Morphology of rat spinal motoneurons with normal and hormonally altered specificity

Potential determinants of motoneuronal morphology were examined by using a sexually dimorphic, steroid-sensitive neuromuscular system in the rat spinal cord. In males, the spinal nucleus of the bulbocavernosus (SNB) innervates the perineal muscles bulbocavernosus (BC) and levator ani (LA), and the dorsolateral nucleus (DLN) innervates the ischiocavernosus muscle (IC). Adult females normally lack these motoneurons and the peripheral targets. Prenatal exposure of females to the androgen dihydrotestosterone propionate (DHTP) partially masculinizes this neuromuscular system and alters moto-neuron-to-muscle specificity, resulting in retained SNB target muscles anomalously innervated by motoneurons in the DLN. Because the morphology of SNB and DLN motoneurons normally differs significantly, the influence of spinal cord location and peripheral target on motoneuron morphology can be directly compared. Injection of cholera toxin conjugated to horseradish peroxidase (CTHRP) into the LA of DHTP-treated females labeled motoneurons predominantly in the SNB. These (SNB-LA) motoneurons in DHTP females were identical in all morphological measures to those of normal males. CTHRP injection into the BC of DHTP females labeled motoneurons in both the SNB and the DLN. SNB-BC motoneurons in DHTP females resembled those of normal males in process number and orientation, but were significantly smaller in dendritic length per motoneuron and in soma size. The DLN motoneurons anomalously projecting to the BC in DHTP females differed significantly from SNB-BC motoneurons in soma size and number and orientation of primary processes. However, these motoneurons were identical in all respects to DLN-IC motoneurons in DHTP females; DLN-IC motoneurons were similar to those of normal males in the orientation of their dendritic arbor, but were significantly smaller in dendritic length, soma size, and number of primary processes. These comparisons make it clear that DHTP selectively affects motoneuronal specificity and morphology in specific motoneuron classes. Further, motoneuronal morphology in the SNB/DLN system appears to be influenced more by spinal cord location than by peripheral target.     

Hormonal control of neuron number in sexually dimorphic spinal nuclei of the rat: III. Differential effects of the androgen dihydrotestosterone

The spinal cord of the rat contains two sexually dimorphic nuclei: the spinal nucleus of the bulbocavernosus (SNB) and the dorsolateral nucleus (DLN). These nuclei and the perineal muscles they innervate are present in males but reduced or absent in females. The sex difference in motoneuron number in these nuclei is due to an androgen-regulated motoneuron death. Developing females treated with the androgen testosterone propionate (TP) have a fully masculine number of SNB and DLN motoneurons and retain the perineal muscles they would normally have lost. Paradoxically, females treated prenatally with the androgen dihydrotestosterone propionate (DHTP) also retain the perineal musculature but as adults lack the SNB motoneurons which would normally innervate them. The SNB target muscles retained by DHTP females are anomalously innervated by motoneurons in the DLN. Counts of motoneurons and degenerating cells in the developing SNB of DHTP-treated females showed that their feminine number is the result of a failure of DHTP to prevent the death of SNB motoneurons. Furthermore, the peak number of SNB motoneurons was below that of normal females, suggesting that DHTP treatment may also have inhibited motoneuronal migration. However, DHTP treatment fully masculinized both motoneuron number and degenerating cell counts in the DLN of these females, and it is this masculinized DLN that gives rise to the anomalous projection. Taken together, these results suggest that the effects of different androgens during development are specific and complex, involving the regulation of motoneuron death, migration, and specification of peripheral projections.     

Motoneuron development after deafferentation: II. Dorsal rhizotomy does doe block estrogen-supported growth in the dorsolateral nucleus (DLN)

The lumbar spinal cord of the rat contains two sexually dimorphic motor nuclei, the spinal nucleus of the bulbocavernosus (SNB) and the dorsolateral nucleus (DLN). Postnatally, SNB and DLN motoneurons grow substantially and reach their adult morphology by 7 weeks of age. The masculinization of SNB and DLN motoneuron dendrites depends upon steroid hormones. After early castration, the growth of SNB and DLN dendrites is markedly attenuated, but testosterone replacement restores this growth. In the SNB, initial dendritic growth is also supported in castrates treated with estrogen. By using castration and hormone replacement techniques, we examined the development of DLN motoneuron morphology in estrogen-treated castrated rats to determine if estrogen also supports the growth of DLN motoneurons. In addition, given that dorsal root ganglia may be a site of estrogen action, we tested the hypothesis that estrogen acts at primary afferents to support DLN dendritic growth. Thus, we attempted to block the potential trophic effect of estrogen by performing unilateral dorsal rhizotomies in estrogen-treated castrates. DLN motoneuron morphology was analyzed at 4 and 7 weeks of age by using cholera toxin horseradish peroxidase (BHRP) histochemistry. As found for SNB motoneurons, estrogen treatment transiently supported development. DLN motoneurons in estrogen-treated castrates developed normally through 4 weeks of age, but by 7 weeks, DLN motoneuron morphology in estrogen-treated castrates was no longer different from that in oil-treated castrates. Moreover, deafferentation via unilateral dorsal rhizotomy did not inhibit estrogen's ability to masculinize the early development of DLN motoneurons. Thus, the trophic effect of estrogen did not appear to act via the dorsal root ganglia to support the early postnatal development of DLN motoneurons.     

Long-term castration effects motoneuron size but not number in the spinal nucleus of the bulbocavernosus in the adult male Mongolian gerbil

The spinal nucleus of the bulbocavernosus (SNB) is a sexually dimorphic group of motoneurons in Rexed's Lamina X of the lumbosacral spinal cord of the Mongolian gerbil. The SNB innervates the perineal musculature, the bulbocavernosus (BC), levator ani (LA), and external anal sphincter (EAS). Recent studies demonstrated a peripubertal component to the masculinization of the gerbil SNB with an apparent increase in both motoneuron size and number after puberty as measured with a Nissl stain. However, these studies could not determine if the apparent change in motoneuron number were due to the long-term castration involved in the methodology or due to a loss of motoneuron size beyond the point of being recognizable as motoneurons. Therefore, the current study was undertaken to examine this possibility by repeating the experimental protocol from previous peripubertal studies, on adult male gerbils with the addition of retrograde tract-tracing. Adult male gerbils were castrated at postnatal day (PND) 150 and given subcutaneous implants of testosterone proprionate (TP), dihydrotestosterone (DHT), estradiol benzoate (EB), EB and DHT, no steroid, or left intact. At PND215, the animals were injected with fluorogold (FG), a retrograde tract-tracer. At PND220, the animals were aldehyde perfused transcardially. The spinal cords were sectioned and alternate sections processed for either thionin-stain or FG visualization. Results indicated that long-term castration had no effect on SNB motoneuron number but did decrease SNB motoneuron size. TP, and to a lesser extent DHT, treatment could prevent the reduction in motoneuron size, however, EB could not. This study indicates that the maintenance of the adult male gerbil SNB-BC system is androgen, not estrogen, dependent and that long-term castration does not reduce motoneuron size to the point where they can no longer be distinguished.     

Hormonal control of neuron number in sexually dimorphic spinal nuclei of the rat: II. Development of the spinal nucleus of the bulbocavernosus in androgen-insensitive (Tfm) rats

The spinal nucleus of the bulbocavernosus (SNB) is a sexually dimorphic motor nucleus whose development is under the control of steroid hormones. The SNB contains many more motoneurons in adult male rats than in females, and this sex difference is produced by a sexually dimorphic motoneuron death which is regulated by androgens. To study further the role of androgens in the development of sex differences in SNB motoneuron number, we examined SNB development in males with the testicular feminization mutation (Tfm) which renders them insensitive to androgens. Counts of SNB motoneurons perinatally revealed that SNB development in normal male and female King-Holtzman rats was similar to that reported previously for Sprague-Dawley rats; SNB motoneuron number increased from initially low levels at embryonic day 18 through the day before birth, when motoneuron numbers in both sexes were substantially higher than adult levels. After this prenatal increase, motoneuron number declined in both sexes, until by postnatal day 10 motoneuron numbers were in their adult ranges and the sex difference was fully expressed. Females lost more motoneurons than did males during this period, and this loss was due to motoneuron death as revealed by counts of degenerating cells. SNB development in King-Holtzman Tfm males was similar to that of normal males through embryonic day 20, suggesting that androgens may not be necessary for the initial increase in motoneuron numbers in the SNB. Thereafter, SNB motoneuron numbers in Tfm males declined in a female-typical fashion; Tfm males and normal females did not differ at any postnatal age.(ABSTRACT TRUNCATED AT 250 WORDS)     

Development and loss of early projections in a sexually dimorphic rat spinal nucleus

The spinal nucleus of the bulbocavernosus (SNB) contains 3-4 times more motoneurons in adult male rats compared to females. This large dimorphism in motoneuron number is produced perinatally by an androgen-regulated cell death. To determine if the early projections of the SNB to its target musculature may be involved in the creation of this sexual dimorphism, and how these projections might interact with androgens, HRP tracing techniques were used to retrogradely label SNB motoneurons during prenatal and postnatal development in males, females, and masculinized females. HRP labeling revealed that the prenatal formation of early projections of the SNB in males and females is comparable. SNB motoneuron number increases through the day before birth in all groups, and during this increase, labeled cells can be seen outside the SNB, which we hypothesize are in the process of migrating into the SNB from the lateral motoneuron column. Postnatally, SNB motoneuron number declines, especially in females, and by postnatal day 10 the sexual dimorphism in cell number and projections has been established. These results indicate that although masculine androgen levels are critical in determining SNB motoneuron survival, they are not necessary for initial axon outgrowth of SNB motoneurons. However, androgens may be involved in the regulation of SNB motoneuron migration and the stabilization of the peripheral projections of the SNB. Both male and female SNB motoneuron axons are present at their target muscles during the time in which sex differences in motoneuron number develop, suggesting that the interaction of SNB motoneurons with their targets could be involved in the dimorphic regulation of cell survival.     

Additive effects of ciliary neurotrophic factor and testosterone on motoneuron survival; differential effects on motoneuron size and muscle morphology

Testosterone and ciliary neurotrophic factor (CNTF) each enhance motoneuron survival in the spinal nucleus of the bulbocavernosus (SNB) of newborn rats. Here we directly compared the effects of CNTF and testosterone, alone and in combination, on SNB motoneuron number, SNB cell size, and morphology of the levator ani (LA) target muscle. Female rat pups were treated daily from postnatal day 1 through 6 (P1-P6) with recombinant human CNTF (hCNTF), testosterone propionate (TP), both hCNTF and TP, or neither. Effects of treatment were assessed on P7. TP and hCNTF each increased the number of SNB motoneurons and did so to a similar degree. Females treated with both hCNTF and TP had significantly more SNB cells than those receiving either hCNTF or TP alone. TP administered from P1 to P6 also increased SNB motoneuron size on P7. In contrast, hCNTF alone did not significantly affect SNB cell size, and hCNTF in combination with TP antagonized the effect of TP on motoneuron size. TP also increased LA muscle fiber number and LA fiber size, whereas hCNTF did not significantly influence LA muscle morphology in this study. Immunohistochemistry established that virtually all SNB motoneurons of both males and females express the CNTF alpha receptor (CNTFRalpha) between embryonic day 20 and postnatal day 6. Thus, effects of TP and hCNTF on SNB motoneuron survival were additive, and increases in motoneuron survival were dissociated from changes in target muscle morphology in hCNTF-treated animals. SNB motoneurons express CNTFRalpha perinatally and are therefore potential direct sites of hCNTF action.     

Hormonal control of a developing neuromuscular system. II. Sensitive periods for the androgen-induced masculinization of the rat spinal nucleus of the bulbocavernosus

The spinal nucleus of the bulbocavernosus (SNB) and its target muscles are reduced or absent in normal female rats (Breedlove, S. M., and A. P. Arnold (1980) Science 210: 564-566). We now report that prenatal treatment of females with testosterone propionate (TP) significantly increases the number of SNB neurons found in adulthood. Dihydrotesterone propionate (DHTP) treatment just after but not before birth also masculinizes the number of SNB neurons in females. SNB soma size is significantly masculinized, i.e., enlarged, by administration of androgen prenatally or as late as 7 to 11 days after birth, even though this late postnatal treatment has no effect on the number of SNB cells. Following TP treatment in adulthood, the androgenized females did not display the postural correlates of male copulatory behavior more often than did control females. From these results we infer the following. (1) Androgens act both before and after birth to influence the sexually dimorphic development of the SNB system. (2) There are different sensitive periods for the masculinization of SNB neuronal number and neuronal size, indicating that these two dimorphic characteristics of the SNB are masculinized by somewhat independent mechanisms. (3) TP and DHTP may act via separate mechanisms to alter the number of SNB neurons. (4) Aromatized metabolites of testosterone are not necessary for masculinization of the SNB system. (5) Virilization of the SNB system does not ensure the masculinization of the traditionally defined measures of male copulatory behavior in rodents.     

Sex differences in the pattern of steroidaccumulation by motoneurons of the rat lumbar spinal cord

We previously reported that male rat lumbar motoneurons accumulate radioactivity after injection of tritiated testosterone (T) or dihydrotestoster-one (DHT), but not estradiol (E). We now report autoradiographic evidence that lumbar motoneurons in male rats accumulate T or its metabolites more frequently than do female motoneurons. However, this sex difference in hormone accumulation by motoneurons is not observed following the injection of DHT or E, both of which are normal metabolites of T. Very few motoneurons from any population accumulated E or its metabolites. In fact, some motoneurons had fewer silver grains over their nuclei than would be expected by chance, thus suggesting that these cells not only failed to accumulate E or its metabolites, but actively or passively excluded them from their nuclei. Virtually every motoneuron of either sex accumulated hormone after DHT injection. Following T injection, more motoneurons were labeled in males (72–77%) than in females (28ndash39%), indicating a sex difference in hormone accumulation. Taken together, these results suggest that either (1) there are separate receptors for T and DHT, and motoneurons have more T receptors (but equal numbers of DHT receptors) in males than in females, or (2) the motoneurons of male rats have greater access to systemically administered T or its metabolites than do those of females.     

Hormonal control of neuron number in sexually dimorphic spinal nuclei of the rat: I. Testosterone-regulated death in the dorsolateral nucleus

Adult male rats have substantially more motoneurons than do females in two motor nuclei in the lumbar spinal cord: the spinal nucleus of the bulbocavernosus (SNB) and the dorsolateral nucleus (DLN). Previous studies of the development of the SNB revealed that the sex difference in SNB motoneuron number is established through a differential motoneuron death which is under the control of androgens. In this study the development of the sexually dimorphic DLN was examined to test the hypothesis that early androgen action also determines the sex difference in DLN motoneuron number by regulating normally occurring motoneuron death. Because SNB motoneurons may migrate from the DLN, quantitative examination of DLN development was necessary in order to understand more completely the cellular mechanisms contributing to the establishment of dimorphic motoneuron number. At 5 days before birth, the number of motoneurons in the DLN is significantly higher than in adulthood in both sexes, and no sex difference is present. There is a decrease in motoneuron numbers prenatally in both sexes, which is consistent with the emigration of presumptive SNB motoneurons. Motoneuron number declines differentially through the first week of postnatal life and by postnatal day 10 motoneuron numbers are in the adult range and the sex difference is fully expressed. Females lose significantly more DLN motoneurons than males through a differential death as revealed by the higher incidence of degenerating cell profiles. Females treated with testosterone propionate have a male-typical motoneuron loss and incidence of degenerating cells. These results indicate that steroid hormones establish the sex difference in DLN motoneuron number by regulating normally occurring cell death.     

Hormone-sensitive periods for the control of motoneuron number and soma size in the dorsolateral nucleus of the rat spinal cord

The dorsolateral nucleus (DLN) of the rat lumbosacral spinal cord is sexually dimorphic, with males having more and larger DLN motoneurons than do females. The development of this dimorphism depends on the presence of perinatal androgens. The present study sought to determine the periods in development during which the DLN is sensitive to the masculinizing effects of the androgen testosterone propionate (TP). The size and number of DLN motoneurons in neonatally ovariectomized female rats that were exposed to TP during either the late prenatal, early postnatal, or late postnatal period were compared to control males and females. Both late prenatal and early postnatal TP injections significantly increased DLN number by 48% and 50%, respectively, but the sensitive period for TP masculinization of soma size seems to be primarily postnatal, because prenatal TP injections had little or no effect on that measure. The sensitive period for TP masculinization of DLN neuron number is similar to that of the sexually dimorphic spinal nucleus of the bulbocavernosus (SNB). However, the sensitive period for TP masculinization of DLN soma size appears to begin later than for the SNB.     

Increase in motoneurons in the spinal nucleus of the bulbocavernosus of prepubertally castrated male Mongolian gerbils following delayed treatment with testosterone

Sexual dimorphism in the spinal nucleus of the bulbocavernosus (SNB) of the Mongolian gerbil is achieved by two periods of postnatal increase, one in the first month after birth and one at puberty. The pubertal increase in motoneuron number is of particular interest because it occurs in a nearly adult animal. The purpose of this research was threefold. The first was to determine the response of the SNB in prepubertally castrated male gerbils receiving delayed hormone replacement as adults. Testosterone propionate (TP) treatment resulted in numbers of SNB motoneurons comparable to those seen in intact males, whereas androgen metabolites were less effective. The second purpose was to determine the latency of motoneurons to appear in response to TP. New SNB motoneurons appeared within 2 days of delayed TP replacement in prepubertally castrated males, and 16 days of treatment did not further increase SNB motoneuron numbers. The response of the motoneurons to TP appeared more rapid than the response of the bulbocavernosus (BC) muscle, scent gland, and seminal vesicles. The third purpose was to determine whether the new cells were connected to a target muscle. After 16 days of TP treatment, more motoneurons were labeled in the SNB following injection of a retrograde tract tracer into the BC muscle compared with the number seen in control animals. Thus, new motoneurons appeared in the SNB of prepubertally castrated male Mongolian gerbils within 2 days of the start of delayed TP treatment and were connected to a target within 16 days of TP treatment.     

Intrauterine position affects motoneuron number and muscle size in a sexually dimorphic neuromuscular system

The intrauterine position occupied by a rodent fetus influences the amount of testosterone to which it is exposed before birth. Animals that are gestated between two male fetuses (2M) are exposed to higher circulating levels of testosterone than are animals positioned between two female fetuses (2F) and there are reliable differences in the reproductive physiology and behavior of 2M and 2F animals when adult. To determine whether intrauterine position modifies development of the central nervous system, we examined the sexually dimorphic spinal nucleus of the bulbocavernosus (SNB) in male and female gerbils from known intrauterine positions. We found that adult 2M female gerbils had 16% more SNB motoneurons than did 2F females. 2M males did not differ from 2F males in SNB motoneuron number, but the bulbocavernosus muscle, which is innervated by SNB motoneurons, was approximately 50% larger in 2M than in 2F males. These data indicate that intrauterine position can influence the morphology of the sexually dimorphic SNB neuromuscular system.     

Testosterone manipulation protects motoneurons from dendritic atrophy after contralateral motoneuron depletion

Dendritic morphology is reactive to many kinds of injuries, including axotomy and deafferentation. In this study, we examined the response of motoneurons in the spinal nucleus of the bulbocavernosus (SNB), an androgen-dependent population of motoneurons in the lumbar spinal cord of the rat, to partial motoneuron depletion. We depleted SNB motoneurons on one side only of the spinal cord by unilateral intramuscular injection of a retrogradely transported form of saporin, and examined the morphology of contralateral SNB motoneurons. Motoneuron morphology was assessed in normal control males, gonadally intact saporin-treated males, and saporin-treated males who had been castrated 6 weeks previously and given testosterone replacement beginning at the time of saporin injection. Untreated castrated males served as an additional control group. Four weeks after saporin treatment, SNB motoneurons contralateral to the saporin injection were retrogradely labeled with horseradish peroxidase conjugated to the cholera toxin B subunit and reconstructed in three dimensions. In gonadally intact males, unilateral motoneuron depletion caused regressive changes in contralateral SNB motoneurons: Soma size and dendritic length were both decreased. However, testosterone manipulation (i.e., castration followed by testosterone replacement) completely prevented the dendritic retraction. These data suggest a therapeutic role for testosterone in preventing, or accelerating recovery from, dendritic atrophy induced by motoneuron injury.     

Motoneuron morphology in the dorsolateral nucleus of the rat spinal cord: Normal development and androgenic regulation

The rat lumbar spinal cord contains two sexually dimorphic motor nuclei, the spinal nucleus of the bulbocavernosus (SNB), and the dorsolateral nucleus (DLN). These motor nuclei innervate anatomically distinct perineal muscles that are involved in functionally distinct copulatory reflexes. The motoneurons in the SNB and DLN have different dendritic morphologies. The dendrites of motoneurons in the medially positioned SNB have a radial, overlapping arrangement, whereas the dendrites of the laterally positioned DLN have a bipolar and strictly unilateral organization. During development, SNB motoneuron dendrites grow exuberantly and then retract to their mature lengths. In this experiment we determined whether the adult difference in SNB and DLN motoneuron morphology was reflected in different patterns of dendritic growth during normal development. Furthermore, the development of both these nuclei is under androgenic control. In the absence of androgens, SNB dendrites fail to grow; testosterone replacement supports normal dendritic growth. Thus, we also examined the development of DLN dendrites for similar evidence of androgenic regulation. By using cholera toxin-horseradish peroxidase (BHRP) to label motoneurons retrogradely, we measured the morphology of DLN motoneurons in normal males, and in castrates treated with testosterone or oil/blank implants at postnatal day (P) 7, P28, P49, and P70. Our results demonstrate that in contrast to the biphasic pattern of dendritic development in the SNB, dendritic growth in the DLN was monotonic; the dendritic length of motoneurons increased more than 500% between P7 and P70. However, as in the SNB, development of DLN motoneuron morphology is androgen-dependent. In castrates treated with oil/blank implants, DLN somal and dendritic growth were greatly attenuated compared to those of normal or testosterone-treated males. Thus, while androgens are clearly necessary for the growth of motoneurons in both the SNB and DLN, their different developmental patterns suggest that other factors must be involved in regulating this growth. © 1993 Wiley-Liss, Inc.     

Motoneurons dorsolateral to the central canal innervate perineal muscles in the mongolian gerbil

The Mongolian gerbil provides a model in which sexually dimorphic areas in the hypothalamus are correlated with sociosexual behaviors such as scent marking and male copulatory behavior. To extend this model, investigations were conducted to determine whether sexually dimorphic areas existed in the spinal cord that could be relevant to male sexual behavior. The focus of these investigations was the perineal muscles associated with the penis. Therefore, this research identified the spinal motoneurons that innervate the bulbocavernosus, levator ani, anal sphincter, and ischiocavernosus muscles of Mongolian gerbils. The motoneuron pool that innervates the bulbocavernosus, levator ani, and anal sphincter was designated the spinal nucleus of the bulbocavernosus (SNB), as for other species of rodents. The motoneuron pool innervating the ischiocavernosus was identified as the dorsolateral nucleus, again, to be consistent with the designation for other rodents. The motoneurons of the gerbil SNB were distributed dorsolateral to the central canal in the lumbosacral transition zone of the spinal column. These motoneurons are located in the region classically defined as area X of the spinal cord. The number of SNB motoneurons was sexually dimorphic, with male gerbils having about five times as many SNB motoneurons as do female gerbils. The size of SNB motoneurons was also sexually dimorphic. The SNB motoneurons of males were 1. 5 times larger than the SNB motoneurons of females. The effects of adult castration on the male SNB were also studied. After castration, the size, but not the number, of SNB motoneurons in males was significantly decreased. This decrease was prevented by testosterone treatment. The percentage of calcitonin gene-related peptide (CGRP)-immunoreactive SNB motoneurons was also affected by adult castration. The percentage of CGRP-immunoreactive motoneurons was significantly decreased after adult castration. Again, this decrease was reversed by testosterone treatment. These findings suggest that the SNB of gerbils is sexually dimorphic and is sensitive to circulating levels of gonadal steroids. The unique placement of the SNB motoneurons suggests that an alternative laminar organizational scheme may be necessary for Mongolian gerbil. © 1995 Wiley-Liss, Inc.     

Motoneuron development after deafferentation. I. Dorsal rhizotomy does not alter growth in the spinal nucleus of the bulbocavernosus (SNB)

The spinal nucleus of the bulbocavernosus (SNB) and the dorsolateral nucleus (DLN) are sexually dimorphic motor nuclei in the rat lumbar spinal cord. During postnatal development, SNB and DLN motoneurons grow substantially in measures of soma size, dendritic length, and radial dendritic extent. SNB motoneurons exhibit a biphasic pattern of dendritic growth, where there is an initial period of exuberant growth followed by a period of retraction to mature lengths by 7 weeks. In this experiment, we examined whether primary afferent input to the SNB nucleus was necessary for the normal postnatal growth of SNB motoneurons. We partially deafferented the SNB via unilateral dorsal rhizotomy of lumbosacral dorsal roots in male rats at 1 week of age. Using cholera toxin horseradish peroxidase (BHRP) to visualize SNB motoneurons, we examined SNB motoneuron morphology at 4 and 7 weeks of age. SNB motoneurons in rhizotomized males developed normally; measures of dendritic length in rhizotomized males were typically exuberant at 4 weeks of age, and declined significantly to mature lengths by 7 weeks of age. In addition, dorsal rhizotomy did not alter the development of SNB motoneuron soma size or radial dendritic extent. These results are discussed in reference to sensorimotor connections in the SNB, the extent of the deafferentation, and dendrodendritic interactions.     

Androgen effects on the development of the zebra finch song system.

In adult zebra finches, males sing and females do not. This behavioral sex difference is associated with sex differences in brain regions that control singing. Treatment of hatchling females with androgen causes permanent masculinization of neuron number in the robust nucleus of the archistriatum (RA), a brain region involved in song. We have re-examined the possible permanent effects of androgen on the zebra finch song system by treating male and female hatchlings with Silastic implants containing 50 or 200 micrograms 5 alpha-dihydrotestosterone (DHT) or 200 micrograms of the antiandrogen flutamide. Birds were sacrificed as adults and their brains prepared for histological analysis of the vocal control nuclei. Some DHT-treated females also received testosterone in adulthood. DHT had small, but significant effects on several attributes of the female song system, including increases of neuron number in RA and neuron size of RA and lateral magnocellular nucleus of the neostriatum (IMAN). DHT had no significant effects in males. Flutamide did not demasculinize any measures of the male song system but hypermasculinized volume and neuron number in RA. These data confirm studies that report few masculinizing effects of androgen on the female zebra finch song system. Nevertheless, the modest effects of DHT leave open the possibility that masculinization of the song system requires an action of androgen, perhaps in synergy with estrogen.     

Androgen regulation of dendritic growth and retraction in the development of a sexually dimorphic spinal nucleus

The spinal nucleus of the bulbocavernosus (SNB) is a sexually dimorphic group of motoneurons whose development and maintenance are under androgenic control. Exposure to androgens early in development permanently alters SNB motoneuron number and soma size; in adulthood, androgens regulate dendritic and synaptic architecture. The present set of experiments investigates the influence of androgens on the development of SNB dendritic morphology. In normal males, SNB dendritic growth is biphasic, reaching exuberant lengths by the fourth postnatal week and then retracting to adult lengths by 7 weeks of age. This dendritic growth is androgen dependent--males castrated on postnatal day (P) 7 and given daily injections of testosterone propionate (TP) had exuberant dendritic lengths similar to those of normal males; dendritic length in oil-treated males remained at P7 levels. The early exuberant dendritic length was retained in TP-treated males through P49. The retraction of SNB dendrites after P28 is also influenced by androgens. Males castrated at P28 and given testosterone implants retained exuberant dendritic length at P49; blank-implanted males had significantly shorter dendritic lengths by P70. These results suggest that androgens are necessary for the early exuberant growth of SNB dendrites. Furthermore, the subsequent retraction of SNB dendrites may be halted when testosterone titers reach a critical level during puberty, stabilizing their adult length.     

Testosterone fails to save androgen-sensitive rat motoneurons following early target removal.

Axotomy during development can result in the death of up to 100% of the affected motoneurons. However, axotomy-induced death can be significantly reduced by administration of androgens in young rats. Motoneuron death in the spinal nucleus of the bulbocavernosus (SNB) has previously been shown to be regulated by androgens during development. the present experiment examined the effects of androgen treatment on the survival of SNB motoneurons after target removal and concomitant axotomy early in development. On the day of birth, two target muscles of SNB motoneurons of male and female rats were bilaterally extirpated. Target removal resulted in a dramatic loss of SNB motoneurons within 48 h of surgery, with an ultimate loss of virtually all motoneurons projecting to the extirpated muscles by postnatal day 10. Treatment with testosterone failed to save SNB motoneurons from target removal-induced death. Pups treated with testosterone after target removal did not differ in the pattern or timing of motoneuron loss from untreated pups at any age examined. Counts of degenerating cells in the SNB reflected the extensive motoneuron loss and also did not differ with testosterone treatment. These results indicate that testosterone cannot save the androgen-sensitive SNB motoneurons from death after target removal and concomitant axotomy early in development. The failure of testosterone treatment to rescue SNB motoneurons in the absence of the SNB target musculature further suggests that during normal development, both androgens and target muscles are necessary for SNB motoneuron survival.