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.     

Structural and Biological Characterization of Two Crotamine Isoforms IV-2 and IV-3 Isolated from the <Emphasis Type="Italic">Crotalus durissus cumanensis</Emphasis> Venom

In this work, we isolated the two new crotamine isoforms from the Crotalus durissus cumanensis rattlesnake venom and its “in vitro” neurotoxic, myotoxic and lethality (DL₅₀) intracerebroventricular (i.c.v.) effects were characterized. These proteins were named IV-2 and IV-3 and were purified by combination of two chromatographic steps on molecular exclusion chromatography on Superdex 75 and reverse phase HPLC (μ-Bondapack C18). The molecular mass of the crotamine isoforms was 4905.96 Da for isoform IV-2 and 4956.97 Da for IV-3 and, as determined by mass spectrometry, and both contained six Cys residues. Enzymatic hydrolysis followed by de novo sequencing by tandem mass spectrometry was used to determine the primary structure of both isoforms. The positions of five sequenced tryptic peptides, including the N-terminal of the isoform IV-2 and four from isoform IV-3 were deduced by comparison with a homologous protein from the crotamine family. The isoforms IV-2 and IV-3 had a sequence of amino acids of 42 amino acid residues IV-2: YKRCHIKGGH CFPKEKLICI PPSSDIGKMD CPWKRKCCKK RS and pI value 9.54 and IV-3: YKQCHKKGGH CFPKEVLICI PPSSDFGKMD CRWKRKCCKK RS with a pI value of 9.54. This protein showed high molecular amino acid sequence identity with other crotamine-like proteins from Crotalus durissus terrificus. These new crotamine isoforms induced potent blockade of neuromuscular transmission in young chicken biventer cervicis preparation and potent myotoxic effect. In mice, both isoforms induced myonecrosis, upon intramuscular or subcutaneous injections. These activities were modulated by the presence of positively charged amino acid residues. The LD₅₀ of isoform IV-2 was 0.07 mg/kg and isoform IV-3 was 0.06 mg/kg the animal weight, by i.c.v. route.     

Tissue-specific expression and chromosome assignment of genes specifying two isoforms of subunit VIIa of human cytochrome c oxidase.

Subunit VIIa of mammalian cytochrome c oxidase (COX; EC 1.9.3.1) exists in at least two isoforms, one present in all tissue types ('liver' isoform; COX VIIa-L) and the other specific for cardiac and skeletal muscle (COX VIIa-M). We have isolated a full-length cDNA encoding human COX VIIa-M. The deduced polypeptide represents the human ortholog of COX VIIa-M, as it shares 78% identity with bovine COX VIIa-M, but only 63% identity with human COX VIIa-L. Northern-blot analysis of primate tissues demonstrated that COXVIIa-M mRNA is present only in muscle tissues; in contrast, the COXVIIa-L mRNA is present in both muscle and nonmuscle tissues. Southern-blot hybridization of human-rodent cell hybrid genomic DNA indicates that the COXVIIa-M gene maps to a single locus on chromosome 19, designated COX7AM. In contrast, COXVIIa-L cDNA probes hybridized to fragments from two COX7AL loci, on chromosomes 4 and 14.     

Investigating the role of the physiological isoform switch of cytochrome c oxidase subunits in reversible mitochondrial disease

Reversible infantile respiratory chain deficiency is characterised by spontaneous recovery of mitochondrial myopathy in infants. We studied whether a physiological isoform switch of nuclear cytochrome c oxidase subunits contributes to the age-dependent manifestation and spontaneous recovery in reversible mitochondrial disease. Some nuclear-encoded subunits of cytochrome c oxidase are present as tissue-specific isoforms. Isoforms of subunits COX6A and COX7A expressed in heart and skeletal muscle are different from isoforms expressed in the liver, kidney and brain. Furthermore, in skeletal muscle both the heart and liver isoforms of subunit COX7A have been demonstrated with variable levels, indicating that the tissue-specific expression of nuclear-encoded subunits could provide a basis for the fine-tuning of cytochrome c oxidase activity to the specific metabolic needs of the different tissues.We demonstrate a developmental isoform switch of COX6A and COX7A subunits in human and mouse skeletal muscle. While the liver type isoforms are more present soon after birth, the heart/muscle isoforms gradually increase around 3 months of age in infants, 4 weeks of age in mice, and these isoforms persist in muscle throughout life. Our data in follow-up biopsies of patients with reversible infantile respiratory chain deficiency indicate that the physiological isoform switch does not contribute to the clinical manifestation and to the spontaneous recovery of this disease. However, understanding developmental changes of the different cytochrome c oxidase isoforms may have implications for other mitochondrial diseases.This article is part of a Directed Issue entitled: Energy Metabolism Disorders and Therapies.     

The isoforms of yeast cytochrome c oxidase subunit V alter the in vivo kinetic properties of the holoenzyme.

One of the nuclear-coded subunits of yeast cytochrome c oxidase is specified by a gene family composed of two genes, COX5a and COX5b. These genes are regulated differentially by oxygen and encode isoforms of subunit V, designated Va and Vb, which have only 66% primary sequence identity. Yeast cells require one or the other isoform for a functional cytochrome c oxidase (Trueblood, C. E., and Poyton, R. O. (1987) Mol. Cell Biol. 7, 3520-3526). To determine if these isoforms of subunit V alter the catalytic properties of holocytochrome c oxidase, we have analyzed various aspects of cytochrome c oxidase function in intact yeast cells that produce only one type of isoform. From measurements of room temperature turnover numbers and low temperature rates of ligand binding, single turnover cytochrome c oxidation, and internal electron transfer (heme a oxidation), we have found that isozymes which incorporate the Vb isoform have both higher turnover rates and higher rates of heme a oxidation than isozymes which incorporate Va. These findings support the conclusion that the isoforms of subunit V modulate cytochrome c oxidase activity in vivo and suggest that they do so by altering the rates of one or more intramolecular electron transfer reactions.     

A single human myosin light chain kinase gene (MLCK; MYLK)

The myosin light chain kinase (MLCK) gene, a muscle member of the immunoglobulin gene superfamily, yields both smooth muscle and nonmuscle cell isoforms. Both isoforms are known to regulate contractile activity via calcium/calmodulin-dependent myosin light chain phosphorylation. We previously cloned from a human endothelial cell (EC) cDNA library a high-molecular-weight nonmuscle MLCK isoform (EC MLCK (MLCK 1) with an open reading frame that encodes a protein of 1914 amino acids. We now describe four novel nonmuscle MLCK isoforms (MLCK 2, 3a, 3b, and 4) that are the alternatively spliced variants of an mRNA precursor that is transcribed from a single human MLCK gene. The primary structure of the cDNA encoding the nonmuscle MLCK isoform 2 is identical to the previously published human nonmuscle MLCK (MLCK 1) (J. G. N. Garcia et al., 1997, Am. J. Respir. Cell Mol. Biol. 16, 489-494) except for a deletion of nucleotides 1428-1634 (D2). The full nucleotide sequence of MLCK isoforms 3a and 3b and partial sequence for MLCK isoform 4 revealed identity to MLCK 1 except for deletions at nucleotides 5081-5233 (MLCK 3a, D3), double deletions of nucleotides 1428-1634 and 5081-5233 (MLCK 3b), and nucleotide deletions 4534-4737 (MLCK 4, D4). Northern blot analysis demonstrated the extended expression pattern of the nonmuscle MLCK isoform(s) in both human adult and human fetal tissues. RT-PCR using primer pairs that were designed to detect specifically nonmuscle MLCK isoforms 2, 3, and 4 deletions (D2, D3, and D4) confirmed expression in both human adult and human fetal tissues (lung, liver, brain, and kidney) and in human endothelial cells (umbilical vein and dermal). Furthermore, relative quantitative expression studies demonstrated that the nonmuscle MLCK isoform 2 is the dominant splice variant expressed in human tissues and cells. Further analysis of the human MLCK gene revealed that the MLCK 2 isoform represents the deletion of an independent exon flanked by 5' and 3' neighboring introns of 0.6 and 7.0 kb, respectively. Together these studies demonstrate for the first time that the human MLCK gene yields multiple nonmuscle MLCK isoforms by alternative splicing of its transcribed mRNA precursor with differential distribution of these isoforms in various human tissues and cells.     

Identification and quantification of actin isoforms in vertebrate cells and tissues

The cytoskeletal protein actin exists in vertebrates as six different isoforms, which are difficult to identify conclusively because of a high degree (greater than 90%) of overall sequence homology. We have used IEF immunoblotting in combination with a panel of isoform-specific and -selective antibodies to analyze the actin isoform composition of nine tissues from adult rat. In three nonmuscle tissues (lung, spleen, and testis), we detected a previously unreported isoform that we identified as smooth muscle alpha. The IEF immunoblot technique was also used to quantify the proportions of the isoforms expressed in these nine rat tissues.     

Effect of Antioxidant Diets on Mitochondrial Gene Expression in Rat Brain During Aging

Age-related increase of reactive oxygen species (ROS) is particularly detrimental in postmitotic tissues. Calorie restriction (CR) has been shown to exert beneficial effects, consistent with reduced ROS generation by mitochondria. Many antioxidant compounds also mimic such effects. N-acetyl cysteine (NAC) provides thiol groups to glutathione and to mitochondrial respiratory chain proteins; thus, it may counteract both ROS generation and effects. In the present study we investigated, in different rat brain areas during aging (6, 12, and 28 months), the effect of 1-year treatment with CR and dietary supplementation with NAC on the expression of subunit 39 kDa and ND-1 (mitochondrial respiratory complex I), subunit IV (complex IV), subunit α of F₀F₁-ATP synthase (complex V) and of adenine nucleotide translocator, isoform 1 (ANT-1). The observed age-related changes of expression were prevented by the dietary treatments. The present study provides further evidence for the critical role of mitochondria in the aging process.