progenitor cells

Gene regulatory mechanisms of neocortex development and evolution

The neocortex is considered to be the seat of higher cognitive functions in humans. During its evolution, most notably in humans, the neocortex has undergone considerable expansion, which is reflected by an increase in the number of neurons. Neocortical neurons are generated during development by neural stem and progenitor cells. Epigenetic mechanisms play a pivotal role in orchestrating the behaviour of stem cells during development. We are interested in the mechanisms that regulate gene expression in neural stem cells, which have implications for our understanding of neocortex development and evolution, neural stem cell regulation and neurodevelopmental disorders.

Clonal analysis at single cell level helps to understand neural crest development

Recent research on the neural crest has revealed the multipotency and plasticity of nerve-associated Schwann cell precursors, which can differentiate into diverse cell types, including parasympathetic neurons, neuroendocrine cells, and mesenchymal stem cells. These findings challenge the traditional view of peripheral nerves, highlighting their role as niches for migratory progenitor cells that contribute to tissue formation and regeneration.

Modeling human brain development and disease: the role of primary cilia

Neurodevelopmental disorders (NDDs) impose a global burden, affecting an increasing number of individuals. While some causative genes have been identified, understanding the human-specific mechanisms involved in these disorders remains limited. Traditional gene-driven approaches for modeling brain diseases have failed to capture the diverse and convergent mechanisms at play. Centrosomes and cilia act as intermediaries between environmental and intrinsic signals, regulating cellular behavior. Mutations or dosage variations disrupting their function have been linked to brain formation deficits, highlighting their importance, yet their precise contributions remain largely unknown. Hence, we aim to investigate whether the centrosome/cilia axis is crucial for brain development and serves as a hub for human-specific mechanisms disrupted in NDDs. Towards this direction, we first demonstrated species-specific and cell-type-specific differences in the cilia-genes expression during mouse and human corticogenesis. Then, to dissect their role, we provoked their ectopic overexpression or silencing in the developing mouse cortex or in human brain organoids. Our findings suggest that cilia genes manipulation alters both the numbers and the position of NPCs and neurons in the developing cortex. Interestingly, primary cilium morphology is disrupted, as we find changes in their length, orientation and number that lead to disruption of the apical belt and altered delamination profiles during development. Our results give insight into the role of primary cilia in human cortical development and address fundamental questions regarding the diversity and convergence of gene function in development and disease manifestation. It has the potential to uncover novel pharmacological targets, facilitate personalized medicine, and improve the lives of individuals affected by NDDs through targeted cilia-based therapies.

Cellular and genetic mechanisms of cerebral cortex folding

One of the most prominent features of the human brain is the fabulous size of the cerebral cortex and its intricate folding, both of which emerge during development. Over the last few years, work from my lab has shown that specific cellular and genetic mechanisms play central roles in cortex folding, particularly linked to neural stem and progenitor cells. Key mechanisms include high rates of neurogenesis, high abundance of basal Radial Glia Cells (bRGCs), and neuron migration, all of which are intertwined during development. We have also shown that primary cortical folds follow highly stereotyped patterns, defined by a spatial-temporal protomap of gene expression within germinal layers of the developing cortex. I will present recent findings from my laboratory revealing novel cellular and genetic mechanisms that regulate cortex expansion and folding. We have uncovered the contribution of epigenetic regulation to the establishment of the cortex folding protomap, modulating the expression levels of key transcription factors that control progenitor cell proliferation and cortex folding. At the single cell level, we have identified an unprecedented diversity of cortical progenitor cell classes in the ferret and human embryonic cortex. These are differentially enriched in gyrus versus sulcus regions and establish parallel cell lineages, not observed in mouse. Our findings show that genetic and epigenetic mechanisms in gyrencephalic species diversify cortical progenitor cell types and implement parallel cell linages, driving the expansion of neurogenesis and patterning cerebral cortex folds.

Integration of 3D human stem cell models derived from post-mortem tissue and statistical genomics to guide schizophrenia therapeutic development

Schizophrenia is a neuropsychiatric disorder characterized by positive symptoms (such as hallucinations and delusions), negative symptoms (such as avolition and withdrawal) and cognitive dysfunction1. Schizophrenia is highly heritable, and genetic studies are playing a pivotal role in identifying potential biomarkers and causal disease mechanisms with the hope of informing new treatments. Genome-wide association studies (GWAS) identified nearly 270 loci with a high statistical association with schizophrenia risk; however each locus confers only a small increase in risk therefore it is difficult to translate these findings into understanding disease biology that can lead to treatments. Induced pluripotent stem cell (iPSC) models are a tractable system to translate genetic findings and interrogate mechanisms of pathogenesis. Mounting research with patient-derived iPSCs has proposed several neurodevelopmental pathways altered in SCZ, such as neural progenitor cell (NPC) proliferation, imbalanced differentiation of excitatory and inhibitory cortical neurons. However, it is unclear what exactly these iPS models recapitulate, how potential perturbations of early brain development translates into illness in adults and how iPS models that represent fetal stages can be utilized to further drug development efforts to treat adult illness. I will present the largest transcriptome analysis of post-mortem caudate nucleus in schizophrenia where we discovered that decreased presynaptic DRD2 autoregulation is the causal dopamine risk factor for schizophrenia (Benjamin et al, Nature Neuroscience 2022 https://doi.org/10.1038/s41593-022-01182-7). We developed stem cell models from a subset of the postmortem cohort to better understand the molecular underpinnings of human psychiatric disorders (Sawada et al, Stem Cell Research 2020). We established a method for the differentiation of iPS cells into ventral forebrain organoids and performed single cell RNAseq and cellular phenotyping. To our knowledge, this is the first study to evaluate iPSC models of SZ from the same individuals with postmortem tissue. Our study establishes that striatal neurons in the patients with SCZ carry abnormalities that originated during early brain development. Differentiation of inhibitory neurons is accelerated whereas excitatory neuronal development is delayed, implicating an excitation and inhibition (E-I) imbalance during early brain development in SCZ. We found a significant overlap of genes upregulated in the inhibitory neurons in SCZ organoids with upregulated genes in postmortem caudate tissues from patients with SCZ compared with control individuals, including the donors of our iPS cell cohort. Altogether, we demonstrate that ventral forebrain organoids derived from postmortem tissue of individuals with schizophrenia recapitulate perturbed striatal gene expression dynamics of the donors’ brains (Sawada et al, biorxiv 2022 https://doi.org/10.1101/2022.05.26.493589).

Pro-regenerative functions of microglia in demyelinating diseases

Our goal is to understand why myelin repair fails in multiple sclerosis and to develop regenerative medicines for the nervous system. A central obstacle for progress in this area has been the complex biology underlying the response to CNS injury. Acute CNS damage is followed by a multicellular response that encompasses different cell types and spans different scales. Currently, we do not understand which factors determines lesion recovery. Failure of inflammation to resolve is a key underlying reason of poor regeneration, and one focus is therefore on the biology of microglia during de- and remyelination, and their cross talk to other cells, in particular oligodendrocytes and the progenitor cells. In addition, we are exploring the link between lipid metabolism and inflammation, and its role in the regulation of regeneration. I will report about our recent progress in our understanding of how microglia promote regeneration in the CNS.

Modulation of oligodendrocyte development and myelination by voltage-gated Ca++ channels

The oligodendrocyte generates CNS myelin, which is essential for normal nervous system function. Thus, investigating the regulatory and signaling mechanisms that control its differentiation and the production of myelin is relevant to our understanding of brain development and of adult pathologies such as multiple sclerosis. We have recently established that the activity of voltage-gated Ca++ channels is crucial for the adequate migration, proliferation and maturation of oligodendrocyte progenitor cells (OPCs). Furthermore, we have found that voltage-gated Ca++ channels that function in synaptic communication between neurons also mediate synaptic signaling between neurons and OPCs. Thus, we hypothesize that voltage-gated Ca++ channels are central components of OPC-neuronal synapses and are the principal ion channels mediating activity-dependent myelination.

Epigenetic regulation of neural progenitor cells in the developing neocortex

Morphology of neural progenitor cells in neocortex development and evolution

Assembly of the neocortex

The symposium will start with Prof Song-Hai Shi who will present “Assembly of the neocortex”. Then, Dr Lynette Lim will talk about “Shared and Unique Developmental Trajectories of Cortical Inhibitory Neurons”. Dr Alfredo Molina will deal with the “Tuneable progenitor cells to build the cerebral cortex”, and Prof Tomasz Nowakowski will present “Charting the molecular 'protomap' of the human cerebral cortex using single cell genomic”.

Fate and freedom in the developing mammalian brain

While the diversity of neurons in the adult mammalian brain is staggering, these cells emerge from a seemingly limited set of progenitors during development. This begs the question of how complexity emerges from a finite number of elements during dynamic biological processes. Here, I will discuss recent work from my laboratory addressing relationships between genetic diversity and connectivity in single-cell types, and how progenitor diversity may constrain adult brain cellular states during normal and abnormal brain development.

Fate and freedom in developing neocortical circuits

During brain development, neurons are born in specialized niches and migrate to target regions where they assemble to form the circuits that underlie mammalian behaviour. During their journey, neurons follow cell-intrinsic, genetic programs transmitted by their mother cells but also environmental cues, which together drive their maturation. Here, focusing on the neocortex, I will discuss recent findings from our laboratory in which we untangle and manipulate the programs at play in progenitors and their daughter neurons to better understand the emergence of cellular diversity in the developing brain.

Cell Fate Determination in the Retina

The Cepko lab investigates the mechanisms that direct development of the central nervous system (CNS) of vertebrates, with a focus on the retina. These studies have revealed that the retina has distinct types of progenitor cells that are biased, or committed, to produce distinct types of daughter cells in terminal divisions. The gene regulatory networks that underlie these cell fate choices are being studied by analysis of both gene function and cis-regulatory networks. New methods that enable these studies have been developed, including high throughput enhancer assays and quantitative, inexpensive and sensitive multiplex in situ hybridization methods.

MYELIN PLASTICITY MEDIATED BY NMDA RECEPTORS CONTAINING GLUN3A SUBUNITS OLIGODENDROCYTE PROGENITOR CELLS

FENS Forum 2026

UNRAVELLING THE ROLE OF NEURAL PROGENITOR CELLS IN THE DEVELOPMENT OF PAEDIATRIC HIGH-GRADE GLIOMA

FENS Forum 2026

MUTATIONS IN CUL4B AFFECT NEURAL PROGENITOR CELLS IN THE DEVELOPING BRAIN

FENS Forum 2026

SURVIVAL AND MATURATION OF HUMAN NEURONAL PROGENITOR CELLS IN HUMAN CORTICAL ORGANOTYPIC SLICE CULTURES

FENS Forum 2026

THE NETWORK CONNECTIVITY ANALYSIS AS AN EVALUATION OF THE DEVELOPMENTAL PROCESS OF NEURAL CIRCUITS ON-A-CHIP GENERATED FROM HUMAN IPS CELL-DERIVED NEURAL PROGENITOR CELLS​

FENS Forum 2026

STORE-OPERATED CALCIUM ENTRY TRIGGERS THE ACTIVATION OF CAMP RESPONSE ELEMENT BINDING PROTEIN THROUGH THE CALCIUM/CALMODULIN-DEPENDENT PROTEIN KINASE PATHWAY IN HUMAN NEURAL PROGENITOR CELLS

FENS Forum 2026

INVESTIGATING THE ROLE OF THE GLUCOCORTICOID RECEPTOR IN OLIGODENDROCYTE PROGENITOR CELLS MICROGLIA INTERACTION

FENS Forum 2026

TARGETING AGE-DYSREGULATED MICRORNAS TO RESCUE OLIGODENDROCYTE PROGENITOR CELLS DURING AGING

FENS Forum 2026

DIRECT NEURONAL REPROGRAMMING OF OLIGODENDROCYTE PROGENITOR CELLS

FENS Forum 2026

Clinical grade production of large-scale neural progenitor cells (NPC) for Huntington’s disease treatment

FENS Forum 2024

Development of iPSC-derived neural progenitor cells with enhanced migration to stroke tissue and inducible ablation systems

FENS Forum 2024

Pax6 isoforms label distinct populations of cortical progenitor cells in the mouse brain

FENS Forum 2024

A mouse model to explore clonal evolution in fast-proliferating neuronal progenitor cells during early neurodevelopment

FENS Forum 2024

Neuropilin-mediated Sema 3 signaling is crucial for chick spinal cord neuroprogenitor cells to exit the cell cycle and protect early-born neurons from apoptosis

FENS Forum 2024

Novel pathways translating astrocyte-derived signalling into cell fate specification of neural progenitor cells: Relevance in neurodevelopment and neurodegeneration

FENS Forum 2024

Transplanted rat embryonic neural progenitor cells form integrated brain-like tissue in young and aged host environment

FENS Forum 2024

Unraveling the roles of oligodendrocyte progenitor cells in the development of the cortical inhibitory system

FENS Forum 2024

Fate and Cell Potential of Single Pallial Progenitor Cells

Fate potential of ventral progenitor cells during the course of neurogenesis

Injury-induced upregulation of fibronectin and BMP4 modulates the differentiation of oligodendrocyte progenitor cells into Schwann cells

"Milking": an innovative approach to investigate the properties of postnatal brain neural stem cells and to obtain oligodendrocyte progenitor cells from live experimental animals

Molecular and functional heterogeneity in dorsal and ventral oligodendrocyte progenitor cells of the mouse forebrain in response to DNA damage

Oscillations of membrane voltage recorded in human undifferentiated neurons or rat oligodendroglial progenitor cells require the activation of big-conductance K+ (BK) channels

The wild and the tamed; a comparison of the activity of postnatal brain neural stem and progenitor cells between lab and wild rodents

Viral encephalitis causes rapid transient depletion of neuronal progenitor cells and chronically alters neurogenesis in the adult mouse dentate gyrus

FENS Forum 2024