Long-term effects of ciliary neurotrophic factor on the survival of vasopressin magnocellular neurones in the rat supraoptic nucleus in vitro.

The use of hypothalamic organotypic cultures for the long-term study of mechanisms in magnocellular neurones (MCNs) of the hypothalamic-neurohypophysial system has been limited by the relatively poor maintenance of the vasopressin MCNs in vitro. Recent studies have shown that addition of ciliary neurotrophic factor (CNTF) to the media significantly reduced the apoptosis of both oxytocin and vasopressin MCNs. Here, we studied various temporal factors in the CNTF treatment that can influence the efficacy of MCN survival. Immunohistochemistry was used to identify and count surviving vasopressin and oxytocin MCNs in the supraoptic nucleus (SON) in hypothalamic slices cultured in the presence of CNTF (10 ng/ml media) for various time intervals, and in situ hybridization for vasopressin mRNA was used to evaluate the vasopressin mRNA gene expression in the SON under the same conditions. The presence of CNTF in the medium for 10 days produced a maximal increase in the survival of vasopressin MCNs (by 11-fold) and in the survival of oxytocin-MCNs (by approximately four-fold) over controls. These effects persisted for an additional 7-10 days even in the absence of CNTF. The ability of CNTF to increase survival of the MCNs or increase vasopressin mRNA levels in the SON required that the CNTF be present during the initial 7-10 days of culture. CNTF failed to rescue vasopressin or oxytocin MCNs when added to the media only for the last 7 days of a total of 14 days in vitro. Similar results were observed when SON vasopressin mRNA levels were measured. These results indicate that the presence of CNTF is required at the outset to rescue the vasopressin and oxytocin MCN from axotomy induced apoptosis, and that, after 10 days in CNTF, the MCNs no longer require the CNTF for survival.

The magnocellular neuronal phenotype: cell-specific gene expression in the hypothalamo-neurohypophysial system.

The magnocellular oxytocin (OT) and vasopressin (VP) neurons of the hypothalamo-neurohypophysial system are exceptional cell biological models to study mechanisms of cell-specific gene expression and neurosecretion of neuropeptides in the central nervous system. Single cell differential gene expression experiments have further defined these phenotypes by identifying novel and distinct regulatory molecules in these neurons. Transgenic mouse studies have led to the intergenic region (IGR) hypothesis, which states that the DNA sequences between the OT- and VP-genes contain critical enhancer sites for their cell-specific expression. The recent cloning and sequencing of the human IGR, and its comparison with the mouse IGR sequence has identified conserved sequences as putative, cell-specific enhancer sites which are now being evaluated by biolistic transfections of organotypic hypothalamic cultures. With these data, it is possible to target the gene expression of specific molecules to magnocellular neurons both in vivo and in vitro, in order to perturb and/or visualize neurosecretory and other processes.

Direct stimulation of arginine vasopressin gene transcription by cAMP in parvocellular neurons of the paraventricular nucleus in organotypic cultures.

The regulation of arginine vasopressin (AVP) gene transcription in the paraventricular nucleus (PVN) was studied in rat hypothalamic organotypic cultures using intronic in situ hybridization. While AVP heteronuclear (hn) RNA was not detected in the PVN under basal conditions, a marked induction of AVP hnRNA was observed after 2 and 3 h incubation of slices with forskolin. In contrast to the stimulatory effects of forskolin, phorbol 12-myristate 13-acetate (PMA) was completely ineffective in inducing AVP hnRNA in the PVN at any time examined (1-3 h). Forskolin-induced AVP hnRNA expression was unaffected by blockage of neurotransmission by the sodium channel inhibitor, tetrodotoxin, indicating that forskolin acts directly on AVP cells in the PVN. Dual staining in situ hybridization of forskolin-stimulated hypothalamic sections using both radio labeled AVP hnRNA and digoxigenin-labeled CRH mRNA probes revealed colocalization of both transcripts, indicating AVP hnRNA is expressed in the parvocellular neurons. The data demonstrate that cAMP directly activates AVP gene transcription in parvocellular neurons of the PVN.

Vasopressin gene expression: experimental models and strategies.

The intergenic region (IGR) separating the genes for vasopressin (VP) and oxytocin (OT) has been shown to be critical for the cell-specific expression of these peptide genes in hypothalamic neurons. To date, the most relevant information about the putative cis-elements in the IGR that might determine cell-specific gene expression has come from studies in transgenic models. As a first step toward increasing the efficiency of the IGR sequence deletion studies in transgenic animals, a comparative genomics approach comparing the IGR sequence in humans versus mice was used to identify conserved sequences that might be candidate regulatory elements. The nucleotide sequence of the IGR between the human VP and OT genes was determined and compared to the mouse IGR, and 26 conserved sequences in three distinct clusters were found. These conserved sequences and motifs may be important for the cell-specific expression of the VP and OT genes. However, before further significant progress can be made, a "high-throughput" method for the analysis of deletion constructs in relevant cell types in vitro is needed. It is proposed here that organotypic culture models combined with the use of particle-mediated gene transfer methods may provide an effective, general strategy for the study of cell-specific expression in the central nervous system.

Effects of osmotic pressure and brain-derived neurotrophic factor on the survival of postnatal hypothalamic oxytocinergic and vasopressinergic neurons in dissociated cell culture.

Neurons from hypothalamic paraventricular nuclei (PVN) and supraoptic nuclei (SON) from postnatal day 6-8 rats were enzymatically dissociated and separately maintained in monolayer cultures for 14 days. The osmotic pressure of the culture medium, based on Neurobasal medium (Life Technologies), was varied (255, 300 and 330 mOsm/l) by adjustment using mannitol. The survival of oxytocin (OT), vasopressin (VP) and oxytocin-vasopressin (OT/VP) coexpressing neurons were studied under these varied conditions, and the identification of the cell phenotypes in the cultures was carried out by using double-label immunofluorescence. Under control osmolar conditions (300 mOsm/l) equivalent numbers of OT and VP neurons were found in the SON (P = 0.8398) and PVN (P = 0.4721) cultures. The OT neurons' survival did not change in 255 or 330 mOsm media in the SON cultures, but the VP neurons in the SON cultures were significantly increased in 255 mOsm/l medium as compared to control (300 mOsm/l) medium (P = 0.0088). No significant changes were found in VP neuron survival in SON cultures between the 300-330 mOsm/l media (P = 0.2372). Similar data were obtained for the VP neurons in PVN-derived cultures, but the OT neurons in these cultures survived significantly better at 300 mOs/l than at 255 mOsm/l (P<0.0001), but were not significantly different at 330 mOsm/l (P = 0.1208). In general, the VP neurons were more vulnerable than OT neurons to increases of culture medium osmolarity with respect to their survival. The number of OT/VP coexpressing neurons was greater in SON-derived cell cultures as compared to PVN-derived cell cultures, and their numbers were higher in the lower osmolarity media. The effects of adding brain-derived neurotrophic factor (BDNF) to the culture medium on survival were determined. BDNF significantly increased the numbers of all three types of neurons in both PVN and SON cell cultures (P = 0.0001-0.0060). The phenotypically identified cells, cultured in the 300 mOsm/l medium, responded by depolarization or hyperpolarization when transferred to hypertonic or hypotonic perfusion salines, respectively.

Gene transfer into hypothalamic organotypic cultures using an adeno-associated virus vector.

Organotypic cultures of rat hypothalamic slice cultures were successfully transduced using adeno-associated viral vectors. Using nuclear-targeted Lac-Z as the reporter gene, transduction was found to be very effective, occurring in as high as 89% of a specific cell type, the oxytocin neurons, present in the cultured explants. These transduction levels were not accompanied by any deleterious effects in the cultured cells 7 days after transduction. Such an in vitro approach should be valuable for the study of cell-specific gene expression in neurons in the central nervous system for which there are no homologous (surrogate) cell lines.

Stationary organotypic cultures of oxytocin and vasopressin magnocellular neurones from rat and mouse hypothalamus.

Rat and mouse hypothalami from postnatal animals containing highly differentiated neurones survive very well in long-term (>15 days in vitro, DIV) stationary organotypic cultures. Magnocellular oxytocin (OT) and vasopressin (VP) neurones are present in identifiable paraventricular (PVN), supraoptic (SON) and accessory (ACC) nuclei in these cultures. After 15 DIV in standard medium immunocytochemistry revealed 427 +/- 63 OT cells and 217 +/- 27 VP cells per cultured rat hypothalamus, and 380 +/- 72 OT cells and 622 +/- 91 VP cells per cultured mouse hypothalamus. Following a 7-day adaptation period in standard culture medium containing serum, the rat slice-explants survived very well after subsequent transfer to defined, serum- free media (SFM) for an additional 8 days. The number of OT cells surviving in SFM was 612 +/- 147 OT cells per cultured rat hypothalamus. Only 0.5% of the magnocellular OT and VP neurones in the cultures appeared to express both peptides. Experiments on c-fos gene expression in these cultures showed that while only 12% of the magnocellular OT and VP neurones contained barely detectable Fos protein in their nuclei under control conditions, potassium depolarization of these cultures for 3 h produced intense c-fos expression in 87-91% of these cells. Thus, magnocellular neurones in these cultures are sufficiently stable and responsive to permit long-term physiological and gene expression studies to be done under defined media conditions.

Developmental regulation of two distinct neuronal phenotypes in rat dorsal root ganglia.

In a previous study we described two distinct neuronal phenotypes in rat dorsal root ganglia based on immunocytochemical assays for the neuronal intermediate filament proteins, peripherin and low-molecular-weight neurofilaments [Goldstein M. E. et al. (1991) J. Neurosci. Res. 30, 92-104]. In this paper we have extended this classification by using in situ hybridization to localize and evaluate the levels of various cytoskeletal and neuropeptide messenger RNAs within the peripherin-immunoreactive and peripherin-immunoreactive-negative neurons found in embryonic day 15 and 20, postnatal day 2 and adult dorsal root ganglia. We found in postnatal and adult dorsal root ganglia in vivo that the large, peripherin-immunoreactive-negative neurons, which are intensely stained by low-molecular-weight neurofilament antibodies, also contain high levels of low, medium and high-molecular-weight neurofilament messenger RNAs, whereas the smaller peripherin-immunoreactive neurons do not. On the other hand, both cell types contained comparable levels of peripherin and alpha-tubulin messenger RNA. The presence of peripherin messenger RNA but no peripherin immunoreactivity in the large cells suggested either a translational or post-translational regulation of this polypeptide, or rapid clearance of this protein from the perikaryon into the axon. In adult dorsal root ganglia, more than 50% of the peripherin-immunoreactive neurons also contained high levels of substance P and/or calcitonin gene-related peptide messenger RNAs, while less than 20% of the large peripherin-immunoreactive-negative neurons did. The attainment of these phenotypic characteristics during development in vivo was studied by northern blot and in situ hybridization histochemistry. In early embryonic stages (embryonic days 15-16), virtually all neurons were peripherin-immunoreactive and were positive for peripherin, alpha-tubulin and low-molecular-weight neuro-filament messenger RNAs, suggesting a homogeneous population. By embryonic day 20, the two adult phenotypes became clearly evident, and were fully established by postnatal day 2. In cultures of embryonic day 15 dorsal root ganglion neurons grown in the presence of nerve growth factor, peripherin and low-molecular-weight neurofilament messenger RNAs were expressed in all neurons, even after nine days in vitro, similar to embryonic dorsal root ganglia in vivo. Nerve growth factor supplemented by skeletal and heart muscle extracts did up-regulate neurofilament gene expression, but not to the extent characteristic of the peripherin-immunoreactive-negative adult phenotype. These results suggest that development of the mature phenotype of dorsal root ganglion neurons occurs by postnatal day 2 in vivo and is dependent upon target contact and/or target-derived factors.

NF-L and peripherin immunoreactivities define distinct classes of rat sensory ganglion cells.

Double immunofluorescence studies using antibodies against NF-L and peripherin revealed three distinct subpopulations of neurons in rat dorsal root ganglia (DRG). In the adult rat, 46% of the DRG neurons were small and peripherin-positive (NF-L-negative), and 48% were large and NF-L-positive (peripherin-negative). About 6% were both peripherin- and NF-L-positive. All of the DRG neurons reacted with antibodies to NF-M and nonphosphorylation-dependent or phosphorylation-independent antibodies to NF-H. The neuropeptides were predominantly found in the peripherin-positive small cell population. Eighty-seven percent of the peripherin-positive small cell population contained substance P immunoreactivity, while 43% of this cell population contained CGRP. In contrast, only 18-24% of the NF-L-positive large-cell population contained neuropeptides, and these were primarily in a smaller sized subpopulation. Similar patterns of antigen representation were observed in neonatal (PN2) DRG cell populations. Tissue cultures of sensory ganglion cells from PN2 DRG, in serum-free medium, stably maintained exclusively peripherin-positive neurons, with about 5% of these containing coexistent NF-L immunoreactivity. Very high levels of neuropeptide gene expression were exhibited by these postnatal neurons in culture.

The autologous mixed lymphocyte reaction in strains of mice with autoimmune disease.

We have studied the autologous mixed lymphocyte reaction (AMLR) in 3 strains of mice with autoimmune disease. T cell proliferation to autologous non-T cells occurs in young mice of these 3 strains (as it does in normal mice) but is absent or greatly reduced in older mice of strains with autoimmune disease. Reciprocal mixing experiments revealed that the defect in the AMLR of the older mice resides in the responder T cell population. Further analysis of the cells participating in the AMLR of young mice of the B/W F1 strain revealed that: 1) a Thy 1- and Ly1-positive responder cell was necessary at the start of the culture to initiate the AMLR; 2) the cells present after 5 days of culture contained very few, if any, Ly123 cells in the B/W F1 strain compared with the normal C57BL/6 strain; and 3) the stimulating cell appear to be a macrophage, and an Ia-bearing cell must be present for the reaction to occur.