Regulation of molecular components of the synapse in the developing and adult rat superior cervical ganglion

Localization of brain-derived neurotrophic factor and TrkB receptors to postsynaptic densities of adult rat cerebral cortex

Although neurotrophins are critical for neuronal survival and differentiation, recent studies suggest that they also regulate synaptic plasticity. Brain-derived neurotrophic factor (BDNF) rapidly increases synaptic transmission in hippocampal neurons, and enhances long-term potentiation (LTP), a cellular and molecular model of learning and memory. Loci and precise mechanisms of BDNF action remain to be defined: evidence supports both pre- and postsynaptic sites of action. To help elucidate the synaptic mechanisms of BDNF action, we used antisera directed against the extracellular and intracellular domains of trkB receptors, anti-trkBout and anti-trkBin, respectively, to localize the receptors in relation to synapses. Synaptic localization of BDNF was examined in parallel using anti-BDNF antisera. By light microscopy, trkBin and trkBout immunoreactivities were localized to hippocampal neurons and all layers of the overlying visual cortex. Immunoelectron microscopic analysis of the cerebral cortex revealed that trkB and BDNF localize discretely to postsynaptic densities (PSD) of axo-spinous asymmetric synaptic junctions, that are the morphological correlates of excitatory, glutamatergic synapses. TrkB immunoreactivity was also detected in the nucleoplasm by light and electron microscopy. Western blot analysis indicated that both anti-trkBout and anti-trkBin antisera react with a protein band in the PSD corresponding to the molecular weight expected for trkB; however, molecular species distinct from that for trkB were recognized in the nuclear fraction by both anti-trkBin and anti-trkBout antisera, indicating that the nuclear immunoreactivity, seen by immunocytochemistry, reflects cross-reactivity with proteins closely related to, but distinct from, trkB. The PSD localization of both BDNF and trkB supports the contention that this receptor/ligand pair participates in postsynaptic plasticity.

Immunocytochemical changes of cytoskeleton components and calmodulin in the frog cerebellum and optic tectum during hibernation

During hibernation, variation in the metabolism of nerve cells occurs. Since the cytoskeleton plays an important role in nerve cell function, we have analyzed the immunocytochemical expression of two cytoskeleton components, i.e. phosphorylated 200 kDa neurofilament protein, and microtubule-associated protein 2 in the cerebellum and optic tectum of hibernating frogs (Rana esculenta) in comparison with active animals. In addition, we have considered the immunocytochemical expression of calmodulin, which is known to be involved in neurofilament phosphorylation. In hibernating animals, there was a decrease in the immunoreactivity for phosphorylated 200 kDa neurofilament protein and microtubule-associated protein 2 of fibers in both the cerebellum and in the optic tectum. In contrast, in the large neurons of the cerebellum, i.e. Purkinje neurons, there was an increase in the immunoreactivity for microtubule-associated protein 2. The changes in the cytoskeleton components were accompanied by a decrease in calmodulin immunoreactivity in the cytoplasm of nerve cells of the cerebellum. All the changes observed are consistent with a low neuronal activity during hibernation, as also indicated by previous microdensitometric and microfluorometric data. This shows a higher degree of chromatin condensation in hibernating animals and suggests that hibernation represents a simple form of neuronal plasticity.

Effects of axotomy, deafferentation, and reinnervation on sympathetic ganglionic synapses: a comparative study

The main physiological and morphological features of the synapses in the superior cervical ganglia of mammals and the last two abdominal ganglia of the frog sympathetic chain are summarized. The effects of axotomy on structure and function of ganglionic synapses are then reviewed, as well as various changes in neuronal metabolism in mammals and in the frog, in which the parallel between electrophysiological and morphological data leads to the conclusion that a certain amount of synaptic transmission occurs at "simple contacts." The effects of deafferentation on synaptic transmission and ultrastructure in the mammalian ganglia are reviewed: most synapses disappear, but a number of postsynaptic thickenings remain unchanged. Moreover, intrinsic synapses persist after total deafferentation and their number is strongly increased if axotomy is added to deafferentation. In the frog ganglia, the physiological and morphological evolution of synaptic areas is comparable to that of mammals, but no intrinsic synapses are observed. The reinnervation of deafferented sympathetic ganglia by foreign nerves, motor or sensory, is reported in mammals, with different degrees of efficiency. In the frog, the reinnervation of sympathetic ganglia with somatic motor nerve fibers is obtained in only 20% of the operated animals. The possible reasons for the high specificity of ganglionic connections in the frog are discussed.

Detection of dystrophin in the postsynaptic density of rat brain and deficiency in a mouse model of Duchenne muscular dystrophy

Duchenne muscular dystrophy (DMD) is a common, lethal, chromosome X-linked inherited disease. Moderate cognitive impairment is a feature of DMD, but the underlying mechanisms are unknown. DMD is characterized by a defect in a protein, dystrophin, that is located predominantly in muscle but has been detected in brain. We sought to directly localize dystrophin within the complex synaptic structure of the cerebral cortex by focusing on the postsynaptic density (PSD), which appears to be central to synaptic function. We report that a specific anti-dystrophin antibody (anti 6-10) recognizes three distinct proteins in the purified PSD: the 400-kDa dystrophin and two previously unidentified dystrophin-related proteins of 120 and 110 kDa. These proteins exhibited differential regional expression in PSDs from cerebral cortex, cerebellum, and olfactory bulb. In the cortical PSD, the 400-kDa dystrophin was predominant, whereas the 120-kDa protein was the major species in cerebellum and olfactory bulb PSDs. The three proteins were differentially expressed in the PSD during cortical development: the 400-kDa protein exhibited a selective 9-fold increase during postnatal days 7 to 10, suggesting a normal physiological role in synaptic maturation. The PSD from the mdx mouse, a model of human DMD, contained no detectable 400-kDa dystrophin but expressed the two dystrophin-related proteins. Our results indicate that brain dystrophins are localized to the PSD, potentially as three isoforms, and raise the possibility that cognitive abnormalities in DMD are attributable to synaptic dysfunction associated with deficits in brain dystrophin molecules.

On the identity of the major postsynaptic density protein

Increasing evidence suggests that the postsynaptic density (PSD) plays a critical role in synaptic communication and plasticity. The major PSD protein (mPSDp), a calcium/calmodulin-dependent protein kinase, appears to be central to PSD function. The mPSDp has long been considered identical to the alpha subunit of the soluble calmodulin kinase II (alpha-CKII). However, mPSDp and alpha-CKII do differ in solubility and antigenicity, raising the possibility that the two proteins are distinct. To further define the relationship between the two proteins, we purified the mPSDp to homogeneity from adult rat cerebral cortex and compared the proteins. In contrast to alpha-CKII, the purified mPSDp was insoluble in high concentrations of salt, various detergents, chelators of divalent cations, and the strong denaturant guanidine hydrochloride. The pI value of the mPSDp was 6.2, whereas that of alpha-CKII was 6.7-7.2. The purified mPSDp bound calmodulin in the presence of Ca2+ and was autophosphorylated in a Ca2+/calmodulin-dependent manner. Polyclonal antiserum raised against mPSDp (anti-mPSDp) recognized purified mPSDp or mPSDp in synaptic membrane, indicating immunologic specificity among the synaptic proteins. Anti-mPSDp did not recognize alpha-CKII, whereas anti-alpha-CKII antibodies reacted only weakly with mPSDp, suggesting that the proteins are distinct but structurally similar. Moreover, sequence analysis of protease V8-digested polypeptides revealed that there was at least an 8-amino acid sequence, MLKVPNIS, that is not present in alpha-CKII. Finally, HPLC analysis of V8-digested fragments of mPSDp and alpha-CKII in parallel revealed dissimilar peptide patterns. Thus our observations suggest that mPSDp and alpha-CKII are similar but not identical. The unique physicochemical and structural properties of the mPSDp may provide insights into molecular mechanisms mediating synaptic plasticity.

Expression of calmodulin-dependent enzymes in developing rat striatum is not affected by perturbation of dopaminergic systems

Transsynaptic regulation is one mechanism that controls expression of several calmodulin (CaM)-dependent enzymes. This observation and the demonstration that expression of several CaM-dependent enzymes in developing striatum occurred with a spatial and temporal pattern similar to that seen for dopamine and tyrosine hydroxylase suggested that the nigrostriatal pathway may influence the expression of CaM-binding proteins (CaM-BPs) during striatal development. Therefore, the possible role of nigrostriatal dopamine systems regulating the expression of CaM-dependent enzymes was studied in Sprague-Dawley rats by using surgical hemitransections of brain, 6-hydroxydopamine lesions, and chronic haloperidol treatments. Alterations in CaM-BP expression following perturbation of the developing nigrostriatal tract were analyzed by using immunoblots, biotinylated CaM overlays, and enzyme assays. The extent of nigrostriatal lesions was assessed by using depletion of immunoreactive tyrosine hydroxylase levels in striatum. All three experimental paradigms failed to alter the normal developmental expression of CaM-dependent enzymes. From these results we conclude that the increased expression of CaM-dependent enzymes during striatal development is not directly dependent on synaptic input from the nigrostriatal dopamine system.

Expression of calmodulin-dependent phosphodiesterase, calmodulin-dependent protein phosphatase, and other calmodulin-binding proteins in human SMS-KCNR neuroblastoma cells

Calmodulin (CaM)-dependent enzymes, such as CaM-dependent phosphodiesterase (CaM-PDE), CaM-dependent protein phosphatase (CN), and CaM-dependent protein kinase II (CaM kinase II), are found in high concentrations in differentiated mammalian neurons. In order to determine whether neuroblastoma cells express these CaM-dependent enzymes as a consequence of cellular differentiation, a series of experiments was performed on human SMS-KCNR neuroblastoma cells; these cells morphologically differentiate in response to retinoic acid and phorbol esters [12-O-tetradecanoylphorbol 13-acetate (TPA)]. Using biotinylated CaM overlay procedures, immunoblotting, and protein phosphorylation assays, we found that SMS-KCNR cells expressed CN and CaM-PDE, but did not appear to have other neuronal CaM-binding proteins. Exposure to retinoic acid, TPA, or conditioned media from human HTB-14 glioma cells did not markedly alter the expression of CaM-binding proteins; 21-day treatment with retinoic acid, however, did induce expression of novel CaM-binding proteins of 74 and 76 kilodaltons. Using affinity-purified polyclonal antibodies, CaM-PDE immunoreactivity was detected as a 75-kilodalton peptide in undifferentiated cells, but as a 61-kilodalton peptide in differentiated cells. CaM kinase II activity and subunit autophosphorylation was not evident in either undifferentiated or neurite-bearing cells; however, CaM-dependent phosphatase activity was seen. Immunoblot analysis with affinity-purified antibodies against CN indicated that this enzyme was present in SMS-KCNR cells regardless of their state of differentiation. Although SMS-KCNR cells did not show a complete pattern of neuronal CaM-binding proteins, particularly because CaM kinase II activity was lacking, they may be useful models for examination of CaM-PDE and CN expression. It is possible that CaM-dependent enzymes can be used as sensitive markers for terminal neuronal differentiation.

Transsynaptic impulse activity regulates postsynaptic density molecules in developing and adult rat superior cervical ganglion

Ganglionic postsynaptic density protein (PSDp) was used to monitor the influence of transsynaptic impulse activity on synaptic structure in the developing and adult rat superior cervical sympathetic ganglion (SCG). Since transsynaptic activity is known to regulate ontogeny of postsynaptic transmitter enzymes, we initially studied the developing ganglion. Denervation in neonates prevented normal development, decreasing calmodulin binding to the ganglionic PSDp by 71% after 4 weeks. During this period, denervation elicited only a 42% decrease in total protein of the synaptic membrane fraction, suggesting that innervation regulates development of various synaptic components differentially. Effects of denervation were extremely rapid, resulting in a 44% decrease in calmodulin binding within 1 day, consistent with regulation by a signaling process such as impulse activity. The effect of impulse activity was examined more directly in adults by treatment with the agents reserpine or phenoxybenzamine, which elicit reflex increases in sympathetic transmission. Administration of reserpine resulted in a progressive 90% increase in calmodulin binding to the PSDp over 4 weeks. Phenoxybenzamine also elicited an increase, mimicking the effects of reserpine. Neither agent altered total protein of the synaptic membrane fraction, suggesting that impulse activity regulates specific synaptic components. Finally, ganglionic denervation in adults decreased PSDp binding within 12 hr, consistent with acute effects of impulse reduction. Our results suggest that transsynaptic impulse activity plays an important role in regulation of specific molecular components of the synapse.