Renata Graciele Zanon

Astrocyte reactivity influences the number of presynaptic terminals apposed to spinal motoneurons after axotomy.

Although synaptic plasticity is a widespread phenomenon, the underlying mechanisms leading to its occurrence are virtually unknown. In this sense, glial cells, especially astrocytes, may have a role in network changes of the nervous system, influencing the retraction of boutons as well as providing a proper perisynaptic environment, thereby affecting the replacement of inputs. Interestingly, the glial reaction does vary between strains of rats and mice. In this sense, we present evidence that C57BL/6J and A/J isogenic mice present different astrocyte reactivity after a peripheral lesion in vivo as well as in vitro, by analyzing primary cell cultures. Such a difference in the glial reaction has a direct influence on in vivo number of pre-synaptic terminals and on in vitro synaptogenesis.

Major histocompatability complex class I expression and glial reaction influence spinal motoneuron synaptic plasticity during the course of experimental autoimmune encephalomyelitis

Recent studies have shown that major histocompatibility complex class I (MHC I) expression directly influences the stability of nerve terminals. Also, the acute phase of experimental autoimmune encephalomyelitis (EAE) has shown a significant impact on inputs within the spinal cord. Therefore, the present work investigated the synaptic covering of motoneurons during the induction phase of disease and progressive remissions of EAE. EAE was induced in C57BL/6J mice, which were divided into four groups: normal, peak disease, first remission, and second remission. The animals were killed and their lumbar spinal cords processed for in situ hybridization (IH), immunohistochemistry, and transmission electron microscopy (TEM). The results indicated an increase in glial reaction during the peak disease. During this period, the TEM analysis showed a reduction in the synaptic covering of the motoneurons, corresponding to a reduction in synaptophysin immunolabeling and an increase in the MHC I expression. The IH analysis reinforced the immunolabeling results, revealing an increased expression of MHC I mRNA by motoneurons and nonneuronal cells during the peak disease and first remission. The results observed in both remission groups indicated a return of the terminals to make contact with the motoneuron surface. The ratio between excitatory and inhibitory inputs increased, indicating the potential for development of an excitotoxic process. In conclusion, the results presented here indicate that MHC I up‐regulation during the course of EAE correlates with the periods of synaptic plasticity induced by the infiltration of autoreactive immune cells and that synaptic plasticity decreases after recurrent peaks of inflammation. J. Comp. Neurol. 518:990–1007, 2010.

Interferon (IFN) beta treatment induces major histocompatibility complex (MHC) class I expression in the spinal cord and enhances axonal growth and motor function recovery following sciatic nerve crush in mice

R. G. Zanon, L. P. Cartarozzi, S. C. S. Victório, J. C. Moraes, J. Morari, L. A. Velloso and A. L. R. Oliveira (2010) Neuropathology and Applied Neurobiology36, 515–534
Interferon (IFN) beta treatment induces major histocompatibility complex (MHC) class I expression in the spinal cord and enhances axonal growth and motor function recovery following sciatic nerve crush in mice

Glatiramer acetate positively influences spinal motoneuron survival and synaptic plasticity after ventral root avulsion.

Avulsion of ventral roots induces degeneration of most axotomized motoneurons. At present there are no effective strategies to prevent such neuronal loss and to preserve the affected spinal circuits. Interestingly, changes in the spinal cord network also occur during the course of the experimental model of multiple sclerosis (experimental autoimmune encephalomyelitis-EAE). Glatiramer acetate (GA) significantly reduces the seriousness of the symptoms during the exacerbation of EAE. However, little is known about its effects on motoneurons. In the present study, we investigated whether GA has an influence on synapse plasticity and glial reaction after ventral root avulsion (VRA). Lewis rats were subjected to the avulsion of lumbar ventral roots and treated with GA. The animals were sacrificed after 14 days of treatment and the spinal cords processed for immunohistochemistry. A correlation between the synaptic changes and glial activation was obtained by performing immunolabeling against synaptophysin, GFAP and Iba-1. GA treatment preserved synaptophysin labeling, and significantly reduced the glial reaction in the area surrounding the axotomized motoneurons. After ventral root avulsion, GA treatment was also neuroprotective. The present results indicate that the immunomodulator GA has an influence on the stability of nerve terminals in the spinal cord, which may in turn contribute to future treatment strategies after proximal lesions to spinal motoneurons.

Spinal motoneuron synaptic plasticity after axotomy in the absence of inducible nitric oxide synthase

BackgroundAstrocytes play a major role in preserving and restoring structural and physiological integrity following injury to the nervous system. After peripheral axotomy, reactive gliosis propagates within adjacent spinal segments, influenced by the local synthesis of nitric oxide (NO). The present work investigated the importance of inducible nitric oxide synthase (iNOS) activity in acute and late glial responses after injury and in major histocompatibility complex class I (MHC I) expression and synaptic plasticity of inputs to lesioned alpha motoneurons.MethodsIn vivo analyses were carried out using C57BL/6J-iNOS knockout (iNOS-/-) and C57BL/6J mice. Glial response after axotomy, glial MHC I expression, and the effects of axotomy on synaptic contacts were measured using immunohistochemistry and transmission electron microscopy. For this purpose, 2-month-old animals were sacrificed and fixed one or two weeks after unilateral sciatic nerve transection, and spinal cord sections were incubated with antibodies against classical MHC I, GFAP (glial fibrillary acidic protein - an astroglial marker), Iba-1 (an ionized calcium binding adaptor protein and a microglial marker) or synaptophysin (a presynaptic terminal marker). Western blotting analysis of MHC I and nNOS expression one week after lesion were also performed. The data were analyzed using a two-tailed Students t test for parametric data or a two-tailed Mann-Whitney U test for nonparametric data.ResultsA statistical difference was shown with respect to astrogliosis between strains at the different time points studied. Also, MHC I expression by iNOS-/- microglial cells did not increase at one or two weeks after unilateral axotomy. There was a difference in synaptophysin expression reflecting synaptic elimination, in which iNOS-/- mice displayed a decreased number of the inputs to alpha motoneurons, in comparison to that of C57BL/6J.ConclusionThe findings herein indicate that iNOS isoform activity influences MHC I expression by microglial cells one and two weeks after axotomy. This finding was associated with differences in astrogliosis, number of presynaptic terminals and synaptic covering of alpha motoneurons after lesioning in the mutant mice.

Ultra-som contínuo no tratamento da fasciíte plantar crônica

In this study, the efficiency of continuous high-power ultrasound was assessed for plantar fasciitis treatment. Twenty two individuals were assessed, reporting pain lasting more than six months, through a functional questionnaire and visual scale for pain at the first morning load. Twenty seven feet were distributed into two groups: group 1 (stretching + ultrasound turned off) and group 2 (stretching + 2 w/cm² ultrasound). After 15 treatment sessions, an analysis of the absolute values and improvement percentages for collected variables was performed. A functional improvement was seen for both groups, with no difference between them. The analysis of the absolute values for pain intensity (at first, eighth, and last session) showed similarity between groups. The improvement percentage for 15 sessions did not present differences between both groups. That percentage was also calculated for two periods (before and after the eighth session). It was noted that the improvement percentage on all 15 sessions for group 2 (46.5%) was inferior to the percentage of the first eighth sessions for group 1 (54.6%). Thus, the high-power continuous ultrasound did not add value for function and pain; additionally, only specific stretching exercises were efficient in reducing more than 50% of the pain in chronic plantar fasciitis.

Supraorganized collagen enhances Schwann cell reactivity and organization in vitro.

We investigated the reactivity and expression of basal lamina collagen by Schwann cells (SCs) cultivated on a supraorganized bovine-derived collagen substrate. SC cultures were obtained from sciatic nerves of neonatal Sprague-Dawley rats and seeded on 24-well culture plates containing collagen substrate. The homogeneity of the cultures was evaluated with an SC marker antibody (anti-S-100). After 1 week, the cultures were fixed and processed for immunocytochemistry by using antibodies against type IV collagen, S-100 and p75NTR (pan neurotrophin receptor) and for scanning electron microscopy (SEM). Positive labeling with antibodies to the cited molecules was observed, indicating that the collagen substrate stimulates SC alignment and adhesion (collagen IV labeling - organized collagen substrate: 706.33 ± 370.86, non-organized collagen substrate: 744.00 ± 262.09; S-100 labeling - organized collagen: 3809.00 ± 120.28, non-organized collagen: 3026.00 ± 144.63, P < 0.05) and reactivity (p75NTR labeling - organized collagen: 2156.33 ± 561.78, non-organized collagen: 1424.00 ± 405.90, P < 0.05; means ± standard error of the mean in absorbance units). Cell alignment and adhesion to the substrate were confirmed by SEM analysis. The present results indicate that the collagen substrate with an aligned suprastructure, as seen by polarized light microscopy, provides an adequate scaffold for SCs, which in turn may increase the efficiency of the nerve regenerative process after in vivo repair.

Expressão do complexo de histocompatilidade principal de classe I (MHC I) no sistema nervoso central: plasticidade sináptica e regeneração

It has been recently demonstrated that the major histocompatibility complex of class I (MHC I) expressed in the central nervous system (CNS) does not only function as a molecule of the immune system, but also plays a role in the synaptic plasticity. The expression of MHC I influences the intensity and selectivity of elimination of synapses apposed to neurons that were subjected to lesion, besides influencing the reactivity of neighboring glial cells. MHC I expression and the degree of synaptic rearrangement and glial response after injury correlate with differences in the regenerative potential and functional recovery of isogenic mice strains. In this way, the new aspects regarding MHC I functions in the CNS may guide further studies aiming at searching the involvement of MCH I in neurologic disorders, as well as the development of new therapeutic strategies.Foi demonstrado recentemente que o complexo de histocompatibilidade principal de classe I (MHC I), expresso no sistema nervoso central (SNC), nao funciona somente como molecula com papel imunologico, mas tambem como parte de um mecanismo envolvido na plasticidade sinaptica. A expressao de MHC I interfere na intensidade e seletividade da retracao de sinapses em contato com neuronios que sofreram lesao e tambem influencia a reatividade das celulas gliais proximas a esses neuronios. A intensidade do rearranjo sinaptico e resposta glial apos lesao, ligadas a expressao de MHC I no SNC, repercute em diferencas na capacidade regenerativa e recuperacao funcional em linhagens de camundongos isogenicos. Dessa forma, os novos aspectos sobre a funcao do MHC I no SNC direcionam futuras pesquisas no sentido de buscar o envolvimento do MHC I em doencas neurologicas e tambem o desenvolvimento de novas estrategias terapeuticas.

MHC class I upregulation is not sufficient to rescue neonatal alpha motoneurons after peripheral axotomy

Associated with neuronal death, profound synaptic changes occur in the spinal cord during the apoptotic process triggered after axotomy in neonatal rats. With respect to this, the major histocompatibility complex of class I (MHC class I) has recently emerged as a new mechanism related to synaptic stripping and plasticity. The present study investigated the impact of upregulating MHC class I expression by treatment with beta interferon (beta INF) on motoneuron survival, synaptic plasticity and astrogliosis after neonatal sciatic nerve injury. P2 rats were subjected to unilateral axotomy followed by three days of beta INF treatment. The results were analyzed by counting Nissl stained motoneurons, immunohistochemistry (anti-synaptophysin, MHC class I, GFAP and Iba-1) and transmission electron microscopy. INF treatment induced an increased expression of MHC class I, which resulted in a stronger synaptic elimination process in the spinal cord, as seen by the synaptophysin labeling. GFAP and Iba-1 upregulation were not significantly altered by the INF treatment, displaying the same degree of enhanced reactivity as compared to the placebo group. The ultrastructural analysis showed that, apart from the overall reduction of inputs in the neuropil, no statistical differences were present when comparing the INF and placebo treated animals. Also, neuronal survival was not altered by cytokine administration. The present results provide evidence that MHC class I upregulation after neonatal injury does not change the fate of lesioned motoneurons. In this way, the lack of neurotrophic support may cause broader synaptic loss, which superposes the more subtle effects of the upregulation of MHC class I.

Interferon beta modulates major histocompatibility complex class I (MHC I) and CD3-zeta expression in PC12 cells

It has been demonstrated that the major histocompatibility complex of class I (MHC I) up regulation by exogenous treatment with interferon beta (IFNbeta) influences the glial reaction and synaptic elimination process. Therefore, the present study aimed to investigate the effects of IFNbeta treatment on the expression of MHC I, CD3-zeta (a subunit of MHC I receptor) and synaptic formation in PC12 cells, an in vitro model for studying the synaptic formation/elimination process. For this purpose, established cultures were subjected to IFNbeta (500 and 1000IU/ml) treatment for 5, 10 and 15 days. The cells were then fixed and processed for immunocytochemistry with antisera against MHC I (OX18), CD3-zeta and synaptophysin. The results were compared with control cultures only treated with basal medium. IFNbeta (500IU/ml) modulated the MHC I expression in PC12 cells, especially after 10 days of treatment. In this sense, IFNbeta induced MHC I as well as CD3-zeta up regulation. It was observed that the highest dose caused culture degeneration. Interestingly, differential regulation of MHC I was paralleled by enhancement in synaptic network remodeling. Altogether, the present data indicate that PC12 cells may be used as an in vitro model for studying MHC I modulation and synaptic plasticity. It also reinforced the role of IFNbeta on the synaptic elimination process.