Quantitative Mutation Analysis of Genes and Proteins of Major SARS-CoV-2 Variants of Concern and Interest.

Of various SARS-CoV-2 variants, some have drawn special concern or interest because of their heightened disease threat. The mutability of individual SARS-CoV-2 genes/proteins presumably varies. The present study quantified gene/protein mutations in 13 major SARS-CoV-2 variants of concern/interest, and analyzed viral protein antigenicity using bioinformatics. The results from 187 carefully perused genome clones showed significantly higher mean percent mutations in the spike, ORF8, nucleocapsid, and NSP6 than in other viral proteins. The ORF8 and spike proteins also tolerated higher maximal percent mutations. The omicron variant presented more percent mutations in the NSP6 and structural proteins, whereas the delta featured more in the ORF7a. Omicron subvariant BA.2 exhibited more mutations in ORF6, and omicron BA.4 had more in NSP1, ORF6, and ORF7b, relative to omicron BA.1. Delta subvariants AY.4 and AY.5 bore more mutations in ORF7b and ORF8 than delta B.1.617.2. Predicted antigen ratios of SARS-CoV-2 proteins significantly vary (range: 38-88%). To overcome SARS-CoV-2 immune evasion, the relatively conserved, potentially immunogenic NSP4, NSP13, NSP14, membrane, and ORF3a viral proteins may serve as more suitable targets for molecular vaccines or therapeutics than the mutation-prone NSP6, spike, ORF8, or nucleocapsid protein. Further investigation into distinct mutations of the variants/subvariants may help understand SARS-CoV-2 pathogenesis.

COVID-19 Anosmia: High Prevalence, Plural Neuropathogenic Mechanisms, and Scarce Neurotropism of SARS-CoV-2?

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is the causative pathogen of coronavirus disease 2019 (COVID-19). It is known as a respiratory virus, but SARS-CoV-2 appears equally, or even more, infectious for the olfactory epithelium (OE) than for the respiratory epithelium in the nasal cavity. In light of the small area of the OE relative to the respiratory epithelium, the high prevalence of olfactory dysfunctions (ODs) in COVID-19 has been bewildering and has attracted much attention. This review aims to first examine the cytological and molecular biological characteristics of the OE, especially the microvillous apical surfaces of sustentacular cells and the abundant SARS-CoV-2 receptor molecules thereof, that may underlie the high susceptibility of this neuroepithelium to SARS-CoV-2 infection and damages. The possibility of SARS-CoV-2 neurotropism, or the lack of it, is then analyzed with regard to the expression of the receptor (angiotensin-converting enzyme 2) or priming protease (transmembrane serine protease 2), and cellular targets of infection. Neuropathology of COVID-19 in the OE, olfactory bulb, and other related neural structures are also reviewed. Toward the end, we present our perspectives regarding possible mechanisms of SARS-CoV-2 neuropathogenesis and ODs, in the absence of substantial viral infection of neurons. Plausible causes for persistent ODs in some COVID-19 convalescents are also examined.

Sustentacular Cell Enwrapment of Olfactory Receptor Neuronal Dendrites: An Update.

The pseudostratified olfactory epithelium (OE) may histologically appear relatively simple, but the cytological relations among its cell types, especially those between olfactory receptor neurons (ORNs) and olfactory sustentacular cells (OSCs), prove more complex and variable than previously believed. Adding to the complexity is the short lifespan, persistent neurogenesis, and continuous rewiring of the ORNs. Contrary to the common belief that ORN dendrites are mostly positioned between OSCs, recent findings indicate a sustentacular cell enwrapped configuration for a majority of mature ORN dendrites at the superficial layer of the OE. After vertically sprouting out from the borderlines between OSCs, most of the immature ORN dendrites undergo a process of sideways migration and terminal maturation to become completely invaginated into and enwrapped by OSCs. Trailing the course of the dendritic sideways migration is the mesodendrite (mesentery of the enwrapped dendrite) made of closely apposed, cell junction connected plasma membrane layers of neighboring folds of the host sustentacular cell. Only a minority of the mature ORN dendrites at the OE apical surface are found at the borderlines between OSCs (unwrapped). Below I give a brief update on the cytoarchitectonic relations between the ORNs and OSCs of the OE. Emphasis is placed on the enwrapment of ORN dendrites by OSCs, on the sideways migration of immature ORN dendrites after emerging from the OE surface, and on the terminal maturation of the ORNs. Functional implications of ORN dendrite enwrapment and a comparison with myelination or Remak's bundling of axons or axodendrites in the central and peripheral nervous system are also discussed.

Olfactory receptor neuronal dendrites become mostly intra-sustentacularly enwrapped upon maturity.

The mammalian olfactory epithelium (OE) sustains persistent neurogenesis even in the adult. Sustentacular cells therein play both epithelial and neuroglial roles, although their relation with olfactory receptor neurons (ORNs) and their function in ORN maturation remain insufficiently understood. Sustentacular wrapping of ORN dendrites has been long known but always considered a minor presence, as opposed to the supposedly unwrapped majority of ORN dendrites at inter-sustentacular borderlines. Using immunofluorescence, confocal and immuno-electron microscopy, the current study examined cytoarchitectonic organization and maturation of ORN dendrites at the rat OE apical layer. Contrary to common belief, the observations here on tangential histological sections of the OE apical junctional belt layer showed on average 53.93% sustentacular cell-enwrapped, 18.46% partially wrapped (in the vertical grooves on the sides of sustentacular apices) and 27.61% unwrapped ORN dendrites (at the borderlines between sustentacular cells). The enwrapped dendrites were found within the confines of sustentacular apices but linked to the sides of the latter each by a mesentery (mesodendrite) of sustentacular plasma membranes and autotypic cell junctions. Up to six dendrites were seen in one sustentacular apical process. As marked by high and low immunoreactivity for class III beta-tubulin, respectively, immature and mature ORN dendrites accounted on average for 12.46 and 87.54% of the total ORN dendrites at the OE apical layer. By correlative analysis of the maturity level and wrapping status, most immature ORN dendrites were found unwrapped (immature unwrapped = 9.71% of the total dendrites), and practically no immature dendrites appeared enwrapped. In contrast, mature ORN dendrites comprised all the enwrapped (mature enwrapped = 53.93% of the total), most of the partially wrapped (mature partially wrapped = 15.71% of the total) and a portion of the unwrapped ORN dendrites (mature unwrapped = 17.9% of the total dendrites). Based on the current findings and previous data by other researchers, it is concluded that immature ORN dendrites emerge vertically from the OE apical surface between sustentacular cell apices. A large majority of the newly emerged dendrites then undergo sideways migration, sustentacular enwrapment and further maturation. Only a small minority of the newly emerged dendrites reach maturity and remain unwrapped. These divergent maturational courses imply structural or functional differences between the enwrapped and unwrapped mature ORN dendrites.

Juxtanodin in retinal pigment epithelial cells: Expression and biological activities in regulating cell morphology and actin cytoskeleton organization.

Juxtanodin (JN, also known as ermin) was initially identified as an actin cytoskeleton-related oligodendroglial protein in the rat central nervous system. It was subsequently also found in the rat olfactory neuroepithelium, especially at the apical junctional belt of the sustentacular cells. We further examined JN expression and functional roles in the retina using fluorescence histochemistry, confocal microscopy, immuno-electron microscopy, molecular biology, and cell culture. Prominent JN expression was found in the photoreceptor-supporting retinal pigment epithelium (RPE), especially in a zone corresponding to the apices of RPE cells, at the roots of the RPE microvilli, and at the base of RPE cells next to the Bruch's membrane. Partial co-localization of JN immunoreactivity with F-actin (labeled with phalloidin) was observed at the apices and bases of RPE cells. No JN was detected in other cell types of the retina. In cultured human RPE cell line ARPE-19, expression of extrinsic JN up-regulated formation of actin cytoskeleton stress fibers, caused redistribution of more F-actin fibers to the cell periphery, and promoted spreading/enlargement of transfected cells. These findings suggest possible roles of JN in RPE molecular transport, phagocytosis and formation of outer blood-retinal barrier, or possible involvement of JN expression perturbations in pathogenesis of such retinal disorders as proliferative vitreoretinopathy and age-related macular degeneration.

Sirtuin 5 is Anti-apoptotic and Anti-oxidative in Cultured SH-EP Neuroblastoma Cells.

As a nicotinamide adenine dinucleotide (NAD+)-dependent deacetylase, demalonylase, and desuccinylase, sirtuin 5 (SIRT5) in host cells has been reportedly observed in the mitochondria, in the cytosol/cytoplasm or in the nucleus. Various functional roles of SIRT5 have also been described in cellular metabolism, energy production, detoxification, oxidative stress, and apoptosis, but some of the reported results are seemingly inconsistent or even contradictory to one another. Using immunocytochemistry, molecular biology, gene transfection, and flow cytometry, we investigated the expression, subcellular distribution, and possible functional roles of SIRT5 in regulating apoptosis and oxidative stress of cultured SH-EP neuroblastoma cells. Both endogenous and transfected exogenous SIRT5 were observed in mitochondria of host SH-EP cells. Overexpression of SIRT5 markedly protected SH-EP cells from apoptosis induced by staurosporine or by incubation in Hank's balanced salt solution. SIRT5 also lowered the level of oxidative stress and countered the toxicity of hydrogen peroxide to SH-EP cells. It was suggested that the anti-apoptotic role of SIRT5 was mediated, at least in part, by its anti-oxidative effect in SH-EP neuroblastoma cells although the involved molecular mechanisms remain to be elucidated in details.

BNIP-H Recruits the Cholinergic Machinery to Neurite Terminals to Promote Acetylcholine Signaling and Neuritogenesis.

Synthesis and release of neurotransmitters such as acetylcholine (ACh) are key to synaptic function. However, little is known about the spatial regulation of their synthesizing machinery. Here, we demonstrate that ataxia-related protein BNIP-H/Caytaxin links kinesin-1 (KLC1) to ATP citrate lyase (ACL), a key enzyme for ACh synthesis, and transports it toward neurite terminals. There, BNIP-H/ACL complex synergistically recruits another enzyme choline acetyltransferase (ChAT), leading to enhanced secretion of ACh. ACh then activates MAPK/ERK via muscarinic receptors to promote neurite outgrowth. In mice deficient in BNIP-H, ACL fails to interact with KLC1, and formation of the ACL/ChAT complex is prevented, whereas the disease-associated BNIP-H mutation fails to target ACL for neurite outgrowth. Significantly, Bnip-h knockdown in zebrafish causes developmental defect in motor neurons through impaired cholinergic pathway, leading to motor disorder. Therefore, precise targeting of the cholinergic machinery through BNIP-H is essential for the local production of ACh for morphogenesis and neurotransmission.

Multiple C2 domains transmembrane protein 1 is expressed in CNS neurons and possibly regulates cellular vesicle retrieval and oxidative stress.

Multiple C2 domains transmembrane protein 1 (MCTP1) contains two transmembrane regions and three C2 domains of high Ca(2+)-binding affinity. Single-nucleotide polymorphism (SNP) of human MCTP1 gene is reportedly associated with bipolar disorder, but expression and function of MCTP1 in the CNS is still largely unknown. We cloned rat MCTP1 isoforms, and studied expression of MCTP1 transcript and protein in the CNS. Subcellular distribution and functional roles of MCTP1 were investigated in cultured primary neurons or PC12 cells by over-expression, cell imaging, and flow cytometry. MCTP1 immunostaining was seen in both CNS neuronal cell bodies and processes, especially in the hippocampus, dentate gyrus, medial habenular nucleus, amygdala, and selected cerebral and cerebellar cortical areas/layers. Under an electron microscope, MCTP1 immunoreactivity was observed on vesicles in neuronal cell bodies and pre-synaptic axon terminals. In cultured primary neurons and PC12 cells MCTP1 was detected on selected populations of secretory vesicles and endosomes. MCTP1 over-expression significantly inhibited neuronal transferrin endocytosis, secretory vesicle retrieval, cell migration, and oxidative stress from glutamate toxicity. Thus MCTP1 might be involved in regulating endocytic recycling of specific CNS neurons and synapses. MCTP1 abnormality might cause altered synaptic vesicle recycling, and thereby lead to vulnerability to neuropsychiatric diseases.

Characterization and therapeutic evaluation of a Nestin⁺ CNP⁺ NG2⁺ cell population on mouse spinal cord injury.

The NG2 chondroitin sulfate proteoglycan-expressing neural cells (NG2 cells) have originally been considered as oligodendrocyte progenitor cells (OPCs). However, recent findings on their diverse functions and lineage heterogeneity demonstrated that the NG2 cells contain various sub-populations whose concrete features and therapeutic potential yet remained elucidated. In the present study, we characterized a Nestin(+) 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNP)(+) NG2(+) subpopulation from embryonic rat cerebral cortex. The Nestin(+) CNP(+) NG2(+) cells exhibited remarkable progenitor characteristics. Having been immortalized by human telomerase reverse transcriptase (hTERT), the life span of Nestin(+) CNP(+) NG2(+) cells was extended to 230 population doublings (PDs). With immortalized NG2 cells, we demonstrated their differentiation capacities to oligodendrocytes, astrocytes and neurons. Furthermore, transplanted into injured spinal cord of a mouse model, they were able to promote remyelination and neuronal regeneration, thereby enhancing the functional recovery. Our findings suggest that the Nestin(+) CNP(+) NG2(+) progenitor cells could be a good alternative cell source of cell therapy for neurological disorders.

Juxtanodin is an intrinsically disordered F-actin-binding protein.

Juxtanodin, also called ermin, is an F-actin-binding protein expressed by oligodendrocytes, the myelin-forming cells of the central nervous system. While juxtanodin carries a short conserved F-actin-binding segment at its C terminus, it otherwise shares no similarity with known protein sequences. We carried out a structural characterization of recombinant juxtanodin in solution. Juxtanodin turned out to be intrinsically disordered, as evidenced by conventional and synchrotron radiation CD spectroscopy. Small-angle X-ray scattering indicated that juxtanodin is a monomeric, highly elongated, unfolded molecule. Ensemble optimization analysis of the data suggested also the presence of more compact forms of juxtanodin. The C terminus was a strict requirement for co-sedimentation of juxtanodin with microfilaments, but juxtanodin had only mild effects on actin polymerization. The disordered nature of juxtanodin may predict functions as a protein interaction hub, although F-actin is its only currently known binding partner.

Sub-cellular localization, expression and functions of Sirt6 during the cell cycle in HeLa cells.

Sirtuin 6 (Sirt6), a mammalian Sir2 (silent information regulator-2) ortholog, is an NAD (+) -dependent histone deacetylase that modulates chromatin structure and genomic stability. Sirt6 knockout cells demonstrate genomic instability, and a deficiency of Sirt6 in mice leads to an aging phenotype early in life. Some nuclear sirtuins, such as Sirt7, localize to the nucleolus, and others, such as Sirt1, are mainly found in the nucleoplasm, with a minor population in the nucleolus. However, Sirt6 has been reported to be a nucleoplasmic protein that is excluded from the nucleolus. Because of the importance of a protein's localization to its interactions and functions, we evaluated Sirt6 sub-cellular localization, expression and functions throughout the cell cycle in HeLa cells. Our results showed that during interphase, Sirt6 was mostly localized to the nucleus, although it was not absent from the nucleolus. Sirt6 was enriched in the nucleolus in the G 1 phase of the cell cycle, while S phase nucleoli were almost entirely free of Sirt6. During mitosis, the Sirt6 expression level was increased, and while Sirt6 was not associated with condensed chromosomes, it partially co-localized with mitotic spindles. Cells overexpressing Sirt6 had a lower proliferation rate with a lower percentage of cells in mitosis. These findings suggest roles for Sirt6 in the nucleolus and in the mitotic phase of the cell cycle.

4.1G promotes arborization and tight junction formation of oligodendrocyte cell line OLN-93.

4.1G belongs to the membrane-associated band 4.1 protein family, which plays important roles in establishing and maintaining the links between transmembrane proteins and the cytoskeleton. Till date, expression and functions of 4.1G in the central nervous system (CNS) have not been fully elucidated. We investigated expression, cellular/subcellular distribution, and biological roles of 4.1G in the rat CNS and in cultured oligodendrocyte cell line OLN-93. Immunoblotting (IB) and immunoprecipitation revealed CNS 4.1G protein isoforms with molecular weights ranging from ∼80 to ∼180 kDa. In subconfluent OLN-93 cell culture, overexpression of full-length 4.1G and C-terminal-domain-deleted 4.1G, but not the FERM-domain-deleted 4.1G, promoted cellular arborization. In confluent cells, endogenous 4.1G was upregulated and clustered in the cytoplasmic periphery together with tight junction protein ZO-1. FERM domain seemed essential for this recruitment of 4.1G to OLN-93 cell periphery. Calcium switch experiment demonstrated that overexpressed 4.1G promoted tight junction reassembly, whereas siRNA knockdown of endogenous 4.1G inhibited tight junction formation among confluent OLN-93 cells. Together, these results suggest functional roles of 4.1G in cellular arborization and tight junction formation. In the CNS, 4.1G might be involved in maturation of host cells as well as in interaction among neurons/neuroglia.

Dephosphorylation-dependent inhibitory activity of juxtanodin on filamentous actin disassembly.

In the vertebrate central nervous system, maturation of oligodendrocytes is accompanied by a dramatic transformation of cell morphology. Juxtanodin (JN) is an actin cytoskeleton-related oligodendroglial protein that promotes arborization of cultured oligodendrocytes. We performed in vitro and in culture experiments to further elucidate the biochemical effects, molecular interactions, and activity regulation of JN. Pulldown and co-sedimentation assays confirmed JN binding to filamentous but not globular beta-actin largely through a C-terminal domain of 14 amino acid residues. JN had much lower affinity to F-alpha-actin than to F-beta-actin. Bundling and actin polymerization assays revealed no JN influence on F-beta-actin cross-linking or G-beta-actin polymerization. Sedimentation assay, however, demonstrated that JN slowed the rate of F-beta-actin disassembly induced by dilution with F-actin depolymerization buffer. JN-S278E mutant, a mimic of phosphorylated JN at serine 278, exhibited a much diminished affinity/stabilizing effect on F-beta-actin. Immunoblotting revealed both phosphorylated and dephosphorylated native JN of the brain, with the former migrating slightly slower than the latter and becoming undetectable when brain lysate was subjected to in vitro dephosphorylation prior to being loaded for electrophoresis. In cultured OLN-93 cells, overexpression of JN promoted the formation of actin fibers and inhibited F-actin disassembly induced by latrunculin A. S278E phosphomimetic mutation resulted in loss of JN activity in cultured cells, whereas S278A, T258A, and T258E dephospho-/phosphomimetic mutations did not. These findings establish JN as an actin cytoskeleton-stabilizing protein that may play active roles in oligodendroglial differentiation and myelin formation. Specific phosphorylation of JN might serve as an important mechanism regulating JN functions.

Rab22B is expressed in the CNS astroglia lineage and plays a role in epidermal growth factor receptor trafficking in A431 cells.

The expression profile and functions of the brain-enriched Rab22B/Rab31 small GTPase had remained uncharacterized. Using specific antibodies against Rab22B, we found the protein to be exceptionally enriched in nestin and RC2-positive radial glia of the embryonic mouse brain. In the adult brain, Rab22B is rather specifically expressed in glial fibrillary acidic protein (GFAP)-positive mature astrocytes, but is not clearly detectable in either 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNPase)-positive mature oligodendrocytes or betaIII-tubulin (TuJ)-positive neurons. In probing for specific functions of Rab22B, we found that Rab22B silencing in A431 cells resulted in abnormal trafficking of the epidermal growth factor receptor (EGFR), Texas-red-labeled EGF, and the cation-independent mannose 6-phosphate receptor (M6PR). Affinity pull-down assays and co-immunoprecipitation analysis indicated that Rab22B could associate with EGFR in a GTP-dependent manner. Rab22B is thus a Rab protein specifically expressed in the astroglia lineage and may have a role in regulating EGFR trafficking in some cell types. Given that EGFR signaling modulates astrocyte development and oncogenesis of multiple cell types, Rab22B may thus have specific developmental or pathophysiological roles in cell types which it is enriched in.

RIM3gamma is a postsynaptic protein in the rat central nervous system.

RIMs (Rab3-interacting molecules) are synaptic proteins essential for neural transmission and plasticity. RIM1alpha has been implicated in membrane trafficking and regulation of secretory vesicle exocytosis in eukaryotic cells. Little information is as yet available on RIM3gamma. In the present study, we investigated the cellular expression, subcellular distribution, and possible functions of RIM3gamma in the rat CNS. Rim3gamma cDNA was subcloned and the protein expressed in vitro for the generation and purification of a rabbit anti-RIM3gamma polyclonal antibody. In situ hybridization histochemistry, immunohistochemistry, and immunoelectron microscopy were performed to map expression of the mRNA and protein in the rat CNS. Our results indicated widespread distribution of RIM3gamma in diverse CNS neuronal cell types. The mRNA was found mainly in the cell bodies, whereas the protein immunoreactivity was localized chiefly to neuronal dendrites and to the postsynaptic densities as visualized under the light and electron microscope. This postsynaptic placement of RIM3gamma is distinct from the presynaptic localization of RIM1alpha but may contribute to regulating synaptic transmission and plasticity. The identification of RIM3gamma as a postsynaptic protein has functional implications for CNS synapse functions.

Sirtuin 2, a mammalian homolog of yeast silent information regulator-2 longevity regulator, is an oligodendroglial protein that decelerates cell differentiation through deacetylating alpha-tubulin.

Silent information regulator-2 (SIR2) proteins regulate lifespan of diverse organisms, but their distribution and roles in the CNS remain unclear. Here, we show that sirtuin 2 (SIRT2), a mammalian SIR2 homolog, is an oligodendroglial cytoplasmic protein and localized to the outer and juxtanodal loops in the myelin sheath. Among cytoplasmic proteins of OLN-93 oligodendrocytes, alpha-tubulin was the main substrate of SIRT2 deacetylase. In cultured primary oligodendrocyte precursors (OLPs), SIRT2 emergence accompanied elevated alpha-tubulin acetylation and OLP differentiation into the prematurity stage. Small interfering RNA knockdown of SIRT2 increased the alpha-tubulin acetylation, myelin basic protein expression, and cell arbor complexity of OLPs. SIRT2 overexpression had the opposite effects, and counteracted the cell arborization-promoting effect of overexpressed juxtanodin. SIRT2 mutation concomitantly reduced its deacetylase activity and its impeding effect on OLP arborization. These results demonstrated a counterbalancing role of SIRT2 against a facilitatory effect of tubulin acetylation on oligodendroglial differentiation. Selective SIRT2 availability to oligodendroglia may have important implications for myelinogenesis, myelin-axon interaction, and brain aging.

Brain-specific BNIP-2-homology protein Caytaxin relocalises glutaminase to neurite terminals and reduces glutamate levels.

Human Cayman ataxia and mouse or rat dystonia are linked to mutations in the genes ATCAY (Atcay) that encode BNIP-H or Caytaxin, a brain-specific member of the BNIP-2 family. To explore its possible role(s) in neuronal function, we used protein precipitation and matrix-assisted laser desorption/ionisation mass spectrometry and identified kidney-type glutaminase (KGA) as a novel partner of BNIP-H. KGA converts glutamine to glutamate, which could serve as an important source of neurotransmitter. Co-immunoprecipitation with specific BNIP-H antibody confirmed that endogenous BNIP-H and KGA form a physiological complex in the brain, whereas binding studies showed that they interact with each other directly. Immunohistochemistry and in situ hybridisation revealed high BNIP-H expression in hippocampus and cerebellum, broadly overlapping with the expression pattern previously reported for KGA. Significantly, BNIP-H expression was activated in differentiating neurons of the embryonic carcinoma cell line P19 whereas its overexpression in rat pheochromocytoma PC12 cells relocalised KGA from the mitochondria to neurite terminals. It also reduced the steady-state levels of glutamate by inhibiting KGA enzyme activity. These results strongly suggest that through binding to KGA, BNIP-H could regulate glutamate synthesis at synapses during neurotransmission. Thus, loss of BNIP-H function could render glutamate excitotoxicity or/and deregulated glutamatergic activation, leading to ataxia, dystonia or other neurological disorders.

Juxtanodin: an oligodendroglial protein that promotes cellular arborization and 2',3'-cyclic nucleotide-3'-phosphodiesterase trafficking.

In the process of screening cell-type-specific genes, we identified juxtanodin (JN), an oligodendroglial protein featuring a putative C-terminal actin-binding domain. At the cellular level, JN in the rat CNS colocalized with 2',3'-cyclic nucleotide-3'-phosphodiesterase (CNPase), a cytoskeleton-related oligodendroglial protein. In the myelin sheath, JN was found mainly in the abaxon and the lateral few terminal loops. Its apposition to the myelinated axon, through the latter, defined an axonal subregion, herewith termed juxtanode, at the Ranvier node-paranode junction. During forebrain ontogenesis, JN expression paralleled that of MBPs but lagged behind CNPase. Juxtanodin transfection promoted arborization of cultured OLN-93 cells and augmented endogenous CNPase expression and transport to the process arbors of cultured primary oligodendrocyte precursors. These results reveal JN as a cytoskeleton-related oligodendroglial protein that delineates the juxtanode and might serve oligodendrocyte motility, differentiation, or myelin-axon signaling. Functionally, JN may be involved in CNS myelination and/or specialization of the node of Ranvier.

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.

Non-polarized distribution of synaptotagmin IV in neurons: evidence that synaptotagmin IV is not a synaptic vesicle protein.

Synaptotagmin IV (Syt IV) expression is regulated by neuronal development and by depolarization in the brain and in neuronal cell cultures. In cultures, immunocytochemical analysis has shown that Syt IV is localized at the Golgi and at the tips of growing neurites, but little was known about associations between Syt IV and vesicles or organelles [J. Neurochem. 74 (2000) 518]. In this study we performed an electron microscopic (EM) analysis of developing mouse neocortex to determine the exact localization of Syt IV in native mouse tissues. In neurons of layer II/III, Syt IV was found to be localized in the dendrites and axons, and at the Golgi in the cell body. Some Syt IV signals were clearly associated with vesicles and/or organelles, but EM and cell fractionation studies showed no Syt IV signals at synaptic vesicles. Detection of fluorescence protein-tagged Syt IV (Syt IV-EGFP) in hippocampal neurons also showed the presence of Syt IV-EGFP vesicles or organelles in the axons and dendrites. These results suggest that Syt IV regulates non-polarized membrane trafficking in neurons, which may be involved in synaptic plasticity or neuronal development.