Transneuronal tracing of neural pathways that regulate hindlimb muscle blood flow

Despite considerable interest in the neural mechanisms that regulate muscle blood flow, the descending pathways that control sympathetic outflow to skeletal muscles are not adequately understood. The present study mapped these pathways through the transneuronal transport of two recombinant strains of pseudorabies virus (PRV) injected into the gastrocnemius muscles in the left and right hindlimbs of rats: PRV-152 and PRV-BaBlu. To prevent PRV from being transmitted to the brain stem via motor circuitry, a spinal transection was performed just below the L2 level. Infected neurons were observed bilaterally in all of the areas of the brain that have previously been shown to contribute to regulating sympathetic outflow: the medullary raphe nuclei, rostral ventrolateral medulla (RVLM), rostral ventromedial medulla, A5 adrenergic cell group region, locus coeruleus, nucleus subcoeruleus, and the paraventricular nucleus of the hypothalamus. The RVLM, the brain stem region typically considered to play the largest role in regulating muscle blood flow, contained neurons infected following the shortest postinoculation survival times. Approximately half of the infected RVLM neurons were immunopositive for tyrosine hydroxylase, indicating that they were catecholaminergic. Many (47%) of the RVLM neurons were dually infected by the recombinants of PRV injected into the left and right hindlimb, suggesting that the central nervous system has a limited capacity to independently regulate blood flow to left and right hindlimb muscles.     

Transneuronal tracing of neural pathways influencing both diaphragm and genioglossal muscle activity in the ferret.

In prior experiments that employed the transneuronal transport of isogenic recombinants of pseudorabies virus (PRV), we demonstrated that neurons located ventrally in the medial medullary reticular formation (MRF) of the ferret provide collateralized projections to both diaphragm and abdominal muscle motoneurons as well as to multiple abdominal muscle motoneuron pools. The goal of the present study was to determine whether single MRF neurons also furnish inputs to diaphragm motoneurons and those innervating an airway muscle with inspiratory-related activity: the tongue protruder genioglossus. For this purpose, PRV recombinants expressing unique reporters (beta-galactosidase or enhanced green fluorescent protein) were injected into either the diaphragm or the genioglossal muscle. The virus injections produced transneuronal infection of overlapping populations of MRF neurons. A small proportion of these neurons (<15%) was infected by both PRV recombinants, which indicated that they provide collateralized inputs to genioglossal and diaphragm motoneurons. These findings show that, whereas some MRF neurons simultaneously influence the activity of upper airway and respiratory pump muscles, other cells in this brain stem region independently contribute to diaphragm and genioglossal muscle contraction regulation.     

Transneuronal induction of muscle atrophy in grasshoppers

Autotomy is a process in grasshoppers whereby one or both hindlimbs can be shed to escape a predator or can be abandoned if damaged. It occurs between the trochanter and the femur (second and third leg segments) and once lost, the legs never regenerate. Autotomy severs branches of the leg nerve (N5) but damages no muscles since none span the autotomy plane. We find, however, that undamaged muscles intrinsic to the thorax of grasshoppers, Barytettix psolus, atrophy to less than 15% of their normal mass after autotomy of a hindlimb. These muscles operate the coxa and trochanter (first and second leg segments) and are innervated by branches of nerves 3 and 4; nerve branches that are not damaged by autotomy. Atrophy is localized to the side and body segment where autotomy occurs. Atrophy is evident 7-10 days after loss of a limb, is complete by about 30 days, and follows a similar time course whether induced in young adult, or sexually mature grasshoppers. During autotomy, leg nerve 5 is served distal to the trochanter, the thoracic muscles lose their normal static and dynamic load, and these muscles are subsequently no longer used to support the weight of the insect during posture and locomotion. Experimental loading and unloading of the affected muscles, and cutting of nerves indicated that it is the severing of leg nerve 5 during autotomy that transneuronally induces muscle atrophy.     

Pineal 'synaptic' ribbons in sympathectomized rats

The melatonin metabolism in the mammalian pineal gland is under the clear influence of sympathetic fibers originating in the superior cervical ganglia (SCG). Previous studies suggested that also pineal 'synaptic' ribbons (SR) are regulated by the gland's sympathetic innervation. To gain more insight into the mechanisms involved, SR numbers were determined in adult rats which were chemically sympathectomized as newborns by injection of 6-hydroxydopamine (6-OHDA). In control animals (saline injections), a clear day/night difference in the number of SR is present. In sympathectomized animals, SR are higher in number throughout the 24-hour cycle but are not significantly elevated at night. The present results further strengthen the hypothesis that SR are involved in intercellular communication in the mammalian pineal gland.     

Brain enzyme activity in irradiated sympathectomized rats

The results are reviewed from studies of activity of hexokinase (2.7.1.1.EC), dehydrogenase glucose-6-phosphate (1.1.1.49 EC), and cholinesterase (3.1.1.7 EC) in subcellular fractions of rat brain at the background of chemical sympathectomy induced by long-term administration of guanethidine and subsequent irradiation with a dose of 7 Gy. In conditions of sympathectomy, the enzyme activity is inhibited; in irradiated sympathectomized rats, activity of hexokinase and cholinesterase increases to reach the level of that of intact animals while dehydrogenase remains inhibited.     

Testosterone and muscle hypertrophy in female rats

The effects of chronic treatment with testosterone propionate on compensatory muscle hypertrophy secondary to synergist removal were studied in female rats. Synergist removal resulted in a significant (2-fold) increase in muscle wet weight, with no changes in protein concentration. As reported previously, oxidation of [2-14C]pyruvate to 14CO2 was significantly decreased in hypertrophic muscles. In addition, malate dehydrogenase and lactate dehydrogenase activities were significantly decreased in overloaded muscles on a wet weight basis but not on the basis of noncollagen protein. These data suggest that specific metabolic adaptations may occur in response to overload of muscle. Administration of testosterone propionate in subcutaneously implanted Silastic capsules resulted in a 20-fold increase in serum testosterone levels. This treatment had no effect on body weight, muscle weight, pyruvate oxidation, or malate and lactate dehydrogenase activities in both control and hypertrophic muscles, although there was an effect on the noncollagen protein content of overloaded muscles. These results do not support the hypothesis that androgens, in conjunction with weight-bearing exercise in female subjects, are effective in increasing muscle mass or function in female subjects.     

Theophylline stimulation of gluconeogenesis from alanine in normal and sympathectomized rats.

The influence of theophylline ethylenediamine (100 mg/kg i.p.) on gluconeogenesis was studied in normal and in adrenodemedullated and reserpinized rats after overnight fasting by measuring the time-course of Alanine-14C incorporation into Glucose-14C. In the normal rat, theophylline produced a moderate hyperglycemia associated with an increased conversion of alanine to glucose at all time intervals. In addition, a marked rise of plasma levels of insulin and glucagon was observed. In sympathetctomized rats, plasma glucose and gluconeogenesis were again enhanced by theophylline, but the pattern of these modifications differed from that of normal rats since the peak values occurred earlier. Subsequently, both parameters rapidly declined reaching values lower than controls at the end of the experiment. Insulin response to theophylline was higher in sympathectomized animals in comparison to normal rats, while glucagon response was approximately of the same magnitude in the two groups. From these findings it was concluded that theophylline is able to stimulate gluconeogenesis from alanine both in the normal and sympathectomized rat. The different pattern of alanine conversion to glucose seems to depend on the different participation of insulin and catecholamines in the two groups.     

In vitro estimates of power output by epaxial muscle during feeding in largemouth bass

Recent work has employed video and sonometric analysis combined with hydrodynamic modeling to estimate power output by the feeding musculature of largemouth bass in feeding trials. The result was an estimate of approximately 69 W kg(-1) of power by the epaxial muscle during maximal feeding strikes. The present study employed in vitro measurements of force, work and power output by fast-twitch epaxial muscle bundles stimulated under activation conditions measured in vivo to evaluate the power output results of the feeding experiments. Isolated muscle bundles from the epaxial muscle, the sternohyoideus and the lateral red or slow-twitch muscle were tied into a muscle mechanics apparatus, and contractile properties during tetanic contractions and maximum shortening velocity (Vmax) were determined. For the epaxial muscles, work and power output during feeding events was determined by employing mean stimulation conditions derived from a select set of maximal feeding trials: 17% muscle shortening at 3.6 muscle lengths/s, with activation occurring 5 ms before the onset of shortening. Epaxial and sternohyoideus muscle displayed similar contractile properties, and both were considerably faster (Vmax approximately 11-13 ML s(-1)) than red muscle (Vmax approximately 5 ML s(-1)). Epaxial muscle stimulated under in vivo activation conditions generated approximately 60 W kg(-1) with a 17% strain and approximately 86 W kg(-1) with a 12% strain. These values are close to those estimated by hydrodynamic modeling. The short lag time (5 ms) between muscle activation and muscle shortening is apparently a limiting parameter during feeding strikes, with maximum power found at an offset of 15-20 ms. Further, feeding strikes employing a faster shortening velocity generated significantly higher power output. Power production during feeding strikes appears to be limited by the need for fast onset of movement and the hydrodynamic resistance to buccal expansion.     

Regulation of hemodynamics in sympathectomized rats after adaptation to tail suspension

The organism adapts to actual or simulated microgravity by complex interactions of nervous, hormonal and local control mechanisms. Sympathetic nervous system is believed to play the leading role in this adaptation (Robertson et al. 1994). However, this conclusion seems to be rather deductive, as it has not been proved directly. Chronic sympathectomy provides a straightforward approach to this problem. We have studied the role of sympathetic nervous system in adaptation of cardiovascular system to simulated microgravity by tail suspension in intact and sympathectomized rats.     

Long-term dynamics of blood pressure in intact and sympathectomized post-suspension rats

Low-frequency dynamics of mean arterial pressure (MAP) and pulse interval (PI) was studied in intact and sympathectomized rats after 2-week tail suspension. Correlation properties of long-term (f<0.8 Hz) MAP fluctuations were analyzed using R/S Hurst method. It was shown that time series of successive increments in MAP level display power-law fractal anticorrelations in wide range of time scales. After sympathectomy and/or suspension averaged Hurst exponents were more close to the value for uncorrelated random process (H=0.5), indicating deterioration of regulatory feedbacks. Besides, a decrease of coherence between MAP and PI in low-frequency range was observed after suspension in both intact and sympathectomized rats, indicating alteration of non-sympathetic cardiovascular control mechanisms.     

Cardiac biochemical and functional adaptations to exercise in sympathectomized neonatal rats

This study was undertaken to examine the influence of guanethidine monosulfate-induced sympathectomy on exercise-induced adaptations of cardiac contractile protein and on acute hemodynamic responses to exercise involving female neonatal rats. Four groups of rats were studied: 1) normal sedentary (NS), 2) normal trained (NT), 3) sympathectomized sedentary (SS), and 4) sympathectomized trained (ST). The 9-wk running program, which began at 20 days of age, induced increases in whole-body maximal O2 consumption and skeletal-muscle citrate synthase activity in both NT and ST groups compared with NS (P less than 0.05). Submaximal exercise tests demonstrated circulatory adaptations for NT, SS, and ST groups compared with NC; however, the ST group demonstrated the greatest degree of altered cardiac function (decreased heart rate, left ventricular pressure, and contractility index) during exercise. Also, significant reductions in both myosin- and Ca2+-regulated myofibril adenosinetriphosphatase (ATPase) activity and increases in the relative content of the low ATPase myosin isozyme, V3, occurred in the hearts of the two trained groups (P less than 0.05). These findings suggest that chronic exercise involving normal and sympathectomized neonatal rats improves cardiac function without compromising maximal exercise capacity. Also, the exercise-related adaptation involving myosin isozyme shifts are exaggerated when involvement of the sympathetic nervous system is reduced during training.     

Postexercise muscle and liver glycogen metabolism in male and female rats

Male and female Wistar rats were run for 5 min at 1.7 mph at a 17% grade to determine whether a sex difference exists in the rate of glycogen resynthesis during recovery in fast-twitch red muscle, fast-twitch white muscle, and liver. Rats were killed at one of three time points: immediately after the exercise bout, and at 1 or 4 h later. Males had significantly higher resting muscle glycogen levels (P less than 0.05). Exercise resulted in significant glycogen depletion in both sexes (P less than 0.01). Males utilized approximately 50% more glycogen during the exercise bout than females (P less than 0.05). During the food-restricted 4-h recovery period, muscle glycogen was repleted significantly during the 1st h (P less than 0.05). Liver glycogen was not depleted as a result of the exercise bout, but fell during the first h of recovery (P less than 0.05) and remained low during the subsequent 3 h. The greater glycogen utilization in red and white fast-twitch muscle during exercise by males could represent a true sex difference but could also be attributable in part to the males having performed more work as a result of 20% greater body mass. We conclude that no sex difference was observed in the rates of muscle glycogen repletion after exercise or in liver glycogen metabolism during and after exercise, and rapid postexercise muscle glycogen repletion occurred at a time of accelerated liver glycogen depletion.     

Kinetic properties of pyruvate kinase from the epaxial muscle of the marine fishes Mugil lisa and Chaetoditerus faber

Kinetic studies were carried out on the reaction catalyzed by pyruvate kinase (ATP:pyruvate phosphotransferase, E.C. 2.7.1.40) purified from white striated (epaxial) muscle of two marine fish Mugil lisa (Brazilian mullet) and Chaetoditerus faber (harvest fish). This included the establishment of kinetic parameters. Attention was given to the effect of fructose 1,6-bisphosphate (Fru-P2) on PK activity. Effects of ATP, alanine and the divalent ions, Mg2+, Mn2+, Cu2+, Be2+ and Co2+, on the fish muscle enzyme were also studied.     

Alterations in physiological functions and in brain monoamine content in the sympathectomized rats

In the present study, we conducted pre-ganglionic decentralization (or sympathetic trunk resection) of the superior cervical ganglia and observed alterations in several physiological functions and in the monoamine content of different brain regions. Over an ambient temperature range of 8-30 degrees C, these sympathectomized rats maintained their rectal temperatures within a normal limit displayed by the intact controls. These sympathectomized animals, although showing no change in the level of spontaneous pain threshold or motor activity, did display an increased sensitivity of analgesic responses to morphine administration or locomotor stimulant responses to amphetamine administration. Biochemical examination revealed that these sympathectomized animals had a higher level of norepinephrine, dopamine or 5-hydroxytryptamine in the hypothalamus, as well as a higher level of dopamine in the corpus striatum. However, in the brainstem, these sympathectomized animals had a unaltered monoamine level. The data indicate that, in a sympathectomized condition, changes in the monoamine content of different brain regions may be correlated with the above-mentioned alterations in somatosensory and motor neural functions.     

Changes in nitric oxide in heart of intact and sympathectomized rats of different age

Nitric oxide production in heart tissues of rats of different age in the norm and after pharmacological sympathectomy was studied by electron spin resonance spin-trapping. Rats at the age of 14, 21, 70, and 100 days were used in the experiment. The concentration of nitric oxide produced in rat heart tissues proved to considerably decrease during ontogeny. Pharmacological sympathectomy notably decreased nitric oxide production in the heart in 14-and 21-day-old rats: the nitric oxide concentration in the spin trap as well as the level of R and T conformers of hemoglobin nitrosyl complexes decreased. In 70-day-old rats, pharmacological sympathectomy had no notable effect on the level of nitric oxide-containing paramagnetic complexes.     

Calcitonin gene-related peptide and substance P contribute to reduced blood pressure in sympathectomized rats

CGRP and substance P (SP) are produced in dorsal root ganglia (DRG) sensory neurons and modulate vascular tone. Sympathetic and sensory nerves compete for NGF, a potent stimulator of CGRP and SP, and it has been suggested that sympathetic hyperinnervation in spontaneously hypertensive rats may reduce the availability of NGF to sensory nerves, thus reducing CGRP and SP. The purpose of this study was to determine whether destruction of peripheral sympathetic nerves in normal rats would increase the availability of NGF for sensory neurons and enhance expression of CGRP and SP. Sympathectomy was produced in rats by guanethidine sulfate administration. Control rats received saline. Sympathectomized rats displayed reductions in blood pressure (BP) and atria norepinephrine levels, whereas NGF levels in the DRG, spleen, and ventricles were increased. Sympathectomy also enhanced CGRP and SP mRNA and peptide content in DRG. Administration of CGRP and SP receptor antagonists increased the BP in sympathectomized rats but not in the controls. Thus sympathectomy enhances sensory neuron CGRP and SP expression that contributes to the BP reduction.     

Neuroendocrine changes in female rats born from streptozotocin-diabetic mothers

In adult female rats born from Streptozotocin-diabetic mothers, blood glucose measured under basal conditions or 30 min after glucose administration was similar to controls; however at 180 min 50% of offspring from diabetics was moderately hyperglycemic whereas 100% of controls were normoglycemic. The time of vaginal opening, and after maturity, the number of rats with regular estrous cycles was in the range of controls. After ovariectomy, control rats receiving estradiol showed a sharp increase of serum LH at 4 pm following progesterone treatment at 10 am, while rats born from diabetic mothers failed to modify serum LH. Estradiol receptors in cell nuclei and cytosolic progestin receptors were determined in anterior pituitary, hypothalamus and preoptic area of rats subjected to a 4-day estradiol treatment. Changes were statistically significant in the hypothalamus only, in that rats born from diabetic mothers showed reduced induction of progestin receptors coupled to increased binding of (3H)-estradiol in cell nuclei. These findings bring support for a hypothalamic defect in rats born from diabetic mothers, the reduction of hypothalamic progestin receptors being reflected in the reduced sensitivity to the positive feedback action of progesterone to release LH.     

Effects of exogenous growth hormone on skeletal muscle of young female rats

We examined the effects of exogenous growth hormone (GH) treatment on the soleus and rectus femoris muscles of young female rats. Rat GH (1.8 IU/mg) was administered for 3 weeks by subcutaneous injection, twice a day, at doses of 0.5, 0.6, and 0.8 mg/day during the 1st, 2nd, and 3rd week, respectively. Final body weight, as well as wet and dry weight, of the soleus and rectus femoris muscles were significantly greater in the GH-treated group, compared to controls. Muscle weight to body weight ratios did not differ between the two groups. The fiber type composition of the soleus muscle was determined by histochemical staining for myosin ATPase activity. No statistically significant difference was found between the GH-treated and the control groups in the percentages of fiber types. However, GH treatment significantly increased the cross-sectional area of type II fibers of the soleus muscle. These results suggest that, in young female rats, acceleration of body weight gain by homologous GH administration is accompanied by a proportional hypertrophy of skeletal muscle mass. Increased muscle mass is due to hypertrophy of muscle fibers. Type II muscle fibers appear to be more sensitive to GH stimulation.