Use of fura red as an intracellular calcium indicator in frog skeletal muscle fibers.

Fura red, a fluorescent Ca2+ indicator with absorbance bands at visible wavelengths, was injected into intact single muscle fibers that had been stretched to a long sarcomere length (approximately 3.8 microns) and bathed in a 'high-Ca2+' Ringer ([Ca2+] = 11.8 mM). From fura red's slow diffusion coefficient in myoplasm, 0.16 (+/- 0.01, SEM) x 10(-6) cm2 s-1 (N = 5; 16 degrees C), it is estimated that approximately 85% of the indicator molecules are bound to muscle constituents of large molecular weight. Binding appears to elevate, by 3- to 4-fold, the indicator's apparent dissociation constant for Ca2+ (KD), which is estimated to be 1.1-1.6 microM in myoplasm. Fura red's myoplasmic absorbance spectrum was used to estimate fr, the fraction of fura red molecules in the Ca2+-bound form at rest. In 3 fibers thought to be minimally damaged by the micro-injection, fr was estimated to be 0.15 (+/- 0.01). Thus, resting myoplasmic free [Ca2+] ([Ca2+]r) is estimated to be 0.19-0.28 microM. For fibers in normal Ringer solution ([Ca2+] = 1.8 mM), at shorter sarcomere length (approximately 2.7 microns), and containing a nonperturbing concentration of indicator (< or = 0.2 mM), [Ca2+]r is estimated to be 0.18-0.27 microM. This range is higher than estimated previously in frog fibers with other techniques. In 6 fibers, R, the indicator's fluorescence ratio signal (equal to the emission intensity measured with 420 nm excitation divided by that measured with 480 nm excitation), was measured at rest and following electrical stimulation and compared with absorbance measurements made from the same fiber region. The analysis implies that RMIN and RMAX (the values of R that would be measured if all indicator molecules were in the Ca(2+)-free and Ca(2+)-bound states, respectively) were substantially smaller in myoplasm than in calibration solutions lacking muscle proteins. Several methods for estimation of [Ca2+]r from R are analyzed and discussed.     

Bilateral asymmetry in skeletal growth and maturation as an indicator of environmental stress.

This study examined the efficacy of bilateral asymmetry in epiphyseal union as an indicator of environmental stress affecting the skeleton. We compared the extent of asymmetry in the postcranial skeleton between two cemetery samples excavated from Medieval Kulubnarti, Sudanese Nubia. Past studies have strongly suggested that these ancient Nubians experienced environmental stress-the early Christian period (550-750 AD) population to a greater extent than the late Christian period (750-1450 AD) population. We hypothesized that if bilateral asymmetry is a reflection of stress, then it should be present or greater in the more stressed population, the early Christian period population, while absent or found to a lesser extent in the less stressed population, the late Christian period population. We computed two mean values, representative of right-side and left-side epiphyseal union, for each individual in both cemetery samples, and tested for significant differences. Bilateral asymmetry was significant in the combined cemetery sample of 90 individuals (P < 0.019). When cemetery samples were tested separately, bilateral asymmetry was significant for the early Christian period sample (P < 0.001), but not for the late Christian period sample. There were no differences attributable to sex. Finally, we discuss why we conclude that environmental stress was favored over a biomechanic explanation as the cause for asymmetry. To the extent that our results support previous findings that early Christian period individuals were more affected by environmental stress than late Christian period individuals, it is reasonable to consider bilateral asymmetry in skeletal growth and maturation a good indicator of environmental stress.     

Phosphoenolpyruvate-dependent protein kinase activity in rat skeletal muscle

Phosphoenolpyruvate-dependent protein kinase activity has been demonstrated in the soluble fraction of rat skeletal muscle. The reaction was not due to the formation of ATP in the incubation mixture. Cyclic AMP, calcium, ATP and a number of phosphate acceptor proteins did not stimulate the reaction. One 32P-labelled protein (Mr 25000) was observed on SDS gels. The phosphorylated protein contained acid stable phosphoserine as a major phosphorylated amino acid. The phosphorylation reaction in crude extracts was not directly proportional to the amount of protein, but typical of a two-component system; i.e., kinase and substrate. The chromatography of soluble proteins on Ultrogel AcA44 separated the phosphate acceptor protein(s) from the phosphoenolpyruvate-dependent protein kinase activity.     

Three fast myosin heavy chains in adult rat skeletal muscle

A new fast myosin heavy chain isoform was electrophoretically detected in adult rat skeletal muscles. It was present at high levels in diaphragm and, therefore, designated as MHCIId. Appreciable amounts of MHCIId were detected in tongue musculature, the extraocular muscles, and in the deep red portions of various fast muscles. Its concentration in fast-twitch muscle was greatly increased by chronic stimulation.     

Early postnatal growth of skeletal muscle blood vessels of the rat

The development of blood vessels during the first three postnatal weeks was studied in the ventral stripe of the spinotrapezius muscle of the rat by use of India ink-gelatine injections, and electron microscopy. The number of terminal arterioles and collecting venules remained unchanged postnatally in the observed area. A remarkable proximodistal gradient of vascular development was apparent: while the basic structure of the hilar vessels remained unchanged in the time studied, the intramuscular arteries and veins matured gradually. More peripherally, gradual maturation of terminal and precapillary arterioles was observed. The capillary endothelium and the pericytes showed immature features, and remained unchanged during the time studied. An intense rebuilding activity was found in the endothelial cells of the growing venules, expressed by various forms of gaps, covered by an intact basal lamina and pericytes. Numerous mast cells and macrophages were found along all vessels. Intramuscular lymphatics were not present prior to the first postnatal week.     

Perturbed skeletal muscle insulin signaling in the adult female intrauterine growth-restricted rat

To determine the molecular mechanism(s) linking fetal adaptations in intrauterine growth restriction (IUGR) to adult maladaptations of type 2 diabetes mellitus, we investigated the effect of prenatal seminutrient restriction, modified by early postnatal ad libitum access to nutrients (CM/SP) or seminutrient restriction (SM/SP), vs. early postnatal seminutrient restriction alone (SM/CP) or control nutrition (CM/CP) on the skeletal muscle postreceptor insulin-signaling pathway in the adult offspring. The altered in utero hormonal/metabolic milieu was associated with no change in basal total IRS-1, p85, and p110beta subunits of PI 3-kinase, PKCtheta, and PKCzeta concentrations but an increase in basal IRS-2 (P < 0.05) only in the CM/SP group and an increase in basal phospho (p)-PDK-1 (P < 0.05), p-Akt (P < 0.05), and p-PKCzeta (P < 0.05) concentrations in the CM/SP and SM/SP groups. Insulin-stimulated increases in p-PDK-1 (P < 0.05) and p-Akt (P < 0.0007), with no increase in p-PKCzeta, were seen in both CM/SP and SM/SP groups. SHP2 (P < 0.03) and PTP1B (P < 0.03) increased only in SM/SP with no change in PTEN in CM/SP and SM/SP groups. Aberrations in kinase and phosphatase moieties in the adult IUGR offspring were initiated in utero but further sculpted by the early postnatal nutritional state. Although the CM/SP group demonstrated enhanced kinase activation, the SM/SP group revealed an added increase in phosphatase concentrations with the net result of heightened basal insulin sensitivity in both groups. The inability to further respond to exogenous insulin was due to the key molecular distal roadblock consisting of resistance to phosphorylate and activate PKCzeta necessary for GLUT4 translocation. This protective adaptation may become maladaptive and serve as a forerunner for gestational and type 2 diabetes mellitus.     

Neighbourhood analysis as an indicator of spatial requirements of broiler chickens

The appropriate stocking density for broiler chickens is a much discussed topic in animal welfare. To determine at which stocking density the level of crowding becomes aversive to 4–6-week-old broiler chickens, spatial distribution and behaviour of groups stocked at 8, 19, 29, 40, 45, 51, 61 or 72 birds per 3.3 m² were analysed. Spatial distribution was evaluated using three different indices: inter-individual distances, nearest neighbour distances and Dirichlet polygon areas. The assumption was that broilers would increase the distance to their pen mates if high densities (i.e., close proximity to pen mates) were experienced as aversive, whereas they would decrease this distance if close proximity was experienced positively. Increased distances to pen mates would lead to increased nearest neighbour distances and a more homogeneous distribution (i.e., lower variation of inter-individual distances and of Dirichlet-polygon size) than expected by chance. The distribution expected by chance was determined from both a random distribution and a ‘resource-corrected’ random distribution (which incorporated environmental influences on spatial distribution but excluded social ones).Behavioural observations showed that at higher stocking densities more sitting bouts (P = 0.003) and adjustments of the sitting and lying posture (P < 0.001) occurred. It was also found that nearest neighbour distance varied according to behaviour (P = 0.001). Birds that were eating/drinking were further apart from their nearest neighbour than birds that were foraging, preening, adjusting their sitting or lying posture or showing “other” behaviour.The results from all three methods of spatial analysis suggested that broilers in groups ≥19 birds per 3.3 m² (ultimately equivalent to 15 kg/m²) started to experience the proximity of conspecifics as aversive at some point during the last 3 weeks of rearing. However, nearest neighbour distance analysis showed evidence of aversiveness earlier in life than the other methods of analyzing spatial distribution (variation in inter-individual distance and polygon size), suggesting that nearest neighbour distance is the more sensitive indicator of space requirements.When uneven use of the different areas within the pen was reflected in the expected distribution (i.e., for comparisons to the resource-corrected random distribution) different results were obtained than when such measures were omitted (i.e., for comparisons to the random distribution). As such, this study emphasises the importance of accounting for environmental influences on distribution within a pen.     

Induction of GLUT-1 protein in adult human skeletal muscle fibers

Prompted by our recent observations that GLUT-1 is expressed in fetal muscles, but not in adult muscle fibers, we decided to investigate whether GLUT-1 expression could be reactivated. We studied different stimuli concerning their ability to induce GLUT-1 expression in mature human skeletal muscle fibers. Metabolic stress (obesity, non-insulin-dependent diabetes mellitus), contractile activity (training), and conditions of de- and reinnervation (amyotrophic lateral sclerosis) could not induce GLUT-1 expression in human muscle fibers. However, regenerating muscle fibers in polymyositis expressed GLUT-1. In contrast to GLUT-1, GLUT-4 was expressed in all investigated muscle fibers. Although the significance of GLUT-1 in adult human muscle fibers appears limited, GLUT-1 may be of importance for the glucose supplies in immature and regenerating muscle.     

Hypoxia affects mitochondrial protein expression in rat skeletal muscle

Hypoxia affects mammalian mitochondrial function, as well as mitochondria-based energy metabolism. The detail mechanism has not been fully understood. In this study, we detected protein expression levels in mitochondrial fractions of Wistar rats exposed to hypobaric hypoxia by use of proteomic methods. Adult male Wistar rats were randomized into an hypoxic (4,500?m, 30 days) group and a normoxic control group (sea level). Gastrocnemius muscles mitochondria were extracted and purified. Mitochondrial oxygen consumption was measured with a Clark oxygen electrode; mitochondrial transmembrane potential was detected with Rhodamine 123 as a fluoresce probe. Using 2-DE and MALDI-TOF MS analysis, we identified eight mitochondrial protein spots that were differentially expressed in the hypoxic group compared with the normoxic control. These proteins included Chain A of F1-ATPase, voltage dependent anion channel 1 (VDAC), hydroxyacyl Coenzyme A dehydrogenase α-subunit, mitochondrial F1 complex γ-subunit, androgen-regulated protein and tripartite motif protein 50. Two of the spots, VDAC and ATP synthase α-subunit, were confirmed by Western blotting analysis. Oxygen consumption during State 3 respiration, as well as the respiratory control ratio (RCR) was significantly higher in the control than that in the hypoxic group; mitochondrial transmembrane potential was significantly higher in hypoxic group than that in the control. With successful use of multiple proteomic analysis techniques, we demonstrates that 30 days hypoxia exposure has effects on the expression of mitochondrial proteins involved in ATP production and lipid metabolism, decrease the stability of mitochondrial membrane, and affect the mitochondrial electron transport chain.     

Proteomic identification of age-dependent protein nitration in rat skeletal muscle

Age-related protein nitration was studied in skeletal muscle of Fisher 344 and Fisher 344/Brown Norway (BN) F1 rats by a proteomic approach. Proteins from young (4 months) and old (24 months) Fisher 344 rats and young (6 months) and old (34 months) Fisher 344/BN F1 animals were separated by 2-D gel electrophoresis. Western blot showed an age-related increase in the nitration of a few specific proteins, which were identified by MALDI-TOF MS and ESI-MS/MS. We identified age-dependent apparent nitration of beta-enolase, alpha-fructose aldolase, and creatine kinase, which perform important functions in muscle energy metabolism, suggesting that the nitration of such key proteins can be, in part, responsible for the decline of muscle motor function of the muscle. Furthermore, we have identified the apparent nitration of succinate dehydrogenase, rab GDP dissociation inhibitor beta (GdI-2), triosephosphate isomerase, troponin I, alpha-crystallin, and glyceraldehyde-3-phosphate dehydrogenase (GAPDH).     

Contraction-associated translocation of protein kinase C in rat skeletal muscle

Electrical stimulation of the sciatic nerve of the anaesthetized rat in vivo led to a time-dependent translocation of protein kinase C from the muscle cytosol to the particulate fraction. Maximum activity of protein kinase C in the particulate fraction occurred after 2 min of intermittent short tetanic contractions of the gastrocnemius-plantaris-soleus muscle group and coincided with the loss of activity from the cytosol. Translocation of protein kinase C may imply a role for this kinase in contraction-initiated changes in muscle metabolism.     

Expression of beta-catenin is necessary for physiological growth of adult skeletal muscle

Expression of beta-catenin is known to be important for developmental processes such as embryonic pattern formation and determination of cell fate. Inappropriate expression, however, has been linked to pathological states such as cancer. Here we report that expression of beta-catenin is necessary for physiological growth of skeletal muscle in response to mechanical overload. Conditional inactivation of beta-catenin was induced in control and overloaded muscle through intramuscular injection of adenovirus expressing Cre recombinase in beta-catenin floxed mice. Individual muscle fiber analysis was performed to identify positively transfected/inactivated cells and determine fiber cross-sectional area. The results demonstrate that fiber growth is completely inhibited when the beta-catenin expression is lost. This effect was cell autonomous, as fibers that did not exhibit recombination in the floxed mice grew to the same magnitude as infected/noninfected fibers from wild-type mice. These findings suggest that beta-catenin may be a primary molecular site through which multiple signaling pathways converge in regulating physiological growth.