Differential regulation of transcripts for dystrophin Isoforms, dystroglycan, and alpha3AChR subunit in mouse sympathetic ganglia following postganglionic nerve crush.

Previous data suggest that in mouse superior cervical ganglion (SCG) the dystrophin-dystroglycan complex may be involved in the axotomy-induced intraganglionic synapse remodeling. Here we analyzed the levels of mRNAs encoding dystrophins, dystroglycan (Dg), and the alpha3 subunit of the nicotinic acetylcholine receptor (alpha3AChR) in mouse SCG at various postaxotomy intervals. We found that axotomy downregulates the levels of transcripts for molecules related to synaptic transmission (alpha3AChR) and those presumably involved in postsynaptic apparatus organization (dystrophin isoforms) and upregulates the transcript encoding Dg, which, by binding dystrophin, bridges the actin cytoskeleton and several extracellular matrix proteins and may thus be involved in postaxotomy neuronal recovery. The observed transcriptional modulation of the components of dystrophin-dystroglycan complexes indicates their involvement in injury-induced neuronal plasticity and suggests a role in other forms of plasticity such as those required in learning and memory, functions often impaired in Duchenne muscular dystrophy patients.

Dystroglycan distribution in adult mouse brain: a light and electron microscopy study.

Dystroglycan, originally identified in muscle as a component of the dystrophin-associated glycoprotein complex, is a ubiquitously expressed cell-surface receptor that forms a transmembrane link between the extracellular matrix and the cytoskeleton. It contains two subunits, alpha and beta, formed by proteolytic cleavage of a common precursor. In the brain, different neuronal subtypes and glial cells may express dystroglycan in complex with distinct cytoplasmic proteins such as dystrophin, utrophin and their truncated forms. To examine the distribution of dystroglycan in adult mouse brain, we raised antibodies against the recombinant amino- and carboxyl-terminal domains of alpha-dystroglycan. On western blot, the antibodies recognized specifically alpha-dystroglycan in cerebellar extracts. Using light microscopy, alpha-dystroglycan was found in neurons of the cerebral cortex, hippocampus, olfactory bulb, basal ganglia, thalamus, hypothalamus, brainstem and cerebellum, where dystrophin and its truncated isoforms are also known to be present. Electron microscopy revealed that alpha-dystroglycan immunoreactivity was preferentially associated with the postsynaptic specializations. Dystroglycan immunostaining was also detected in perivascular astrocytes and in those facing the pia mater, where utrophin and dystrophin truncated isoforms are present. The cell body and endfeet of astrocytes around blood vessels and the endothelial cells at the blood-brain barrier also expressed dystroglycan. From these data, we suggest that dystroglycan, by bridging the extracellular matrix and the cytoskeleton, may play an important functional role at specialized intercellular contacts, synapses and the blood-brain barrier, whose structural and functional organization strictly depend on the integrity of the extracellular matrix-cytoskeleton linkage.

Presence and possible functional role of nerve growth factor in the thymus.

We have previously reported that the nerve growth factor (NGF), a polypeptide known for its neurotrophic activities, is also involved in proliferation, growth and survival of cells of the immune system. Working with animal models, we found that NGF and NGF-receptors (NGF-r) are present in the cells of the medullary layer of the thymus, a lymphoid gland involved in the production and differentiation of T-lymphocytes. Using immunohistochemical and biochemical approaches, we also showed that the expression of NGF in the thymus is high during late prenatal life and decreases later in postnatal life. A significant alteration of NGF levels was also found during pregnancy and aging, two events characterized by thymic involution. The aim of this study is to investigate whether NGF and NGF-r expression in the thymus are influenced by immuno- and neuro-pathological events. These observations will be presented and discussed.

Selective reduction in the nicotinic acetylcholine receptor and dystroglycan at the postsynaptic apparatus of mdx mouse superior cervical ganglion.

Our previous data suggested that in mouse sympathetic superior cervical ganglion (SCG) the dystrophin-dystroglycan complex may be involved in the stabilization of the nicotinic acetylcholine receptor (nAChR) clusters. Here we used SCG of dystrophic mdx mice, which express only the shorter isoforms of dystrophin (Dys), to investigate whether the lack of the full-length dystrophin (Dp427) could affect the localization of the dystroglycan and the alpha3 nAChR subunit (alpha3AChR) at the postsynaptic apparatus. We found a selective reduction in intraganglionic postsynaptic specializations immunopositive for alpha3AChR and for alpha- and beta-dystroglycan compared with the wild-type. Moreover, in mdx mice, unlike the wild-type, the disassembly of intraganglionic synapses induced by postganglionic nerve crush occurred at the slower rate and was not preceded by the loss of immunoreactivity for Dys isoforms, beta-dystroglycan, and alpha3AChR. These data indicate that the absence of Dp427 at the intraganglionic postsynaptic apparatus of mdx mouse SCG interferes with the presence of both dystroglycan and nAChR clusters at these sites and affects the rate of synapse disassembly induced by postganglionic nerve crush. Moreover, they suggest that the decrease in ganglionic nAChR may be one of the factors responsible for autonomic imbalance described in Duchenne muscular dystrophy patients.

Disassembly of the cholinergic postsynaptic apparatus induced by axotomy in mouse sympathetic neurons: the loss of dystrophin and beta-dystroglycan immunoreactivity precedes that of the acetylcholine receptor.

In mouse sympathetic superior cervical ganglion (SCG), cortical cytoskeletal proteins such as dystrophin (Dys) and beta1sigma2 spectrin colocalize with beta-dystroglycan (beta-DG), a transmembrane dystrophin-associated protein, and the acetylcholine receptor (AChR) at the postsynaptic specialization. The function of the dystrophin-dystroglycan complex in the organization of the neuronal cholinergic postsynaptic apparatus was studied following changes in the immunoreactivity of these proteins during the disassembly and subsequent reassembly of the postsynaptic specializations induced by axotomy of the ganglionic neurons. After axotomy, a decrease in the number of intraganglionic synapses was observed (t1/2 8 h 45'), preceded by a rapid decline of postsynaptic specializations immunopositive for beta-DG, Dys, and alpha3 AChR subunit (alpha3AChR) (t1/2 3 h 45', 4 h 30' and 6 h, respectively). In contrast, the percentage of postsynaptic densities immunopositive for beta1sigma2 spectrin remained unaltered. When the axotomized neurons began to regenerate their axons, the number of intraganglionic synapses increased, as did that of postsynaptic specializations immunopositive for beta-DG, Dys, and alpha3AChR. The latter number increased more slowly than that of Dys and beta-DG. These observations suggest that in SCG neurons, the dystrophin-dystroglycan complex might play a role in the assembly-disassembly of the postsynaptic apparatus, and is probably involved in the stabilization of AChR clusters.

Dystrophin and its isoforms in a sympathetic ganglion of normal and dystrophic mdx mice: immunolocalization by electron microscopy and biochemical characterization.

In normal mouse superior cervical ganglion, dystrophin immunoreactivity is present in ganglionic neurons, satellite cells and Schwann cells. It is associated with several cytoplasmic organelles and specialized plasma membrane domains, including two types of structurally and functionally different intercellular junctions: synapses, where it is located at postsynaptic densities, and adherens junctions. Dystrophin immunostaining can be ascribed to the 427,000 mol. wt full-length dystrophin, as well as to the several dystrophin isoforms present in superior cervical ganglion, as revealed by western immunoblots. In mdx mouse superior cervical ganglion, which lacks the 427,000 mol. wt dystrophin, the unchanged pattern of dystrophin immunolabelling observed at several subcellular structures indicates the presence of dystrophin isoforms at these sites. Moreover, the absence of labelled adherens junctions indicates the presence of full-length dystrophin at this type of junction in the normal mouse superior cervical ganglion. The lower number of immunopositive postsynaptic densities in mdx mouse superior cervical ganglion than in normal mouse ganglion suggests the presence, in the latter, of postsynaptic densities with differently organized dystrophin cytoskeleton: some containing dystrophin isoforms alone or together with 427,000 mol. wt dystrophin, and others containing 427,000 mol. wt dystrophin alone.

Nuclear lamina assembly in the first cell cycle of rat liver regeneration.

The nuclear lamina is a fibrous structure at the nucleoplasmic surface of the inner nuclear membrane. Its assembly state is regulated by phosphorylation of its protein components, the lamins A, B, and C. The isoprenylation of the lamins is essential for their proper membrane anchoring and functionality. The content and the membrane association of nuclear lamins and the subcellular localization at light and electron microscopical levels were studied at different times of rat liver regeneration. This model for the good synchrony of the first cell cycle is particularly suited for the study of cell-cycle-dependent modifications and is particularly interesting for the increased protein prenylation found in S phase. The biochemical results show an increased lamin content in nuclear proteins in G1 phase and a decreased content in M phase, along with an enhanced cytosolic localization of A and C lamins at later stages. The morphological results show in M phase, also in nondividing cells, a decreased lamin-like immunoreactivity around the nucleus with an apparent nuclear lamina disassembly. These data emphasize the dynamic organization of nuclear lamina not only in mitosis but also in interphase. The reduction and partial solubilization of nuclear lamina in M phase suggest a reorganization of the nuclear envelope also in those cells that do not appear in mitosis but have replicated their DNA content that will result in a higher degree of polyploidy.