Caty Casas

Spinal cord injury induces endoplasmic reticulum stress with different cell‐type dependent response

The mechanisms of injury‐induced apoptosis of neurons within the spinal cord are poorly understood. In this study, we show that spinal cord injury (SCI) induces endoplasmic reticulum stress revealed by the activation of an unbalanced unfolded protein response (UPR). Using a weight‐drop contusion model of SCI, the UPR activation was characterized by a quick transient phosphorylation of alpha subunit of eukaryotic initiation factor 2 soon restored by the up‐regulation of its regulator Gadd34; an effective cleavage/activation of the ATF6α transcription factor leading to up‐regulation of the canonical UPR target genes Chop, Xbp1 and Grp78; the presence of the processing of Xbp1 mRNA indicative of inositol requiring kinase 1 activation, and a gradual accumulation of C/EBP homologous transcription factor protein (CHOP) with concomitant caspase‐12 activation. Interestingly, the subcellular distribution of CHOP was found in the nucleus of neurons and oligodendrocytes but in the cytoplasm of astrocytes. Considering the pro‐apoptotic action attributed to this transcription factor, this phenomenon might account for the different susceptibility of cell types to dye after SCI.

Valproate reduces CHOP levels and preserves oligodendrocytes and axons after spinal cord injury

Spinal cord injury (SCI) is a major cause of disability to which there are not yet effective treatments. We previously reported that degeneration of oligodendrocytes and neurons that occurs after SCI is associated with the development of endoplasmic reticulum (ER) stress and the progressive accumulation of the pro-apoptotic factor CHOP. Since following ER stress, the balance between the pro-survival chaperone BiP and CHOP drives the cell destiny, we aimed to find drugs that modulate this ratio in favour of the former. We found that valproate (VPA) induced a significant reduction of CHOP levels after ER stress in an organotypic-based culture of spinal cord in vitro. We then administered different doses of VPA to rats following spinal cord contusion, and found that the treatment caused a marked reduction of CHOP levels early after the lesion. In addition, VPA administration partially prevented cord tissue, myelin and axonal loss, and significantly increased the relative number of surviving oligodendrocytes in the damaged spinal cord. Besides, VPA-treated rats showed better recovery of the locomotor activity than vehicle-treated rats after SCI. Since VPA is a drug already in clinical use, these results open the avenue for its therapeutical use in SCI as well as in demyelinating disorders.

Autophagy, and BiP level decrease are early key events in retrograde degeneration of motoneurons

Disconnection of the axon from the soma of spinal motoneurons (MNs) leads either to a retrograde degenerative process or to a regenerative reaction, depending on the severity and the proximity to the soma of the axonal lesion. The endoplasmic reticulum (ER) is a continuous membranous network that extends from the nucleus to the entire cytoplasm of the neuronal soma, axon and dendrites. We investigated whether axonal injury is sensed by the ER and triggers the activation of protective mechanisms, such as the unfolded protein response (UPR) and autophagy. We found early (at 3 days) accumulation of beclin1, LC3II and Lamp-1, hallmarks of autophagy, in both degenerating MNs after spinal root avulsion and in non-degenerating MNs after distal nerve section, although Lamp-1 disappeared by 5 days only in the former. In contrast, only degenerating MNs presented early activation of IRE1α, revealed by an increase of the spliced isoform of Xbp1 and accumulation of ATF4 in their nucleus, two branches of the UPR, and late BiP downregulation in association with cytoskeletal and organelle disorganization. We conclude that BiP decrease is a signature of the degenerating process, as its overexpression led to an increase in MN survival after root avulsion. Besides, Bcl2 is strongly implicated in the survival pathway activated by BiP overexpression.

Selective sigma receptor agonist 2-(4-morpholinethyl)1-phenylcyclohexanecarboxylate (PRE084) promotes neuroprotection and neurite elongation through protein kinase C (PKC) signaling on motoneurons.

Neuronal loss and interruption of axonal pathways are occurring after spinal cord injury. This is initiated by the mechanical damage and propagated by secondary events that include the fast rise of glutamate concentration and the subsequent over-activation of glutamate receptors, triggering noxious processes to the cell. Excitotoxic processes are also observed in degenerative diseases that involve motoneuron loss. Sigma-1 receptors (Sig-1Rs) are expressed in the CNS and their ligands have been shown to prevent neuronal death associated to glutamate toxicity. In the present study, we used organotypic cultures of spinal cord slices and dorsal root ganglia (DRG) explants from 7-8 days old postnatal rats to assess whether the agonist of the Sig-1R, 2-(4-morpholinethyl)1-phenylcyclohexanecarboxylate (PRE084), protects the spinal cord against glutamate excitotoxicity and promotes neurite elongation. The results showed that PRE084 exerted a bell-shape dose-dependent protective response of the motoneurons, with a significant neuroprotection obtained with 10 microM PRE084. PRE084 also caused an increase in the length of neurites in both motoneurons and neurons in DRG explants. Both effects were abrogated with the addition of BD 1063, an antagonist of Sig-1R, and the use of chelerythrine, a protein kinase C (PKC) pan-inhibitor indicating that PKC is implicated in the observed effects. These results suggest the use of PRE084 as a neuroprotective agent for spinal cord damage.

Sigma receptor agonist 2-(4-morpholinethyl)1 phenylcyclohexanecarboxylate (Pre084) increases GDNF and BiP expression and promotes neuroprotection after root avulsion injury

Spinal root avulsion leads to a progressive loss of axotomized motoneurons (MNs). Nowadays, there is no effective treatment to prolong MN survival that could permit recovery as a result of delayed surgical repair. Administration of Sigma-1 receptor (Sig-1R) ligands has been reported to promote beneficial effects after several types of neural injury. In order to shed light of whether Sig-1R ligands could promote MN survival after root avulsion, L4-L5 spinal roots were unilaterally avulsed in adult rats and the Sig-1R agonist Pre084 was administered at different doses. The ventral spinal cords of the animals were studied from 3 to 21 days post-operation (DPO) by using histological, immunohistochemical, and Western blot techniques. Daily treatment with 0.25 mg/kg Pre084 significantly promoted MN survival (68% vs 43% in untreated rats) at 21 DPO, an effect that was antagonized by coadministration of BD1063, an antagonist of Sig-1R. There was a reduction in astroglial- associated immunoreactivity in rats treated with Pre084. Moreover, Pre084 produced an increase in the Sig-1R co-chaperone BiP within MNs, and an increase of GDNF expression by astrocytes in the ventral horn early after injury. Although the mechanisms promoting MN survival by Pre084 remain unclear, we hypothesize that it is mediated at least in part through the increase in these cytoprotective factors. Therefore, early application of Sig-1R agonist appears to be a promising therapy to improve MN survival after root avulsion.

Early presymptomatic cholinergic dysfunction in a murine model of amyotrophic lateral sclerosis

Sporadic and familiar amyotrophic lateral sclerosis (ALS) cases presented lower cholinergic activity than in healthy individuals in their still preserved spinal motoneurons (MNs) suggesting that cholinergic reduction might occur before MN death. To unravel how and when cholinergic function is compromised, we have analyzed the spatiotemporal expression of choline acetyltransferase (ChAT) from early presymptomatic stages of the SOD1G93A ALS mouse model by confocal immunohistochemistry. The analysis showed an early reduction in ChAT content in soma and presynaptic boutons apposed onto MNs (to 76%) as well as in cholinergic interneurons in the lumbar spinal cord of the 30‐day‐old SOD1G93A mice. Cholinergic synaptic stripping occurred simultaneously to the presence of abundant surrounding major histocompatibility complex II (MHC‐II)‐positive microglia and the accumulation of nuclear Tdp‐43 and the appearance of mild oxidative stress within MNs. Besides, there was a loss of neuronal MHC‐I expression, which is necessary for balanced synaptic stripping after axotomy. These events occurred before the selective raise of markers of denervation such as ATF3. By the same time, alterations in postsynaptic cholinergic‐related structures were also revealed with a loss of the presence of sigma‐1 receptor, a Ca2+ buffering chaperone in the postsynaptic cisternae. By 2 months of age, ChAT seemed to accumulate in the soma of MNs, and thus efferences toward Renshaw interneurons were drastically diminished. In conclusion, cholinergic dysfunction in the local circuitry of the spinal cord may be one of the earliest events in ALS etiopathogenesis.

Effect of genetic background on onset and disease progression in the SOD1-G93A model of amyotrophic lateral sclerosis

Abstract Knowledge of the potential effect of genetic background in disease models is important. The SOD1-G93A transgenic mouse is the most widely used model in amyotrophic lateral sclerosis (ALS). Since these animals show considerable variability both in the onset and the progression of the disease, this study aimed to characterize the potential differences between the two most widely used strains, C56BL/6 (B6) and B6SJL. A rotarod test was carried out to assess strength and motor coordination, while electrophysiology tests were performed to evaluate the function of upper and lower motor neurons. Survival of the animals and motor neuron loss were also studied. The results did not show any background effect regarding the rotarod test, despite the differences in the pattern of decline in central and peripheral motor conduction. The onset of motor neuron abnormalities was later in B6SJL mice, but progressed more rapidly. Lifespan was longer for B6 than for B6SJL animals. In conclusion, background differences in disease onset and progression are important. The characteristics of the strain should be taken into account in experimental design of therapeutic studies.

Analysis of FK506-mediated protection in an organotypic model of spinal cord damage: Heat shock protein 70 levels are modulated in microglial cells

Functional loss after spinal cord injuries is originated by primary and secondary injury phases whose underlying mechanisms include massive release of excitatory amino acids to cytotoxic levels that contribute to neural death. Attenuation of this excitotoxicity is a key point for improving the functional outcome after injury. One of the drugs with potential neuroprotective actions is FK506, a molecule widely used as an immunosuppressant. FK506 may exert neuroprotection via inhibition of calcineurin by binding the FKBP12, or by binding other immunophilins such as FKBP52, leading to modulation of heat shock proteins (Hsp) 90 and 70. In the present study, we used an in vitro model of organotypic culture of rat spinal cord slices to assess whether FK506 is able to protect them against glutamate excitotoxicity. The results showed that FK506 promoted a significant protective effect on the spinal cord tissue at concentrations of 50 and 100 nM. Hsp70 induction was restricted to microglial cells in spinal cord slices treated with either glutamate or FK506. In contrast, the combination of both agents led to a transient reduction in Hsp70 levels in parallel to a marked reduction in IL-1beta precursor production by glial cells. The use of geldanamycin, which promotes persistent induction of Hsp70 in these cells as well as in motoneurons, did not produce tissue neuroprotection. These observations suggest that FK506 might protect spinal cord tissue by targeting on microglial cells and that transient downregulation of Hsp70 on these cells after excitotoxicity is a relevant mechanism of action of FK506.

Drug screening of neuroprotective agents on an organotypic-based model of spinal cord excitotoxic damage.

PURPOSE Damage to segmental motoneurons and to spinal cord parenchyma cause denervation atrophy to the muscles, contributing to the chronic disability originated by spinal cord injury (SCI) and spinal motor neuron diseases. After SCI, damage is promoted by several underlying mechanisms, including release of glutamate and consequent over-activation of glutamate receptors, mainly NMDA receptors, that lead to neuronal death. Due to the lack of effective treatments for such conditions, new alternatives need to be explored. METHODS In order to perform a relatively quick and high-fidelity drug screening, we optimized a postnatal rat organotypic spinal cord culture. By using a glutamate excitotoxic model of spinal cord damage on the explants, we compared the neuroprotective efficacy of four agents: methylprednisolone, erythropoietin, riluzole and rolipram. We evaluated the number of surviving ventral motor neurons stained with the SMI32 antibody and estimated the cord tissue preservation by quantifying the amount of EthD fluorescent probe incorporated into the cells. RESULTS The best tissue protection was achieved with riluzole (98%) whereas the highest motoneuron preservation was obtained with methylprednisolone (92%). CONCLUSION The in vitro model used may serve to initiate comparative analyses of new compounds to narrow the choice for future neuroprotective agents to be tested in vivo.

Network-based proteomic approaches reveal the neurodegenerative, neuroprotective and pain-related mechanisms involved after retrograde axonal damage

Neurodegenerative processes are preceded by neuronal dysfunction and synaptic disconnection. Disconnection between spinal motoneuron (MN) soma and synaptic target leads either to a retrograde degenerative process or to a regenerative reaction, depending injury proximity among other factors. Distinguished key events associated with one or other processes may give some clues towards new therapeutical approaches based on boosting endogenous neuroprotective mechanisms. Root mechanical traction leads to retrograde MN degeneration, but share common initial molecular mechanisms with a regenerative process triggered by distal axotomy and suture. By 7 days post-injury, key molecular events starts to diverge and sign apart each destiny. We used comparative unbiased proteomics to define these signatures, coupled to a novel network-based analysis to get biological meaning. The procedure implicated the previous generation of combined topological information from manual curated 19 associated biological processes to be contrasted with the proteomic list using gene enrichment analysis tools. The novel and unexpected results suggested that motoneurodegeneration is better explained mainly by the concomitant triggering of anoikis, anti-apoptotic and neuropathic-pain related programs. In contrast, the endogenous neuroprotective mechanisms engaged after distal axotomy included specifically rather anti-anoikis and selective autophagy. Validated protein-nodes and processes are highlighted across discussion.