Adaptor protein complex-4 (AP-4) is expressed in the central nervous system neurons and interacts with glutamate receptor delta2.

Ion channels and receptors are targeted and localized at specific postsynaptic sites to mediate neurotransmission. Receptors clustering at postsynaptic sites has been extensively studied; however, the molecular mechanisms underlying intracellular trafficking of receptors to their specific destinations remain unclear. In the present study, we found that glutamate receptor delta2 interacted directly with AP-4, a newly identified adaptor protein complex-4 that mediates protein sorting in mammalian cells. The interaction between mu4 subunit of AP-4 and the delta2 C-terminal involved multiple amino acid sequence motifs other than the classical tyrosine-based signals. AP-4 complex is expressed ubiquitously in many regions of brain, with localization on the Golgi-like structures in the cell bodies and dendrites of neurons. In addition, overexpression of mu4 substantially altered the distribution pattern of delta2 in heterologous cells. These results suggest a potential involvement of AP-4 in the trafficking of delta2 in the brain.

Differential expression and function of apoptosis-associated tyrosine kinase (AATYK) in the developing mouse brain.

Apoptosis-associated tyrosine kinase (AATYK) is a non-receptor type tyrosine kinase that is predominantly expressed in adult mouse brain. Although it is also expressed in developing brains, its expression pattern and physiological functions are unclear. In the present study, we analyzed expression profiles of AATYK in developing mouse brains and its functional role and subcellular localization in cultured cerebellar granule cells. Expression of AATYK mRNA and protein increased during postnatal brain development. Immunohistochemical analysis indicated that the protein was differentially expressed in postmitotic neurons within various brain areas including the olfactory bulb, cerebral cortex, hippocampus, thalamus, colliculus, cerebellum, and brain stem. Developmental increases in its expression were also observed in cultured cerebellar granule cells. AATYK protein was largely fractionated into the microsomal fraction and was immunocytochemically distributed in an ER-like meshwork of the granule cell soma, suggesting a possible association with the ER membrane. AATYK protein was also present in neurites. In immature granule cells, overexpression of wild-type AATYK promoted neurite outgrowth, whereas that of tyrosine kinase-defective mutant significantly inhibited it. These results suggest that, in addition to its role in cell death in mature neurons, AATYK has a unique role in promoting neurite extension through its tyrosine kinase activity in developing neurons.

CIP98, a novel PDZ domain protein, is expressed in the central nervous system and interacts with calmodulin-dependent serine kinase.

Receptors and various molecules in neurons are localized at precise locations to perform their respective functions, especially in synaptic sites. Among synaptic molecules, PDZ domain proteins play major roles in scaffolding and anchoring membrane proteins for efficient synaptic transmission. In the present study, we isolated CIP98, a novel protein (98 kDa) consisting of three PDZ domains and a proline-rich region, which is widely expressed in the central nervous system. In situ hybridization and immunohistochemical staining patterns demonstrate that CIP98 is expressed strongly in certain types of neurons, i.e. pyramidal cells in layers III-V of the cerebral cortex, projecting neurons in the thalamus and interneurons in the cerebellum. The results of immunocytochemical staining and electron microscopy revealed that CIP98 is localized both in dendrites and axons. Interestingly, CIP98 interacts with CASK (calmodulin-dependent serine kinase), a member of the membrane-associated guanylate kinase (MAGUK) family that plays important roles in the molecular organization of proteins at synapses. CIP98 was shown to co-localize with CASK along the dendritic processes of neurons. In view of its direct association with CASK, CIP98 may be involved in the formation of CASK scaffolding proteins complex to facilitate synaptic transmission in the CNS.

PKC regulates the delta2 glutamate receptor interaction with S-SCAM/MAGI-2 protein.

Inside cells, membrane proteins are localized at particular surface domains to perform their precise functions. Various kinds of PDZ domain proteins have been shown to play important roles in the intracellular trafficking and anchoring of membrane proteins. In this study, we show that delta2 glutamate receptor is interacting with S-SCAM/MAGI-2, a PDZ domain protein localized in the perinuclear region and postsynaptic sites of cerebellar Purkinje cells. The binding is regulated by PKC (protein kinase-C) mediated phosphorylation of the receptor with a unique repetitive structure in S-SCAM/MAGI-2. Co-expression of both proteins resulted in drastic changes of the receptor localization in COS7 cells. These results show a novel regulatory mechanism for the binding of PDZ domain proteins and suggest that the interaction between delta2 receptor and S-SCAM/MAGI-2 may be important for intracellular trafficking of the receptor.

Molecular mechanisms of analgesia induced by opioids and ethanol: is the GIRK channel one of the keys?

Opioids and ethanol have been used since ancient times for pain relief. Opioid signaling is mediated by various effectors, including G protein-activated inwardly rectifying potassium (GIRK) channels, adenylyl cyclases, voltage-dependent calcium channels, phospholipase Cbeta(PLCbeta), and mitogen-activated protein kinases, although it has been unclear which effector mediates the analgesic effects of opioids. Ethanol induces a variety of physiological phenomena via various proteins, including GIRK channels rather than via membrane lipids. GIRK channel activation by either G proteins or ethanol is impaired in weaver mutant mice. The mutant mice may therefore serve as a useful animal model for studying the role of GIRK channels in vivo. Reduced analgesia by using either opioids or ethanol in weaver mutant mice suggests that GIRK channels are important effectors in both opioid- and ethanol-induced analgesia. This hypothesis is supported by similar findings in GIRK2 knockout mice. Among the various effectors coupled with opioid receptors and various targets of ethanol, GIRK channels are the only molecules whose involvement in opioid- and ethanol-induced analgesia has been demonstrated in vivo. The GIRK channel is potentially one of the key molecules in furthering the understanding of the pain control system and in developing advanced analgesics with fewer adverse effects.

Degeneration of pontine mossy fibres during cerebellar development in weaver mutant mice.

In weaver mutant mice, substitution of an amino acid residue in the pore region of GIRK2, a subtype of the G-protein-coupled inwardly rectifying K+ channel, changes the properties of the homomeric channel to produce a lethal depolarized state in cerebellar granule cells and dopaminergic neurons in substantia nigra. Degeneration of these types of neurons causes strong ataxia and Parkinsonian phenomena in the mutant mice, respectively. On the other hand, the mutant gene is also expressed in various other brain regions, in which the mutant may have effects on neuronal survival. Among these regions, we focused on the pontine nuclei, the origin of the pontocerebellar mossy fibres, projecting mainly into the central region of the cerebellar cortex. The results of histological analysis showed that by P9 the number of neurons in the nuclei was reduced in the mutant to about one half and by P18 to one third of those in the wild type, whereas until P7 the number were about the same in wild-type and weaver mutant mice. Three-dimensional reconstruction of the nuclei showed a marked reduction in volume and shape of the mutant nuclei, correlating well with the decrease in neuronal number. In addition, DiI (a lipophilic tracer dye) tracing experiments revealed retraction of pontocerebellar mossy fibres from the cerebellar cortex after P5. From these results, we conclude that projecting neurons in the pontine nuclei, as well as cerebellar granule cells and dopaminergic neurons in substantia nigra, strongly degenerate in weaver mutant mice, resulting in elimination of pontocerebellar mossy fibres during cerebellar development.

MALC, a novel microinjection method for loading of macromolecules into cultured neurons.

Microinjection is one of the most useful and important methods in cellular neurobiology. However, direct insertion and retraction of a capillary produce physical stresses inside cells that make it difficult to apply on small and fragile cells, especially the central nervous system (CNS) neurons. In this study, we developed a novel method called MALC (microinjection method assisted with laser activated chromophore) to avoid this disadvantage of the conventional method. In MALC, a capillary is just attached on cell surface, and combination of a newly developed photosensitizer with a laser pointing system makes the plasma membrane permeable to molecules. This novel method can expand the application of the microinjection method and realize molecular manipulations inside CNS neurons.