emerin and Disease-Models--Animal

Emery-Dreifuss muscular dystrophy (EDMD) is an inherited muscular disorder clinically characterized by slowly progressive weakness affecting humero-peroneal muscles, early joint contractures and cardiomyopathy with conduction defects. Autosomal dominant and recessive forms are caused by mutations in lamin A/C gene. Lamin A/C is a major component of nuclear lamina, and its gene mutations cause several human disorders including muscular dystrophy, cardiomyopathy, lipodystrophy, neuropathy, and progeria syndrome. X-linked recessive form of EDMD is caused by mutation in EMD (or STA) gene encoding an integral protein of the inner nuclear membrane. Emerin expresses ubiquitously, but its deficiency affects only limited tissues of skeletal and cardiac muscles and joints. In this paper, I will focus on clinical and pathological aspects of X-EDMD and possible functions of emerin.

Topics: Animals; Disease Models, Animal; DNA-Binding Proteins; Genetic Diseases, X-Linked; Humans; Membrane Proteins; Mice; Muscular Dystrophy, Emery-Dreifuss; Nuclear Proteins; Thymopoietins

Mutations in LMNA encoding lamin A/C and EMD encoding emerin cause cardiomyopathy and muscular dystrophy. Lmna null mice develop these disorders and have a lifespan of 7-8 weeks. Emd null mice show no overt pathology and have normal skeletal muscle but with regeneration defects. We generated mice with germline deletions of both Lmna and Emd to determine the effects of combined loss of the encoded proteins. Mice without lamin A/C and emerin are born at the expected Mendelian ratio, are grossly normal at birth but have shorter lifespans than those lacking only lamin A/C. However, there are no major differences between these mice with regards to left ventricular function, heart ultrastructure or electrocardiographic parameters except for slower heart rates in the mice lacking both lamin A/C and emerin. Skeletal muscle is similarly affected in both of these mice. Lmna+/- mice also lacking emerin live to at least 1 year and have no significant differences in growth, heart or skeletal muscle compared to Lmna+/- mice. Deletion of the mouse gene encoding lamina-associated protein 1 leads to prenatal death; however, mice with heterozygous deletion of this gene lacking both lamin A/C and emerin are born at the expected Mendelian ratio but had a shorter lifespan than those only lacking lamin A/C and emerin. These results show that mice with combined deficiencies of three interacting nuclear envelope proteins have normal embryonic development and that early postnatal defects are primarily driven by loss of lamin A/C or lamina-associated polypeptide 1 rather than emerin.

Topics: Animals; Animals, Newborn; Carrier Proteins; Disease Models, Animal; Female; Haploinsufficiency; Heart; Lamin Type A; Male; Membrane Proteins; Mice; Mice, Knockout; Muscle, Skeletal; Muscular Dystrophy, Emery-Dreifuss; Mutation; Myocardium; Nuclear Proteins

Hutchinson-Gilford progeria syndrome (HGPS) is the result of a defective form of the lamin A protein called progerin. While progerin is known to disrupt the properties of the nuclear lamina, the underlying mechanisms responsible for the pathophysiology of HGPS remain less clear. Previous studies in our laboratory have shown that progerin expression in murine epidermal basal cells results in impaired stratification and halted development of the skin. Stratification and differentiation of the epidermis is regulated by asymmetric stem cell division. Here, we show that expression of progerin impairs the ability of stem cells to maintain tissue homeostasis as a result of altered cell division. Quantification of basal skin cells showed an increase in symmetric cell division that correlated with progerin accumulation in HGPS mice. Investigation of the mechanisms underlying this phenomenon revealed a putative role of Wnt/β-catenin signaling. Further analysis suggested an alteration in the nuclear translocation of β-catenin involving the inner and outer nuclear membrane proteins, emerin and nesprin-2. Taken together, our results suggest a direct involvement of progerin in the transmission of Wnt signaling and normal stem cell division. These insights into the molecular mechanisms of progerin may help develop new treatment strategies for HGPS.

Topics: Animals; beta Catenin; Cell Division; Cell Nucleus; Cells, Cultured; Disease Models, Animal; Epidermis; Humans; Lamin Type A; Membrane Proteins; Mice; Mice, Transgenic; Nerve Tissue Proteins; Nuclear Envelope; Nuclear Proteins; Progeria; Protein Transport; Stem Cells; Wnt Signaling Pathway

Alteration of the nuclear Ca

Topics: Active Transport, Cell Nucleus; Angiotensin II; Aniline Compounds; Animals; Atrial Remodeling; Calcium; Cardiomegaly; Cytoplasm; Disease Models, Animal; Endothelin-1; Fluorescent Dyes; Gene Expression Regulation; Heterocyclic Compounds, 3-Ring; Humans; Membrane Proteins; Muscular Dystrophy, Emery-Dreifuss; Myocardium; Myocytes, Cardiac; Nuclear Envelope; Nuclear Proteins; Phenylephrine; Primary Cell Culture; Rats; Rats, Sprague-Dawley; RNA, Small Interfering; Ventricular Remodeling; Xanthenes

The pathological mechanisms underlying neurological deficits observed in individuals born prematurely are not completely understood. A common form of injury in the preterm population is periventricular white matter injury (PWMI), a pathology associated with impaired brain development. To mitigate or eliminate PWMI, there is an urgent need to understand the pathological mechanism(s) involved on a neurobiological, structural, and functional level. Recent clinical data suggest that a percentage of premature infants experience relative hyperoxia. Using a hyperoxic model of premature brain injury, we have previously demonstrated that neonatal hyperoxia exposure in the mouse disrupts development of the white matter (WM) by delaying the maturation of the oligodendroglial lineage. In the present study, we address the question of how hyperoxia-induced alterations in WM development affect overall WM integrity and axonal function. We show that neonatal hyperoxia causes ultrastructural changes, including: myelination abnormalities (i.e., reduced myelin thickness and abnormal extramyelin loops) and axonopathy (i.e., altered neurofilament phosphorylation, paranodal defects, and changes in node of Ranvier number and structure). This disruption of axon-oligodendrocyte integrity results in the lasting impairment of conduction properties in the adult WM. Understanding the pathology of premature PWMI injury will allow for the development of interventional strategies to preserve WM integrity and function.

Topics: 2',3'-Cyclic-Nucleotide Phosphodiesterases; Action Potentials; Age Factors; Animals; Animals, Newborn; Axons; Brain; Disease Models, Animal; Female; Gene Expression Regulation, Developmental; Hyperoxia; Male; Membrane Proteins; Mice; Mice, Inbred C57BL; Microscopy, Confocal; Microscopy, Electron, Transmission; Myelin-Associated Glycoprotein; NAV1.6 Voltage-Gated Sodium Channel; Nerve Fibers, Myelinated; Neurofilament Proteins; Nuclear Proteins; Oligodendroglia

Emerin is an integral membrane protein of the inner nuclear membrane. Mutations in emerin cause X-linked Emery-Dreifuss muscular dystrophy (EDMD), a disease characterized by skeletal muscle wasting and dilated cardiomyopathy. Current evidence suggests the muscle wasting phenotype of EDMD is caused by defective myogenic progenitor cell differentiation and impaired muscle regeneration. We obtained genome-wide expression data for both mRNA and micro-RNA (miRNA) in wildtype and emerin-null mouse myogenic progenitor cells. We report here that emerin-null myogenic progenitors exhibit differential expression of multiple signaling pathway components required for normal muscle development and regeneration. Components of the Wnt, IGF-1, TGF-β, and Notch signaling pathways are misexpressed in emerin-null myogenic progenitors at both the mRNA and protein levels. We also report significant perturbations in the expression and activation of p38/Mapk14 in emerin-null myogenic progenitors, showing that perturbed expression of Wnt, IGF-1, TGF-β, and Notch signaling components disrupts normal downstream myogenic signaling in these cells. Collectively, these data support the hypothesis that emerin is essential for proper myogenic signaling in myogenic progenitors, which is necessary for myogenic differentiation and muscle regeneration.

Topics: Animals; Cell Differentiation; Cell Proliferation; Cells, Cultured; Disease Models, Animal; Gene Expression Profiling; Gene Regulatory Networks; Membrane Proteins; Mice; MicroRNAs; Morpholines; Muscle Development; Muscular Dystrophy, Emery-Dreifuss; Myoblasts, Skeletal; Nuclear Proteins; Signal Transduction

Mutations in the human LMNA gene underlie many laminopathic diseases, including Emery-Dreifuss muscular dystrophy (EDMD); however, a mechanistic link between the effect of mutations on lamin filament assembly and disease phenotypes has not been established. We studied the ΔK46 Caenorhabditis elegans lamin mutant, corresponding to EDMD-linked ΔK32 in human lamins A and C. Cryo-electron tomography of lamin ΔK46 filaments in vitro revealed alterations in the lateral assembly of dimeric head-to-tail polymers, which causes abnormal organization of tetrameric protofilaments. Green fluorescent protein (GFP):ΔK46 lamin expressed in C. elegans was found in nuclear aggregates in postembryonic stages along with LEM-2. GFP:ΔK46 also caused mislocalization of emerin away from the nuclear periphery, consistent with a decreased ability of purified emerin to associate with lamin ΔK46 filaments in vitro. GFP:ΔK46 animals had motility defects and muscle structure abnormalities. These results show that changes in lamin filament structure can translate into disease-like phenotypes via altering the localization of nuclear lamina proteins, and suggest a model for how the ΔK32 lamin mutation may cause EDMD in humans.

Topics: Amino Acid Sequence; Animals; Caenorhabditis elegans; Cloning, Molecular; Cryoelectron Microscopy; Cytoskeleton; Disease Models, Animal; Escherichia coli; Genetic Association Studies; Green Fluorescent Proteins; Humans; Lamin Type A; Membrane Proteins; Molecular Sequence Data; Movement; Muscles; Muscular Dystrophy, Emery-Dreifuss; Mutation; Nuclear Lamina; Nuclear Proteins; Phenotype; Plasmids; Recombinant Proteins; Transformation, Bacterial

Laminopathies encompass a wide array of human diseases associated to scattered mutations along LMNA, a single gene encoding A-type lamins. How such genetic alterations translate to cellular defects and generate such diverse disease phenotypes remains enigmatic. Recent work has identified nuclear envelope proteins--emerin and the linker of the nucleoskeleton and cytoskeleton (LINC) complex--which connect the nuclear lamina to the cytoskeleton. Here we quantitatively examine the composition of the nuclear envelope, as well as the architecture and functions of the cytoskeleton in cells derived from two laminopathic mouse models, including Hutchinson-Gilford progeria syndrome (Lmna(L530P/L530P)) and Emery-Dreifuss muscular dystrophy (Lmna(-/-)). Cells derived from the overtly aphenotypical model of X-linked Emery-Dreifuss muscular dystrophy (Emd(-/y)) were also included. We find that the centrosome is detached from the nucleus, preventing centrosome polarization in cells under flow--defects that are mediated by the loss of emerin from the nuclear envelope. Moreover, while basal actin and focal adhesion structure are mildly affected, RhoA activation, cell-substratum adhesion, and cytoplasmic elasticity are greatly lowered, exclusively in laminopathic models in which the LINC complex is disrupted. These results indicate a new function for emerin in cell polarization and suggest that laminopathies are not directly associated with cells' inability to polarize, but rather with cytoplasmic softening and weakened adhesion mediated by the disruption of the LINC complex across the nuclear envelope.

Topics: Actins; Animals; Biomechanical Phenomena; Cell Adhesion; Cell Line; Cell Movement; Cell Nucleus; Cytoplasm; Cytoskeleton; Disease Models, Animal; Humans; Membrane Proteins; Mice; Microtubules; Muscular Dystrophy, Emery-Dreifuss; Nuclear Envelope; Nuclear Proteins; Phenotype; Progeria; Rats; rhoA GTP-Binding Protein

Emery-Dreifuss muscular dystrophy (EMD) is an X-linked recessive disorder associated with muscle wasting, contractures, and cardiomyopathy. The responsible emerin gene has recently been identified and found to encode a serine-rich protein similar to lamina-associated protein 2 (LAP2), although the disease mechanism remains obscure. In order to pursue the pathophysiology of this disorder, we report here the isolation and characterization of the complete mouse emerin gene. The emerin cDNA was isolated from murine strain BALB/c, and the emerin gene was isolated from strain 129. The 2.9-kb mouse emerin gene was completely sequenced and found to be composed of 6 exons and encode a protein 73% identical to that of the human protein. Key similarities with LAP2 were found to be conserved, including critical LAP2 phosphorylation sites. Examination of the murine promoter revealed three previously unrecognized cAMP response elements (CRE) conserved between human and mouse. While Northern analysis shows emerin to be widely expressed in the mouse, as it is in humans, these promoter elements may indicate cAMP responsiveness. These data provide the necessary elements to further investigate EMD in a murine system.

Topics: Amino Acid Sequence; Animals; Base Sequence; Chromosome Mapping; Conserved Sequence; Disease Models, Animal; DNA Primers; DNA-Binding Proteins; DNA, Complementary; Genetic Linkage; Humans; Membrane Proteins; Mice; Mice, Inbred BALB C; Molecular Sequence Data; Muscular Dystrophies; Muscular Dystrophy, Animal; Nuclear Proteins; Rats; Sequence Homology, Amino Acid; Sequence Homology, Nucleic Acid; Species Specificity; Thymopoietins; X Chromosome