[Mercury erythema after accidental exposure to mercury vapor]

Mercury exanthem can be considered as a systemic contact dermatitis following exposure to mercury vapor in patients with a prior sensitization to mercurials. It is characterized by a symmetrically distributed erythematous eruption appearing predominantly in the major flexural areas, in the neck, the lower portion of the abdomen and the upper anteromedial part of the thighs. In some cases, small pustules develop over the erythematous surfaces. We report our observations of two patients with mercury exanthem after exposure to mercury vapor caused by a broken thermometer. One of these patients presented with an unusual bullous form of mercury exanthem. Although diagnosis of mercury exanthem can be essentially based on clinical features, confirmation of the patient's exposure to mercury should be obtained. Cutaneous patch tests often prove the sensitization to mercurials.

Morphological and immunophenotypic microglial changes in the denervated fascia dentata of adult rats: correlation with blood-brain barrier damage and astroglial reactions

The reactions of microglial and astroglial cells to anterograde axonal degeneration were studied in the fascia dentata of adult rats from 1 to 42 days after removal of the entorhinal perforant path projection. The observations focused on the kinetics of glial activation in terms of induction of immunomolecules on the glial cells and the possible correlation between these changes and lesion-induced extravasation of plasma constituents. Normal and activated microglial cells were identified by immunohistochemical visualization of the constitutively expressed complement type 3 receptor (CR3/CD11b). Activated microglial cells were stained immunohistochemically for the inducible major histocompatibility complex (MHC) antigen class I and class II and the leukocyte common antigen LCA/CD45). Astroglial cells were identified by immunohistochemical staining for glial fibrillary acidic protein (GFAP). Blood-brain barrier (BBB) conditions were primarily evaluated by immunohistochemical staining for extravasated Immunoglobulin G (IgG), but also by intravenously injected horseradish peroxidase (HRP) and Evans Blue. Twenty-four hours after entorhinal cortex ablation, microglial cells in the perforant path terminal zones displayed an increase in CR3 immunoreactivity, changes of morphology and an induced expression of MHC antigen class I. At the same time there was a hitherto undescribed leakage of IgG through the BBB (albeit without detectable extravasation of HRP and Evans Blue). One day later microglial cells also expressed LCA, but MHC antigen class II was not induced under these degenerative conditions. The activation of microglial cells occurred prior to a noticeable hypertrophy of astroglial cells and increase in GFAP immunoreactivity, as this first became evident on Postlesional Day 2. From the results we conclude (1) that perforant path axonal degeneration induces an endothelial transcytosis of blood-borne IgG by mechanisms which cannot be envisioned by conventional HRP tracer methods and (2) that the early activation of both microglial cells and astroglial cells is likely to be initiated and later influenced by both axonal degeneration and extravasated plasma constituents. The demonstration of an early induction of immunomolecules on activated microglial cells and extravasation of blood borne molecules might moreover form the basis for a correspondingly early intervention aiming to regulate microglial immunomolecule, cytokine, and growth factor gene expression in the affected areas.

Effects of donor age and brain-derived neurotrophic factor on the survival of dopaminergic neurons and axonal growth in postnatal rat nigrostriatal cocultures

Early postnatal rat brain tissue can be grown for several weeks as organotypic slice cultures by the roller-tube method. We have here used this method to study the effects of donor age and brain-derived neurotrophic factor (BDNF) on the survival and growth of tyrosine hydroxylase immunoreactive (TH-i), dopaminergic (DA) neurons during the postnatal period when their nerve fibers normally innervate the striatal target. Tissue slices of ventral mesencephalon (VM) and striatum were prepared from newborn and 7-day-old rats and cocultured for 3--3 1/2 weeks with different combinations of the two donor ages. After immunocytochemical staining the number of TH-i, ventral mesencephalic neurons were counted, and the growth of TH-i fibers into the striatal part of the cocultures was evaluated. Co-cultures, with both VM and striatal slices prepared from newborn rats, contained a significantly higher number of TH-i neurons and displayed a significantly increased innervation of the striatal slices compared with other combinations of donor ages. Addition of BDNF resulted in both an increased survival of TH-i neurons and an increased growth of TH-i fibers into the cocultured striatal slices. Significant neurotrophic effect of BDNF did, however, require young donor age of both VM and striatal slices. It is suggested that BDNF induces more cells, possibly progenitor cells, to express TH immunoreactivity. Alternatively BDNF may suppress apoptotic cell death documented by others to occur in the postnatal rat substantia nigra pars compacta. Irrespective of the mechanisms, survival of more TH-i neurons was related to an increased innervation of the striatal slices by TH-i nerve fibers. The observed effects of BDNF on both survival and fiber growth of TH-i neurons indicate a potential role of BDNF for treatment of Parkinson's disease or grafts of immature DA neurons transplanted to patients with Parkinson's disease. A significant trophic effect of BDNF did, however, seem to depend on young developmental age of both striatum and VM. Parallel treatment with striatal neurotrophic factors may therefore be a necessary prerequisite to a trophic effect of BDNF under clinical conditions.

Reduction of the microglial cell number in rat primary glial cell cultures by exogenous addition of dibutyryl cyclic adenosine monophosphate

The present work examined the effects induced by dibutyryl cyclic adenosine monophosphate (dB-cAMP) on microglial cells in primary glial cell cultures from newborn rats. Microglial cells were identified by OX42 immunohistochemistry and nucleoside diphosphatase histochemistry. Double staining for astrocytes was carried out by combination with glial fibrillary acidic protein immunolabeling. Addition of 0.25 mM dB-cAMP to the cultures decreased the microglial cell number about sixfold. The findings suggest that the effect of dB-cAMP on the microglial cells might be either a direct action of dB-cAMP on the microglial cells or an indirect effect mediated by the astroglial cells.

Microglial reactions to retrograde degeneration of tracer-identified thalamic neurons after frontal sensorimotor cortex lesions in adult rats

Thalamic neuronal degeneration after neocortical lesions involve both anterograde and retrograde components. This study deals with the thalamic microglial response after neocortical aspiration lesions, using fluorogold fluorescent prelabeling, to identify retrogradely degenerating thalamocortical neurons, combined with histochemical or immunohistochemical staining of microglial cells. Adult male Wistar rats were injected with the retrograde fluorescent tracer fluorogold, in the right sensorimotor cortex (forepaw area) in order to retrogradely label thalamic neurons projecting to this area. After 1 week, the fluorogold injection site was removed by aspiration, axotomizing at the same time the thalamic projection neurons now retrogradely labeled with fluorogold. After 3, 7, 14, and 28 days the animals were killed and processed for nucleoside diphosphatase histochemistry or complement type 3 receptor immuno-histochemistry and class I and II major histocompatibility complex immunohistochemistry using OX42, OX18, and OX6 antibodies. The histological analysis showed a prominent and progressive nucleoside diphosphatase-, OX42-, and OX6-positive microglial cell response in the ventrolateral, posterior, and ventrobasal thalamic nuclei with ongoing retrograde and anterograde neuronal degeneration. Initially the reactive microglia had a bushy morphology and were succeeded by ameboid microglia and microglial cluster cells as the reaction progressed. However, in the reticular thalamic nucleus, which suffered exclusively anterograde neuronal degeneration, a different picture was seen with only bushy microglia. The neurons undergoing retrograde degeneration in the ventrolateral, posterior, and ventrobasal thalamic nuclei were retrogradely labeled by the fluorogold tracer. Individual nucleoside diphosphatase-, OX42-, or OX6-positive microglial cells extended long cytoplasmic processes surrounding fluorogold-labeled neurons and had in some cases apparently phagocytized these. Several microglial cells were thus double-labeled with nucleoside diphosphatase or OX42 and fluorogold. In addition, small nucleoside diphosphatase-positive, fluorogold-labeled perivascular cells were observed in the neocortex near the fluorogold-injected and ablated neocortical areas and in the ipsilateral thalamus. This study demonstrates: (1) that the microglial response to thalamic degeneration after neocortical lesion is graded with a limited reaction to the well-known massive anterograde axonal degeneration and a more extended reaction to the axotomy-induced retrograde cell death; and (2) that also perivascular cells and possibly macrophages may contribute to this reaction, as seen by uptake of fluorogold from axotomized neurons in the degenerating thalamic nuclei.

Presence of renin within intramitochondrial dense bodies of the rat adrenal cortex

It has been suggested that tissue-specific expression of the genes of the renin-angiotensin system (RAS) leads to local generation of angiotensin (ANG) II with specific physiological implications. We demonstrate here that an intracellular RAS exists in adrenal glomerulosa cells; 60 h after bilateral nephrectomy and hemodialysis, renin and prorenin were eliminated from the circulation, whereas intra-adrenal renin content increased (control rats: 2 +/- 0.5 ng ANG I.mg-1.h-1; anephric rats: 25 +/- 2). Thus renin is produced locally within adrenal cells. We obtained immunocytochemical and biochemical evidence for the presence of renin within intramitochondrial dense bodies of the zona glomerulosa. After nephrectomy, dense bodies increased in number, size, and renin content (control rats: 2.5 +/- 0.7 ngANGI.mg-1.h-1; anephric rats: 43 +/- 7). Angiotensin-converting enzyme (ACE) was also present within mitochondria and their dense bodies. In addition, in adrenal cortex of anephric rats, giant dense bodies were observed, which contain renin and strongly react with an anti-angiotensinogen antibody. The localization of renin, ACE, and angiotensinogen at these sites provides new evidence for the existence of an intracellular adrenal RAS.

Fetal neocortical tissue blocks implanted in brain infarcts of adult rats interconnect with the host brain

The purpose of the present study was to study if the connectivity of fetal neocortical tissue blocks placed in ischemic brain infarcts of adult rats would be enhanced in rats housed in an enriched environment. We also investigated whether the enriched housing conditions could enhance the postischemic and postgrafting functional outcome, in terms of motor behavior. This part of the study has been published recently. The middle cerebral artery was ligated on the right side in 37 inbred, adult male spontaneously hypertensive rats. The rats were placed at random either in an enriched environment (groups A and B) or in standard laboratory cages (group C). Three weeks after the artery occlusion, blocks of fetal sensorimotor cortex (embryonic day 17) were transplanted into the infarct cavity of rats from groups B and C. After 9 weeks all transplanted rats received an injection, into the graft, of a mixture containing the two tracers Fluoro-Gold and biotinylated Dextran amine. The transplants revealed a structured morphology with whorls and bands of cells reminiscent of normal neocortex. Tracing of efferent transplant to host fibers with biotinylated Dextran amine showed pronounced intrinsic transplant projections, as well as fibers, although significantly fewer, to the host ipsilateral sensorimotor cortex, striatum, and thalamus. Host to transplant projections were revealed by Fluoro-Gold-labeled cells found in the ipsilateral host sensorimotor cortex, the basal nucleus of Meynert, the thalamic ventrobasal, ventrolateral and posterior nuclei, and in the dorsal raphe nuclei. We conclude that fetal frontal neocortical block grafts placed in brain infarcts of adult rats develop a morphology reminiscent of normal neocortex and that both afferent and efferent neural connections, although sparse, are established with the host brain, whether the rats are reared under enriched housing conditions or not.

The effect of fetal neocortical transplants on lesion-induced cerebral cortex plasticity

Sensorimotor cortical lesions in newborn rats lead to the formation of abnormal projections from the opposite intact sensorimotor cortex. In the present study the influence of fetal neocortical transplants on this lesion-induced plasticity was examined. Newborn rats received unilateral frontal neocortical lesions. One experimental group received grafts of fetal neocortical tissue (E14-E16) into the lesion cavities. Another group served as lesion-only animals, while a third group was left unlesioned and without grafts as normal controls. At 3 mo of age, the animals received injections of the anterograde tracer biotinylated dextran amine (BDA) into the sensorimotor cortex contralateral to the lesion/transplantation area. After sacrifice 2 wk later, the brains were processed histochemically for detection of BDA-labeled cells and fibers. As a measure of the lesion-induced axonal sprouting response, corticothalamic and corticopontine fibers crossing the midline were counted. Significantly fewer cortical efferent fibers crossed the thalamic midline in the transplanted rats compared to the lesion-only controls. In contrast, the presence of transplants did not reduce the corticopontine sprouting response. These results therefore indicate that fetal neocortical grafts have a modulatory, yet variable effect on the lesion-induced axonal sprouting of contralateral sensorimotor cortical neurons.

The Effect of Fetal Neocortical Transplants on Lesion-Induced Cerebral Cortex Plasticity

Sensorimotor cortical lesions in newborn rats lead to the formation of abnormal projections from the opposite intact sensorimotor cortex. In the present study the influence of fetal neocortical transplants on this lesion-induced plasticity was examined. Newborn rats received unilateral frontal neocortical lesions. One experimental group received grafts of fetal neocortical tissue (E14–E16) into the lesion cavities. Another group served as lesion-only animals, while a third group was left unlesioned and without grafts as normal controls. At 3 mo of age, the animals received injections of the anterograde tracer biotinylated dextran amine (BDA) into the sensorimotor cortex contralateral to the lesion/transplantation area. After sacrifice 2 wk later, the brains were processed histochemically for detection of BDA-labeled cells and fibers. As a measure of the lesion-induced axonal sprouting response, corticothalamic and corticopontine fibers crossing the midline were counted. Significantly fewer cortical efferent fibers crossed the thalamic midline in the transplanted rats compared to the lesion-only controls. In contrast, the presence of transplants did not reduce the corticopontine sprouting response. These results therefore indicate that fetal neocortical grafts have a modulatory, yet variable effect on the lesion-induced axonal sprouting of contralateral sensorimotor cortical neurons.

Memory impaired aged rats: no loss of principal hippocampal and subicular neurons

A group of 52 male, 2-year-old Ico:WIST rats were tested on the spatial reference memory version of the Morris water maze. Their performance was rated by comparisons with the performance of 2.5-month-old control rats. Unbiased stereological estimates were made of the number of neurons in the major subdivisions of the hippocampus proper and the subiculum of the 5 aged rats with the most impaired performance, the 5 aged rats with the best performance, and 5 young control rats. There were no significant differences between the mean numbers of neurons in the various subdivisions of the hippocampal region of the impaired and nonimpaired aged groups and similarly no decreases in neuron numbers in the pooled group of aged rats relative to the control rats. The results indicate that, in rats, the structural correlates of age-related deficits in spatial memory are to be found in parameters other than the number of neurons in the hippocampus proper and the subiculum.

Connective integration of hippocampal grafts in excitotoxic hippocampal lesions in adult rats: an anterograde axonal tracing study

Exchange of nerve connections between developing neural grafts and adult recipient brains is enhanced for grafts placed in excitotoxic lesions, which spare recipient brain afferent axons in otherwise neuron-depleted lesion areas. In previous studies of hippocampal grafts placed in such lesions, we have used anterograde axonal degeneration, histochemical Timm staining and acetylcholinesterase to demonstrate host-graft interconnectivity. In this study, we have now used three anterograde axonal tracers, Phaseoulus vulgaris-leukoaglutinin (PHA-L), biocytin and biotinylated dextran amine (BDA), which allow individual fibers to be traced. Adult male rats with 1-week-old axon-sparing ibotenic acid lesions of the dorsal CA3 region or fascia dentata were grafted into the respective lesions with suspensions of fetal (El8-19) CA3 cells or a block of neonatal fascia dentata tissue. One to twelve months later, recipients were injected with Phaseoulus vulgaris-leukoaglutinin or biocytin in the hippocampus contralateral to the graft to trace the possible ingrowth and distribution within the transplants of host commissural axons, or into the transplants with biotinylated dextran amine in order to trace outgrowing graft fibers. In rats with succesfull host Phaseoulus vulgaris-leukoaglutinin or biocytin injections, the CA3 and fascia dentata transplants were innervated by labelled host commissural fibers. In the dentate transplants, most commissural fibers projected as normally to the inner part of the molecular layer, with fewer aberrant fibers extending more superficially into the molecular layer. Following injections into the fascia dentata and CA3 grafts of biotinylated dextran amine, labelled graft fibers were traced into the ipsilateral host dentate hilus, CA3 and CA1. From some CA3 containing grafts, a few labelled fibers were also observed passing through the host fimbria-fornix to the lateral septum on the grafted side. A few fibers were projected as far as to the most septal levels of the contralateral CA1.

c-JUN, KROX-24, and c-FOS expression in hippocampal grafts placed in excitotoxic hippocampal lesions of the rat

Hippocampal transplants were examined for the expression of three specific immediate early gene encoded proteins in order to establish if grafted immature tissue maintains the basic molecular program necessary for gene transcription after grafting to excitotoxic (ibotenic acid-induced) lesions in adult host rat brains. The transplants were derived from newborn donor rats and were analyzed immunocytochemically for the presence of c-JUN, KROX-24, and c-FOS transcription factors 5 months after grafting. The expression and distribution patterns of these genes in the host hippocampus were identical to those in hippocampal neurons of normal untreated animals. c-JUN-, KROX-24-, and c-FOS-labeled neurons were also present in the transplants, where KROX-24 and c-FOS exhibited a distribution similar to host hippocampus. In contrast, c-JUN was more extensively expressed in the transplants, suggesting a molecular response to the grafting conditions and the actual graft-host brain interactions.

Influence of an enriched environment and cortical grafting on functional outcome in brain infarcts of adult rats

The purpose of this work was to study if enriched housing conditions and fetal neocortical transplantation could enhance the functional outcome after focal brain ischemia in adult rats. The right middle cerebral artery (MCA) was ligated in 34 inbred, spontaneously hypertensive male rats, which were then randomly divided into three groups. Groups A and B were transferred to an enriched environment, i.e., a large cage with opportunities for various activities but not forcing the rats to do any particular tasks; group C was kept in standard laboratory cages. Three weeks after the MCA occlusion blocks of fetal neocortical tissue (Embryonic Day 17) were transplanted to the infarct cavity in groups B and C. Rats in group A (n = 11) and group B (n = 11) performed equally well and significantly better than rats in group C (n = 10) when placed on an inclined plane and when traversing a rotating pole 6 and 9 weeks after the MCA occlusion and in a leg placement test at 9, but not 6 and 12 weeks. Skilled forelimb function did not differ between the groups. Infarct size and thalamic atrophy did not differ between the groups and graft size was similar in group B and C. There was no correlation between infarct size and motor function in any of the tests in rats housed in an enriched environment. Since the environment can significantly alter functional outcome without reducing infarct size we suggest that more attention should be given to the role of the laboratory environment and to long term behavioral outcome in experimental stroke.

Prevention of mouse-rat brain xenograft rejection by a combination therapy of cyclosporin A, prednisolone and azathioprine

Embryonic mouse hippocampal tissue was grafted as tissue blocks to the hippocampal region of adult rats and the effect of two different immunosuppressive treatments compared. Immunosuppression with cyclosporin A, prednisolone and azathioprine or with cyclosporin A alone was compared with placebo treatment. Eight weeks' postgrafting medication with cyclosporin A, prednisolone and azathioprine had resulted in survival of 14 out of 15 grafts (93%), compared with 11 out of 14 (79%) in the group treated with cyclosporin A alone. Only 2 out of 13 grafts (15%) survived in placebo-treated animals. Transplants in the trimedication group displayed distinct cell and neuropil layers and only minimal cellular infiltration by leukocyte common antigen-expressing cells, whereas grafts in cyclosporin A- and placebo-treated groups were densely infiltrated. The results are discussed in relation to the need for extended immunosuppressive and antiinflammatory therapies after intracerebral grafting of histoincompatible tissues.

Organotypic slice cultures of the rat striatum: an immunocytochemical, histochemical and in situ hybridization study of somatostatin, neuropeptide Y, nicotinamide adenine dinucleotide phosphate-diaphorase, and enkephalin

In order to establish an in vitro model of Huntington's disease, we prepared slice cultures of striatal tissue from newborn rats. The striatal cultures were grown for 12-39 days in the absence of any other brain tissue. The presence of specific cell markers was shown by immunocytochemistry, histochemistry and in situ hybridization with alkaline-phosphatase-labeled oligonucleotide probes. We focused on (1) the medium-sized, aspiny interneurons, which in vivo express the neuropeptides somatostatin and neuropeptide Y and the nitric oxide synthesizing enzyme nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase, and which are spared in Huntington's disease and (2) the enkephalinergic, medium-sized projection neurons, which are particularly vulnerable in Huntington's disease. Similar basic morphologies of the presumed interneurons and double staining of NADPH-diaphorase positive and somatostatin immunoreactive neurons suggest that the two neuropeptides and NADPH-diaphorase are extensively colocalized in the cultures, as in vivo. In the newborn rats, included as controls, a patch-matrix distribution of the NADPH-diaphorase staining is described for the first time. In the striatal slices the distribution of the NADPH-diaphorase staining stayed uneven after 3-5 weeks in culture, with areas almost devoid of staining alternating with more heavily stained areas. This pattern may represent an intermediate stage between the patch-matrix distribution in the newborn and the homogeneous staining in the adult rat striatum. From quantitative estimates we found the same mutual rank order of the numbers of neuropeptide Y- and somatostatin-immunoreactive neurons and NADPH-diaphorase positive neurons in vivo and in vitro. Both in the slice cultures and in the brain, the number of enkephalin mRNA-containing neurons significantly exceeded that of neuropeptide Y- and somatostatin mRNA-containing neurons. This implies that the mutual distribution of presumed interneurons and projection neurons was preserved in the slice cultures. Comparison of cell numbers per unit volume showed that, in the cultures, the number of presumed interneurons, with the exception of NPY mRNA-containing neurons, significantly exceeded that in vivo. In contrast, the enkephalin mRNA-containing neurons, which in vivo are projection neurons, were significantly fewer in the cultures. The relative loss of projection neurons and preservation of interneurons in single slice cultures of striatal tissue apparently mimick some of the neurodegenerative changes of Huntington's disease.(ABSTRACT TRUNCATED AT 400 WORDS)

Cytokines in cerebral ischemia: expression of transforming growth factor beta-1 (TGF-beta 1) mRNA in the postischemic adult rat hippocampus

Transient global cerebral ischemia induces selective neuronal degeneration in the adult rat hippocampus, which is both preceded and accompanied by activation of microglia and astrocytes. Altered expression patterns of cytokines and growth factors might influence the postischemic neuron-glial interactions as well as the degenerative neuronal processes. Northern blotting of hippocampal tissue from ischemic animals revealed elevated levels of transforming growth factor beta-1 (TGF-beta 1) mRNA, and in the present in situ hybridization study we examine the endogenous expression and cellular localization of TGF-beta 1 mRNA in the adult rat hippocampus at various intervals following 10 min of global cerebral ischemia. Six hours after ischemia, a diffuse expression of TGF-beta 1 mRNA was found throughout the brain, which further intensified until Day 2 and thereafter subsided. In parallel, a massive increase of signal was observed in the hilus fascia dentata from Day 1 and in area CA1 from Day 2 to 4, both areas displaying selective neuronal degeneration. Peak levels of TGF-beta 1 mRNA were found in the hilus around Day 4, whereas expression in the CA1 area persisted through Day 21, the latest time point examined. A similar biphasic response, consisting of a transient, generalized reaction and a persistent lesion-associated activation in areas undergoing selective neuronal degeneration, was previously described for microglia and is reconfirmed in the present study. Cells of the microglial/macrophage lineage thus include the potent modulatory cytokine TGF-beta 1 in their potential repertoire of responses to both CNS activation and lesioning.

Fetal neocortical transplants grafted into neocortical lesion cavities made in newborn rats: an analysis of transplant integration with the host brain

Fetal neocortical transplants placed into frontal cortex aspiration lesion cavities in newborn rats have been shown to survive and exchange connections with the host brain. To further study the afferent innervation of such transplants, enzyme- and immunohistochemical techniques were employed to examine the distribution of cholinergic, catecholaminergic and serotonergic fibers within the transplants, and radiochemical enzyme assays and high performance liquid chromatography were used to determine the content of neurotransmitter markers for these same fiber systems. To examine functional integration of the transplanted neurons in terms of activation of molecular signaling systems, the graft recipient animals were exposed to a novel open field environment. This behavioral testing paradigm is known to induce c-fos mRNA and Fos protein within several areas of the normal brain, including the sensorimotor cortex. Subsequent detection of the induction of this particular immediate early gene (transcription as well as translation) in the grafts would gene (transcription as well as translation) in the grafts would accordingly indicate genomic activation and therefore functional integration at the level of molecular signaling systems. Our results showed that these global fiber systems are distributed evenly throughout the extent of three mo old neocortical grafts and that the content of transmitter-related markers for these systems do not differ significantly from control cortex. Open field exposure of the grafted animals resulted in c-fos mRNA and Fos protein expression of cells distributed throughout the transplants. We conclude that the "global" fiber system innervation of neocortical transplants placed into newborn rats is similar to the innervation of normal cortex and that grafted neurons respond to host brain activation at the level of molecular signaling systems.

Autosomal sex reversal and campomelic dysplasia are caused by mutations in and around the SRY-related gene SOX9

A human autosomal XY sex reversal locus, SRA1, associated with the skeletal malformation syndrome campomelic dysplasia (CMPD1), has been placed at distal 17q. The SOX9 gene, a positional candidate from the chromosomal location and expression pattern reported for mouse Sox9, was isolated and characterized. SOX9 encodes a putative transcription factor structurally related to the testis-determining factor SRY and is expressed in many adult tissues, and in fetal testis and skeletal tissue. Inactivating mutations on one SOX9 allele identified in nontranslocation CMPD1-SRA1 cases point to haploinsufficiency for SOX9 as the cause for both campomelic dysplasia and autosomal XY sex reversal. The 17q breakpoints in three CMPD1 translocation cases map 50 kb or more from SOX9.

Kindling induces transient changes in neuronal expression of somatostatin, neuropeptide Y, and calbindin in adult rat hippocampus and fascia dentata

Fully hippocampus-kindled rats were examined 1 day and 1 month after the last stimulation for changes in somatostatin (SS)-, neuropeptide Y (NPY)-, and calbindin (CaBP)-immunoreactivity (ir) and SS- and NPY-mRNA in situ hybridization (ISH). One day after the last stimulation, there was marked, bilateral increase in SS- and NPY-ir in the outer part of the dentate molecular layer. The cell bodies of dentate hilar SS- and NPY-containing neurons, known to project to this area, also appeared to display increased immunoreactivity as well as an increased ISH signal for SS and NPY mRNA. Bilateral de novo expression of NPY-ir in dentate mossy fiber projection to dentate hilus and CA3 was also evident, but we noted no corresponding NPY-mRNA signal in the parent cell bodies, the dentate granule cells. After 1 month, the levels of NPY-ir and ISH signal appeared essentially normal. In contrast, the levels of SS apparently were decreased, although not yet normal. CaBP-ir was markedly and selectively reduced in dentate granule cell bodies, dendrites, and mossy fibers 1 day after the last stimulation, but after 1 month CaBP-ir appeared essentially normal. Because kindling, once established, is a permanent phenomenon, the observed transient changes in SS, NPY, and CaBP in specific hippocampal terminal fields and neuronal populations cannot be associated specifically with kindling. Rather, they relate to the repeated high-frequency stimulations and may serve as protective measures against deleterious effects of such stimulations.

Grafting of dopaminergic ventral mesencephalic slice cultures to the striatum of adult rats

Live storage of dopaminergic neurons before intracerebral grafting will allow pregrafting examination and manipulation of the cells, as well as pooling and mixing of cells from several donors. In this study we examined whether mesencephalic dopaminergic neurons, grown in organotypic cultures for 1 week, would survive subsequent grafting to the adult rat striatum. Slices of ventral mesencephalon from neonatal rats were grown by the Roller drum method for 1 week and then grafted into the striatum of adult rats, with and without preceding 6-hydroxydopamine lesions of their nigrostriatal pathway. Using immunocytochemical staining for tyrosine hydroxylase, cultured dopaminergic neurons were found to survive and to extend fibers into the host striatum when examined 4, 7, 14, 28, and 87 days after grafting. When compared with slices of noncultured mesencephalic tissue from 1-week-old rats the slice culture period did not significantly reduce the number of surviving tyrosine hydroxylase positive neurons. From this we conclude that slice cultures can be used for transient storage of dopaminergic donor tissue before intracerebral grafting. The surviving tyrosine hydroxylase positive neurons in control grafts from 1-week-old rats, furthermore, extends the time frame of possible donor ages used for grafting.