Tissue-Specific Expression and Mapping of theCox7ahGene in Mouse

We have isolated and examined the gene for the heart isoform of cytochromecoxidase subunit VIIa (COX VIIa-H) in mouse, an isoform gene previously thought to be lacking in rodents. Interspecies amino acid comparisons indicate that mouse COX VIIa-H protein displays 82.5 and 70.9% identity with the bovine and human heart isoforms of COX VIIa, but only 53.7% identity with the paralogous mouse liver isoform (COX VIIa-L). Expression in adult mouse tissues is limited to heart and skeletal muscle, as found in other species. In the early mouse embryo,Cox7alwas the exclusive isoform expressed andCox7ahmRNA was not detectable until day 17postcoitum.That the mouseCox7ahgene characterized in this study is orthologous to the humanCOX7AHgene was also suggested by its mapping to mouse chromosome 7, to a conserved region syntenic with the human chromosome location ofCOX7AH,19q13.1. As a result, all three COX heart isoform genes in mouse group to chromosome 7. Interestingly, mapping of the mouseCox7alto chromosome 9 suggests a new syntenic region between the mouse and the human genomes.     

Molecular cloning and nucleotide sequence of cDNA encoding human muscle glycogen debranching enzyme.

cDNA comprising the entire length of the human muscle glycogen debranching enzyme was cloned and its nucleotide sequence determined. The debrancher mRNA includes a 4545-base pair coding region and a 2371-base pair 3'-nontranslated region. The calculated molecular mass of the debrancher protein derived from cDNA sequence is 172,614 daltons, consistent with the estimated size of purified protein (Mr 165,000 +/- 500). A partial amino acid sequence (13 internal tryptic peptides with a total of 213 residues) determined on peptides derived from purified porcine muscle debrancher protein confirmed the identity of the cDNA clone. Comparison of the amino acid sequence predicted from the human glycogen debrancher cDNA with the partial protein sequence of the porcine debrancher revealed a high degree (88%) of interspecies sequence identity. RNA blot analysis showed that debrancher mRNA in human muscle, lymphoblastoid cells, and in porcine muscle are all similar in size (approximately 7 kilobases). Two patients with inherited debrancher deficiency had a reduced level of debrancher mRNA, whereas two other patients had no detectable abnormality in RNA blots. The isolation of the debrancher cDNA and determination of its primary structure is an important step toward defining the structure-function relationship of this multifunctional enzyme and in understanding the molecular basis of the type III glycogen storage disease.     

Cloning and tissue distribution of a novel human cytochrome p450 of the CYP3A subfamily, CYP3A43

On the basis of the detection of an expressed sequence tag ('EST') similar to the human cytochrome P450 3A4 cDNA, we have identified a novel member of the human cytochrome P450 3A subfamily. The coding region is 1512-bp long and shares 84, 83, and 82% sequence identity on the cDNA level with CYP3A4, 3A5, and 3A7, respectively, with a corresponding amino acid identity of 76, 76, and 71%. Quantitative real time based mRNA analysis revealed CYP3A43 expression levels at about 0.1% of CYP3A4 and 2% of CYP3A5 in the liver, with significant expression in 70% of the livers examined. Gene specific PCR of cDNA from extrahepatic tissues showed, with the exception of the testis, only low levels of CYP3A43 expression. The CYP3A43 cDNA was heterologously expressed in yeast, COS-1 cells, mouse hepatic H2.35 cells and in human embryonic kidney (HEK) 293 cells, but in contrast to CYP3A4 which was formed in all cell types, no detectable CYP3A43 protein was produced. This indicates a nonfunctional protein or specific conditions required for proper folding. It is concluded that CYP3A43 mRNA is expressed mainly in liver and testis and that the protein would not contribute significantly to human drug metabolism.     

cDNA Cloning and mRNA analysis of PGC-1 in epitrochlearis muscle in swimming-exercised rats

Peroxisome proliferator-activated receptor gamma coactivator-1 (PGC-1), a cold-inducible coactivator of nuclear receptors, stimulates mitochondrial biogenesis and respiration in muscle cells. In the present study, we first cloned a rat PGC-1 gene from a brown adipose tissue cDNA library which encodes a predicted 796-amino-acid protein and exhibits respectively 98% and 95% identity with the mouse and human homologues. Next, we examined the effect of swimming exercise training on the level of expression of the PGC-1 gene in rat epitrochlearis (Epi) muscle. PGC-1 mRNA level in Epi muscle in rats that swam 2 h a day for 3 and 7 days increased dramatically by 154% and 163%, respectively, compared to the non-exercised control group. PGC-1 mRNA up-regulation was not observed in an immersion group treated at 35 degrees C during the training program but without swimming exercise. These results demonstrate that expression of the PGC-1 gene in Epi muscle is induced not only by cold exposure but also by prolonged low-intensity physical exercise.     

Structural characterization and tissue-specific expression of the mRNAs encoding isoenzymes from two rat mitochondrial creatine kinase genes.

Creatine kinase (CK; EC 2.7.3.2) isoenzymes play prominent roles in energy transduction. Mitochondrial CK (MtCK) reversibly catalyzes the transfer of high energy phosphate to creatine and exists, in the human, as two isoenzymes encoded by separate genes. We report here the cDNA sequences of the two isoenzymes of MtCK in the rat. Rat sarcomeric MtCK has 87% nucleotide identity in the 1257 bp coding region and 82% in the 154 bp 3' untranslated region as compared with human sarcomeric MtCK. Rat ubiquitous MtCK has 92% nucleotide identity over the 1254 bp coding region with human ubiquitous MtCK and 81% identity of the 148 by 3' untranslated region. Nucleotide identity between the rat sarcomeric and ubiquitous MtCK coding regions is 70%, with no conservation of their 3' untranslated regions. Thus, MtCK sequence is conserved in a tissue-specific, rather than species-specific, manner. Conservation of the 3' untranslated regions is highly unusual and suggests a regulatory function for this region. The NH2-terminal transit peptide sequences share 82% amino acid homology between rat and human sarcomeric MtCKs and 92% homology between rat and human ubiquitous MtCKs, but have only 41% homology to each other. This tissue-specific conservation of the transit peptides suggests receptor specificity in mitochondrial uptake. Rat sarcomeric MtCK mRNA is expressed only in skeletal muscle and heart, but rat ubiquitous MtCK mRNA is expressed in many tissues, with highest levels in brain, gut and kidney. Ubiquitous MtCK mRNA levels are dramatically regulated in uterus and placenta during pregnancy. Coexpression of sarcomeric and ubiquitous MtCK with their cytosolic counterparts, MCK and BCK, respectively, supports the creatine phosphate shuttle hypothesis and suggests that expression of these genes is coordinately regulated.     

Separate nuclear genes encode sarcomere-specific and ubiquitous human mitochondrial creatine kinase isoenzymes

Creatine kinase (EC 2.7.3.2) isoenzymes play a central role in energy transduction. Nuclear genes encode creatine kinase subunits from muscle, brain, and mitochondria (MtCK). We have recently isolated a cDNA clone encoding MtCK from a human placental library which is expressed in many human tissues (Haas, R. C., Korenfeld, C., Zhang, Z., Perryman, B., Roman, D., and Strauss, A. W. (1989) J. Biol. Chem. 264, 2890-2897). With nontranslated and coding region probes, we demonstrated by RNA blot analysis that the MtCK mRNA in sarcomeric muscle is distinct from this placenta-derived, ubiquitous MtCK cDNA. To compare these different mRNAs, a MtCK cDNA clone was isolated from a human heart library and characterized by complete nucleotide sequence analysis. The chemically determined NH2-terminal 26 residues of purified human heart MtCK protein are identical to those predicted from this sarcomeric MtCK cDNA. The human sarcomeric and ubiquitous cDNAs share 73% nucleotide and 80% predicted amino acid sequence identities, but have less than 66% identity with the cytosolic creatine kinases. The sarcomeric MtCK cDNA encodes a 419-amino acid protein which contains a 39-residue transit peptide essential for mitochondrial import. Primer extension analysis predicts a 348-base pair 5'-nontranslated region. RNA blot analysis demonstrates that heart-derived MtCK is sarcomere-specific, but the ubiquitous MtCK mRNA is expressed in most tissues. Thus, separate nuclear genes encode two closely related, tissue-specific isoenzymes of MtCK. Our finding that multiple genes encode different mitochondrial protein isoenzymes is rare.     

Cloning and tissue distribution of Leptin mRNA in the pig∗

Abstract

The sequence of the pig ob cDNA, which codes for the protein leptin, has been determined by screening a pig adipose cDNA library with an RT‐PCR amplified cDNA fragment of this gene. The 501 bp ob cDNA has 89% identity to the human ob cDNA, 92% identity to the bovine ob cDNA, 84% identity to the mouse ob cDNA and 84% identity to the rat ob cDNA. At the amino acid level, pig leptin which codes for a protein with a predicted molecular weight of 18,661‐dalton, has 86% identity to human leptin, 93% identity to bovine leptin, 84% identity to rat leptin and 84% identity to mouse leptin. RT‐PCR screening of RNA isolated from pig adipose, skeletal muscle, cardiac muscle, pancreas, stomach, kidney, spleen and jejunum detected ob mRNA only in adipose tissue; Northern blots with an ob cDNA probe identified a 4.0 kb species in adipose tissue. The conservation of sequence and expression pattern of leptin in the pig reported here indicates that as in other species, this protein likely plays an important role in controlling food intake and fat deposition in the pig.