Regulation of terminal Schwann cell number at the adult neuromuscular junction.

Terminal Schwann cells (TSCs), neuroglia that cover motoneuron terminals, play a role in regulating the structure and function of the neuromuscular junction. In rats, the number of TSCs at each junction increases rapidly in early postnatal life and more slowly in young adults. It is possible that TSC number increases to match increasing endplate area. Alternatively, the increase in TSC number may reflect a developmental process independent of endplate size or terminal function. To experimentally test the relationship between endplate size and TSC number, we manipulated endplate area in an androgen-sensitive muscle of the rat, the levator ani (LA), by castration and by androgen replacement. We found that TSC number not only increased as endplates enlarged but also decreased when endplates shrank. Ninety days after castration, TSC number decreased by approximately 20% (one cell per junction) as endplate size decreased by 30%. These effects were reversed by testosterone. Testosterone levels did not affect TSC number in the extensor digitorum longus (EDL) muscle, where endplate area was unaffected by castration or testosterone treatment. TSC number was, however, significantly correlated with endplate area in both LA and EDL muscles. Furthermore, the relationship between endplate size and TSC number, as defined by the slope of the regression line, was the same in LA and EDL muscles, indicating that this relationship is not a unique feature of the LA muscle. These data suggest that TSC number is a dynamic property of the neuromuscular synapse that is actively regulated throughout life.

Neonatal partial denervation results in nodal but not terminal sprouting and a decrease in efficacy of remaining neuromuscular junctions in rat soleus muscle.

Mature motoneurons respond to partial denervation of their target muscle by sprouting to reinnervate denervated fibers, thus maintaining muscle strength in the face of motoneuronal loss caused by injury or disease. Neonatal motoneurons, however, do not expand to innervate more muscle fibers. The present work seeks to understand this developmental change in motoneuron response to partial denervation. It has been suggested that neonatal motor units cannot increase in size because they are already at their maximum size (approximately five times larger than in adulthood). We ruled out this explanation by showing that after partial denervation on postnatal day 14 (P14), when motor units have decreased to their adult size, motoneurons still did not sprout to reinnervate as many fibers as in adulthood. Instead, we found evidence supporting an alternative explanation involving terminal Schwann cells. After partial denervation of neonatal (but not adult) muscles, terminal Schwann cells at denervated endplates undergo apoptosis. We found that terminal (but not nodal) sprouting was absent in partially denervated neonatal muscles. This finding suggests that terminal Schwann cells, previously reported to guide terminal sprouts to denervated endplates in adult muscles, are necessary for the formation and growth of terminal sprouts. Moreover, partial denervation on P14 severely weakened the remaining, uninjured synapses, suggesting that neonatal motoneurons may withdraw terminals after the denervation of nearby fibers. These findings have implications for the interpretation of previous studies on synapse elimination and offer insight into the failure of young motor units to expand after partial denervation.

Respecified larval proleg and body wall muscles circulate hemolymph in developing wings of Manduca sexta pupae.

Most larval external muscles in Manduca sexta degenerate at pupation, with the exception of the accessory planta retractor muscles (APRMs) in proleg-bearing abdominal segment 3 and their homologs in non-proleg-bearing abdominal segment 2. In pupae, these APRMs exhibit a rhythmic 'pupal motor pattern' in which all four muscles contract synchronously at approximately 4 s intervals for long bouts, without externally visible movements. On the basis of indirect evidence, it was proposed previously that APRM contractions during the pupal motor pattern circulate hemolymph in the developing wings and legs. This hypothesis was tested in the present study by making simultaneous electromyographic recordings of APRM activity and contact thermographic recordings of hemolymph flow in pupal wings. APRM contractions and hemolymph flow were strictly correlated during the pupal motor pattern. The proposed circulatory mechanism was further supported by the findings that unilateral ablation of APRMs or mechanical uncoupling of the wings from the abdomen essentially abolished wing hemolymph flow on the manipulated side of the body. Rhythmic contractions of intersegmental muscles, which sometimes accompany the pupal motor pattern, had a negligible effect on hemolymph flow. The conversion of larval proleg and body wall muscles to a circulatory function in pupae represents a particularly dramatic example of functional respecification during metamorphosis.

Target muscles and sensory afferents do not influence steroid-regulated, segment-specific death of identified motoneurons in Manduca sexta.

Programmed cell death plays a critical role in sculpting the nervous system during embryonic development. In holometabolous insects, cell death also plays an important role in the reorganization of the nervous system during metamorphosis. In Manduca sexta, cell death and the factors that regulate it can be studied at the level of individually identified neurons. The accessory planta retractor (APR) motoneurons undergo segment-specific death during the larval-pupal transformation. APRs in abdominal segments 1, 5, and 6 die at pupation; those in abdominal segments 2, 3, and 4 survive until adulthood. Juvenile hormone and ecdysteroids regulate the metamorphic restructuring of the nervous system, but the factors that determine which APRs will live and which will die are not known. The present study assessed the possible importance of cell-cell interactions in determining APR survival at pupation by removing APR's target muscle or mechanosensory input early in the final larval instar, prior to the hormonal cues that trigger the larval-pupal transformation. The motoneurons showed their normal, segment-specific pattern of death in nearly all cases. These results suggest that target muscles and sensory input play little or no role in determining the segment-specific pattern of APR survival at pupation.

Axotomy transiently down-regulates androgen receptors in motoneurons of the spinal nucleus of the bulbocavernosus.

Testosterone is an important trophic factor for motoneurons in the spinal nucleus of the bulbocavernosus (SNB), and SNB motoneurons are more responsive to testosterone than are other motoneurons. Axonal injury during early postnatal life prevents the normal development of steroid-sensitivity by adult SNB motoneurons. Axonal injury also causes changes in the expression by motoneurons of a wide range of proteins, including the up-regulation of trophic factor receptors. We have used a polyclonal antibody (PG-21; G.S. Prins) to study the expression of androgen receptors in SNB motoneurons after axonal injury. PG-21 labeled motoneuronal nuclei in the lower lumbar spinal cord of rats in a pattern that matched autoradiographic reports of androgen accumulation in this region of the nervous system. A population of numerous, small cells located dorsal to the central canal also showed evidence of androgen receptor expression. Cutting the axons of SNB motoneurons in adulthood or in development caused a decrease in androgen receptor immunoreactivity in SNB motoneurons. This is the first report that a trophic factor receptor in motoneurons is down-regulated after axonal injury, and is interesting in light of reports that testosterone treatment can facilitate motoneuronal regeneration after nerve cut. Androgen receptor levels subsequently returned to normal, regardless of the age at axotomy, providing no evidence for a lasting effect of developmental axotomy on androgen receptor levels in SNB motoneurons. Thus, axotomy-induced down-regulation of androgen receptors does not underlie the inability of SNB motoneurons to respond to androgen treatment several months after pudendal nerve cut in development.

Axotomy of developing rat spinal motoneurons: cell survival, soma size, muscle recovery, and the influence of testosterone.

During the period of synapse elimination, motoneurons are impaired in their ability to generate or regenerate axonal branches: following partial denervation of their target muscle, young motoneurons do not sprout to nearby denervated fibers and after axonal injury, they fail to reinnervate the muscle. In the rat levator ani (LA) muscle, which is innervated by motoneurons in the spinal nucleus of the bulbocavernosus (SNB), synapse elimination ends relatively late in development and can be regulated by testosterone. We took advantage of this system to determine if the end of synapse elimination and the development of regenerative capabilities by motoneurons share a common mechanism, or, alternatively, if these two events can be dissociated in time. Axotomy on or before postnatal day 14 (P14) caused the death of SNB motoneurons. By P21, toward the end of synapse elimination in the LA muscle, SNB motoneurons had developed the ability to survive axonal injury. Altering testosterone levels by castration on P7 followed by 4 weeks of either testosterone propionate or control injections did not change the ability of SNB motoneurons to survive axonal injury during development, although these same treatments alter the time course of synapse elimination in the LA muscle. Thus, we dissociated the inability of SNB motoneurons to recover from axonal injury from their developmental elimination of synaptic terminals. We also measured the effect of early axotomy on motoneuronal soma size and on target muscle weight. Axotomy on P14 caused a long-lasting decrease in the soma size of surviving SNB motoneurons, whereas motoneurons axotomized on P28 recovered their normal soma size. Axotomy on or before P7 caused severe atrophy of the target muscles, matching the extensive loss of motoneurons. However, target muscle recovery after axotomy on P14 was as good as recovery after axotomy at later ages, despite greater motoneuronal death after axotomy on P14. This result may reflect an increase in motor unit size, a decrease in polyneuronal innervation by SNB motoneurons that survive axotomy on P14, or a combination of the two.

Evidence for target regulation of the development of androgen sensitivity in rat spinal motoneurons.

Specific neuronal circuits within the vertebrate nervous system express high levels of steroid receptors and are sensitive to the effects of steroid hormones. The mechanisms by which these neuronal circuits develop their unique steroid sensitivity are unknown. One intriguing hypothesis is that retrograde influences during early postnatal life play a role in determining which central nervous system (CNS) neurons become sensitive to steroids. We now present evidence that during a critical period in early postnatal development, axonal injury disrupts the normal development of steroid sensitivity. The spinal nucleus of the bulbocavernosus (SNB) is a neuromuscular system that is highly androgen-sensitive at the level of both the motoneurons and their target muscles. Testosterone levels regulate the size of SNB motoneurons and their muscles in adult rats. Cutting the axons of SNB motoneurons on postnatal day 14 (P14) caused permanent decreases in SNB motoneuronal soma size, as well as in SNB target muscle weight. Interestingly, SNB motoneurons that survived axotomy on P14 failed to develop their normal ability to respond to testosterone in adulthood. That is, they did not respond to changes in testosterone levels with changes in soma size. The same effect was not seen after axotomy 1 week later in development, suggesting a critical period for this effect. Thus, separation from the target muscles during an early critical period in development blocked the differentiation of androgen sensitivity by SNB motoneurons, consistent with a role for the target in the normal development of steroid sensitivity by CNS neurons.

Transient and permanent effects of androgen during synapse elimination in the levator ani muscle of the rat.

Young male rats were castrated at 7 days of age, and treated with testosterone propionate daily from 7 to 34 days of age. At 13 months of age, motor axons and terminals innervating the levator ani (LA) muscle were stained with tetranitroblue tetrazolium (TNBT). The number of separate axons innervating individual muscle fibers was counted, and muscle fiber diameter was measured. Previous studies have shown that this androgen treatment increases muscle fiber diameter and delays synapse elimination, measured as (1) a greater percentage of muscle fibers innervated by multiple axons and (2) larger motor units. The present results indicate that the androgenic effect on synapse elimination is permanent, in that high levels of multiple innervation persisted for 12 months after the end of androgen treatment. In contrast, the effect on muscle fiber diameter was not maintained for this period. This dissociation of androgenic effects on the pattern of innervation from androgenic effects on muscle fiber diameter offers further evidence that the androgenic maintenance of multiple innervation is not dependent on muscle fiber size. In addition, circulating testosterone levels were measured at 50 and 60 days of age in animals similarly treated with androgen or oil from 7 to 34 days of age. By 60 days of age, testosterone levels in hormone-treated animals had dropped below detectability, comparable to levels in oil-treated controls. This provides additional evidence that androgen treatment during juvenile development can have permanent effects on the adult pattern of innervation in the LA muscle.

Autoradiographic localization of progestin-concentrating cells in the brain of the zebra finch.

The production of song in passerine birds is under the control of steroid hormones, and brain regions involved in song production have been shown to contain androgen and/or estrogen receptors. Studies to date, however, have not considered the possible role of progestins in this behavior. As one approach to this question, the autoradiographic method was used to investigate the distribution of progestin-concentrating cells in the brain of the adult male zebra finch (Poephila guttata) after injection of the radiolabeled synthetic progestin [17 alpha-methyl-3H]-promegestone. In the telencephalon, identifiable groups of progestin-accumulating cells were found in the hyperstriatum dorsale, at the medial edge of the lobus parolfactorius, and in the medial septum. In the diencephalon, labeled groups of cells were found in the preoptic area, through much of the medial hypothalamus--including nucleus periventricularis magnocellularis, nucleus medialis hypothalami posterialis, and area infundibularis--and in the medial spiriform nucleus and dorsomedial thalamus. In the myelencephalon, labeled cells are described at the dorsal edge of the medulla and scattered lateral to nXII. These findings offer no support for the hypothesis that progestin acts on any of the known song regions, but do suggest areas of progestin action in the avian central nervous system outside of the known song system. Not surprisingly, these include many areas of the medial hypothalamus and other midline structures.