Your search keyword '"Christiane Haffner"' showing total 12 results

1. Human-specific ARHGAP11B increases size and folding of primate neocortex in the fetal marmoset

Author

Erika Sasaki, Yoko Kurotaki, Wieland B. Huttner, Ayako Y. Murayama, Haruka Shinohara, Hideyuki Okano, Michael Heide, and Christiane Haffner

Subjects

0301 basic medicine, Multidisciplinary, Neocortex, biology, Subventricular zone, Marmoset, Evolution of mammals, biology.organism_classification, Callithrix, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, biology.animal, medicine, Primate, Progenitor cell, Neuroscience, Gene, 030217 neurology & neurosurgery

Abstract

Neocortex in the fetal brain Along the path of human evolution, gene duplication and divergence produced a protein, ARHGAP11B, that is found in humans but not nonhuman primates or other mammals. Heide et al. analyzed the effects of ARHGAP11B gene expression, under control of its own human-specific promoter, in the fetal marmoset (see the Perspective by Dehay and Kennedy). In the early weeks of fetal growth, the gene drove greater elaboration of neural progenitors and neocortex than is evident in the normal fetal marmoset. ARHGAP11B expression may be one cause of the more robust neocortex that characterizes the human brain. Science , this issue p. 546 ; see also p. 506

Published

2020

2. Ex vivo Tissue Culture Protocols for Studying the Developing Neocortex

Author

Christiane Haffner, Takashi Namba, and Wieland B. Huttner

Subjects

Neocortex, Strategy and Management, Mechanical Engineering, Electroporation, Metals and Alloys, Biology, Industrial and Manufacturing Engineering, Brain anatomy, Tissue culture, Basic knowledge, medicine.anatomical_structure, Methods Article, medicine, Neuroscience, Ex vivo, Neocortical slice, Organotypic slice

Abstract

The size of the neocortex and its morphology are highly divergent across mammalian species. Several approaches have been utilized for the analysis of neocortical development and comparison among different species. In the present protocol (Note: This protocol requires basic knowledge of brain anatomy), we describe three ex vivo neocortical slice/tissue culture methods: (i) organotypic slice culture (mouse, ferret, human); (ii) hemisphere rotation culture (mouse, ferret); and (iii) free-floating tissue culture (mouse, ferret, human). Each of these three culture methods offers distinct features with regard to the analyses to be performed and can be combined with genetic manipulation by electroporation and treatment with specific inhibitors. These three culture methods are therefore powerful techniques to examine the function of genes involved in neocortical development.

Published

2021

3. Epigenome profiling and editing of neocortical progenitor cells during development

Author

Nereo Kalebic, Marta Florio, Christiane Haffner, Naharajan Lakshmanaperumal, Wieland B. Huttner, Holger Brandl, Mareike Albert, and Ian Henry

Subjects

Resource, 0301 basic medicine, Neurogenesis, Mice, Transgenic, Neocortex, macromolecular substances, Biology, Methylation, General Biochemistry, Genetics and Molecular Biology, Epigenesis, Genetic, Histones, 03 medical and health sciences, Neural Stem Cells, Histone methylation, Animals, Progenitor cell, Molecular Biology, Genetics, Genome, General Immunology and Microbiology, Gene Expression Profiling, General Neuroscience, EZH2, Gene Expression Regulation, Developmental, Epigenome, Chromatin, Cell biology, 030104 developmental biology, Histone, Histone methyltransferase, biology.protein

Abstract

The generation of neocortical neurons from neural progenitor cells (NPCs) is primarily controlled by transcription factors binding to DNA in the context of chromatin. To understand the complex layer of regulation that orchestrates different NPC types from the same DNA sequence, epigenome maps with cell type resolution are required. Here, we present genomewide histone methylation maps for distinct neural cell populations in the developing mouse neocortex. Using different chromatin features, we identify potential novel regulators of cortical NPCs. Moreover, we identify extensive H3K27me3 changes between NPC subtypes coinciding with major developmental and cell biological transitions. Interestingly, we detect dynamic H3K27me3 changes on promoters of several crucial transcription factors, including the basal progenitor regulator Eomes. We use catalytically inactive Cas9 fused with the histone methyltransferase Ezh2 to edit H3K27me3 at the Eomes locus in vivo, which results in reduced Tbr2 expression and lower basal progenitor abundance, underscoring the relevance of dynamic H3K27me3 changes during neocortex development. Taken together, we provide a rich resource of neocortical histone methylation data and outline an approach to investigate its contribution to the regulation of selected genes during neocortical development.

Published

2017

4. Robotic Platform for the Delivery of Gene Products Into Single Cells in Organotypic Slices of the Developing Mouse Brain

Author

Gabriella Shull, Suhasa B. Kodandaramaiah, Wieland B. Huttner, Elena Taverna, and Christiane Haffner

Subjects

Biology, Neuroscience, Gene

Abstract

Microinjection of genetic components and dye into organotypic slices provides excellent single cell resolution for unraveling biological complexities, but is extremely difficult and time consuming to perform manually resulting in low yield and low use in the developmental biology field. We developed a computer vision guided platform to inject specimen with mRNA, and/or dye and investigated the efficiency of the process using organotypic slices of the mouse developing neocortex. We demonstrate that the system significantly increases yield of injection relative to manual use by an order of magnitude, allows for cell tracking over 0, 24, and 48 hours post injection in culture, and enables mRNA translation of injected product. The autoinjector platform thus can open the door to new types of experiments including investigating effects of mRNA concentration, and composition on cell fate, and tracking these effects on cell reprogramming and lineage.

Published

2018

5. Human-specific gene ARHGAP11B promotes basal progenitor amplification and neocortex expansion

Author

Robert Lachmann, Holger Brandl, Kay Prüfer, Fong Kuan Wong, Mareike Albert, Elaine Guhr, Andreas Dahl, Ronald Naumann, Janet Kelso, Wieland B. Huttner, Marta Florio, Ina Nüsslein, Jula Peters, Svante Pääbo, Takashi Namba, Alex M. Sykes, Sylvia Klemroth, Eric Lewitus, Elena Taverna, and Christiane Haffner

Subjects

Lineage (genetic), Neurogenesis, Subventricular zone, Neocortex, Cell Separation, Biology, Mice, Neural Stem Cells, Gene Duplication, Lateral Ventricles, Cell polarity, medicine, Animals, Humans, Progenitor cell, Progenitor, Neurons, Genetics, Multidisciplinary, GTPase-Activating Proteins, Gene Expression Regulation, Developmental, Protein Structure, Tertiary, Cell biology, Corticogenesis, medicine.anatomical_structure, nervous system, Transcriptome, Neuroglia

Abstract

Evolutionary expansion of the human neocortex reflects increased amplification of basal progenitors in the subventricular zone, producing more neurons during fetal corticogenesis. In this work, we analyze the transcriptomes of distinct progenitor subpopulations isolated by a cell polarity-based approach from developing mouse and human neocortex. We identify 56 genes preferentially expressed in human apical and basal radial glia that lack mouse orthologs. Among these, ARHGAP11B has the highest degree of radial glia-specific expression. ARHGAP11B arose from partial duplication of ARHGAP11A (which encodes a Rho guanosine triphosphatase-activating protein) on the human lineage after separation from the chimpanzee lineage. Expression of ARHGAP11B in embryonic mouse neocortex promotes basal progenitor generation and self-renewal and can increase cortical plate area and induce gyrification. Hence, ARHGAP11B may have contributed to evolutionary expansion of human neocortex.

Published

2015

6. A new approach to manipulate the fate of single neural stem cells in tissue

Author

Christiane Haffner, Elena Taverna, Wieland B. Huttner, and Rainer Pepperkok

Subjects

Time Factors, Microinjections, Mice, Transgenic, In Vitro Techniques, Biology, Immediate-Early Proteins, Mice, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, Neurosphere, Animals, RNA, Messenger, Progenitor cell, cdc42 GTP-Binding Protein, 030304 developmental biology, Progenitor, 0303 health sciences, Tumor Suppressor Proteins, General Neuroscience, Cell Cycle, Cell Differentiation, Embryo, Mammalian, Embryonic stem cell, Neural stem cell, Cell biology, Mice, Inbred C57BL, Rhombencephalon, Neuroepithelial cell, Luminescent Proteins, Mutation, Stem cell, Neuroscience, 030217 neurology & neurosurgery, Adult stem cell

Abstract

A challenge in the field of neural stem cell biology is the mechanistic dissection of single stem cell behavior in tissue. Although such behavior can be tracked by sophisticated imaging techniques, current methods of genetic manipulation do not allow researchers to change the level of a defined gene product on a truly acute time scale and are limited to very few genes at a time. To overcome these limitations, we established microinjection of neuroepithelial/radial glial cells (apical progenitors) in organotypic slice culture of embryonic mouse brain. Microinjected apical progenitors showed cell cycle parameters that were indistinguishable to apical progenitors in utero, underwent self-renewing divisions and generated neurons. Microinjection of single genes, recombinant proteins or complex mixtures of RNA was found to elicit acute and defined changes in apical progenitor behavior and progeny fate. Thus, apical progenitor microinjection provides a new approach to acutely manipulating single neural stem and progenitor cells in tissue.

Published

2011

7. Insulinoma-Associated 1 Has a Panneurogenic Role and Promotes the Generation and Expansion of Basal Progenitors in the Developing Mouse Neocortex

Author

Svante Pääbo, Thomas Giger, Carmen Birchmeier, Philipp Khaitovich, Lilla M. Farkas, Katja Nowick, Christiane Haffner, and Wieland B. Huttner

Subjects

Neuroscience(all), Mice, Transgenic, Neocortex, DEVBIO, Biology, MOLNEURO, Mice, Basal (phylogenetics), Pregnancy, medicine, Animals, Progenitor cell, Mitosis, Transcription factor, Cells, Cultured, Progenitor, Mice, Knockout, Neurons, Stem Cells, General Neuroscience, Gene Expression Regulation, Developmental, Cell Differentiation, Embryo, Cell biology, DNA-Binding Proteins, Mice, Inbred C57BL, Repressor Proteins, Neuroepithelial cell, medicine.anatomical_structure, SIGNALING, Female, Neuroscience, Transcription Factors

Abstract

SUMMARY Basal (intermediate) progenitors are the major source of neurons in the mammalian neocortex. The molecular machinery governing basal progenitor biogenesis is unknown. Here, we show that the zinc-finger transcription factor Insm1 (insulinoma-associated 1) is expressed specifically in progenitors undergoing neurogenic divisions, has a panneurogenic role throughout the brain, and promotes basal progenitor formation in the neocortex. Mouse embryos lacking Insm1 contained half the number of basal progenitors and showed a marked reduction in cortical plate radial thickness. Forced premature expression of Insm1 in neuroepithelial cells resulted in their mitosis occurring at the basal (rather than apical) side of the ventricular zone and induced expression of the basal progenitor marker Tbr2. Remarkably, these cells remained negative for Tis21, a marker of neurogenic progenitors, and did not generate neurons but underwent self-amplification. Our data imply that Insm1 is involved in the generation and expansion of basal progenitors, a hallmark of neocortex evolution.

Published

2008

8. Non-canonical features of the Golgi apparatus in bipolar epithelial neural stem cells

Author

Caren Norden, Marta Florio, Elena Taverna, Wieland B. Huttner, Jaroslav Icha, Felipe Mora-Bermúdez, Paulina Strzyz, Michaela Wilsch-Bräuninger, and Christiane Haffner

Subjects

0301 basic medicine, Gene Expression, Golgi Apparatus, Mitosis, Mice, Transgenic, Biology, Cell fate determination, Endoplasmic Reticulum, Article, Cell membrane, 03 medical and health sciences, symbols.namesake, Mice, Neural Stem Cells, Genes, Reporter, Polysaccharides, Cell polarity, medicine, Animals, Multidisciplinary, Endoplasmic reticulum, Cell Membrane, Apical constriction, Epithelial Cells, Golgi apparatus, Cell biology, Protein Transport, 030104 developmental biology, medicine.anatomical_structure, symbols, Basal lamina

Abstract

Apical radial glia (aRG), the stem cells in developing neocortex, are unique bipolar epithelial cells, extending an apical process to the ventricle and a basal process to the basal lamina. Here, we report novel features of the Golgi apparatus, a central organelle for cell polarity, in mouse aRGs. The Golgi was confined to the apical process but not associated with apical centrosome(s). In contrast, in aRG-derived, delaminating basal progenitors that lose apical polarity, the Golgi became pericentrosomal. The aRG Golgi underwent evolutionarily conserved, accordion-like compression and extension concomitant with cell cycle-dependent nuclear migration. Importantly, in line with endoplasmic reticulum but not Golgi being present in the aRG basal process, its plasma membrane contained glycans lacking Golgi processing, consistent with direct ER-to-cell surface membrane traffic. Our study reveals hitherto unknown complexity of neural stem cell polarity, differential Golgi contribution to their specific architecture and fundamental Golgi re-organization upon cell fate change.

Published

2016

9. Neural stem and progenitor cells shorten S-phase on commitment to neuron production

Author

Ina Nüsslein, Yoko Arai, Jeremy N. Pulvers, Britta Schilling, Christiane Haffner, Wieland B. Huttner, and Federico Calegari

Subjects

Multidisciplinary, General Physics and Astronomy, General Chemistry, Biology, Cell cycle, Bioinformatics, Article, General Biochemistry, Genetics and Molecular Biology, Neural stem cell, Cell biology, Endothelial stem cell, Neuroepithelial cell, medicine.anatomical_structure, Neurosphere, medicine, Neuron, Progenitor cell, Adult stem cell

Abstract

During mammalian cerebral cortex development, the G1-phase of the cell cycle is known to lengthen, but it has been unclear which neural stem and progenitor cells are affected. In this paper, we develop a novel approach to determine cell-cycle parameters in specific classes of neural stem and progenitor cells, identified by molecular markers rather than location. We found that G1 lengthening was associated with the transition from stem cell-like apical progenitors to fate-restricted basal (intermediate) progenitors. Unexpectedly, expanding apical and basal progenitors exhibit a substantially longer S-phase than apical and basal progenitors committed to neuron production. Comparative genome-wide gene expression analysis of expanding versus committed progenitor cells revealed changes in key factors of cell-cycle regulation, DNA replication and repair and chromatin remodelling. Our findings suggest that expanding neural stem and progenitor cells invest more time during S-phase into quality control of replicated DNA than those committed to neuron production., During neurogenesis, neural stem and progenitor cells can either proliferate or produce neurons. Here, the authors show that proliferating neural stem and progenitor cells have a longer S-phase portion of the cell cycle than cells committed to neuron production, suggesting that this may enable faithful DNA replication.

Published

2011

10. miRNAs are essential for survival and differentiation of newborn neurons but not for expansion of neural progenitors during early neurogenesis in the mouse embryonic neocortex

Author

Christiane Haffner, Jeremy N. Pulvers, Elizabeth P. Murchison, Davide De Pietri Tonelli, Gregory J. Hannon, and Wieland B. Huttner

Subjects

Ribonuclease III, Cell Survival, Cellular differentiation, Neurogenesis, Embryonic Development, Mitosis, Apoptosis, Cell Count, Neocortex, Biology, Article, DEAD-box RNA Helicases, Mice, Interneurons, Endoribonucleases, medicine, Animals, Cell Lineage, Progenitor cell, Molecular Biology, Cell Proliferation, Genetics, Neurons, Stem Cells, Gene Expression Regulation, Developmental, Cell Differentiation, Embryo, Mammalian, Cell biology, Neuroepithelial cell, MicroRNAs, medicine.anatomical_structure, Animals, Newborn, biology.protein, Stem cell, Gene Deletion, Developmental Biology, Dicer, Adult stem cell

Abstract

Neurogenesis during the development of the mammalian cerebral cortex involves a switch of neural stem and progenitor cells from proliferation to differentiation. To explore the possible role of microRNAs (miRNAs) in this process, we conditionally ablated Dicer in the developing mouse neocortex using Emx1-Cre, which is specifically expressed in the dorsal telencephalon as early as embryonic day (E) 9.5. Dicer ablation in neuroepithelial cells, which are the primary neural stem and progenitor cells,and in the neurons derived from them, was evident from E10.5 onwards, as ascertained by the depletion of the normally abundant miRNAs miR-9and miR-124. Dicer ablation resulted in massive hypotrophy of the postnatal cortex and death of the mice shortly after weaning. Analysis of the cytoarchitecture of the Dicer-ablated cortex revealed a marked reduction in radial thickness starting at E13.5, and defective cortical layering postnatally. Whereas the former was due to neuronal apoptosis starting at E12.5, which was the earliest detectable phenotype, the latter reflected dramatic impairment of neuronal differentiation. Remarkably, the primary target cells of Dicer ablation, the neuroepithelial cells, and the neurogenic progenitors derived from them, were unaffected by miRNA depletion with regard to cell cycle progression, cell division, differentiation and viability during the early stage of neurogenesis, and only underwent apoptosis starting at E14.5. Our results support the emerging concept that progenitors are less dependent on miRNAs than their differentiated progeny, and raise interesting perspectives as to the expansion of somatic stem cells.

Published

2008

11. Selective Lengthening of the Cell Cycle in the Neurogenic Subpopulation of Neural Progenitor Cells during Mouse Brain Development

Author

Wulf Haubensak, Wieland B. Huttner, Federico Calegari, and Christiane Haffner

Subjects

Telencephalon, Time Factors, Cellular differentiation, Recombinant Fusion Proteins, Development/Plasticity/Repair, Green Fluorescent Proteins, Subventricular zone, Gestational Age, Biology, Immediate-Early Proteins, Mice, Genes, Reporter, medicine, Animals, Genes, Tumor Suppressor, Progenitor cell, Neurons, General Neuroscience, Stem Cells, Tumor Suppressor Proteins, Neurogenesis, Cell Cycle, Brain, Gene Expression Regulation, Developmental, Cell Differentiation, Neural stem cell, Neuroepithelial cell, Mice, Inbred C57BL, medicine.anatomical_structure, Stem cell, Neuroscience, Neuroglia, Cell Division, Adult stem cell

Abstract

During embryonic development of the mammalian brain, the average cell-cycle length of progenitor cells in the ventricular zone is known to increase. However, for any given region of the developing cortex and stage of neurogenesis, the length of the cell cycle is thought to be similar in the two coexisting subpopulations of progenitors [i.e., those undergoing (symmetric) proliferative divisions and those undergoing (either asymmetric or symmetric) neuron-generating divisions]. Using cumulative bromodeoxyuridine labeling ofTis21-green fluorescent protein knock-in mouse embryos, in which these two subpopulations of progenitors can be distinguishedin vivo, we now show that at the onset as well as advanced stages of telencephalic neurogenesis, progenitors undergoing neuron-generating divisions are characterized by a significantly longer cell cycle than progenitors undergoing proliferative divisions. In addition, we find that the recently characterized neuronal progenitors dividing at the basal side of the ventricular zone and in the subventricular zone have a longer G2phase than those dividing at the ventricular surface. These findings are consistent with the hypothesis (Calegari and Huttner, 2003) that cell-cycle lengthening can causally contribute to neural progenitors switching from proliferative to neuron-generating divisions and may have important implications for the expansion of somatic stem cells in general.

Published

2005

12. 3′ UTR-Dependent, miR-92-Mediated Restriction of Tis21 Expression Maintains Asymmetric Neural Stem Cell Division to Ensure Proper Neocortex Size

Author

Ji-Feng Fei, Christiane Haffner, and Wieland B. Huttner

Subjects

Untranslated region, Neurogenesis, Population, Down-Regulation, Neocortex, Biology, General Biochemistry, Genetics and Molecular Biology, Immediate-Early Proteins, Mice, 03 medical and health sciences, 0302 clinical medicine, Neural Stem Cells, medicine, Asymmetric cell division, Animals, Progenitor cell, education, 3' Untranslated Regions, lcsh:QH301-705.5, 030304 developmental biology, Genetics, 0303 health sciences, education.field_of_study, Tumor Suppressor Proteins, Asymmetric Cell Division, Organ Size, Neural stem cell, Cell biology, Mice, Inbred C57BL, MicroRNAs, medicine.anatomical_structure, lcsh:Biology (General), Microcephaly, Stem cell, 030217 neurology & neurosurgery

Abstract

Summary: Mammalian neocortex size primarily reflects the number and mode of divisions of neural stem and progenitor cells. Cortical stem cells (apical progenitors) switching from symmetric divisions, which expand their population, to asymmetric divisions, which generate downstream neuronal progenitors (basal progenitors), start expressing Tis21, a so-called antiproliferative/prodifferentiative gene. Tis21 encodes a small (17.5 kDa), functionally poorly characterized protein and a relatively large (2 kb), highly conserved 3′ UTR. Here, we show that mice lacking the Tis21 3′ UTR develop a microcephalic neocortex with fewer neurons, notably in the upper layers. This reflects a progressive decrease in basal progenitors, which in turn is due to a fraction of apical progenitors prematurely switching from asymmetric self-renewing to symmetric self-consuming divisions. This switch is caused by the markedly increased Tis21 protein level resulting from lack of microRNA-, notably miR-92-, dependent restriction of Tis21 expression. Our data show that a premature onset of consumptive neural stem cell divisions can lead to microcephaly. : The size of the neocortex primarily reflects the number and mode of divisions of neural stem and progenitor cells, and aberrations result in microcephaly. Here, Fei et al. describe a mechanism causing microcephaly because of neural stem cells prematurely switching from self-renewing to consumptive division. This switch is due to the overexpression of a gene called Tis21 that occurs when its 3′ UTR is deleted and microRNAs, notably miR-92, can no longer mediate rapid Tis21 mRNA turnover.