Neural stem cells (NSCs) transplantation enhances plasticity and restores functions in neurological diseases. Therapeutic benefits of NSCs are due to their ability to replace the lost neurons and glial cells and also secreting a wide array of free and membrane-bound bioactive molecules that can reduce the hostility of diseased microenvironment, resolve inflammation, and rescue damaged neural cells. Membrane-encircled spherical nanostructures that are collectively known as extracellular vesicles (EVs) contain mRNA, miRNA, lipids, and specific proteins that affect different biological processes in cells located nearby or at far distances. Using EVs as an alternative non-cell-based therapy has gained huge attention, and developing methods for large-scale production of EVs is of great clinical importance. Here, we describe an efficient method to yield significant quantity of EVs from human NSCs that are expanded under free floating neurosphere assay culture system. Using the neurosphere assay in bioreactors under GMP-compliant conditions can result in scalable NSC-EVs required for human trials.

The neurosphere assay is the most widely used in vitro tool to determine the proliferative and differentiation potential of adult neural precursor cells in rodents. Although originally developed for, and predominantly applied to, the growth of embryonic and adult subventricular zone-derived stem cells, hippocampal neurospheres are now routinely cultured by many laboratories. As hippocampal neurospheres are fewer in number, on average smaller in size, and more slowly growing than their ventricular counterparts, the methodology traditionally used to isolate and culture neurospheres from the subventricular zone is not optimal for hippocampal neurosphere growth. Here, we provide a detailed description of an optimized protocol for the microdissection, dissociation, and neurosphere generation from adult hippocampal dentate gyrus tissue. We also outline the protocols required to perform downstream passaging, differentiation, and immunohistological determination of the multipotentiality of hippocampal neurospheres.

Neural precursor cells (NPCs) are a renewable cell source that can proliferate and expand for long periods of time and give rise to the main neural cell types of the central nervous system (CNS). Establishing simple and reproducible growth culture conditions is of great importance to study the biology of NPCs and to understand the molecular basis of their behavior in healthy and diseased conditions.Here, we describe a simple free-floating , serum-free culture condition, known as the neurosphere assay, which is the most commonly used method for the isolation and expansion of NPCs harvested from the adult and fetal CNS. This culture system will result in large numbers of undifferentiated NPC progenies that represents a useful cell source for many in vitro and in vivo applications.

Proper regulation of neurogenesis, the process by which new neurons are generated from neural stem and progenitor cells (NS/PCs), is essential for embryonic brain development and adult brain function. The transcription regulator Patz1 is ubiquitously expressed in early mouse embryos and has a key role in embryonic stem cell maintenance. At later stages, the detection of Patz1 expression mainly in the developing brain suggests a specific involvement of Patz1 in neurogenesis. To address this point, we first got insights in Patz1 expression profile in different brain territories at both embryonic and postnatal stages, evidencing a general decreasing trend with respect to time. Then, we performed in vivo and ex vivo analysis of Patz1-knockout mice, focusing on the ventricular and subventricular zone, where we confirmed Patz1 enrichment through the analysis of public RNA-seq datasets. Both embryos and adults showed a significant reduction in the number of Patz1-null NS/PCs, as well as of their self-renewal capability, compared to controls. Consistently, molecular analysis revealed the downregulation of stemness markers in NS/PCs derived from Patz1-null mice. Overall, these data demonstrate the requirement of Patz1 for NS/PC maintenance and proliferation, suggesting new roles for this key transcription factor specifically in brain development and plasticity, with possible implications for neurodegenerative disorders and glial brain tumors.

Until very recently, distance education, including digital science labs, served a rather small portion of postsecondary students in the United States and many other countries. This situation has, however, dramatically changed in 2020 in the wake of the COVID-19 pandemic, which forced colleges to rapidly transit from face-to-face instructions to online classes. Here, we report the development of an interactive simulator that is freely available on the web (http://neurosphere.cos.northeastern.edu/) for teaching lab classes in developmental biology. This simulator is based on cellular automata models of neural-stem-cell-driven tissue growth in the neurosphere assay. By modifying model parameters, users can explore the role in tissue growth of several developmental mechanisms, such as regulation of mitosis or apoptotic cell death by contact inhibition. Besides providing an instantaneous animation of the simulated development of neurospheres, the Neurosphere Simulator tool offers also the possibility to download data for detailed analysis. The simulator function is complemented by a tutorial that introduces students to computational modeling of developmental processes.

The discovery of neural stem cells (NSCs) in the mammalian brain has raised many expectations as these unique cells might recapitulate different neurological diseases, including brain tumors, both from a functional and molecular perspective. Proper in vitro culturing of NSCs has emerged as a critical methodological issue, given that it should preserve the in vivo features of NSCs, with particular emphasis on cell heterogeneity. At the same time, the methodology for NSC culturing should allow the production of large amounts of cells to be exploited not only for prospective clinical applications but also for drug screening. Direct in vitro selection of NSCs and, very recently, cancer stem cells (CSCs) by means of defined serum-free conditions represents the most reliable methodology to obtain long-term expanding SC lines. Here we describe the methods currently employed to enrich for NSCs/CSCs based on the neurosphere assay (NSA) and their adaptation to specific assays for testing the efficacy of neuroactive compounds.

The neurosphere assay is a powerful in vitro system for studying stem/progenitor-cell-driven tissue growth. By employing a stochastic cellular automata model, we simulated the development of tumorous neurospheres in response to transformation of a randomly selected progenitor cell into a brain tumor stem cell. Simulated tumorous neurospheres were distinguished from normal neurospheres by their size, which exceeded that of normal neurospheres typically manifold. A decisive factor that determined whether brain tumor stem cells gave rise to tumorous neurospheres was their ability to escape encapsulation by neighboring cells, which suppressed mitotic activity through contact inhibition. In our simulations, the likelihood of tumorigenesis was strongly negatively correlated with the developmental maturity of the neurospheres in which the transformation of a progenitor cell into a brain tumor stem cell was induced. This likelihood was furthermore modulated by the probability of the progeny of dividing cells to undergo cell death. In developmentally immature neurospheres, the number of normal neurospheres, relative to the number of tumorous neurospheres, increased with increasing cell death probability. Markedly, in developmentally mature neurospheres the opposite effect was observed. This dichotomous effect of cell death on simulated tumor progression provides theoretical support for the seemingly paradoxical finding made by other authors in experimental studies that anti-cancer therapies based on induction of apoptosis may both promote and suppress tumor growth.

Neural stem and progenitor cells isolated from the central nervous system form, under specific culture conditions, clonal cell clusters known as neurospheres. The neurosphere assay has proven to be a powerful in vitro system to study the behavior of such cells and the development of their progeny. However, the theory of neurosphere growth has remained poorly understood. To overcome this limitation, we have, in the present paper, developed a cellular automata model, with which we examined the effects of proliferative potential, contact inhibition, cell death, and clearance of dead cells on growth rate, final size, and composition of neurospheres. Simulations based on this model indicated that the proliferative potential of the founder cell and its progenitors has a major influence on neurosphere size. On the other hand, contact inhibition of proliferation limits the final size, and reduces the growth rate, of neurospheres. The effect of this inhibition is particularly dramatic when a stem cell becomes encapsulated by differentiated or other non-proliferating cells, thereby suppressing any further mitotic division - despite the existing proliferative potential of the stem cell. Conversely, clearance of dead cells through phagocytosis is predicted to accelerate growth by reducing contact inhibition. A surprising prediction derived from our model is that cell death, while resulting in a decrease in growth rate and final size of neurospheres, increases the degree of differentiation of neurosphere cells. It is likely that the cellular automata model developed as part of the present investigation is applicable to the study of tissue growth in a wide range of systems.

Reptiles and birds have been highlighted as excellent experimental models for the study of developmental biology; however, due to technical limitations in cellular analysis, dynamics of neural stem/progenitor cells of these animals remain unclear. In this chapter, we introduce the protocols for neurosphere culture and ex ovo embryonic culture of developing reptilian and avian embryos, which are modified from the method originally established for rodent embryos. Applications of these techniques provide powerful strategies for the study of comparative neural development of amniotes.

BACKGROUND: Natural products from lichens are widely investigated for their biological properties, yet their potential as central nervous system (CNS) therapeutic agents is less explored.
OBJECTIVE: The present study investigated the neuroactive properties of selected lichen compounds (atranorin, perlatolic acid, physodic acid and usnic acid), for their neurotrophic, neurogenic and acetylcholine esterase (AChE) activities.
METHODS: Neurotrophic activity (neurite outgrowth) was determined using murine neuroblastoma Neuro2A cells. A MTT assay was performed to assess the cytotoxicity of compounds at optimum neurotrophic activity. Neuro2A cells treated with neurotrophic lichen compounds were used for RT-PCR to evaluate the induction of genes that code for the neurotrophic markers BDNF and NGF. Immunoblotting was used to assess acetyl H3 and H4 levels, the epigenetic markers associated with neurotrophic and/or neurogenic activity. The neurogenic property of the compounds was determined using murine hippocampal primary cultures. AChE inhibition activity was performed using a modified Ellman\'s esterase method.
RESULTS: Lichen compounds atranorin, perlatolic acid, physodic acid and (+)-usnic acid showed neurotrophic activity in a preliminary cell-based screening based on Neuro2A neurite outgrowth. Except for usnic acid, no cytotoxic effects were observed for the two depsides (atranorin and perlatolic acid) and the alkyl depsidone (physodic acid). Perlatolic acid appears to be promising, as it also exhibited AChE inhibition activity and potent proneurogenic activity. The neurotrophic lichen compounds (atranorin, perlatolic acid, physodic acid) modulated the gene expression of BDNF and NGF. In addition, perlatolic acid showed increased protein levels of acetyl H3 and H4 in Neuro2A cells.
CONCLUSIONS: These lichen depsides and depsidones showed neuroactive properties in vitro (Neuro2A cells) and ex vivo (primary neural stem or progenitor cells), suggesting their potential to treat CNS disorders.