Evidence for spinal N-methyl-d-aspartate receptor involvement in prolonged chemical nociception in the rat.

We used in vivo electrophysiology and a model of more persistent nociceptive inputs to monitor spinal cord neuronal activity in anaesthetised rats to reveal the pharmacology of enhanced pain signalling. The study showed that all responses were blocked by non-selective antagonism of glutamate receptors but a selective and preferential role of the N-methyl-d-aspartate (NMDA) receptor in the prolonged plastic responses was clearly seen. The work lead to many publications, initially preclinical but increasingly from patient studies, showing the importance of the NMDA receptor in central sensitisation within the spinal cord and how this could relate to persistent pain states. This article is part of a Special Issue entitled SI:50th Anniversary Issue.

VCP binding influences intracellular distribution of the slow Wallerian degeneration protein, Wld(S).

Wallerian degeneration slow (Wld(S)) mice express a chimeric protein that delays axonal degeneration. The N-terminal domain (N70), which is essential for axonal protection in vivo, binds valosin-containing protein (VCP) and targets both Wld(S) and VCP to discrete nuclear foci. We characterized the formation, composition and localization of these potentially important foci. Missense mutations show that the N-terminal sixteen residues (N16) of Wld(S) are essential for both VCP binding and targeting Wld(S) to nuclear foci. Removing N16 abolishes foci, and VCP binding sequences from ataxin-3 or HrdI restore them. In vitro, these puncta co-localize with proteasome subunits. In vivo, Wld(S) assumes a range of nuclear distribution patterns, including puncta, and its neuronal expression and intranuclear distribution is region-specific and varies between spontaneous and transgenic Wld(S) models. We conclude that VCP influences Wld(S) intracellular distribution, and thus potentially its function, by binding within the N70 domain required for axon protection.

Delayed synaptic degeneration in the CNS of Wlds mice after cortical lesion.

Therapies that might delay degeneration of synapses offer an appealing strategy for treatment of neurodegenerative diseases, including Alzheimer's disease and related dementias, prion diseases, schizophrenia and amyotrophic lateral sclerosis. Analysis of mouse mutants provides one possible avenue towards identifying relevant mechanisms. Here, we used quantitative and serial section electron microscopy to find out whether the onset and time course of pre-synaptic nerve terminal degeneration is delayed in the striatum of Wallerian degeneration slow (Wld(s)) mutant mice. Synaptic degeneration was observed within 48 h of cortical ablation in wild-type mice but was delayed by approximately 1 week in Wld(s) mice. However, the morphological characteristics of degenerating nerve terminals in wild-type and Wld(s) mice were indistinguishable, in contrast to the differences reported previously in studies of the PNS. Surprisingly, the delayed onset of synaptic degeneration was accompanied by an increased incidence of complex synaptic morphologies on post-synaptic spines in the denervated Wld(S) striatum indicating an enhanced plastic response at both injured and uninjured synapses. The data suggest that targeting Wallerian-like mechanisms of synaptic degeneration could lead to the development of new therapies for the treatment of CNS disorders where synapse loss is a primary feature.

The neuroprotective WldS gene regulates expression of PTTG1 and erythroid differentiation regulator 1-like gene in mice and human cells.

Wallerian degeneration of injured neuronal axons and synapses is blocked in Wld(S) mutant mice by expression of an nicotinamide mononucleotide adenylyl transferase 1 (Nmnat-1)/truncated-Ube4b chimeric gene. The protein product of the Wld(S) gene localizes to neuronal nuclei. Here we show that Wld(S) protein expression selectively alters mRNA levels of other genes in Wld(S) mouse cerebellum in vivo and following transfection of human embryonic kidney (HEK293) cells in vitro. The largest changes, identified by microarray analysis and quantitative real-time polymerase chain reaction of cerebellar mRNA, were an approximate 10-fold down-regulation of pituitary tumour-transforming gene-1 (pttg1) and an approximate 5-fold up-regulation of a structural homologue of erythroid differentiation regulator-1 (edr1l-EST). Transfection of HEK293 cells with a Wld(S)-eGFP construct produced similar changes in mRNA levels for these and seven other genes, suggesting that regulation of gene expression by Wld(S) is conserved across different species, including humans. Similar modifications in mRNA levels were mimicked for some of the genes (including pttg1) by 1 mm nicotinamide adenine dinucleotide (NAD). However, expression levels of most other genes (including edr1l-EST) were insensitive to NAD. Pttg1(-/-) mutant mice showed no neuroprotective phenotype. Transfection of HEK293 cells with constructs comprising either full-length Nmnat-1 or the truncated Ube4b fragment (N70-Ube4b) demonstrated selective effects of Nmnat-1 (down-regulated pttg1) and N70-Ube4b (up-regulated edr1l-EST) on mRNA levels. Similar changes in pttg1 and edr1l-EST were observed in the mouse NSC34 motor neuron-like cell line following stable transfection with Wld(S). Together, the data suggest that the Wld(S) protein co-regulates expression of a consistent subset of genes in both mouse neurons and human cells. Targeting Wld(S)-induced gene expression may lead to novel therapies for neurodegeneration induced by trauma or by disease in humans.

The slow Wallerian degeneration protein, WldS, binds directly to VCP/p97 and partially redistributes it within the nucleus.

Slow Wallerian degeneration (Wld(S)) mutant mice express a chimeric nuclear protein that protects sick or injured axons from degeneration. The C-terminal region, derived from NAD(+) synthesizing enzyme Nmnat1, is reported to confer neuroprotection in vitro. However, an additional role for the N-terminal 70 amino acids (N70), derived from multiubiquitination factor Ube4b, has not been excluded. In wild-type Ube4b, N70 is part of a sequence essential for ubiquitination activity but its role is not understood. We report direct binding of N70 to valosin-containing protein (VCP; p97/Cdc48), a protein with diverse cellular roles including a pivotal role in the ubiquitin proteasome system. Interaction with Wld(S) targets VCP to discrete intranuclear foci where ubiquitin epitopes can also accumulate. Wld(S) lacking its N-terminal 16 amino acids (N16) neither binds nor redistributes VCP, but continues to accumulate in intranuclear foci, targeting its intrinsic NAD(+) synthesis activity to these same foci. Wild-type Ube4b also requires N16 to bind VCP, despite a more C-terminal binding site in invertebrate orthologues. We conclude that N-terminal sequences of Wld(S) protein influence the intranuclear location of both ubiquitin proteasome and NAD(+) synthesis machinery and that an evolutionary recent sequence mediates binding of mammalian Ube4b to VCP.

A rat model of slow Wallerian degeneration (WldS) with improved preservation of neuromuscular synapses.

The slow Wallerian degeneration phenotype, Wld(S), which delays Wallerian degeneration and axon pathology for several weeks, has so far been studied only in mice. A rat model would have several advantages. First, rats model some human disorders better than mice. Second, the larger body size of rats facilitates more complex surgical manipulations. Third, rats provide a greater yield of tissue for primary culture and biochemical investigations. We generated transgenic Wld(S) rats expressing the Ube4b/Nmnat1 chimeric gene in the central and peripheral nervous system. As in Wld(S) mice, their axons survive up to 3 weeks after transection and remain functional for at least 1 week. Protection of axotomized nerve terminals is stronger than in mice, particularly in one line, where 95-100% of neuromuscular junctions remained intact and functional after 5 days. Furthermore, the loss of synaptic phenotype with age was much less in rats than in mice. Thus, the slow Wallerian degeneration phenotype can be transferred to another mammalian species and synapses may be more effectively preserved after axotomy in species with longer axons.

Neuroprotection after transient global cerebral ischemia in Wld(s) mutant mice.

The Wld(s) mouse mutant demonstrates a remarkable phenotype of delayed axonal and synaptic degeneration after nerve lesion. In this study, the authors tested the hypothesis that expression of Wld protein is neuroprotective in an in vivo mouse model of global cerebral ischemia. This model is associated with selective neuronal degeneration in specific brain regions such as the caudate nucleus and CA2 hippocampal pyramidal cell layer. The extent of neuronal damage was quantified in Wld(s) compared to wild-type mice after an identical episode of global cerebral ischemia. The results demonstrated a significant and marked reduction in the extent of neuronal damage in Wld(s) as compared to wild-type C57Bl/6 mice. In the caudate nucleus, Wld expression significantly reduced the percentage of ischemic neuronal damage after global ischemia (Wld(s), 27.7 +/- 16.8%; wild-type mice, 58.7 +/- 32.3%; P = 0.036). Similarly, in the CA2 pyramidal cell layer, there was a significant reduction of neuronal damage in the Wld(s) mice as compared to wild-type mice after ischemia (Wld(s), 17.7 +/- 23.0%; wild-type mice, 41.9 +/- 28.0%; P < 0.023). Thus, these results clearly demonstrate that the Wld gene confers substantial neuroprotection after cerebral ischemia, and suggest a new role to that previously described for Wld(s).