Subsarcolemmal and intermyofibrillar mitochondria play distinct roles in regulating skeletal muscle fatty acid metabolism

Skeletal muscle contains two populations of mitochondria that appear to be differentially affected by disease and exercise training. It remains unclear how these mitochondrial subpopulations contribute to fiber type-related and/or training-induced changes in fatty acid oxidation and regulation of carnitine palmitoyltransferase-1 (CPT1), the enzyme that controls mitochondrial fatty acid uptake in skeletal muscle. To this end, we found that fatty acid oxidation rates were 8.9-fold higher in subsarcolemmal mitochondria (SS) and 5.3-fold higher in intermyofibrillar mitochondria (IMF) that were isolated from red gastrocnemius (RG) compared with white gastrocnemius (WG) muscle, respectively. Malonyl-CoA (10 µM), a potent inhibitor of CPT1, completely abolished fatty acid oxidation in SS and IMF mitochondria from WG, whereas oxidation rates in the corresponding fractions from RG were inhibited only 89% and 60%, respectively. Endurance training also elicited mitochondrial adaptations that resulted in enhanced fatty acid oxidation capacity. Ten weeks of treadmill running differentially increased palmitate oxidation rates 100% and 46% in SS and IMF mitochondria, respectively. In SS mitochondria, elevated fatty acid oxidation rates were accompanied by a 48% increase in citrate synthase activity but no change in CPT1 activity. Nonlinear regression analyses of mitochondrial fatty acid oxidation rates in the presence of 0–100 µM malonyl-CoA indicated that IC₅₀ values were neither dependent on mitochondrial subpopulation nor affected by exercise training. However, in IMF mitochondria, training reduced the Hill coefficient (P < 0.05), suggesting altered CPT1 kinetics. These results demonstrate that endurance exercise provokes subpopulation-specific changes in mitochondrial function that are characterized by enhanced fatty acid oxidation and modified CPT1-malonyl-CoA dynamics. endurance exercise training; CPT-1; fiber type; rat; mitochondrial subpopulations     

Mitochondrial Ca2+-induced K+ influx increases respiration and enhances ROS production while maintaining membrane potential

We recently demonstrated a role for altered mitochondrial bioenergetics and reactive oxygen species (ROS) production in mitochondrial Ca²⁺-sensitive K⁺ (mtK_Ca) channel opening-induced preconditioning in isolated hearts. However, the underlying mitochondrial mechanism by which mtK_Ca channel opening causes ROS production to trigger preconditioning is unknown. We hypothesized that submaximal mitochondrial K⁺ influx causes ROS production as a result of enhanced electron flow at a fully charged membrane potential (_m). To test this hypothesis, we measured effects of NS-1619, a putative mtK_Ca channel opener, and valinomycin, a K⁺ ionophore, on mitochondrial respiration, _m, and ROS generation in guinea pig heart mitochondria. NS-1619 (30 µM) increased state 2 and 4 respiration by 5.2 ± 0.9 and 7.3 ± 0.9 nmol O₂·min^–1·mg protein^–1, respectively, with the NADH-linked substrate pyruvate and by 7.5 ± 1.4 and 11.6 ± 2.9 nmol O₂·min^–1·mg protein^–1, respectively, with the FADH₂-linked substrate succinate (+ rotenone); these effects were abolished by the mtK_Ca channel blocker paxilline. _m was not decreased by 10–30 µM NS-1619 with either substrate, but H₂O₂ release was increased by 44.8% (65.9 ± 2.7% by 30 µM NS-1619 vs. 21.1 ± 3.8% for time controls) with succinate + rotenone. In contrast, NS-1619 did not increase H₂O₂ release with pyruvate. Similar results were found for lower concentrations of valinomycin. The increase in ROS production in succinate + rotenone-supported mitochondria resulted from a fully maintained _m, despite increased respiration, a condition that is capable of allowing increased electron leak. We propose that mild matrix K⁺ influx during states 2 and 4 increases mitochondrial respiration while maintaining _m; this allows singlet electron uptake by O₂ and ROS generation. mitochondrial bioenergetics; heart mitochondria     

Coordinate downregulation of CaM kinase II and phospholamban accompanies contractile phenotype transition in the hyperthyroid rabbit soleus

This study investigated the effects of L-thyroxine-induced hyperthyroidism on Ca²⁺/calmodulin (CaM)-dependent protein kinase (CaM kinase II)-mediated sarcoplasmic reticulum (SR) protein phosphorylation, SR Ca²⁺ pump (Ca²⁺-ATPase) activity, and contraction duration in slow-twitch soleus muscle of the rabbit. Phosphorylation of Ca²⁺-ATPase and phospholamban (PLN) by endogenous CaM kinase II was found to be significantly lower (30–50%) in soleus of the hyperthyroid compared with euthyroid rabbit. Western blotting analysis revealed higher levels of sarco(endo)plasmic reticulum Ca²⁺-ATPase (SERCA) 1 (150%) Ca²⁺ pump isoform, unaltered levels of SERCA2 Ca²⁺ pump isoform, and lower levels of PLN (50%) and -, -, and -CaM kinase II (40 70%) in soleus of the hyperthyroid rabbit. SR vesicles from hyperthyroid rabbit soleus displayed approximately twofold higher ATP-energized Ca²⁺ uptake and Ca²⁺-stimulated ATPase activities compared with that from euthyroid control. The V_max of Ca²⁺ uptake (in nmol Ca²⁺·mg SR protein^–1·min^–1: euthyroid, 818 ± 73; hyperthyroid, 1,649 ± 90) but not the apparent affinity of the Ca²⁺-ATPase for Ca²⁺ (euthyroid, 0.97 ± 0.02 µM, hyperthyroid, 1.09 ± 0.04 µM) differed significantly between the two groups. CaM kinase II-mediated stimulation of Ca²⁺ uptake by soleus muscle SR was 60% lower in the hyperthyroid compared with euthyroid. Isometric twitch force of soleus measured in situ was significantly greater (36%), and the time to peak force and relaxation time were significantly lower (30–40%), in the hyperthyroid. These results demonstrate that thyroid hormone-induced transition in contractile properties of the rabbit soleus is associated with coordinate downregulation of the expression and function of PLN and CaM kinase II and selective upregulation of the expression and function of SERCA1, but not SERCA2, isoform of the SR Ca²⁺ pump. calmodulin kinase II; phospholamban ; calcium ion-adenosinetriphosphatase; sarcoplasmic reticulum     

Fasertypen in der Unterschenkelmuskulatur der Maus

Zusammenfassung M. gastrocnemius und M. soleus der Maus enthalten mindestens zweierlei Fasertypen. Im M. gastrocnemius überwiegen dicke Fasern, die im Bereich der I-Bänder liegende, spärlich entwickelte, siebartige Mitochondrienplatten enthalten. Im M. soleus überwiegen dünne Fasern, die ebenfalls im Bereich der I-Bänder liegende, aber kräftig entwickelte rostartige Mitochondrienplatten enthalten. Diese Roste sind durch längsverlaufende Mitochondrienanteile untereinander verbunden, so daß ein zusammenhängendes Mitochondriengerüst vorliegt. Nur in den dünnen Fasern sind Triglyzeridtropfen nachweisbar.Die Unterscheidung der beiden Fasertypen ist nicht nur elektronenmikroskopisch, sondern mit einer empfindlichen Fettfärbung auch lichtmikroskopisch einwandfrei möglich. Mit Hilfe der aus der Literatur bekannten reizphysiologischen Angaben über das Verhalten ganzer Muskeln wird die dicke Faser als schnell, nur mit hoher Reizfrequenz tetanisierbar, aber wenig ausdauernd identifiziert. Die dünne Faser hat dagegen eine geringere Kontraktionsgeschwindigkeit, ist mit geringerer Reizfrequenz tetanisierbar und ausdauernder als die dicke Faser.Da in Fasern von Wirbeltiermuskeln Differenzierungen nach Stoffwechselform, Erregbarkeit, Kontraktionsablauf und Kraftentfaltung vorliegen, denen jeweils auch morphologische Merkmale zukommen, reichen bisher übliche Unterteilungen in schnelle und langsame, dicke und dünne, fibrilläre und gefelderte, weiße und rote Fasern, durch die nur jeweils ein Merkmalspaar beschrieben wird, zur genauen Kennzeichnung der Fasern nicht aus.

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Summary Gastrocnemius and soleus muscles of mouse contain at least two types of fibers. In m. gastrocnemius prevail thick fibers, which contain poorly developed mitochondrial nets at the level of the I-band. In m. soleus there are mostly thin fibers, which contain grid-like well developed mitochondria in the same position. The mitochondrial grids of the thin fiber are joined by longitudinal mitochondria, which together with the grids form a continuous three-dimensional mitochondrial frame-work. Only in the thin fibers droplets of triglycerids are to be found.The distinction of the two types of fibers is also possible by light microscopy using a sensitive fat staining method. Electrophysiological information on the reactions of total m. gastrocnemius and m. soleus allow to identify the thick fiber to be fast, to be tetanized only by high frequency of stimulation and to be easily fatigued. In contrast the thin fiber is slow, can be tetanized by low frequency and is more easily fatigued than the thick one.Since in muscle special morphological properties correspond with form of metabolism, excitability, type of contraction and tension output, the differentiations of fast or slow, thick or thin, fibrillär or gefeldert, white or red muscle fibers are insufficient, since each describes only one pair of characteristics.

     

Mitochondrial subpopulations and heterogeneity revealed by confocal imaging: possible physiological role?

Heterogeneity of mitochondria has been reported for a number of various cell types. Distinct mitochondrial subpopulations may be present in the cell and may be differently involved in physiological and pathological processes. However, the origin and physiological roles of mitochondrial heterogeneity are still unknown. In mice skeletal muscle, a much higher oxidized state of subsarcolemmal mitochondria as compared with intermyofibrillar mitochondria has been demonstrated. Using confocal imaging technique, we present similar phenomenon for rat soleus and gastrocnemius muscles, where higher oxidative state of mitochondrial flavoproteins correlates also with elevated mitochondrial calcium. Moreover, subsarcolemmal mitochondria demonstrate distinct arrangement and organization. In HL-1 cardiomyocytes, long thread mitochondria and small grain mitochondria are observed irrespective of a particular cellular region, showing also heterogeneous membrane potential and ROS production. Possible physiological roles of intracellular mitochondrial heterogeneity and specializations are discussed.     

Effect of clenbuterol on sarcoplasmic reticulum function in single skinned mammalian skeletal muscle fibers

We examined the effect of the₂-agonist clenbuterol (50 µM)on depolarization-induced force responses and sarcoplasmic reticulum (SR) function in muscle fibers of the rat (Rattusnorvegicus; killed by halothane overdose) that had beenmechanically skinned, rendering the₂-agonist pathway inoperable.Clenbuterol decreased the peak of depolarization-induced forceresponses in the extensor digitorum longus (EDL) and soleus fibers to77.2 ± 9.0 and 55.6 ± 5.4%, respectively, ofcontrols. The soleus fibers did not recover. Clenbuterol significantlyand reversibly reduced SR Ca²⁺loading in EDL and soleus fibers to 81.5 ± 2.8 and 78.7 ± 4.0%, respectively, of controls. Clenbuterol also producedan ~25% increase in passive leak ofCa²⁺ from the SR of the EDL andsoleus fibers. These results indicate that clenbuterol has directeffects on fast- and slow-twitch skeletal muscle, in the absence of the₂-agonist pathway. Theincreased Ca²⁺ leak in the triadregion may lead to excitation-contraction coupling damage in the soleusfibers and could also contribute to the anabolic effect of clenbuterolin vivo.

     

Troglitazone and pioglitazone interactions via PPAR-gamma-independent and -dependent pathways in regulating physiological responses in renal tubule-derived cell lines

Troglitazone (Tro) and pioglitazone (Pio) activation of peroxisome proliferator-activated receptor (PPAR)- and PPAR--independent pathways was studied in cell lines derived from porcine renal tubules. PPAR--dependent activation of PPAR response element-driven luciferase gene expression was observed with Pio at 1 µM but not Tro at 1 µM. On the other hand, PPAR--independent P-ERK activation was observed with 5 µM Tro but not with Pio (5–20 µM). In addition, Pio (1–10 µM) increased metabolic acid production and activated AMP-activated protein kinase (AMPK) associated with decreased mitochondrial membrane potential, whereas Tro (1–20 µM) did not. These results are consistent with three pathways through which glitazones may act in effecting metabolic processes (ammoniagenesis and gluconeogenesis) as well as cellular growth: 1) PPAR--dependent and PPAR--independent pathways, 2) P-ERK activation, and 3) mitochondrial AMPK activation. The pathways influence cellular acidosis and glucose and glutamine metabolism in a manner favoring reduced plasma glucose in vivo. In addition, significant interactions can be demonstrated that enhance some physiological processes (ammoniagenesis) and suppress others (ligand-mediated PPAR- gene expression). Our findings provide a model both for understanding seemingly opposite biological effects and for enhancing therapeutic potency of these agents. peroxisome proliferator-activated receptor-; phospho-extracellular signal-regulated kinase; intracellular pH; Na⁺/H⁺ exchanger; AMP-activated protein kinase; mitochondria     

Type II skeletal myofibers possess unique properties that potentiate mitochondrial H(2)O(2) generation

Mitochondrial dysfunction is implicated in a number of skeletal muscle pathologies, most notably aging-induced atrophy and loss of type II myofibers. Although oxygen-derived free radicals are thought to be a primary cause of mitochondrial dysfunction, the underlying factors governing mitochondrial superoxide production in different skeletal myofiber types is unknown. Using a novel in situ approach to measure H₂O₂ production (indicator of superoxide formation) in permeabilized rat skeletal muscle fiber bundles, we found that mitochondrial free radical leak (H₂O₂ produced/O₂ consumed) is two- to threefold higher (P < 0.05) in white (WG, primarily type IIB fibers) than in red (RG, type IIA) gastrocnemius or soleus (type I) myofibers during basal respiration supported by complex I (pyruvate + malate) or complex II (succinate) substrates. In the presence of respiratory inhibitors, maximal rates of superoxide produced at both complex I and complex III are markedly higher in RG and WG than in soleus muscle despite 50% less mitochondrial content in WG myofibers. Duplicate experiments conducted with ±exogenous superoxide dismutase revealed striking differences in the topology and/or dismutation of superoxide in WG vs. soleus and RG muscle. When normalized for mitochondrial content, overall H₂O₂ scavenging capacity is lower in RG and WG fibers, whereas glutathione peroxidase activity, which is largely responsible for H₂O₂ removal in mitochondria, is similar in all three muscle types. These findings suggest that type II myofibers, particularly type IIB, possess unique properties that potentiate mitochondrial superoxide production and/or release, providing a potential mechanism for the heterogeneous development of mitochondrial dysfunction in skeletal muscle. superoxide; reactive oxygen species; skeletal muscle; respiration; fiber type     

Ca2+ influx through alpha1S DHPR may play a role in regulating Ca2+ release from RyR1 in skeletal muscle

Skeletal muscle fiber types differ in their contents of total phosphate, which includes inorganic phosphate (P_i) and high-energy organic pools of ATP and phosphocreatine (PCr). At steady state, uptake of P_i into the cell must equal the rate of efflux, which is expected to be a function of intracellular P_i concentration. We measured ³²P-labeled P_i uptake rates in different muscle fiber types to determine whether they are proportional to cellular P_i content. P_i uptake rates in isolated, perfused rat hindlimb muscles were linear over time and highest in soleus (2.42 ± 0.17 µmol·g^–1·h^–1), lower in red gastrocnemius (1.31 ± 0.11 µmol·g^–1·h^–1), and lowest in white gastrocnemius (0.49 ± 0.06 µmol·g^–1·h^–1). Reasonably similar rates were obtained in vivo. P_i uptake rates at plasma P_i concentrations of 0.3–1.7 mM confirm that the P_i uptake process is nearly saturated at normal plasma P_i levels. P_i uptake rate correlated with cellular P_i content (r = 0.99) but varied inversely with total phosphate content. Sodium-phosphate cotransporter (PiT-1) protein expression in soleus and red gastrocnemius were similar to each other and seven- to eightfold greater than PiT-1 expression in white gastrocnemius. That the PiT-1 expression pattern did not match the pattern of P_i uptake across fiber types implies that other factors are involved in regulating P_i uptake in skeletal muscle. Furthermore, fractional turnover of the cellular P_i pool (0.67, 0.57, and 0.33 h^–1 in soleus, red gastrocnemius, and white gastrocnemius, respectively) varies among fiber types, indicating differential management of intracellular P_i, likely due to differences in resistance to P_i efflux from the fiber. inorganic phosphate; sodium-inorganic phosphate transporters; PiT-2; inorganic phosphate efflux     

Human cytomegalovirus-induced host cell enlargement is iron dependent

A hallmark of human cytomegalovirus (HCMV) infection is the characteristic enlargement of the host cells (i.e., cytomegaly). Because iron (Fe) is required for cell growth and Fe chelators inhibit viral replication, we investigated the effects of HCMV infection on Fe homeostasis in MRC-5 fibroblasts. Using the metallosensitive fluorophore calcein and the Fe chelator salicylaldehyde isonicotinoyl hydrazone (SIH), the labile iron pool (LIP) in mock-infected cells was determined to be 1.04 ± 0.05 µM. Twenty-four hours postinfection (hpi), the size of the LIP had nearly doubled. Because cytomegaly occurs between 24 and 96 hpi, access to this larger LIP could be expected to facilitate enlargement to 375% of the initial cell size. The ability of Fe chelation by 100 µM SIH to limit enlargement to 180% confirms that the LIP plays a major role in cytomegaly. The effect of SIH chelation on the mitochondrial membrane potential (_M) and morphology was studied using the mitochondrial voltage-sensitive dye JC-1. The mitochondria in mock-infected cells were heterogeneous with a broad distribution of _M and were threadlike. In contrast, the mitochondria of HCMV-infected cells had a more depolarized _M distributed over a narrow range and were grainlike in appearance. However, the HCMV-induced alteration in _M was not affected by SIH chelation. We conclude that the development of cytomegaly is inhibited by Fe chelation and may be facilitated by an HCMV-induced increase in the LIP. cell size; mitochondria     

Palmitate incorporation into lipids pools of contracting red and white muscles

We compared the incorporation of the blood-borne [14C]-palmitate into selected lipid and phospholipid pools in rat muscles (soleus, red and white gastrocnemius), at rest and during contractions (15 and 60 tetani/min) in one leg (5 min) while the contralateral leg served as a control. [1-14C]-palmitate (20 µCi/rat) was administered into the carotid artery (t = 1 min). [14C]-palmitate deposition was greatest in soleus (100%) and lower in red (82%) and white gastrocnemius muscles (63%), respectively (p < 0.05). [14C] was deposited primarily into the tri-acylglycerol (50%) and phospholipid pools (30%) of soleus and red gastrocnemius muscles, and into the di-acylglycerol (30%), tri-acylglycerol (30%) and phospholipid pools (30%) in white gastrocnemius muscle. During contraction the concentrations of tri-acylglycerol were not changed. But, contraction increased [14C]-palmitate incorporation into soleus and red gastrocnemius muscles (600-700%) and into white gastrocnemius muscles (200%). Slightly more [14C] was directed from the phospholipids into the tri-acylglycerol pool during contraction. [14C]-palmitate deposition was also increased in the subclasses of phospholipids during contraction in red and white gastrocnemius. In conclusion, the deposition of [14C]palmitate into different lipid and phospholipid pools is quite rapid, and is dependent on contraction and the muscle fiber type. (Mol Cell Biochem 166: 73-83, 1997)     

Tenotomy decreases reporter protein synthesis via the 3'-untranslated region of the beta-myosin heavy chain mRNA

We tested thehypothesis that the -myosin heavy chain (-MHC) 3'-untranslatedregion (UTR) mediates decreased protein expression after tenotomy ofthe rat soleus. We also tested the hypothesis that decreased proteinexpression is the result of RNA-protein interactions within the 3'-UTR.-MHC was chosen for study because of its critical role in thefunction of postural muscles such as soleus. Adult rat soleus muscleswere directly injected with luciferase (LUC) reporter constructscontaining either the -MHC or SV40 3'-UTR. After 48 h oftenotomy, there was no significant effect on LUC expression in the SV403'-UTR group. In the -MHC 3'-UTR group, LUC expression was 37.3 ± 4% (n = 5, P = 0.03) of that in shamcontrols. Gel mobility shift assays showed that a protein factorspecifically interacts with the -MHC 3'-UTR and that tenotomysignificantly increases the level of this interaction (25 ± 7%,n = 5, P = 0.02). Thus the -MHC3'-UTR is directly involved in decreased protein expression that isprobably due to increased RNA-protein binding within the UTR.

     

Effects of lactic acid and catecholamines on contractility in fast-twitch muscles exposed to hyperkalemia

Intensive exercise is associated with a pronounced increase in extracellular K⁺ ([K⁺]_o). Because of the ensuing depolarization and loss of excitability, this contributes to muscle fatigue. Intensive exercise also increases the level of circulating catecholamines and lactic acid, which both have been shown to alleviate the depressing effect of hyperkalemia in slow-twitch muscles. Because of their larger exercise-induced loss of K⁺, fast-twitch muscles are more prone to fatigue caused by increased [K⁺]_o than slow-twitch muscles. Fast-twitch muscles also produce more lactic acid. We therefore compared the effects of catecholamines and lactic acid on the maintenance of contractility in rat fast-twitch [extensor digitorum longus (EDL)] and slow-twitch (soleus) muscles. Intact muscles were mounted on force transducers and stimulated electrically to evoke short isometric tetani. Elevated [K⁺]_o (11 and 13 mM) was used to reduce force to 20% of control force at 4 mM K⁺. In EDL, the ₂-agonist salbutamol (10^–5 M) restored tetanic force to 83 ± 2% of control force, whereas in soleus salbutamol restored tetanic force to 93 ± 1%. In both muscles, salbutamol induced hyperpolarization (5–8 mV), reduced intracellular Na⁺ content and increased Na⁺-K⁺ pump activity, leading to an increased K⁺ tolerance. Lactic acid (24 mM) restored force from 22 ± 4% to 58 ± 2% of control force in EDL, an effect that was significantly lower than in soleus muscle. These results amplify and generalize the concept that the exercise-induced acidification and increase in plasma catecholamines counterbalance fatigue arising from rundown of Na⁺ and K⁺ gradients. muscle fatigue; Na⁺-K⁺ pump; membrane potential     

Streptozotocin induces G2 arrest in skeletal muscle myoblasts and impairs muscle growth in vivo

Streptozotocin (STZ) is used extensively to induce pancreatic -cell death and ultimately diabetes mellitus in animal models. However, the direct effects of STZ on muscle are largely unknown. To delineate the effects of STZ from the effects of hypoinsulinemia/hyperglycemia, we injected young rats with 1) saline (control), 2) STZ (120 mg/kg) or 3) STZ and insulin (STZ-INS; to maintain euglycemia). STZ rats demonstrated significantly elevated blood glucose throughout the 48-h protocol, while control and STZ-INS rats were euglycemic. Body mass increased in control (13 ± 4 g), decreased by 19 ± 2 g in STZ and remained unchanged in STZ-INS rats (–0.3 ± 2 g). Cross-sectional areas of gastrocnemius muscle fibers were smaller in STZ vs. control (1,480 ± 149 vs. 1,870 ± 40 µm², respectively; P < 0.05) and insulin treatment did not rescue this defect (STZ-INS: 1,476 ± 143 µm²). Western blot analysis revealed a detectable increase in ubiquitinated proteins in the STZ skeletal muscles compared with control and STZ-INS. To further define the effects of STZ on skeletal muscle, independent of hyperglycemia, myoblasts were exposed to varying doses of STZ (0.25–3.0mg/ml) in vitro. Both acute and chronic exposures of STZ significantly impaired proliferative capacity in a dose-dependent manner. Within STZ-treated myoblasts, increased reactive oxygen species was associated with significant G₂/M phase cell-cycle arrest. Taken together, our findings show that the effects of STZ are not -cell specific and reveal that STZ should not be used for studies examining diabetic myopathy. satellite cell; diabetes; diabetic model; type 1 diabetes mellitus; cell cycle; proliferation; hypertrophy     

Cytoplasm-to-myonucleus ratios and succinate dehydrogenase activities in adult rat slow and fast muscle fibers

The relationship between myonuclear number, cellular size, succinate dehydrogenase activity, and myosin type was examined in single fiber segments (n = 54; 9 ± 3 mm long) mechanically dissected from soleus and plantaris muscles of adult rats. One end of each fiber segment was stained for DNA before quantitative photometric analysis of succinate dehydrogenase activity; the other end was double immunolabelled with fast and slow myosin heavy chain monoclonal antibodies. Mean ± S.D. cytoplasmic volume/myonucleus ratio was higher in fast and slow plantaris fibers (112 ± 69 vs. 34 ± 21 x 10 ³µm ³) than fast and slow soleus fibers (40 ± 20 vs. 30 ± 14 x 10 ³µm ³), respectively. Slow fibers always had small volumes/myonucleus, regardless of fiber diameter, succinate dehydrogenase activity, or muscle of origin. In contrast, smaller diameter (<70 µm) fast soleus and plantaris fibers with high succinate dehydrogenase activity appeared to have low volumes/myonucleus while larger diameter (>70 µm) fast fibers with low succinate dehydrogenase activity always had large volume/myonucleus. Slow soleus fibers had significantly greater numbers of myonuclei/mm than did either fast soleus or fast plantaris fibers (116 ± 51 vs. 55 ± 22 and 44 ± 23), respectively. These data suggest that the myonuclear domain is more limited in slow than fast fibers and in the fibers with a high, compared to a low, oxidative metabolic capability.     

Rabbit conjunctival epithelium transports fluid, and P2Y22 receptor agonists stimulate Cl{-} and fluid secretion

Rabbit conjunctival epithelium exhibits UTP-dependentCl secretion into the tears. We investigated whetherfluid secretion also takes place. Short-circuit current(I_sc) was 14.9 ± 1.4 µA/cm²(n = 16). Four P2Y₂ purinergic receptoragonists [UTP and the novel compounds INS365, INS306, and INS440(Inspire Pharmaceuticals)] added apically (10 µM) resulted intemporary (~30 min) I_sc increases (88%, 66%,57%, and 28%, respectively; n = 4 each). Importantly, the conjunctiva transported fluid from serosa to mucosa at a rate of6.5 ± 0.7 µl · h¹ · cm² (range2.1-15.3, n = 20). Fluid transport was stimulatedby mucosal additions of 10 µM: 1) UTP, from 7.4 ± 2.3 to 10.7 ± 3.3 µl · h¹ · cm²,n = 5; and 2) INS365, from 6.3 ± 1.0 to 9.8 ± 2.5 µl · h¹ · cm²,n = 5. Fluid transport was abolished by 1 mMouabain (n = 5) and was drastically inhibited by 300 µM quinidine (from 6.4 ± 1.2 to 3.6 ± 1.0 µl · h¹ · cm²,n = 4). We conclude that this epithelium secretes fluidactively and that P2Y₂ agonists stimulate bothCl and fluid secretions.

     

Regulation of dihydropyridine receptor gene expression in mouse skeletal muscles by stretch and disuse

This study examined dihydropyridine receptor (DHPR) gene expression in mouse skeletal muscles during physiological adaptations to disuse. Disuse was produced by three in vivo models—denervation, tenotomy, and immobilization—and DHPR _1s mRNA was measured by quantitative Northern blot. After 14-day simultaneous denervation of the soleus (Sol), tibialis anterior (TA), extensor digitorum longus (EDL), and gastrocnemius (Gastr) muscles by sciatic nerve section, DHPR mRNA increased preferentially in the Sol and TA (+1.6-fold), whereas it increased in the EDL (+1.6-fold) and TA (+1.8-fold) after selective denervation of these muscles by peroneal nerve section. It declined in all muscles (–1.3- to –2.6-fold) after 14-day tenotomy, which preserves nerve input but removes mechanical tension. Atrophy was comparable in denervated and tenotomized muscles. These results suggest that factor(s) in addition to inactivity per se, muscle phenotype, or associated atrophy can regulate DHPR gene expression. To test the contribution of passive tension to this regulation, we subjected the same muscles to disuse by limb immobilization in a maximally dorsiflexed position. DHPR _1s mRNA increased in the stretched muscles (Sol, +2.3-fold; Gastr, +1.5-fold) and decreased in the shortened muscles (TA, –1.4-fold; EDL, –1.3-fold). The effect of stretch was confirmed in vitro. DHPR protein did not change significantly after 4-day immobilization, suggesting that additional levels of regulation may exist. These results demonstrate that DHPR _1s gene expression is regulated as an integral part of the adaptive response of skeletal muscles to disuse in both slow- and fast-twitch muscles and identify passive tension as an important signal for its regulation in vivo. dihydropyridine receptor mRNA; decreased use; passive tension; denervation; tenotomy; hindlimb immobilization     

beta -Adrenergic regulation of constitutive nitric oxide synthase in cardiac myocytes

Nitric oxide (NO) has been implicated in endogenous control ofmyocardial contractility. However, NO release has not yet been demonstrated in cardiac myocytes. Accordingly, endogenous NO production was measured with a porphyrinic microsensor positioned on the surfaceof individual neonatal or adult rat ventricular myocytes (n > 6 neonatal and adult cells perexperiment). In beating neonatal myocytes, there was no detectablespontaneous NO release with each contraction. However, norepinephrine(NE; 0.25-1 µM) elicited transient NO release from beatingneonatal (149 ± 11 to 767 ± 83 nM NO) and noncontracting adult(157 ± 13 to 791 ± 89 nM NO) cells. NO was released byadrenergic agonists with the following rank order of potency:isoproterenol(₁₂) > NE (/₁) > dobutamine (₁)  epinephrine(/₁₂) > tertbutylene (₂); NO wasnot released by phenylephrine (). NE-evoked NO release wasreversibly blocked byN^G-monomethyl-L-arginine,trifluoperazine, guanosine5'-O-(2-thiodiphosphate), andnifedipine but was enhanced by 3-isobutyl-1-methylxanthine (0.5 mM = 14.5 ± 1.6%) and BAY K 8644 (10 µM = 11.9 ± 1%). NO wasalso released by A-23187 (10 µM = 884 ± 88 nM NO), guanosine 5'-O-(3-thiotriphosphate) (1 µM = 334 ± 56 nMNO), and dibutyryl adenosine 3',5'-cyclic monophosphate(10-100 µM = 35 ± 9 to 284 ± 49 nM NO) but not by ATP,bradykinin, carbachol, 8-bromoguanosine 3',5'-cyclicmonophosphate, or shear stress. This first functional demonstration ofa constitutive NO synthase in cardiac myocytes suggests its regulationby a -adrenergic signaling pathway and may provide a novel mechanismfor the coronary artery vasodilatation and enhanced diastolicrelaxation observed with adrenergic stimulation.

     

Volume-regulated chloride conductance in the LNCaP human prostate cancer cell line

Patch-clamp recordings were used to study ioncurrents induced by cell swelling caused by hypotonicity in humanprostate cancer epithelial cells, LNCaP. The reversal potential of the swelling-evoked current suggested that Cl was the primarycharge carrier (termed I_Cl,swell). Theselectivity sequence of the underlying volume-regulated anion channels(VRACs) for different anions wasBrI > Cl > F > methanesulfonate glutamate, with relativepermeability numbers of 1.26, 1.20, 1.0, 0.77, 0.49, and 0.036, respectively. The current-voltage patterns of the whole cell currentsas well as single-channel currents showed moderate outwardrectification. Unitary VRAC conductance was determined at 9.6 ± 1.8 pS. Conventional Cl channel blockers5-nitro-2-(3-phenylpropylamino)benzoic acid (100 µM) and DIDS (100 µM) inhibited whole cell I_Cl,swell in a voltage-dependent manner, with the block decreasing from 39.6 ± 9.7% and 71.0 ± 11.0% at +50 mV to 26.2 ± 7.2% and14.5 ± 6.6% at 100 mV, respectively. Verapamil (50 µM), astandard Ca²⁺ antagonist and P-glycoprotein functioninhibitor, depressed the current by a maximum of 15%. Protein tyrosinekinase inhibitors downregulated I_Cl,swell(genistein with an IC₅₀ of 2.6 µM and lavendustin A by60 ± 14% at 1 µM). The protein tyrosine phosphatase inhibitorsodium orthovanadate (500 µM) stimulatedI_Cl,swell by 54 ± 11%. We conclude thatVRACs in human prostate cancer epithelial cells are modulated viaprotein tyrosine phosphorylation.