Co-localization of proenkephalin mRNA using cRNA probes and a cell-type-specific immunocytochemical marker for intact astrocytes in vitro

To determine whether cultured astrocytes express opioid gene mRNA, a method was developed for co-localizing a cell-type specific immunocytochemical marker for astrocytes, glial fibrillary acidic protein (GFAP), and proenkephalin mRNA in situ hybridization signal using high affinity cRNA probes. GFAP immunoreactivity and proenkephalin mRNA hybridization reaction were examined in intact glial cell preparations from neonatal mice that were cultured for 4-6 days prior to fixation. The double labelling method described herein permits the unambiguous identification of mRNA expression in specific populations of intact cultured cells using cell type-specific markers.

Cellular localization of proenkephalin mRNA and enkephalin peptide products in cultured astrocytes

To identify the possible cellular sites of opioid gene expression during ontogeny, proenkephalin mRNA and enkephalin peptide expression were examined, respectively, by in situ hybridization and immunocytochemistry in organotypic explants of rat cerebellum and in astrocyte-enriched cultures of murine cerebral hemispheres. High levels of proenkephalin mRNA and enkephalin immunoreactivity were detected in immature cells identified as astrocytes. Double-labeling studies combining in situ hybridization and immunocytochemical localization of the astrocytic marker, glial fibrillary acidic protein, provided direct evidence that proenkephalin mRNA is expressed by astrocytes in culture. Based on previous studies that Met-enkephalin can inhibit astrocyte growth in vitro, the present results suggest that proenkephalin gene expression by astrocytes is important during central nervous system maturation.

Opioid-dependent growth of glial cultures: suppression of astrocyte DNA synthesis by met-enkephalin

The action of met-enkephalin on the growth of astrocytes in mixed-glial cultures was examined. Primary, mixed-glial cultures were isolated from 1 day-old mouse cerebral hemispheres and continuously treated with either basal growth media (controls), 1 microM met-enkephalin, 1 microM met-enkephalin plus the opioid antagonist naloxone (3 microM), or naloxone alone (3 microM). Absolute numbers of neural cells were counted in unstained preparations, while combined [3H]-thymidine autoradiography and glial fibrillary acid protein (GFAP) immunocytochemistry was performed to identify specific changes in astrocytes. When compared to control and naloxone treated cultures, met-enkephalin caused a significant decrease in both total cell numbers, and in [3H]-thymidine incorporation by GFAP-positive cells with flat morphology. These results indicate that met-enkephalin suppresses astrocyte growth in culture.

Androgen increases the number of cells in fetal mouse spinal cord cultures: implications for motoneuron survival

Androgen effects were studied in organotypic cultures of the E12 fetal mouse lumbosacral spinal cord labeled in utero with [3H]thymidine on E10. Following continuous exposure to androgens for one month in vitro, the number of labeled cells was significantly increased in whole explants, and in hemisected segments in the presence or absence of co-cultured fetal thigh muscle. Because lumbosacral motoneurons undergo their final mitosis predominantly on E10 and thus remain permanently labeled, the results suggest that androgens increase neuronal numbers by directly modulating motoneuron survival rather than stimulating mitosis. These findings demonstrate for the first time that in addition to the well documented role of the muscle target in motoneuron survival, the direct neuronotrophic effects of androgen at the level of the spinal cord must also be considered.

Endogenous opioid systems and the regulation of dendritic growth and spine formation

The role of endogenous opioid systems (endogenous opioids and opioid receptors) in neuronal development was examined in 10- and 21-day-old rats by utilizing an opioid antagonist (naltrexone) paradigm. Throughout the first 3 weeks of life, Sprague-Dawley rats were given daily subcutaneous injections of either 50 mg/kg naltrexone, a dosage that invoked a complete (24 hours/day) receptor blockade, or 1 mg/kg naltrexone, a dosage which intermittently blocked (4-6 hours/day) opioid receptors and exacerbated opioid action; animals injected with sterile water served as controls. Pyramidal cells from the frontoparietal cortex (layer III) and hippocampal field CA1, and cerebellar Purkinje cells, were impregnated by using the Golgi-Kopsch method; total and mean dendrite segment length, branch frequency, and spine concentration were analyzed morphometrically. Perturbations of endogenous opioid systems caused region-dependent alterations in dendrite complexity and/or spine concentration in all brain areas. Continuous opioid receptor blockade resulted in dramatic increases in dendrite and/or spine elaboration compared to controls at 10 days in all brain regions; however, these increases were only evident in the hippocampus at 21 days. With intermittent blockade, dendrite and/or spine growth were often subnormal, being predominant at day 21. Our results indicate that endogenous opioid systems are critical regulators of neuronal differentiation, and they control growth through an inhibitory mechanism. Considering previous findings demonstrating that neurobehavioral ontogeny is dependent on endogenous opioid-opioid receptor interactions, the present results suggest an opioid-dependent, structure-function relationship between neuronal and behavioral maturation.

Autoradiographic studies of cerebellar histogenesis in the premetamorphic bullfrog tadpole: II. Formation of the interauricular granular band

This study examines the origin of cells in the interauricular granular band (iagb) in the cerebellum of the frog tadpole during early stages of development by means of histological and autoradiographic methods. Premetamorphic bullfrog tadpoles were exposed to multiple doses of 3H-thymidine (10 microCi/g body weight per exposure) at developmental stages ranging from 1 week to 1 year and were killed at either 6 or 12 months of age. The autoradiographic data were examined to determine the time when cells of the iagb were generated. Our findings show that initial generation of iagb cells begins at week 3 and that a peak in the formation of postmitotic neurons is reached at the age of 10 weeks. This is followed by other peaks of cell generation at the ages of 16 weeks, 10 months, and 11.5 months. The generation cycles of iagb cells are interrupted by periods of quiescence when label cannot be detected in any of the cells. These quiescent periods occur at the ages of 20-26 weeks, 7 months, and 12 months. These findings indicate that cells of the iagb are generated in a cyclical manner over the entire 1-year period which was studied. Comparison of our present data on iagb cell formation with the generation of cells in the EGL shows that the production of these two groups of cells is overlapping, but cells of the iagb begin and cease production before those of the EGL. On the basis of our findings we propose that the cells of the iagb and the EGL belong in separate cell groups which are generated by distinct subpopulations of germinal cells in the neuroepithelial cap.

Autoradiographic studies of cerebellar histogenesis in the premetamorphic bullfrog tadpole: I. Generation of the external granular layer

This study examines the time of origin of cells in the external granular layer (EGL) in the frog cerebellum during early stages of development. Premetamorphic bullfrog tadpoles were given multiple intraperitoneal injections of 3H-thymidine (10 microCi/g body weight per injection) at developmental stages ranging from 4 weeks to 1 year and were killed at either 6 or 12 months of age. Autoradiograms were analyzed to determine the time when cells of the EGL were generated by an examination of the labeling pattern in the neuroepithelial cap where EGL cells were presumably formed and in the EGL into which they migrated. The developmental stage of the cerebellum in the 6-month-old tadpole was essentially the same as that of the 12-month-old animal except for an increased size in the older tadpole. The cerebellum in both age groups contained a distinct neuroepithelial cap and an EGL, which was somewhat better formed in the 12-month-old tadpole. Some heavily labeled cells were found in the neuroepithelial caps of 6-month-old tadpoles from injection times of 6 weeks to 6 months. In the cerebella of 12-month-old tadpoles, however, heavily labeled cells were found in the neuroepithelial cap only with the injection time of 12 months; with injection times from 7 to 11 months, the cells were labeled lightly. Labeled EGL cells were found in the cerebella of 6-month-old tadpoles from an injection time of 6 weeks on; with injection times from 10 weeks to 6 months some EGL cells contained heavy amounts of label. In the cerebella of 12-month-old tadpoles, labeling of EGL cells was not detectable with injection times of 7-9 months; they contained light to medium labeling with injection times of 10 and 11 months and heavy labeling when injected at 12 months. These results indicate that EGL cells are generated continuously in premetamorphic tadpoles from the age of 6 weeks to 12 months. Furthermore, these results suggest that the rate of EGL cell formation is faster during the second half-year of development than during the first.

Endogenous opioids regulate dendritic growth and spine formation in developing rat brain

Continuous blockade of endogenous opioid-opioid receptor interaction by opioid antagonists from birth to day 10 increased neuronal maturation in the rat brain. The lengths of oblique dendrites of pyramidal cells in the cerebral cortex and basilar dendrites of the hippocampus were increased from controls by 136 and 51%, respectively, whereas the concentrations of spines in these cells were increased 183 and 69%, respectively. Total dendritic length of spiny branches of cerebellar Purkinje neurons was 65% greater than controls, and spine concentration of granule cells in the dentate gyrus was increased by 76%. Thus, endogenous opioids exert a remarkable influence on the timetable and magnitude of dendritic elaboration and spine formation, and serve as an important trophic influence in the regulation of neuro-ontogeny.

Androgen action in fetal mouse spinal cord cultures: metabolic and morphologic aspects

Morphologic and metabolic aspects of androgen effects on the developing spinal cord were studied in organotypic cultures of the E13 (embryonic day 13) fetal mouse lumbosacral spinal cord, maintained as either hemisected, homologous explant pairs co-cultured with bulbocavernosus muscle (morphologic studies), or as whole cross-sectional segments without muscle in which the nutrient medium was supplemented with muscle extract (metabolic studies). Metabolic studies demonstrated the total absence of aromatase activity. 5 alpha-Reductase activity, on the other hand, increased differentially in a segment-dependent manner in spinal cord explants from 0 to 35 days in culture, suggesting regional differences in the utilization of testosterone and its 5 alpha-reduced metabolites. In all studies, spinal cord explants showed androgen-dependent increases in neurite outgrowth, although this was most pronounced in spinal cord-muscle co-cultures. These results indicate that androgens per se affect very early development throughout the entire lumbosacral spinal cord, and that this influence is not restricted to those segments reported to be sexually dimorphic in the adult.

Granule cell development in the frog cerebellum during spontaneous and thyroxine-induced metamorphosis

Granule cell maturation in the cerebellum of bullfrog tadpoles was studied during both spontaneous and thyroxine-induced metamorphosis by using electron microscopy and Golgi-impregnated preparations. The production of cerebellar microneurons, a majority of which are granule cell precursors, was quantitatively compared during spontaneous and thyroxine-induced metamorphosis by using stereological methods and biochemical measurements of DNA. Granule cell migration and differentiation appeared morphologically similar during spontaneous and thyroxine-induced metamorphosis. In both instances, granule cells migrated tangentially along the pial surface, migrated into the internal granular layer, developed dendritic arbors, and formed synaptic contacts with the processes of Golgi cells and with mossy fibers. These events are similar to developmental processes that have been described in detail in other animals. Quantitative stereological measurements demonstrated similar overall patterns of change during spontaneous and thyroxine-induced metamorphosis. Most notably, increases in the volume of the external granule layer correlated with increases in the relative and total amounts of DNA. However, measurements of total DNA were consistently reduced during the period of accelerated change that occurs in thyroxine-induced metamorphosis, although external granular layer volume was greater in these tadpoles after 2 and 3 weeks of thyroxine treatment than in spontaneously metamorphosing tadpoles. While granule cell development in the frog is largely dependent on thyroid hormone, differences between thyroid-hormone-induced and spontaneously metamorphosing tadpoles suggest that normal patterns of cerebellar development are also dependent on events that occur in premetamorphic tadpoles in the absence of thyroid hormone.

Stellate cell development in the frog cerebellum during spontaneous and thyroxine-induced metamorphosis

Stellate cell development was studied in the bullfrog cerebellum during spontaneous and thyroxine-induced metamorphosis using the Golgi-Kopsch method and electron microscopy. Cells that possessed axosomatic synapses and resembled stellate cells were present even in the incipient molecular layer of the cerebellum in the premetamorphic tadpole. These cells may have originated from the early, transient wave of external granule cells that have been reported in the cerebellum of premetamorphic tadpoles in the first 6 months of development, and may constitute the variant population of stellate cells that are present later during development or the degenerating cells that have been observed during metamorphosis as scattered dying cells in the molecular layer. Typical stellate cells, whose development resembled the genesis and differentiation of stellate cells in birds and mammals, were initially observed at the outer border of the molecular layer that is adjacent to the external granular layer during the onset of metamorphosis. These stellate cells were bipolar with processes extending in a plane perpendicular to elongating parallel fibers, and with progressive development, became multipolar with dendrites oriented in various directions with respect to the pia. Stellate cell axons innervate the dendrites and somata of Purkinje cells and other stellate cells, and can be categorized into two types: (1) axons with extensive branching near the soma of origin, and (2) long axons with few branches that occasionally terminate in the Purkinje cell layer. Atypical neurons that did not resemble typical stellate cells were also present in the molecular layer; these might be classified as a stellate cell variant. The generation and differentiation of stellate cells can be induced 1 to 2 years prematurely by administering thyroid hormone to premetamorphic tadpoles. Like most events of cerebellar histogenesis in the frog, stellate cell development also appears to be largely a thyroid-dependent phenomenon.

Purkinje cell maturation in the frog cerebellum during thyroxine-induced metamorphosis

Purkinje cell maturation during thyroxine-induced metamorphosis in premetamorphic bullfrog tadpoles was studied using electron microscopy and Golgi (silver-impregnated) preparations. Cerebella from tadpoles were examined following 1, 2, or 3 weeks of thyroxine treatment. Particular attention was paid to possible differences between the two populations of Purkinje cells previously described, i.e. (i) the smaller population located in the dorsal part of the cerebellum, where the Purkinje cells show dendritic arborization long before the appearance of the external granular layer, and (ii) the larger population located in the middle and ventral regions of the cerebellum, where the Purkinje cells begin to undergo maturation during metamorphosis when the external granular layer is established. Following thyroxine treatment, both populations of Purkinje cells showed rapid maturational change. In the mature (dorsal) group, dendritic growth resumed in the presence of an external granular layer increasing the complexity of their dendritic arbors. Moreover, climbing fiber synapses translocated from contacts on the soma to the thorns of growing dendrites, and somatic processes often disappeared. The immature (ventral) group showed dramatic differentiation of the perikaryon including polarization of cytoplasm with subsequent dendritic outgrowth and formation of somatic processes in the presence of climbing fibers. Stellate cell contacts appeared on the smooth portion of the soma of many Purkinje cells. Dendritic growth during thyroxine-induced metamorphosis was characterized by growth (elongation) with minimal branching, which is initially observed during spontaneous metamorphosis. Typically, these growing dendrites ended in growth cones, some with one or several filopodia. Developing Purkinje cell dendritic spines formed synapses with parallel fibers. The present study has provided an example of the dramatic nature of thyroxine's action in inducing the complex series of detailed maturational changes in the cerebellum 1-2 yr ahead of schedule. In addition, the results show that thyroxine-induced Purkinje cell maturation is more rapid and synchronous than that seen during spontaneous metamorphosis. It is concluded that Purkinje cell maturation during metamorphosis is largely dependent on thyroid hormone.

Effects of thyroidectomy and season on the external granular layer of the cerebellum in metamorphosing bullfrog tadpoles (Rana catesbeiana)

Transient formation of the cerebellar external granular layer (EGL) occurs during metamorphosis in frog tadpoles and is dependent on thyroid hormone. Late prometamorphic bullfrog tadpoles at similar stages of development were thyroidectomized and then killed after 1 month and 2 months during the fall and winter. The cerebellum was studied by qualitative and quantitative light microscopy. Thyroidectomy resulted in an inhibition of external metamorphic changes such as hind limb growth. Examination of the cerebellum after thyroidectomy showed the EGL greatly decreased in thickness after 1 month and in some cases was altogether absent after 2 months. Because the disappearance of EGL cells was a result of their inward migration into the IGL, we conclude that thyroid hormone was not necessary for granule cell migration. In addition, metamorphic change normally occurs in the late spring and summer in bullfrog tadpoles, and is inhibited during the fall and winter (metamorphic stasis). During the winter, the volume of the EGL was significantly less compared with tadpoles undergoing active metamorphosis. Although lowered temperature appears to contribute to the large decline in EGL thickness, significant seasonal differences in the EGL volume ratio were still observed in tadpoles maintained under conditions of constant temperature and light. Thyroxine administered to thyroidectomized tadpoles during the winter increased the thickness of the EGL. Therefore, the seasonal decline in the EGL thickness reflects a decrease in thyroid hormone activity, which in turn appears controlled by both internal (hypothalamic) and environmental (e.g., temperature) factors.

Ultrastructural studies on the ventricular surface of the frog cerebellum

Ultrastructural studies of the ventricular surface of the frog cerebellum showed regional differences. In the midline region of the adult cerebellum was found a band of profusely ciliated squamous ependymal cells. In the rest of the cerebellum the ependymal cells were columnar and each had a single cilium. In the cerebellum of the premetamorphic tadpole, the squamous ependymal cells of the midline region also were monociliated. During metamorphosis they gradually became multiciliated. Additionally, supraependymal cells and synaptic elements were present on the ventricular surface of the cerebellum of adult frogs as well as in late metamorphic tadpoles. In contrast, supraependymal cells were rarely observed in premetamorphic tadpoles, and it was concluded that the supraependymal system develops during metamorphosis. It is postulated that the band of cilia may be associated with the circulation of cerebrospinal fluid, and supraependymal synaptic elements function in neuroendocrine regulation.