Jordi Calderó

Defective Neuromuscular Junction Organization and Postnatal Myogenesis in Mice With Severe Spinal Muscular Atrophy

A detailed pathologic analysis was performed on Smn−/−;SMN2+/+ mice as a mouse model for human type I spinal muscular atrophy (SMA). We provide new data concerning changes in the spinal cord, neuromuscular junctions and muscle cells, and in the organs of the immune system. The expression of 10 synaptic proteins was analyzed in 3-dimensionally reconstructed neuromuscular junctions by confocal microscopy. In addition to defects in postsynaptic occupancy, there was a marked reduction in calcitonin gene-related peptide and Rab3A in the presynaptic motor terminals of some, but not all, of the skeletal muscles analyzed. Defects in the organization of presynaptic nerve terminals were also detected by electron microscopy. Moreover, degenerative changes in muscle cells, defective postnatal muscle growth, and prominent muscle satellite cell apoptosis were also observed. All of these changes occurred in the absence of massive loss of spinal cord motoneurons. On the other hand, astroglia, but not microglia, increased in the ventral horn of newborn SMA mice. In skeletal muscles, the density of interstitial macrophages was significantly reduced, and monocyte chemotactic protein-1 was downregulated. These findings raise questions regarding the primary contribution of a muscle cell defect to the SMA phenotype.

Calcitonin gene-related peptide in rat spinal cord motoneurons: Subcellular distribution and changes induced by axotomy

Using light and electron microscopy, a study has been made of the changes of calcitonin gene-related peptide-like immunoreactivity in rat lumbar spinal cord motoneurons during cell body response to sciatic nerve injury. At light microscopy level, calcitonin gene-related peptide-like immunoreactivity was evaluated using an indirect immunofluorescence technique combined with Fast Blue retrograde tracing and a peroxidase-antiperoxidase procedure. The calcitonin gene-related peptide changes to sciatic nerve transection and crushing were compared. Calcitonin gene-related peptide-like immunoreactivity was transiently increased after the peripheral nerve lesion, but the response was sustained for a longer period when the peripheral nerve was transected and nerve regeneration prevented. The first changes in calcitonin gene-related peptide-like immunoreactivity were detected four days after nerve crush or transection. In animal spinal cords to which nerve crush had been applied, the maximal enhancement of immunoreactivity was found 11 days after lesion. This was followed by a gradual decline, normal levels being attained 45 days after nerve crushing. When the nerve was transected, the response was similar, but the maximal calcitonin gene-related peptide-like immunoreactivity was maintained over a period of between 11 and 30 days. As with crushing, an important decrease was observed after 45 days. The ultrastructural compartmentation of calcitonin gene-related peptide-like immunoreactivity was studied using either peroxidase-antiperoxidase method or immunogold labelling. Calcitonin gene-related peptide-like immuno-reactivity was located in restricted sacs of the Golgi complex, multivesicular bodies, small vesicles and tubulo-vesicular structures. Large, strongly labelled vesicles resembling secretory granules were also observed in neuronal bodies. Our results reveal that the increase of calcitonin gene-related peptide in motoneurons is a relevant change the cell body undergoes in response to peripheral injury. The ultrastructural location of the peptide distribution suggests specific compartmentation on tubulo-vesicular structures connected with the Golgi complex which form a network in the neuronal cytoplasm. The distribution pattern observed may be related to the sorting and delivery of calcitonin gene-related peptide to secretory vesicles.

Regulation of Motoneuronal Calcitonin Gene–related Peptide (CGRP) During Axonal Growth and Neuromuscular Synaptic Plasticity Induced by Botulinum Toxin in Rats

The aim of this study was to examine whether changes in rat motoneuronal calcitonin gene–related peptide (CGRP) can be correlated with axonal growth and plasticity of neuromuscular synapses. Nerve terminal outgrowth was induced by local paralysis with botulinum toxin. Normal adult soleus and tibialis anterior did not show detectable CGRP content at the motor endplates. Following botulinum toxin injection there was a progressive, transient and bimodal increase in CGRP in both motoneuron cell bodies which innervated poisoned muscles and their motor endplates. CGRP content was moderately increased 1 day after paralysis and, after an initial decline, reached a peak 20 days after injection. This was followed by a gradual decrease and a return to normal levels at the 200th day. CGRP changes in intoxicated endplates were less evident in the tibialis anterior than in the soleus muscle. The CGRP content in motoneurons was positively correlated with the degree of intramuscular nerve sprouting found by silver staining. In situ hybridization revealed an increase in CGRP mRNA in spinal cord motoneurons 20 days after toxin administration. We conclude that motoneurons regulate their CGRP in situations in which peripheral synapse remodelling and plasticity occur.

Lithium prevents excitotoxic cell death of motoneurons in organotypic slice cultures of spinal cord

Several studies have reported the neuroprotective effects of lithium (Li) suggesting its potential in the treatment of neurological disorders, among of them amyotrophic lateral sclerosis (ALS). Although the cause of motoneuron (MN) death in ALS remains unknown, there is evidence that glutamate-mediated excitotoxicity plays an important role. In the present study we used an organotypic culture system of chick embryo spinal cord to explore the presumptive neuroprotective effects of Li against kainate-induced excitotoxic MN death. We found that chronic treatment with Li prevented excitotoxic MN loss in a dose dependent manner and that this effect was mediated by the inhibition of glycogen synthase kinase-3beta (GSK-3beta) signaling pathway. This neuroprotective effect of Li was potentiated by a combined treatment with riluzole. Nevertheless, MNs rescued by Li displayed structural changes including accumulation of neurofilaments, disruption of the rough endoplasmic reticulum and free ribosome loss, and accumulation of large dense core vesicles and autophagic vacuoles. Accompanying these changes there was an increase in immunostaining for (a) phosphorylated neurofilaments, (b) calcitonin gene-related peptide (CGRP) and (c) the autophagic marker LC3. Chronic Li treatment also resulted in a reduction in the excitotoxin-induced rise in intracellular Ca(2+) in MNs. In contrast to the neuroprotection against excitotoxicity, Li was not able to prevent normal programmed (apoptotic) MN death in the chick embryo when chronically administered in ovo. In conclusion, these results show that although Li is able to prevent excitotoxic MN death by targeting GSK-3beta, this neuroprotective effect is associated with conspicuous cytopathological changes.

Protein retention in the endoplasmic reticulum, blockade of programmed cell death and autophagy selectively occur in spinal cord motoneurons after glutamate receptor-mediated injury

We previously showed that, in contrast to the acute administration of NMDA, chronic treatment of chick embryos from embryonic day (E) 5 to E9 with this excitotoxin rescues motoneurons (MNs) from programmed cell death. Following this protocol, MNs are also protected against later acute excitotoxic cell death. Previously, we found that MNs treated from E5 to E9 develop long-lasting changes involving vesicular trafficking and other organelle pathology similar to the abnormalities observed in certain chronic neurological diseases including amyotrophic lateral sclerosis (ALS). Here we extend these previous results by showing that protein aggregation within the endoplasmic reticulum (ER) takes place selectively in MNs as an early event of chronic excitotoxicity. Although protein aggregates do not induce appreciable MN death, they foreshadow the activation of a conspicuous autophagic response leading to long-lasting degenerative changes that causes dysfunction but not immediate cell death. Chronic early treatment with NMDA results in a transient (between E6 and E10) lack of vulnerability to undergo cell death induced by different types of stimuli. It is suggested that blockade of protein translation in stressed ER may inhibit apoptosis in NMDA-treated MNs. However, in embryos older than E12, degenerating MNs are sensitized to die after limb ablation (axotomy) and accumulate hyperphosphorylated neurofilaments. Moreover, chronic NMDA treatment does not induce the upregulation of molecular chaperones in spinal cord. These results represent a new model of glutamate receptor-mediated neurotoxicity that selectively occurs in spinal cord MNs and also demonstrate an experimental system that may be valuable for understanding the mechanisms involved in chronic MN degeneration and in certain cytological hallmarks of ALS-diseased MNs such as inclusion bodies.

Development of microglia in the chick embryo spinal cord: implications in the regulation of motoneuronal survival and death.

The role of microglia during normal development of the nervous system is still not well understood. In the present study, a chick embryo model was used to examine the development of microglia in the spinal cord and characterize their changes in response to naturally occurring and pathological death of motoneurons (MNs). The microglial response to MN axotomy and the effects of microglial activation on MN survival were also studied. We found that: 1) macrophages/microglial cells were present in the spinal cord at early developmental stages (E3) and that they were recruited after normal and induced MN apoptosis; 2) although many microglial cells were seen phagocytosing apoptotic bodies, a proportion of dying cells were devoid of engulfing microglia; 3) axotomy of mature MNs was accompanied by microglial activation in the absence of MN death; 4) excitotoxic (necrotic) MN death provoked a rapid and massive microglial recruitment with phagocytic activity; 5) lipopolysaccharide‐induced microglial activation in vivo resulted in the death of immature, but not mature, microglia; and 6) overactivation of microglia modulated the survival of mature MNs, either by killing them or by enhancing their vulnerability to die in response to a mild injury. Taken together, these observations indicate that normal microglia do not play an active role in triggering apoptosis of developing MNs. Rather, they act as phagocytes for the removal of dying cells during the process of programmed cell death.

Effects of excitatory amino acids on neuromuscular development in the chick embryo.

To investigate the presumptive role of excitatory amino acids (EAAs) in the regulation of normally occurring motoneuron (MN) death, chick embryos were treated with the glutamate receptor antagonists dizocilpine maleate and 1,2,3,4‐tetrahydro‐6‐nitro‐2,3‐dioxo‐benzo[f]quinoxaline‐7‐sulfonamide disodium. Both failed to alter the number of surviving MNs at the end of the critical period of programmed cell death. However, treatment with 3‐(2‐carboxypiperazin‐4‐yl)‐propyl‐1‐phosphonic acid, a competitive N‐methyl‐D‐aspartic acid (NMDA) receptor antagonist, was able to rescue a significant number of MNs from death. Treatment with several EAA agonists induced extensive excitotoxic lesions in the spinal cord. MN degeneration induced by excitotoxins exhibited changes characteristic of necrosis rather than apoptosis. However, when either 0.5 or 1 mg of NMDA was applied acutely on embryonic day (E) 7, about 50% of treated embryos failed to exhibit NMDA‐induced excitoxicity but rather showed a clear reduction in the number of pyknotic MNs. This apparent neuroprotective effect of NMDA was also observed in a subset of embryos chronically treated with NMDA, in which an excessive number of MNs was detected when examined on E9. Surprisingly, in the same experiment other embryos showed either normal or highly reduced MN numbers. Embryos with motoneuronal depletion induced by NMDA also showed a delayed impairment of later neuromuscular development with the appearance of degenerative changes in surviving MNs and apoptosis of skeletal muscle cells. Because some of the alterations reported here are similar to those described in MN diseases, our experimental model may be useful for gaining insights into the mechanisms that control both developmentally regulated and pathological MN death. J. Comp. Neurol. 387:73–95, 1997.

Rescue of developing spinal motoneurons from programmed cell death by the GABAA agonist muscimol acts by blockade of neuromuscular activity and increased intramuscular nerve branching

Blockade of neuromuscular activity in the chick embryo during the period of programmed cell death of motoneurons results in a complete rescue of these cells. Understanding the cellular mechanisms that mediate this counterintuitive effect is of considerable interest with respect to the regulation of motoneuron survival during development as well as for understanding why motoneurons die pathologically. Although considerable evidence supports the role of a peripheral site of action at the neuromuscular junction in mediating the rescue of motoneurons following activity blockade, some evidence also supports a role for central nervous system (CNS) neurons. For example, the rescue of motoneurons by curare has been reported to be blocked by the GABA(A) agonist muscimol via its actions on CNS neurons. We have carried out a series of studies to further investigate this interesting observation. Surprisingly, we find that: (1) muscimol blocks activity and rescues MNs in a dose-dependent manner, similar to curare; (2) muscimols effects on MN survival appear to be mediated by its action on intramuscular nerve branching, similar to curare; and (3) although muscimol acts centrally, the effects of muscimol on MN survival and axon branching are mediated peripherally at the neuromuscular junction, similar to curare. Because muscimol reduces MN depolarization these data also suggest that the depolarization of MNs by afferents is not required for promoting MN survival. Taken together, these data provide further evidence in support of a peripheral site of action of activity blockade in rescuing motoneurons from developmental cell death.

Survival and death of mature avian motoneurons in organotypic slice culture: trophic requirements for survival and different types of degeneration.

We have developed an organotypic culture technique that uses slices of chick embryo spinal cord, in which trophic requirements for long‐term survival of mature motoneurons (MNs) were studied. Slices were obtained from E16 chick embryos and maintained for up to 28 days in vitro (DIV) in a basal medium. Under these conditions, most MNs died. To promote MN survival, 14 different trophic factors were assayed. Among these 14, glial cell line‐derived neurotrophic factor (GDNF) and vascular endothelial growth factor were the most effective. GDNF was able to promote MN survival for at least 28 DIV. K+ depolarization or caspase inhibition prevented MN death but also induced degenerative‐like changes in rescued MNs. Agents that elevate cAMP levels promoted the survival of a proportion of MNs for at least 7 DIV. Examination of dying MNs revealed that, in addition to cells exhibiting a caspase‐3‐dependent apoptotic pattern, some MNs died by a caspase‐3‐independent mechanism and displayed autophagic vacuoles, an extremely convoluted nucleus, and a close association with microglia. This organotypic spinal cord slice culture may provide a convenient model for testing conditions that promote survival of mature‐like MNs that are affected in late‐onset MN disease such as amyotrophic lateral sclerosis. J. Comp. Neurol. 501:669–690, 2007.

Neuregulin-1 is concentrated in the postsynaptic subsurface cistern of C-bouton inputs to α-motoneurons and altered during motoneuron diseases

C boutons are large, cholinergic, synaptic terminals that arise from local interneurons and specifically contact spinal α‐motoneurons (MNs). C boutons characteristically display a postsynaptic specialization consisting of an endoplasmic reticulum‐related subsurface cistern (SSC) of unknown function. In the present work, by using confocal microscopy and ultrastructural immunolabeling, we demonstrate that neuregulin‐1 (NRG1) accumulates in the SSC of mouse spinal MNs. We also show that the NRG1 receptors erbB2 and erbB4 are presynaptically localized within C boutons, suggesting that NRG1‐based retrograde signaling may occur in this type of synapse. In most of the cranial nuclei, MNs display the same pattern of NRG1 distribution as that observed in spinal cord MNs. Conversely, MNs in oculomotor nuclei, which are spared in amyotrophic lateral sclerosis (ALS), lack both C boutons and SSC‐associated NRG1. NRG1 in spinal MNs is developmentally regulated and depends on the maintenance of nerve‐muscle interactions, as we show after nerve transection experiments. Changes in NRG1 in C boutons were also investigated in mouse models of MN diseases: i.e., spinal muscular atrophy (SMNΔ7) and ALS (SOD1G93A). In both models, a transient increase in NRG1 in C boutons occurs during disease progression. These data increase our understanding of the role of C boutons in MN physiology and pathology.—Gallart‐Palau, X., Tarabal, O., Casanovas, A., Sábado, J., Correa, F. J., Hereu, M., Piedrafita, L., Calderó, J., Esquerda, J. E. Neuregulin‐1 is concentrated in the postsynaptic subsurface cistern of C‐bouton inputs to α‐motoneurons and altered during motoneuron diseases. FASEB J. 28, 3618–3632 (2014). www.fasebj.org