The omentum harbors unique conditions in the peritoneal cavity to promote healing and regeneration for diaphragm muscle repair in mdx mice.

Although the primary cause of Duchenne muscular dystrophy (DMD) is a genetic mutation, the inflammatory response contributes directly to severity and exacerbation of the diaphragm muscle pathology. The omentum is a lymphoid organ with unique structural and immune functions serving as a sanctuary of hematopoietic and mesenchymal progenitors that coordinate immune responses in the peritoneal cavity. Upon activation, these progenitors expand and the organ produces large amounts of growth factors orchestrating tissue regeneration. The omentum of mdx mouse, a DMD murine model, is rich in milky spots and produces growth factors that promote diaphragm muscle regeneration. The present review summarizes the current knowledge of the omentum as an important immunologic structure and highlights its contribution to resolution of dystrophic muscle injury by providing an adequate environment for muscle regeneration, thus being a potential site for therapeutic interventions in DMD.

Omentum acts as a regulatory organ controlling skeletal muscle repair of mdx mice diaphragm.

Duchenne muscular dystrophy is a lethal X-linked muscle wasting disease due to mutations of the dystrophin gene leading to distinct susceptibility to degeneration and fibrosis among skeletal muscles. This study aims at verifying whether intense mdx diaphragm remodeling could be attributed to influences from the omentum, a lymphohematopoietic tissue rich in progenitor cells and trophic factors. Mdx omentum produces growth factors HGF and FGF and increased amounts of VEGF with pleiotropic actions upon muscular progenitors and myoblast differentiation. Histology revealed that the absence of the omentum reduced inflammation and collagen deposition in the diaphragm. The diaphragm from omentectomized mdx mice presents impaired repair with a predominance of collagen type I deposition, decreased muscle regeneration and a reduction in collagen type IV and indication of altered basal lamina integrity in the diaphragm. Omentectomy further reduced inflammatory infiltration and NFκ-B activation but a change in the pattern of muscle inflammation with low numbers of the F4/80+CD206+ M-2 macrophage subset. Although omentectomized mice had high levels of Pax7, myogenin and TNF-α, the percentage of myofibers undergoing regeneration was low thus suggesting that a lack of the omentum halts the muscle differentiation program. Such results support that omentum exerts a regulatory function inducing an inflammatory process that favors regeneration and inhibits fibrosis selectively in the diaphragm muscle thus being a potential site for therapeutic interventions in DMD.

Pattern of cardiotoxin-induced muscle remodeling in distinct TLR-4 deficient mouse strains.

Tissue damage triggers innate immune response mediated by Toll-like receptor 4 (TLR) that recognizes endogenous host danger molecules associated with cell death and tissue inflammation, although the precise role of TLR-4 signaling in muscle tissue repair is still uncertain. Previously, we observed that TLR-4 exerted a protective effect preventing excessive muscular damage induced by Bothrops jararacussu crude venom. This study aimed to evaluate the involvement of TLR-4 at early stages of muscular tissue remodeling in distinct mouse strains after injection of purified snake venom. Muscular injury was induced by injection of 25 µl (0.05 mg/ml) of cardiotoxin (CTX) from Naja mossambica in the gastrocnemius muscle of C3H/HeN (wild-type); C3H/HeJ mice that express a non-functional TLR-4 receptor, C57BL/6 and Tlr4 -/- (B6 background) mice. Comparing to control, Tlr4 -/- mice presented at early stages (3 DPI) of muscle injury mild inflammation with low MMP-9 activity, scarce macrophage infiltration and premature change to anti-inflammatory phenotype, low TNF-α mRNA levels and reduced myogenin expression, with low regeneration and tissue remodeling. The presence of more Ly6Cneg macrophages in Tlr4 -/- mice at 3 DPI indicates that TLR-4 may influence the differentiation into Ly6Cneg or likely affect proliferation of such cells in the muscle. The present study shows that TLR-4 deficiency and genetic background influence the outcome of muscular tissue repair in aseptic lesions and yet still maintaining some level of signaling in the TLR4-mutant mice.

The histopathological and immunological pattern of CBA mice infected with Leishmania amazonensis after treatment with pyrazole carbohydrazide derivatives.

Because there is no vaccine in clinical use, control of Leishmaniasis relies almost exclusively on chemotherapy and the conventional treatments exhibit high toxicity for patients and emerging drug resistance. Recently, we showed that oral treatment with synthetic pyrazole carbohydrazide compounds induced lower parasite load in draining lymph nodes and reduced skin lesion size without causing any toxic effects in an experimental murine infection model with Leishmania amazonensis. In this study, CBA mice were infected in the footpad with L. amazonensis and then orally treated with pyrazole carbohydrazides derivatives, such as BrNO(2), NO(2)Cl and NO(2)Br and their histopathological and immunological effects were then investigated. Epidermis and dermis had lower levels of inflammatory infiltration compared to the infected untreated control mice. In the dermis of treated animals, the numbers of vacuolated macrophages containing intracellular parasites were far lower than in infected untreated animals. In addition to dermal macrophages, we also observed a mixed inflammatory infiltrate containing lymphocytes and granulocyte cells. Lower numbers of B cells (B220+) and T lymphocytes (CD3+) were identified in the lesions of treated mice compared with the untreated, infected mice. In draining lymph node cells, the number of T lymphocytes (CD3+) was decreased, and the numbers of B cells (CD19+) and CD8+ T cells were increased in infected mice, when compared with the non-infected control group. In additional, we have shown that infected treated and untreated lymph node cells had similar levels of TGF-ß and IFN-γ mRNA expression, whereas IL-4 was expressed at a lower level in the treated group. Increased levels of the specific anti-Leishmania IgG2a or IgG3 antibody subclass were observed in NO(2)Cl or BrNO(2)-treated group, respectively. Overall, our experimental findings suggest that pyrazole carbohydrazides exert modulation of IL-4 expression and B cell levels; however, further evaluation is required to determine the optimal treatment regime.

Persistent activation of omentum influences the pattern of muscular lesion in the mdx diaphragm.

The mdx (X chromosome-linked muscular dystrophy) mouse develops a multi-staged disorder characterized by muscle degeneration and reactive fibrosis. Skeletal muscles of mdx mice are not equally susceptible to degeneration. The aim of this study was to verify whether the intense remodeling of the mdx diaphragm could be attributed to influences from the peritoneal microenvironment and omentum, a lymphohematopoietic tissue rich in progenitor cells and trophic factors. At ages corresponding to increased muscular regeneration (12 weeks) and activation of fibrosis (24 weeks), the mdx omentum exhibited (1) morphological and functional characteristics of activation with enlarged milk-spots, an accumulation of CD4(+), CD8(+) and CD19(+)B220(+) B lymphocytes; (2) the formation of clusters positive for proliferating cell nuclear antigen, mainly in B220(+)-rich areas organized in a follicular structure with a germinative center without any challenge by external antigen inducers; (3) clusters with cells positive for fibroblast growth factor-2, numerous Sca-1(+)CD3(-)CD19(-)Mac-1(-) progenitor cells and increased CD4(+), CD8(+) and CD3(+)NK1.1(+) cells in the peritoneal cavity. Omentectomy reduced areas with F4/80(+) inflammatory infiltrate the activity of matrix metalloproteases 9 and 2, collagen deposition and areas with regenerating myofibers in the diaphragm. Thus, persistent activation of the omentum influences the pattern of inflammation and regeneration of the mdx diaphragm partly via the activation of progenitor cells and the production of growth factors that influence the physiopathology of the muscular tissue remodeling.

Animal models applied to acute-on-chronic liver failure: Are new models required to understand the human condition?

The liver is a multifaceted organ; its location and detoxifying function expose this organ to countless injuries. Acute-on-chronic failure liver (ACLF) is a severe syndrome that affects the liver due to acute decompensation in patients with chronic liver disease. An infection environment, ascites, increased liver enzymes and prothrombin time, encephalopathy and fast-evolving multiorgan failure, leading to death, usually accompany this. The pathophysiology remains poorly understand. In this context, animal models become a very useful tool in this regard, as understanding; the disease may be helpful in developing novel therapeutic methodologies for ACLF. However, although animal models display several similarities to the human condition, they do not represent all ACLF manifestations, resulting in significant challenges. An initial liver cirrhosis framework followed by the induction of an acute decompensation by administering lipopolysaccharide and D-GaIN, potentiating liver damage supports the methodologies applied to induce experimental ACLF. The entire methodology has been described mostly for rats. Nevertheless, a quick PubMed database search indicates about 30 studies concerning ACFL models and over 1000 regarding acute liver failure models. These findings demonstrate the clear need to establish easily reproducible ACFL models to elucidate questions about this quickly established and often fatal syndrome.

Immunological Tolerance in Liver Transplant Recipients: Putative Involvement of Neuroendocrine-Immune Interactions.

The transplantation world changed significantly following the introduction of immunosuppressants, with millions of people saved. Several physicians have noted that liver recipients that do not take their medication for different reasons became tolerant regarding kidney, heart, and lung transplantations at higher frequencies. Most studies have attempted to explain this phenomenon through unique immunological mechanisms and the fact that the hepatic environment is continuously exposed to high levels of pathogen-associated molecular patterns (PAMPs) or non-pathogenic microorganism-associated molecular patterns (MAMPs) from commensal flora. These components are highly inflammatory in the periphery but tolerated in the liver as part of the normal components that arrive via the hepatic portal vein. These immunological mechanisms are discussed herein based on current evidence, although we hypothesize the participation of neuroendocrine-immune pathways, which have played a relevant role in autoimmune diseases. Cells found in the liver present receptors for several cytokines, hormones, peptides, and neurotransmitters that would allow for system crosstalk. Furthermore, the liver is innervated by the autonomic system and may, thus, be influenced by the parasympathetic and sympathetic systems. This review therefore seeks to discuss classical immunological hepatic tolerance mechanisms and hypothesizes the possible participation of the neuroendocrine-immune system based on the current literature.

Role of Regulatory T Cells in Skeletal Muscle Regeneration: A Systematic Review.

Muscle injuries are frequent in individuals with genetic myopathies and in athletes. Skeletal muscle regeneration depends on the activation and differentiation of satellite cells present in the basal lamina of muscle fibers. The skeletal muscle environment is critical for repair, metabolic and homeostatic function. Regulatory T cells (Treg) residing within skeletal muscle comprise a distinct and special cell population that modifies the inflammatory environment by secreting cytokines and amphiregulin, an epidermal growth factor receptor (EGFR) ligand that acts directly upon satellite cells, promoting tissue regeneration. This systematic review summarizes the current knowledge regarding the role of Treg in muscle repair and discusses their therapeutic potential in skeletal muscle injuries. A bibliographic search was carried out using the terms Treg and muscle regeneration and repair, covering all articles up to April 2021 indexed in the PubMed and EMBASE databases. The search included only published original research in human and experimental animal models, with further data analysis based on the PICO methodology, following PRISMA definitions and Cochrane guidelines.

Persistent mdx diaphragm alterations are accompanied by increased expression and activity of calcium and muscle-specific proteins.

The mdx mouse model of Duchenne Muscular Dystrophy (DMD) presents sarcolemma instability and develops a mild multi-stage dystrophinopathy characterized by intense myonecrosis with inflammatory infiltrate at 4-weeks; muscular regeneration at 12-weeks and persistent fibrosis onwards. Mdx diaphragm muscle has a more severe phenotype with structural and functional deterioration that closely resembles the diaphragm impairment responsible for DMD human patients' morbidity. Herein, we compared calcium deposits, activity of calcium-related proteases, and expression of muscle-specific proteins in mdx diaphragm at 4-weeks and 12-weeks. We found increased calcium deposits mainly at 12-weeks, concomitant with high activity of calpains and matrix metalloprotease-9, but decreased expression of Myh4 (Myhc IIb) and Atp2a1 (SERCA1), and high expression of the myogenic regulatory factors Myod1 and Myog. Our results suggest that increased calcium deposits and persistent activity of calcium dependent proteases throughout the disease are involved in the degeneration and regeneration processes in the mdx diaphragm.

Anti-inflammatory activity of Eugenia punicifolia extract on muscular lesion of mdx dystrophic mice.

Eugenia punicifolia known as "pedra-ume caá" is a shrub largely distributed in the Amazon region popularly used in decoctions or infusions as a natural therapeutic agent, which can interfere on cholinergic nicotinic neurotransmission. This work aimed to investigate a putative anti-inflammatory effect of dichloromethane fraction of E. punicifolia extract (Ep-CM) in the muscular lesion of mdx dystrophic mice, considering that activation of cholinergic mechanisms mitigates inflammation. A polymer containing the Ep-CM was implanted in mdx gastrocnemius muscle before onset of myonecrosis for local slow and gradual release of bioactive compounds and mice sacrificed 7 days or 9 weeks after surgery. Comparing to control muscle, treatment did not alter choline acetyltransferase and acetylcholinesterase enzymatic activities, but decreased metaloproteases-9 and -2 activities and levels of tumor necrosis factor α and NFκB transcription factor. In addition, treatment also reduced levels of bioactive IL-1ß form and cleaved caspase-3, related to early events of cellular death and inflammatory activation and further increased myogenin expression without affecting collagen production which is associated with fibrosis. In vivo treatment of mdx dystrophic mice with Ep-CM caused significant reduction of muscular inflammation and improved skeletal muscle regeneration without inducing fibrosis.

Characteristic pattern of skeletal muscle remodelling in different mouse strains.

Muscular injury associated with local inflammatory reaction frequently occurs in sports medicine, but the individual response and capacity of regeneration vary among subjects. Inflammatory cytokines are probably implicated in activation of repair mechanisms by specifically influencing tissue microenvironment. This work aimed to compare muscle tissue repair in different mouse lineages. We used C57BL/6 and BALB/c mice genetically predisposed to either Type1 or Type2 cytokine production. The role of Type1 cytokines was also investigated in C57IFN-γ (IFNγ-KO) and C57IL-12 (IL12-KO) knockout mice. Participation of T lymphocytes was assessed in athymic BALB/c nude (nu/nu) mice. Muscular lesion was induced with bupivacaine injection in the Triceps brachii muscle. BALB/c mice showed marked collagen deposition and increased TGF-ß mRNA content, contrasting with mild fibrosis observed in C57BL/6 mice. C57-IFNγ-KO mice, exhibited pronounced fibrosis, but IL12-KO collagen deposition was similar to that of C57. Twenty-four hours after lesion, C57BL/6 and BALB/c(nu/nu) presented numerous regenerating myofibres and marked increase of metalloprotease-9 activity compared with BALB/c. These data support that skeletal muscle remodelling is greatly influenced by the genetic backgrounds, shedding light on the molecular mechanisms influencing differential muscular remodelling and tissue regeneration among individuals.

Leishmania amazonensis infection induces behavioral alterations and modulates cytokine and neurotrophin production in the murine cerebral cortex.

Neurological symptoms have been associated with Leishmania infection, however little is known about how the nervous system is affected in leishmaniasis. This work aimed to analyze parasitic load, production of cytokines/neurotrophins in the prefrontal cortex and behavioral changes in BALB/c mice infected with Leishmania amazonensis. At 2 and 4months post-infection, infected mice showed a decrease in IFN-γ, IL-1, IL-6, IL-4, IL-10 cytokines and BDNF and NGF neurotrophins in prefrontal cortex associated with increased anxiety behavior. Parasite DNA was found in brain of all animals at 4months post-infection, when the levels of IBA-1 (activated macrophage/microglia marker) and TNF-α was increased in the prefrontal cortex. However TNF-α returned to normal levels at 6months post-infection suggesting a neuroprotective mechanism.

Selective activation of α7 nicotinic acetylcholine receptor (nAChRα7) inhibits muscular degeneration in mdx dystrophic mice.

Amount evidence indicates that α7 nicotinic acetylcholine receptor (nAChRα7) activation reduces production of inflammatory mediators. This work aimed to verify the influence of endogenous nAChRα7 activation on the regulation of full-blown muscular inflammation in mdx mouse with Duchenne muscular dystrophy. We used mdx mice with 3 weeks-old at the height myonecrosis, and C57 nAChRα7(+/+) wild-type and nAChRα7(-/-) knockout mice with muscular injury induced with 60µL 0.5% bupivacaine (bp) in the gastrocnemius muscle. Pharmacological treatment included selective nAChRα7 agonist PNU282987 (0.3mg/kg and 1.0mg/kg) and the antagonist methyllycaconitine (MLA at 1.0mg/kg) injected intraperitoneally for 7 days. Selective nAChRα7 activation of mdx mice with PNU282987 reduced circulating levels of lactate dehydrogenase (LDH, a marker of cell death by necrosis) and the area of perivascular inflammatory infiltrate, and production of inflammatory mediators TNFα and metalloprotease MMP-9 activity. Conversely, PNU282987 treatment increased MMP-2 activity, an indication of muscular tissue remodeling associated with regeneration, in both mdx mice and WTα7 mice with bp-induced muscular lesion. Treatment with PNU282987 had no effect on α7KO, and MLA abolished the nAChRα7 agonist-induced anti-inflammatory effect in both mdx and WT. In conclusion, nAChRα7 activation inhibits muscular inflammation and activates tissue remodeling by increasing muscular regeneration. These effects were not accompanied with fibrosis and/or deposition of non-functional collagen. The nAChRα7 activation may be considered as a potential target for pharmacological strategies to reduce inflammation and activate mechanisms of muscular regeneration.

Implant of polymer containing pentacyclic triterpenes from Eugenia punicifolia inhibits inflammation and activates skeletal muscle remodeling.

Sustained chronic inflammation induces activation of genes involved in cellular proliferation and apoptosis, thereby causing skeletal muscle degeneration. To investigate in vitro effects of isolated pentacyclic triterpenes from Eugenia punicifolia (Ep-CM) upon signaling pathways involved in the regulation of skeletal muscle cell line proliferation, and in vivo muscular tissue remodeling. C2C12 cells were seeded on eight-well plates and [(3)H]-thymidine incorporation, TUNEL assays, mitochondria viability, zymography for matrix metalloproteases (MMPs), Western blot analysis for MAPKinase signaling pathway, NFκB activation and HMGB1 production subsequently determined under basal conditions and after Ep-CM treatment. A polymer containing Ep-CM was implanted on the volar surface of gastrocnemius muscles subjected to acute injury induced by bupivacaine for local slow and gradual release of bioactive compounds, and mice killed 4 days after surgery. Ep-CM inhibited proliferation of C2C12 myoblast cell line in a dose-dependent manner, confirmed by reduction of [(3)H]-thymidine uptake without affecting cell viability or inducing apoptosis. The cytostatic effect of Ep-CM occurred mainly via inhibition of phosphorylated extracellular signal-regulated kinase (pERK) activation and DNA synthesis, possibly inhibiting the G1 phase of the cell cycle, since Ep-CM increased pAkt and p27(kip1) but reduced Cyclin D1. Ep-CM in vitro treatment increased MMP-9 and MMP-2 activities of C2C12 myoblast cells, but reduced in vivo MMP-9 activity and acute muscular inflammation. Besides cytostatic and anti-inflammatory effects, Ep-CM pentacyclic triterpenes also contributed to degradation of basement membrane components by activating mechanisms of skeletal muscle remodeling in response to local injury.

Intranasal administration of perillyl alcohol activates peripheral and bronchus-associated immune system in vivo.

Perillyl alcohol (POH) presents antitumoral activity but clinical application is hampered by adverse effects following oral administration. This work aimed to verify the cytotoxic effect of intranasal POH administration in the histology of lung, liver, brain; the cellularity and function of peripheral and bronchoalveolar-associated immune system. C57 adult mice received 1-min inhalation with POH, vehicle 70 % ethanol or saline buffer, once (84 µg/day) or twice (164 µg/day) during five consecutive days, and were killed 72 h after treatment. Spleen, cervical and mesenteric lymph nodes were removed for (3)H-thymidine proliferation assay, leukocyte cellularity and flow cytometry analysis. Peripheral blood and bronchoalveolar lavage cells were collected to assess cellularity and immunoglobulin (IgA, IgM) levels. Intranasal POH did not alter body weight or liver, brain and lung morphology, but increased splenocyte and cervical lymph node cell proliferation, and IgM production without altering peripheral lymphocyte subsets. Treatment also increased the percentage of alveolar macrophages (83 %) and IgA-producing lymphocytes (15 %), a pattern characteristic of activated bronchoalveolar innate immune system. Intranasal administration of POH activated peripheral immune system and innate immunity of bronchus-associated lymphoid tissue, thus suggesting a possible role for POH as a chemotherapeutic drug also in pathological processes affecting the lung.

TLR4 signaling protects from excessive muscular damage induced by Bothrops jararacussu snake venom.

Immune cells and skeletal muscle express Toll-like receptors (TLRs) that participate as sensors of tissue injury triggering signals for activation of innate and adaptive immune responses. This study aimed to investigate the involvement of TLR4 in the process of skeletal muscle repair. Muscular injury was induced by injection of 0.6 mg/kg of Bothrops jararacussu snake venom in the gastrocnemius muscle of C3H/HeJ mice that express a non-functional TLR-4 receptor and C3H/HeN mice with functional receptor. TLR4-deficient mice had persistent muscular inflammation with few F4/80 macrophages at onset but increased MMP9 activity and collagen deposition during resolution of injury. Since such effect was not observed in the mouse strain with functional receptor it is concluded that TLR4 signaling exerts a protective role preventing from excessive muscular damage induced by B. jararacussu venom.

Brain sweet brain: importance of sugars for the cerebral microenvironment and tumor development.

The extracellular matrix (ECM) in the brain tissue is a complex network of glycoproteins and proteoglycans that fills the intercellular space serving as scaffolding to provide structural framework for the tissue and regulate the behavior of cells via specific receptors - integrins. There is enormous structural diversity among proteoglycans due to variation in the core protein, the number of glycosaminoglycans chains, the extent and position of sulfation. The lectican family of proteoglycans interacts with growth factors, hyaluronan and tenascin forming a complex structure that regulates neuronal plasticity and ion homeostasis around highly active neurons. In this review, we will discuss the latest insights into the roles of brain glycoproteins as modulators of cell adhesion, migration, neurite outgrowth and glial tumor invasion.

Nicotinic acetylcholine receptor activation reduces skeletal muscle inflammation of mdx mice.

Mdx mice develop an inflammatory myopathy characterized at different ages by myonecrosis with scattered inflammatory infiltrates followed by muscular regeneration and later persistent fibrosis. This work aimed to verify the putative anti-inflammatory role of nicotinic acetylcholine receptor (nAChR) in the mdx muscular lesion. Mitigation of myonecrosis and decreased TNFα production were accompanied by increased numbers of F4/80 macrophages expressing nAChRα7. In vivo treatment with nicotine attenuated muscular inflammation characterized by reduced metalloprotease MMP-9 activity, TNFα and NFkB content and increased muscular regeneration. Our data indicate that nAChR activation influences local inflammatory responses in the muscular lesion of mdx mice.

Pattern of metalloprotease activity and myofiber regeneration in skeletal muscles of mdx mice.

Matrix metalloproteases (MMPs) are key regulatory molecules in the formation, remodeling, and degradation of extracellular matrix components in both physiological and pathological processes. Skeletal muscles of mdx dystrophic mice show distinct patterns of inflammation and regeneration, suggesting that factors within the microenvironment influence the adaptive responses of muscles with predominantly slow-twitch or fast-twitch fibers. This study aimed to verify the pattern of MMP activity in gastrocnemius, soleus, and diaphragm muscles and correlate it with the regenerative capability at distinct stages of the mdx myopathy. Marked inflammation and myonecrosis was associated with increased MMP-9 activity and TNF-alpha (tumor necrosis factor-alpha) production, whereas muscle regeneration, evidenced by NCAM (neural cell adhesion molecule) expression and MMP-2 activity, varied at different stages of the disease. Soleus muscles showed a high percentage of NCAM-positive myofibers in the early stages (2 weeks) of the disease, but they appeared in the gastrocnemius muscles at 12 weeks and in the diaphragm at 24 weeks. Increased MMP-2 activity in the diaphragm throughout all stages of the disease suggests important tissue remodeling, which is probably associated with persistent inflammation. The results indicate that the microenvironment of distinct skeletal muscle may influence a particular kinetic pattern of MMP activity, which ultimately favors persistent inflammation and myofiber regeneration at different stages of the myopathy in mdx mice.

Brain sweet brain: importance of sugars for the cerebral microenvironment and tumor development / Cérebro doce cérebro: importância dos açúcares para o microambiente cerebral e o desenvolvimento tumoral

The extracellular matrix (ECM) in the brain tissue is a complex network of glycoproteins and proteoglycans that fills the intercellular space serving as scaffolding to provide structural framework for the tissue and regulate the behavior of cells via specific receptors - integrins. There is enormous structural diversity among proteoglycans due to variation in the core protein, the number of glycosaminoglycans chains, the extent and position of sulfation. The lectican family of proteoglycans interacts with growth factors, hyaluronan and tenascin forming a complex structure that regulates neuronal plasticity and ion homeostasis around highly active neurons. In this review, we will discuss the latest insights into the roles of brain glycoproteins as modulators of cell adhesion, migration, neurite outgrowth and glial tumor invasion.

A matriz extracelular (ECM) no tecido cerebral é formada por uma rede complexa de glicoproteínas e proteoglicanas que preenchem o espaço intercelular participando como estrutura de sustentação do arcabouço tecidual regulando a função celular por interações com receptores específicos - as integrinas. Existe enorme diversidade estrutural entre as proteoglicanas, devido à variação na proteína central (core), à quantidade de cadeias de glicosaminoglicanas, ao grau e posição de grupamentos sulfato na molécula. As proteoglicanas lecticanas interagem com fatores de crescimento, com hialuronana e tenascina formando uma estrutura complexa regulando a homeostase de íons e a plasticidade neuronal. Neste artigo de revisão serão apresentados dados relevantes da literatura sobre o papel das glicoproteínas no microambiente do tecido cerebral, como moduladores da neuritogênese, da adesão, migração celular e invasividade de células tumorais de origem glial.