Your search keyword '"Victor V. Chizhikov"' showing total 16 results

1. Unified rhombic lip origins of Group 3 and Group 4 medulloblastoma

Author

Kyle S. Smith, Laure Bihannic, Brian L. Gudenas, Parthiv Haldipur, Ran Tao, Qingsong Gao, Yiran Li, Kimberly A. Aldinger, Igor Y. Iskusnykh, Victor V. Chizhikov, Matthew Scoggins, Silu Zhang, Angela Edwards, Mei Deng, Ian A. Glass, Lynne M. Overman, Jake Millman, Alexandria H. Sjoboen, Jennifer Hadley, Joseph Golser, Kshitij Mankad, Heather Sheppard, Arzu Onar-Thomas, Amar Gajjar, Giles W. Robinson, Volker Hovestadt, Brent A. Orr, Zoltán Patay, Kathleen J. Millen, and Paul A. Northcott

Subjects

Neurons, Mice, Multidisciplinary, Cerebellum, Animals, Humans, Cell Lineage, Prospective Studies, Cerebellar Neoplasms, Article, Medulloblastoma, Metencephalon

Abstract

Medulloblastoma, a malignant childhood cerebellar tumor, molecularly segregates into biologically distinct subgroups warranting personalized therapy(1). Murine modeling and cross-species genomics have provided mounting evidence of discrete, subgroup-specific developmental origins(2). However, human-specific anatomic and cellular complexity(3), particularly within the rhombic lip germinal zone that produces all glutamatergic neuronal lineages prior to internalization into the cerebellar nodulus, complicates prior murine-derived inferences. Here, we utilized multi-omics to resolve medulloblastoma subgroup origins in the developing human cerebellum. Molecular signatures encoded within a human rhombic lip-derived lineage trajectory aligned with photoreceptor and unipolar brush cell expression profiles maintained in Group 3 and Group 4 medulloblastoma, implicating convergent basis. Systematic diagnostic imaging review of a prospective institutional cohort localized the putative anatomic origins of Group 3 and Group 4 tumors to the nodulus. Our results connect molecular and phenotypic features of clinically challenging medulloblastoma subgroups to their unified beginnings in the early human rhombic lip.

Published

2022

2. Early dorsomedial tissue interactions regulate gyrification of distal neocortex

Author

Igor Y. Iskusnykh, Victor V. Chizhikov, Nikolai Fattakhov, Shubha Tole, Achira Roy, Kathleen J. Millen, Ashwin S. Shetty, Ekaterina Y. Steshina, and Anne G. Lindgren

Subjects

Male, 0301 basic medicine, Science, Mesenchyme, LIM-Homeodomain Proteins, Neuroepithelial Cells, General Physics and Astronomy, Lissencephaly, Developmental neurogenesis, Neocortex, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Mesoderm, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, lcsh:Science, Gyrification, Mice, Knockout, Regulation of gene expression, Multidisciplinary, Wnt signaling pathway, Neural tube, Cell type diversity, Gene Expression Regulation, Developmental, General Chemistry, medicine.disease, Mice, Inbred C57BL, Wnt Proteins, Neuroepithelial cell, 030104 developmental biology, medicine.anatomical_structure, Female, lcsh:Q, Neuroscience, 030217 neurology & neurosurgery, Signal Transduction, Transcription Factors

Abstract

The extent of neocortical gyrification is an important determinant of a species’ cognitive abilities, yet the mechanisms regulating cortical gyrification are poorly understood. We uncover long-range regulation of this process originating at the telencephalic dorsal midline, where levels of secreted Bmps are maintained by factors in both the neuroepithelium and the overlying mesenchyme. In the mouse, the combined loss of transcription factors Lmx1a and Lmx1b, selectively expressed in the midline neuroepithelium and the mesenchyme respectively, causes dorsal midline Bmp signaling to drop at early neural tube stages. This alters the spatial and temporal Wnt signaling profile of the dorsal midline cortical hem, which in turn causes gyrification of the distal neocortex. Our study uncovers early mesenchymal-neuroepithelial interactions that have long-range effects on neocortical gyrification and shows that lissencephaly in mice is actively maintained via redundant genetic regulation of dorsal midline development and signaling., The contribution of long-range signaling to cortical gyrification remains poorly understood. In this study, authors demonstrate that the combined genetic loss of transcription factors Lmx1a and Lmx1b, expressed in the telencephalic dorsal midline neuroepithelium and head mesenchyme, respectively, induces gyrification in the mouse neocortex

Published

2019

3. Active medulloblastoma enhancers reveal subgroup-specific cellular origins

Author

Volker Hovestadt, Peter Lichter, Linlin Yin, Sebastian M. Waszak, Victor V. Chizhikov, Maia Segura-Wang, Donald R. Polaski, Marc Zapatka, Parthiv Haldipur, Marcel Kool, Andrey Korshunov, James E. Bradner, Paul A. Northcott, Roland Eils, David T.W. Jones, Laura Sieber, Lukas Chavez, Bensheng Ju, Wenbiao Chen, Barbara C. Worst, Yiai Tong, Pascal Johann, Hans Lehrach, Rhamy Zeid, Vyacheslav Amstislavskiy, Serap Erkek, Thomas Risch, Ivo Buchhalter, Stefan M. Pfister, Marie-Laure Yaspo, Stefan Gröschel, Brent A. Orr, Daisuke Kawauchi, Jan O. Korbel, Hans-Jörg Warnatz, Kathleen J. Millen, Marina Ryzhova, Charles Y. Lin, and Alexander J. Federation

Subjects

Male, 0301 basic medicine, Gene regulatory network, Biology, Article, Transcriptome, Mice, 03 medical and health sciences, Genes, Reporter, medicine, Animals, Humans, Gene Regulatory Networks, Cerebellar Neoplasms, Enhancer, Transcription factor, Zebrafish, Regulation of gene expression, Medulloblastoma, Genetics, Multidisciplinary, Reproducibility of Results, medicine.disease, Gene Expression Regulation, Neoplastic, Enhancer Elements, Genetic, 030104 developmental biology, DNA methylation, Female, Chromatin immunoprecipitation, Genes, Neoplasm, Transcription Factors

Abstract

Medulloblastoma is a highly malignant paediatric brain tumour, often inflicting devastating consequences on the developing child. Genomic studies have revealed four distinct molecular subgroups with divergent biology and clinical behaviour. An understanding of the regulatory circuitry governing the transcriptional landscapes of medulloblastoma subgroups, and how this relates to their respective developmental origins, is lacking. Here, using H3K27ac and BRD4 chromatin immunoprecipitation followed by sequencing (ChIP-seq) coupled with tissue-matched DNA methylation and transcriptome data, we describe the active cis-regulatory landscape across 28 primary medulloblastoma specimens. Analysis of differentially regulated enhancers and super-enhancers reinforced inter-subgroup heterogeneity and revealed novel, clinically relevant insights into medulloblastoma biology. Computational reconstruction of core regulatory circuitry identified a master set of transcription factors, validated by ChIP-seq, that is responsible for subgroup divergence, and implicates candidate cells of origin for Group 4. Our integrated analysis of enhancer elements in a large series of primary tumour samples reveals insights into cis-regulatory architecture, unrecognized dependencies, and cellular origins.

Published

2016

4. The Spontaneous Ataxic Mouse Mutant Tippy is Characterized by a Novel Purkinje Cell Morphogenesis and Degeneration Phenotype

Author

Kathleen J. Millen, Christian Hansel, Gabriella Sekerková, Evelyn K. Shih, Enrico Mugnaini, Victor V. Chizhikov, Gen Ohtsuki, and Kimberly A. Aldinger

Subjects

Male, Cerebellum, Dendritic Spines, Purkinje cell, Mutant, Parallel fiber, Cerebellar Purkinje cell, Biology, Article, Cerebellar Cortex, Mice, Mice, Neurologic Mutants, Purkinje Cells, Morphogenesis, medicine, Animals, Dystrophy, Dendrites, Climbing fiber, Axons, Mice, Inbred C57BL, Disease Models, Animal, Phenotype, medicine.anatomical_structure, Neurology, Cerebellar cortex, Nerve Degeneration, Ataxia, Female, Neurology (clinical), Neuroscience

Abstract

This study represents the first detailed analysis of the spontaneous neurological mouse mutant, tippy, uncovering its unique cerebellar phenotype. Homozygous tippy mutant mice are small, ataxic, and die around weaning. Although the cerebellum shows grossly normal foliation, tippy mutants display a complex cerebellar Purkinje cell phenotype consisting of abnormal dendritic branching with immature spine features and patchy, non-apoptotic cell death that is associated with widespread dystrophy and degeneration of the Purkinje cell axons throughout the white matter, the cerebellar nuclei, and the vestibular nuclei. Moderate anatomical abnormalities of climbing fiber innervation of tippy mutant Purkinje cells were not associated with changes in climbing fiber-EPSC amplitudes. However, decreased ESPC amplitudes were observed in response to parallel fiber stimulation and correlated well with anatomical evidence for patchy dark cell degeneration of Purkinje cell dendrites in the molecular layer. The data suggest that the Purkinje neurons are a primary target of the tippy mutation. Furthermore, we hypothesize that the Purkinje cell axonal pathology together with disruptions in the balance of climbing fiber and parallel fiber-Purkinje cell input in the cerebellar cortex underlie the ataxic phenotype in these mice. The constellation of Purkinje cell dendritic malformation and degeneration phenotypes in tippy mutants is unique and has not been reported in any other neurologic mutant. Fine mapping of the tippy mutation to a 2.1 MB region of distal chromosome 9, which does not encompass any gene previously implicated in cerebellar development or neuronal degeneration, confirms that the tippy mutation identifies novel biology and gene function.

Published

2015

5. Loss of Ptf1a Leads to a Widespread Cell-Fate Misspecification in the Brainstem, Affecting the Development of Somatosensory and Viscerosensory Nuclei

Author

Ekaterina Y. Steshina, Victor V. Chizhikov, and Igor Y. Iskusnykh

Subjects

0301 basic medicine, Cerebellum, Neurogenesis, LIM-Homeodomain Proteins, Hindbrain, Mice, Transgenic, Biology, Somatosensory system, 03 medical and health sciences, Mice, medicine, Animals, Humans, Body Patterning, Neurons, Afferent Pathways, Caspase 3, Glutamate Decarboxylase, General Neuroscience, Solitary tract, Gene Expression Regulation, Developmental, Cell Differentiation, Articles, Spinal cord, Embryo, Mammalian, Luminescent Proteins, 030104 developmental biology, medicine.anatomical_structure, Bromodeoxyuridine, Brainstem, Neuroscience, Nucleus, Brain Stem, Transcription Factors

Abstract

The brainstem contains diverse neuronal populations that regulate a wide range of processes vital to the organism. Proper cell-fate specification decisions are critical to achieve neuronal diversity in the CNS, but the mechanisms regulating cell-fate specification in the developing brainstem are poorly understood. Previously, it has been shown that basic helix-loop-helix transcription factor Ptf1a is required for the differentiation and survival of neurons of the inferior olivary and cochlear brainstem nuclei, which contribute to motor coordination and sound processing, respectively. In this study, we show that the loss ofPtf1acompromises the development of the nucleus of the solitary tract, which processes viscerosensory information, and the spinal and principal trigeminal nuclei, which integrate somatosensory information of the face. Combining genetic fate-mapping, birth-dating, and gene expression studies, we found that at least a subset of brainstem abnormalities inPtf1a−/−mice are mediated by a dramatic cell-fate misspecification in rhombomeres 2–7, which results in the production of supernumerary viscerosensory and somatosensory neurons of the Lmx1b lineage at the expense of Pax2+GABAergic viscerosensory and somatosensory neurons, and inferior olivary neurons. Our data identifyPtf1aas a major regulator of cell-fate specification decisions in the developing brainstem, and as a previously unrecognized developmental regulator of both viscerosensory and somatosensory brainstem nuclei.SIGNIFICANCE STATEMENTCell-fate specification decisions are critical for normal CNS development. Although extensively studied in the cerebellum and spinal cord, the mechanisms mediating cell-fate decisions in the brainstem, which regulates a wide range of processes vital to the organism, remain largely unknown. Here we identified mousePtf1aas a novel regulator of cell-fate decisions during both early and late brainstem neurogenesis, which are critical for proper development of several major classes of brainstem cells, including neurons of the somatosensory and viscerosensory nuclei. Since loss-of-functionPTF1Amutations were described in human patients, we suggestPtf1a-dependent cell-fate misspecification as a novel mechanism of human brainstem pathology.

Published

2016

6. Multiple developmental programs are altered by loss ofZic1andZic4to cause Dandy-Walker malformation cerebellar pathogenesis

Author

Christine L. Laliberté, Inessa Grinberg, R. Mark Henkelman, Marissa C. Blank, Kathleen J. Millen, Emmanuel Aryee, and Victor V. Chizhikov

Subjects

Cerebellum, Mutant, Purkinje cell, Biology, ZIC1, Mice, Dandy–Walker syndrome, Pregnancy, medicine, Animals, Humans, Hedgehog Proteins, Progenitor cell, Molecular Biology, Research Articles, Cell Proliferation, Homeodomain Proteins, Mice, Knockout, Genetics, Regulation of gene expression, Gene Expression Regulation, Developmental, Organ Size, Embryo, Mammalian, medicine.disease, Granule cell, Cell biology, medicine.anatomical_structure, Animals, Newborn, Female, Dandy-Walker Syndrome, Transcription Factors, Developmental Biology

Abstract

Heterozygous deletions encompassing the ZIC1;ZIC4 locus have been identified in a subset of individuals with the common cerebellar birth defect Dandy-Walker malformation (DWM). Deletion of Zic1 and Zic4 in mice produces both cerebellar size and foliation defects similar to human DWM, confirming a requirement for these genes in cerebellar development and providing a model to delineate the developmental basis of this clinically important congenital malformation. Here, we show that reduced cerebellar size in Zic1 and Zic4 mutants results from decreased postnatal granule cell progenitor proliferation. Through genetic and molecular analyses, we show that Zic1 and Zic4 have Shh-dependent function promoting proliferation of granule cell progenitors. Expression of the Shh-downstream genes Ptch1, Gli1 and Mycn was downregulated in Zic1/4 mutants, although Shh production and Purkinje cell gene expression were normal. Reduction of Shh dose on the Zic1+/−;Zic4+/− background also resulted in cerebellar size reductions and gene expression changes comparable with those observed in Zic1−/−;Zic4−/− mice. Zic1 and Zic4 are additionally required to pattern anterior vermis foliation. Zic mutant folial patterning abnormalities correlated with disrupted cerebellar anlage gene expression and Purkinje cell topography during late embryonic stages; however, this phenotype was Shh independent. In Zic1+/−;Zic4+/−;Shh+/−, we observed normal cerebellar anlage patterning and foliation. Furthermore, cerebellar patterning was normal in both Gli2-cko and Smo-cko mutant mice, where all Shh function was removed from the developing cerebellum. Thus, our data demonstrate that Zic1 and Zic4 have both Shh-dependent and -independent roles during cerebellar development and that multiple developmental disruptions underlie Zic1/4-related DWM.

Published

2011

7. Lmx1a regulates fates and location of cells originating from the cerebellar rhombic lip and telencephalic cortical hem

Author

Yuriko Mishima, Richard Roberts, Victor V. Chizhikov, George R. Miesegaes, Anne G. Lindgren, Edwin S. Monuki, Kathleen J. Millen, Kimberly A. Aldinger, and D. Spencer Currle

Subjects

Telencephalon, Cerebellum, LIM-Homeodomain Proteins, Morphogenesis, Biology, Mice, Fate mapping, medicine, Animals, Cell Lineage, Progenitor cell, Rhombic lip, Homeodomain Proteins, Mice, Knockout, Multidisciplinary, Vermis hypoplasia, Cerebrum, Neurogenesis, Gene Expression Regulation, Developmental, Anatomy, Biological Sciences, stomatognathic diseases, medicine.anatomical_structure, nervous system, Transcription Factors

Abstract

The cerebellar rhombic lip and telencephalic cortical hem are dorsally located germinal zones which contribute substantially to neuronal diversity in the CNS, but the mechanisms that drive neurogenesis within these zones are ill defined. Using genetic fate mapping in wild-type and Lmx1a −/− mice, we demonstrate that Lmx1a is a critical regulator of cell-fate decisions within both these germinal zones. In the developing cerebellum, Lmx1a is expressed in the roof plate, where it is required to segregate the roof plate lineage from neuronal rhombic lip derivatives. In addition, Lmx1a is expressed in a subset of rhombic lip progenitors which produce granule cells that are predominantly restricted to the cerebellar posterior vermis. In the absence of Lmx1a , these cells precociously exit the rhombic lip and overmigrate into the anterior vermis. This overmigration is associated with premature regression of the rhombic lip and posterior vermis hypoplasia in Lmx1a −/− mice. These data reveal molecular organization of the cerebellar rhombic lip and introduce Lmx1a as an important regulator of rhombic lip cell-fate decisions, which are critical for maintenance of the entire rhombic lip and normal cerebellar morphogenesis. In the developing telencephalon Lmx1a is expressed in the cortical hem, and in its absence cortical hem progenitors contribute excessively to the adjacent hippocampus instead of producing Cajal-Retzius neurons. Thus, Lmx1a activity is critical for proper production of cells originating from both the cerebellar rhombic lip and the telencephalic cortical hem.

Published

2010

8. The roof plate regulates cerebellar cell-type specification and proliferation

Author

D. Spencer Currle, Kathleen J. Millen, Matthew F. Rose, Anne G. Lindgren, Victor V. Chizhikov, and Edwin S. Monuki

Subjects

Cerebellum, animal structures, Cell division, Embryonic Development, Biology, Cerebellar cell, Cell Physiological Phenomena, Congenital Abnormalities, Mice, medicine, Animals, Neural Tube Defects, Molecular Biology, Rhombic lip, Progenitor, Embryogenesis, Neural tube, Anatomy, Spinal cord, Mice, Mutant Strains, Cell biology, medicine.anatomical_structure, Spinal Cord, nervous system, embryonic structures, Cell Division, Developmental Biology

Abstract

During embryogenesis, the isthmic organizer, a well-described signaling center at the junction of the mid-hindbrain, establishes the cerebellar territory along the anterior/posterior axis of the neural tube. Mechanisms specifying distinct populations within the early cerebellar anlage are less defined. Using a newly developed gene expression map of the early cerebellar anlage, we demonstrate that secreted signals from the rhombomere 1 roof plate are both necessary and sufficient for specification of the adjacent cerebellar rhombic lip and its derivative fates. Surprisingly, we show that the roof plate is not absolutely required for initial specification of more distal cerebellar cell fates, but rather regulates progenitor proliferation and cell position within the cerebellar anlage. Thus, in addition to the isthmus, the roof plate represents an important signaling center controlling multiple aspects of cerebellar patterning.

Published

2006

9. Foxc1 dependent mesenchymal signalling drives embryonic cerebellar growth

Author

Richard J. Miller, Parthiv Haldipur, Victor V. Chizhikov, Gwendolyn S Gillies, Divakar S. Mithal, Olivia K Janson, and Kathleen J. Millen

Subjects

Receptors, CXCR4, Mesoderm, Cerebellum, cerebellum, QH301-705.5, Cellular differentiation, Mesenchyme, Science, radial glia, Biology, General Biochemistry, Genetics and Molecular Biology, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Biology (General), Cxcl12, mouse, Cell Proliferation, 030304 developmental biology, Mice, Knockout, 0303 health sciences, General Immunology and Microbiology, General Neuroscience, Cell Differentiation, Forkhead Transcription Factors, General Medicine, Embryonic Tissue, Anatomy, foxc1, neurodevelopmental disorder, Chemokine CXCL12, Cell biology, Developmental Biology and Stem Cells, medicine.anatomical_structure, CXCL3, nervous system, Embryonic mesenchyme, Medicine, sense organs, Stem cell, 030217 neurology & neurosurgery, Signal Transduction, Research Article, Neuroscience

Abstract

Loss of Foxc1 is associated with Dandy-Walker malformation, the most common human cerebellar malformation characterized by cerebellar hypoplasia and an enlarged posterior fossa and fourth ventricle. Although expressed in the mouse posterior fossa mesenchyme, loss of Foxc1 non-autonomously induces a rapid and devastating decrease in embryonic cerebellar ventricular zone radial glial proliferation and concurrent increase in cerebellar neuronal differentiation. Subsequent migration of cerebellar neurons is disrupted, associated with disordered radial glial morphology. In vitro, SDF1α, a direct Foxc1 target also expressed in the head mesenchyme, acts as a cerebellar radial glial mitogen and a chemoattractant for nascent Purkinje cells. Its receptor, Cxcr4, is expressed in cerebellar radial glial cells and conditional Cxcr4 ablation with Nes-Cre mimics the Foxc1−/− cerebellar phenotype. SDF1α also rescues the Foxc1−/− phenotype. Our data emphasizes that the head mesenchyme exerts a considerable influence on early embryonic brain development and its disruption contributes to neurodevelopmental disorders in humans. DOI: http://dx.doi.org/10.7554/eLife.03962.001, eLife digest The part of the brain responsible for coordinating and fine-tuning movement, sensory processing and some cognitive functions—the cerebellum—is found tucked away at the back of the brain, where it sits in a hollow in the skull called the posterior fossa. In a relatively common neurological disorder called Dandy-Walker malformation, part of the cerebellum doesn't develop and the posterior fossa is abnormally large. One contributing factor to Dandy-Walker malformation is the loss of a protein called Foxc1. This protein is a so-called transcription factor, meaning it activates other genes, and so it has various important roles in helping an embryo to develop. In mouse embryos, the gene that produces Foxc1 is not activated in the developing cerebellum itself, but rather in the adjacent mesenchyme, a primitive embryonic tissue that will develop into the membranes that cover the brain and the skull bones that define the posterior fossa. This led Haldipur et al. to propose that the mesenchyme and the cerebellum communicate with each other as they develop. To investigate this idea, Haldipur et al. carefully analysed how the development of the mouse cerebellum goes awry when Foxc1 is absent. This revealed that Foxc1-deficient mice have lower numbers of a type of cell called radial glial cells in their cerebellum. These are ‘progenitor’ cells that develop into the various types of cell found in the cerebellum, and also act as a scaffold for other neurons to migrate across. Therefore, the loss of radial glial cells in Foxc1-deficient mice substantially disrupts how the cerebellum develops, and how the neurons in the cerebellum work. One gene activated by the Foxc1 protein encodes another protein called SDF1-alpha. This protein is released from the tissue that will develop into the posterior fossa, and binds to a receptor protein that is present on radial glial cells in the cerebellum. When this binding occurs, the radial glial cells grow and divide, and so the embryo's cerebellum also grows. Haldipur et al. found that mouse embryos specifically missing this receptor develop many of the abnormalities seen in Foxc1-deficient mice and further, when SDF1-alpha was provided back into Foxc1-deficient cerebella, the defects were rescued. This suggests that the cerebellar defects caused by the loss of Foxc1 stem from disrupting the signalling pathways that are triggered by the interaction between SDF1-alpha and its receptor. These studies highlight that the brain does not develop in isolation. It is strongly dependent on the signals it receives from the embryonic mesenchyme that surrounds it. Identifying these signals and understanding how they can be disrupted by both genetic and non-genetic causes, such as inflammation, may be key to understanding this important class of brain birth defects. DOI: http://dx.doi.org/10.7554/eLife.03962.002

Published

2014

10. Control of Roof Plate Development and Signaling by Lmx1b in the Caudal Vertebrate CNS

Author

Victor V. Chizhikov and Kathleen J. Millen

Subjects

animal structures, Interneuron, Basal plate (neural tube), Cellular differentiation, LIM-Homeodomain Proteins, Development/Plasticity/Repair, Chick Embryo, In Vitro Techniques, Biology, Mice, Interneurons, Basic Helix-Loop-Helix Transcription Factors, medicine, Animals, Homeodomain Proteins, General Neuroscience, Neural tube, Wnt signaling pathway, Cell Differentiation, Anatomy, Roof plate formation, Spinal cord, Cell biology, DNA-Binding Proteins, body regions, medicine.anatomical_structure, Spinal Cord, GDF7, embryonic structures, Transcription Factors

Abstract

Numerous studies have identified the roof plate as an important signaling center controlling dorsal interneuron specification and differentiation in the developing spinal cord. Currently, the molecular pathways of roof plate formation and function are poorly understood. We determined that the LIM-homeodomain transcription factor Lmx1b is sufficient to induce functional roof plate in the early chick developing spinal cord. In the chick, Lmx1b acts upstream of Lmx1a in the roof plate developmental program. Once the roof plate forms, we show that Bmp and Wnt signaling are the major components ofLmx1a/b-dependent roof plate dorsal patterning activity. The roof plate function ofLmx1bis not conserved across vertebrates becauseLmx1bis not expressed in mouse roof plate progenitors. Instead, mouse caudal CNS roof plate formation relies entirely onLmx1a. Lmx1bcan, however, partially rescue roof plate development indreher(Lmx1a-/-) mice, indicating that Lmx1b has some functional redundancy to Lmx1a. Furthermore, we demonstrate that the roof plate-inducing activity of Lmx1b can be suppressed by Mash1 (Cash1), which is normally expressed in intermediate neural tube in both chick and mouse. Our data identifyLmx1bas a key regulator of spinal cord roof plate induction and function.

Published

2004

11. Development and malformations of the cerebellum in mice

Author

Kathleen J. Millen and Victor V. Chizhikov

Subjects

Cerebellum, Endocrinology, Diabetes and Metabolism, Cerebellar cell, Biology, medicine.disease_cause, Biochemistry, Mice, Endocrinology, Cell Movement, Mesencephalon, Genetics, medicine, Animals, Humans, Molecular Biology, SENSORY DISCRIMINATION, Regulation of gene expression, Mutation, Gene Expression Regulation, Developmental, Gene targeting, Anatomy, Motor coordination, Rhombencephalon, medicine.anatomical_structure, nervous system, Developmental physiology, Neuroscience

Abstract

The cerebellum is the primary motor coordination center of the CNS and is also involved in cognitive processing and sensory discrimination. Multiple cerebellar malformations have been described in humans, however, their developmental and genetic etiologies currently remain largely unknown. In contrast, there is extensive literature describing cerebellar malformations in the mouse. During the past decade, analysis of both spontaneous and gene-targeted neurological mutant mice has provided significant insight into the molecular and cellular mechanisms that regulate cerebellar development. Cerebellar development occurs in several distinct but interconnected steps. These include the establishment of the cerebellar territory along anterior-posterior and dorsal-ventral axes of the embryo, initial specification of the cerebellar cell types, their subsequent proliferation, differentiation and migration, and, finally, the interconnection of the cerebellar circuitry. Our understanding of the basis of these developmental processes is certain to provide insight into the nature of human cerebellar malformations.

Published

2003

12. Transformation of the cerebellum into more ventral brainstem fates causes cerebellar agenesis in the absence of Ptf1a function

Author

Ekaterina Y. Steshina, Kathleen J. Millen, Victor V. Chizhikov, and Igor Y. Iskusnykh

Subjects

Cerebellum, Glutamine, Sensory system, Hindbrain, Apoptosis, Cell fate determination, Biology, Models, Biological, Mice, medicine, Basic Helix-Loop-Helix Transcription Factors, Animals, Humans, Cell Lineage, Cerebellar agenesis, Neurons, Multidisciplinary, Stem Cells, Neural tube, Human brain, medicine.disease, Embryo, Mammalian, medicine.anatomical_structure, nervous system, PNAS Plus, Mutation, Brainstem, Neuroscience, Brain Stem, Transcription Factors

Abstract

Model organism studies have demonstrated that cell fate specification decisions play an important role in normal brain development. Their role in human neurodevelopmental disorders, however, is poorly understood, with very few examples described. The cerebellum is an excellent system to study mechanisms of cell fate specification. Although signals from the isthmic organizer are known to specify cerebellar territory along the anterior-posterior axis of the neural tube, the mechanisms establishing the cerebellar anlage along the dorsal-ventral axis are unknown. Here we show that the gene encoding pancreatic transcription factor PTF1A, which is inactivated in human patients with cerebellar agenesis, is required to segregate the cerebellum from more ventral extracerebellar fates. Using genetic fate mapping in mice, we show that in the absence of Ptf1a, cells originating in the cerebellar ventricular zone initiate a more ventral brainstem expression program, including LIM homeobox transcription factor 1 beta and T-cell leukemia homeobox 3. Misspecified cells exit the cerebellar anlage and contribute to the adjacent brainstem or die, leading to cerebellar agenesis in Ptf1a mutants. Our data identify Ptf1a as the first gene involved in the segregation of the cerebellum from the more ventral brainstem. Further, we propose that cerebellar agenesis represents a new, dorsal-to-ventral, cell fate misspecification phenotype in humans.

Published

2014

13. Overlapping function of Lmx1a and Lmx1b in anterior hindbrain roof plate formation and cerebellar growth

Author

Anne Lindgren, Kathleen J. Millen, Randy L. Johnson, Victor V. Chizhikov, and Yuriko Mishima

Subjects

Cerebellum, animal structures, LIM-Homeodomain Proteins, Morphogenesis, Hindbrain, Mice, Transgenic, Biology, Article, Mice, medicine, Genes, Overlapping, Animals, Transcription factor, Homeodomain Proteins, Mice, Knockout, General Neuroscience, Wnt signaling pathway, Anatomy, Roof plate formation, Spinal cord, Embryonic stem cell, Cell biology, body regions, Rhombencephalon, medicine.anatomical_structure, embryonic structures, Transcription Factors

Abstract

The roof plate is an organizing center in the dorsal CNS that controls specification and differentiation of adjacent neurons through secretion of the BMP and WNT signaling molecules.Lmx1a, a member of the LIM-homeodomain (LIM-HD) transcription factor family, is expressed in the roof plate and its progenitors at all axial levels of the CNS and is necessary and sufficient for roof plate formation in the spinal cord. In the anterior CNS, however, a residual roof plate develops in the absence ofLmx1a. Lmx1b, another member of the LIM-HD transcription factor family which is highly related toLmx1a, is expressed in the roof plate in the anterior CNS. AlthoughLmx1b-null mice do not show a substantial deficiency in hindbrain roof plate formation,Lmx1a/Lmx1bcompound-null mutants fail to generate hindbrain roof plate. This observation indicates that both genes act in concert to direct normal hindbrain roof plate formation. Since the requirement ofLmx1bfunction for normal isthmic organizer at the mid–hindbrain boundary complicates analysis of a distinct dorsal patterning role of this gene, we also used a conditional knock-out strategy to specifically delete dorsal midlineLmx1bexpression. Phenotypic analysis of single and compound conditional mutants confirmed overlapping roles forLmx1genes in regulating hindbrain roof plate formation and growth and also revealed roles in regulating adjacent cerebellar morphogenesis. Our data provides the first evidence of overlapping function of theLmx1genes during embryonic CNS development.

Published

2009

14. Cilia Proteins Control Cerebellar Morphogenesis by Promoting Expansion of the Granule Progenitor Pool

Author

Evelyn K. Shih, Olga A. Cabello, James R. Davenport, Kathleen J. Millen, Jannon L. Fuchs, Qihong Zhang, Victor V. Chizhikov, and Bradley K. Yoder

Subjects

Cerebellum, Population, Kinesins, Mice, Transgenic, Biology, Gene mutation, Joubert syndrome, Mice, Mice, Neurologic Mutants, Intraflagellar transport, medicine, Morphogenesis, Animals, KIF3A, education, Cell Proliferation, Neurons, education.field_of_study, General Neuroscience, Cilium, Stem Cells, Tumor Suppressor Proteins, Cell Differentiation, Articles, medicine.disease, Granule cell, medicine.anatomical_structure, Ataxia, Neuroscience

Abstract

Although human congenital cerebellar malformations are common, their molecular and developmental basis is still poorly understood. Recently, cilia-related gene deficiencies have been implicated in several congenital disorders that exhibit cerebellar abnormalities such as Joubert syndrome, Meckel-Gruber syndrome, Bardet-Biedl syndrome, and Orofaciodigital syndrome. The association of cilia gene mutations with these syndromes suggests that cilia may be important for cerebellar development, but the nature of cilia involvement has not been elucidated. To assess the importance of cilia-related proteins during cerebellar development, we studied the effects of CNS-specific inactivation of two mouse genes whose protein products are critical for cilia formation and maintenance,IFT88, (also known aspolarisorTg737), which encodes intraflagellar transport 88 homolog, andKif3a, which encodes kinesin family member 3a. We showed that loss of either of these genes caused severe cerebellar hypoplasia and foliation abnormalities, primarily attributable to a failure of expansion of the neonatal granule cell progenitor population. In addition, granule cell progenitor proliferation was sensitive to partial loss of IFT function in a hypomorphic mutant ofIFT88(IFT88orpk), an effect that was modified by genetic background.IFT88andKif3awere not required for the specification and differentiation of most other cerebellar cell types, including Purkinje cells. Together, our observations constitute the first demonstration that cilia proteins are essential for normal cerebellar development and suggest that granule cell proliferation defects may be central to the cerebellar pathology in human cilia-related disorders.

Published

2007

15. Molecular definition of an allelic series of mutations disrupting the mouse Lmx1a (dreher) gene

Author

Victor V. Chizhikov, Richard Roberts, Linda L. Washburn, Kathleen J. Millen, Ekaterina Y. Steshina, and Yesim Ilkin

Subjects

Ataxia, Positional cloning, DNA Mutational Analysis, LIM-Homeodomain Proteins, Molecular Sequence Data, Biology, medicine.disease_cause, Frameshift mutation, Mice, Cerebellum, Genetics, medicine, Missense mutation, Animals, Amino Acid Sequence, Allele, Gene, Alleles, Homeodomain Proteins, Mutation, Sequence Homology, Amino Acid, Molecular biology, Null allele, Mice, Inbred C57BL, Disease Models, Animal, medicine.symptom, Dandy-Walker Syndrome, Transcription Factors

Abstract

Mice homozygous for the dreher (dr) mutation are characterized by pigmentation and skeletal abnormalities and striking behavioral phenotypes, including ataxia, vestibular deficits, and hyperactivity. The ataxia is associated with a cerebellar malformation that is remarkably similar to human Dandy-Walker malformation. Previously, positional cloning identified mutations in LIM homeobox transcription factor 1 alpha gene (Lmx1a) in three dr alleles. Two of these alleles, however, are extinct and unavailable for further analysis. In this article we report a new spontaneous dr allele and describe the Lmx1a mutations in this and six additional dr alleles. Strikingly, deletion null, missense, and frameshift mutations in these alleles all cause similar cerebellar malformations, suggesting that all dr mutations analyzed to date are null alleles.

Published

2006

16. Control of roof plate formation by Lmx1a in the developing spinal cord

Author

Kathleen J. Millen and Victor V. Chizhikov

Subjects

animal structures, Interneuron, Central nervous system, LIM-Homeodomain Proteins, MafB Transcription Factor, Ectoderm, Bone Morphogenetic Protein 4, Chick Embryo, Biology, Avian Proteins, Mice, Proto-Oncogene Proteins, medicine, Animals, Molecular Biology, Body Patterning, Embryonic Induction, Homeodomain Proteins, Neurons, Oncogene Proteins, Stem Cells, Cell Cycle, Neural tube, Neural crest, Gene Expression Regulation, Developmental, Cell Differentiation, Anatomy, Roof plate formation, Spinal cord, Mice, Mutant Strains, Cell biology, DNA-Binding Proteins, Wnt Proteins, medicine.anatomical_structure, Spinal Cord, Neural Crest, GDF7, embryonic structures, Bone Morphogenetic Proteins, Trans-Activators, Developmental Biology, Signal Transduction, Transcription Factors

Abstract

Numerous studies have identified the roof plate as an embryonic signaling center critical for dorsal central nervous system patterning, but little is known about mechanisms that control its formation and its separation from clonally related neural crest cells and dI1 sensory interneurons. We demonstrate that the LIM homeodomain transcription factor, Lmx1a,mutated in the dreher mouse, acts to withdraw dorsal spinal cord progenitors from the cell cycle and simultaneously direct their differentiation into functional roof plate cells. Lmx1a cell-autonomously represses the dI1 progenitor fate, distinguishing the roof plate and dI1 interneuron programs, two major developmental programs of the dorsal neural tube. Lmx1a is not directly involved in neural crest development. We establish that Bmp signaling from epidermal ectoderm is necessary and sufficient for inducing Lmx1a and other co-factors that also regulate the extent of roof plate induction. We conclude that Lmx1a controls multiple aspects of dorsal midline patterning and is a major mediator of early Bmp signaling in the developing spinal cord.

Published

2004