FGF2, but not EGF, Induces multiciliated ependymal cells to dedifferentiate and adopt radial glial features in vitro

Multiciliated ependymal cells form an epithelium lining most of the ventricular cavities of vertebrates brain. Although considered postmitotic and completely differentiated, ependymal cells maintain some phenotypic characteristics of neural stem cells. Thereby, under specific conditions they behave as neural stem cells, developing radial glia characteristics, and undergoing asymmetric division. Our group is searching for factors that promote dedifferentiation of ependymal cells in vitro. We developed a simple method to obtain pure cultures of non-adherent multiciliated ependymal cells from adult rats. These cultures were used to investigate the effect of FGF2 on the differentiation state and the aggregation of ependymal cells. Thus, FGF2 treated ependymal cells lose cilia and hence mobility, and after 7 days they aggregate to form irregular spheres (diameter ≥ 20-30 μm). Such changes were not observed when EFG was used instead of FGF2. To assess the specificity of FGF2 action on cell aggregation, the FGF receptor inhibitor PD166866 and an anti-FGF2 neutralizing antibody were used. In both conditions the aggregative effect of FGF2 was abolished. No cell proliferation was observed during sphere formation, at least in such experimental conditions. Spheres were analyzed by immunocytochemistry using radial glia markers. They were positive for GFAP, vimentin, BLBP and GLAST. These data suggest that FGF2 promotes the identity loss in multiciliated ependymal cells in vitro, which are transformed into cells with radial glia features.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Neuraminidase-activated microglia compromise the viability of ependymocytes

Neuraminidase (NA) is a sialidase present in the envelope/wall of some virus/bacteria responsible for brain infections, such as flu, mumps or meningitis. The intracerebroventricular injection of NA in the rat brain provokes ependymal detachment and death, and an acute inflammatory process. Although inflammation reverses, ependymal lining is not regenerated. Complement system activation within the CSF contributes to ependymal damage, but is not the only cause (Granados-Duran et al, 2016). Here we aimed to investigate if microglial activation might also play a role. For this purpose we used pure isolated ependymocytes (Grondona et al, 2013) and ventricular wall explants, which were co-cultured with microglial cells, both in basal conditions and with agents that induce microglial activation: NA, LPS, or Pam3CSK4 (synthetic lipopeptide). The viability of the ependymal cells was assessed by trypan blue exclusion. The viability of isolated ependymocytes was reduced when NA or LPS were added to the culture, compared to controls without additives. In the absence of microglia, NA or LPS did not compromise viability significantly, indicating that microglia was involved in ependymocytes death. The addition of NA to cultured explants reduced ependymocytes viability only when microglial cells were present in the culture; a similar reduction was observed when LPS or Pam3CSK4 were added. Conversely, explants cultured in the absence of microglia did not suffer a significant decrease in ependymocytes viability upon NA addition to the medium. We hypothesized that cytokines released by activated microglia, such as IL1β or TNFα, could mediate ependymocytes death. RT-PCR performed in RNA obtained from pure ependymocytes confirmed the presence of IL1β and TNFα receptors in ependymal cells. Nevertheless further experiments are required to confirm this hypothesis. We conclude that microglia activated by NA mediates, at least in part, ependymal cell death, what might be relevant for neuroinflammatory diseases mediated by NA bearing virus/bacteria.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Neuraminidase-induced neuroinflammation is largely dependent on microglial TLR4 receptor

The sialidase neuraminidase (NA) cleaves terminal sialic acid from glycoproteins and glycolipids. Among its various locations, it is present in the envelope/membrane of some bacteria/viruses (e.g. influenza virus), where it is involved in infectiveness and dispersion. The injection of NA within the brain lateral ventricle represents a model of acute sterile inflammation. The relevance of the toll-like receptors TLR2 and TLR4 (particularly those in microglial cells) in such process was investigated using mouse strains deficient in these receptors. In septofimbria and hypothalamus, IBA1-positive and IL-1β-positive cell counts increased after NA injection in wild type (WT) mice. In TLR4-/- mice such increases were largely abolished, while only slightly affected in TLR2-/- mice. Similarly, the NA-induced expression of IL-1β, TNFα and IL-6 (evaluated by qPCR) was completely blocked in TLR4-/- mice, and only partially reduced in TLR2-/- mice. Microglia was isolated from the three mouse strains and exposed to NA or to specific TLR2 and TLR4 agonists (Pam3CSK4 and LPS respectively) in vitro. NA induced a cytokine response (IL-1β, TNFα and IL-6) in WT microglia, but was unable to do so in TLR4-/- microglia; TLR2 deficiency partially affected the NA-induced microglia response. To investigate if such response of microglial cells to NA was dependent on the sialidase activity of the enzyme, WT microglia was exposed in vitro to NA previously inactivated with heat, or inhibited with two different sialidase inhibitors (oseltamivir phosphate and N-acetyl-2,3-dehydro-2-deoxyneuraminic acid). In all cases, NA- induced microglia activation was dependent on the intact sialidase activity of NA. Therefore, we conclude that NA is able to directly activate microglial cells, mostly through TLR4 receptor and due to its sialidase activity. Accordingly, the inflammatory reaction induced by NA in vivo is partially dependent on TLR2, while TLR4 plays a crucial role.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

Long-term priming of hypothalamic microglia is associated with energy balance disturbances under diet-induced obesity

Exposure of microglia to an inflammatory environment may lead to their priming and exacerbated response to future inflammatory stimuli. Here we aimed to explore hypothalamic microglia priming and its consequences on energy balance regulation. A model of intracerebroventricular administration of neuraminidase (NA, which is present in various pathogens such as influenza virus) was used to induce acute neuroinflammation. Evidences of primed microglia were observed 3 months after NA injection, namely (1) a heightened response of microglia located in the hypothalamic arcuate nucleus after an in vivo inflammatory challenge (high fat diet [HFD] feeding for 10 days), and (2) an enhanced response of microglia isolated from NA-treated mice and challenged in vitro to LPS. On the other hand, the consequences of a previous NA-induced neuroinflammation were further evaluated in an alternative inflammatory and hypercaloric scenario, such as the obesity generated by continued HDF feeding. Compared with sham-injected mice, NA-treated mice showed increased food intake and, surprisingly, reduced body weight. Besides, NA-treated mice had enhanced microgliosis (evidenced by increased number and reactive morphology of microglia) and a reduced population of POMC neurons in the basal hypothalamus. Thus, a single acute neuroinflammatory event may elicit a sustained state of priming in microglial cells, and in particular those located in the hypothalamus, with consequences in hypothalamic cytoarchitecture and its regulatory function upon nutritional challenges.Ministerio de Economía, Industria yCompetitividad, Gobierno de España, Grant/Award Number: SAF2017-83645; Ministeriode Educación y Formación Profesional; Funding for open access charge: Universidadde Málaga/CBU

Microbial neuraminidase induces TLR4-dependent long-term immune priming in the brain

Innate immune memory explains the plasticity of immune responses after repeated immune stimulation, leading to either enhanced or suppressed immune responses. This process has been extensively reported in peripheral immune cells and also, although modestly, in the brain. Here we explored two relevant aspects of brain immune priming: its persistence over time and its dependence on TLR receptors. For this purpose, we used an experimental paradigm consisting in applying two inflammatory stimuli three months apart. Wild type, toll-like receptor (TLR) 4 and TLR2 mutant strains were used. The priming stimulus was the intracerebroventricular injection of neuraminidase (an enzyme that is present in various pathogens able to provoke brain infections), which triggers an acute inflammatory process in the brain. The second stimulus was the intraperitoneal injection of lipopolysaccharide (a TLR4 ligand) or Pam3CSK4 (a TLR2 ligand). One day after the second inflammatory challenge the immune response in the brain was examined. In wild type mice, microglial and astroglial density, as well as the expression of 4 out of 5 pro-inflammatory genes studied (TNFα, IL1β, Gal-3, and NLRP3), were increased in mice that received the double stimulus compared to those exposed only to the second one, which were initially injected with saline instead of neuraminidase. Such enhanced response suggests immune training in the brain, which lasts at least 3 months. On the other hand, TLR2 mutants under the same experimental design displayed an enhanced immune response quite similar to that of wild type mice. However, in TLR4 mutant mice the response after the second immune challenge was largely dampened, indicating the pivotal role of this receptor in the establishment of immune priming. Our results demonstrate that neuraminidase-induced inflammation primes an enhanced immune response in the brain to a subsequent immune challenge, immune training that endures and that is largely dependent on TLR4 receptor

Anxiety and mild microglial activation in the amygdala two weeks after NA-induced neuroinflammation

A single injection of neuraminidase (NA) within the cerebral ventricles (ICV) triggers an acute neuroinflammation. Neurological complications or behavioral alterations have been associated to neuroinflammation. While some of these symptoms decline with time along with inflammation, the possibility of long-term sequelae should be considered. Thus, we aimed to explore if NA-induced neuroinflammation provokes behavioral or neurological disturbances at medium (2 weeks) and long (10 weeks) term. Rats were ICV injected with NA or saline. First, neurological alterations of the sensorimotor reflexes were not found, suggesting that NA does not cause disturbances in major brain functions. While the open field test revealed normal locomotor capacity in the animals injected with NA, however the evaluation of specific behaviors (rearing and rearing with support) pointed out an increased anxiety state 2 weeks after NA administration, but not at long term (10 weeks). A histological study of brain areas related to emotions (amygdala) and stress response (hypothalamic PVN) revealed no significant differences in the number of microglia or astrocytes. Nevertheless, the morphological analysis of microglial cells demonstrated that, in the amygdala of NA injected rats, microglia presented a morphology consistent with a slightly activated state. Such morphological change, which was evident 2 weeks after NA injection, was virtually reverted 10 weeks post-ICV. These results point out that NA injected ICV may cause anxiety in the medium term (while not affecting other functions like sensorimotor functions or the locomotor capacity), a behavioral alteration that is transient and that concurs with a mild inflammation, evidenced by the overexpression of certain genes and, more notably, by the morphological bias of microglial cells located in the amygdala towards an activated profile.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech

A model of neuroinflammation and demyelination by intracerebroventricular injection of microbial neuraminidase

Comunicación en forma de poster al congresoNeuraminidase from Clostridium perfringens, which cleaves terminal sialic acid from carbohydrate chains, was injected in the lateral ventricle of rats. It diffused in the ipsilateral ventricle, the third ventricle, and also towards the periventricular brain parenchyma. Soon after, the complement system activated, and some ependymal cells detached and died. In the affected zones, there was an increased expression of GFAP in astrocytes, IBA1 in microglia, and ICAM1 in the endothelial cells of blood vessels. Cytokines, such as IL1β secreted by activated macrophages and microglia, provoked the extravasation of leucocytes from about 4 h post-injection. The main sources of cells were large venules located in the choroid plexus, the meninges and the subependyma around the foramen interventricularis. Invading cells arrived orderly: first neutrophils, then macrophage-monocytes, and last lymphocytes (mainly CD8α-positive T-lymphocytes). Leucocytes invaded the ventricle and the meninges, and also penetrated the brain parenchyma, sometimes passing through the ependyma and the glia limitans. As a result, some myelinated tracts suffered vacuolar degeneration, being the stria medullaris consistently affected. Oligodendrocytes in the damaged tracts were not affected. Vacuolated myelin recovered with time. Thus, the intracerebroventricular injection of neuraminidase may represent a novel reversible animal model to study experimental neuroinflammation and myelin vacuolization.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech. Ministerio de Ciencia e Innovación, SAF2010-19087; Junta de Andalucía, Consejería de Sanidad, SAS 08-0029; Junta de Andalucía, Proyecto de excelencia P-11-CVI-07637

Chronic ethanol induces morpohological changes on hippocampal microglia, which are reverted by pharmacological blockade of faah with urb597

Tipo de presentación: PósterHere, we evaluated the pharmacological effects of fatty-acid amide-hydrolase (FAAH) inhibitor URB597 (0.3 mg/kg), oleoylethanolamide (OEA, 10 mg/kg), arachidonoylethanolamide (AEA, 10 mg/kg), the CB1 receptor agonist ACEA (3 mg/kg) and the CB2 receptor agonist JWH133 (0.2 mg/kg) administered for 5 days in a rat model of sub-chronic (2 weeks) ethanol diet (11% v/v) exposure. As a result of these trials, URB597 turned to be the most effective treatment. Contrary to ethanol, URB597 reduced the mRNA levels of Iba-1, Tnfα, IL-6 and monocyte chemoattractant protein-1 (MCP-1/CCL2), as well as the number of cells expressing GFAP or iNOS. Moreover, URB597 effects on hippocampal immune system were accompanied by changes in short and long-term visual recognition memory. Microglial morphometric analysis pointed out significant changes after ethanol exposure, suggesting that microglial cell morphology is closely related to ethanol-induced neuroinflammation. Ethanol provoked changes in fractal dimension, lacunarity, density, roughness, cell area and cell perimeter, which explain a decreased complexity of branches and increased cell surface irregularities. Such changes may represent a chronic activation state of microglia. In addition, ethanol effects on the microglial morphological parameters density and fractal dimension were reverted by URB597. Thus, this FAAH inhibitor was able to counteract the sub-chronic ethanol-induced morphological changes of microglia, resulting in a more compact and increased branch complexity, which apparently relate to a less activated state. Therefore, these morphometric parameters are sensitive and valuable tools to evaluate the chronic activation of microglia by ethanol and its pharmacological blockade.Universidad de Málaga. Campus de Excelencia Internacional Andalucía Tech. RETICS Red de Trastornos Adictivos, ISCIII, MINECO, ERDF-EU (RD16/0017/0001; PI17/02026; SAF2017-83645R). Plan Nacional sobre Drogas, MSCBS (PNSD2015/047; PND2017/043). Proyectos de investigación de excelencia, Junta de Andalucía (P11-CVI-07637)

Complement system activation contributes to the ependymal damage induced by microbial neuraminidase

Background In the rat brain, a single intracerebroventricular injection of neuraminidase from Clostridium perfringens induces ependymal detachment and death. This injury occurs before the infiltration of inflammatory blood cells; some reports implicate the complement system as a cause of these injuries. Here, we set out to test the role of complement. Methods The assembly of the complement membrane attack complex on the ependymal epithelium of rats injected with neuraminidase was analyzed by immunohistochemistry. Complement activation, triggered by neuraminidase, and the participation of different activation pathways were analyzed by Western blot. In vitro studies used primary cultures of ependymal cells and explants of the septal ventricular wall. In these models, ependymal cells were exposed to neuraminidase in the presence or absence of complement, and their viability was assessed by observing beating of cilia or by trypan blue staining. The role of complement in ependymal damage induced by neuraminidase was analyzed in vivo in two rat models of complement blockade: systemic inhibition of C5 by using a function blocking antibody and testing in C6-deficient rats. Results The complement membrane attack complex immunolocalized on the ependymal surface in rats injected intracerebroventricularly with neuraminidase. C3 activation fragments were found in serum and cerebrospinal fluid of rats treated with neuraminidase, suggesting that neuraminidase itself activates complement. In ventricular wall explants and isolated ependymal cells, treatment with neuraminidase alone induced ependymal cell death; however, the addition of complement caused increased cell death and disorganization of the ependymal epithelium. In rats treated with anti-C5 and in C6-deficient rats, intracerebroventricular injection of neuraminidase provoked reduced ependymal alterations compared to non-treated or control rats. Immunohistochemistry confirmed the absence of membrane attack complex on the ependymal surfaces of neuraminidase-exposed rats treated with anti-C5 or deficient in C6. Conclusions These results demonstrate that the complement system contributes to ependymal damage and death caused by neuraminidase. However, neuraminidase alone can induce moderate ependymal damage without the aid of complement

Microglial activation by microbial neuraminidase through TLR2 and TLR4 receptors.

Neuraminidase (NA) is a sialidase present, among various locations, in the envelope/membrane of some bacteria/viruses (e.g., influenza virus), and is involved in infectiveness and/or dispersion. The administration of NA within the brain lateral ventricle represents a model of acute sterile inflammation. The relevance of the Toll-like receptors TLR2 and TLR4 (particularly those in microglial cells) in such process was investigated. Mouse strains deficient in either TLR2 (TLR2-/-) or TLR4 (TLR4-/-) were used. NA was injected in the lateral ventricle, and the inflammatory reaction was studied by immunohistochemistry (IBA1 and IL-1β) and qPCR (cytokine response). Also, microglia was isolated from those strains and in vitro stimulated with NA, or with TLR2/TLR4 agonists as positive controls (P3C and LPS respectively). The relevance of the sialidase activity of NA was investigated by stimulating microglia with heat-inactivated NA, or with native NA in the presence of sialidase inhibitors (oseltamivir phosphate and N-acetyl-2,3-dehydro-2-deoxyneuraminic acid). In septofimbria and hypothalamus, IBA1-positive and IL-1β-positive cell counts increased after NA injection in wild type (WT) mice. In TLR4-/- mice, such increases were largely abolished, while were only slightly diminished in TLR2-/- mice. Similarly, the NA-induced expression of IL-1β, TNFα, and IL-6 was completely blocked in TLR4-/- mice, and only partially reduced in TLR2-/- mice. In isolated cultured microglia, NA induced a cytokine response (IL-1β, TNFα, and IL-6) in WT microglia, but was unable to do so in TLR4-/- microglia; TLR2 deficiency partially affected the NA-induced microglial response. When WT microglia was exposed in vitro to heat-inactivated NA or to native NA along with sialidase inhibitors, the NA-induced microglia activation was almost completely abrogated. NA is able to directly activate microglial cells, and it does so mostly acting through the TLR4 receptor, while TLR2 has a secondary role. Accordingly, the inflammatory reaction induced by NA in vivo is partially dependent on TLR2, while TLR4 plays a crucial role. Also, the sialidase activity of NA is critical for microglial activation. These results highlight the relevance of microbial NA in the neuroinflammation provoked by NA-bearing pathogens and the possibility of targeting its sialidase activity to ameliorate its impact