Post-Translational Tubulin Modifications in Differentiated Human Neural Stem Cells

The tubulin protein fulfills a variety of cellular functions that range from chromosomal separation to locomotion. The functional diversity of tubulin is achieved through the expression of specific tubulin isotypes in different cell types or developmental time periods. Post-translational modifications (PTMs) of tubulin also are vital for specific intracellular tasks, such as binding and recruiting motor proteins. In neurons, the isotypic expression profile for tubulin is well characterized, and the importance of PTMs for proper neuronal function has gained recent attention due to their implication in neurodegenerative disorders. In contrast, the role of tubulin specializations in the specification of neural cell fate has received minimal attention and studies of tubulin PTMs and isotypes in neuroglia such as astrocytes are relatively few. To bridge this knowledge gap, we undertook an analysis of PTMs in neurons and astrocytes derived from the federally approved H9 hESC-derived human neural stem cell (hNSC) line. In hNSCs, basal cells can be directed to assume neural fate as neurons or astrocytes by specifying different media growth conditions. Immunocytochemical methods, fluorescent antibody probes, and confocal microscopy facilitated image acquisition of fluorescent signals from class III β- tubulin (βIII-tubulin), acetylated tubulin, and polyglutamylated tubulin. Fluorescent probe intensities were assessed with the EBImage package for the statistical programming language R and compared using Student's t-tests. Qualitative analysis indicated that βIII-tubulin, acetylated tubulin, and polyglutamylated tubulin were expressed to some degree in basal hNSCs and their media-differentiated hNSC neuronal and astroglial progeny. In media-differentiated hNSC astrocyte progeny, quantification and statistical analysis of fluorescence probe intensity showed that acetylated tubulin/ βIII-tubulin ratios were greater than the ratio for polyglutamylated tubulin/ βIII-tubulin. These findings represent a snapshot of the dynamic and varied changes tubulin expression profile during the specification of neural cell fate. Results imply that investigations of tubulin PTMs have the potential to advance our understanding of the generation and regeneration of nervous tissue.

Metabolism navigates neural cell fate in development, aging and neurodegeneration

ABSTRACT An uninterrupted energy supply is critical for the optimal functioning of all our organs, and in this regard the human brain is particularly energy dependent. The study of energy metabolic pathways is a major focus within neuroscience research, which is supported by genetic defects in the oxidative phosphorylation mechanism often contributing towards neurodevelopmental disorders and changes in glucose metabolism presenting as a hallmark feature in age-dependent neurodegenerative disorders. However, as recent studies have illuminated roles of cellular metabolism that span far beyond mere energetics, it would be valuable to first comprehend the physiological involvement of metabolic pathways in neural cell fate and function, and to subsequently reconstruct their impact on diseases of the brain. In this Review, we first discuss recent evidence that implies metabolism as a master regulator of cell identity during neural development. Additionally, we examine the cell type-dependent metabolic states present in the adult brain. As metabolic states have been studied extensively as crucial regulators of malignant transformation in cancer, we reveal how knowledge gained from the field of cancer has aided our understanding in how metabolism likewise controls neural fate determination and stability by directly wiring into the cellular epigenetic landscape. We further summarize research pertaining to the interplay between metabolic alterations and neurodevelopmental and psychiatric disorders, and expose how an improved understanding of metabolic cell fate control might assist in the development of new concepts to combat age-dependent neurodegenerative diseases, particularly Alzheimer's disease.

Dynamic profiling and functional interpretation of histone lysine crotonylation and lactylation during neural development

Metabolites such as crotonyl-CoA and lactyl-CoA influence gene expression through covalently modifying histones, known as histone lysine crotonylation (Kcr) and histone lysine lactylation (Kla). However, we do not know their dynamic changes, biological functions and associations with histone lysine acetylation (Kac) in vivo and during development. Here, we profile H3K9ac, H3K9cr and H3K18la in the developing telencephalon, and find that genome-wide alterations of these histone marks collaboratively regulate transcriptome remodelling to favour neural differentiation. We also demonstrate that global histone Kcr and Kla levels are not affected by transcription inhibition. Importantly, we identify HDAC1-3 as novel erasers of H3K18la and furtherly show that a selective inhibitor of HDAC1-3, MS-275 promotes transcriptional programs associated with neural cell fate decisions via H3K18la. Taken together, our results uncover the interplays between histone lysine acylations to regulate gene expression and the differentiation-promoting functions of histone Kcr and Kla during development.

Chromatin-mediated translational control is essential for neural cell fate specification

Neural cell fate specification is a multistep process in which stem cells undergo sequential changes in states, giving rise to particular lineages such as neurons and astrocytes. This process is accompanied by dynamic changes of chromatin and in transcription, thereby orchestrating lineage-specific gene expression programs. A pressing question is how these events are interconnected to sculpt cell fate. We show that altered chromatin due to loss of the chromatin remodeler Chd5 causes neural stem cell activation to occur ahead of time. This premature activation is accompanied by transcriptional derepression of ribosomal subunits, enhanced ribosome biogenesis, and increased translation. These untimely events deregulate cell fate decisions, culminating in the generation of excessive numbers of astrocytes at the expense of neurons. By monitoring the proneural factor Mash1, we further show that translational control is crucial for appropriate execution of cell fate specification, thereby providing new insight into the interplay between transcription and translation at the initial stages of neurogenesis.

Bcl6 promotes neurogenic conversion through transcriptional repression of multiple self-renewal-promoting extrinsic pathways

SummaryDuring neurogenesis, progenitors switch from self-renewal to differentiation through the interplay of intrinsic and extrinsic cues, but how these are integrated remains poorly understood. Here we combine whole genome transcriptional and epigenetic analyses with in vivo functional studies and show that Bcl6, a transcriptional repressor known to promote neurogenesis, acts as a key driver of the neurogenic transition through direct silencing of a selective repertoire of genes belonging to multiple extrinsic pathways promoting self-renewal, most strikingly the Wnt pathway. At the molecular level, Bcl6 acts through both generic and pathway-specific mechanisms. Our data identify a molecular logic by which a single cell-intrinsic factor ensures robustness of neural cell fate transition by decreasing responsiveness to the extrinsic pathways that favor self-renewal.

Smek1/2 is a nuclear chaperone and cofactor for cleaved Wnt receptor Ryk, regulating cortical neurogenesis

The receptor-like tyrosine kinase (Ryk), a Wnt receptor, is important for cell fate determination during corticogenesis. During neuronal differentiation, the Ryk intracellular domain (ICD) is cleaved. Cleavage of Ryk and nuclear translocation of Ryk-ICD are required for neuronal differentiation. However, the mechanism of translocation and how it regulates neuronal differentiation remain unclear. Here, we identified Smek1 and Smek2 as Ryk-ICD partners that regulate its nuclear localization and function together with Ryk-ICD in the nucleus through chromatin recruitment and gene transcription regulation. Smek1/2 double knockout mice displayed pronounced defects in the production of cortical neurons, especially interneurons, while the neural stem cell population increased. In addition, both Smek and Ryk-ICD bound to the Dlx1/2 intergenic regulator element and were involved in its transcriptional regulation. These findings demonstrate a mechanism of the Ryk signaling pathway in which Smek1/2 and Ryk-ICD work together to mediate neural cell fate during corticogenesis.