Developmental changes in neuromuscular transmission in the rat diaphragm.

Neuromuscular transmission was studied in diaphragms from rats of three ages, 4-7 days old, 11-12 days old, and adults with the use of an in vitro phrenic nerve-hemidiaphragm preparation. Each hemidiaphragm was stimulated via either muscle or nerve with 1-s stimulus trains at frequencies from 10 to 100 Hz. The patterns of force development obtained in response to the two routes of stimulation were compared for each group. Diaphragms from adults developed maximum force in response to stimulation of approximately 40 Hz with no significant decrease in force at higher frequencies. Within each stimulus train, once peak force was achieved, it was maintained for the remainder of the stimulus and responses to nerve and muscle stimulation were almost identical. In contrast, diaphragms from 4- to 7-day-old rats developed maximum force at approximately 20 Hz; stimulation at greater than or equal to 60 Hz induced significantly less peak force. This decrease in peak force at higher frequencies was significantly larger for nerve than for muscle stimulation. In addition, during each nerve stimulus train diaphragms from 4- to 7-day-old rats were unable to maintain peak force, which decreased at frequencies greater than 20 Hz. The decrease in force reached approximately 50% of peak at stimulation frequencies greater than or equal to 60 Hz. Diaphragms from 11- to 12-day-old rats showed intermediate responses. Based on the responses to phrenic nerve stimulation, we conclude that the neonatal rat diaphragm shows marked neuromuscular transmission failure that is not seen in the adult.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental changes in heart and muscle phosphofructokinase isozymes

Phosphofructokinase isozymes of fetal, neonatal, and adult rat heart and skeletal muscle were characterized by DEAE-cellulose chromatography, agarose gel electrophoresis, and immunodiffusion with specific antisera. The results of these studies indicate that in skeletal muscle and heart the levels of the major liver phosphofructokinase isozyme (PFK-L2) and the muscle phosphofructokinase isozyme (PFK-M) are dependent on the developmental status of the rat. For example, PFK-L2 and PFK-M are present in fetal and early neonatal skeletal muscle; whereas in adult skeletal muscle, only PFK-M is detectable. By DEAE- cellulose chromatography, PFK-L2 activity was estimated to be 2.4 units/g (41% of total phosphofructokinase activity) in fetal muscle, very low and not resolved from PFK-M in 7-day neonatal muscle, and not detectable in adult muscle. Further, PFK-M activity was found to be 3.4 units/g (59% of total phosphofructokinase activity), 10 units/g, and 31.6 units/g in fetal, 7-day neonatal, and adult skeletal muscle, respectively. The developmental changes of heart phosphofructokinase isozymes differ considerably from that of the skeletal muscle phosphofructokinase isozymes. In fetal heart, PFK-L2 is the major phosphofructokinase isozyme (5.6 units/g), constituting 67% of total phosphofructokinase activity. Further, in fetal heart another phosphofructokinase isozyme (33% of total phosphofructokinase activity) was found by DEAE-cellulose chromatography which is different from PFK-M and PFK-L2. In 7-day neonatal and adult heart, PFK-M and PFK-L2 are the only detectable phosphofructokinase isozymes. Varying from 5.6 units/g (44% of total) in 7-day neonatal to 5.9 units/g (40% of total) in adult heart, PFK-L2 activity remains fairly constant. Also, PFK-M is very low in fetal heart but increases within 1 week postpartum to 5.5 units/g (50% of total activity) and to 8.9 units/g (60% of total activity) in adult heart.     

Developmental regulation of membrane traffic organization during synaptogenesis in mouse diaphragm muscle

In innervated adult skeletal muscles, the Golgi apparatus (GA) displays a set of remarkable features in comparison with embryonic myotubes. We have previously shown by immunocytochemical techniques, that in adult innervated fibers, the GA is no longer associated with all the nuclei, but appears to be concentrated mostly in the subneural domain under the nerve endings in chick (Jasmin, B. J., J. Cartaud, M. Bornens, and J.- P. Changeux. 1989. Proc. Natl. Acad. Sci. USA. 86:7218-7222) and rat (Jasmin, B. J., C. Antony, J.-P. Changeux, and J. Cartaud. 1995. Eur. J. Neurosci. 7:470-479). In addition to such compartmentalization, biochemical modifications take place that suggest a functional specialization of the subsynaptic GA. Here, we focused on the developmental regulation of the membrane traffic organization during the early steps of synaptogenesis in mouse diaphragm muscle. We investigated by immunofluorescence microscopy on cryosections, the distribution of selected subcompartments of the exocytic pathway, and also of a representative endocytic subcompartment with respect to the junctional or extrajunctional domains of developing myofibers. We show that throughout development the RER, the intermediate compartment, and the prelysosomal compartment (mannose 6-phosphate receptor-rich compartment) are homogeneously distributed along the fibers, irrespective of the subneural or extrajunctional domains. In contrast, at embryonic day E17, thus 2-3 d after the onset of innervation, most GA markers become restricted to the subneural domain. Interestingly, some Golgi markers (e.g., alpha-mannosidase II, TGN 38, present in the embryonic myotubes) are no longer detected in the innervated fiber even in the subsynaptic GA. These data show that in innervated muscle fibers, the distal part of the biosynthetic pathway, i.e., the GA, is remodeled selectively shortly after the onset of innervation. As a consequence, in the innervated fiber, the GA exists both as an evenly distributed organelle with basic functions, and as a highly differentiated subsynaptic organelle ensuring maturation and targeting of synaptic proteins. Finally, in the adult, denervation of a hemidiaphragm causes a burst of reexpression of all Golgi markers in extrasynaptic domains of the fibers, hence showing that the particular organization of the secretory pathway is placed under nerve control.     

Relaxation of diaphragm muscle.

Relaxation is the process by which, after contraction, the muscle actively returns to its initial conditions of length and load. In rhythmically active muscles such as diaphragm, relaxation is of physiological importance because diaphragm must return to a relatively constant resting position at the end of each contraction-relaxation cycle. Rapid and complete relaxation of the diaphragm is likely to play an important role in adaptation to changes in respiratory load and breathing frequency. Regulation of diaphragm relaxation at the molecular and cellular levels involves Ca(2+) removal from the myofilaments, active Ca(2+) pumping by the sarcoplasmic reticulum (SR), and decrease in the number of working cross bridges. The relative contribution of these mechanisms mainly depends on sarcomere length, muscle tension, and the intrinsic contractile function. Increased capacity of SR to take up Ca(2+) can arise from increased density of active SR pumping sites or in slow-twitch fibers from phosphorylation of phospholamban, whereas impaired coupling between ATP hydrolysis and Ca(2+) transport into the SR or intracellular acidosis reduces SR Ca(2+) pump activity. In experimental conditions of decreased contractile performance, slowed, enhanced, or unchanged relaxation rates have been reported in vitro. In vivo, a slowing in the rate of decline of the respiratory pressure is generally considered an early reliable index of respiratory muscle fatigue. Impaired relaxation rate may, in turn, favor mismatch between blood flow and metabolic demand, especially at high breathing frequencies.     

Respiratory sensation and pattern of respiratory muscle activation during diaphragm fatigue

We have examined the relationship between respiratory effort sensation (modified Borg scale) and amplitude of the integrated surface electromyogram of the diaphragm (Edi, esophageal electrode), rib cage muscles (Erc), and sternomastoid muscle (Esm) during the development of diaphragm fatigue in five normal subjects. Three conditions were studied: run A: transdiaphragmatic pressure (Pdi), 65% Pdimax; esophageal pressure (Pes), 60% Pesmax; run B: Pdi, 50% Pdimax; Pes, 60% Pesmax; and run C: Pdi, 50% Pdimax; Pes, 20% Pesmax. During all runs there was a progressive rise in sensation, which was greater in runs A and B than in run C (P less than 0.05, analysis of variance). There was no difference between runs A and B. At the end of run C subjects did not report a maximal Borg score despite their inability to generate the target Pdi. The increase in sensory score with fatigue correlated highly with Esm/Esmmax and with Erc/Ercmax. There was no correlation between sensory score and Edi/Edimax. We conclude that the increase in respiratory effort sensation that accompanies diaphragm fatigue is not due to perception of increased diaphragmatic activation. It may reflect increased overall respiratory motor output not directed to the diaphragm.     

Alterations in respiratory muscle activation in the ischemic fatigued canine diaphragm

The purpose of the present study was to examine the respiratory motor response to diaphragm fatigue. Studies were performed using in situ diaphragm muscle strips dissected from the left costal diaphragm in anesthetized dogs. The left inferior phrenic artery was isolated, and diaphragmatic strip fatigue was elicited by occluding this vessel. Strip tension, strip electromyographic activity, parasternal electromyographic activity, and the electromyogram of the right hemidiaphragm were recorded during spontaneous breathing efforts before, during, and after periods of phrenic arterial occlusion. In separate trials, we examined the neuromuscular responses to phrenic arterial occlusion at arterial PCO2 (PaCO2) of 40, 55, and 75 Torr. No fatigue and no alteration in electromyographic activities were observed in trials at PaCO2 of 40 Torr. During trials at PaCO2 of 55 and 75 Torr, however, diaphragm tension fell, the peak height of the diaphragm strip electromyogram decreased, and the peak heights of the parasternal and right hemidiaphragm electromyograms increased. Relief of phrenic arterial occlusion resulted in a return of strip tension and all electromyograms toward base-line values. In additional experiments, the left phrenic nerve was sectioned in the chest after producing fatigue. Phrenic section was followed by an increase in the peak height of the left phrenic neurogram (recorded above the site of section). This latter finding suggests that diaphragm strip motor drive may be reflexly inhibited during the development of fatigue by neural traffic carried along phrenic afferents.     

Developmental changes in expression of adhesion-mediating proteins in human aortic smooth muscle.

Phenotypic variability of vascular smooth muscle cells (SMCs) can serve as a good model for studying the mechanisms regulating the expression of adhesion-mediating proteins. To describe phenotypic changes of human aortic SMCs, we have studied the expression of cytodifferentiation-related adhesion-mediating proteins in samples of media from fetal, child and adult human aorta, and in subendothelial intima of normal and atherosclerotic aorta. We have shown that during prenatal and post-natal development vascular SMCs co-ordinately change several times the expression of certain differentiation-related proteins. Our data show the existence of certain groups of proteins whose expression during smooth muscle development might be controlled by two basic mechanisms: selection of genes to be expressed at particular developmental stages and generation of several different protein variants from a single gene via alternative RNA splicing.     

Developmental changes in hepatic activation of dietary mutagens by mice

Metabolic activation of the food mutagens 2-amino-3,4-dimethylimidazo[4,5-f]quinoline (MeIQ), 3-amino-1-methyl-5H-pyrido[4,3-b]indole (Trp-P-2) and aflatoxin B1 by female BALB/c mice of different ages (2-24 weeks) was investigated in vivo and in vitro using Salmonella typhimurium TA98 as the indicator organism. The in vivo activation of the three mutagens was investigated in 4- and 24-week-old mice using an intrasanguineous host-mediated assay. All three compounds showed reduced levels of activation with the older hosts. Hepatic S9 fractions from female mice of varying ages between 2 and 24 weeks were used in the in vitro mutagenicity assay. To achieve optimal activation to bacterial mutagens, 5% S9 was required for aflatoxin B1 and Trp-P-2 and 10% S9 for MeIQ; age of donor generally had little effect on the profile of these protein activation curves. Under these optimal conditions MeIQ and Trp-P-2 both exhibited, as before, age-dependent decreases in activation over a wide range of mutagen concentrations, however the in vitro activation of aflatoxin showed no consistent change with age. Spectrophotometric measurements of S9 cytochrome P-450 content showed a decrease in concentration with increasing age, but this was not sufficient to account for changes observed in hepatic mutagen activation. However, changes in the activities of certain cytochrome P-450 isoenzymes and cytosolic GSH-transferases, which in turn result in changes in the activation and detoxification capacity of the liver, would appear to explain age-dependent changes in the activity of mutagens in vivo.     

Age-related changes in protein turnover and ribonucleic acid of the diaphragm muscle of normal and dystrophic hamsters.

Diaphragm muscles of dystrophic hamsters were found to be larger than those of control animals at two of three ages studied. The additional growth of these afflicted muscles correlated with large increases in protein synthesis and concentrations of RNA. Protein breakdown was also increased in the dystrophic muscles, but to a smaller extent than synthesis.     

Fatty-acid-binding protein in locust flight muscle. Developmental changes of expression, concentration and intracellular distribution.

Fatty-acid-binding protein (FABP) from the flight muscle of the locust, Schistocerca gregaria, is similar to mammalian heart FABP in its primary structure and biochemical characteristics. We have studied developmental changes using enzyme-linked immunosorbent assays, RNA hybridization and electron microscopy of immunogold-labeled sections. Locust muscle FABP is the most abundant soluble muscle protein in fully developed adult locusts, comprising 18% of the total cytosolic protein. At the beginning of the adult stage, however, no FABP is detectable. Its concentration rises during the following 10 days, after which it reaches its maximal value. FABP mRNA is present shortly after adult ecdysis; its concentration increases for 10 days, before it diminishes and reaches a constant, low level, probably needed to maintain the established FABP level. The protein is abundant in cytosol and nuclei, but virtually absent in mitochondria.     

Developmental changes in inotropic actions of neurotoxins observed in ventricular muscle of rat heart.

Developmental changes in functions of myocardial sodium channels were examined from inotropic effects of several neurotoxins in ventricular muscle preparations obtained from prenatal (20-22 day gestation) or adult (3-4 months old) rat hearts. Tetrodotoxin caused a negative inotropic effect in low concentrations and a loss of muscle responsiveness to electrical stimulation in high concentrations in preparations obtained from either prenatal or adult rat heart. The tetrodotoxin concentration that caused a 50% decrease in developed tension was higher in prenatal rats. Anemonia sulcata toxin, Androctonus australis toxin, veratridine, and Centruroides sculpturatus toxin all produced positive inotropic effects in adult rat heart. The effects were largest with A. sulcata and A. australis toxins, intermediate with veratridine, and smallest with C. sculpturatus toxin. Prenatal heart required higher concentrations of either veratridine, or A. sulcata or A. australis toxins to produce comparable positive inotropic effects. With C. sculpturatus toxin, no significant positive inotropic effect was observed in prenatal heart muscle preparations. These results indicate that cardiac sodium channels undergo significant functional changes during development and that negative and positive inotropic effects of neurotoxins resulting from inhibition and enhancement of fast Na+ channels reflect developmental changes in the cardiac sodium channels.     

Developmental changes in ECG associated with heart rate are similar in squirrel monkey and human infants.

Interest in refining noninvasive methods of diagnosis and further characterization of squirrel monkeys (Saimiri sp.) as a model for pediatric cardiology studies led to this investigation of electrocardiogram (ECG) changes associated with changes in age and position. During a single delivery season, ECGs were performed at 1 day, 1 month, and 1 year of age. For each age group, ECGs were recorded with animals in dorsal, ventral, and right lateral recumbency. The 1-day-old group had the lowest heart rates (271 +/- 10, right lateral recumbency, mean +/- SEM) relative to the other age groups. One-year-old monkeys had heart rates of 333 +/- 18. One-month-old infants had rates significantly higher than the other two age groups (366 +/- 4). The QRS frontal-plane axis showed an age-related leftward change from 1 day (151 +/- 28 degrees) to 1 year of age (121 +/- 44 degrees) while the P-wave frontal plane axis remained nearly constant over a narrow range at all ages. The pattern of heart rate changes with age were similar to those in humans, although the ranges of absolute heart rates were markedly different. These data suggest that factors that influence maturational changes in heart rate, conduction time (as reflected by ECG intervals) and cardiac chamber size and position (inferred from axis and voltage) are similar among primates of widely variant body sizes.     

Electromyographic measures of muscle activation and changes in muscle architecture of human elbow flexors during fatiguing contractions.

The study compared changes in intramuscular and surface recordings of EMG amplitude with ultrasound measures of muscle architecture of the elbow flexors during a submaximal isometric contraction. Ten subjects performed a fatiguing contraction to task failure at 20% of maximal voluntary contraction force. EMG activity was recorded in biceps brachii, brachialis, and brachioradialis muscles using intramuscular and surface electrodes. The rates of increase in the amplitude of the surface EMG for the long and short heads of biceps brachii and brachioradialis were greater than those for the intramuscular recordings measured at different depths. The amplitude of the intramuscular recordings from three muscles increased at a similar rate (P = 0.13), as did the amplitude of the three surface recordings from two muscles (P = 0.83). The increases in brachialis thickness (27.7 +/- 5.7 to 30.9 +/- 3.5 mm; P < 0.05) and pennation angle (10.9 +/- 3.5 to 16.5 +/- 4.8 degrees ; P = 0.003) were not associated with the increase in intramuscular EMG amplitude (P > 0.58). The increase in brachioradialis thickness (22.8 +/- 4.8 to 25.5 +/- 3.4 mm; P = 0.0075) was associated with the increase in the amplitude for one of two intramuscular EMG signals (P = 0.007, r = 0.79). The time to failure was more strongly associated with the rate of increase in the amplitude of the surface EMG than that for the intramuscular EMG, which suggests that the surface measurement provides a more appropriate measure of the change in muscle activation during a fatiguing contraction.