The Caenorhabditis elegans gene unc-22 encodes a very large muscle protein, called twitchin, which consists of a protein kinase domain and several copies of two short motifs. The sequence of twitchin has unexpected similarities to the sequences of proteins of the immunoglobulin superfamily, cell adhesion molecules and vertebrate muscle proteins, including myosin light-chain kinase. These homologies, together with results from earlier genetic and molecular analyses, indicate that twitchin is involved in a novel mechanism of myosin regulation.
We have characterized a 1400-nucleotide cDNA for the human skeletal muscle ADP/ATP translocator. The deduced amino acid sequence is 94% homologous to the beef heart ADP/ATP translocator protein and contains only a single additional amino-terminal methionine. This implies that the human translocator lacks an amino-terminal targeting peptide, a conclusion substantiated by measuring the molecular weight of the protein synthesized in vitro. A 1400-nucleotide transcript encoding the skeletal muscle translocator was detected on blots oftotal RNA from human heart, kidney, skeletal muscle, and HeLa cells by hybridization with oligonucleotide probes homologous to the coding region and 3' noncoding region of the cDNA. However, the level of this mRNA varied substantially among tissues. Comparison of our skeletal muscle translocator sequence with that of a recently published human fibroblast translocator cognate revealed that the two proteins are 88% identical and diverged about 275 million years ago. Hence, tissues vary both in the level of expression of individual translocator genes and in differential expression of cognate translocator genes. Comparison of the base substitution rates of the ADP/ATP translocator and the oxidative phosphorylation genes encoded by mitochondrial DNA revealed that the mitochondrial DNA genes fix 10 times more synonymous substitutions and 12 times more replacement substitutions; yet, these nuclear and cytoplasmic respiration genes experience comparable evolutionary constraints. This suggests that the mitochondrial DNA genes are highly prone to deleterious mutations.The ADP/ATP translocator, or adenine nucleotide translocator (ANT), is the most abundant mitochondrial protein (1). In its functional state it forms a dimer consisting of two identical 30-kDa subunits embedded asymmetrically in the inner mitochondrial membrane (2). The dimer forms a gated pore through which ADP is moved across the inner membrane into the mitochondrial matrix and ATP is moved from the matrix into the cytoplasm (2).Mitochondrial energy production varies greatly in importance between human tissues (3). Because the ANT determines the rate of ADP/ATP flux between the mitochondrion and the cytosol, the ANT would be a logical site for regulating cellular dependence on oxidative energy metabolism. Such regulation could be accomplished by producing varying amounts of the ANT or by elaborating tissue-specific ANT isoforms with different kinetic properties. Although Neurospora crassa has only one ANT gene (4), antigenic and electrophoretic mobility differences among bovine heart, kidney, and liver ANTs (5, 6) suggest that mammals may have multiple ANT genes that are expressed in a tissuespecific manner. Tissue-specific expression of functionally similar genes encoding proteins involved in oxidative phosphorylation (Ox/Phos) has been reported for the bovine ATP synthase proteolipid (7).The ANT and most other Ox/Phos genes are encoded in the nucleus, but 13 essential Ox/Phos polypeptides are encoded in the maternally inh...
A 2.76 kb segment of the 12 kb divergent region of the Leishmania tarentolae kinetoplast maxicircle DNA consists almost entirely of repeated sequences. The repeats can be grouped into six families, some of which are present throughout the remainder of the divergent region. The repeats are oriented in a head-to-tail fashion with the three simplest repeats clustered into large arrays. A 47 bp palindrome and two copies of a "supercluster" of three different types of repeats are also present in the sequenced region. A sequence change in the divergent region is described for a clonal strain of L. tarentolae which was passaged continuously for several years. The repetitive sequences found in the divergent region appear to be appropriate substrates for the presumed deletion/insertion/recombination events occurring in this rapidly evolving portion of the maxicircle.
Transcripts for six Leishmania tarentolae maxicircle structural genes (cytochrome oxidase subunits I, II and III, cytochrome b, human mitochondrial unidentified reading frames 4 and 5) and several unidentified open reading frames were mapped, and the locations of the 5' ends determined by primer runoff analysis. All genes studied here are transcribed from the same strand as the 12S and 9S ribosomal RNAs except for the cytochrome oxidase subunit I gene. In two cases (ORF3 and ORF4, ORF5 and ORF6), a single transcript covers two contiguous overlapping reading frames. The 5' ends of the RNAs are located 20-64 nt from the putative translation initiation codons. Primary transcripts from a mitochondrial RNA preparation were 5' end-labeled with guanylyltransferase and alpha -32P-GTP; the major labeled species comigrated with the 12S and 9S mitochondrial rRNAs, and in addition there were at least four higher molecular weight labeled species.
The PARFAH method not only provides a sensitive, high-throughput, and cost-effective strategy for the detection of low levels of mtDNA mutations in peripheral tissues, but also facilitates the estimation of the percentage of mutant DNA in the sample. The fact that samples can be readily obtained from peripheral tissues in many cases will avoid the need for invasive muscle biopsies. Our ability to detect low levels of mtDNA mutations in blood samples of carriers will allow us to reassess the prevalence of the MTTL1 3243A>G mutation in patients with diabetes.
Human cardiac myocytes undergo degeneration, cytolysis, and necrosis in a number of clinical disease conditions such as myocarditis, dilated cardiomyopathy, and during episodes of cardiac allograft rejection. The precise cellular, biochemical, and molecular mechanisms that lead to such abnormalities in myocytes have been difficult to investigate because at present it is not possible to obtain and maintain viable cell cultures of human adult cardiac myocytes in vitro. However, human fetal cardiac myocytes are relatively easy to maintain and culture in vitro, but their limited availability and growth, variability from one preparation to another, and varying degrees of contamination with endothelial and epithelial cell types have made it difficult to obtain reliable data on the effect of cardiotropic viruses and cardiotoxic drugs on such myocytes. These thoughts prompted us to attempt to derive a cell line of human cardiac origin. Highly enriched human fetal cardiac myocytes were transfected with the plasmids pSV2Neo and pRSVTAg and gave rise to a cell line (W1) which has been maintained in culture for 1 yr. Morphologic and phenotypic analyses of W1 cells by flow microfluorometry and immunoperoxidase techniques indicate that the W1 cell line shares many properties of human fetal cardiac myocytes, but appears not to react with specific antibodies known to react with markers unique to human endothelial, epithelial, skeletal muscle, and dendritic cells. These preliminary data suggest that the W1 cells may provide a unique source of an established cell line that shares many properties ascribed to human cardiac myocytes.
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