Emanuele Cacci

In vitro neuronal and glial differentiation from embryonic or adult neural precursor cells are differently affected by chronic or acute activation of microglia.

The contribution of microglia to the modulation of neurogenesis under pathological conditions is unclear. Both pro‐ and anti‐neurogenic effects have been reported, likely reflecting the complexity of microglial activation process. We previously demonstrated that prolonged (72 hr) in vitro exposure to lipopolysaccharide (LPS) endows microglia with a potentially neuroprotective phenotype, here referred as to “chronic”. In the present study we further characterized the chronic phenotype and investigated whether it might differently regulate the properties of embryonic and adult neural precursor cells (NPC) with respect to the “acute” phenotype acquired following a single (24 hr) LPS stimulation. We show that the LPS‐dependent induction of the proinflammatory cytokines interleukin (IL)‐1α, IL‐1β, IL‐6, and tumor necrosis factor (TNF)‐α was strongly reduced after chronic stimulation of microglia, as compared with acute stimulation. Conversely, the synthesis of the anti‐inflammatory cytokine IL‐10 and the immunomodulatory prostaglandin E2 (PGE2) was still elevated or further increased, after chronic LPS exposure, as revealed by real time PCR and ELISA techniques. Acutely activated microglia, or their conditioned medium, reduced NPC survival, prevented neuronal differentiation and strongly increased glial differentiation, likely through the release of proinflammatory cytokines, whereas chronically activated microglia were permissive to neuronal differentiation and cell survival, and still supported glial differentiation. Our data suggest that, in a chronically altered environment, persistently activated microglia can display protective functions that favor rather than hinder brain repair processes.

Docosahexaenoic acid modulates inflammatory and antineurogenic functions of activated microglial cells

The complex process of microglial activation encompasses several functional activation states associated either with neurotoxic/antineurogenic or with neurotrophic/proneurogenic properties, depending mainly on the extent of activation and the nature of the activating stimuli. Several studies have demonstrated that acute exposure to the prototypical activating agent lipopolysaccharide (LPS) confers antineurogenic properties upon microglial cells. Acutely activated microglia ortheir conditioned media (CM) reduce neural stem progenitor cell (NPC) survival and prevent NPC differentiation into neurons. The present study tested the hypothesis that docosahexaenoic acid (DHA), a long‐chain polyunsatured fatty acid (L‐PUFA) with potent immunomodulatory properties, could dampen microglial proinflammatory functions and modulate their antineurogenic effect. We demonstrate that DHA dose dependently inhibits the synthesis of inflammatory products in activated microglia without inducing an alternative antiinflammatory phenotype. Among the possible DHA mechanisms of action, we propose the inhibition of p38 MAPK phosphorylation and the activation of the nuclear receptor peroxisome proliferator activated receptor (PPAR)‐γ. The attenuation of M1 proinflammatory phenotype has relevant consequences for the survival and differentiation of NPC, because DHA reverses the antineurogenic activities of conditioned media from LPS‐activated microglia. Our study identifies new relevant potentially protective and proneurogenic functions of DHA, exerted through the modulation of microglial functions, that could be exploited to sustain or promote neuroregenerative processes in damaged/aged brain.

Neural stem cells at the crossroads: MMPs may tell the way

Matrix metalloproteinases (MMP) constitute a family of more than 25 enzymes which process a large number of pericellular substrates. Even though initially reported to have an ability to degrade almost all of the extracellular components, MMP are now known to play roles which are not limited to the breakdown of extracellular barriers. In fact, MMPs regulate many biological processes, being involved not only in physiological events, but also in pathological processes. Strikingly, MMPs have been found to be involved in the physiology of the Central Nervous System (CNS), taking part and playing important roles in several processes such as repair and ontogeny, as well as in pathological conditions of the CNS. Initially considered to be a static structure, lacking regenerative capability, the CNS has been considered for a long time to be a system without renewal capabilities. Recently, the discovery of constant neural replacement has changed our way of considering the adult brain, and the finding of the existence of neural stem cells has opened the way to exciting and fascinating perspectives of the CNS. So, could MMPs, originally found during metamorphosis in tadpoles, and now amazingly identified in the CNS, have something to do in neuronal function? In this review we take into consideration the possible roles of two metalloproteinases, MMP-2 and MMP-9, also called gelatinases, in controlling several aspects of CNS organization, including the modulation of neural stem cell properties and the differentiation of their progeny, both under normal and pathophysiological conditions.

Pro-gliogenic effect of IL-1α in the differentiation of embryonic neural precursor cells in vitro

J. Neurochem. (2010) 113, 1060–1072.

Hepatocyte Growth Factor Stimulates Cell Motility in Cultures of the Striatal Progenitor Cells ST14A

Hepatocyte growth factor/scatter factor (HGF/SF) is a growth factor with pleiotropic effects on different cell types. It acts as a mitogen and motility factor for many epithelial cells. HGF/SF and its receptor Met are present in the developing and adult mammalian brain and control neuritogenesis of sympathetic and sensory neurons. We report that the striatal progenitor ST14A cells express the Met receptor, which is activated after binding with HGF/SF. The interaction between Met and HGF/SF triggers a signaling cascade that leads to increased levels of c‐Jun, c‐Fos, and Egr‐1 proteins, in agreement with data reported on the signaling events evoked by HGF in other cellular types. We also studied the effects of the exposure of ST14A cells to HGF/SF. By time‐lapse photography, we observed that a 24‐hr treatment with 50 ng/ml HGF/SF induced modification in cell morphology, with a decrease in cell‐cell interactions and increase of cell motility. In contrast, no effect on cell proliferation was observed. To investigate which intracellular pathway is primarily involved we used PD98059 and LY294002, two specific inhibitors of mitogen‐activated protein kinase/extracellular signal‐regulated kinase (MAP‐kinase/ERK‐kinase) and phosphoinositide 3‐OH kinase (PI3‐K), respectively. Cell motility in HGF/SF treated cultures was inhibited by LY294002 but not by PD98059, suggesting that PI3‐K plays a key role in mediating the HGF/SF‐induced dissociation of ST14A cells. Previous evidence of HGF stimulation of motility in nervous system has been obtained on postmitotic neurons, which have already acquired their specificity. Data reported here of a motogenic response of ST14A cell line, which displays properties of neuronal progenitors, seem of interest because they suggest that HGF could play a role in very early steps of neurogenesis.

Prolonged lifespan with enhanced exploratory behavior in mice overexpressing the oxidized nucleoside triphosphatase hMTH1

The contribution that oxidative damage to DNA and/or RNA makes to the aging process remains undefined. In this study, we used the hMTH1‐Tg mouse model to investigate how oxidative damage to nucleic acids affects aging. hMTH1‐Tg mice express high levels of the hMTH1 hydrolase that degrades 8‐oxodGTP and 8‐oxoGTP and excludes 8‐oxoguanine from both DNA and RNA. Compared to wild‐type animals, hMTH1‐overexpressing mice have significantly lower steady‐state levels of 8‐oxoguanine in both nuclear and mitochondrial DNA of several organs, including the brain. hMTH1 overexpression prevents the age‐dependent accumulation of DNA 8‐oxoguanine that occurs in wild‐type mice. These lower levels of oxidized guanines are associated with increased longevity and hMTH1‐Tg animals live significantly longer than their wild‐type littermates. Neither lipid oxidation nor overall antioxidant status is significantly affected by hMTH1 overexpression. At the cellular level, neurospheres derived from adult hMTH1‐Tg neural progenitor cells display increased proliferative capacity and primary fibroblasts from hMTH1‐Tg embryos do not undergo overt senescence in vitro. The significantly lower levels of oxidized DNA/RNA in transgenic animals are associated with behavioral changes. These mice show reduced anxiety and enhanced investigation of environmental and social cues. Longevity conferred by overexpression of a single nucleotide hydrolase in hMTH1‐Tg animals is an example of lifespan extension associated with healthy aging. It provides a link between aging and oxidative damage to nucleic acids.

Non steroidal anti-inflammatory drugs and neurogenesis in the adult mammalian brain

Non steroidal anti-inflammatory drugs (NSAIDs) are therapeutic agents of first choice for the treatment of inflammation, pain, and fever. Neuroscience research of the last decades has pointed out the important role of inflammation in the pathogenesis of several brain disorders, and epidemiological and experimental evidence has suggested a beneficial role of NSAIDs in both chronic and acute neuropathologies. More recently NSAIDs have gained further attention as potential tools to enhance neuroregenerative processes in the adult mammalian brain. The rational behind their use arises from the notion that inflammatory processes that accompany brain damage would exert a major detrimental effect on endogenous neurogenesis. However, inflammation and glial responses to acute or chronic injuries constitute a complex and multifaceted process by which, besides potentially harmful and cytotoxic activities, beneficial responses can be initiated in the attempt to re-establish the lost tissue integrity. The individuation of optimal timing and type of pharmacological intervention able to potentiate the beneficial aspects of inflammation rather than to suppress it as a whole, would allow the achievement of enhanced and successful regenerative responses. In the present article, we will review the current literature on the effects of NSAIDs on neurogenesis and briefly discuss the cellular or molecular mechanisms by which these drugs can modulate brain restorative processes.

Mir-23a and mir-125b regulate neural stem/progenitor cell proliferation by targeting Musashi1

Musashi1 is an RNA binding protein that controls the neural cell fate, being involved in maintaining neural progenitors in their proliferative state. In particular, its downregulation is needed for triggering early neural differentiation programs. In this study, we profiled microRNA expression during the transition from neural progenitors to differentiated astrocytes and underscored 2 upregulated microRNAs, miR-23a and miR-125b, that sinergically act to restrain Musashi1 expression, thus creating a regulatory module controlling neural progenitor proliferation.

The matrix metalloproteinase inhibitor marimastat promotes neural progenitor cell differentiation into neurons by gelatinase-independent TIMP-2-dependent mechanisms.

Metalloproteinases (MMPs) and their endogenous inhibitors (TIMPs), produced in the brain by cells of non-neural and neural origin, including neural progenitors (NPs), are emerging as regulators of nervous system development and adult brain functions. In the present study, we explored whether MMP-2, MMP-9, and TIMP-2, abundantly produced in the brain, modulate NP developmental properties. We found that treatment of NPs, isolated from the murine fetal cerebral cortex or adult subventricular zone, with the clinically tested broad-spectrum MMP inhibitor Marimastat profoundly affected the NP differentiation fate. Marimastat treatment allowed for an enrichment of our cultures in neuronal cells, inducing NPs to generate higher percentage of neurons and a lower percentage of astrocytes, possibly affecting NP commitment. Consistently with its proneurogenic effect, Marimastat early downregulated the expression of Notch target genes, such as Hes1 and Hes5. MMP-2 and MMP-9 profiling on proliferating and differentiating NPs revealed that MMP-9 was not expressed under these conditions, whereas MMP-2 increased in the medium as pro-MMP-2 (72 kDa) during differentiation; its active form (62 kDa) was not detectable by gel zymography. MMP-2 silencing or administration of recombinant active MMP-2 demonstrated that MMP-2 does not affect NP neuronal differentiation, nor it is involved in the Marimastat proneurogenic effect. We also found that TIMP-2 is expressed in NPs and increases during late differentiation, mainly as a consequence of astrocyte generation. Endogenous TIMP-2 did not modulate NP neurogenic potential; however, the proneurogenic action of Marimastat was mediated by TIMP-2, as demonstrated by silencing experiments. In conclusion, our data exclude a major involvement of MMP-2 and MMP-9 in the regulation of basal NP differentiation, but highlight the ability of TIMP-2 to act as key effector of the proneurogenic response to an inducing stimulus such as Marimastat.

Histone Methylation and microRNA-dependent Regulation of Epigenetic Activities in Neural Progenitor Self-Renewal and Differentiation

Neural stem/progenitor cell (NSPC) self-renewal and differentiation in the developing and the adult brain are controlled by extra-cellular signals and by the inherent competence of NSPCs to produce appropriate responses. Stage-dependent responsiveness of NSPCs to extrinsic cues is orchestrated at the epigenetic level. Epigenetic mechanisms such as DNA methylation, histone modifications and non-coding RNA-mediated regulation control crucial aspects of NSPC development and function, and are also implicated in pathological conditions. While their roles in the regulation of stem cell fate have been largely explored in pluripotent stem cell models, the epigenetic signature of NSPCs is also key to determine their multipotency as well as their progressive bias towards specific differentiation outcomes. Here we review recent developments in this field, focusing on the roles of histone methylation marks and the protein complexes controlling their deposition in NSPCs of the developing cerebral cortex and the adult subventricular zone. In this context, we describe how bivalent promoters, carrying antagonistic epigenetic modifications, feature during multiple steps of neural development, from neural lineage specification to neuronal differentiation. Furthermore, we discuss the emerging cross-talk between epigenetic regulators and microRNAs, and how the interplay between these different layers of regulation can finely tune the expression of genes controlling NSPC maintenance and differentiation. In particular, we highlight recent advances in the identification of astrocyte-enriched microRNAs and their function in cell fate choices of NSPCs differentiating towards glial lineages.