Kenji Sakimura

Impairment of suckling response, trigeminal neuronal pattern formation, and hippocampal LTD in NMDA receptor ε2 subunit mutant mice

Multiple epsilon subunits are major determinants of the NMDA receptor channel diversity. Based on their functional properties in vitro and distributions, we have proposed that the epsilon 1 and epsilon 2 subunits play a role in synaptic plasticity. To investigate the physiological significance of the NMDA receptor channel diversity, we generated mutant mice defective in the epsilon 2 subunit. These mice showed no suckling response and died shortly after birth but could survive by hand feeding. The mutation hindered the formation of the whisker-related neuronal barrelette structure and the clustering of primary sensory afferent terminals in the brainstem trigeminal nucleus. In the hippocampus of the mutant mice, synaptic NMDA responses and longterm depression were abolished. These results suggest that the epsilon 2 subunit plays an essential role in both neuronal pattern formation and synaptic plasticity.

The Endocannabinoid 2-Arachidonoylglycerol Produced by Diacylglycerol Lipase α Mediates Retrograde Suppression of Synaptic Transmission

Endocannabinoids are released from postsynaptic neurons and cause retrograde suppression of synaptic transmission. Anandamide and 2-arachidonoylglycerol (2-AG) are regarded as two major endocannabinoids. To determine to what extent 2-AG contributes to retrograde signaling, we generated and analyzed mutant mice lacking either of the two 2-AG synthesizing enzymes diacylglycerol lipase alpha (DGLalpha) and beta (DGLbeta). We found that endocannabinoid-mediated retrograde synaptic suppression was totally absent in the cerebellum, hippocampus, and striatum of DGLalpha knockout mice, whereas the retrograde suppression was intact in DGLbeta knockout brains. The basal 2-AG content was markedly reduced and stimulus-induced elevation of 2-AG was absent in DGLalpha knockout brains, whereas the 2-AG content was normal in DGLbeta knockout brains. Morphology of the brain and expression of molecules required for 2-AG production other than DGLs were normal in the two knockout mice. We conclude that 2-AG produced by DGLalpha, but not by DGLbeta, mediates retrograde suppression at central synapses.

Selective scarcity of NMDA receptor channel subunits in the stratum lucidum (mossy fibre-recipient layer) of the mouse hippocampal CA3 subfield

Hippocampal synapses express two distinct forms of the long‐term potentiation (LTP), i.e. NMDA receptor‐dependent and ‐independent LTPs. To understand its molecular‐anatomical basis, we produced affinity‐purified antibodies against the GluRε1 (NR2A), GluRε2 (NR2B), and GluRζ1 (NR1) subunits of the N‐methyl‐d‐aspartate (NMDA) receptor channel, and determined their distributions in the mouse hippocampus. Using NMDA receptor subunit‐deficient mice as the specificity controls, section pretreatment with proteases (pepsin and proteinase K) was found to be very effective to detect authentic NMDA receptor subunits. As the result of modified immunohistochemistry, all three subunits were detected at the highest level in the strata oriens and radiatum of the CA1 subfield, and high levels were also seen in most other neuropil layers of the CA1 and CA3 subfields and of the dentate gyrus. However, the stratum lucidum, a mossy fibre‐recipient layer of the CA3 subfield, contained low levels of the GluRε1 and GluRζ1 subunits and almost excluded the GluRε2 subunit. Double immunofluorescence with the AMPA receptor GluRα1 (GluR1 or GluR‐A) subunit further demonstrated that the GluRε1 subunit was colocalized in a subset, not all, of GluRα1‐immunopositive structures in the stratum lucidum. Therefore, the selective scarcity of these NMDA receptor subunits in the stratum lucidum suggests that a different synaptic targeting mechanism exerts within a single CA3 pyramidal neurone in vivo, which would explain contrasting significance of the NMDA receptor channel in LTP induction mechanisms between the mossy fibre‐CA3 synapse and other hippocampal synapses.

Trans-Synaptic Interaction of GluRδ2 and Neurexin through Cbln1 Mediates Synapse Formation in the Cerebellum

Elucidation of molecular mechanisms that regulate synapse formation is required for the understanding of neural wiring, higher brain functions, and mental disorders. Despite the wealth of in vitro information, fundamental questions about how glutamatergic synapses are formed in the mammalian brain remain unanswered. Glutamate receptor (GluR) delta2 is essential for cerebellar synapse formation in vivo. Here, we show that the N-terminal domain (NTD) of GluRdelta2 interacts with presynaptic neurexins (NRXNs) through cerebellin 1 precursor protein (Cbln1). The synaptogenic activity of GluRdelta2 is abolished in cerebellar primary cultures from Cbln1 knockout mice and is restored by recombinant Cbln1. Knockdown of NRXNs in cerebellar granule cells also hinders the synaptogenic activity of GluRdelta2. Both the NTD of GluRdelta2 and the extracellular domain of NRXN1beta suppressed the synaptogenic activity of Cbln1 in cerebellar primary cultures and in vivo. These results suggest that GluRdelta2 mediates cerebellar synapse formation by interacting with presynaptic NRXNs through Cbln1.

Functional expression from cloned cDNAs of glutamate receptor species responsive to kainate and quisqualate

The complete amino acid sequences of two mouse glutamate receptor subunits (GluR1 and GluR2) have been deduced by cloning and sequencing the cDNAs. Xenopus oocytes injected with mRNA derived from the GluR1 cDNA exhibit current responses both to kainate and to quisqualate as well as to glutamate, whereas oocytes injected with mRNA derived from the GluR2 cDNA show little response. Injection of oocytes with both the mRNAs produces current responses larger than those induced by the GluR1‐specific mRNA and the dose‐response relations indicate a positively cooperative interaction between the two subunits. These results suggest that kainate and quisqualate can activate a common glutamate receptor subtype and that glutamate‐gated ionic channels are hetero‐oligomers of different subunits.

Serine racemase is predominantly localized in neurons in mouse brain

D‐Serine is the endogenous ligand for the glycine binding site of the N‐methyl‐D‐aspartate (NMDA)‐type glutamate receptor (GluR) channel and is involved in the regulation of synaptic plasticity, neural network formation, and neurodegenerative disorders. D‐Serine is synthesized from L‐serine by serine racemase (SR), which was first reported to be localized in astrocytes. However, recently, SR mRNA and its protein have been detected in neurons. In this study, we examined the SR distribution in the brain during postnatal development and in cultured cells by using novel SR knockout mice as negative controls. We found that SR is predominantly localized in pyramidal neurons in the cerebral cortex and hippocampal CA1 region. Double immunofluorescence staining revealed that SR signals colocalized with those of the neuron‐specific nuclear protein, but not with the astrocytic markers glial fibrillary acid protein and 3‐phosphoglycerate dehydrogenase. In the striatum, we observed SR expression in γ‐aminobutyric acid (GABA)ergic medium‐spiny neurons. Furthermore, in the adult cerebellum, we detected weak but significant SR signals in GABAergic Purkinje cells. From these findings, we conclude that SR is expressed predominantly in many types of neuron in the brain and plays a key role in the regulation of brain functions under physiological and pathological conditions via the production of the neuromodulator D‐serine. J. Comp. Neurol. 510:641–654, 2008.

Distal Extension of Climbing Fiber Territory and Multiple Innervation Caused by Aberrant Wiring to Adjacent Spiny Branchlets in Cerebellar Purkinje Cells Lacking Glutamate Receptor δ2

Organized synapse formation on to Purkinje cell (PC) dendrites by parallel fibers (PFs) and climbing fibers (CFs) is crucial for cerebellar function. In PCs lacking glutamate receptor δ2 (GluRδ2), PF synapses are reduced in number, numerous free spines emerge, and multiple CF innervation persists to adulthood. In the present study, we conducted anterograde and immunohistochemical labelings to investigate how CFs innervate PC dendrites under weakened synaptogenesis by PFs. In the GluRδ2 knock-out mouse, CFs were distributed in the molecular layer more closely to the pial surface compared with the wild-type mouse. Serial electron microscopy demonstrated that CFs in the knock-out mouse innervated all spines protruding from proximal dendrites of PCs, as did those in the wild-type mouse. In the knock-out mouse, however, CF innervation extended distally to spiny branchlets, where nearly half of the spines were free of innervation in contrast to complete synapse formation by PFs in the wild-type mouse. Furthermore, from the end point of innervation, CFs aberrantly jumped to form ectopic synapses on adjacent spiny branchlets, whose proximal portions were often innervated by different CFs. Without GluRδ2, CFs are thus able to expand their territory along and beyond dendritic trees of the target PC, resulting in persistent surplus CFs by innervating the distal dendritic segment. We conclude that GluRδ2 is essential to restrict CF innervation to the proximal dendritic segment, by which territorized innervation by PFs and CFs is properly structured and the formation of excess CF wiring to adjacent PCs is suppressed.

Role of the Carboxy-Terminal Region of the GluRε2 Subunit in Synaptic Localization of the NMDA Receptor Channel

The synaptic localization of the N-methyl-D-aspartate (NMDA) type glutamate receptor (GluR) channel is a prerequisite for synaptic plasticity in the brain. We generated mutant mice carrying the carboxy-terminal truncated GluR epsilon2 subunit of the NMDA receptor channel. The mutant mice died neonatally and failed to form barrelette structures in the brainstem. The mutation greatly decreased the NMDA receptor-mediated component of hippocampal excitatory postsynaptic potentials and punctate immunofluorescent labelings of GluR epsilon2 protein in the neuropil regions, while GluR epsilon2 protein expression was comparable. Immunostaining of cultured cerebral neurons showed the reduced punctate staining of the truncated GluR epsilon2 protein at synapses. These results suggest that the carboxy-terminal region of the GluRepsilon2 subunit is important for efficient clustering and synaptic localization of the NMDA receptor channel.

Gq protein alpha subunits Galphaq and Galpha11 are localized at postsynaptic extra-junctional membrane of cerebellar Purkinje cells and hippocampal pyramidal cells.

Following cell surface receptor activation, the α subunit of the Gq subclass of GTP‐binding proteins activates the phosphoinositide signalling pathway. Here we examined the expression and localization of Gq protein α subunits in the adult mouse brain by in situ hybridization and immunohistochemistry. Of the four members of the Gq protein α subunits, Gαq and Gα11 were transcribed predominantly in the brain. The highest transcriptional level of Gαq was observed in cerebellar Purkinje cells (PCs) and hippocampal pyramidal cells, while that of Gα11 was noted in hippocampal pyramidal cells. Antibody against the C‐terminal peptide common to Gαq and Gα11 strongly labelled the cerebellar molecular layer and hippocampal neuropil layers. In these regions, immunogold preferentially labelled the cytoplasmic face of postsynaptic cell membrane of PCs and pyramidal cells. Immunoparticles were distributed along the extra‐junctional cell membrane of spines, dendrites and somata, but were almost excluded from the junctional membrane. By double immunofluorescence, Gαq/Gα11 was extensively colocalized with metabotropic glutamate receptor mGluR1α in dendritic spines of PCs and with mGluR5 in those of hippocampal pyramidal cells. Together with concentrated localization of mGluR1α and mGluR5 in a peri‐junctional annulus on PC and pyramidal cell synapses ( Baude et al. 1993 , Neuron, 11, 771–787; Luján et al. 1996 , Eur. J. Neurosci., 8, 1488–1500), the present molecular‐anatomical findings suggest that peri‐junctional stimulation of the group I metabotropic glutamate receptors is mediated by Gαq and/or Gα11, leading to the activation of the intracellular effector, phospholipase Cβ.

Motor Neuron-specific Disruption of Proteasomes, but not Autophagy, Replicates Amyotrophic Lateral Sclerosis.*

Background: It is not clear how protein degradation systems are involved in ALS pathogenesis. Results: Transgenic mice with motor neuron-specific knock-out of proteasomes, but not of autophagy showed ALS phonotypes. Conclusion: Dysfunction of proteasome may primarily contribute to the pathogenesis of ALS than that of autophagy. Significance: Modulation of proteasome function is a promising approach toward treatment of ALS. Evidence suggests that protein misfolding is crucially involved in the pathogenesis of amyotrophic lateral sclerosis (ALS). However, controversy still exists regarding the involvement of proteasomes or autophagy in ALS due to previous conflicting results. Here, we show that impairment of the ubiquitin-proteasome system, but not the autophagy-lysosome system in motor neurons replicates ALS in mice. Conditional knock-out mice of the proteasome subunit Rpt3 in a motor neuron-specific manner (Rpt3-CKO) showed locomotor dysfunction accompanied by progressive motor neuron loss and gliosis. Moreover, diverse ALS-linked proteins, including TAR DNA-binding protein 43 kDa (TDP-43), fused in sarcoma (FUS), ubiquilin 2, and optineurin were mislocalized or accumulated in motor neurons, together with other typical ALS hallmarks such as basophilic inclusion bodies. On the other hand, motor neuron-specific knock-out of Atg7, a crucial component for the induction of autophagy (Atg7-CKO), only resulted in cytosolic accumulation of ubiquitin and p62, and no TDP-43 or FUS pathologies or motor dysfunction was observed. These results strongly suggest that proteasomes, but not autophagy, fundamentally govern the development of ALS in which TDP-43 and FUS proteinopathy may play a crucial role. Enhancement of proteasome activity may be a promising strategy for the treatment of ALS.