GluD2 Endows Parallel Fiber-Purkinje Cell Synapses with a High Regenerative Capacity.

UNLABELLED: Although injured axons usually do not regenerate in the adult CNS, parallel fibers (PFs) regenerate synaptic connections onto cerebellar Purkinje cells (PCs). In this study, we investigated the role of GluD2 in this regenerative process after PF transection using GluD2-knock-out (KO) mice. All dendritic spines on distal dendrites were innervated by PFs in sham-operated wild-type controls, whereas one-third were devoid of innervation in GluD2-KO mice. In both genotypes, a steep drop in the number of PF synapses occurred with a reciprocal surge in the number of free spines on postlesion day 1, when the PF territory aberrantly expanded toward the proximal dendrites. In wild-type mice, the territory and number of PF synapses were nearly fully restored to normal on postlesion day 7, although PF density remained low. Moreover, presynaptic and postsynaptic elements were markedly enlarged, and the PF terminal-to-PC spine contact ratio increased from 1:1 to 1:2 at most synapses. On postlesion day 30, the size and contact ratio of PF synapses returned to sham-operated control values and PF density recovered through the sprouting and elongation of PF collaterals. However, GluD2-KO mice showed neither a hypertrophic response nor territorial restoration 7 d postlesion, nor the recovery of PF axons or synapses on postlesion day 30. This suggests that PF wiring regenerates initially by inducing hypertrophic responses in surviving synaptic elements (hypertrophic phase), followed by collateral formation by PF axons and retraction of PF synapses (remodeling phase). Without GluD2, no transition to these regenerative phases occurs. SIGNIFICANCE STATEMENT: The glutamate receptor GluD2 expressed at parallel fiber (PF)-Purkinje cell (PC) synapses regulates the formation and maintenance of the synapses. To investigate the role of GluD2 in their extraordinarily high regenerative capacity, the process after surgical transection of PFs was compared between wild-type and GluD2-knock-out mice. We discovered that, in wild-type mice, PF synapses regenerate initially by inducing hypertrophic responses in surviving synaptic elements, and then by sprouting and elongation of PF collaterals. Subsequently, hypertrophied PF synapses remodel into compact synapses. In GluD2-knock-out mice, PF wiring remains in the degenerative phase, showing neither a hypertrophic response nor recovery of PF axons or synapses. Our finding thus highlights that synaptic connection in the adult brain can regenerate with aid of GluD2.

Territories of heterologous inputs onto Purkinje cell dendrites are segregated by mGluR1-dependent parallel fiber synapse elimination.

In Purkinje cells (PCs) of the cerebellum, a single "winner" climbing fiber (CF) monopolizes proximal dendrites, whereas hundreds of thousands of parallel fibers (PFs) innervate distal dendrites, and both CF and PF inputs innervate a narrow intermediate domain. It is unclear how this segregated CF and PF innervation is established on PC dendrites. Through reconstruction of dendritic innervation by serial electron microscopy, we show that from postnatal day 9-15 in mice, both CF and PF innervation territories vigorously expand because of an enlargement of the region of overlapping innervation. From postnatal day 15 onwards, segregation of these territories occurs with robust shortening of the overlapping proximal region. Thus, innervation territories by the heterologous inputs are refined during the early postnatal period. Intriguingly, this transition is arrested in mutant mice lacking the type 1 metabotropic glutamate receptor (mGluR1) or protein kinase Cγ (PKCγ), resulting in the persistence of an abnormally expanded overlapping region. This arrested territory refinement is rescued by lentivirus-mediated expression of mGluR1α into mGluR1-deficient PCs. At the proximal dendrite of rescued PCs, PF synapses are eliminated and free spines emerge instead, whereas the number and density of CF synapses are unchanged. Because the mGluR1-PKCγ signaling pathway is also essential for the late-phase of CF synapse elimination, this signaling pathway promotes the two key features of excitatory synaptic wiring in PCs, namely CF monoinnervation by eliminating redundant CF synapses from the soma, and segregated territories of CF and PF innervation by eliminating competing PF synapses from proximal dendrites.

Developmental switching of perisomatic innervation from climbing fibers to basket cell fibers in cerebellar Purkinje cells.

In early postnatal development, perisomatic innervation of cerebellar Purkinje cells (PCs) switches from glutamatergic climbing fibers (CFs) to GABAergic basket cell fibers (BFs). Here we examined the switching process in C57BL/6 mice. At postnatal day 7 (P7), most perisomatic synapses were formed by CFs on to somatic spines. The density of CF-spine synapses peaked at P9, when pericellular nest around PCs by CFs was most developed, and CF-spine synapses constituted 88% of the total perisomatic synapses. Thereafter, CF-spine synapses dropped to 63% at P12, 6% at P15, and <1% at P20, whereas BF synapses increased reciprocally. During the switching period, a substantial number of BF synapses existed as BF-spine synapses (37% of the total perisomatic synapses at P15), and free spines surrounded by BFs or Bergmann glia also emerged. By P20, BF-spine synapses and free spines virtually disappeared, and BF-soma synapses became predominant (88%), thus attaining the adult pattern of perisomatic innervation. Parallel with the presynaptic switching, postsynaptic receptor phenotype also switched from glutamatergic to GABAergic. In the active switching period, particularly at P12, fragmental clusters of AMPA-type glutamate receptor were juxtaposed with those of GABA(A) receptor. When examined with serial ultrathin sections, immunogold labeling for glutamate and GABA(A) receptors was often clustered beneath single BF terminals. These results suggest that a considerable fraction of somatic spines is succeeded from CFs to BFs and Bergmann glia in the early postnatal period, and that the switching of postsynaptic receptor phenotypes mainly proceeds under the coverage of BF terminals.

Translocation of a "winner" climbing fiber to the Purkinje cell dendrite and subsequent elimination of "losers" from the soma in developing cerebellum.

Functional neural circuits are formed by eliminating early-formed redundant synapses and strengthening necessary connections during development. In newborn mouse cerebellum, each Purkinje cell (PC) is innervated by multiple climbing fibers (CFs) with similar strengths. Subsequently, a single CF is selectively strengthened by postnatal day 7 (P7). We find that this competition among multiple CFs occurs on the soma before CFs form synapses along dendrites. Notably, in most PCs, the single CF that has been functionally strengthened (the "winner" CF) undergoes translocation to dendrites while keeping its synapses on the soma. Synapses of the weaker CFs (the "loser" CFs) remain around the soma and form "pericellular nests" with synapses of the winner CFs. Then most perisomatic synapses are eliminated nonselectively by P15. Thus, our results suggest that the selective translocation of the winner CF to dendrites in each PC determines the single CF that survives subsequent synapse elimination and persistently innervates the PC.

Transient neonatal expression of NR2B/2D subunit mRNAs of the N-methyl-D-aspartate receptor in the parasympathetic preganglionic neurons in the rat spinal cord.

Physiological studies have shown that lower urinary tract function is regulated through glutamate receptors at the levels of spinal and supraspinal cord. Of the receptor family, N-methyl-D-aspartate (NMDA) receptors mediate activity-dependent changes of synaptic efficacy, underlying synaptic plasticity and synapse development. To know the ontogenic changes of NMDA receptor expression in the visceromotor system innervating pelvic organs, including the bladder, we employed double labeling technique of retrograde neuronal tracing and in situ hybridization for detecting NMDA subunit mRNAs in preganglionic neurons (PGNs) of the lumbosacral cord. Rats at postnatal day 7 (P7), 14 (P14), 21 (P21), and adult were used. In situ hybridization was conducted using 35S-labeled antisense oligonucleotides specific to mRNAs for NMDA receptor subunits. Hybridizing signals in PGNs were detected by a dark-field microscope equipped fluorescence detector. PGNs showed strong signals for NR1 subunit mRNA at each developmental stage examined. Moderate signals for the NR2B and NR2D subunit mRNAs were found in PGNs at P7. However, their expression levels decreased thereafter, reaching the minimal level in adults. No significant signals for NR2A and NR2C subunit mRNAs were detected at any stages. This temporal pattern of expression suggests a possible involvement of NMDA receptors in the development of micturitional neural circuit through activity-dependent mechanisms.

Ovariectomy attenuates hyperpolarization and relaxation mediated by endothelium-derived hyperpolarizing factor in female rat mesenteric artery: a concomitant decrease in connexin-43 expression.

Estrogen status is known to affect the incidence of cardiovascular disease. Experiments were designed to prove the influences of in vivo estrogen manipulations on vascular hyperpolarization and relaxation mediated by endothelium-derived hyperpolarizing factor (EDHF), and to explore the possible mechanism contributing to the altered EDHF responses in estrogen-deficient states. Mesenteric arteries with intact endothelium were isolated from sham-operated (control), ovariectomized (OVX), or OVX with 17beta-estradiol replacement (OVX + E ) female rats. In the presence of apamin and charybdotoxin, there was no difference between groups in relaxations to the Ca ionophore A23187 and the endoplasmic reticulum Ca -adenosine triphosphatase inhibitor cyclopiazonic acid (CPA). However, N -nitro-L-arginine produced a marked decrease in A23187- and CPA-induced relaxations in OVX compared with control and OVX + E arteries. In control arteries, A23187 and CPA elicited membrane hyperpolarization in a sustained manner. In contrast, A23187 produced only a small and transient hyperpolarizing effect in OVX arteries. OVX also greatly attenuated the sustained pattern of hyperpolarization to CPA. Such changes in hyperpolarizations were not seen in OVX + E arteries. The EDHF-mediated relaxant and hyperpolarizing responses of control arteries to A23187 and CPA were significantly inhibited by the gap junction inhibitor 18 alpha-glycyrrhetinic acid. Immunohistochemical examination for connexin-43 showed that the expression was abundant along the endothelial layer in control and OVX + E arteries, while being much less in OVX arteries. It was concluded that estrogen deficiency specifically impairs EDHF-mediated vascular actions. This may be partly explained by the reduced expression of connexin-43, a protein molecule that could form myoendothelial gap junction channels.

Distal extension of climbing fiber territory and multiple innervation caused by aberrant wiring to adjacent spiny branchlets in cerebellar Purkinje cells lacking glutamate receptor delta 2.

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 delta2 (GluRdelta2), 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 GluRdelta2 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 GluRdelta2, 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 GluRdelta2 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.