Initial sex differences in neuron growth and survival within an avian song nucleus develop in the absence of afferent input

Only male zebra finches (Poephila guttata) sing, and nuclei implicated in song behavior exhibit marked sex differences in neuron number. In the robust nucleus of the anterior neostriatum (RA), these sex differences develop because more neurons die in young females than in males. However, it is not known whether the sexually dimorphic survival of RA neurons is a primary event in sexual differentiation or a secondary response to sex differences in the number of cells interacting trophically with RA neurons. In particular, since sexual differentiation of the RA parallels the development of dimorphisms in the numbers of neurons providing afferent input from the lateral magnocellular nucleus of the anterior neostriatum (lMAN) and the high vocal center (HVC), it has been hypothesized that sex differences in the size of these afferent populations trigger differential RA neuron survival and growth. To test this hypothesis, we lesioned either the lMAN or both the lMAN and HVC unilaterally in 12-day-old male and female zebra finches. Subsequently, RA cell death and RA neuron number and size were measured. Unilateral lMAN lesions increased cell death and decreased neuron number and size within the ipsilateral RA of both sexes. However, even in the lMAN-lesioned hemisphere, these effects were less pronounced in males than in females, so that by day 25 the volume, number, and size of neurons were sexually dimorphic in both the contralateral and ipsilateral RA. Similarly, the absence of both lMAN and HVC afferents did not prevent the emergence of sex differences in the number and size of RA neurons by 25 day posthatching. We conclude that these sex differences within the RA are not a secondary response to dimorphisms in the numbers of lMAN or HVC neurons providing afferent input. © 1995 John Wiley & Sons, Inc.     

Trophic effects of androgen: Development and hormonal regulation of neuron number in a sexually dimorphic vocal motor nucleus

In Xenopus laevis, the laryngeal motor nucleus (n. of cranial nerves IX‐X) is part of a sexually differentiated, androgen sensitive neuromuscular system devoted to vocalization. Adult males have more n. IX‐X neurons than females; however, during development of n. IX‐X, the rate of neurogenesis does not appear to differ between the sexes. In this study, we explored the role of naturally occurring cell death in the development of this nucleus and asked whether cell death might be involved in establishing the sex difference in neuron number. Counts of n. IX‐X neurons reveal that at tadpole stage 56, males and females have similar numbers of n. IX‐X neurons, but by stage 64 male neuron numbers are greater. This sex difference arises owing to a greater net loss of neurons in females—males lose ∼25% of their n. IX‐X neurons between stages 56 and 64, while females lose ∼47%. Sexual differentiation of n. IX‐X neuron number coincides with a period of developmental cell death, as evidenced by terminal transferase‐mediated dUTP nick‐end labeling and the presence of pyknotic nuclei in n. IX‐X. A role for gonadal hormones in controlling cell number was examined by treating tadpoles with exogenous androgen and determining the number of n. IX‐X neurons at stage 64. Dihydrotestosterone (DHT) treatment from the beginning of the cell death period (stage 54) until stage 64 had no effect on the number of n. IX‐X neurons in males but did significantly increase n. IX‐X neuron number in females. This increase was sufficient to abolish the sex difference normally observed at stage 64. Although DHT induced increases in female neuron number, it did not induce increases in cell proliferation or addition of newly born neurons to n. IX‐X. DHT may therefore have increased neuron number by protecting cells from death. We conclude that androgens can influence the survival of n. IX‐X neurons during a period of naturally occurring cell death, and that this action of androgen is critical to the development of sex differences in n. IX‐X neuron number. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 375–385, 1999     

Sex-dependent loss of projection neurons involved in avian song learning

In zebra finches, only males sing, and the neural regions controlling song exhibit prominent, hormone-induced sex diffences in neuron number. In order to understand how sexual differentiation regulates neuron number within one song nucleus, the lateral magnocellular nucleus of the anterior neostriatum (IMAN), we studied the development of sex differences among IMAN neurons that project to the robust nucleus of the archistriatum (RA). The IMAN is implicated in song learning, and previous ontogenetic studies have indicated that males lose over 50% of their IMAN neurons during the juvenile song learning period. Based on developmental changes in both the extent of androgen accumulation within the IMAN and its appearance in Nissl-stained tissue, it had been hypothesized that IMAN neuron loss was even greater in young females, resulting in sex differences in neuron number. However, this hypothesis has not been tested directly because the Nissl-stained boundaries of the IMAN sometimes are ambiguous in young animals, and are not evident at all in adult females. To circumvent these problems, we employed the retrograde tracer fast blue to study the development of IMAN neurons defined on the basis of their projections to the RA. We find that the number of these IMAN-RA projection neurons is much greater in adult males than in females, and that this sex difference develops during the juvenile period of sexual differentiation and song learning because a significant number of these neurons are lost in females but not in males. With respect to sexual differentiation, we conclude that masculinization (which is stimulated by the hormone estradiol) promotes the retention of IMAN-RA projection neurons. In addition, our results indicate that any loss of IMAN neurons that may occur in young males does not include cells projecting to the RA. © 1992 John Wiley & Sons, Inc.     

Sexually dimorphic neuron addition to an avian song-control region is not accounted for by sex differences in cell death

Only male zebra finches sing, and several brain regions implicated in song behavior exhibit marked sex differences in neuron number. In one region, the high vocal center (HVC), this dimorphism develops because the incorporation of new neurons is greater in males than in females during the first several weeks after hatching. Although estrogen (E₂) exposure stimulates neuron addition in females, it is not known where (E₂) acts, or to what extent sexual differentiation influences the production, specification, or survival of HVC neurons. In the present study we first reassessed sex and (E₂)-induced differences in cell degeneration within the HVC using the TUNEL technique to identify cells undergoing DNA fragmentation indicative of apoptosis. HVC neuron number, as well as the density and number of TUNEL-labeled and pyknotic cells within the HVC were measured in normal 20- and 30-day-old males and females, and in 30-day-old females implanted with E₂ on posthatch day 18. Although HVC neuron number was greater in males than in females, and was masculinized in E₂ females, no group differences were evident in the absolute number of dying cells. These results indicate that sex differences in cell survival within the HVC do not entirely account for sexually dimorphic neuron addition to this region. Rather, sexual differentiation acts on some HVC neurons before they complete their migration and/or early differentiation. Although the migratory route of HVC neurons is not known, a large number of E₂ receptor-containing cells (ER cells) reside just ventromedial to the HVC and adjacent to the proliferative ventricular zone. Next, we investigated whether these ER cells contribute to early-arising sex differences in HVC neuron addition. By combining [³H] thymidine autoradiography with immunocytochemistry for ERs, we first established that ER-expressing cells are not generated during posthatch sexually dimorphic HVC neuron addition, and thus are not young HVC neurons that transiently express ERs during their migration. Furthermore, in 25-day-old birds we found no sex difference in the density of pyknotic cells among this group of ER cells, suggesting that these cells do not promote the differential survival of HVC neuronal precursors migrating through this region. Rather, ER cells or other cell populations may establish sex differences in HVC neuron number by creating dimorphisms in cellular specification. © 1997 John Wiley & Sons, Inc. J Neurobiol 33: 61–71, 1997     

Fibroblast growth factor-2 stimulates cell proliferation and decreases sexually dimorphic cell death in an avian song control nucleus

The neural system controlling song in birds has proven a useful model for investigating how neuronal growth and survival are regulated by sexual differentiation. The present study focused on one song control area, the robust nucleus of the archistriatum (RA), and explored how sex differences in the proliferation of putative glia cells in this region influence sexually dimorphic cell survival. In zebra finches (Poephila guttata), RA neuron death is much greater in young females than in males, resulting in marked sex differences in RA neuron number. An earlier study indicated that just prior to this sexually dimorphic neuron death the proliferation of putative glia cells within the RA is significantly lower in females than in males and remains so throughout the peak of neuron death. This suggests that sex differences in glia (or glia-derived molecules) might regulate neuron survival during sexual differentiation of the RA. To determine whether increased cell proliferation within the RA favors increased cell survival, we infused the potent glia mitogen fibroblast growth factor-2 (FGF-2) into the RA unilaterally in young females. We find that FGF-2 infusions increase RA cell proliferation and concurrently decrease the incidence of degenerating RA cells, results consistent with the hypothesis that glia exert neurotrophic effects on RA neurons during sexual differentiation. © 1998 John Wiley & Sons, Inc. J Neurobiol 37: 573–581, 1998     

Neurogenesis of the sexually dimorphic vasopressin cells of the bed nucleus of the stria terminalis and amygdala of rats

The bed nucleus of the stria terminalis (BNST) and centromedial amygdala share many neuroanatomical and neurochemical characteristics, suggesting similarities in their development. Here we compare the neurogenesis of a group of cells for which already several common characteristics have been documented, that is, the sexually dimorphic arginine vasopressin-immunoreactive (AVP-ir) cells of the BNST and amygdala. To determine when these cells are born, pregnant rats received intraperitoneal injections of the thymidine analogue bromo-2-deoxy-5-uridine (BrdU) on one of nine embryonic days, E10 to E18; E1 being the day that a copulatory plug was found. At 3 months of age, the offsprings of these females were killed and their brains stained immunocytochemically for BrdU and AVP. Most AVP-ir cells were labeled with BrdU by injections on E12 and E13. Although BrdU labeling of AVP-ir cells did not differ between the BNST and amygdala, it differed between males and females. From E12 to E13, the percentage of BrdU-labeled AVP-ir cells decreased more in males than in females. AVP-ir cells appeared to be born earlier than most other cells in the same area, the majority of which were labeled with BrdU by injections on E14, E15, and E16. The similarities in the birthdates of AVP-ir cells in the BNST and amygdala may help to explain why these cells take on so many similar characteristics. The sex difference in birthdates of AVP-ir cells may help to explain which cellular processes underlie the sexual differentiation of these cells. © 1996 John Wiley & Sons, Inc.