Biochemical and stereological analysis of rat liver mitochondria in different thyroid states.

The concentrations of the inner mitochondrial membrane markers cardiolipin and cytochrome alpha have been measured in liver homogenates and in purified mitochondria after thyroxine administration to thyroidectomized and normal rats. The biochemical results have been correlated with stereological electron micrographic analyses of hepatocytes in liver sections, and of isolated mitochondrial pellets. There were progressive and parallel increases in homogenate and mitochondrial cardiolipin concentration, and in mitochondrial cytochrome alpha concentration, after administration of 20 microgram of thyroxine on alternate days to thyroidectomized rats, and of 300 microgram on alternate days to normal rats. Electron microscope measurements showed marked differences in the shape of the mitochondria and in the number of cristae in different thyroid states. Hypothyroid mitochondria were shorter and wider than controls, and hyperthyroid mitochondria longer but of similar width. Mitochondrial volume per unit cell volume was virtually unchanged in hypo- and hyperthyroid animals. The most striking changes were a decrease in the area of the inner membrane plus cristae in thyroidectomized rats, and a substantial increase in membrane area after thyroxine administration. The biochemical and electron micrographic results indicate that, in rat liver, thyroid hormone administration leads to a selective increase in the relative amount of mitochondrial inner membranes, with little or no change in the mitochondrial volume per unit cell volume, or in total mitochondrial protein per unit total cell protein.

Cardiolipin content of wild type and mutant yeasts in relation to mitochondrial function and development.

The phospholipid composition of various strains of the yeast, Saccharomyces cerevisiae, and several of their derived mitochondrial mutants grown under conditions designed to induce variations in the complement of mitochondrial membranes has been examined. Wild type and petite (cytoplasmic respiratory deficient) yeasts were fractionated into various subcellular fractions, which were monitored by electron microscopy and analyzed for cytochrome oxidase (in wild type) and phospholipid composition. 90% or more of the phospholipid, cardiolipin was found in the mitochondrial membranes of wild type and petite yeast. Cardiolipin content differed markedly under various growth conditions. Stationary yeast grown in glucose had better developed mitochondria and more cardiolipin than repressed log phase yeast. Aerobic yeast contained more cardiolipin than anaerobic yeast. Respiration-deficient cytoplasmic mitochondrial mutants, both suppressive and neutral, contained less cardiolipin than corresponding wild types. A chromosomal mutant lacking respiratory function had normal cardiolipin content. Log phase cells grown in galactose and lactate, which do not readily repress the development of mitochondrial membranes, contained as much cardiolipin as stationary phase cells grown in glucose. Cytoplasmic mitochondrial mutants respond to changes in the glucose concentration of the growth medium by variations in their cardiolipin content in the same way as wild type yeast does under similar growth conditions. It is concluded that cardiolipin content of yeast is correlated with, and is a good indicator of, the state of development of mitochondrial membrane.

Control of myosin heavy chain expression in cardiac hypertrophy.

The control of myosin expression by thyroid hormone is analyzed as an example of compensatory mechanisms of the heart. Two topics are discussed in detail: polymorphism of cardiac myosin heavy chains in the mammalian heart, and effect of thyroid hormone on myosin heavy chain expression by thyroid hormone. Our current knowledge about the identity of heavy chains and their corresponding isomyosins myosins is summarized and the dynamic nature of the myosin phenotype of the heart is discussed. The data on the thyroid hormone's role include studies in which the synthesis rate of the 2 classes of heavy chains (alpha and beta) was compared with their respective messenger RNA levels. A close correlation was observed and is consistent with pretranslational control. Transcription of myosin heavy chain genes was examined using isolated nuclei in a run-off experiment The rate of gene transcription was found to be the principal determinant of the cytoplasmic level of messenger RNA and of the isomyosin composition of the heart.

Sequence homology of the mitochondrial leucyl-tRNA cistron in different organisms.

Sequence divergence of the mitochondrial leucytl-tRNA cistron in several eukaryotes has been examined by RNA-DNA hybridized. Rat mitochondria Leucyl-tRNA was hybridized with rat, mouse, guinea pig, monkey, chicken, and yeast mitochondrial DNAs (mtDNA) immobilized onfilters. Hybridization was carried out in 50% formamide (Tm -12degrees) or in 20% fromamide (Tm -21degrees). melting profiles of the hybrids were obtained for evaluation of the extent of base sequence micmatching. Under the more stringent hybridization conditions (50% formamide, Tm -12degrees), only mouse and quines pig mtDNAs hybridized with rat mitochondrial leucyl-tRNA. The Tm's of the heterohybrids were depressed by 2 and 9 degrees, respectively. Under less stringent hybridization conditions (Tm-21 degrees), monkey mtDNA also hybridized, and the Tm was depressed by about 15 degrees. Chicken and yeast mtDNAs did not form specific hybrids with rat mibochondrial leucyl-tRNA under these hybridization conditions. Mitochondrial leucyl-tRNA sequences in different eukaryotes appear to be conserved to a less extent than cytoplasmic rRNA, 5S RNA, or hemoglobin mRNA sequences.

Sequence homology between mitochondrial DNAs of different eukaryotes.

The sequence divergence of mitochondrial DNAs (mtDNA) from rat, mouse, guinea pig, monkey, and chicken has been examined by DNA-DNA hybridization. mtDNAs, isolated as closed circular molecules by propidium iodide-CsCl centrifugation, were labeled in vitro by use of Escherichia coli DNA polymerase I, and renatured (Tm-35 degrees) in the presence of a 2500-fold excess of heterologous mtDNA. Single-stranded and duples DNA were separated by hydroxylapatite chromatography. The thermal stability of heteroduplexes was compared to the homoduplex by thermal elution chromatography on hydroxylapatite columns. Heteroduplex fromation between the tritiated myDNAs and a 2500-fole excess of rar mtDNA were 70, 59, 37, and 22%, respectively, for mouse, guinea pig, monkey, and chicken. Similar results were obrained in reciprocal hybridizations where one of the other mtDNAs was present in excess. Considerable mismatching of sequences in all the heterohybrids was indicated by a 18-24 degrees depression in the te50 of the heteroduplexes compared with the homoduplex. There was no apparent change in heteroduplex formation when the concentration ratio of driving DNA in excess to [3H]mtDNA was varied between 1250 and 7500. Furthermore, a second renaturation with excess driving DNA after completion of the first reaction resulted in no detectable augmenting of heteroduplex formation. Similar sequences appear to be conserved preferentially in different organisms, since the presence of two of fouf different heterologous mtDNAs in excess resulted in only moderate and nonadditive increases in heteroduplex formation. Evolutionary divergence of mtDNA sequences appears to have occurred at rates similar to that for unique sequences nuclear DNA.

Studies of cytochrome synthesis in rat liver.

The incorporation of radioactive amino acids and of delta-amino[2,3-(3)H(2)]laevulinate into rat liver cytochromes b(5) and c and cytochrome oxidase has been examined with and without protein-synthesis inhibitors. Cycloheximide promptly inhibits labelling of both haem and protein for cytochrome c in parallel fashion. Although incorporation of (14)C-labelled amino acid into microsomal cytochrome b(5) is also rapidly inhibited, cycloheximide incompletely inhibits haem labelling of cytochrome b(5) and cytochrome a+a(3), and inhibition occurs only after repeated antibiotic injections. The possibility of apo-protein pools, or of haem exchange, with a rapidly renewed ;free' haem pool, is considered. Consistent with this model is the observation of non-enzymic haem exchange in vitro between cytochrome b(5) and methaemoglobin. Chloramphenicol, injected intravenously over 5h, results in a 20-40% decrease in incorporation of delta-amino[2,3-(3)H(2)]laevulinate into haem a+a(3) and haem of cytochromes b(5) and c. With the dosage schedule of chloramphenicol studied, amino acid labelling of total liver protein and of cytochrome c was not inhibited. Similarly, ferrochelatase activity was not decreased.

Differential expression of ventricular-like myosin heavy chain mRNA in developing and regenerating avian skeletal muscles.

Based on previous immunological data, cross-reactivity of myosin heavy chain (MHC) with the ventricular (V) isoform was observed in primordia of avian skeletal muscles and in regenerating adult anterior latissimus dorsi (ALD) muscle. To determine whether this primordial (P) MHC is identical to adult V-MHC gene product, we have cloned and characterized the 3' portion of MHC cDNA that is expressed in ALD muscle at 3 d of regeneration. Comparison of nucleotide sequences between adult V-MHC and P-MHC cDNAs revealed more than 98% homology in the 3'-untranslated (UT) portions of these genes. The expression pattern of P-MHC was analyzed in adult regenerating muscles using total RNA from two fast muscles, posterior latissimus dorsi (PLD) and pectoralis major (PM), as well as from slow ALD and mixed fast/slow gastrocnemius muscles at 0, 1, 3, 4, 6, 9, and 14 d after cold injury. Identical results were obtained by RNase protection assays using either a probe specifying the coding region of adult V-MHC or a P-MHC probe encoding the carboxy end plus the 3'-UT region. The expected protected fragments were detected early from day 2 up to day 6 in ALD muscle. Similar rate of appearance, reaching the highest level at day 3, was observed in PLD, PM, and gastrocnemius muscles. However, the amount and the kinetics of disappearance differed among the various muscles analyzed. In contrast, during development, steady-state levels and kinetics of V-MHC mRNA expression were found to be alike in axial and appendicular muscles. These data strongly suggest the identity of P-MHC as the ventricular isoform and support the concept that expression of P-MHC mRNA is a common feature of developing as well as of all regenerating adult skeletal muscles. Interestingly, no expression of cardiac specific myosin light chain (MLC) 2A was observed after cold injury, suggesting independent regulatory pathways for the two kinds of myosin subunits.

Cardiac phenotypic markers expressed in early stages of both cardiac and skeletal muscle development.

We have examined changes in the expression of chicken myosin heavy chain (MHC) mRNAs in the heart and skeletal muscles during normal development and in regenerating adult muscles. cDNA clones isolated from adult heart and regenerating skeletal muscle libraries revealed more than 98% sequence homology in the 3' untranslated regions. Using specific cDNA probes we have detected ventricular MHC transcripts in the heart and in early developmental stages of fast as well as slow skeletal muscles. The expression of ventricular MHC mRNA in skeletal muscles is especially significant since, in contrast to mammals, the avian ventricular and slow MHC mRNAs are encoded by different genes.

Catecholamines and cardiac growth.

The present knowledge concerning the alpha- and beta-adrenergic systems in the regulation of cardiac growth and gene expression is reviewed. To investigate the mechanism by which cAMP regulates the expression of cardiac genes we have used cultured myocytes derived from fetal rat hearts. We have shown previously that the addition of Br cAMP to the culture medium produced an increase in alpha-myosin heavy chain (alpha-MHC) mRNA level, in its rate of transcription as well as in the amount of V1 isomyosin. To characterize the promoter element(s) involved in cAMP responsive regulation of alpha-MHC expression we performed transient transfection analysis with a series of alpha-MHC gene promoter-CAT constructs. We have identified a 13 bp E-box/M-CAT hybrid motif (EM element) which conferred a basal muscle specific and cAMP inducible expression of the alpha-MHC gene. Using mobility shift assay we have documented that one of the EM element binding protein is TEF-1. Moreover, by incubating cardiac nuclear extracts with the catalytic subunit of PK-A we have found that factor(s) binding to the EM element is a substrate for cAMP dependent phosphorylation.

Developmental shift of myosin heavy chain mRNA expression due to neural factor(s) and muscle activity.

The adult ventricular isoform of chicken myosin heavy chain (MHC-V) is transiently expressed in all skeletal muscle primordia analyzed and is completely repressed around embryonic days 10-12, when functional innervation is established. By ribonuclease protection assay, we demonstrated that denervation of the adult anterior latissimus dorsi muscle resulted in reexpression of MHC-V mRNA. In contrast, treatment of primary cultures of fetal breast or leg muscles with embryonic brain extract or conditioned media from glial or neuroblastoma cell lines, but not from a myogenic cell line or primary muscle cell cultures, led to inhibition of MHC-V expression. This inhibitory activity was abolished by heating and increased with protein concentration. The acquisition of both brain inhibitory activity and the competence of myogenic cells to downregulate MHC-V mRNA expression were age dependent. Furthermore, either paralysis of muscle in ovo by curare or contraction arrest of cultured myotubes resulted in persistent expression of MHC-V mRNA. Thus a putative soluble factor(s) of nerve origin as well as muscle activity are involved in the developmental downregulation of MHC-V expression in muscle primordia.

Structural and phylogenetic analysis of the chicken ventricular myosin heavy chain rod.

We have isolated and characterized five overlapping clones that encompass 3.2 kb and encode a part of the short subfragment 2, the hinge, and the light meromyosin regions of the myosin heavy chain rod as well as 143 bp of the 3' untranslated portion of the mRNA. Northern blot analysis showed expression of this mRNA mainly in ventricular muscle of the adult chicken heart, with trace levels detected in the atrium. Transient expression was seen in skeletal muscle during development and in regenerating skeletal muscle following freeze injury. To our knowledge, this is the first report of an avian ventricular myosin heavy chain sequence. Phylogenetic analysis indicated that this isoform is a distant homolog of other ventricular and skeletal muscle myosin heavy chains and represents a distinct member of the multigene family of sarcomeric myosin heavy chains. The ventricular myosin heavy chain of the chicken is either paralogous to its counterpart in other vertebrates or has diverged at a significantly higher rate.

Mitochondrial development in liver of foetal and newborn rats.

THE DEVELOPMENT OF THE INNER MITOCHONDRIAL MEMBRANE IN FOETAL AND NEONATAL RAT LIVER WAS STUDIED BY FOLLOWING THREE PARAMETERS: (1) the activity of several respiratory enzymes in homogenates and purified mitochondria, (2) the spectrophotometric determination of cytochrome content in the mitochondria and (3) the cardiolipin content in both homogenates and purified mitochondria. Respiratory-enzyme activities of homogenates of foetal liver were one-quarter to one-twentieth of those of homogenates of adult liver, and the enzyme specific activities in purified mitochondria from foetal liver were one-half to one-eighth of those in mitochondria from adult liver. The cardiolipin content of liver homogenates increased approximately twofold during the development period, but there was no significant change in the cardiolipin content of purified mitochondria. It is concluded that cell mitochondrial content approximately doubles in the immediate postnatal period. There was no evidence for an increase in the relative amount of cristae protein in mitochondria during this period to account for increases in mitochondrial enzyme specific activity, since cardiolipin and cytochrome concentrations remained unchanged and electron micrographs revealed no differences. The cause of the lower respiratory-enzyme specific activity in foetal liver mitochondria is unclear. Qualitative differences in respiratory units in foetal and mature animals are suggested.

Molecular cloning of mRNA sequences for cardiac alpha- and beta-form myosin heavy chains: expression in ventricles of normal, hypothyroid, and thyrotoxic rabbits.

We have isolated cDNA clones from thyrotoxic (pMHC alpha) and normal (pMHC beta) adult rabbit hearts. Restriction map analysis and DNA sequence analyses show that, although there is strong homology between overlapping regions of the two clones, they are distinctly different. The two clones exhibited 78-83% homology between the derived amino acid sequences and those determined by direct amino acid sequence analysis of rabbit fast skeletal muscle myosin heavy chains. The clones specify a segment of the myosin heavy chain corresponding to subfragment 2 and the COOH-terminal portions of subfragment 1. Nuclease S1 mapping was used to compare transcription of the two clones with expression of the alpha and beta forms of myosin heavy chains in the ventricles of thyrotoxic, hypothyroid (propylthiouracil-treated), and normal rabbits. Thyrotoxic ventricles contained only pMHC alpha transcripts whereas hypothyroid ventricles contained exclusively pMHC beta transcripts. These data correlate well with the presence of alpha- and beta-form myosin heavy chains. In the normal young adult rabbit, pMHC beta transcripts predominate, agreeing with the known beta form/alpha form ratio of 4:1. We therefore conclude that pMHC alpha and pMHC beta contain sequences of the alpha- and beta-form myosin heavy chain genes, respectively.

Cloned mRNA sequences for two types of embryonic myosin heavy chains from chick skeletal muscle. II. Expression during development using S1 nuclease mapping.

We have examined the expression of two embryonic myosin HC mRNAs using two cDNA clones (110 and 251) which we have previously constructed from RNA isolated from 14-day-old embryonic chick skeletal muscle. Sequence divergence in the 3' nontranslated regions enabled us to analyze the differential expression of the mRNAs corresponding to the two clones using the S1 nuclease mapping procedure. Clone 251 mRNA is expressed primarily in embryonic fast muscle, where its transcripts appear to be the predominant species. This mRNA is minimally expressed in the posthatching period, but it is not detected in adult leg and breast muscle. Messenger RNA for clone 110 is also primarily expressed in embryonic fast muscle. However, in the posthatching and adult stages of development, it continues to be expressed at a low level in leg muscle but not in breast muscle. The differential expression of these mRNAs during development strongly indicates that they correspond to two different genes coding for embryonic myosin HCs. Other myosin HC mRNAs which were partially homologous to the clone 110 or 251 mRNAs were also identified by S1 nuclease mapping. Using the probes from these two clones, a minimum of four other developmentally expressed forms were detected. Two of these correspond to "neonatal" myosin HCs, while the other two code for different adult myosin HCs present in leg and in breast muscle, respectively. The results therefore suggest a much greater diversity of myosin HC mRNAs expressed during development than previously reported.

Isolation and characterization of two molecular variants of myosin heavy chain from rabbit ventricle. Change in their content during normal growth and after treatment with thyroid hormone.

We have prepared monoclonal antibodies specific for cardiac myosin heavy chain. These antibodies were used for the separation and characterization of the molecular variants of myosin heavy chain present in the rabbit heart. Two molecular forms of myosin heavy chain, HC alpha and HC beta, were isolated from the euthyroid rabbit heart by affinity chromatography. Their reactivity with our antibodies indicated that the primary structures of HC alpha and HC beta differ in at least four and share at least two antigenic determinants. Differences in the primary structure of HC alpha and HC beta were confirmed by analysis of the peptides produced by limited chymotryptic digestion of the two heavy chains. Thirteen peptide differences were consistently found. The HC alpha and HC beta variants are shown by immunologic analysis and in chymotryptic peptide profiles to be identical with the predominant forms of myosin heavy chain synthesized in the hearts of hyperthyroid and adult euthyroid rabbits, respectively. During development and maturation of the euthyroid rabbit heart, HC alpha comprises approximately 50% of the ventricular myosin between birth and 4 weeks of age; it diminishes to 20-30% by 8 weeks and to 10-20% by 12 weeks of age. Cardiac myosin from a 1-year-old rabbit is composed almost entirely of HC beta. Cardiac myosin from embryonic animals at 20 days gestation contained 20% HC alpha. These results show that HC alpha occurs normally in the euthyroid rabbit heart and that the relative proportions of HC alpha and HC beta depend on both the developmental stage and the thyroid state of the animal.

Muscle-specific regulation of a transfected rabbit myosin heavy chain beta gene promoter.

We have examined the transcriptional regulation of the rabbit myosin heavy chain (HC) beta gene by using DNA-mediated transfection experiments. To analyze the activity of the myosin HC beta promoter in a myogenic background, cultured myoblasts from 12-day-old chick embryonic breast muscle were transfected with a chimeric gene containing 781 base pairs of the promoter region fused to the gene for chloramphenicol acetyltransferase (CAT). As indicated by the transient expression of chloramphenicol acetyltransferase, the activity of the promoter in myoblast cultures increased at least 32-fold following differentiation and was selectively inhibited when myogenesis was blocked with 5-bromodeoxyuridine. Furthermore, RNase protection experiments showed that the in vivo myosin HC beta transcriptional initiation (or cap) site was utilized in the transfected skeletal muscle cells and also that the regulation of the exogenous promoter was similar to the induction of the endogenous skeletal alpha-actin gene. The results indicated that the exogenous promoter is regulated in a tissue- and stage-specific manner. By creating progressive 5' deletions of the promoter, we showed that only the region extending -294 base pairs upstream from the cap site is necessary for the muscle-specific expression. Linker-scanner mutagenesis of this region indicated that the positive regulation in differentiated skeletal muscle is mediated by at least two distinct elements within the 5'-flanking region of the myosin HC beta gene.

Expression of rabbit ventricular alpha-myosin heavy chain messenger RNA sequences in atrial muscle.

We have constructed and isolated a cardiac myosin heavy chain (HC) cDNA clone, pMHC alpha 81, with mRNA from ventricular heart muscle of hyperthyroid rabbits. The clone encodes approximately 480 amino acids of the COOH terminus of light meromyosin and all of the 3' nontranslated region of the corresponding mRNA. Nuclease S1 analyses indicated that the clone is transcribed in hyperthyroid, but not in hypothyroid ventricles and, therefore, corresponds to ventricular alpha-HC mRNA. With probes from the more divergent 3' non-translated region of pMHC alpha 81 and also from selected portions of two previously characterized rabbit cDNA clones ( pMHC alpha 252 and pMHC beta 174), we analyzed the myosin HC mRNAs of atrial, fast skeletal, and slow skeletal muscles by nuclease S1 mapping. In atrial muscle, only one major transcript was detected. The sequence of this transcript was indistinguishable from ventricular alpha-HC mRNA in the 3' nontranslated region and in two coding segments. In contrast, the sequence divergence between the ventricular alpha-HC mRNA and the mRNAs of ventricular beta, fast skeletal, and slow skeletal myosin HCs was clearly detected. There appeared to be, however, considerable homology between coding sequences of ventricular beta and slow skeletal myosin HC mRNAs. The results strongly suggest that rabbit atrial and ventricular alpha-HCs are encoded by the same gene.

Regulation of myosin synthesis by thyroid hormone: relative change in the alpha- and beta-myosin heavy chain mRNA levels in rabbit heart.

The expression of mRNAs for two cardiac myosins has been examined in the ventricles of hypo- and hyperthyroid rabbits by means of cloned cDNA sequences corresponding to the mRNAs of the alpha- and beta-myosin heavy chains (HCs). The temporal change in the relative levels of the alpha- and beta-HC mRNAs after 3,5,3'-triiodothyronine (T3) treatment of hypothyroid rabbits was determined by nuclease S1 mapping. In the hypothyroid state, only HC beta-mRNA was expressed in the ventricles. The HC alpha-mRNA was first detectable 4 h after administration of T3 (200 micrograms/kg) to hypothyroid animals. By 12 h, HC alpha-mRNA represented 20% of total myosin mRNA, increasing to 50% by 24 h and to about 90% by 72 h. The relationship between the relative mRNA levels and relative synthesis rates of the myosin HCs was evaluated in 5-6-week-old normal and thyrotoxic rabbits. Myosin synthesis rates were determined by labeling of protein in vivo with [3H]leucine. The V1 (HC alpha) and V3 (HC beta) isomyosins were separated by affinity chromatography with monoclonal antibodies, and the HCs were isolated electrophoretically. In a normal euthyroid group of animals and in animals 12 and 24 h after administration of 200 micrograms of 3,5,3',5'-tetraiodothyronine/kg, the relative mRNA levels and relative synthesis rates of the alpha- and beta-HCs were not significantly different. Our results show that, first, thyroid hormone causes a rapid accumulation of HC alpha-mRNA and loss of HC beta-mRNA and, second, in normal and thyrotoxic rabbits, the relative synthesis rates of HC alpha and HC beta reflect the relative abundance of the alpha- and beta-HC mRNAs.(ABSTRACT TRUNCATED AT 250 WORDS)