Effect of foreign innervation on the androgen-sensitive levator ani muscle of the rat

Summary Cross-union of the tibial with the pudendal nerve innervating the androgen-sensitive levator ani (LA) muscle of male rats, results in reversal of the histochemical muscle fibre pattern concerning myofibrillar ATPase, succinate dehydrogenase and phosphorylase enzyme activities. The homogeneous muscle fibre pattern of the LA muscle is changed to a mosaic pattern of muscles normally innervated by the tibial nerve. The success of the hetero-reinnervation is shown by practically full recovery of muscle weight and of isometric twitch-contraction properties of the LA muscle. Castration of 2-months duration, i. e. lack of the male sex hormone, leads to marked atrophy but no change in histochemical muscle fibre pattern. Hetero-reinnervation of the LA muscle results in change of histochemical enzyme pattern even if the cross-union of nerves is performed after long periods of castration leading to very marked decrease of muscle fibre size. However, testosterone application alone after castration increases markedly muscle fibre size but does not lead to reversal of muscle fibre pattern. The myotropic hormonal influence on the target (LA) muscle is therefore primarily of myogenic origin and specificity of hormonal action is maintained even with a foreign nerve innervating the muscle. The experiments, thus, provide evidence for the differentiation of specific neural influences affecting muscle fibre pattern and hormonal influences in respect to the myotropic action of the sex hormone on the androgen-sensitive LA muscle.     

Transplantation and transposition of skeletal muscles into the faces of monkeys

Restoration of normal facial movement after long-term facial paralysis with muscle atrophy has not yet been achieved reliably by either free grafts, in which fibers degenerate and regenerate, or by grafts made with microneurovascular repair, in which most fibers survive. Our purpose was to compare the structural and functional properties of free muscle grafts and continuously perfused muscle flaps transplanted into the faces of monkeys. In adult monkeys, the facial muscles were replaced by either a free graft of a donor muscle from the lower limb or a denervated flap of ipsilateral temporalis muscle. Each graft or flap was reinnervated with the preserved buccal branch of the facial nerve. The control muscles, grafts, and flaps were examined 90 days later for gross appearance, contractile properties, and fiber areas. Compared with muscle flaps, free grafts showed greater adaptability to the new location and innervation and a closer approximation to the structural and functional properties of the original facial musculature.     

Innervation of free muscle grafts in the rat in the absence of mechanical trauma to surrounding muscles or nerves.

Soleus muscles in the rat were freely grafted alongside a normal soleus muscle in the absence of mechanical trauma to any of the surrounding muscles or motor nerves. The object of this experiment was to determine whether or not the muscle grafts would become reinnervated under these circumstances. Contractile and histochemical properties of the grafts were compared with those of the contralateral denervated soleus as well as normal muscles. Innervation of the grafts did occur, and it was concluded that the innervation of the grafts arose primarily from sprouts from nerves supplying neighboring muscles. The grafts were studied with specific nerve stains, histochemical techniques and by analysis of their contractile properties.     

Reinnervation of the rat levator ani muscle after neonatal denervation

After axonal injury on postnatal day 14 (P14), but not P21, motoneurons in the spinal nucleus of the bulbocavernosus (SNB) do not display their normal response to circulating testosterone levels. This could result from a permanent disruption of communication between motoneurons and their testosterone-sensitive target muscles. We assessed the extent of reinnervation of one of these target muscles, the levator ani (LA) muscle, 5 months after the pudendal nerve was cut either on P14 or P21. The number of motoneurons innervating the LA in control and nerve cut animals was determined using retrograde labeling procedures. Functional recovery of the LA muscle was determined via the testing of its in situ contractile properties. Compared to control muscles, reinnervated LA muscles were smaller, had fewer muscle fibers, generated a lower maximum tetanic tension, and were more fatigable. In spite of the fact that fewer motoneurons reinnervated the LA muscle after nerve cut on P14 than on P21, there were no differences in the weight or contractile properties of the LA muscle between these two groups. These data suggest that motoneurons that survived injury on P14 innervated more muscle fibers than normal and exhibited a similar ability to functionally reinnervate the target muscle as those motoneurons that survived injury on P21.     

Regeneration and transplantation of muscles in old rats and between young and old rats.

In order to compare the regenerative ability of skeletal muscle between young (5 month) and old (26 month) rats, sliced or intact extensor digitorum longus muscles were freely autografted into young and old rats and also reciprocally grafted from young to old inbred animals and vice versa. Sixty days after grafting, the transplants were analyzed for contractile and histochemical properties. There was a relative similarity between the contraction times of both normal control muscles and of all groups of transplants, although the contraction time tended to be prolonged and histochemical fiber pattern was more often found to be uniform in grafts of senescent animals. All groups of transplants possessed histochemically heterogeneous fiber types at 60 days. The experiments demonstrate that skeletal muscle in old rats possesses a substantial degree of regenerative ability and that the free tranpllantation of entire muscles in old animals is feasible.     

Functional properties of palmaris longus muscles of rhesus monkeys transplanted as index finger flexors

This experiment with skeletal muscle autografts in monkeys was designed to retest previous findings that transplanted skeletal muscle can regenerate to a functional degree in primates without predenervation and to test a new hypothesis that increased functional demands on regenerated muscle grafts in monkeys may result in improved functional capacity of the grafts. Rhesus monkey index flexors were replaced with free palmaris longus muscle autografts with microneural anastomoses between the graft motor nerve and the severed profundus motor nerve. One monkey was taught selective index flexion before grafting and continued with this program after grafting to test the effect of training on the graft. Mature grafts were evaluated for in vivo contractile properties and by histology and histochemistry and were compared with a group of normal Rhesus palmaris longus muscles. The results reconfirm the capacity of nonpredenervated monkey skeletal muscle grafts to regenerate and to achieve some contractile ability and suggest that training of free muscle grafts may enhance recovery of their functional and structural properties.     

Plasticity of skeletal muscle: regenerating fibers adapt more rapidly than surviving fibers

The properties of mammalian skeletal muscle demonstrate a high degree of structural and functional plasticity as evidenced by their adaptability to an atypical site after cross-transplantation and to atypical innervation after cross-innervation. We tested the hypothesis that, regardless of fiber type, skeletal muscles composed of regenerating fibers adapt more readily than muscles composed of surviving fibers when placed in an atypical site with atypical innervation. Fast muscles of rats were autografted into the site of slow muscles or vice versa with the donor muscle innervated by the motor nerve to the recipient site. Surviving fibers in donor muscles were obtained by grafting with vasculature intact (vascularized muscle graft), and regenerating fibers were obtained by grafting with vasculature severed (free muscle graft). Our hypothesis was supported because 60 days after grafting, transposed muscles with surviving fibers demonstrated only a slight change from the contractile properties and fiber typing of donor muscles, whereas transplanted muscles with regenerating fibers demonstrated almost complete change to those of the muscle formerly in the atypical site.     

Relationship among fibre type, myosin ATPase activity and contractile properties

Summary At least two types of skeletal muscle myosin have been described which differ in ATPase activity and stability in alkaline or acidic media. Differences in ATPase characteristics distinguish Type I and Type II fibres histochemically. In this study, ATPase activity of myosin from muscles of several species with known histochemical and contractile properties has been determined to test the hypothesis that (1) myosin ATPase activity, (2) histochemical determination of fibre types and (3) maximum shortening velocity, all provide equivalent estimates of contractile properties in muscles of mixed fibre types. Maximum shortening velocity appears to be proportional to ATPase activity as expected from previous reports by Barany. However, both myosin ATPase and the maximum shortening velocity exhibit curvilinear relationships to the fraction of cross-sectional area occupied by Type II fibres. Therefore, we reject the hypothesis and conclude that histochemically determined myofibrillar ATPase does not accurately reflect the intrinsic ATPase activity or shortening velocity in muscles of mixed fibre types. Our data are consistent with the presence of more than two myosin isozymes or with a mixture of isozymes within single muscle fibres.     

Effect of the survival of xenografts in animals

A method of free xenotransplantation of skeletal muscles (from rat donors) to another species (mouse, hamster or guinea pig) has been elaborated. It has been shown that the muscle (gastrocnemius) of the donor animal acquires the property to survive and develop when wrapped in a cellophane film. The muscle should be kept wrapped in a cellophane film for up to 330 days. The transplanted muscle can survive and develop, acquiring normal histological structure, typical motor innervation and contractile activity. For xenotransplantation a fragment of the donor muscle corresponding to the size of the removed recipient muscle was excised. Mouse and hamster recipients were last examined 330 days, and guinea pigs 60 days after transplantation.     

Histochemical fiber type distribution and epinephrine sensitivity in normal and cross-transplanted rat muscles

The metabolic integrity of fully regenerated transplants was investigated by measuring induced changes in glycogen concentration. The extensor digitorum longus and the soleus muscles were cross transplanted: the extensor digitorum longus into the soleus muscle bed (SOLT) and the soleus muscle into the extensor digitorum longus bed (EDLT). The histochemical fiber type distribution of the regenerated muscles was determined and was found to transform in cross-transplanted EDLT and SOLT. After transplantation and regeneration, both muscles had initially low glycogen concentrations. However, the EDLT glycogen concentration was not significantly different from that of the contralateral extensor digitorum longus control muscle after 60 days. In the SOLT, glycogen gradually increased but remained less than in the contralateral soleus control muscle. SOLT and control soleus muscles responded with a significant glycogen depletion to an epinephrine dose two orders of magnitude less than the lowest dose affecting glycogen levels in EDLT and extensor digitorum longus muscles. These results indicate that transplanted muscles are capable of regenerating normal glycogenolytic responses and that the sensitivity of the response observed depends on the site of transplantation and is related to the type of innervation and histochemical fiber type.     

Regeneration of skeletal muscle after grafting in monkeys.

Twenty-five palmaris longus muscles were transplanted into the forearm (orthotopic autografts) or into the face (heterotopic autografts) in 15 Rhesus monkeys. These muscles were transplanted with or without anastomosis to a motor nerve. No significant difference was observed long-term between the grafts done with or without prior denervation of the muscle. The forearm muscle grafts without neurorrhaphies formed a static, fibrous sling which did not contract. The forearm autografts with neurorrhaphy and the grafts to the face, with or without neurorrhaphy, all developed regenerating skeletal muscle fibers and showed contractile activity.     

Plasticity in mammalian skeletal muscle.

While it has been recognized for many years that different limb muscles belonging to the same mammal may have markedly differing contractile characteristics, it is only comparatively recently that it has been demonstrated that these differences depend upon the motor innervation. By appropriately changing the peripheral nerve innervating a mammalian skeletal muscle, it is possible to change dramatically the contractile behaviour of the reinnervated muscle. The manner by which the motor innervation determines the nature of a muscle fibre's contractile machinery is not completely understood, but it appears that the number and pattern of motor nerve impulses reaching the muscle play an important role. The biochemical changes occurring within muscle fibres whose contractile properties have been modified by altered motor innervation include the synthesis of different contractile proteins.     

Histochemical and Ultrastructural Features of the Biceps Brachii of the African Chameleon (Chamaeleo senegalensis)

Abstract Characteristics of reptilian muscle fibres were investigated in the biceps brachii of the African chameleon, Chamaeleo senegalensis. Fibres were classified as slow and fast. These types of fibre were distinguished on the basis of histochemical staining for myofibrillar ATPase (mATPase). Fast fibres stained dark for mATPase while slow fibres stained light. The patterns of innervation of slow and fast fibres were investigated by staining nerve endings for acetylcholinesterase activity. Slow fibres have a pattern of multiple innervation, whereas fast fibres are associated with individual endplates. The organization of the myofibrils and the sarcoplasmic reticulum in slow muscle fibres from the chameleon biceps brachii was compared with that in fast fibres. Slow fibres lacked an M-line and the Z-lines were uneven. They had fibrils that were not clearly separated from each other and the sarcoplasmic reticulum was poorly developed. These features are in sharp contrast to those of fast fibres which had straight Z-lines, clear M-lines and well-developed sarcoplasmic reticulum.     

Ultrastructural transformation of fast chicken muscle fibres induced by nerve cross-union

Summary The fast posterior latissimus dorsi (PLD) muscle of newly hatched chickens was transposed and cross-innervated by the slow-type nerve originally innervating the anterior latissimus dorsi (ALD) muscle. The innervation and the ultrastructure of the cross-innervated posterior latissimus dorsi (PLD-X) muscle was investigated from one week up to 18 months after the operation and compared with that of the control fast (PLD-C) and control slow (ALD-C) muscles. All nerve terminals in the PLD-X muscle were of the slow type. Yet the degree of ultrastructural transformation differed from fibre to fibre. Only about 30% of PLD-X fibres had transformed ultrastructure closely resembling the control slow fibres. In this group of maximally altered fibres, the myofibrils had large diameters, wide Z lines and indistinct M lines as the control slow fibres. The amount of mitochondria was increased to levels found in control slow fibres. The mean percentage of triads was also comparable to that of control slow fibres, being approximately by two thirds lower than in control fast fibres.The differences in the degree of ultrastructural transformation are presumably due to different plasticity of muscle cells at the time of cross-innervation. In the transposed PLD-X muscles large areas undergo degeneration and regeneration. It is suggested that an almost complete changeover of the fibre type is only brought about after cross-innervation of newly differentiating muscle cells, whereas partial alteration occurs after reinnervation of young myofibres.The skillful technical assistance of Dr. Z. Liková, Mrs. M. Sobotková, Ing. M. Doubek and Mr. H. Kunz is gratefully acknowledged.     

Differentiation of slow and fast muscles in chickens

1. The development of the characteristic histochemical appearance of the slow anterior latissimus dorsi (ALD) and fast posterior latissimus dorsi (PLD) was studied in chickens during embryonic development as well as during regeneration of minced muscle. 2. During embryonic development the activity of the oxidative enzyme succinic dehydrogenase (SDH) is higher in the slow ALD muscle already at 16 days of incubation. At this time the fast PLD has a higher activity of the glycolytic enzyme, phosphorylase. Although the histochemical appearance of the two types of muscle is already different at 16 days, their contractile speeds are still similar. No difference in myosin ATP-ase was found in the two muscles in young embryos but in 20-day old embryos the two muscles became distinctly different when stained for this enzyme. 3. When PLD muscles in hatched chickens redeveloped during regeneration in place of ALD the histochemical characteristics of the regenerated muscle resembled ALD, and when ALD regenerated in place of PLD it resembled PLD. 4. It is concluded that the histochemical characteristics of slow and fast muscles become determined during early development, even before any difference in contractile properties can be detected and that they are determined by the nerve.     

Myosin heavy chain isoform composition in striated muscle after denervation and self-reinnervation

The total content of myosin heavy chains (MHC) and their isoform pattern were studied by biochemical methods in the slow-twitch (soleus) and fast-twitch (extensor digitorum longus) muscles of adult rat during atrophy after denervation and recovery after self-reinnervation. The pattern of fibre types, in terms of ultrastructure, was studied in parallel. After denervation, total MHC content decreased sooner in the slow-twitch muscle than in the fast-twitch. The ratio of MHC-1 and the MHC-2B isoforms to the MHC-2A isoform decreased in the slow and the fast denervated muscles, respectively. After reinnervation of the slow muscle, the normal pattern of MHC recovered within 10 days and the type 1 isoform increased above the normal. In the reinnervated fast muscle, the 2B/2A isoform ratio continued to decrease. Traces of the embryonic MHC isoform, identified by immunochemistry, were found in both denervated and reinnervated slow and fast muscles. A shift in fibre types was similar to that found in the MHC isoforms. Within 2 months of recovery a tendency to normalization was observed. The results show that (a) MHC-2B isoform and the morphological characteristics of the 2B-type muscle fibres are susceptible to lack of innervation, similar to those of type 1, (b) during muscle recovery induced by reinnervation the MHC isoforms and muscle fibres shift transiently to type 1 in the soleus and to type 2A in the extensor digitorum longus muscles, and (c) the embryonic isoform of MHC may appear in the adult skeletal muscles if innervation is disturbed.     

Morphological effects of ciliary neurotrophic factor treatment during neuromuscular synapse elimination

In adult skeletal muscles, exogenous ciliary neurotrophic factor (CNTF) induces axons and their nerve terminals to sprout. CNTF also regulates the amount of multiple innervation in developing skeletal muscles during synapse elimination, maintaining multiple innervation of muscle fibers. While CNTF may maintain multiple innervation by regulating developmental synapse elimination, it is also possible that CNTF induces the formation of new multiple innervation through a sprouting response. In this study I examined morphologically the effects of CNTF during synapse elimination in the extensor digitorum longus (EDL) muscle. Rat pups received injections of CNTF in one leg and vehicle in the other either early [postnatal day 7 (P7)-P13] or late (P14–P20) in development. The early treatment period corresponds to that time when the pattern of innervation in the EDL is converted from predominantly multiple to single innervation. The late treatment period is at the end of synapse elimination for the EDL but corresponds to the major period of synapse elimination in the levator ani (LA), allowing a comparison of effects on these two muscles from the same animals. On the day after the final injection, EDL muscles were dissected and stained with tetranitroblue tetrazolium and the resulting pattern of innervation was assessed. The present findings indicate that only the early CNTF treatment regulates the level of multiple innervation in the EDL. Moreover, the effect of early CNTF treatment was local, affecting multiple innervation only in the EDL from the CNTF-treated leg. CNTF injected during the late treatment period had no apparent effects on the EDL but had a potent effect on the pattern of innervation in the LA, significantly increasing the level of multiple innervation in this muscle. Thus, CNTF affected multiple innervation in these two muscles only if provided during the period when single innervation normally develops. There was no evidence to indicate that CNTF induced axons or their terminals to sprout during either treatment period. In conclusion, CNTF increases the level of multiple innervation, probably by regulating synapse elimination, and skeletal muscles themselves may be an important target site for CNTF action. Presumably, the sprouting response to CNTF found in adult muscle develops sometime after P21. © 1996 John Wiley & Sons, Inc.     

Muscles of the pelvic outlet in the fowl (Gallus gallus domesticus) with special reference to their nerve supply.

The manner of innervation of the pelvic outlet muscles in fowl (Gallus gallus domesticus) was examined in detail in four male pelvic halves. The segmental arrangement of the nerve supply in the sacral and pudendal plexuses was compared to that of Lacertilia and Urodela as a basis for a morphological analysis of the pelvic outlet muscles. From the viewpoint of innervation, the pelvic outlet muscles of fowl are classified into two groups: a sphincter muscle group and a levator muscle group. These two groups are closely related to the ventral muscles of the pelvic limb. In contrast to the morphology of pelvic outlet muscles in lacertilians, in fowl the caudal muscle element does not contribute to the formation of these muscles.     

Lack of fiber type selectivity during reinnervation of neonatal rabbit soleus muscle

Fast and slow contracting fibers in neonatal mammalian skeletal muscle are each innervated in a highly specific manner by motor neurons of the corresponding type, even at an age when polyinnervation is widespread. Chemospecific recognition is a possible mechanism by which this pattern of innervation could be established. We have investigated this possibility by studying the degree of specificity during reinnervation of rabbit soleus muscle following nerve crush on Postnatal Day 1 or 4. We assayed fiber type composition by measuring the twitch rise times of motor units within 2 days of the onset of functional reinnervation (5-6 days after nerve crush). In contrast to the broad, bimodal distribution of single motor unit twitch rise times seen in normal muscles, motor units in reinnervated muscles yielded a narrower, unimodal distribution of rise times. Rise times of reinnervated units were intermediate to those of normal fast and slow units, suggesting that reinnervated units were composed of a mixture of fast and slow contracting fibers. An alternative possibility, that specific reinnervation was masked by contractile dedifferentiation of muscle fibers, was examined by maintaining a transmission blockade induced by botulinum toxin poisoning for an equivalent interval. Twitch rise times of treated motor units exhibited the distinctly bimodal distribution characteristic of normal muscles, suggesting that muscle fibers can retain contractile diversity during a transient period of denervation. We carried out computer simulations to estimate the amount of rise time diversity induced by varying degrees of specificity during reinnervation. Based on this analysis, we conclude that there is little if any selective reinnervation of muscle fiber types at the ages studied.     

Restoration of fast muscle characteristics following cessation of chronic stimulation: physiological, histochemical and metabolic changes during slow-to-fast transformation

Implantable electronic stimulators were used to subject fast-twitch tibialis anterior and extensor digitorum longus muscles of adult rabbits to a chronically increased level of use. Stimulation was discontinued after 6 weeks and physiological, histochemical and biochemical properties of the muscles were examined at intervals over the ensuing 20 weeks. Previous work had shown that 6 weeks of stimulation was sufficient to bring about a substantial transformation of type in fast-twitch muscles, which then exhibited much of the character of muscles of the slow-twitch type. The present experiments showed that these stimulation-induced changes were completely reversible. The time-course of reversion was such that the muscles had recovered their original fast properties by about 12 weeks after the cessation of stimulation. The contractile characteristics and post-tetanic potentiation typical of fast muscle returned rapidly, in only 3-4 weeks, and over the same period the proportion of histochemical type 1 fibres declined from about 70% to control levels. Changes in fatigue-resistance, capillary density and enzyme activity followed a more prolonged time-course; in particular, the decline in the activity of enzymes of oxidative metabolism corresponded closely to that already established for the mitochondrial volume fraction. Reacquisition of fast properties was not accompanied by any changes in specific force-generating capacity. Observations from these experiments and from a related morphological study fit into a 'first-in, last-out' pattern for the response to stimulation and recovery. The slow-to-fast reversion that takes place during the recovery period provides a further opportunity for testing causal associations within the events underlying type transformation. It has important consequences for therapeutic applications that make use of the fatigue-resistant character of chronically stimulated muscle.