Calculated free bilirubin levels and neurotoxicity.

Although most bilirubin in the circulation is bound to albumin, a relatively small fraction remains unbound. The concentration of this 'free' bilirubin (B(F)) is believed to dictate the biologic effects of bilirubin in jaundiced newborns, including its neurotoxicity. The threshold at which B(F) produces changes in cellular function culminating in permanent cell injury and cell death has been the subject of considerable debate. The objective of this study was to compare calculated central nervous system (CNS) B(F) levels in Gunn rat pups during (i) peak postnatal hyperbilirubinemia and (ii) sulfadimethoxine-induced acute bilirubin encephalopathy (ABE) previously reported from our laboratory with those predicted in human neonates with peak total serum bilirubin (TSB) levels of 35 mg per 100 ml (599 micromol l(-1)), a clinical cohort that often evidence moderate-to-severe adverse post-icteric neurodevelopmental sequelae. Homozygous j/j Gunn rat pups with neonatal hyperbilirubinemia due to a deficiency of the bilirubin conjugating enzyme uridine-diphosphate-glucuronosyl transferase 1A1 were studied along with non-jaundiced littermate heterozygous J/j controls. Sulfadimethoxine was used to displace bilirubin from albumin in hyperbilirubinemic j/j Gunn rat pups to increase their brain bilirubin content and induce ABE. Calculated Gunn rat CNS B(F) levels were determined as a function of genotype, sulfadimethoxine exposure and albumin-bilirubin binding constant. These data were compared with the human CNS B(F) predicted from the calculated serum B(F) in human neonates with a TSB of 35 mg per 100 ml as a function of albumin-bilirubin binding constant, albumin concentration and the assumption that at this hazardous bilirubin level there may be rapid equilibration of B(F) between serum and brain. There was a large gap between the upper limit of the calculated CNS B(F) 95% confidence interval (CI) range in non-jaundiced J/j pups (for example, 112 nM at k=9.2 l micromol(-1)) and the lower limit seen in the saline-treated hyperbilirubinemic j/j pups (556 nM at k=9.2 l micromol(-1)) as well as between the upper limit in saline-treated hyperbilirubinemic j/j pups (1110 nM at k=9.2 l micromol(-1)) and the lower limit seen in sulfadimethoxine-treated jaundiced j/j littermates (3461 nM at k=9.2 l micromol(-1)). There was considerable overlap and remarkable similarity between the predicted human CNS B(F) values at a TSB of 35 mg per 100 ml for a range of reported human serum bilirubin-albumin binding constants and albumin concentrations, and those calculated for saline-treated hyperbilirubinemic j/j Gunn rat pups. This exercise yielded strikingly similar apparent calculated neurotoxic B(F) levels for Gunn rat pups and human neonates rather than orders of magnitude differences that might have been predicted at the outset and add to a growing literature aimed at defining clinically germane neurotoxic B(F) thresholds.Journal of Perinatology (2009) 29, S14-S19; doi:10.1038/jp.2008.218.

Effect of chronic denervation and denervation-reinnervation on cytoplasmic creatine kinase transcript accumulation.

The extensor digitorum longus (EDL) and soleus muscles of adult mice were chronically denervated or denervated and allowed to reinnervate. Muscles were evaluated 1, 5, 14, 21, and 52 days after sciaticectomy. In terms of weight loss, myofiber atrophy, degeneration, and fibrosis, the soleus muscle was more affected than the EDL by chronic denervation. Fifty-two days after chronic denervation, the number of molecules of MCK/ng total RNA in both muscles (determined with competitive PCR) decreased, with the soleus muscle being more affected. At that stage, BCK mRNA levels in the denervated soleus were unchanged, but they were increased (>50%) in the EDL. Reinnervation restored MCK transcript accumulation in the EDL, whereas, in the soleus MCK, transcripts exceeded control values by 57%, approaching levels in the reinnervated EDL. Despite restoration of MCK mRNA levels, the number of molecules of BCK mRNA/ng total RNA was four- to fivefold higher in reinnervated versus control muscles, suggesting that the genes encoding the CK mRNAs are not coordinately regulated in adult muscle. The role of denervation induced, fiber type changes in regulating CK mRNA accumulation has been evaluated. Electron microscopic analyses have established that fibrosis is not a factor that determines BCK mRNA levels in the chronically denervated or denervated-reinnervated muscles. CK isozyme analyses support the hypothesis that a greater proportion of BCK mRNA found in 52 day chronically denervated and denervated-reinnervated muscles is produced in myofibers vs. nonmuscle cells than in control muscles.

Ontogeny of P-glycoprotein in mouse intestine, liver, and kidney.

BACKGROUND: P-glycoprotein (Pgp) is an ATP-dependent, integral plasma-membrane efflux pump that is constitutively expressed on (i) adult apical brush-border epithelial cells of the intestine, (ii) the bile canalicular face of hepatocytes, and (iii) the brush border epithelium of renal proximal tubules. This Pgp tissue distribution and localization affects the absorption, distribution, metabolism, and excretion of Pgp substrates. Little is known regarding the ontogeny of Pgp expression in these tissues. METHODS: Postnatal expression of Pgp on brush border membranes of small intestine, liver, and kidney as a function of maturity from birth through adulthood was determined using Western immunoblotting and immunohistochemical techniques. Tissue was isolated from FVB mice at four different ages: day of life 0 (D0), day of life 7 (D7), day of life 21 (D21), and adult (Ad). The relative expression of Pgp protein on Western immunoblots was assessed by scanning densitometry and indexed as a percentage (mean+/-SEM) of the adult levels. RESULTS: On Western immunoblots, Pgp expression was limited at birth (19+/-6% of Ad) and increased significantly with maturation in intestine (ANOVA, P<0.005). In contrast, hepatic (113+/-12% of Ad) and renal (96+/-15% of Ad) Pgp expression were at adult levels at birth. The tissue-specific developmental pattern of Pgp expression was confirmed by immunohistochemistry. CONCLUSIONS: We conclude that Pgp is expressed in a tissue-specific and developmentally regulated fashion and speculate that developmental modulation of intestine-Pgp expression may affect the oral bioavailability of Pgp substrates.

P-glycoprotein and bilirubin disposition.

P-glycoprotein (Pgp), an ATP-dependent plasma membrane efflux pump, is expressed in abundance on the luminal aspect of brain capillary endothelial cells and astrocytes of the blood-brain barrier where it limits the passage of a variety of lipophilic substrates into the central nervous system. This review summarizes current evidence characterizing (1) unconjugated bilirubin as a potential substrate for Pgp and (2) the ontogeny of Pgp expression at the blood-brain barrier and apical brush border epithelium of the gastrointestinal tract, findings that may provide insights regarding the disposition of bilirubin in immature subjects.

Enhancement of adult muscle regeneration by primary myoblast transplantation.

Extensor digitorum longus muscles (EDL) of SCID mice were induced to undergo degeneration-regeneration subsequent to orthotopic, whole-muscle transplantation. Two days after transplantation some of these muscles received injections of primary myoblasts derived from EDL muscles of transgenic mice, which express nuclear localizing beta-galactosidase under the control of the myosin light-chain 3F promoter and enhancer. Nine weeks after transplantation, regenerated muscles that received exogenous myoblasts were compared to similarly transplanted muscles that received no further treatment and to unoperated EDL muscles in order to determine the effect of myoblast transfer on muscle regeneration. Many myofibers containing donor derived myonuclei could be identified in the regenerated muscles that had received exogenous myoblasts. The mass of the muscles subjected to transplantation only was significantly less (31% less) than that of unoperated muscles. The addition of exogenous myoblasts to the regenerating EDL resulted in a muscle mass similar to that of unoperated muscles. The absolute twitch and tetanic tensions and specific twitch and tetanic tensions of transplant-only muscles were 28%, 36%, 32%, and 41%, respectively, of those of unoperated muscles. Myoblast transfer increased the absolute twitch and tetanic tensions of the regenerated muscles by 65% and 74%, respectively, and their specific twitch and tetanic tensions were increased by 41% and 48%, respectively. These data suggest a possible role for the addition of exogenous, primary myoblasts in the treatment of traumatized and/or diseased muscles that are characterized by myofiber loss.

Myofibrillar or mitochondrial creatine kinase deficiency alone does not impair mouse diaphragm isotonic function.

Creatine kinase (CK) provides ATP buffering in skeletal muscle and is expressed as 1) cytosolic myofibrillar CK (M-CK) and 2) sarcomeric mitochondrial CK (ScCKmit) isoforms that differ in their subcellular localization. The diaphragm (Dia) expresses both M-CK and ScCKmit in abundance. We compared the power and work output of 1) control CK-sufficient (Ctl), 2) M-CK-deficient [M-CK(-/-)], 3) ScCKmit-deficient [ScCKmit(-/-)], and 4) combined M-CK/ScCKmit-deficient null mutant [CK(-/-)] Dia during repetitive isotonic activations to determine the effect of CK phenotype on Dia function. Maximum power was obtained at approximately 0.4 tetanic force in all groups. M-CK(-/-) and ScCKmit(-/-) Dia were able to sustain power and work output at Ctl levels during repetitive isotonic activation (75 Hz, 330-ms duration repeated each second at 0.4 tetanic force load), and the duration of sustained Dia shortening was 67 +/- 4 s in M-CK(-/-), 60 +/- 4 s in ScCKmit(-/-), and 62 +/- 5 s in Ctl Dia. In contrast, CK(-/-) Dia power and work declined acutely and failed to sustain shortening altogether by 40 +/- 6 s. We conclude that Dia power and work output are not absolutely dependent on the presence of either M-CK or ScCKmit, whereas the complete absence of CK acutely impairs Dia shortening capacity during repetitive activation.

Growth hormone improves body mass recovery with refeeding after chronic undernutrition-induced muscle atrophy in aging male rats.

The effects of growth hormone (GH) administration and refeeding after chronic undernutrition (UN) were investigated in Fischer 344 male rats aging into senescence (24.5 mo of age) during UN initiated at 12.5 mo of age that produced muscle atrophy and a 50% decrease in body mass. Muscle mass, protein, myosin heavy-chain (MHC) composition and circulating testosterone levels were measured and compared to controls with free access to food. Within 9 wk, refeeding + GH restored body mass to control levels, whereas it was still decreased with refeeding alone. By 24.5 mo of age, refeeding alone restored body mass, while addition of GH resulted in overshoot. UN uniformly decreased mass of the gastrocnemius, extensor digitorum longus, soleus and diaphragm muscles to 50-60% of controls. Refeeding and refeeding + GH restored these losses with some overshoot of gastrocnemius muscle suggesting hypertrophy. UN more than doubled slow Type I MHC composition and approximately halved fast Type IIB and IIX MHC in the deep gastrocnemius muscle while it increased Type IIA MHC in the diaphragm. Refeeding and refeeding + GH reversed these shifts. MHC shifts in the extensor digitorum longus and soleus muscles were not statistically significant, whereas UN increased fast Type IIA MHC followed by decrease with refeeding + GH. UN decreased testosterone levels to nearly zero followed by restoration with refeeding and refeeding + GH. We conclude that the phenotype of mixed-MHC muscles such as the gastrocnemius and diaphragm are most affected by chronic UN, which is reversible with refeeding and refeeding + GH. These alterations were associated with changes in circulating testosterone, which may be a key regulatory element in these processes.

Growth hormone restores aged diaphragm myosin composition and performance after chronic undernutrition.

The effects of growth hormone (GH) on diaphragm muscle myosin heavy chain (MHC) composition and mechanical performance were investigated in Fischer 344 male rats aged to senescence (24.5 mo of age). Chronic undernutrition (UN), refeeding (RF), and RF+GH were compared with ad libitum feeding by using a model of UN that produced a 50% decrease in body weight over a 12-mo period. The effect of aging was assessed by comparing MHC composition of ad libitum-fed rats at 12 and 24.5 mo of age. At senescence, significant decreases in slow type I (-23%) and fast type IIA (-31%) MHC had occurred with aging. Conversely, UN over this aging period increased types I (32-73%) and IIA (22-23%) MHC and decreased fast types IIB (32-54%) and IIX (30-31%) MHC. RF and RF+GH reversed these shifts back toward control values. At senescence, maximal specific force, maximal velocity, and specific power capacity were not different across treatment groups. During repetitive isotonic contraction trials, the diaphragms of UN rats maintained power production over time (54% of initial power at 60 s), whereas the power production of diaphragms of ad libitum-fed rats fell to 0% (P < 0.05). In comparison with UN rats, the diaphragms of RF and RF+GH rats produced 23 (not significant) and 11% (P < 0.05) of initial power, respectively, suggesting that RF+GH treatment restored performance characteristics after UN. We conclude that RF+GH can reverse alterations in MHC composition and mechanical performance produced by chronic UN in the aged rat diaphragm.

Leptin attenuates respiratory complications associated with the obese phenotype.

A profile of respiratory complications has been associated with the onset and development of obesity in humans. Similar phenotypes have been routinely demonstrated in genetic animal models of obesity such as the ob mouse (C57BL/6J-Lepob). The objective of the present study was to test the hypothesis that a constellation of respiratory complications are attenuated with leptin (i.e., protein product of the ob gene) replacement. Daily leptin administration during a 6-wk period was conducted to control body weight of mutant ob mice similar to genotypic control groups. During the treatment period, repeated baseline ventilatory measurements were assessed by using whole body plethysmography while quasistatic pressure-volume curves were performed to further explore the role of leptin in improving lung mechanics. Diaphragmatic myosin heavy chain (MHC) isoform phenotype was examined to determine proportional changes in MHC composition. In room air, breathing frequency and minute ventilation were significantly (P < 0.01) different among ob treatment groups, suggesting that leptin opposed the development of a rapid breathing pattern observed in vehicle-treated ob mice. Quasistatic deflation curves indicated that the lung volume of leptin-treated ob mice was significantly (P < 0.05) greater relative to vehicle-treated ob mice at airway pressures between 0 and 30 cmH2O. Diaphragm MHC composition of leptin-treated ob mice was restored significantly (P < 0.05) to resemble the control phenotype. In this genetic mouse model of obesity, the results suggested that respiratory complications associated with the obese phenotype, including rapid breathing pattern at baseline, diminished lung compliance, and abnormal respiratory muscle adaptations, are attenuated with prolonged leptin treatment.

Brain bilirubin content is increased in P-glycoprotein-deficient transgenic null mutant mice.

P-glycoprotein (P-gp), encoded by the mdr1a gene, is an ATP-dependent plasma membrane protein that is expressed in abundance on the blood-brain barrier (BBB). P-gp limits the CNS influx and retention of a variety of lipophilic compounds. We hypothesized that brain bilirubin content after an i.v. bilirubin infusion would be increased in P-gp-deficient mdr1a null mutant transgenic mice (mdr1a(-/-)) compared with controls. Eighteen mdr1a(-/-) null mutant and 18 P-gp-sufficient wild type mice (+/+) were anesthetized and 50 mg/kg bilirubin infused through the tail vein. Brain bilirubin content (mean +/- SEM) 10 min after infusion was significantly higher in mdr1a(-/-) (18.1 +/- 2.4 nmol/g) compared with (+/+) mice (10.4 +/- 1.0 nmol/g). Brain bilirubin content declined 60 min after infusion but remained higher in mdr1a(-/-) (10.3 +/- 1.4 nmol/g) compared with (+/+) mice (5.3 +/- 0.9 nmol/g). Brain bilirubin clearance did not differ between groups (t 1/2 approximately 55 min). We conclude that P-gp-deficient mdr1a(-/-) mice have significantly higher brain bilirubin content compared with controls after an i.v. bilirubin load. These data suggest that 1) bilirubin is a substrate for P-gp and 2) the increased brain bilirubin content in mdr1a(-/-) mice is due to enhanced brain bilirubin influx. We speculate that BBB P-gp provides a protective effect against bilirubin neurotoxicity by reducing brain bilirubin influx.

Refeeding reverses cardiac myosin shifts induced by undernutrition in aged rats: modulation by growth hormone.

Growth hormone (GH) was administered (1 mg/day, i.p., 7.5 months) to male Fischer 344 rats, in conjunction with refeeding (RF) after chronic undernutrition (UN), from middle age (17 months old) to senescence (24.5 months old), during which cardiac myosin heavy chain (MHC) profiles were determined by gel-electrophoresis. At 17 months of age, respective MHC-alpha and -beta composition was 74 and 26% in the right ventricle (RV), and 58 and 42% in the left ventricle (LV), of ad libitum-fed controls. At 24.5 months of age, MHC profiles of controls were shifted toward the MHC-beta isoform in both RV (alpha=53%, beta=47%) and LV (alpha=40%, beta=60%), indicating a significant effect of aging on MHC composition in both ventricles. At 17 months of age, 7.5 months of UN likewise resulted in a shift toward the MHC-beta isoform in both RV (alpha=31%, beta=69%) and LV (alpha=22%, beta=78%) as compared to controls, indicating a significant effect of UN in both ventricles. Continued UN into senescence maintained these altered profiles in both ventricles, at 24.5 months of age (RV: alpha=35%, beta=65%; LV: alpha=24%, beta=76%). RF+GH administered from middle age into senescence restored the MHC composition in both ventricles (RV: alpha=57%, beta=43%; LV: alpha=43%, beta=57%), to that of the controls. RF, alone, likewise reversed ventricular MHC composition toward that of MHC-alpha, but appeared to overcompensate (RV: alpha=67%, beta=33%; LV: alpha=46%, beta=54%), surpassing the control and RF+GH profiles, significantly in the RV. These data suggest that GH is a modulator of restoration of cardiac MHC composition, when RF is administered to counter the effects of chronic UN, in the aging rat heart.

Myosin heavy chain transitions during development. Functional implications for the respiratory musculature.

The myosin heavy chain (MHC) exists as multiple isoforms that are encoded for by a family of genes. The respiratory musculature demonstrates muscle-specific and temporally-dependent changes in MHC isoform expression during maturation. Developmental expression of MHC isoforms correlate well with postnatal changes in actomyosin ATPase activity, specific force generation (P0/CSA), maximum unloaded velocity of shortening (V0) and and fatigue resistance. More specifically, as the expression of MHCneonatal declines and MHC2A, MHC2X, and MHC2B increase, actomyosin ATPase activity, P0/CSA, V0, and muscle fatigability increase. The increase in actomyosin ATPase activity with maturation is partially offset by a postnatal increase in oxidative capacity; however, as fatigue resistance declines with development it is apparent that the energy costs of contraction are not fully matched by an increase in energy production. Developmental transitions in smooth muscle MHC phenotype also occur although their functional importance remains unclear.

Diaphragm myosin heavy chain composition shifts in aging chronically-undernourished Fischer 344 male rats.

The effects of chronic undernutrition (UN) on respiratory muscle were investigated during UN producing a 50% decrease in body weight over a prolonged period (45 weeks) in Fischer 344 male rats. This model focused on progressive, aging-related changes in myosin heavy chain (MHC) profile over time, in which the confounding effects of early development and late senescence were avoided. With aging toward late adulthood (68 weeks), MHC composition of control diaphragms was shifted, with decreased type I (slow) and IIA MHC, and increased type IIB and IIX (fast) MHC. UN produced a divergence of this profile, with an increase in type I and IIA MHC, and decreased type IIX MHC. UN diaphragms in vitro were more resistant to loss of active force with fatigue, during repetitive contractions. However, passive tension rose disproportionately during fatigue, suggesting increased fatigability. We conclude that the observed changes in diaphragm mechanical function are consistent with the UN-induced shifts in MHC composition; however, the elevated passive tension with fatigue suggests additional UN-induced changes in mechanical properties that are possibly detrimental to respiratory muscle function. The UN-dependent divergence in phenotype and mechanical properties may be amplified by aging-related shifts in muscle MHC composition over time, in the control group.

Absence of myofibrillar creatine kinase and diaphragm isometric function during repetitive activation.

Creatine kinase (CK) provides ATP buffering in skeletal muscle and is expressed as 1) cytosolic myofibrillar CK (M-CK) and 2) sarcomeric mitochondrial CK (ScCKmit) isoforms that differ in their subcellular localization. We compared the isometric contractile and fatigue properties of 1) control CK-sufficient (Ctl), 2) M-CK-deficient (M-CK[-/-]), and 3) combined M-CK/ScCKmit-deficient null mutant (CK[-/-]) diaphragm (Dia) to determine the effect of the absence of M-CK activity on Dia performance in vitro. Baseline contractile properties were comparable across groups except for specific force, which was approximately 16% lower in CK[-/-] Dia compared with M-CK[-/-] and Ctl Dia. During repetitive activation (40 Hz, (1)/(3) duty cycle), force declined in all three groups. This decline was significantly greater in CK[-/-] Dia compared with Ctl and M-CK[-/-] Dia. The pattern of force decline did not differ between M-CK[-/-] and Ctl Dia. We conclude that Dia isometric muscle function is not absolutely dependent on the presence of M-CK, whereas the complete absence of CK acutely impairs isometric force generation during repetitive activation.

Rat diaphragm oxidative capacity, antioxidant enzymes, and fatigue: newborn versus adult.

Little is known about the antioxidant capacity and oxidant-generating potential of newborn muscle, or how these properties compare with the adult and relate to fatigue resistance. We determined the 1) antioxidant enzyme activities [superoxide dismutase (SOD), catalase, glutathione peroxidase], 2) glutathione content, 3) oxidative capacity [indexed by succinic dehydrogenase activity], 4) extracellular cytochrome c reduction, and 5) efficacy of exogenously administered SOD in ameliorating fatigue in vitro of newborn and adult diaphragm (DIA). Newborn and adult DIA SOD activities were not different, whereas newborn catalase activity was greater, and newborn glutathione peroxidase activity and glutathione content less than adult DIA. Succinic dehydrogenase activity was approximately 2-fold greater in the adult compared with the neonate. Repetitive contractions led to a significant decline in newborn and adult DIA force; this decline was greater in the adult (78 +/- 4% decrement in force at 2 min) compared with newborn DIA (28 +/- 8% decrement in force at 2 min). Extracellular cytochrome c reduction was greater in adult as compared with newborn DIA during fatiguing contractions. Exogenous SOD attenuated fatigue in the adult, but had no effect on newborn DIA. We conclude that the oxidative capacity of the adult DIA is greater than that of the newborn and not matched by a concomitant increase in SOD activity. Our data suggest that the increased oxidative capacity relative to SOD activity in adult DIA may lead to oxidative stress and an enhanced susceptibility to fatigue.

Combined myofibrillar and mitochondrial creatine kinase deficiency impairs mouse diaphragm isotonic function.

Creatine kinase (CK) is an enzyme central to cellular high-energy phosphate metabolism in muscle. To characterize the physiological role of CK in respiratory muscle during dynamic contractions, we compared the force-velocity relationships, power, and work output characteristics of the diaphragm (Dia) from mice with combined myofibrillar and sarcomeric mitochondrial CK deficiency (CK[-/-]) with CK-sufficient controls (Ctl). Maximum velocity of shortening was significantly lower in CK[-/-] Dia (14.1 +/- 0.9 Lo/s, where Lo is optimal fiber length) compared with Ctl Dia (17.5 +/- 1.1 Lo/s) (P < 0.01). Maximum power was obtained at 0.4-0.5 tetanic force in both groups; absolute maximum power (2,293 +/- 138 W/m2) and work (201 +/- 9 J/m2) were lower in CK[-/-] Dia compared with Ctl Dia (2,744 +/- 146 W/m2 and 284 +/- 26 J/m2, respectively) (P < 0.05). The ability of CK[-/-] Dia to sustain shortening during repetitive isotonic activation (75 Hz, 330-ms duration repeated each second at 0.4 tetanic force load) was markedly impaired, with CK[-/-] Dia power and work declining to zero by 37 +/- 4 s, compared with 61 +/- 5 s in Ctl Dia. We conclude that combined myofibrillar and sarcomeric mitochondrial CK deficiency profoundly impairs Dia power and work output, underscoring the functional importance of CK during dynamic contractions in skeletal muscle.

Creatine kinase activity in rat skeletal muscle relates to myosin phenotype during development.

Creatine kinase (CK) has been implicated in the maintenance of skeletal muscle intracellular energy supply via its ATP buffering capacity. We examined the postnatal expression of CK activity and isoform phenotype in four skeletal muscles [diaphragm (DIA), intercostal (IC), external abdominal oblique (EAO), and the soleus (SOL)] of the rat. Moreover, we correlated CK activity during development with postnatal changes in myosin heavy chain (MHC) phenotype, the latter an index of relative changes in the energetic demands of muscle contractile proteins. CK activity was lowest in the immediate newborn period and increased in all muscles during postnatal development; the highest levels of CK activity were observed in the adult IC and EAO. CK activity did relate to the MHC phenotype as indexed by the ratio of adult MHC isoform content (slow + IIa + IIx + IIb) to developmental MHC isoform content (slow + neonatal; r2 = 0.93, p < 0.001). Stepwise regression revealed that type IIb MHC expression alone accounted for 79% of the developmental variance in CK activity. We conclude that CK activity increases during postnatal development in a muscle specific fashion and relates to the energetic demands of the muscle contractile proteins as reflected by MHC isoform composition. We speculate that the role of CK as an energy buffer is greatest in muscles expressing the IIb MHC isoform.

SDH and actomyosin ATPase activities of different fiber types in rat diaphragm muscle.

In the rat diaphragm muscle, the histochemical classification of type I, IIa, IIb, or IIx fibers was correlated with myosin heavy chain (MHC) immunoreactivity. Expression of MHC isoforms in single dissected fibers was also assessed electrophoretically. Most fibers (approximately 86%) expressed a single MHC isoform, and when present, coexpression of MHC-2X and MHC-2B isoforms was most prevalent. Type I and IIa fibers were the smallest, type IIb fibers were the largest, and type IIx fibers were intermediate. Succinate dehydrogenase (SDH) and calcium-activated myosin adenosinetriphosphatase (actomyosin ATPase) activities were measured with quantitative histochemical procedures. Type I and IIa fibers had the highest SDH activities, followed in rank order by type IIx and IIb fibers. Type I fibers had the lowest actomyosin ATPase activity, followed in rank order by type IIa, IIx, and IIb fibers. Across all fibers, there was an inverse relationship between fiber SDH activity and cross-sectional area and a positive correlation between fiber actomyosin ATPase activity and cross-sectional area. The SDH and actomyosin ATPase activities of muscle fibers were also inversely correlated. These phenotypic differences in SDH and ATPase activities may be important in determining the contractile and fatigue properties of different fiber types in the rat diaphragm muscle.

Contractile properties of the developing diaphragm correlate with myosin heavy chain phenotype.

The objective of this study was to determine the relationship between developmental transitions in myosin heavy chain (MHC) composition and changes in maximum unloaded shortening velocity (Vo) and maximum specific force (Po) of the rat diaphragm muscle. The diaphragm was excised at postnatal days 0, 3, 7, 14, 21, and 28 and in adults. MHC isoform expression was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and laser densitometry. In muscle fiber bundles, Vo was determined at 15 degrees C by use of the "slack" test. Isometric Po was determined at 15 and 26 degrees C. Simple and stepwise regressions were used to evaluate the correlations between Vo, Po, and MHC phenotype transitions and the various developmental ages. The progressive increases in Vo and Po with age were found to be inversely correlated to MHC-neonatal isoform expression (r2 = -0.84 and -0.63, respectively) and positively correlated to MHC-2X (r2 = 0.78 and 0.57) and MHC-2B (r2 = 0.51 and 0.40) isoform expression (P < 0.001). Changes in MHC-neonatal isoform expression contributed to most of the developmental variance in Vo and Po, with changes in MHC-2X and MHC-2B expression also contributing significant increments to total variance. The postnatal increase in Vo most likely relates to differences in the actomyosin adenosinetriphosphatase activity between neonatal and adult fast MHC phenotypes. The increase in Po may reflect inherent differences in myofibrillar density, cross-bridge cycling kinetics, and/or the force produced per cross bridge among fibers composed of the different MHC isoforms.

Postnatal expression of myosin isoforms in the genioglossus and diaphragm muscles.

We studied the expression of myosin heavy chain (MHC) and native myosin isoforms in the genioglossus (GG) and costal diaphragm (DIA) muscles of the rat during postnatal development using both denaturing and nondenaturing gel electrophoresis. Primary myotubes in both fast and slow muscles homogeneously express slow as well as embryonic myosin. Since the adult GG is comprised primarily of fast MHC isoforms, whereas the adult DIA is characterized by a mixture of MHC slow and fast isoforms, we hypothesized that the GG and DIA would be subject to different temporal patterns of MHC isoform expression during postnatal development. Native myosin and MHC gels demonstrated a persistence of neonatal MHC (MHC neo) on day 25 in the GG, whereas this isoform was not detected beyond day 21 in the DIA. The MHC phenotype in GG of the adult demonstrated a predominance of MHC 2X (35% +/- 8) and MHC 2B (45% +/- 10) with a smaller proportion of MHC 2A (19% +/- 5). In contrast, the MHC phenotype in adult DIA was characterized by approximately equal proportions of MHC slow (25% +/- 3), MHC 2A (34% +/- 10), and MHC 2X (31% +/- 12) with a small percentage of MHC 2B (9% +/- 7). These data suggest that postnatal regulation of MHC expression in the GG and DIA is muscle specific.