Your search keyword '"Studer, M."' showing total 8 results

1. Mitochondrial regulation of adult hippocampal neurogenesis: Insights into neurological function and neurodevelopmental disorders.

Author

Bonzano S, Dallorto E, Bovetti S, Studer M, and De Marchis S

Subjects

Animals, Humans, Neural Stem Cells metabolism, Neurogenesis physiology, Neurodevelopmental Disorders metabolism, Neurodevelopmental Disorders genetics, Neurodevelopmental Disorders pathology, Neurodevelopmental Disorders physiopathology, Hippocampus metabolism, Mitochondria metabolism

Abstract

Mitochondria are essential regulators of cellular energy metabolism and play a crucial role in the maintenance and function of neuronal cells. Studies in the last decade have highlighted the importance of mitochondrial dynamics and bioenergetics in adult neurogenesis, a process that significantly influences cognitive function and brain plasticity. In this review, we examine the mechanisms by which mitochondria regulate adult neurogenesis, focusing on the impact of mitochondrial function on the behavior of neural stem/progenitor cells and the maturation and plasticity of newborn neurons in the adult mouse hippocampus. In addition, we explore the link between mitochondrial dysfunction, adult hippocampal neurogenesis and genes associated with cognitive deficits in neurodevelopmental disorders. In particular, we provide insights into how alterations in the transcriptional regulator NR2F1 affect mitochondrial dynamics and may contribute to the pathophysiology of the emerging neurodevelopmental disorder Bosch-Boonstra-Schaaf optic atrophy syndrome (BBSOAS). Understanding how genes involved in embryonic and adult neurogenesis affect mitochondrial function in neurological diseases might open new directions for therapeutic interventions aimed at boosting mitochondrial function during postnatal life., (Copyright © 2023. Published by Elsevier Inc.)

Published

2024

2. The Parkinson's-disease-associated mutation LRRK2-G2019S alters dopaminergic differentiation dynamics via NR2F1.

Author

Walter J, Bolognin S, Poovathingal SK, Magni S, Gérard D, Antony PMA, Nickels SL, Salamanca L, Berger E, Smits LM, Grzyb K, Perfeito R, Hoel F, Qing X, Ohnmacht J, Bertacchi M, Jarazo J, Ignac T, Monzel AS, Gonzalez-Cano L, Krüger R, Sauter T, Studer M, de Almeida LP, Tronstad KJ, Sinkkonen L, Skupin A, and Schwamborn JC

Subjects

Animals, Brain pathology, COUP Transcription Factor I genetics, Cell Cycle, Cell Line, Cell Proliferation, Cell Survival, Dopaminergic Neurons pathology, Female, Humans, Induced Pluripotent Stem Cells pathology, Leucine-Rich Repeat Serine-Threonine Protein Kinase-2 genetics, Male, Mice, 129 Strain, Mice, Knockout, Mutation, Neural Stem Cells pathology, Parkinson Disease genetics, Parkinson Disease pathology, Phenotype, RNA-Seq, Signal Transduction, Single-Cell Analysis, Time Factors, Mice, Brain enzymology, COUP Transcription Factor I metabolism, Dopaminergic Neurons enzymology, Induced Pluripotent Stem Cells enzymology, Leucine-Rich Repeat Serine-Threonine Protein Kinase-2 metabolism, Neural Stem Cells enzymology, Neurogenesis, Parkinson Disease enzymology

Abstract

Increasing evidence suggests that neurodevelopmental alterations might contribute to increase the susceptibility to develop neurodegenerative diseases. We investigate the occurrence of developmental abnormalities in dopaminergic neurons in a model of Parkinson's disease (PD). We monitor the differentiation of human patient-specific neuroepithelial stem cells (NESCs) into dopaminergic neurons. Using high-throughput image analyses and single-cell RNA sequencing, we observe that the PD-associated LRRK2-G2019S mutation alters the initial phase of neuronal differentiation by accelerating cell-cycle exit with a concomitant increase in cell death. We identify the NESC-specific core regulatory circuit and a molecular mechanism underlying the observed phenotypes. The expression of NR2F1, a key transcription factor involved in neurogenesis, decreases in LRRK2-G2019S NESCs, neurons, and midbrain organoids compared to controls. We also observe accelerated dopaminergic differentiation in vivo in NR2F1-deficient mouse embryos. This suggests a pathogenic mechanism involving the LRRK2-G2019S mutation, where the dynamics of dopaminergic differentiation are modified via NR2F1., Competing Interests: Declaration of interests J.C.S., J.J., and S.B. are shareholders of the spin-off company OrganoTherapeutics sarl. J.C.S. and J.J. are also partially paid by the company., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

3. COUP-TFI/Nr2f1 Orchestrates Intrinsic Neuronal Activity during Development of the Somatosensory Cortex.

Author

Del Pino I, Tocco C, Magrinelli E, Marcantoni A, Ferraguto C, Tomagra G, Bertacchi M, Alfano C, Leinekugel X, Frick A, and Studer M

Subjects

Animals, Female, Gene Expression Regulation, Developmental physiology, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Somatosensory Cortex metabolism, COUP Transcription Factor I metabolism, Neurogenesis physiology, Pyramidal Cells metabolism, Somatosensory Cortex embryology, Somatosensory Cortex growth & development

Abstract

The formation of functional cortical maps in the cerebral cortex results from a timely regulated interaction between intrinsic genetic mechanisms and electrical activity. To understand how transcriptional regulation influences network activity and neuronal excitability within the neocortex, we used mice deficient for Nr2f1 (also known as COUP-TFI), a key determinant of primary somatosensory (S1) area specification during development. We found that the cortical loss of Nr2f1 impacts on spontaneous network activity and synchronization of S1 cortex at perinatal stages. In addition, we observed alterations in the intrinsic excitability and morphological features of layer V pyramidal neurons. Accordingly, we identified distinct voltage-gated ion channels regulated by Nr2f1 that might directly influence intrinsic bioelectrical properties during critical time windows of S1 cortex specification. Altogether, our data suggest a tight link between Nr2f1 and neuronal excitability in the developmental sequence that ultimately sculpts the emergence of cortical network activity within the immature neocortex., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2020

4. The pleiotropic transcriptional regulator COUP-TFI plays multiple roles in neural development and disease.

Author

Bertacchi M, Parisot J, and Studer M

Subjects

Animals, COUP Transcription Factor I physiology, Gene Expression Regulation, Developmental genetics, Hippocampus metabolism, Humans, Neocortex metabolism, Neurodegenerative Diseases genetics, Neurodegenerative Diseases metabolism, Neurons metabolism, Receptors, Cytoplasmic and Nuclear metabolism, Transcription Factors metabolism, COUP Transcription Factor I metabolism, Neurogenesis physiology

Abstract

Transcription factors are expressed in a dynamic fashion both in time and space during brain development, and exert their roles by activating a cascade of multiple target genes. This implies that understanding the precise function of a transcription factor becomes a challenging task. In this review, we will focus on COUP-TFI (or NR2F1), a nuclear receptor belonging to the superfamily of the steroid/thyroid hormone receptors, and considered to be one of the major transcriptional regulators orchestrating cortical arealization, cell-type specification and maturation. Recent data have unraveled the multi-faceted functions of COUP-TFI in the development of several mouse brain structures, including the neocortex, hippocampus and ganglionic eminences. Despite NR2F1 mutations and deletions in humans have been linked to a complex neurodevelopmental disease mainly associated to optic atrophy and intellectual disability, its role during the formation of the retina and optic nerve remains unclear. In light of its major influence in cortical development, we predict that its haploinsufficiency might be the cause of other cognitive diseases, not identified so far. Mouse models offer a unique opportunity of dissecting COUP-TFI function in different regions during brain assembly; hence, the importance of comparing and discussing common points linking mouse models to human patients' symptoms., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published

2019

5. Neuron-Astroglia Cell Fate Decision in the Adult Mouse Hippocampal Neurogenic Niche Is Cell-Intrinsically Controlled by COUP-TFI In Vivo.

Author

Bonzano S, Crisci I, Podlesny-Drabiniok A, Rolando C, Krezel W, Studer M, and De Marchis S

Subjects

Aging, Animals, Cell Line, Dentate Gyrus metabolism, Down-Regulation, Female, Inflammation pathology, Male, Mice, Inbred C57BL, Neural Stem Cells metabolism, Astrocytes metabolism, COUP Transcription Factor I metabolism, Cell Lineage, Hippocampus metabolism, Neurogenesis, Neurons metabolism

Abstract

In the dentate gyrus (DG) of the mouse hippocampus, neurogenesis and astrogliogenesis persist throughout life. Adult-born neurons and astrocytes originate from multipotent neural stem cells (NSCs) whose activity is tightly regulated within the neurogenic niche. However, the cell-intrinsic mechanisms controlling neuron-glia NSC fate choice are largely unknown. Here, we show COUP-TFI/NR2F1 expression in DG NSCs and its downregulation upon neuroinflammation. By using in vivo inducible knockout lines, a retroviral-based loss-of-function approach and genetic fate mapping, we demonstrate that COUP-TFI inactivation in adult NSCs and/or mitotic progenitors reduces neurogenesis and increases astrocyte production without depleting the NSC pool. Moreover, forced COUP-TFI expression in adult NSCs/progenitors decreases DG astrogliogenesis and rescues the neuro-astrogliogenic imbalance under neuroinflammation. Thus, COUP-TFI is necessary and sufficient to promote neurogenesis by suppressing astrogliogenesis. Our data propose COUP-TFI as a central regulator of the neuron-astroglia cell fate decision and a key modulator during neuroinflammation in the adult hippocampus., (Copyright © 2018 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2018

6. The atypical cadherin Celsr1 functions non-cell autonomously to block rostral migration of facial branchiomotor neurons in mice.

Author

Glasco DM, Pike W, Qu Y, Reustle L, Misra K, Di Bonito M, Studer M, Fritzsch B, Goffinet AM, Tissir F, and Chandrasekhar A

Subjects

Animals, Facial Nerve metabolism, Gene Expression Regulation, Developmental, Mice, Mice, Knockout, Motor Neurons cytology, Receptors, G-Protein-Coupled genetics, Cell Movement physiology, Facial Nerve embryology, Neurogenesis physiology, Receptors, G-Protein-Coupled metabolism, Rhombencephalon embryology

Abstract

The caudal migration of facial branchiomotor (FBM) neurons from rhombomere (r) 4 to r6 in the hindbrain is an excellent model to study neuronal migration mechanisms. Although several Wnt/Planar Cell Polarity (PCP) components are required for FBM neuron migration, only Celsr1, an atypical cadherin, regulates the direction of migration in mice. In Celsr1 mutants, a subset of FBM neurons migrates rostrally instead of caudally. Interestingly, Celsr1 is not expressed in the migrating FBM neurons, but rather in the adjacent floor plate and adjoining ventricular zone. To evaluate the contribution of different expression domains to neuronal migration, we conditionally inactivated Celsr1 in specific cell types. Intriguingly, inactivation of Celsr1 in the ventricular zone of r3-r5, but not in the floor plate, leads to rostral migration of FBM neurons, greatly resembling the migration defect of Celsr1 mutants. Dye fill experiments indicate that the rostrally-migrated FBM neurons in Celsr1 mutants originate from the anterior margin of r4. These data suggest strongly that Celsr1 ensures that FBM neurons migrate caudally by suppressing molecular cues in the rostral hindbrain that can attract FBM neurons., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

7. Area-specific temporal control of corticospinal motor neuron differentiation by COUP-TFI.

Author

Tomassy GS, De Leonibus E, Jabaudon D, Lodato S, Alfano C, Mele A, Macklis JD, and Studer M

Subjects

Animals, COUP Transcription Factor I genetics, Mice, Mice, Knockout, Motor Neurons metabolism, Pyramidal Tracts metabolism, Temporal Lobe metabolism, Thalamus growth & development, Thalamus metabolism, COUP Transcription Factor I metabolism, Gene Expression Regulation, Developmental, Motor Neurons cytology, Neurogenesis genetics, Pyramidal Tracts cytology, Temporal Lobe growth & development

Abstract

Transcription factors with gradients of expression in neocortical progenitors give rise to distinct motor and sensory cortical areas by controlling the area-specific differentiation of distinct neuronal subtypes. However, the molecular mechanisms underlying this area-restricted control are still unclear. Here, we show that COUP-TFI controls the timing of birth and specification of corticospinal motor neurons (CSMN) in somatosensory cortex via repression of a CSMN differentiation program. Loss of COUP-TFI function causes an area-specific premature generation of neurons with cardinal features of CSMN, which project to subcerebral structures, including the spinal cord. Concurrently, genuine CSMN differentiate imprecisely and do not project beyond the pons, together resulting in impaired skilled motor function in adult mice with cortical COUP-TFI loss-of-function. Our findings indicate that COUP-TFI exerts critical areal and temporal control over the precise differentiation of CSMN during corticogenesis, thereby enabling the area-specific functional features of motor and sensory areas to arise.

Published

2010

8. Dynamic expression of NR2F1 and SOX2 in developing and adult human cortex: comparison with cortical malformations

Author

Laura Avagliano, Laura Rossini, Michèle Studer, Antonino Maiorana, Rita Garbelli, Benedetta Foglio, Roland Coras, Silvia K. Nicolis, Gaetano Bulfamante, Sara Mercurio, Michele Bertacchi, Maria Cristina Regondi, Carolina Frassoni, Foglio, B, Rossini, L, Garbelli, R, Regondi, M, Mercurio, S, Bertacchi, M, Avagliano, L, Bulfamante, G, Coras, R, Maiorana, A, Nicolis, S, Studer, M, and Frassoni, C

Subjects

Adult, Histology, NR2F1/COUP-TF1, Neurogenesis, SOX2, Context (language use), Neocortex, Biology, 03 medical and health sciences, Laminar organization, Mice, 0302 clinical medicine, Interneurons, Cortex (anatomy), Gene expression, BBSOAS, medicine, Animals, Humans, 030304 developmental biology, Neurons, 0303 health sciences, Cortical dysplasia, COUP Transcription Factor I, General Neuroscience, SOXB1 Transcription Factors, medicine.disease, medicine.anatomical_structure, Dysplasia, Human cortical development, Transcription factor, Anatomy, Neuroscience, 030217 neurology & neurosurgery

Abstract

The neocortex, the most recently evolved brain region in mammals, is characterized by its unique areal and laminar organization. Distinct cortical layers and areas can be identified by the presence of graded expression of transcription factors and molecular determinants defining neuronal identity. However, little is known about the expression of key master genes orchestrating human cortical development. In this study, we explored the expression dynamics of NR2F1 and SOX2, key cortical genes whose mutations in human patients cause severe neurodevelopmental syndromes. We focused on physiological conditions, spanning from mid-late gestational ages to adulthood in unaffected specimens, but also investigated gene expression in a pathological context, a developmental cortical malformation termed focal cortical dysplasia (FCD). We found that NR2F1 follows an antero-dorsallow to postero-ventralhigh gradient as in the murine cortex, suggesting high evolutionary conservation. While SOX2 is mainly expressed in neural progenitors next to the ventricular surface, NR2F1 is found in both mitotic progenitors and post-mitotic neurons at GW18. Interestingly, both proteins are highly co-expressed in basal radial glia progenitors of the outer sub-ventricular zone (OSVZ), a proliferative region known to contribute to cortical expansion and complexity in humans. Later on, SOX2 becomes largely restricted to astrocytes and oligodendrocytes although it is also detected in scattered mature interneurons. Differently, NR2F1 maintains its distinct neuronal expression during the whole process of cortical development. Notably, we report here high levels of NR2F1 in dysmorphic neurons and NR2F1 and SOX2 in balloon cells of surgical samples from patients with FCD, suggesting their potential use in the histopathological characterization of this dysplasia.

Published

2020