Integrins direct Src family kinases to regulate distinct phases of oligodendrocyte development

Specific integrins expressed on oligodendrocytes, the myelin-forming cells of the central nervous system, promote either differentiation and survival or proliferation by amplification of growth factor signaling. Here, we report that the Src family kinases (SFKs) Fyn and Lyn regulate each of these distinct integrin-driven behaviors. Fyn associates with α6β1 and is required to amplify platelet-derived growth factor survival signaling, to promote myelin membrane formation, and to switch neuregulin signaling from a phosphatidylinositol 3-kinase to a mitogen-activated protein kinase pathway (thereby changing the response from proliferation to differentiation). However, earlier in the lineage Lyn, not Fyn, is required to drive αVβ3-dependent progenitor proliferation. The two SFKs respond to integrin ligation by different mechanisms: Lyn, by increased autophosphorylation of a catalytic tyrosine; and Fyn, by reduced Csk phosphorylation of the inhibitory COOH-terminal tyrosine. These findings illustrate how different SFKs can act as effectors for specific cell responses during development within a single cell lineage, and, furthermore, provide a molecular mechanism to explain similar region-specific hypomyelination in laminin- and Fyn-deficient mice

Derivation of Enriched Oligodendrocyte Cultures and Oligodendrocyte/Neuron Myelinating Co-cultures from Post-natal Murine Tissues

Identifying the molecular mechanisms underlying OL development is not only critical to furthering our knowledge of OL biology, but also has implications for understanding the pathogenesis of demyelinating diseases such as Multiple Sclerosis (MS). Cellular development is commonly studied with primary cell culture models. Primary cell culture facilitates the evaluation of a given cell type by providing a controlled environment, free of the extraneous variables that are present in vivo. While OL cultures derived from rats have provided a vast amount of insight into OL biology, similar efforts at establishing OL cultures from mice has been met with major obstacles. Developing methods to culture murine primary OLs is imperative in order to take advantage of the available transgenic mouse lines

Investigating demyelination, efficient remyelination and remyelination failure in organotypic cerebellar slice cultures:Workflow and practical tips

Healthy myelin is essential for proper brain function. When the myelin sheath is damaged, fast saltatory impulse conduction is lost and neuronal axons become vulnerable to degeneration. Thus, regeneration of the myelin sheath by encouraging oligodendrocyte lineage cells to remyelinate the denuded axons is a promising therapeutic target for demyelinating diseases such as multiple sclerosis. Ex vivo organotypic cerebellar slice cultures are a useful model to study developmental myelination, demyelination, remyelination and remyelination failure. In these cultures, the cerebellum's three-dimensional architecture and various cell populations remain largely intact, providing a realistic and relatively cost-efficient model that can be easily manipulated by the addition of viral vectors, pharmaceuticals or (transgenic) cells to augment or replace resident cell populations. Moreover, slice cultures can be treated with lysolecithin or polyinosinic:polycytidylic acid to induce demyelination and mimic efficient as well as inefficient remyelination. It can be challenging to set up slice cultures for the first time, as in our experience, seemingly minor differences in technique and materials can make a great difference to the quality of the cultures. Therefore, this report provides an in-depth description for the generation and maintenance of ex vivo organotypic cerebellar cultures for demyelination-remyelination studies with a focus on practical tips for scientists that are new to this technique

The AMPK activator metformin improves recovery from demyelination by shifting oligodendrocyte bioenergetics and accelerating OPC differentiation

Multiple Sclerosis (MS) is a chronic disease characterized by immune-mediated destruction of myelinating oligodendroglia in the central nervous system. Loss of myelin leads to neurological dysfunction and, if myelin repair fails, neurodegeneration of the denuded axons. Virtually all treatments for MS act by suppressing immune function, but do not alter myelin repair outcomes or long-term disability. Excitingly, the diabetes drug metformin, a potent activator of the cellular “energy sensor” AMPK complex, has recently been reported to enhance recovery from demyelination. In aged mice, metformin can restore responsiveness of oligodendrocyte progenitor cells (OPCs) to pro-differentiation cues, enhancing their ability to differentiate and thus repair myelin. However, metformin’s influence on young oligodendroglia remains poorly understood. Here we investigated metformin’s effect on the temporal dynamics of differentiation and metabolism in young, healthy oligodendroglia and in oligodendroglia following myelin damage in young adult mice. Our findings reveal that metformin accelerates early stages of myelin repair following cuprizone-induced myelin damage. Metformin treatment of both isolated OPCs and oligodendrocytes altered cellular bioenergetics, but in distinct ways, suppressing oxidative phosphorylation and enhancing glycolysis in OPCs, but enhancing oxidative phosphorylation and glycolysis in both immature and mature oligodendrocytes. In addition, metformin accelerated the differentiation of OPCs to oligodendrocytes in an AMPK-dependent manner that was also dependent on metformin’s ability to modulate cell metabolism. In summary, metformin dramatically alters metabolism and accelerates oligodendroglial differentiation both in health and following myelin damage. This finding broadens our knowledge of metformin’s potential to promote myelin repair in MS and in other diseases with myelin loss or altered myelination dynamics

220th ENMC workshop: Dystroglycan and the dystroglycanopathies Naarden, The Netherlands, 27–29 May 2016

Highlights • Review of clinical phenotypes associated with the dystroglycanopathies. • Discussion of current animal models and their contribution to understanding the disease process. • New insight into the glycosylation of alpha dystroglycan and the role of LARGE. • Structural information on the LARGE glycan

β1 Integrin Maintains Integrity of the Embryonic Neocortical Stem Cell Niche

IInteractions between laminins and integrin receptors hold neural stem cells in place at the ventricular surface of embryonic brain. Transient disruption leads to abnormal stem cell divisions and permanent cortical malformation

Integrins:Versatile integrators of extracellular signals

Extracellular matrix (ECM) molecules and growth factors have a crucial role in the signalling that controls cell behaviour during development. Integrins, which are cell-surface receptors for ECM molecules, and growth factor receptors cooperate with each other to regulate this signalling by several mechanisms. In particular, direct interactions between the integrin and growth factor receptors themselves, which often occur within a single macromolecular complex, amplify signalling by mechanisms that include posttranslational modifications and integrin shape changes that are related to activation. As a result, growth factor concentrations in the physiological range, which are too low to initiate signalling alone, do so in the presence of the ECM, enabling integrins to control the time and space of growth factor signalling

Mechanisms of glial development

Glial cells comprise most of the non-neuronal cells of the brain and peripheral nervous system, and include the myelin-forming oligodendrocytes and Schwann cells, radial glia and astrocytes. Their functions are diverse and include almost every aspect of nervous system function, from the birth and death of cells to the migrations and cell-cell interactions that connect and integrate the working elements of the nervous system. Recent studies have provided exciting insights into the mechanisms that drive the conversion into a glial cell and the developmental signals that guide the behavior of these multifunctional cells. An emerging theme is the so-called glial lineage being more diverse and more plastic than was previously thought. Here, we highlight some recent insights into glial development

Contrasting effects of mitogenic growth factors on myelination in neuron-oligodendrocyte co-cultures

Mitogenic growth factors play an important role in the initial stages of oligodendrocyte development, but their roles in the process of myelination itself remain less well defined. In order to study directly the effects of different growth factors on myelination, we used a purified in vitro co-culture system with dorsal root ganglion neurons and oligodendrocytes. Extensive myelination had occurred in these cultures 14 days after oligodendrocyte precursors (OPCs) were added, with the relationship between neurite density and the percentage of oligodendrocytes forming myelin sheaths providing a robust and straightforward means of quantifying myelination. Addition of soluble neuregulin (Nrg1), a mitogen for oligodendroglial cells that also provides an axonal signal implicated in oligodendrocyte survival, increased myelination. Conversely, the OPC mitogens FGF-2 and PDGF inhibited myelination. The inhibitory effect of these mitogens was reversible, as inhibition of PDGF allowed myelination to proceed. Taken together, these data indicate that different mitogenic growth factors can regulate myelination by oligodendrocytes in addition to their well-described effects on earlier stages of oligodendroglial development. Moreover, the results highlight important differences between the growth factors