Cardiac myosin heavy chain gene regulation by thyroid hormone involves altered histone modifications.

The antithetical regulation of cardiac α- and ß-myosin heavy chain (MHC) genes by thyroid hormone (T(3)) is not well understood but appears to involve thyroid hormone interaction with its nuclear receptor and MHC promoters as well as cis-acting noncoding regulatory RNA (ncRNA). Both of these phenomena involve epigenetic regulations. This study investigated the extent that altered thyroid state induces histone modifications in the chromatin associated with the cardiac MHC genes. We hypothesized that specific epigenetic events could be identified and linked to cardiac MHC gene switching in response to a hypothyroid or hyperthyroid state. A hypothyroid state was induced in rats by propylthiouracil treatment (PTU), whereas a hyperthyroid (T(3)) was induced by T(3) treatment. The left ventricle was analyzed after 7 days for MHC pre-mRNA expression, and the chromatin was assessed for enrichment in specific histone modifications using chromatin immunoprecipitation quantitative PCR assays. At both the α-MHC promoter and the intergenic region, the enrichment in acetyl histone H3 at K9/14 (H3K9/14ac) and trimethyl histone H3 at K4 (H3K4me3) changed in a similar fashion. They were both decreased with PTU treatment but did not change under T(3), except at a location situated 5' to the antisense intergenic transcription start site. These same marks varied differently on the ß-MHC promoter. For example, H3K4me3 enrichment correlated with the ß-promoter activity in PTU and T(3) groups, whereas H3K9/14ac was repressed in the T(3) group but did not change under PTU. Histone H3K9me was enriched in chromatin of both the intergenic and α-MHC promoters in the PTU group, whereas histone H4K20me1 was enriched in chromatin of ß-MHC promoter in the normal control and T(3) groups. Collectively, these findings provide evidence that specific epigenetic phenomena modulate MHC gene expression in altered thyroid states.

Skeletal muscle growth in young rats is inhibited by chronic exposure to IL-6 but preserved by concurrent voluntary endurance exercise.

Childhood diseases are often accompanied by chronic inflammation, which is thought to negatively impact growth. Interleukin-6 (IL-6) is typically cited as an indicator of inflammation and is linked to impaired growth. This study was designed to isolate and identify potential effects of chronic IL-6 exposure on skeletal muscle growth during development. A second aim was to determine if endurance exercise, thought to antagonize chronic inflammation, would interact with any effects of IL-6. The muscles of one leg of rapidly growing rats were exposed to IL-6 or vehicle for 14 days. Subgroups of IL-6-infused rats were provided access to running wheels. Local IL-6 infusion resulted in approximately 13% muscle growth deficit (myofibrillar protein levels). Exercise (>4,000 m/day) prevented this deficit. IL-6 infusion increased mRNA for suppressor of cytokine signaling-3 (SOCS3) and tumor necrosis factor-alpha (TNF-alpha), and this was not prevented by exercise. IL-6 infusion increased the mRNAs for atrogin, insulin-like growth factor-I (IGF-I), and IGF binding protein-4 (IGFBP4), and these effects were mitigated by exercise. Exercise stimulated an increase in total RNA ( approximately 19%) only in the IL-6-infused muscle, suggesting that a compensatory increase in translational capacity was required to maintain muscle growth. This study indicates that IL-6 exposure during periods of rapid growth in young animals can retard growth possibly via interactions with key growth factors. Relatively high volumes of endurance-type exercise do not exacerbate the negative effects of IL-6 and in fact were found to be beneficial in protecting muscle growth.

Combined isometric, concentric, and eccentric resistance exercise prevents unloading-induced muscle atrophy in rats.

Previously, we reported that an isometric resistance training program that was effective in stimulating muscle hypertrophy in ambulatory rats could not completely prevent muscle atrophy during unloading (Haddad F, Adams GR, Bodell PW, Baldwin KM. J Appl Physiol 100: 433-441, 2006). These results indicated that preventing muscle atrophy does not appear to be simply a function of providing an anabolic stimulus. The present study was undertaken to determine if resistance training, with increased volume (3-s contractions) and incorporating both static and dynamic components, would be effective in preventing unloading-induced muscle atrophy. Rats were exposed to 5 days of muscle unloading via tail suspension. During that time one leg received electrically stimulated resistance exercise (RE) that included an isometric, concentric, and eccentric phase. The results of this study indicate that this combined-mode RE provided an anabolic stimulus sufficient to maintain the mass and myofibril content of the trained but not the contralateral medial gastrocnemius (MG) muscle. Relative to the contralateral MG, the RE stimulus increased the amount of total RNA (indicative of translational capacity) as well as the mRNA for several anabolic/myogenic markers such as insulin-like growth factor-I, myogenin, myoferlin, and procollagen III-alpha-1 and decreased that of myostatin, a negative regulator of muscle size. The combined-mode RE protocol also increased the activity of anabolic signaling intermediates such as p70S6 kinase. These results indicate that a combination of static- and dynamic-mode RE of sufficient volume provides an effective stimulus to stimulate anabolic/myogenic mechanisms to counter the initial stages of unloading-induced muscle atrophy.

Similar acute molecular responses to equivalent volumes of isometric, lengthening, or shortening mode resistance exercise.

The present study was undertaken to test the hypothesis that the contraction mode of action [static-isometric (Iso), shortening-concentric (Con), or lengthening-eccentric (Ecc)] used to stress the muscle provides a differential mechanical stimulus eliciting greater or lesser degrees of anabolic response at the initiation of a resistance training program. We performed an acute resistance training study in which different groups of rodents completed four training sessions in either the Iso, Con, or Ecc mode of contraction under conditions of activation and movement specifically designed to elicit equivalent volumes of force accumulation. The results of this experiment indicate that the three modes of contraction produced nearly identical cell signaling, indicative of an anabolic response involving factors such as increased levels of mRNA for IGF-I, procollagen III alpha1, decreased myostatin mRNA, and increased total RNA concentration. The resulting profiles collectively provide evidence that pure mode of muscle action, in and of itself, does not appear to be a primary variable in determining the efficacy of increased loading paradigms with regard to the initiation of selected muscle anabolic responses.

Regulation of antisense RNA expression during cardiac MHC gene switching in response to pressure overload.

Hypertension has been shown to cause cardiac hypertrophy and a shift in myosin heavy chain (MHC) gene expression from the faster alpha- to slower beta-MHC isoform. The expression of the beta- and alpha-MHC pre-mRNAs, mRNAs, as well as the newly discovered antisense beta-RNA were analyzed in three regions of the normal control (NC) and 12-day pressure-overloaded (AbCon) hearts: the left ventricle apex, left ventricle base, and the septum. The RNA analyses in the AbCon heart targeted both the 5' and the 3' ends of each RNA molecule. beta-MHC mRNA expression significantly increased relative to control in all three regions, regardless of the target site (5' or 3' end). In contrast, beta-MHC pre-mRNA expression in the AbCon heart depended on the site of the measurement (5' vs. 3' end). For example, whereas the pre-mRNA did not change when targeted at the 3' end (last intron), it increased significantly in the AbCon heart when measurement targeted the 5' end (2nd intron) of the 25-kb molecule. Analyses of the antisense beta-RNA revealed that its expression in the AbCon heart was significantly decreased relative to control regardless of its measurement site. A negative correlation was observed between the beta-mRNA expression and the antisense beta-RNA (P < 0.05), suggesting an inhibitory role of antisense RNA on the sense beta-MHC gene expression. In contrast, a positive correlation was observed between the antisense beta-RNA and the alpha-MHC pre-mRNA (P < 0.05). This latter observation along with the alpha-MHC gene position relative to that of the beta-antisense suggest that the alpha-MHC sense and beta-antisense transcription are coregulated likely via common intergenic regulatory sequences. Our results suggest that the increased beta-MHC expression in the AbCon heart not only is the result of increased beta-MHC transcription but also involves an antisense beta-RNA regulation scheme. Although the exact mechanism concerning antisense regulation is not clear, it could involve modulation of both transcriptional activity of the beta-MHC gene and posttranscriptional processing.

Isometric resistance exercise fails to counteract skeletal muscle atrophy processes during the initial stages of unloading.

This study tested the hypothesis that an isometric resistance training paradigm targeting the medial gastrocnemius of adult rodents is effective in preventing muscle atrophy during the early stages of hindlimb unloading by maintaining normal activation of the insulin receptor substrate-1 (IRS-1)/phosphoinositide-3 kinase (PI3K)/Akt signaling pathway. This pathway has been shown to simultaneously create an anabolic response while inhibiting processes upregulating catabolic processes involving expression of key enzymes in the ubiquitination of proteins for degradation. The findings show that during the 5 days of unloading 1) absolute medial gastrocnemius muscle weight reduction occurred by approximately 20%, but muscle weight corrected to body weight was not different from normal weight-bearing controls (P < 0.05); 2) normalized myofibril fraction concentration and content were decreased; and 3) a robust isometric training program, known to induce a hypertrophy response, failed to maintain the myofibril protein content. This response occurred despite fully blunting the increases in the mRNA for of atrogin-1, MURF-1, and myostatin, e.g., sensitive gene markers of an activated catabolic state. Analyses of the IRS-1/PI3K/Akt markers indicated that abundance of IRS-1 and phosphorylation state of Akt and p70S6 kinase were decreased relative to normal control rats, and the resistance training failed to maintain these signaling markers at normal regulatory level. Our findings suggest that to fully prevent muscle atrophy responses affecting the myofibril system during unloading, the volume of mechanical stress must be augmented sufficiently to maintain optimal activity of the IRS-1/PI3K/Akt pathway to provide an effective anabolic stimulus on the muscle.

In vivo regulation of the beta-myosin heavy chain gene in hypertensive rodent heart.

The main goal of this study was to examine the transcriptional activity of different-length beta-myosin heavy chain (beta-MHC) promoters in the hypertensive rodent heart using the direct gene transfer approach. A hypertensive state was induced by abdominal aortic constriction (AbCon) sufficient to elevate mean arterial pressure by approximately 45% relative to control. Results show that beta-MHC promoter activity of all tested wild-type constructs, i.e., -3500, -408, -299, -215, -171, and -71 bp, was significantly increased in AbCon hearts. In the normal control hearts, expression of the -71-bp construct was comparable to that of the promoterless vector, but its induction by AbCon was comparable to that of the other constructs. Additional results, based on mutation analysis and DNA gel mobility shift assays targeting betae1, betae2, GATA, and betae3 elements, show that these previously defined cis-elements in the proximal promoter are indeed involved in maintaining basal promoter activity; however, none of these elements, either individually or collectively, appear to be major players in mediating the hypertension response of the beta-MHC gene. Collectively, these results indicate that three separate regions on the beta-MHC promoter are involved in the induction of the gene in response to hypertension: 1) a distal region between -408 and -3500 bp, 2) a proximal region between -299 and -215 bp, and 3) a basal region within -71 bp of the transcription start site. Future research needs to further characterize these responsive regions to more fully delineate beta-MHC transcriptional regulation in response to pressure overload.

Effects of spaceflight and thyroid deficiency on hindlimb development. I. Muscle mass and IGF-I expression.

Thyroid deficiency (TD) in neonatal rats causes reduced growth of skeletal muscle that is disproportionately greater than that for other tissues (G. R. Adams, S. A. McCue, M. Zeng, and K. M. Baldwin. Am. J. Physiol. Regulatory Integrative Comp. Physiol. 276: R954-R961, 1999). TD depresses plasma insulin-like growth factor I (IGF-I) levels, suggesting a mechanism for this effect. We hypothesized that TD and exposure to spaceflight (SF) would interact to reduce skeletal muscle growth via a reduction in IGF-I levels. Neonatal rats were flown in space for 16 days. There was a similar, nonadditive reduction in the growth of the body ( approximately 50%) and muscle weight (fast muscles, approximately 60%) with either TD or SF. In the soleus muscle, either SF or TD alone resulted in growth reductions that were augmented by SF-TD interactions. There were strong correlations between 1) muscle mass and muscle IGF-I levels and 2) circulating IGF-I and body weight. These results indicate that either hypothyroidism or exposure to SF will limit the somatic and muscle-specific growth of neonatal rats. The impact of these perturbations on skeletal muscle growth is relatively greater than the effect on somatic growth. The mechanisms by which either TD or SF impact growth appear to have a common pathway involving the control of plasma and muscle IGF-I concentrations.

Effects of spaceflight and thyroid deficiency on rat hindlimb development. II. Expression of MHC isoforms.

Both slow-twitch and fast-twitch muscles are undifferentiated after birth as to their contractile protein phenotype. Thus we examined the separate and combined effects of spaceflight (SF) and thyroid deficiency (TD) on myosin heavy chain (MHC) gene expression (protein and mRNA) in muscles of neonatal rats (7 and 14 days of age at launch) exposed to SF for 16 days. Spaceflight markedly reduced expression of the slow, type I MHC gene by approximately 55%, whereas it augmented expression of the fast IIx and IIb MHCs in antigravity skeletal muscles. In fast muscles, SF caused subtle increases in the fast IIb MHC relative to the other adult MHCs. In contrast, TD prevented the normal expression of the fast MHC phenotype, particularly the IIb MHC, whereas TD maintained expression of the embryonic/neonatal MHC isoforms; this response occurred independently of gravity. Collectively, these results suggest that normal expression of the type I MHC gene requires signals associated with weight-bearing activity, whereas normal expression of the IIb MHC requires an intact thyroid state acting independently of the weight-bearing activities typically encountered during neonatal development of laboratory rodents. Finally, MHC expression in developing muscles is chiefly regulated by pretranslational processes based on the tight relationship between the MHC protein and mRNA data.

In vivo regulation of beta-MHC gene in rodent heart: role of T3 and evidence for an upstream enhancer.

Cardiac beta-myosin heavy chain (beta-MHC) gene expression is mainly regulated through transcriptional processes. Although these results are based primarily on in vitro cell culture models, relatively little information is available concerning the interaction of key regulatory factors thought to modulate MHC expression in the intact rodent heart. Using a direct gene transfer approach, we studied the in vivo transcriptional activity of different-length beta-MHC promoter fragments in normal control and in altered thyroid states. The test beta-MHC promoter was fused to a firefly luciferase reporter gene, whereas the control alpha-MHC promoter was fused to the Renilla luciferase reporter gene and was used to account for variations in transfection efficiency. Absolute reporter gene activities showed that beta- and alpha-MHC genes were individually and reciprocally regulated by thyroid hormone. The beta-to-alpha ratios of reporter gene expression demonstrated an almost threefold larger beta-MHC gene expression in the longest than in the shorter promoter fragments in normal control animals, implying the existence of an upstream enhancer. A mutation in the putative thyroid response element of the -408-bp beta-MHC promoter construct caused transcriptional activity to drop to null. When studied in the -3, 500-bp beta-MHC promoter, construct activity was reduced ( approximately 100-fold) while thyroid hormone responsiveness was retained. These findings suggest that, even though the bulk of the thyroid hormone responsiveness of the gene is contained within the first 215 bp of the beta-MHC promoter sequence, the exact mechanism of triiodothyronine (T3) action remains to be elucidated.

Effects of diabetes on rodent cardiac thyroid hormone receptor and isomyosin expression.

Previous studies show that diabetes induces marked transformations in cardiac myosin heavy chain (MHC) gene expression that are somehow linked to the cellular action of thyroid hormone 3,5,3'-triiodothyronine (T3). In this study, we tested the hypothesis that diabetes induces a reduced expression of thyroid hormone receptors (TRs), which are known to be important transcription factors interacting with thyroid response elements (TREs) in the promoter region of both alpha- and beta-MHC genes. Adult female rats were randomly assigned to either a normal control (NC) or diabetic (D) group. Three and/or six weeks after induction of diabetes via streptozotocin injection, the hearts of the animals were analyzed for MHC and TR mRNA isoforms expression, nuclear T3 binding, and nuclear extract interaction with a palindromic TRE. Results showed that diabetes induced significant alteration in alpha- and beta-MHC expression. Northern blot analyses indicated no diabetes-associated differences in TR isoform mRNA signals. Cardiac nuclear T3 binding studies suggested no differences in either the binding capacity or the equilibrium binding constant among the two groups, indicating no changes in either the number of nuclear TRs or their affinity for T3. Furthermore, gel mobility shift assays detected no difference between NC and D groups for cardiac nuclear extract binding to palindromic TRE. Collectively, these findings suggest that, whereas diabetes exerts a profound effect on cardiac isomyosin gene expression, the underlying mechanism, although dependent on factors linked to T3 function, does not involve alterations in TR expression.

Role of thyroid hormone and insulin in control of cardiac isomyosin expression.

Previous studies show that both diabetes and thyroid state exert a strong regulatory influence on the pattern of rodent cardiac isomyosin expression. Therefore, we determined the separate and combined effects of thyroid hormone (T3) and insulin treatment on rodent cardiac myosin heavy chain (MHC) expression using a model of combined thyroid deficiency (Tx) and diabetes (D). The combination of Tx and D completely transformed cardiac isomyosin expression such that the fast alpha-myosin heavy chain (MHC) was completely repressed at both the protein and mRNA level of expression; whereas, the slow beta-MHC was upregulated to constitute 100% of the total MHC pool, based on both protein and mRNA analyses. Daily low doses of exogenous T3 treatment (3 micrograms/kg b.w. i.p.). in the absence of insulin treatment, partially restored expression of the alpha-MHC, while inhibiting expression of the beta-isoform. In contrast daily insulin treatment (4 U/rat), in the absence of exogenous T3 treatment, failed to exert any significant influence on the pattern of isomyosin expression in the thyroid-deficient diabetic rat model. Furthermore, when exogenous T3 was administered in conjunction with insulin, the effect on MHC mRNA expression was greater than that of T3 alone, thus suggesting the existence of interaction between T3 and insulin action in the regulation of MHC mRNA expression. Collectively, these findings suggest that: (a) thyroid state is a dominant regulator of cardiac isomyosin phenotype: and (b) insulin does not exert any regulatory influence on cardiac MHC expression in a severe thyroid deficient state, instead it requires a critical level of circulating T3 in order to be effective in blunting MHC transformation associated with diabetes. It is thus concluded that the regulation of cardiac MHC by insulin is a complex mechanism involving interaction of insulin with subcellular factors likely to have impact on the specific action of T3. This interaction is disrupted in the absence of sufficient thyroid hormone.

Running performance and cardiovascular capacity are not impaired in creatine-depleted rats.

Several published reports have indicated that derangement of the phosphocreatine/creatine (Cr) energy-buffering system via Cr analogue feeding results in cardiomyopathy when cardiac performance is assessed in vitro. The present study was designed to examine indexes of cardiac performance in rats that have been chronically Cr depleted. Adult (180 +/- 4 g) rats were assigned to a normal diet (ND) (n = 8) or a Cr-depletion diet (CD) group (n = 10). After 61 +/- 1 days of ad libitum feeding, measurements of steady-state exercise O2 consumption were made. Hemodynamic indexes were then assessed during incremental running to peak sustained levels. Rats were then killed and the left ventricle was excised. In the CD group Cr was depleted 82% and V1 isomyosin decreased while V2 increased. O2 consumption during steady-state running was not different in CD rats. The respiratory exchange ratios of CD rats reflected a bias toward fat utilization during the latter stages of prolonged exercise. The exercise heart rates and peak systolic blood pressures of CD rats were slightly lower than those of ND rats. Both negative and positive rates of left ventricular pressure development were significantly reduced at all running speeds in the CD rats. CD rats were capable of exercise performance equal to that of ND animals. The hemodynamic and metabolic data suggest that the adaptations seen in the CD animals may be similar to those reported after endurance training. These results indicate that chronic Cr depletion does not impair either the circulatory or exercise capacity of rodents.

Pressure-induced regulation of myosin expression in rodent heart.

A study was undertaken to determine how variations in chronic pressure overload imposed on the left ventricle (LV) regulate both its mass and the relative level of expression of the slow beta-myosin heavy chain (MHC) in rodents. Systemic mean arterial pressure was varied by the following interventions: 1) abdominal aortic constriction (AbCon), 2) unilateral nephrectomy coupled with salt and deoxycorticoacetate treatment (Nx-D), and 3) treatment with the angiotensin II-converting enzyme inhibitor captopril (50 mg.kg-1.day-1) in combination with the other interventions. Results showed that both AbCon and Nx-D induced significant elevations in both beta-MHC protein and mRNA expression relative to the control state. beta-MHC expression (protein and mRNA) strongly correlated with blood pressure as well as LV mass over a wide range. Although captopril treatment significantly reversed the elevations in mean arterial pressure, LV mass, and beta-MHC content in the AbCon group, it had very little effect on these variables in the Nx-D group. Collectively, the results demonstrate that the expression of beta-MHC in the rodent heart is strongly dependent on the arterial pressure imposed on LV. Although the underlying mechanisms have not been elucidated fully as to how alterations in blood pressure are translated to the regulation of the beta-MHC gene expression, these findings suggest that the renin-angiotensin system is not an obligatory factor for inducing cardiac hypertrophy or beta-MHC expression in some models of hypertension.

Food restriction-induced transformations in cardiac functional and biochemical properties in rats.

The primary objective of this study was to ascertain if various degrees of marked chronic food restriction (FR) as well as the combination of FR and exercise training of moderate intensity induce changes in the functional properties of the heart that are consistent with previously reported findings indicative of downregulation of high-adenosinetriphosphatase V1 isomyosin expression. Adult female rodents were randomly assigned to one of four experimental groups: 1) free eating, 2) 50% food restricted, 3) 75% food restricted, or 4) 50% food restricted plus treadmill trained. Results show that FR induced significant depression in the functional properties (heart rate, left ventricular pressure, rate of pressure development, and double product) of the heart in all FR groups and that this depression in functional capacity corresponded to the degree of FR. These functional changes were accompanied by significant downregulation of the alpha- and upregulation of the beta-myosin heavy chain gene expressions, as studied at both the mRNA and protein levels. The exercise training induced further alterations in cardiac function; however, these alterations occurred independently of any shifts in isomyosin composition. These results suggest that although severe FR is a potent stimulus to transform both the biochemical and functional properties of the rodent heart, the underlying mechanism(s) concerning these adaptations remains unresolved.

Effect of thyroid state on cardiac myosin P-light chain phosphorylation during exercise.

This study ascertained the effects of thyroid deficiency (TD) and hyperthyroidism (H) on in vivo cardiovascular functional capacity in the context of cardiac myosin light chain 2 phosphorylation [P-LC(P)], a proposed modulator of myocardial function, at rest and during exercise. Compared with normal controls (NC), Ca2(+)-regulated myofibril adenosinetriphosphatase was reduced by 39% in TD and increased by 9% in H rats. This response was associated with a 20-fold increase in the V3 isoform and an 11% increase in the V1 isoform in TD and H rats, respectively. Submaximal treadmill exercise elicited significant elevations in all myocardial functional indexes examined in H rats compared with the NC group, whereas the opposite occurred for the TD group. Despite the marked contrast in cardiac function among the three groups, intrinsic levels of P-LC(P) were similar at rest among the groups and were significantly reduced in both TD and H groups relative to controls during exercise. These data suggest that although thyroid state exerts a profound impact on intrinsic myocardial functional state, it exerts little control over cellular processes regulating P-LC(P) during rest and exercise.

Left ventricular functional capacity in the endurance-trained rodent.

Cardiac myosin P-light chain phosphorylation [P-LC(P)] has been proposed to augment myocardial force production. This study was undertaken to examine the potential for cardiac myosin P-LC(P) for both equivalent heart rate and work load in exercising endurance-trained and nontrained rodents. A 10-wk training protocol elicited a significant reduction in submaximal running O2 uptake while enhancing peak O2 uptake (-17 and 10%, respectively, P less than 0.05). Left ventricular functional index during submaximal exercise, obtained with a high-fidelity Millar ultraminiature pressure transducer, indicated that the trained animals were able to maintain peak left ventricular pressure (LVP) in comparison to their sedentary counterparts, even though both heart rate and rate of LVP development were significantly reduced (P less than 0.05). When expressed on the basis of equivalent submaximal heart rate, peak LVP was augmented in the trained animals. Cardiac myosin P-LC(P) was examined under two conditions known to produce disparate responses in trained vs. sedentary animals. For an equivalent work load, we observed parallel increases in P-LC(P) (20%) and systolic pressure (17%) in both groups, even though the trained animals exhibited significantly lower heart rates (P less than 0.05). For an equivalent heart rate, training evoked a significant increase in systolic pressure (26%, P less than 0.05) and caused a slight increase in P-LC(P) relative to the nontrained controls. Cardiac myosin adenosinetriphosphatase was reduced approximately 10% in the trained animals (P less than 0.05), commensurate with a 2.0-fold increase in the V3 (low adenosinetriphosphatase) isomyosin.(ABSTRACT TRUNCATED AT 250 WORDS)

Myocardial functional correlates of cardiac myosin light chain 2 phosphorylation.

In vitro and in situ studies have proposed a potentiation of submaximal force production after myosin light chain 2 (P-light chain) phosphorylation in mammalian striated muscle. The purpose of this study was to ascertain the relationship between the augmentation in left ventricular pressure development and cardiac myosin P-light chain phosphorylation at different times during and after submaximal treadmill exercise involving adult female Sprague-Dawley rats. In vivo hemodynamic measurements were monitored with an indwelling high-fidelity solid-state pressure transducer. Exercise heart rate, peak left ventricular (LV) pressure, and rate of LV pressure development/relaxation (LV +/- dP/dt) were significantly elevated compared with a normal sedentary group (P less than 0.001). Peak LV pressure remained significantly elevated throughout 20 min of postexercise recovery (P less than 0.01), and heart rate, LV end-diastolic pressure, and LV +/- dP/dt returned rapidly to preexercise values. Corresponding to these in vivo hemodynamic changes, increased levels of P-light chain phosphorylation were observed during both exercise (16%, P less than 0.01) and subsequent recovery periods (14%, P less than 0.02) compared with the NC group. A quasi-temporal relationship was observed between postexercise peak LV pressure potentiation and P-light chain phosphorylation. These results demonstrate that cardiac myosin P-light chain phosphorylation is associated, in part, with the augmentation of peak LV pressure observed during both exercise and recovery.

Phosphorylation of rodent cardiac myosin light chain 2: effects of exercise.

The purpose of this study was to ascertain whether the degree of cardiac myosin light chain 2 (P-light chain) phosphorylation occurs as a function of changes in cardiovascular functional state as induced by 1) treadmill exercise (20-27 m/min, 0% grade for 20, 30, 45 min) (phase I) and 2) pharmacological intervention (phase II) in adult female Sprague-Dawley rats. It was hypothesized that cardiac myosin phosphorylation is regulated in accordance with time-dependent sustained elevations in myocardial work demands requiring alterations in either heart rate or left ventricular pressure development. Exercise heart rates (HR) and double products (HR x DP) were equivalent among the three exercise groups and were significantly elevated in comparison with the normal-rest (NR) group (P less than 0.05). In phase II, isoproterenol elicited higher HR, although the atenolol group exhibited a marked reduction in HR, mean arterial pressure, and double product relative to NR (P less than 0.05). Percent myosin P-light chain phosphorylation exhibited both a HR- and a work load-dependent modulation in P-light chain levels (-9% to +23% change) in the two phases of the study (P less than 0.05). These data are consistent with the view that the above responses are associated with modulations in intracellular calcium concentrations commensurate with the alterations in HR and left ventricular pressure. Also, elevations in P-light chain phosphorylation could serve to augment left ventricular pressure development under these functional states.