Comparison of myosin heavy chains in atria and ventricles from hyperthyroid, hypothyroid, and euthyroid rabbits

The structural similarities of the heavy chains (HC) of myosin isolated from atria and ventricles of hyper-, hypo-, and euthyroid rabbits were compared by immunological analysis, by one- and two-dimensional peptide mapping, and by electrophoresis under nondenaturing conditions. Monoclonal and polyclonal antibodies, which are specific for HC alpha of ventricular myosin, cross-reacted equally with the HCs of euthyroid atrial myosin. Our immunological analysis identified multiple epitopes common to euthyroid atrial HC and ventricular HC alpha. One- and two-dimensional gel electrophoretic analysis of peptides produced by partial proteolytic digestion of each type of HC reveal no differences between euthyroid atrial HCs and ventricular HC alpha, whereas marked differences are apparent between atrial HC and ventricular HC beta. Nondenaturing gel electrophoresis separates ventricular myosin from hyper- and hypothyroid rabbits into two forms, V1 and V3, respectively. In euthyroid atria, two isomyosins, A1 and A2, were resolved; with the slower moving A2 isomyosin having the same mobility as that of the V1 isomyosin. After cross-hybridization of light chains of ventricular myosin with euthyroid atrial HCs, only a single band having a mobility identical with that of the V1 isomyosin was seen. Furthermore, atrial myosin HCs isolated from hyper- and hypothyroid rabbits were indistinguishable from euthyroid atrial HC and from ventricular HC alpha by these procedures. We conclude that ventricular HC alpha and atrial HC are indistinguishable proteins, and that the type of HC expressed in the atria is unaffected by the thyroid state of the rabbit.     

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.     

Influence of thyroid hormone status on expression of genes encoding G protein subunits in the rat heart.

We have studied the influence of thyroid hormone status in vivo on expression of the genes encoding guanine nucleotide-binding regulatory protein (G protein) alpha-subunits Gs alpha, Gi alpha(2), Gi alpha(3), and both the 36-kDa form (beta 1) and the 35-kDa form (beta 2) of the beta-subunit in rat ventricle. The relative amounts of immunoactive Gi alpha(2) and Gi alpha(3) were greater in ventricular membranes from hypothyroid animals than from euthyroid animals (1.9- and 2.6-fold, respectively). A corresponding 2.3-fold increase in Gi alpha(2) mRNA was observed as well as a 1.5-fold increase in Gi alpha(3) mRNA. The relative amounts of immunoactive beta 1 and beta 2 polypeptides were also increased (2.8- and 1.8-fold, respectively) in the hypothyroid state and corresponded with comparable increases in the relative levels of beta 1 and beta 2 mRNAs. No difference was seen between the amounts of Gi alpha(2), Gi alpha(3), beta 1, and beta 2 in the euthyroid state and the hyperthyroid state. In contrast to these effects of thyroid hormone status on Gi alpha and beta, the steady-state amounts of Gs alpha protein and mRNA were not altered by thyroid hormone status. Thyroid hormone status did not alter sensitivity of adenylyl cyclase to stimulation by sodium fluoride or guanyl-5'-yl imidodiphosphate (GppNHp), nor did it influence GppNHp-induced inhibition of forskolin-stimulated enzyme activity. These results demonstrate that thyroid hormone status in vivo can regulate expression of specific G protein subunits in rat myocardium. However, the physiological consequences of these changes remain unclear.     

Influence of thyroid hormone on the in vitro translational activity of specific mRNAs in the rat heart

The influence of thyroid hormone on the translational activity of specific cardiac mRNA was determined by in vitro translation of RNA isolated from the heart of normal, hypothyroid, and 3,3',5-triiodo-L-thyronine-injected hypothyroid rats. Proteins synthesized in vitro in the presence of [35S]methionine were separated by two-dimensional gel electrophoresis and quantitated by a novel scanning procedure using digital matrix photometry. A total of 421 translational products were detected by fluorography and changes in the predominance of 12 of these were influenced by the thyroid state of the animals. The relative predominance of 8 species was increased in euthyroid animals, whereas 4 translational products were increased in hypothyroid animals. The majority of these thyroid hormone-related alterations occurred in spot pairs of similar molecular weights, but slightly different isoelectric points. In contrast, the relative predominance of mRNAs coding for the major contractile proteins, light chain 1, light chain 2, tropomyosin, actin, and myosin heavy chain was not altered by the thyroid status of the animals. The relative levels of these abundant mRNA species remained unaltered in spite of a thyroid hormone-related increase in total RNA levels. In vivo effects of thyroid hormone on cardiac RNA levels are complex. In addition to a general increase in total RNA and mRNA levels, increases or attenuations in the predominance of a small number of specific mRNA species are observed when euthyroid and hypothyroid animals are compared.     

Differential thyroid hormone-regulated rat thyrotropin beta gene expression detected by blot hybridization

In the rat, there is a single TSH beta-subunit gene represented by three exons interrupted by two introns. This gene contains two promoters which determines the synthesis of two mRNAs with 5'-untranslated regions that differ by 43 base pairs. This study evaluates the steady state levels of these TSH beta mRNAs in various thyroidal states. Blot hybridization analyses of pituitary mRNA with synthetic probes designed to detect either one or both TSH beta mRNAs were performed. One probe corresponds to 24 bases in the 5'-untranslated region of mRNA1 and a second corresponds to 25 nucleotides in the coding region and detects both mRNA1 and mRNA2. These studies indicate the presence of TSH beta mRNA species of indistinguishable size consistent with the presence of two TSH beta mRNAs that contain slightly different 5'-untranslated regions. Comparison of pituitary RNA obtained from normal and hypothyroid rats reveals that the shorter mRNA (mRNA2) is increased approximately 6- to 8-fold with hypothyroidism while the abundance of the longer mRNA (mRNA1) is relatively unchanged. Treatment of either normal or hypothyroid animals with T3 decreases the abundance of mRNA2 while again mRNA1 is relatively unaffected. Thus, although both mRNAs are detected, only one mRNA is dramatically altered by thyroidal status. Therefore, the single rat TSH beta gene is transcribed into two mRNAs via the use of alternative promoters of which only one is markedly regulated by thyroid hormones.     

Thyroxine influences on contractile proteins from atrial and ventricular myocardium

When thyroxine is administered to rats or rabbits, both heart ventricles eventually undergo hypertrophy. Both atria and ventricles show a relative weight increase and this mainly involves sarcoplasmic proteins. Ventricular myosin from thyrotoxic rabbits has higher Ca2+-ATPase activity when compared with euthyroid rabbits, the hyperthropied atria however, show no change in myosin ATPase after thyroxine administration.     

Differential regulation of Na,K-ATPase alpha 1, alpha 2, and beta subunit mRNA and protein levels by thyroid hormone

The purpose of this study was to determine the effect of thyroid status on the Na,K-ATPase alpha isoforms and beta in rat heart, skeletal muscle, kidney, and brain at the levels of mRNA, protein abundance, and enzymatic activity. Northern and dot-blot analysis of RNA (euthyroid, hypothyroid, and triiodothyronine-injected hypothyroids = hyperthyroids) and immunoblot analysis of protein (euthyroid and hypothyroid) revealed isoform-specific regulation of Na,K-ATPase by thyroid status in kidney, heart, and skeletal muscle and no regulation of sodium pump subunit levels in the brain. In general, in the transition from euthyroid to hypothyroid alpha 1 mRNA and protein levels are unchanged in kidney and skeletal muscle and slightly decreased in heart, while alpha 2 mRNA and protein are decreased significantly in heart and skeletal muscle. In hypothyroid heart and skeletal muscle, the decrease in alpha 2 protein levels was much greater than the decrease in alpha 2 mRNA levels relative to euthyroid indicating translational or post-translational regulation of alpha 2 protein abundance by triiodothyronine status in these tissues. The regulation of beta subunit by thyroid status is tissue-dependent. In hypothyroid kidney beta mRNA levels do not change, but immunodetectable beta protein levels decrease relative to euthyroid, and the decrease parallels the decrease in Na,K-ATPase activity. In hypothyroid heart and skeletal muscle beta mRNA levels decrease; beta protein decreases in heart and was not detected in the skeletal muscle. These findings demonstrate that the euthyroid levels of expression of alpha 1 in heart, alpha 2 in heart and skeletal muscle, and beta in kidney, heart, and skeletal muscle are dependent on the presence of thyroid hormone.     

Unequal synthesis and differential degradation of propionyl CoA carboxylase subunits in cells from normal and propionic acidemia patients.

We have characterized further the molecular basis of human inherited propionyl CoA carboxylase deficiency by measuring steady state levels of the mRNAs coding for the enzyme's two protein subunits (alpha and beta) and by estimating initial synthesis and steady state levels of the protein subunits in skin fibroblasts from controls and affected patients. We studied cell lines from both major complementation groups (pccA and pccBC) corresponding, respectively, to defects in the carboxylase's alpha and beta subunits. Analysis of pccA lines revealed the absence of alpha chain mRNA in three and an abnormally small alpha-mRNA in a fourth. Despite the presence of normal beta-mRNA in each of these pccA lines, there was complete absence of both alpha and beta protein subunits under steady state conditions, even though new synthesis and mitochondrial import of beta precursors was normal. Results in nine pccBC lines revealed normal alpha mRNA in each, while the amounts of beta-mRNA were distinctly reduced in every case. Correspondingly, alpha protein subunits were present in normal amounts at steady-state, but beta subunits were uniformly decreased. In addition, in six of the nine beta deficient cell lines, partially degraded beta-subunits were observed. To help interpret these results, synthesis and stability of carboxylase subunits were studied in intact HeLa cells using a pulse-chase protocol. Whereas alpha chains were stable over the four hour interval studied, beta chains--initially synthesized in large excess over alpha chains--were degraded rapidly reaching equivalence with alpha chains after two hours.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunological and biochemical evidence for atrial-like isomyosin in thyrotoxic rabbit ventricle

Immunological, structural and enzymatic characteristics of atrial and ventricular myosin from euthyroid rabbits were analyzed and compared with ventricular myosin from hyperthyroid animals. (1) Specific antibodies against bovine atrial myosin were found to react selectively in double-immunodiffusion and enzyme immunoassay with both rabbit atrial myosin and ventricular myosin from thyroxine-treated animals. These specific anti-bovine atrial myosin antibodies reacted with the heavy chains of thyrotoxic ventricular myosin when examined by enzyme immunoassay combined with SDS-polyacrylamide gel electrophoresis. (2) In one-dimensional SDS-polyacrylamide gel electrophoresis, no difference could be demonstrated in the light chain pattern of ventricular myosin from euthyroid and hyperthyroid rabbit hearts. One-dimensional analysis of myosin heavy chains after chymotryptic digestion in the presence of SDS showed significant differences between the two ventricular myosins. Also, the peptide maps from atrial myosin resembled the pattern of peptides found with ventricular heavy chains from hyperthyroid rabbits. The steady state rate, the alkali stability and the pH sensitivity of Ca2+-ATPase activity of thyrotoxic ventricular myosin were very similar to those of atrial myosin. (3) These results provide direct immunochemical and biochemical evidence for the existence of an atrial-like isomyosin in thyrotoxic rabbit ventricles.     

ATPase sites in two-headed fragment of Tetrahymena 22S ciliary dynein.

Three-headed Tetrahymena 22S ciliary dynein was found to consist of three heavy chains (HCs) and decompose into two-headed and single-headed fragments upon chymotrypsin digestion. The three HCs (A alpha, A beta, and A gamma) were immunologically different, and presumed to be located on each of the head regions. The two-headed fragment contained A beta and A gamma HCs, while the A alpha HC originated in the single-headed fragment. Both fragments were associated with ATPase activity (Toyoshima, Y. (1987a) J. Cell Biol. 105, 887-895 and Toyoshima, Y. (1987b) J. Cell Biol. 105, 897-901). Using the two-headed dynein fragment, we attempted to determine the site of ATP hydrolysis in the fragment. After digestion of the fragment with 100 micrograms/ml thermolysin for 45 min, we noted eight thermolysin-digested polypeptides (TH 1, 2, 3, 4, 5 alpha, 5 beta, 6 alpha, and 6 beta). By precisely analyzing the degradation process and the products using peptide mapping, immunoblotting and high pressure liquid chromatography, it appeared that the two-headed fragment is dissociated as two separate fragments, each of which contained A beta or A gamma HC. Thermolysin digests, TH 1, 2, 5 alpha and 6 beta were found to be derived from A beta HC, while TH 3, 4, 5 beta and 6 alpha originated in the A gamma HC. Based on the measurements of ATPase activity of these polypeptides, we concluded that the ATPase site is located in the A beta and A gamma HCs, which may have their origins in each head of the two-headed fragment of Tetrahymena 22S ciliary dynein.     

Effect of thyroid state on the phospholipid regeneration rate of rat liver mitochondria

The rate of phospholipid renewal in mitochondria of normal, hypothyroid, hyperthyroid and thyrotoxic rats was studied. Mitochondria were isolated from rat livers 24 and 48 hrs after administration of 3H-glycerol and 14C-palmitic acid. In mitochondria of hypothyroid animals, practically no phospholipid renewal is observed. In mitochondria of hyperthyroid and thyrotoxic rats, the rate of degradation of phospholipids labelled with glycerol, was approximately 1.5 times as low as that in controls. The decrease in the rate of renewal of the fatty acid residues in mitochondrial phospholipids was still more pronounced in hyperthyroid and thyrotoxic animals. Possible reasons for these changes connected with the thyroid state are discussed.     

Hormonal regulation of thyrotropin alpha and beta subunit mRNAs

We have examined the effects of 3,5 3'-triiodo-L-thyronine (T3), dexamethasone, bromocriptine, thyrotropin releasing hormone (TRH) and estrogen on the levels of pituitary alpha and TSH-beta protein and mRNA levels in hypothyroid mice. After 3 days of treatment with T3 (0.5 micrograms/100 g body weight) serum TSH, alpha and TSH-beta levels were 77%, 79% and 44% of control, respectively. Pituitary alpha and TSH-beta mRNA content was estimated by dot blot hybridization of total RNA with 32P-labelled alpha and TSH-beta plasmid probes. There was no change in alpha mRNA after 3 days of T3 treatment but TSH-beta mRNA had decreased to 60% of control. With T3 at 2 micrograms/100 g body weight for 3 days, TSH protein was 27% of control and TSH-beta was undetectable, but there was no change in alpha. TSH-beta mRNA was decreased to 40% of control at 1 day and was barely detectable at 3 days, whereas alpha mRNA was 70% of control at 1 day and 42% at 3 days. Dexamethasone and bromocriptine caused no consistent change in pituitary levels of alpha and TSH-beta mRNA. Treatment with TRH caused small increases in serum TSH and in both alpha and TSH-beta mRNA levels. Estrogen treatment increased serum TSH and subunit levels and TSH-beta mRNA, but not alpha. We conclude that thyroid hormones decrease alpha and beta subunit mRNA levels discordantly in both the hypothyroid pituitary and in thyrotropic tumors and that the suppressive effect of thyroid hormone is the major regulator of TSH.     

Regulation of Five Tubulin Isotypes by Thyroid Hormone During Brain Development

Nucleic acid probes derived from the 3' noncoding region of five tubulin cDNAs were used to study the effects of thyroid hormone deficiency on the expression of the mRNAs encoding two alpha (alpha 1 and alpha 2)- and three beta (beta 2, beta 4, and beta 5)-tubulin isotypes in the developing cerebral hemispheres and cerebellum. The content of alpha 1, which markedly declines during development in both brain regions, is maintained at high levels in the hypothyroid cerebellum, whereas it is decreased in the cerebral hemispheres. The alpha 2 level also declines during development and is decreased in both regions by thyroid hormone deficiency, but only during the two first postnatal weeks. Thyroid hormone deficiency slightly increases at all stages the beta 2 level in the cerebellum, whereas a decrease is observed at early stages in the cerebral hemispheres. The beta 5 level seems to be independent of thyroid hormone in the cerebral hemispheres, whereas it decreases at early stages in the hypothyroid cerebellum. Finally, the expression of the brain-specific beta 4 isotype is markedly depressed by thyroid hormone deficiency, particularly in the cerebellum. These data suggest that the genes encoding the tubulin isotypes are, directly or not, differently regulated by thyroid hormone during brain development. This might contribute to abnormal neurite outgrowth seen in the hypothyroid brain and therefore to impairment in brain functions produced by thyroid hormone deficiency.