Developmental studies for identification of the inhibitory center of melanotropes in the toad, Bufo japonicus

Two series of experiments were performed to identify the inhibitory center of the melanotropes in the intermediate lobe of hypophysis of the toad, Bufo japonicus. First, developmental changes in the distribution of dopaminergic neurons were examined from hatching stage to postmetamorphosis using an antiserum against dopamine synthase (tyrosine hydroxylase, TH). In the postmetamorphic toads, TH-positive cell bodies were localized in three clusters. One was the preoptic recess organ (PRO) in the prechiasmatic area, the other two were the paraventricular organ (PVO) and infundibular nucleus (IN) in the postchiasmatic area. Each of them exhibited different ontogenetic changes. During larval development, TH-positive cell bodies were first detected in the PVO and IN at a premetamorphic stage. The number of immunoreactive cells increased rapidly in both loci as metamorphosis proceeded, although the two nuclei showed different growth profiles. By contrast, in the PRO, a very small number of immunoreactive cells were observed before the onset of the prometamorphic period. Although the number of immunoreactive neurons increased as metamorphosis progressed, early neurons were confined to the caudal area of the PRO (cPRO), the rostral area of the PRO (rPRO) being devoid of TH-positive cells. Immunoreactive TH neurons appeared in the rPRO for the first time at the end of meta-morphic climax. This timing coincided well with the development of TH-positive nerve endings in the pars intermedia (PI) and median eminence. In the second series of experiments, the embryonic primordium of the PRO was surgically extirpated from open neurulae to examine the effects of PRO-ectomy. In 75% of the operated animals, background adaptation was not observed, their dermal melanophores remained permanently dispersed even on the white background. Dopaminergic neurons in the rPRO and the immunoreactive nerve endings in the PI and median eminence were scarcely observed in these animals. It was concluded that the present data strongly support the hypothesis that rPRO is the center of white-background adaptation.     

Arrangement and connections of mesencephalic trigeminal neurons in the rat

The morphology of the mesencephalic trigeminal nucleus was examined microscopically in serial frozen sections. The nucleus extends over a length of about 4.5 mm, and its cell number was calculated to range from 1,000 to 1,600. 60% of the cells were located in the caudal third of the nucleus. Clustering of large unipolar cells was seen throughout the nucleus. Small spindle-shaped multipolar cells were found in the pontine part of the nucleus. The efferent connections of the mesencephalic trigeminal neurons were investigated by means of iontophoretically delivered Phaseolus vulgaris leuco-agglutinin or horseradish peroxidase after electrophysiological identification of mesencephalic trigeminal neurons. All projections were found ipsilateral to the injection site; they were confined to the trigeminal motor nucleus, especially to its lateral part, and to the dorsolateral reticular formation. The latter projection area included the supratrigeminal nucleus, the nucleus of Probst, and the parvocellular reticular zone. There were no direct projections to the facial or hypoglossal motor nuclei. It is concluded that proprioceptive input from one side is mediated polysynaptically to the bilateral oral final common-path neurons, with the exception of the ipsilateral trigeminal motoneurons.     

Differentiation of embryonic chick sympathetic neurons in vivo: ultrastructure,and quantitative determinations of catecholamines and somatostatin

Summary The ultrastructural and transmitter development of lumbar sympathetic ganglia was studied in embryonic day-6 through-18 chick embryos. At embryonic day 6, ganglia are populated by two morphologically distinct types of neuronal cells and Schwann cell precursors. The neuronal populations basically comprise a granule-containing cell and a developing principal neuron. Granule-containing cells have, an irregularly shaped or oval nucleus with small clumps of chromatin attached to the inner nuclear membrane and numerous large (up to 300 nm) membrane-limited granules. Developing principal neurons display a more rounded vesicular nucleus with evenly distributed chromatin, prominent nucleoli, more developed areas of Golgi complexes, and rough endoplasmic reticulum and large dense-core vesicles up to 120 nm in diameter. There are granule-containing cells with fewer and smaller granules which still display the nucleus typical for granule-containing cells. These granule-containing cells may develop toward developing principal neurons or the resting state of granule-containing cells found in older ganglia. Both granule-containing cells and developing principal neurons proliferate and can undergo degeneration. At embryonic day 9 there are far more developing principal neurons than granule-containing cells. Most granule-containing cells have very few granules. Mitotic figures and signs of cell degeneration are still apparent. Synapse-like terminals are found on both developing principal neurons and granule-containing cells. Ganglionic development from embryonic day 11 through 18 comprises extensive maturation of developing principal neurons and a numerical decline of granule-containing cells. Some granule-containing cells with very few and small granules still persist at embryonic day 18. The mean catecholamine content per neuron increases from 0.044 femtomol at embryonic day 7 to 0.22 femtomol at embryonic day 15. Concomitantly, there is a more than 6-fold increase in tyrosine hydroxylase activity. Adrenaline has a 14% share in total catecholamines at embryonic day 15. Somatostatin levels are relatively high at embryonic day 7 (1.82 attomol per neuron) and are 10-fold reduced by embryonic day 15. Our results suggest the presence of two morphologically distinct sympathetic neuronal precursors at embryonic day 6: one with a binary choice to become a principal neuron or to die, the other one, a granule-containing cell, which alternatively may develop into a principal neuron, acquire a resting state or die.     

Ontogeny of the FMRFamide-immunoreactivity in the rat forebrain and diencephalon

Ontogeny of the FMRFamide (molluscan cardioexcitatory neuropeptide)-containing structures in the forebrain and diencephalon of the rat was investigated by employing immunohistochemical methods. FMRFamide-like immunoreacted (FMRF-IR) fibers first appeared in the borders of the periventricular zone and the preoptic area at embryonic day 18 (E18). Toward birth, the FMRF-IR fibers gradually increased both in immunoreactivity and in number in these areas. A pronounced increase in FMRF-IR was also found in the septum, the arcuate nucleus, the median eminence, the paraventricular nucleus and the amygdaloid complex. A few FMRF-IR fibers appeared at the prenatal stage in the caudate nucleus, the bed nucleus of the stria terminalis, the dorsomedial nucleus and the cortex. The first FMRFamide-immunoreactive neurons were seen in the caudate-putamen and the amygdaloid complex at E21. These FMRF-IR cells increased in immunoreactivity and a significant number of cells was noted in these nuclei in the adult rat. The highest density of FMRF-IR neurons, especially in the amygdala and tuberal hypothalamic area, was detected at postnatal two weeks (P15). FMRFamide-like immunoreactivity in the forebrain and diencephalon appeared in the cell fibers prior to that observed in the cell bodies. This may suggest that some of the immunoreacted fibers may have originated from the lower areas of the rat brain. High densities of FMRF-IR cells present in the embryonic and early postnatal stages may indicate that FMRFamide is an important factor involved in developmental organization of the central nervous system. These results also indicate a differential genesis of FMRF-IR neuronal groups in different regions.     

Ascorbic acid promotes osteoclastogenesis from embryonic stem cells

Ascorbic acid (AA) is known to regulate cell differentiation; however, the effects of AA on osteoclastogenesis, especially on its early stages, remain unclear. To examine the effects of AA throughout the process of osteoclast development, we established a culture system in which tartrate-resistant acid phosphate (TRAP)-positive osteoclasts were induced from embryonic stem cells without stromal cell lines. In this culture system, the number of TRAP-positive cells was strongly increased by the addition of AA during the development of osteoclast precursors, and reducing agents, 2-mercaptoethanol, monothioglycerol, and dithiothreitol, failed to substitute for AA. The effect of AA was stronger when it was added during the initial 4 days during the development of mesodermal cells than when it was added during the last 4 days. On day 4 of the culture period, AA increased the total cell recovery and frequency of osteoclast precursors. Magnetic cell sorting using anti-Flk-1 antibody enriched osteoclast precursors on day 4, and the proportion of Flk-1-positive cells but not that of platelet-derived growth factor receptor alpha-positive cells was increased by the addition of AA. These results suggest that AA might promote osteoclastogenesis of ES cells through increasing Flk-1-positive cells, which then give rise to osteoclast precursors.     

Ontogenesis of serotoninergic nuclei in the rat stem

The development of central serotoninergic neurons has been investigated with immunohistochemical techniques using the indirect peroxidase-antiperoxidase (PAP) method in 16-and 19-day-old rat embryos, in 1, 10 and 26 days old young and in adult animals. Immunoreactive neurons were present on embryonic day 16 in the subventricular area of the brain stem. First the countour of nucleus raphe dorsalis became distinct in the subventricular cell mass of the lower midbrain. In the ventral part of the tegmentum, cells were grouped along the midline in bilateral columns from which the nucleus centralis superior, the nucleus raphe pontis and the nuclei pontis differentiated. These nuclei were well defined in the newborn on either side of the midline, and the nucleus centralis superior and nucleus raphe pontis were fused on the midline in 10-day old rat. In the ventral part of the pons and medulla, a bilateral cell mass was also found along the midline. A number of immunoreactive cells moving off the midline constituted the nucleus raphe magnus which was formed on 19. embryonis day. Another contingent of immunoreactive cells remained at the midline and formed the nuclei raphe obscurus and pallidus. In newborn rat, these nuclei were well separated from the nucleus raphe magnus. They would later fuse on the midline, whereas the nucleus raphe magnus would remain a bilateral structure.     

Spinal muscular atrophy disrupts the interaction of ZPR1 with the SMN protein

The survival motor neurons (smn) gene in mice is essential for embryonic viability. In humans, mutation of the telomeric copy of the SMN1 gene causes spinal muscular atrophy, an autosomal recessive disease. Here we report that the SMN protein interacts with the zinc-finger protein ZPR1 and that these proteins colocalize in small subnuclear structures, including gems and Cajal bodies. SMN and ZPR1 redistribute from the cytoplasm to the nucleus in response to serum. This process is disrupted in cells from patients with Werdnig-Hoffman syndrome (spinal muscular atrophy type I) that have SMN1 mutations. Similarly, decreased ZPR1 expression prevents SMN localization to nuclear bodies. Our data show that ZPR1 is required for the localization of SMN in nuclear bodies.     

Metamorphosis of the central nervous system of Drosophila

The study of the metamorphosis of the central nervous system of Drosophila focused on the ventral CNS. Many larval neurons are conserved through metamorphosis but they show pronounced remodeling of both central and peripheral processes. In general, transmitter expression appears to be conserved through metamorphosis but there are some examples of possible changes. Large numbers of new, adult-specific neurons are added to this basic complement of persisting larval cells. These cells are produced during larval life by embryonic neuroblasts that had persisted into the larval stage. These new neurons arrest their development soon after their birth but then mature into functional neurons during metamorphosis. Programmed cell death is also important for sculpting the adult CNS. One round of cell death occurs shortly after pupariation and a second one after the emergence of the adult fly.     

GABA influences the development of the ventromedial nucleus of the hypothalamus.

The region that becomes the ventromedial nucleus of the hypothalamus (VMH) is surrounded by cells and fibers containing immunoreactive gamma-aminobutyric acid (GABA) by embryonic day 13 (E13), several days before the nucleus emerges in Nissl stains. As GABA plays many roles during neural development, we hypothesized that it influences VMH development, perhaps by providing boundary information for migrating neurons. To test this hypothesis we examined the VMH in embryonic mice in which the beta3 subunit of the GABA(A)-receptor, a receptor subunit that is normally highly expressed in this nucleus, was disrupted by gene targeting. In beta3 -/- embryos the VMH was significantly larger, and the distribution of cells containing immunoreactive estrogen receptor-alpha was expanded compared to controls. Using in vitro brain slices from wild-type C57BL/6J mice killed at E15 we found that treatment with the GABA(A) antagonist bicuculline increased the number of cells migrating per video field analyzed in the VMH. In addition, treatment with either bicuculline or the GABA(A) agonist muscimol altered the orientation of cell migration in particular regions of this nucleus. These data suggest that GABA is important for the organization of cells during VMH formation.     

Maturation and degeneration of the fat body in the Drosophila larva and pupa as revealed by morphometric analysis

Using morphometric and cytochemical techniques we have described changes taking place in the fat body cells during three different stages of development. The cell number remains constant at about 2200 cells during larval life and then decreases gradually and continuously throughout metamorphosis and the first 3 days of the adult stage until no more cells can be observed. Cell size increases rapidly during the larval period and decreases steadily during metamorphosis and adult stage. The size of the nuclei increases during the larval instars and decreases during the pupal interval. The change in nuclear size is correlated with the amount of DNA present throughout development implying the nuclear DNA is synthesized during the larval period and degraded gradually during metamorphosis. The cell size changes are due in large part to accumulation or loss of reserve substances: lipid droplets, glycogen deposits and protein granules. During metamorphosis the amount of lipid decreases slightly whereas glycogen experiences two loss cycles. The protein granules in the form of lysosomes continue to increase in amount during the first day of metamorphosis because of a short period of massive autophagy. Then the lysosomes decrease in amount throughout the remainder of metamorphosis. The lysosomes stain positively for lipofuscin.     

Experimental analysis of hematopoietic cell development in the liver of larval Rana pipiens.

Hematopoietic cell development in the liver of Rana pipiens throughout the larval period was examined. Differential counts of Wright/Giemsa-stained cell suspensions demonstrated that hepatic hematopoiesis includes lymphoid, myeloid, and erythroid cell lineages. Hematopoietic activity appeared to be initiated near the end of embryonic development (Shumway stages 24–25) and reached a substantial level by 30 days of development (Taylor and Kollros stage IV). Although lymphopoiesis became highly variable during later larval stages, granulopoiesis remained stable and erythropoiesis increased throughout the larval period. Erythropoiesis is the predominant hematopoietic activity in the larval liver. Histological examination of plastic embedded tissue demonstrated that hematopoietic activity is localized in discrete foci within the endothelial-lined sinusoids. These hematopoietic foci are found in both the subcapsular region and deeper portions of the organ. Microdensitometric analysis of experimental embryos which received chromosomally labeled presumptive ventral blood island transplants at Shumway stage 15 indicated that the derivatives of this embryonic region are limited to the circulating erythrocyte population of the early larvae. The hematopoietic cell populations of the liver appear to be derived from an extrinsic stem cell source which may be located in the dorsal region of the early embryo.     

Differential stem cell contributions to thymocyte succession during development of Xenopus laevis.

The contribution of two embryonic stem cell compartments to the developing thymus in the amphibian Xenopus was examined throughout the larval, postmetamorphic, and adult periods. Hematopoietic chimeras were produced by transplanting either the ventral blood islands (VBI) or the dorsal stem cell compartment (DSC) from diploid donors onto triploid hosts. The DNA content of isolated nuclei harvested from the thymus and circulating E populations was analyzed using propidium iodide staining and flow cytometry. The DNA content of mitotic figures derived from PHA reactive splenocytes was analyzed using the Feulgen reaction and microdensitometry. These data suggested that both the VBI and DSC contribute to the thymocyte populations from the earliest developmental stages examined. Moreover, the contribution of both stem cell compartments was cyclic. However, the periods of these cycles were different. Both VBI- and DSC-derived cells entered the thymus 4 days postfertilization. VBI-derived thymocytes were at a minimum at 28 days postfertilization, reached a maximum at 35 days postfertilization and a second minimum at 42 days postfertilization. However, DSC-derived cells reached a maximum at 28 days, a minimum at 35 days, and a second maximum at 42 days. The PHA-reactive splenocyte population followed a similar temporal pattern. In contrast, the VBI-derived E population was at a maximum during early development and steadily declined throughout the larval period. DSC-derived E were undetectable during early development but steadily increased throughout the larval period. Both VBI- and DSC-derived hematopoietic cells persisted after metamorphosis and contributed to all populations examined in adult frogs. Because of temporal differences in the VBI and DSC contributions to the developing thymus, these data suggest heterogeneity within the thymocyte population associated with the embryonic origin of the colonizing stem cells.     

Testosterone propionate administration prevents the loss of neurons within the central part of the medial peroptic nucleus

In the rat, the central part of the medial preoptic nucleus (MPNc) of the male is larger in volume and has a greater number of neurons than that of the female. The nucleus of the female, however, can be “sex reversed” by exposing the rat to gonadal steroids perinatally. The purpose of the present study was to examine the development of the MPNc to determine when the sex difference first appears and whether this difference occurs due to the relative accumulation of neurons into the compact part of the MPNc of the male and sex-reversed female rat or to the loss of MPNc neurons in the control female. Pregnant, female Sprague-Dawley rats were given an injection of [³H]methyl thymidine on embryonic day 18 (E18). Rats were exposed to testosterone propionate (TP) or vehicle from E20 to postnatal day 10 (PN10) or until the time of sacrifice. Pups from three groups [males (oil), females (oil), and sex-reversed females (TP)] were sacrificed on PN2, PN4, PN7, PN10, or PN30. The volume of the compact part of the MPNc increased in males and sex-reversed females after PN4 but the volume in the nucleus of females remained relatively constant. The number of neurons and [³H]thymidine-labeled cells remained elevated from PN2–PN30 in males or sex-reversed females but decreased dramatically in oiltreated females between PN4 and PN7, reaching a minimal number by PN10. Cell cross-sectional area increased with age while cell density decreased. These observations are consistent with the hypothesis that the lack of growth of the compact part of the MPNc of the female is due to a loss of neurons while the increase in volume of the male's nucleus is due at least in part to growth of its constituent neurons. © 1993 John Wiley & Sons, Inc.     

Adipose tissue of Drosophila melanogaster: VII. Distribution of nuclear DNA amounts along the anterior-posterior axis in the larval fat body

The DNA content of fat body nuclei was measured cytophotometrically as a function of position along an anterior-posterior (A-P) axis of the tissue throughout larval development. There was a dramatic 55-fold increase in the average amount of DNA per nucleus during the first 3 days of this period, but there was no further increase during the final day. However, the rate of increase had regional specificity. The amount of DNA per nucleus correlated significantly with its position along the A-P axis of the tissue: nuclei in a posterior direction contain gradually increasing amounts of DNA. There was up to a seven-fold difference between the smallest anterior and largest posterior nucleus. In addition, for three of the ages studied there was a subgradient in the posterior region with a slope that was considerably steeper than that of the overall tissue gradient. The tissue has three characteristic morphological regions, anterior, medial, and posterior, which can be recognized early in development and which are maintained throughout the larval period. The distribution of nuclear DNA classes determined for cells in each region for the final 2 days of larval life became fixed before the final day of development. The significance of the DNA gradient in terms of a protein storage gradient is discussed.     

Synaptic arrays of the inner plexiform layer in the developing retina of Xenopus

During embryonic and larval development in Xenopus laevis, arrays of synapses made by amacrine cells form in two phases: an initial phase of rapid synaptic addition and a second phase of slower addition. In the region near the optic nerve, at which all measurements were made, these synapses first appear at stage 40 (approx 66 hr postfertilization). Connectivity increases at a rate of 8.6 synapses per hr per inner nuclear layer (INL) nucleus until stage 47 (132 hr postfertilization). After this phase the rate of formation decreases to 1.19 synapses per hr per INL nucleus. Synaptic arrays made by bipolar cells have only one phase of addition. A synapse made by a bipolar cell may be identified by its presynaptic ribbon, the first of which are seen at stage 40. Ribbons are added to the IPL neuropil at a rate of 4.6 ribbons per hr per INL nucleus until stage 47. After this the number of ribbons per INL nucleus in the area near the optic nerve remains constant. Although they may be found, amacrine to amacrine synapses (serial conventional) remain at low numbers throughout larval and early postmetamorphic life. This is unlike the condition found in Rana pipiens where a dramatic increase in amacrine to amacrine connectivity occurs at metamorphosis.     

Cholinergic neuronotrophic factors: VI. Age-dependent requirements by chick embryo ciliary ganglionic neurons

During development, ciliary ganglionic neurons become postmitotic and extend neurites in apparent independence of the presence of their future intraocular innervation targets. After reaching their peripheral innervation territory, however, these neurons become target dependent and about half of them die. We have previously reported that chick embryo intraocular target tissues contain a ciliary neuronotrophic factor (CNTF), which can be extracted and partially purified in a soluble form and which ensures near-total survival of 8-day chick embryo ciliary ganglionic neurons in monolayer cultures. In this study we have dissociated and cultured ciliary ganglia from embryonic Day (ED) 5 through 14, and examined dependence and responsiveness of their neurons to exogenously added CNTF. Two cell classes (dark and bright) could be distinguished by phase microscopy and differentially counted in cell dissociates from ED7–14, but not in ED5–6 ones. Dark cell number per ganglion increased from 6000 to 78,000 over this developmental time period. In contrast, bright cells (putative neurons) declined from a maximum of about 10,000 to 6000, suggesting a correlation with the expected neuronal cell death in vivo. Dissociated cells from ED5–14 ganglia were seeded on a polyornithine substratum coated with neurite promoting factor, cultured for 24 hr with or without added CNTF, and numerically examined for survival and neuritic development. Cultures from ED7–14 ganglia showed two cell categories: (i) flat nonneuronal elements dramatically increased in number with ganglionic age (thereby correlating with the increasing number of dark cells in the dissociates) and (ii) large, bright cells (often displaying neurite outgrowth) decreased in number in parallel with bright cell number in the dissociate. The survival of these neuronal elements was strictly dependent on exogenously added CNTF between ED7 and 10, but became progressively independent with older ages. ED14 neurons (fully capable of surviving for 24 hr without added CNTF) continued to require CNTF for neurite extension, thus displaying retained sensitivity to this factor. Although the ED5–6 cultures contained well-recognizable flat cells, the dominant category comprised cells with variable morphology, practically all of which exhibited neurite-like processes. Both the survival and neurite extension of these cells, which we tentatively interpret as immature neurons were independent of the presence of added CNTF.     

Immunocytochemical localization of aromatase-containing neurons in the rat brain during pre- and postnatal development

the present immunohistochemical study demonstrates the ontogenetic appearance of aromatase-immunoreactive neurons in several discrete regions of the hypothalamus and limbic system in the rat brain, using a purified antibody against human placental aromatase cytochrome P450. Immunoreactive cells were first detected in the preoptic area on the 13th day of embryonic life (E 13), and additionally in the bed nucleus of the stria terminalis on E 15. Labeled cells were also found in the medial amygdaloid nucleus and the ventromedial nucleus on E 16, and some were detected in the arcuate nucleus on E 19. As gestation progressed, the number and the immunoreactivity of these cells gradually increased and peaked within definite periods of perinatal life and there-after declined or disappeared. The immunoreactive cells were also found in the central amygdaloid nucleus and the lateral septal nucleus, and in the ventral pallidum, after the 14th day of postnatal life (P 14) and 30th day (P 30), respectively. The distribution of aromatase-immunoreactive neurons was similar between the sexes, while the immunoreactivity was higher in males than in females after late gestational days. No immunoreaction was detectable in other regions of the telencephalon or midbrain at any time periods studied. The aromatase-immunoreactive neurons in the specific regions may be involved in the sexual differentiation of the brain.     

Postnatal changes in the expression of serotonin 2A receptors in various brain stem nuclei of the rat.

Previously, we reported a critical period [around postnatal day (P) 12-13 in the rat] in respiratory network development when distinct neurochemical, metabolic, and physiological changes occur. Since serotonin 2A (5-HT(2A)) receptors play an important role in respiratory modulation, we hypothesized that they may undergo developmental adjustments during the critical period. Semi-quantitative immunohistochemical analyses were conducted in labeled neurons in a number of brain stem nuclei with or without known respiratory functions from P2 to P21 in rats. Our data indicate that the expressions of 5-HT(2A) receptors in neurons of the pre-B?tzinger complex, the nucleus ambiguus, and the hypoglossal nucleus were maintained within a relatively narrow range between P2 and P21, with a dip at P3-P4 and a significant reduction only at P12. This change was not observed in the nonrespiratory cuneate nucleus. These results suggest that reduced expressions of 5-HT(2A) receptors at P12 contributes to neurochemical imbalance within brain stem respiratory nuclei at that time and may be involved in decreased hypoxic ventilatory response at this critical period of development.     

Influence of altered afferent input on the number of trochlear motor neurons during development

A loss of about half of the trochlear motor neurons occurs during the course of normal development. The present investigation was undertaken to examine the role of afferent input in regulating the number of surviving or dying trochlear motor neurons. A majority of the afferent input to the trochlear nucleus comes from the vestibular nuclei of the hindbrain via the medial longitudinal fasciculus. Portions of the hindbrain were lesioned in duck embryos on embryonic day 3, considerably prior to the time motor neurons send their axons out and cell death begins. The effectiveness of hindbrain lesion was verified by electron microscopical examination of synapses. There was a significant decrease in the number of synapses on trochlear motor neurons following hindbrain lesion. Cell counts made after the period of cell death indicated a significant decrease in the final number of surviving trochlear motor neurons. Cell counts made prior to the onset of cell death indicated that there was a drastic reduction in the initial number of trochlear motor neurons produced in hindbrain lesion embryos. In spite of a significant reduction in the initial number of neurons, the percentage loss of neurons was about the same as during normal development. Since trochlear motor neurons are generated prior to the formation of afferent synapses on them, it is unlikely that the reduction in the number of motor neurons initially produced is due to reduced afferent synaptic input. Since the percentage of cell loss in hindbrain lesion and normal embryos is about the same, it seems that the magnitude of cell death is genetically programmed. These observations suggest that the afferent synaptic input to the trochlear motor neurons may not be as important as previously thought in regulating cell number during development. They also suggest that some afferent input, of nonsynaptic type, available at very early stages of development may specify the initial number of trochlear motor neurons produced and that a fixed percentage of that number is programmed to die during development. It is suggested that this early influence may be provided by the embryonic medial longitudinal fasciculus.     

The spinal muscular atrophy disease gene product, SMN: A link between snRNP biogenesis and the Cajal (coiled) body

The spliceosomal snRNAs U1, U2, U4, and U5 are synthesized in the nucleus, exported to the cytoplasm to assemble with Sm proteins, and reimported to the nucleus as ribonucleoprotein particles. Recently, two novel proteins involved in biogenesis of small nuclear ribonucleoproteins (snRNPs) were identified, the Spinal muscular atrophy disease gene product (SMN) and its associated protein SIP1. It was previously reported that in HeLa cells, SMN and SIP1 form discrete foci located next to Cajal (coiled) bodies, the so-called "gemini of coiled bodies" or "gems." An intriguing feature of gems is that they do not appear to contain snRNPs. Here we show that gems are present in a variable but small proportion of rapidly proliferating cells in culture. In the vast majority of cultured cells and in all primary neurons analyzed, SMN and SIP1 colocalize precisely with snRNPs in the Cajal body. The presence of SMN and SIP1 in Cajal bodies is confirmed by immunoelectron microscopy and by microinjection of antibodies that interfere with the integrity of the structure. The association of SMN with snRNPs and coilin persists during cell division, but at the end of mitosis there is a lag period between assembly of new Cajal bodies in the nucleus and detection of SMN in these structures, suggesting that SMN is targeted to preformed Cajal bodies. Finally, treatment of cells with leptomycin B (a drug that blocks export of U snRNAs to the cytoplasm and consequently import of new snRNPs into the nucleus) is shown to deplete snRNPs (but not SMN or SIP1) from the Cajal body. This suggests that snRNPs flow through the Cajal body during their biogenesis pathway.