snake, frog and fish alpha-chains. Phylogenetic analysis of alpha-D chains shows that those of turtles are closer to those of birds than to snakes and lizards.     

Cloning, Sequencing, and Phylogenetic Analysis of Complementary DNA of Novel Cytochrome P-450 CYP1A in Japanese Eel (Anguilla japonica)

Complementary DNA of cytochrome P-450 CYP1A, in addition to CYP1A1, has been isolated from Japanese eel (Anguilla japonica) liver treated with 3-methylcholanthrene. The cDNA contained a 5′ untranslated region of 66 bp, an open reading frame of 1554 bp coding for 517 amino acids and a stop codon, and a 3′ untranslated region of 1166 bp. The predicted molecular weight of the Japanese eel CYP1A was approximately 58.5 kDa. The nucleotide sequence exhibited identities with the reported CYP1A1 sequences of 77% for Japanese eel, 75% for rainbow trout, 72% for scup, plaice, and butterfly fish, and 71% for toadfish. The deduced amino acid sequence exhibited identities with the reported CYP1A1 sequences of 78% for Japanese eel, 77% for rainbow trout, 75% for scup, 74% for toadfish, 73% for plaice, and 72% for butterfly fish. The novel eel CYP1A obtained had less similarity to the other teleost CYP1A1 proteins (72%–78%) than that of the eel CYP1A1 (74%–80%). When compared with mammalian CYP proteins, the novel eel CYP1A was more similar to the CYP1A1 proteins (54%–56%) than to the CYP1A2 proteins (50%–53%). The phylogenetic tree of the teleost CYP1A genes constructed using the maximum likelihood method suggested that the novel eel CYP1A is ubiquitous among the Anguilliformes. Received August 25, 2000; accepted November 30, 2000     

Human urate oxidase gene: cloning and partial sequence analysis reveal a stop codon within the fifth exon

Using the cDNA and selected genomic probes of rat urate oxidase, we have screened the human genomic library and isolated seven clones; one clone (clone 13) contained exonic regions which correspond to the exons 5, 6, and 7 of rat urate oxidase gene. The nucleotide sequence was determined for these three exons and exon/intron junctions, and compared with the sequence from the rat gene. A mutation resulting in a stop codon TGA was found in the fifth exon of the human urate oxidase gene. Sequence analysis of the polymerase chain reaction amplified DNA, corresponding to the fifth exon of urate oxidase from DNA samples from four different individuals, confirmed the same TGA stop codon in all. This single stop codon mutation and/or other mutation(s) in this gene may be responsible for the lack of urate oxidase activity in the human.     

Evolutionary Lability of Context-Dependent Codon Bias in Bacteria

In bacteria, synonymous codon usage can be considerably affected by base composition at neighboring sites. Such context-dependent biases may be caused by either selection against specific nucleotide motifs or context-dependent mutation biases. Here we consider the evolutionary conservation of context-dependent codon bias across 11 completely sequenced bacterial genomes. In particular, we focus on two contextual biases previously identified in Escherichia coli; the avoidance of out-of-frame stop codons and AGG motifs. By identifying homologues of E. coli genes, we also investigate the effect of gene expression level in Haemophilus influenzae and Mycoplasma genitalium. We find that while context-dependent codon biases are widespread in bacteria, few are conserved across all species considered. Avoidance of out-of-frame stop codons does not apply to all stop codons or amino acids in E. coli, does not hold for different species, does not increase with gene expression level, and is not relaxed in Mycoplasma spp., in which the canonical stop codon, TGA, is recognized as tryptophan. Avoidance of AGG motifs shows some evolutionary conservation and increases with gene expression level in E. coli, suggestive of the action of selection, but the cause of the bias differs between species. These results demonstrate that strong context-dependent forces, both selective and mutational, operate on synonymous codon usage but that these differ considerably between genomes. Received: 6 May 1999 / Accepted: 29 October 1999     

Recurrent nonsense mutation in exon 7 of the phenylalanine hydroxylase gene

Summary A new mutation (CGA to TGA) in codon 261 of exon 7 of the phenylalanine hydroxylase gene transforms Arg²⁶¹ to a stop codon in two unrelated patients of German and Turkish origin. The different ethnic backgrounds and the different polymorphic characteristics of the two mutant alleles suggest an independent origin of the mutation. This is the second defect detected in codon 261 of the phenylalanine hydroxylase gene, a codon that thus appears to be a mutation hot spot.     

Lipoprotein Lipase Gene is Linked and Associated with Hypertension in Taiwan Young-onset Hypertension Genetic Study

Summary Hypertriglyceridemia has been extensively associated with hypertension. However, the mechanism behind it is poorly understood. A positive linkage signal between Lipoprotein lipase (LPL) and young-onset hypertension has been identified by us as the strongest among 18 candidate genes. Here we report our fine mapping works with seven microsatellite markers flanking LPL, sequencing results for its promoter and exons, and an extended association study with the identified single nucleotide polymorphisms(SNP). First, using data from 213 individuals in 59 nuclear families of young-onset hypertension, multipoint analysis revealed a NPL score of 3.02 for the LPL (GZ-14/GZ-15) marker in intron 6. LPL marker (p<10⁻¹²) and the haplotypes containing its allele 1 (p<0.0001) were also significantly associated with young hypertension by transmission disequilibrium test. In-depth sequencing revealed no mutation in promoter and exon regions, except two cSNP: 7754C→ A (C/A: 0.91/0.09), a silent mutation in exon 8 and S447X (C/G: 0.92/0.08), a stop codon mutation in exon 9. Other 11 cSNPs documented in NCBI GenBank are absent in our sample. Constructed from the above 2 cSNPs, haplotype AC showed a moderate TDT association with elevated triglyceride (p=0.02) and with hypertension and elevated triglyceride combined (p=0.06). Again, in an extended case-control study, a significant association was found between S447X and patients with persistent hypertension and elevated triglyceride (p=0.02). We conclude that LPL variants may play a causal role in the development of hypertension in Taiwan Han Chinese. The moderate association with SNP haplotype suggests that other regulatory LPL variant may exist.     

Mutation of the Secys residue 266 in human type 2 selenodeiodinase alters 75Se incorporation without affecting its biochemical properties.

Type 2 deiodinase (D2) is a low Km iodothyronine deiodinase that metabolizes thyroxine (T4) to the active metabolite T3. We have recently shown that the cDNA for the human D2 coding region contains two in-frame selenocysteine (TGA) codons. The 3' TGA is seven codons 5' to a universal stop codon, TAA. The human D2 enzyme, transiently expressed in HEK-293 cells, can be in vivo labeled with 75Se as a doublet of approximately 31 kDa. This doublet is consistent with the possibility that the carboxy-terminal TGA codon can either encode selenocysteine or function as a stop codon. To test this hypothesis we mutagenized the second selenocysteine codon to a cysteine (TGC) or to an unambiguous stop codon (TAA). While the selenium incorporation pattern is different between the wild-type and mutant proteins, the deiodination properties of the enzyme are not affected by mutating the 3'TGA codon. Thus, we conclude that neither this residue nor the remaining seven carboxy-terminal amino acids are critical for the deiodination process.     

Membrane and secretory forms of mouse membrane cofactor protein (CD46) generated from a single gene through alternative splicing

 A cDNA encoding a new secretory form of mouse membrane cofactor protein (MCP, CD46) was identified additionally to the membrane form cDNA. The secretory MCP, predicted from the cDNA sequence, consisted of the conserved four short consensus repeats (SCRs) plus a four amino acid-stretch. Unlike human MCP which comprises many isoforms, mouse MCP cDNA predicted a single isoform of membrane MCP with cytoplasmic tail 1 (CYT1) and serine/threonine-rich domain C (ST^C). To clarify the genomic origin and monomorphic alteration of these cDNAs, we cloned and analyzed a mouse genomic DNA harboring the full coding sequence of MCP from a 129/SV mouse genomic library. The mouse Mcp was a single gene ∼50 kilobases long. Eleven of the 14 coding exons of the human MCP gene and intron-exon boundary sequences were found to be conserved in the mouse gene. The ST^C homologue but not the ST^A or ST^B homologue in the mouse exons was functional: the latter being due to deletions and lack of consensus sequences for splicing. The sequence equivalent to cytoplasmic tail 2 (CYT2) has not been identified in the Mcp genome. Thus, the three exons (ST^A, ST^B, and probably CYT2) responsible for the polymorphism of human MCP by differential splicing were missing in the mouse Mcp gene. Unlike the case in humans, no Mcp-related genes or pseudogenes were observed in the mouse genome. The single mouse Mcp gene was mapped to the R-positive H5 band of mouse Chromosome 1 by FISH. Strikingly, one alternative exon with 73 base pairs (encoding the four new amino acids and a TGA stop codon) was discovered between the SCRIV and the ST^C exons; alternative splicing causes the generation of the secretory form of mouse MCP. These results on mouse MCP, together with the information concerning other mouse SCR proteins, infer that the regulator of complement activation (RCA) gene cluster is genetically diverged between humans and mice. Received: 22 April 1999 / Revised: 21 June 1999     

Tandem Stop Codons in Ciliates That Reassign Stop Codons

Tandem stop codons are extra stop codons hypothesized to be present downstream of genes to act as a backup in case of read-through of the real stop codon. Although seemingly absent from Escherichia coli, recent studies have confirmed the presence of such codons in yeast. In this paper we will analyze the genomes of two ciliate species—Paramecium tetraurelia and Tetrahymena thermophila—that reassign the stop codons TAA and TAG to glutamine, for the presence of tandem stop codons. We show that there are more tandem stop codons downstream of both Paramecium and Tetrahymena genes than expected by chance given the base composition of the downstream regions. This excess of tandem stop codons is larger in Tetrahymena and Paramecium than in yeast. We propose that this might be caused by a higher frequency of stop codon read-through in these species than in yeast, possibly because of a leaky termination machinery resulting from stop codon reassignment.     

Identification of wild-type <Emphasis Type="Italic">Mycobacterium tuberculosis</Emphasis> isolates and point mutations associated with isoniazid resistance

Isoniazid resistance in Mycobacterium tuberculosis (MBT) is associated with point mutations in codon 315 of the katG gene. Two PCR technique were developed for detection of point mutations in codon 315. Most frequent point mutations (AGC → ACC and AGC → AGA) were identified in codon 315 by using two sets of primers, either of which included an additional competitive blocking primer with a 3′-terminal phosphate group in order to prevent nonspecific amplification. PCR with a set of two primers, one of which contained five locked nucleic acid monomers (LNA), permits one to detect any of six known mutations in codon 315 of katG and, thereby, discriminate between isoniazid-sensitive and resistant MBT isolates. The structure and purity of the 17-nt long LNA-containing oligonucleotides were characterized by MALDI-TOF mass spectrometry; and the 17 bp duplex formed by two LNA-containing complementary oligonucleotides was analyzed by thermal denaturation.