Age-dependent decline in density of human nerve and spinal ganglia neurons expressing the α3 isoform of Na/K-ATPase.

Ambulatory instability and falls are a major source of morbidity in the elderly. Age-related loss of tendon reflexes is a major contributing factor to this morbidity, and deterioration of the afferent limb of the stretch reflex is a potential contributing factor to such age-dependent loss of tendon reflexes. To evaluate this, we assessed the number and distribution of muscle spindle afferent fibers in human sacral spinal ganglia (S1) and tibial nerve samples obtained at autopsy, using immunohistochemical staining for the α3 isoform of Na(+), K(+)-ATPase (α3NKA), a marker of muscle spindle afferents. Across all age groups, an average of 26 ± 4% of myelinated fibers of tibial nerve and 17 ± 2% of ganglion neuronal profiles were α3NKA-positive (n = 8 per group). Subject age explained 85% of the variability in these counts. The relative frequency of α3NKA-labeled fibers/neurons starts to decline during the 5th decade of life, approaching half that of young adult values in 65-year-old subjects. At all ages, α3NKA-positive neurons were among the largest of spinal ganglia neurons. However, as compared to younger subjects, the population of α3NKA-positive neurons from advanced-age subjects showed diminished numbers of large (both moderately and strongly labeled), and medium-sized (strongly labeled) profiles. Considering the critical significance of ion transport by NKA for neuronal activity, our data suggest that functional impairment and, also, most likely atrophy and/or degeneration of muscle spindle afferents, are mechanisms underlying loss of tendon reflexes with age. The larger and more strongly α3NKA-expressing spindle afferents appear to be proportionally more vulnerable.

Some gamma-motoneurons contain gamma-aminobutyric acid in the rat cervical spinal cord.

Gamma-aminobutyric acid (GABA) is utilized in the peripheral as well as central nervous system. In this study, fibers immunoreactive for 67 kDa isoform of glutamic acid decarboxylase (GAD67), an enzyme which synthesizes GABA, were found to terminate in the intercapsular region of muscle spindles of the upper limb. GABA-containing fibers were also found in the ventral roots of C5 to T5 spinal segments, brachial plexus, and radial nerve. These fibers were thin and immunoreactive for choline-acetyl transferase (ChAT). After transection of the brachial plexus, GABA immunoreactivity disappeared completely in the ipsilateral triceps brachii muscle (TBM). After the injection of fluorogold into the TBM, some retrogradely labeled medium-sized neurons were positive for GAD67, but not VGAT mRNA. All these observations clearly indicate that GABA-containing gamma-motoneurons in the lower cervical spinal cord send their fibers to muscle spindles in the upper extremities. Since we detected neither GABAA nor GABAB receptors in the TBM by RT-PCR, the function of the GABA-containing gamma-motoneurons remains unclear.

Phylogenetic preservation of alpha3 Na+,K+-ATPase distribution in vertebrate peripheral nervous systems.

The alpha(3) isoform of Na(+),K(+)-ATPase is uniquely expressed in afferent and efferent neurons innervating muscle spindles in the peripheral nervous system (PNS) of adult rats, but the distribution pattern of this isoform in other species has not been investigated. We compared expression of alpha(3) Na(+),K(+)-ATPase in lumbar dorsal root ganglia (DRG), spinal roots, and skeletal muscle samples of amphibian (frog), reptilian (turtle), avian (pigeon and chicken), and mammalian (mouse and human) species. In all species studied, the alpha(3) Na(+),K(+)-ATPase isoform was nonuniformly expressed in peripheral ganglia and nerves. In spinal ganglia, only 5-20% of neurons expressed this isoform, and, in avian and mammalian species, these alpha(3) Na(+),K(+)-ATPase-expressing neurons belonged to a subpopulation of large DRG neurons. In ventral root fibers of pigeons, mice, and humans, the alpha(3) Na(+),K(+)-ATPase was abundantly expressed predominantly in small myelinated axons. In skeletal muscle samples from turtles, pigeons, mice, and humans, alpha(3) Na(+),K(+)-ATPase was detected in intramuscular myelinated axons and in profiles of nerve terminals associated with the equatorial and polar regions of muscle spindle intrafusal fibers. These results show that the expression profiles for alpha(3) Na(+),K(+)-ATPase in the peripheral nervous system of a wide variety of vertebrate species are similar to the profile of rats and suggest that stretch receptor-associated expression of alpha(3) Na(+),K(+)-ATPase is preserved through vertebrate evolution.

Involvement of adenylate cyclase and tyrosine kinase signaling pathways in response of crayfish stretch receptor neuron and satellite glia cell to photodynamic treatment.

Neuroglial interactions are most profound during development or damage of nerve tissue. We studied the responses of crayfish stretch receptor neurons (SRN) and satellite glial cells to photosensitization with sulfonated aluminum phthalocyanine Photosens. Although Photosens was localized mainly in the glial envelope, neurons were very sensitive to photodynamic treatment. Photosensitization gradually inhibited and then abolished neuron activity. Neuronal and glial nuclei shrank. Some neurons and glial cells lost the integrity of the plasma membrane and died through necrosis after the treatment. The nuclei of other glial cells but not neurons become fragmented, indicating apoptosis. The number of glial nuclei around neuron soma increased, probably indicating proliferation for enhanced neuron protection. Adenylate cyclase (AC) inhibition by MDL-12330A, or tyrosine kinase (TK) inhibition by genistein, shortened neuron lifetime, whereas AC activation by forskolin or protein tyrosine phosphatases (PTP) inhibition by sodium orthovanadate prolonged neuronal activity. Therefore, cAMP and phosphotyrosines produced by AC and TK, respectively, protected SRN against photoinactivation. AC inhibition reduced photodamage of the plasma membrane and subsequent necrosis in neuronal and glial cells. AC activation prevented apoptosis in photosensitized glial cells and stimulated glial proliferation. TK inhibition protected neurons but not glia against photoinduced membrane permeabilization and subsequent necrosis whereas PTP inhibition more strongly protected glial cells. Therefore, both signaling pathways involving cAMP and phosphotyrosines might contribute to the maintenance of neuronal activity and the integrity of the neuronal and glial plasma membranes. Adenylate cyclase but not phosphotyrosine signaling pathways modulated glial apoptosis and proliferation under photooxidative stress.

Intrafusal fiber type composition of muscle spindles in the first human lumbrical muscle.

We studied muscle spindles in the first lumbrical muscle of adult humans using myofibrillar ATPase (mATPase) activity. We found that muscle spindles exhibited a marked variability with respect to the number, position, length and detailed histochemical features of nuclear bag1, nuclear bag2 and nuclear chain fibers. Regarding mATPase activity, the nuclear bag2 fibers displayed lower alkali-stable mATPase activity along their length and many nuclear bag1 fibers tended to have lower acid-stable activity in the outer B region, whereas nuclear chain fibers exhibited medium acid-stable mATPase activity at pH 4.6. Almost 10% of spindle fibers displayed atypical features, as they were either located only at one spindle pole or exhibited mixed characteristics at either pole. The number of intrafusal fibers per spindle varied between 8 and 24. Strikingly, only 2 pairs from 22 muscle spindles had identical allotments of their intrafusal fibers. Muscle spindles in the first human lumbrical muscle contained more intrafusal fibers (12.3 +/- 4 per spindle on average) and especially relatively more nuclear bag fibers compared to other human skeletal muscles. Since each spindle apparently represents a unique morphological and physiological entity, the observed variability in the number and characteristics of intrafusal fibers in the first human lumbrical muscle likely reflects a wide range of finely tuned muscle spindle responses.

Acetylcholinesterase activity in soleus muscle intrafusal and extrafusal fibres in tail suspended rats.

Objective. To explore the mechanisms involved in muscle atrophy and conversion of the fiber types induced by simulated weightlessness. Method. Weightlessness was simulated by tail suspension of female rats. Intrafusal and extrafusal fibers of soleus muscles in the rat were examined histochemically for their activity of acetylcholinesterase (AChE) and succinic dehydrogenase (SDH) in 7 d, 14 d, 21 d tail-suspended groups and control groups. Result. Staining for succinic dehydrogenase showed that simulated weightlessness caused obvious atrophy and change in fiber type composition in soleus muscle, with decrease of the proportion of type I fiber and increase of type II fiber. Acetylcholinesterase activities of intrafusal and extrafusal fibers were both decreased significantly after 21 d tail suspension. Conclusion. Simulated weightlessness could induce decrease of AChE activity in neuromuscular junctions, which might be linked with decrease in motor neuron activity.

Effects of chlorobutanol on primary and secondary endings of isolated cat muscle spindles.

The effects of the preservative chlorobutanol on primary and secondary endings of muscle spindles isolated from the tenuissimus muscle of the cat were investigated in this study. Chlorobutanol was applied to the bathing solution in final concentrations of between 10 and 100 microg/ml. It induced a reversible and dose dependent decrease in the discharge frequency of both types of ending without any visible length change in the sensory region of the receptor. The initial activity, the peak dynamic discharge, the maximum static discharge value and the final static discharge value were evaluated from an ending's discharge pattern obtained during ramp-and-hold stretches. These four basic discharge frequencies decreased in parallel with increasing concentrations of chlorobutanol. Their sensitivities to chlorobutanol were similar (mean values: -0.11 to -0.29 imp/s per microg/ml chlorobutanol) and were independent of the amplitude of stretch. The dynamic response and the static response of both primary and secondary endings remained unchanged, indicating that the sensitivity of the spindle to stretch was not influenced by chlorobutanol. Chlorobutanol also reduced the discharge activity of the muscle spindle afferents during sinusoidal stretches. The amplitude of the receptor potential (AC component) remained unchanged under chlorobutanol. With the available recording technique it was not possible to measure slow shifts of the membrane potential. However, a hyperpolarization of the ending's membrane might explain why the afferent discharge frequency is reduced by chlorobutanol. The calcium dynamics of the spindle do not appear to be altered by CB, as the effect exerted on the afferent discharge by a change in the extracellular calcium concentration and a blockage of calcium channels was different from the CB effect. As the inhibitory effect of CB was reduced by ouabain, it is possible that CB activates the electrogenic Na/K pump or affects a mechanism that is closely related to the activity of the pump. The properties of the axonal membrane appear not to be altered, as chlorobutanol did not change the shape of action potentials.

Stability of myosin heavy chain isoforms in selectively denervated adult rat muscle spindles.

BACKGROUND: Rat intrafusal fibers consist of multiple isoforms of myosin heavy chains (MHCs) whose expression involves complex interactions among motor neurons, sensory neurons, and muscle cells during spindle development. Little is known about the roles of sensory and motor innervation in regulating and maintaining expression of MHC isoforms in adult rat muscle spindles. METHODS: MHC expression was investigated in deafferented or deefferented adult rat muscle spindles by reacting transverse sections of spindles with a panel of monoclonal antibodies specific for different MHC isoforms. RESULTS: Deefferentation or deafferentation did not alter the number of intrafusal fibers expressing most MHC isoforms. However, the numbers of fibers expressing two MHC isoforms were altered in deefferented muscle spindles. Nuclear bag1 fibers ceased to express alpha-cardiac MHC and upregulated embryonic MHC after ablation of motor innervation. Likewise, bag2 and chain fibers downregulated avian neonatal/fast MHC following deafferentation, but chain fibers upregulated type 2A MHC and became more extrafusal-like in their pattern of MHC expression. CONCLUSIONS: These data indicate that (1) perturbations in spindle sensory and motor nerve supplies produce less severe alterations in MHC expression in mature intrafusal fibers than do similar lesions in developing intrafusal fibers and (2) MHC expression in intrafusal fibers reflects a combination of inductive and suppressive effects of motor and sensory neurons.

[Localization of DM-PK in normal and myotonic dystrophy muscles].

Myotonic dystrophy (DM) is an autosomal-dominant, multi-system disorder characterized by myotonia, progressive muscleatrophy and weakness. DM is also associated with smooth muscle, cardiac muscle, lens, endocrine and central nervous system abnormalities. The phenotypic expression of DM varies from asymptomatic adults to severely affected neonates. The genetic basis for DM is the expansion of a CTG repeat in the 3' end of a transcript that encodes a protein with putative serine/threonine protein kinase (myotonic dystrophy protein kinase, DM-PK). The predicted molecular weight of the full-length human DM-PK is about 69 kDa, while it may have some isoforms. DM-PK expression is observed in neuromuscular junction, muscle spindle, and sarcoplasm on both normal and DM muscles. Other muscular dystrophies, such as Duchenne and Becker type, DM-PK is intensively expressed in cytoplasm on immature regenerating fibers.

Immunocytochemical localization of Na, K-ATPase in rat muscle spindles.

In the muscle spindle, one of the major sensory receptors in the vertebrate skeletal muscle, it was demonstrated that stretching caused a conductance increase of the sensory terminal membrane mainly to Na+ (Hunt, Wilkinson and Fukami, 1978 (6)). Since the muscle spindle is a slowly adapting stretch receptor, and even at rest some spindles are active, a vigorous Na, K-pump activity is expected to counteract the incessant inflow of Na+ into the terminal. To test this assumption, rat muscle spindles were examined by immunofluorescence microscopy as well as by the electron microscopic immunogold technique using antibody against rat alpha-subunit of Na, K-ATPase. The results indicate that the sensory ending has the highest density of the enzyme among the other cellular components examined, and that the enzyme density appears to be higher in the plasma membrane of the sensory ending facing the intrafusal muscle fiber (synaptic membrane) than the rest of the membrane (extra-synaptic membrane). The functional significance of the above findings was discussed.

Immunohistochemical characterization of human masseter muscle spindles.

An enzyme- and immunohistochemical study has been performed on human masseter muscle spindles. Antibodies selective for different myosin heavy chain (MHC) isoforms and M-band proteins (M-protein, myomesin, and MM-CK) were used. The expression of these proteins was determined in the different intrafusal fiber types. Nuclear bag1 and nuclear bag2 fibers expressed predominantly slow-twitch and slow-tonic MHCs. The bag2 fibers in addition contained fetal MHC. Nuclear chain fibers coexpressed embryonic, fetal, and fast-twitch MHCs. The bag2 and chain fibers contained all three M-band proteins, whereas the bag1 fibers contained only myomesin. In general the MHC expression in the human masseter intrafusal fiber types was similar to that previously reported for limb muscles in man as well as for limb and masseter muscles in other species. However, the number of intrafusal fibers per spindle was unusually high (up to 36). This reinforces the idea that masseter muscle spindles have a strong proprioceptive impact during the control of jaw movements.

Fast and slow intrafusal fibre type systems in chicken leg muscle spindles.

The results of this study indicate that in serial sections incubated with monoclonal antibodies against MHC and stained for mATPase, intrafusal fibres in chicken leg muscle spindles are separable into slow and fast types. As observed here, fast fibres are a homogeneous group; however, it had been shown earlier (Maier & Zak, 1990) that based on relative amounts of slow MHC, the slow fibres can be further divided into 2 subgroups. These 3 types of intrafusal fibre conform to 3 recently demonstrated patterns of motor innervation (Maier, 1991). It is suggested that the respective actions of slow and fast intrafusal fibres produce different components of the afferent discharge of chicken muscle spindles.

Classification of the intrafusal muscle fibres in the frog muscle spindle: histochemical and immunofluorescent studies.

Intrafusal muscle fibres from bull-frog semitendinosus, iliofibularis and sartorius muscles were classified into three types using the histochemical, immunofluorescent and morphological characteristics, with reference to the extrafusal muscle fibres, which were classified into five types in accordance with Rowlerson & Spurway (1988). Immunofluorescent reactions with antibodies against slow or fast myosins obtained from anterior or posterior latissimus dorsi muscles (ALD or PLD), respectively, of chicken were used as the primary criterion. Histochemical profiles of muscle fibres were classified into nine types of myosin ATPase activity as the secondary criterion. Anti-PLD intrafusal fibres (polar zone) with ATPase profiles of moderate to high acid and alkaline stabilities correspond to large nuclear bag fibres in the classification of Diwan & Ito (1989), whereas anti-ALD fibres (polar zone) with alkaline-labile ATPase profiles correspond to medium nuclear bag fibres. On the basis of diameter, anti-PLD fibres (polar zone) with ATPase profiles of moderate to low acid stability and moderate to high alkaline stability seem to correspond to two types of small nuclear chain fibre. Variations between muscles, between intra- and extrafusal fibres and also between zones along intrafusal fibres are discussed.

An immunohistochemical approach to the intrafusal fibers of extraocular muscle spindles in sheep, cow, and pig.

Intrafusal muscle fibers of the extraocular muscles (EOMs) of the sheep, cow, and pig were studied histochemically and immunohistochemically. In sheep and cow spindles, three intrafusal fiber types, namely the bag1, bag2, and chain fibers, were identified by a combination of standard histochemical methods and immunohistochemical staining with antibodies selective for slow-tonic (antitonic ALD) and slow twitch (anti-I BA-D5) myosin. The bag1 and bag2 fibers appeared immunologically different on the basis of their differential reactivity with the two antisera. Anti-tonic ALD preferentially stained the bag1 fibers, whereas anti-I BA-D5 labeled the bag2 fibers. Chain fibers did not react with either antisera. In the pig EOM spindles, in general, one bag and some chain intrafusal fibers were identified. The bag fiber was labeled by anti-tonic ALD, but it did not react with the anti-I BA-D5. These findings point to the existence in pig EOM spindles of only one bag fiber antigenically similar to the bag1 fiber of the other species examined.

Individual differences in multiple-bag spindles of cat superficial lumbrical muscles.

A total of 791 spindle poles was analysed with regard to intrafusal fibre composition in the first and second superficial lumbrical muscles from the right and left hindfeet of 9 male and 5 female adult cats. Bag and chain muscle fibres were identified by their myofibrillar ATPase staining profile in the B region, after either acid or alkaline preincubation. A high proportion of the spindle pole population (43.2%) was observed to contain three or more (up to 5) bag fibres; those poles were classified as multiple-bag spindle poles. In the 334 muscle spindles in which both poles were studied, 42 bag fibres (12.6%) were found to be of the 'mixed' type, that is a fibre in which the two poles differ in their ATPase staining profile (either bag1/bag2 or bag/chain). The variability of the intrafusal fibre content observed in spindles of these muscles has been studied in relation to individual characteristics such as sex, weight and side of the animal. In general, multiple-bag spindles are more frequent in male than in female cats and in right as compared to left side muscles. Nearly all 'mixed' bag intrafusal fibres (38 out of 42) were observed in spindles containing 3 or more bag fibres. In 3-bag spindles the proportion of 'mixed' bag spindles is approximately the same in male and female cats. The ratio of 'dynamic' (mean polar bag1 content) to 'static' (mean polar bag2 plus chain fibre content) intrafusal effectors per muscle tends to increase in spindles of right side muscles and to decrease in the heaviest animals. The quantitative and qualitative differences in fibre content of spindles observed in first lumbrical muscles of different animals suggest that the spindle fibre composition, especially that of the 'dynamic' bag1 fibre, may be related to individual predetermined and/or acquired factors.

Influence of neonatal motor denervation on expression of myosin heavy chain isoforms in rat muscle spindles.

In order to evaluate the effects of fusimotor elimination on the expression of myosin heavy chain (MHC) proteins in intrafusal fibres, we compared the muscle spindles in hind limb muscles of 3- to 6-week-old rats de-efferented at birth with those of their litter-mate controls. Serial sections were labelled with antibodies against slow tonic, slow twitch, fast twitch and neonatal MHC isoforms, against synaptophysin, the neurofilament 68 kD subunit and laminin. We found that de-efferented intrafusal fibres differentiated, as in normal spindles, into nuclear bag and bag fibres both containing predominantly slow MHC, and nuclear chain fibres that contained fast and neonatal MHC. In both de-efferented and control intrafusal fibres the same MHCs were stained; the degree and extent of staining, however, varied. Both types of de-efferented bag fibres displayed a high content of slow tonic and slow twitch MHC along most of the fibre length, in contrast to the prominent regional variation in control bag fibres. In their encapsulated regions, the de-efferented bag fibres were more similar to each other in their reactivity to anti-fast twitch and anti-neonatal MHC antibodies than the control bag fibres. In these aspects they resembled more closely the bag fibres of newborn rats. The differences might be due to an arrest of "specialization" in the regional expression of the different MHC isoforms. Chain fibres developed MHC patterns identical to those of control spindles with all the antibodies used, even though they differentiated from the beginning in the absence of motor innervation. The structural differentiation of the capsule and sensory innervation in de-efferented muscle spindles, as shown by anti-laminin, anti-synaptophysin and anti-neurofilament staining, did not differ from the controls. We conclude, in agreement with previous studies, that the sensory innervation plays a key role in inducing and supporting the differentiation of intrafusal fibres and the specific expression of their MHC. However, we also show that motor innervation and/or muscle function seem to be necessary for the diversity in the expression and distribution of different slow and fast MHC isoforms in the bag and bag fibres.

Innervation of regenerated spindles in muscle grafts of the rat.

Features of the nerve supply and the encapsulated fibers of muscle spindles were assessed in grafted and normal extensor digitorum longus (EDL) muscles of rats by analysis of serial 10-microns frozen transverse sections stained for enzymes which delineated motor and sensory endings, oxidative capacity and muscle fiber type. The number of fibers was significantly more variable, and branched fibers were more frequently observed in regenerated spindles than in control spindles. Forty-eight percent of regenerated spindles received sensory innervation. Spindles reinnervated by afferents had a larger periaxial space than did spindles which were not reinnervated by afferents. Regenerated fibers innervated by afferents had small cross-sectional areas, equatorial regions with myofibrils restricted to the periphery of fibers, unpredictable patterns of nonuniform and nonreversible staining along the length of the fiber for 'myofibrillar' adenosine triphosphatase (mATPase) after acid and alkaline preincubation. In contrast, regenerated fibers devoid of sensory innervation resembled extrafusal fibers in that they usually exhibited myofibrils throughout the length of the fiber, no central aggregations of myonuclei, uniform staining for mATPase and a reversal of staining for mATPase after preincubation in an acid or alkaline medium. Approximately thirty percent of encapsulated fibers devoid of sensory innervation stained analogous to a type I extrafusal fiber, a pattern of staining never observed in intrafusal fibers of normal spindles. Groups of encapsulated fibers all exhibiting this pattern of staining reflect that either these fibers may have been innervated by collaterals of skeletomotor axons that originally innervated type I extrafusal fibers or that fibers innervated by only fusimotor neurons express patterns of staining for mATPase similar to extrafusal fibers in the absence of sensory innervation. Sensory innervation may also influence the reestablishment of multiple sites of motor endings on regenerated intrafusal fibers. Those regenerated fibers innervated by afferents had more motor endings than did regenerated fibers devoid of sensory innervation. Differences in size, morphology, and patterns of staining for mATPase and numbers of motor endings between fibers innervated by afferents and fibers devoid of sensory innervation reflect that afferents can influence the differentiation of muscle cells and the reestablishment of motor innervation other than during the late prenatal/early postnatal period when muscle spindles form and differentiate in rats.

Histochemical heterogeneity of intrafusal muscle fibres in slow and fast skeletal muscles of the rat.

Intrafusal muscle fibres of the slow soleus (Sol) and fast vastus lateralis (VL) muscles of the rat were studied histochemically. Serial transverse sections were incubated for the localization of succinate dehydrogenase (SDH), alpha glycerophosphate dehydrogenase (GPD) and adenosine triphosphatase (ATPase). The latter was examined further after preincubation in acidic solution held at either low or room temperature (RT). The bag2 intrafusal fibres in both muscles displayed high regular and acid stable ATPase, but low SHD and GPD activities. Bag1 intrafusal fibres showed low to moderate regular ATPase, a regional heterogeneity after RT acid preincubation (low activity in juxtaequatorial and high in polar zones), moderate SDH, but low GPD reactions. In both muscles the chain fibres usually exhibited high ATPase for both regular and cold acid preincubated reactions, but usually low activity after RT acid preincubation; they had high SDH but variable GPD activities. In Sol muscle, however, approximately 25% of spindles contained chain fibres that showed high acid-stable ATPase reaction after both cold and RT acid preincubation. In contrast, chain fibres in some VL spindles had a characteristically low ATPase reaction even after cold acid preincubation. This study, therefore, has delineated the existence of an inherent heterogeneity among chain fibres (with respect to their histochemical reactions) in muscle spindles located within slow and fast muscles and also between those found within populations of either Sol or VL muscle spindles.

Histochemical properties of intrafusal fibers in the soleus muscle of the aged rat.

ATPase reaction profiles of intrafusal fibers in the muscle spindle of the soleus muscle of 135-week-old rats were examined. Nuclear bag1 fibers contained an acid- and alkaline-labile form of the enzyme or an acid-labile and alkaline-stabile form, nuclear bag2 fibers contained an acid- and alkaline-stabile form, and nuclear chain fibers contained an acid-labile and alkaline-stabile form. These results indicate that the enzyme histochemical heterogeneity of intrafusal fibers is well-preserved during ageing.

Postnatal maturation of spindles in deafferented rat soleus muscles.

Whether the motor innervation can direct the morphological and histochemical differentiation of developing muscle spindles in the absence of sensory innervation was investigated by deafferentation of the soleus muscle in immature rats. Dorsal root ganglia containing the cell bodies of afferents from the soleus muscle were removed surgically at a stage of postnatal development when spindles already contain the full complement of intrafusal fibers innervated by both afferents and efferents, but when the fibers are histochemically and structurally immature. Experimental soleus muscles were excised one year after deafferentation and sectioned frozen at a thickness of 8 micron. Sections were stained for enzymes indicative of types of muscle fibers and sites of neuromuscular junctions, and were examined by light microscopy. Spindles of muscles that matured in the absence of sensory innervation were abnormal. They lacked the periaxial fluid space and contained fewer intrafusal fibers than did normal spindles. The morphological and histochemical profiles of the encapsulated fibers present in the deafferented spindles more closely resembled extrafusal rather than intrafusal muscle fibers. These observations suggest that deafferentation of the immature spindles induces disintegration of some intrafusal fibers and alters maturation of others. Moreover, motor axons terminated less frequently along muscle fibers in deafferented spindles than on intrafusal fibers of normal spindles. Thus, maintenance of a full complement of intrafusal fibers in the developing spindle, emergence of histochemical profiles typical of normal intrafusal fibers, and development of adult pattern of fusimotor innervation require intact sensory innervation.