Your search keyword '"deficiency [Nerve Tissue Proteins]"' showing total 8 results

1. The FTLD Risk Factor TMEM106B Regulates the Transport of Lysosomes at the Axon Initial Segment of Motoneurons

Author

Bernd Knöll, Renate Lüllmann-Rauch, Paul Saftig, Christian Haass, Yasuo Uchiyama, Wolfgang Wurst, Renate Wanner, Anja Capell, Rudi D'Hooge, Georg Werner, Stijn Stroobants, Patrick Lüningschrör, Benedikt Wefers, Daniela Sinske, Soichiro Kakuta, Michael Sendtner, Benjamin Dombert, and Markus Damme

Subjects

0301 basic medicine, MODIFIER, Vacuole, pathology [Facial Nerve], VARIANTS, Axonal Transport, metabolism [Lysosomes], 0302 clinical medicine, innervation [Muscles], Risk Factors, Axon, lcsh:QH301-705.5, genetics [Nerve Tissue Proteins], Mice, Knockout, Motor Neurons, DEMENTIA, Muscles, ultrastructure [Autophagosomes], ultrastructure [Axon Initial Segment], Frontotemporal lobar degeneration, metabolism [Autophagosomes], Cell biology, genetics [Membrane Proteins], Facial Nerve, medicine.anatomical_structure, genetics [Frontotemporal Lobar Degeneration], Life Sciences & Biomedicine, PROTEINS, Nerve Tissue Proteins, ultrastructure [Motor Neurons], Biology, General Biochemistry, Genetics and Molecular Biology, MECHANISMS, Lipofuscin, 03 medical and health sciences, pathology [Brain Stem], MOTILITY, Lysosome, Organelle, medicine, Animals, Genetic Predisposition to Disease, ddc:610, metabolism [Cell Nucleus], PROGRANULIN, deficiency [Membrane Proteins], Axon Initial Segment, Cell Nucleus, FRONTOTEMPORAL LOBAR DEGENERATION, Science & Technology, deficiency [Nerve Tissue Proteins], MUTATIONS, Autophagosomes, metabolism [Axon Initial Segment], Membrane Proteins, ultrastructure [Lysosomes], metabolism [Motor Neurons], Cell Biology, medicine.disease, Axon initial segment, Mice, Inbred C57BL, 030104 developmental biology, nervous system, lcsh:Biology (General), Axoplasmic transport, Frontotemporal Lobar Degeneration, Lysosomes, 030217 neurology & neurosurgery, Brain Stem

Abstract

Summary: Genetic variations in TMEM106B, coding for a lysosomal membrane protein, affect frontotemporal lobar degeneration (FTLD) in GRN- (coding for progranulin) and C9orf72-expansion carriers and might play a role in aging. To determine the physiological function of TMEM106B, we generated TMEM106B-deficient mice. These mice develop proximal axonal swellings caused by drastically enlarged LAMP1-positive vacuoles, increased retrograde axonal transport of lysosomes, and accumulation of lipofuscin and autophagosomes. Giant vacuoles specifically accumulate at the distal end and within the axon initial segment, but not in peripheral nerves or at axon terminals, resulting in an impaired facial-nerve-dependent motor performance. These data implicate TMEM106B in mediating the axonal transport of LAMP1-positive organelles in motoneurons and axonal sorting at the initial segment. Our data provide mechanistic insight into how TMEM106B affects lysosomal proteolysis and degradative capacity in neurons. : Genetic variants in the TMEM106B gene, coding for a lysosomal transmembrane protein, are linked to various neurodegenerative diseases. The function of TMEM106B remains enigmatic. Lüningschrör et al. analyze Tmem106b-knockout mice and find drastically enlarged LAMP1-positive vacuoles in proximal axons of selected motoneuron nuclei. Vacuolization is caused by impaired axonal transport. Keywords: TMEM106B, frontotemporal lobar degeneration, lysosome, retrograde, axon, axon initial segment, motoneurons, FTLD

Published

2020

2. Lack of Sez6 Family Proteins Impairs Motor Functions, Short-Term Memory, and Cognitive Flexibility and Alters Dendritic Spine Properties

Author

Hiroshi Takeshima, Jenny M. Gunnersen, Martina Pigoni, Stefan F. Lichtenthaler, Tim D. Aumann, Kathryn M. Munro, and Amelia Nash

Subjects

Male, Mice, 129 Strain, Dendritic spine, Dendritic Spines, Cognitive Neuroscience, Hippocampus, Morris water navigation task, Nerve Tissue Proteins, metabolism [Hippocampus], Biology, Mice, 03 medical and health sciences, Cellular and Molecular Neuroscience, Cognition, physiology [Locomotion], 0302 clinical medicine, Animals, ddc:610, genetics [Nerve Tissue Proteins], 030304 developmental biology, Mice, Knockout, 0303 health sciences, deficiency [Nerve Tissue Proteins], Working memory, physiology [Cognition], Cognitive flexibility, Motor coordination, Mice, Inbred C57BL, Memory, Short-Term, pathology [Hippocampus], metabolism [Dendritic Spines], Motor Skills, physiology [Memory, Short-Term], Synaptic plasticity, pathology [Dendritic Spines], Motor learning, Neuroscience, Locomotion, physiology [Motor Skills], 030217 neurology & neurosurgery

Abstract

Seizure-related gene 6 (Sez6), Sez6-Like (Sez6L), and Sez6-Like 2 (Sez6L2) comprise a family of homologous proteins widely expressed throughout the brain that have been linked to neurodevelopmental and psychiatric disorders. Here, we use Sez6 triple knockout (TKO) mice, which lack all three Sez6 family proteins, to demonstrate that Sez6 family proteins regulate dendritic spine structure and cognitive functions, motor learning, and maintenance of motor functions across the lifespan. Compared to WT controls, we found that Sez6 TKO mice had impaired motor learning and their motor coordination was negatively affected from 6 weeks old and declined more rapidly as they aged. Sez6 TKO mice had reduced spine density in the hippocampus and dendritic spines were shifted to more immature morphologies in the somatosensory cortex. Cognitive testing revealed that they had enhanced stress responsiveness, impaired working, and spatial short-term memory but intact spatial long-term memory in the Morris water maze albeit accompanied by a reversal deficit. Our study demonstrates that the lack of Sez6 family proteins results in phenotypes commonly associated with neuropsychiatric disorders making it likely that Sez6 family proteins contribute to the complex etiologies of these disorders.

Published

2019

3. Parkin contributes to synaptic vesicle autophagy in Bassoon-deficient mice

Author

Sheila Hoffmann-Conaway, Marisa M Brockmann, Katharina Schneider, Anil Annamneedi, Kazi Atikur Rahman, Christine Bruns, Kathrin Textoris-Taube, Thorsten Trimbuch, Karl-Heinz Smalla, Christian Rosenmund, Eckart D Gundelfinger, Craig Curtis Garner, and Carolina Montenegro-Venegas

Subjects

Male, genetics [Synaptic Vesicles], Mouse, Vesicle-Associated Membrane Protein 2, E3 ubiquitin ligases, Hippocampus, parkin, ultrastructure [Hippocampus], Biology (General), Cells, Cultured, genetics [Nerve Tissue Proteins], presynapse, Mice, Knockout, genetics [Ubiquitin-Protein Ligases], Membrane Glycoproteins, metabolism [Vesicle-Associated Membrane Protein 2], ultrastructure [Presynaptic Terminals], enzymology [Synaptic Vesicles], Medicine, Female, Synaptic Vesicles, Research Article, Signal Transduction, autophagy, QH301-705.5, Ubiquitin-Protein Ligases, Science, Presynaptic Terminals, Nerve Tissue Proteins, ubiquitination, enzymology [Presynaptic Terminals], ultrastructure [Synaptic Vesicles], enzymology [Hippocampus], metabolism [Ubiquitin-Protein Ligases], Autophagy, Animals, metabolism [Nerve Tissue Proteins], deficiency [Nerve Tissue Proteins], bassoon, Ubiquitination, Mice, Inbred C57BL, Proteolysis, Proteostasis, mouse, neuroscience, ddc:600, metabolism [Membrane Glycoproteins], Neuroscience

Abstract

Mechanisms regulating the turnover of synaptic vesicle (SV) proteins are not well understood. They are thought to require poly-ubiquitination and degradation through proteasome, endo-lysosomal or autophagy-related pathways. Bassoon was shown to negatively regulate presynaptic autophagy in part by scaffolding Atg5. Here, we show that increased autophagy in Bassoon knockout neurons depends on poly-ubiquitination and that the loss of Bassoon leads to elevated levels of ubiquitinated synaptic proteins per se. Our data show that Bassoon knockout neurons have a smaller SV pool size and a higher turnover rate as indicated by a younger pool of SV2. The E3 ligase Parkin is required for increased autophagy in Bassoon-deficient neurons as the knockdown of Parkin normalized autophagy and SV protein levels and rescued impaired SV recycling. These data indicate that Bassoon is a key regulator of SV proteostasis and that Parkin is a key E3 ligase in the autophagy-mediated clearance of SV proteins.

Published

2020

4. Severe white matter damage in SHANK3 deficiency: a human and translational study

Author

Jesse, Sarah, Müller, Hans‐Peter, Schoen, Michael, Asoglu, Harun, Bockmann, Juergen, Huppertz, Hans‐Juergen, Rasche, Volker, Ludolph, Albert C., Boeckers, Tobias M., and Kassubek, Jan

Subjects

Adult, Male, genetics [Chromosome Disorders], physiopathology [Autism Spectrum Disorder], Adolescent, Autism Spectrum Disorder, Chromosomes, Human, Pair 22, pathology [Chromosome Disorders], Chromosome Disorders, Nerve Tissue Proteins, Neurosciences. Biological psychiatry. Neuropsychiatry, pathology [Autism Spectrum Disorder], diagnostic imaging [White Matter], Translational Research, Biomedical, Young Adult, physiopathology [Chromosome Disorders], pathology [Gray Matter], pathology [White Matter], pathology [Neurodevelopmental Disorders], Animals, Humans, ddc:610, Gray Matter, Child, RC346-429, Research Articles, Mice, Knockout, deficiency [Nerve Tissue Proteins], genetics [Neurodevelopmental Disorders], Microfilament Proteins, diagnostic imaging [Gray Matter], diagnostic imaging [Chromosome Disorders], Middle Aged, physiopathology [Neurodevelopmental Disorders], White Matter, diagnostic imaging [Neurodevelopmental Disorders], Mice, Inbred C57BL, Disease Models, Animal, Diffusion Tensor Imaging, Neurodevelopmental Disorders, Child, Preschool, genetics [Chromosomes, Human, Pair 22], genetics [Autism Spectrum Disorder], Female, Neurology. Diseases of the nervous system, Chromosome Deletion, diagnostic imaging [Autism Spectrum Disorder], Research Article, RC321-571

Abstract

Objective Heterozygous SHANK3 mutations or partial deletions of the long arm of chromosome 22, also known as Phelan–McDermid syndrome, result in a syndromic form of the autism spectrum as well as in global developmental delay, intellectual disability, and several neuropsychiatric comorbidities. The exact pathophysiological mechanisms underlying the disease are still far from being deciphered but studies of SHANK3 models have contributed to the understanding of how the loss of the synaptic protein SHANK3 affects neuronal function. Methods and results Diffusion tensor imaging‐based and automatic volumetric brain mapping were performed in 12 SHANK3‐deficient participants (mean age 19 ± 15 years) versus 14 age‐ and gender‐matched controls (mean age 29 ± 5 years). Using whole brain–based spatial statistics, we observed a highly significant pattern of white matter alterations in participants with SHANK3 mutations with focus on the long association fiber tracts, particularly the uncinate tract and the inferior fronto‐occipital fasciculus. In contrast, only subtle gray matter volumetric abnormalities were detectable. In a back‐translational approach, we observed similar white matter alterations in heterozygous isoform–specific Shank3 knockout (KO) mice. Here, in the baseline data sets, the comparison of Shank3 heterozygous KO vs wildtype showed significant fractional anisotropy reduction of the long fiber tract systems in the KO model. The multiparametric Magnetic Resonance Imaging (MRI) analysis by DTI and volumetry demonstrated a pathology pattern with severe white matter alterations and only subtle gray matter changes in the animal model. Interpretation In summary, these translational data provide strong evidence that the SHANK3‐deficiency–associated pathomechanism presents predominantly with a white matter disease. Further studies should concentrate on the role of SHANK3 during early axonal pathfinding/wiring and in myelin formation.

Published

2019

5. Disturbed Prefrontal Cortex Activity in the Absence of Schizophrenia-Like Behavioral Dysfunction in Arc/Arg3.1 Deficient Mice

Author

Dietmar Kuhl, Matthias Kneussel, Ora Ohana, Xiaoyan Gao, Ute Süsens, Jasper Grendel, Mary Muhia, Sergio Castro-Gomez, and Dirk Isbrandt

Subjects

0301 basic medicine, Male, Patch-Clamp Techniques, deficiency [Cytoskeletal Proteins], drug effects [Reflex, Startle], Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, chemically induced [Seizures], medicine, Animals, ddc:610, physiopathology [Prefrontal Cortex], Prefrontal cortex, Social Behavior, Evoked Potentials, drug effects [Memory, Short-Term], genetics [Nerve Tissue Proteins], genetics [Cytoskeletal Proteins], Mice, Knockout, Neurons, Arc (protein), deficiency [Nerve Tissue Proteins], Working memory, General Neuroscience, Dopaminergic Neurons, drug effects [Motor Activity], Dopaminergic, Environmental stressor, Excitatory Postsynaptic Potentials, Sensory Gating, medicine.disease, genetics [Seizures], 030104 developmental biology, Schizophrenia, drug effects [Electroencephalography], Synaptic plasticity, Female, Schizophrenic Psychology, Immediate early gene, Neuroscience, 030217 neurology & neurosurgery

Abstract

Arc/Arg3.1, an activity regulated immediate early gene, is essential for learning and memory, synaptic plasticity, and maturation of neural networks. It has also been implicated in several neurodevelopmental disorders, including schizophrenia. Here, we used male and female constitutive and conditionalArc/Arg3.1knock-out (KO) mice to investigate the causal relationship betweenArc/Arg3.1deletion and schizophrenia-linked neurophysiological and behavioral phenotypes. Usingin vivolocal field potential recordings, we observed dampened oscillatory activity in the prefrontal cortex (PFC) of the KO and early conditional KO (early-cKO) mice, in whichArc/Arg3.1was deleted perinatally. Whole-cell patch-clamp recordings from neurons in PFC slices revealed altered synaptic properties and reduced network gain in the KO mice as possible mechanisms underlying the oscillation deficits. In contrast, we measured normal oscillatory activity in the PFC of late conditional KO (late-cKO) mice, in whichArc/Arg3.1was deleted during late postnatal development. Our data show that constitutiveArc/Arg3.1KO mice exhibit no deficit in social engagement, working memory, sensorimotor gating, native locomotor activity, and dopaminergic innervation. Moreover, adolescent social isolation, an environmental stressor, failed to induce deficits in sociability or sensorimotor gating in adult KO mice. Thus, genetic removal ofArc/Arg3.1 per sedoes not cause schizophrenia-like behavior. Prenatal or perinatal deletion ofArc/Arg3.1alters cortical network activity, however, without overtly disrupting the balance of excitation and inhibition in the brain and not promoting schizophrenia. Misregulation ofArc/Arg3.1rather than deletion could potentially tip this balance and thereby promote emergence of schizophrenia and other neuropsychiatric disorders.SIGNIFICANCE STATEMENTThe activity-regulated and memory-linked geneArc/Arg3.1has been implicated in the pathogenesis of schizophrenia, but direct evidence and a mechanistic link are still missing. The current study asks whether loss ofArc/Arg3.1can affect brain circuitry and cause schizophrenia-like symptoms in mice. The findings demonstrate that genetic deletion ofArc/Arg3.1before puberty alters synaptic function and prefrontal cortex activity. Although brain networks are disturbed, genetic deletion ofArc/Arg3.1does not cause schizophrenia-like behavior, even when combined with an environmental insult. It remains to be seen whether misregulation ofArc/Arg3.1might critically imbalance brain networks and lead to emergence of schizophrenia.

Published

2019

6. Streptozotocin-induced β-cell damage, high fat diet, and metformin administration regulate Hes3 expression in the adult mouse brain

Author

Nikolakopoulou, Polyxeni, Chatzigeorgiou, Antonios, Consortium, German Mouse Clinic, Wolf, Eckhard, Klingenspor, Martin, Ollert, Markus, Schmidt-Weber, Carsten, Fuchs, Helmut, Gailus-Durner, Valerie, Hrabe de Angelis, Martin, Tsata, Vasiliki, Monasor, Laura Sebastian, Kourtzelis, Ioannis, Troullinaki, Maria, Witt, Anke, Anastasiou, Vivian, Chrousos, George, Yi, Chun-Xia, García-Cáceres, Cristina, Tschöp, Matthias H, Bornstein, Stefan R, Androutsellis-Theotokis, Andreas, Becker, Lore, Toutouna, Louiza, Klopstock, Thomas, Treise, Irina, Busch, Dirk H, Beckers, Johannes, Moreth, Kristin, Bekeredjian, Raffi, Garrett, Lillian, Hölter, Sabine M, Zimprich, Annemarie, Wurst, Wolfgang, Masjkur, Jimmy, Brommage, Robert, Amarie, Oana, Graw, Jochen, Calzada-Wack, Julia, Neff, Frauke, Zimmer, Andreas, Östereicher, Manuela, Steinkamp, Ralph, Lengger, Christoph, Maier, Holger, Arps-Forker, Carina, Stoeger, Claudia, Leuchtenberger, Stefanie, Poser, Steven W, Rozman, Jan, Rathkolb, Birgit, Aguilar-Pimentel, Juan Antonio, University of Zurich, Androutsellis-Theotokis, Andreas, APH - Aging & Later Life, Amsterdam Neuroscience - Cellular & Molecular Mechanisms, Laboratory for Endocrinology, AGEM - Endocrinology, metabolism and nutrition, and ACS - Diabetes & metabolism

Subjects

Male, 0301 basic medicine, Aging, medicine.medical_treatment, 10265 Clinic for Endocrinology and Diabetology, lcsh:Medicine, drug effects [Gene Expression Regulation], Type 2 diabetes, Insulin-Secreting Cells, pathology [Insulin-Secreting Cells], Basic Helix-Loop-Helix Transcription Factors, Medicine, lcsh:Science, genetics [Nerve Tissue Proteins], Multidisciplinary, Brain, toxicity [Streptozocin], Metformin, Phenotype, Hes3 protein, mouse, medicine.drug, medicine.medical_specialty, genetics [Basic Helix-Loop-Helix Transcription Factors], Nerve Tissue Proteins, 610 Medicine & health, Diet, High-Fat, Article, Streptozocin, 03 medical and health sciences, Insulin resistance, Diabetes mellitus, Internal medicine, Animals, metabolism [Aging], Progenitor cell, 1000 Multidisciplinary, Type 1 diabetes, metabolism [Nerve Tissue Proteins], deficiency [Nerve Tissue Proteins], business.industry, Insulin, lcsh:R, administration & dosage [Metformin], metabolism [Insulin-Secreting Cells], medicine.disease, Streptozotocin, Repressor Proteins, Mice, Inbred C57BL, metabolism [Basic Helix-Loop-Helix Transcription Factors], 030104 developmental biology, Endocrinology, Gene Expression Regulation, deficiency [Basic Helix-Loop-Helix Transcription Factors], metabolism [Brain], lcsh:Q, business, ddc:600, drug effects [Insulin-Secreting Cells]

Abstract

Diabetes mellitus is a group of disorders characterized by prolonged high levels of circulating blood glucose. Type 1 diabetes is caused by decreased insulin production in the pancreas whereas type 2 diabetes may develop due to obesity and lack of exercise; it begins with insulin resistance whereby cells fail to respond properly to insulin and it may also progress to decreased insulin levels. The brain is an important target for insulin, and there is great interest in understanding how diabetes affects the brain. In addition to the direct effects of insulin on the brain, diabetes may also impact the brain through modulation of the inflammatory system. Here we investigate how perturbation of circulating insulin levels affects the expression of Hes3, a transcription factor expressed in neural stem and progenitor cells that is involved in tissue regeneration. Our data show that streptozotocin-induced β-cell damage, high fat diet, as well as metformin, a common type 2 diabetes medication, regulate Hes3 levels in the brain. This work suggests that Hes3 is a valuable biomarker helping to monitor the state of endogenous neural stem and progenitor cells in the context of diabetes mellitus.

Published

2018

7. Semaphorin 4C and 4G are ligands of Plexin-B2 required in cerebellar development

Author

Noriko Takegahara, Roland H. Friedel, Christine Jolicoeur, Atsushi Kumanogoh, Wolfgang Wurst, Viola Maier, Hitoshi Kikutani, Helen Rayburn, and Marc Tessier-Lavigne

Subjects

Cerebellum, Organogenesis, deficiency [Semaphorins], Sema4c protein, mouse, Gene Expression, metabolism [Neural Stem Cells], Semaphorins, Exencephaly, Ligands, Plxnb2 protein, mouse, Mice, Neural Stem Cells, Cell Movement, In Situ Hybridization, genetics [Nerve Tissue Proteins], Neurons, Mice, Knockout, biology, Gene Expression Regulation, Developmental, metabolism [Cerebellum], Immunohistochemistry, Neural stem cell, genetics [Organogenesis], genetics [Semaphorins], metabolism [Semaphorins], medicine.anatomical_structure, metabolism [Neurons], Cerebellar cortex, embryonic structures, animal structures, Blotting, Western, embryology [Cerebellum], Nerve Tissue Proteins, Article, Cellular and Molecular Neuroscience, Sema4g protein, mouse, Semaphorin, medicine, Animals, ddc:610, Molecular Biology, metabolism [Nerve Tissue Proteins], deficiency [Nerve Tissue Proteins], Plexin, Neural tube, Cell Biology, medicine.disease, Granule cell, Molecular biology, Mice, Inbred C57BL, nervous system, biology.protein

Abstract

Semaphorins and Plexins are cognate ligand-receptor families that regulate important steps during nervous system development. The Plexin-B2 receptor is critically involved in neural tube closure and cerebellar granule cell development, however, its specific ligands have only been suggested by in vitro studies. Here, we show by in vivo and in vitro analyses that the two Semaphorin-4 family members Sema4C and Sema4G are likely to be in vivo ligands of Plexin-B2. The Sema4C and Sema4G genes are expressed in the developing cerebellar cortex, and Sema4C and Sema4G proteins specifically bind to Plexin-B2 expressing cerebellar granule cells. To further elucidate their in vivo function, we have generated and analyzed Sema4C and Sema4G knock-out mouse mutants. Like Plexin-B2−/− mutants, Sema4C−/− mutants reveal exencephaly and subsequent neonatal lethality with partial penetrance. Sema4C−/− mutants that bypass exencephaly are viable and fertile, but display distinctive defects of the cerebellar granule cell layer, including gaps in rostral lobules, fusions of caudal lobules, and ectopic granule cells in the molecular layer. In addition to neuronal defects, we observed in Sema4C−/− mutants also ventral skin pigmentation defects that are similar to those found in Plexin-B2−/− mutants. The Sema4G gene deletion causes no overt phenotype by itself, but combined deletion of Sema4C and Sema4G revealed an enhanced cerebellar phenotype. However, Sema4C/Sema4G double mutants showed overall less severe cerebellar phenotypes than Plexin-B2−/− mutants, indicating that further ligands of Plexin-B2 exist. In explant cultures of the developing cerebellar cortex, Sema4C promoted migration of cerebellar granule cell precursors in a Plexin-B2-dependent manner, supporting the model that a reduced migration rate of granule cell precursors is the basis for the cerebellar defects of Sema4C−/− and Sema4C/Sema4G mutants.

Published

2011

8. The novel membrane protein TMEM59 modulates complex glycosylation, cell surface expression, and secretion of the amyloid precursor protein

Author

Jörg Tatzelt, Stephanie Neumann, Anna Münch, Sylvia Ullrich, Stefan F. Lichtenthaler, and Elisabeth Kremmer

Subjects

N-linked glycosylation, Trans-golgi network, Alzheimers-disease, Gamma-secretase, Alpha-Secretase, Beta-secretase, Intramembrane proteolysis, Mediated endocytosis, Converting-enzyme, Cleaving enzyme, metabolism [Receptors, Cell Surface], genetics [RNA, Small Interfering], Kidney, Biochemistry, APP protein, human, chemistry.chemical_compound, Amyloid beta-Protein Precursor, Genes, Reporter, Cricetinae, metabolism [Amyloid beta-Protein Precursor], Chlorocebus aethiops, Amyloid precursor protein, Polylysine, RNA, Small Interfering, genetics [Nerve Tissue Proteins], P3 peptide, Brain, Cell biology, genetics [Membrane Proteins], Ectodomain, Alpha secretase, TMEM59L protein, human, Protein Synthesis and Degradation, genetics [Amyloid beta-Protein Precursor], Gene Knockdown Techniques, ddc:540, COS Cells, symbols, Glycosylation, Endosome, Nerve Tissue Proteins, Receptors, Cell Surface, CHO Cells, Biology, Cell Line, symbols.namesake, Cricetulus, mental disorders, Animals, Humans, Molecular Biology, deficiency [Membrane Proteins], metabolism [Nerve Tissue Proteins], deficiency [Nerve Tissue Proteins], TMEM59, Membrane Proteins, Cell Biology, Golgi apparatus, Blotting, Northern, DCF1 protein, human, Protease Nexins, chemistry, metabolism [Brain], biology.protein, metabolism [Membrane Proteins]

Abstract

Ectodomain shedding of the amyloid precursor protein (APP) by the two proteases alpha- and beta-secretase is a key regulatory event in the generation of the Alzheimer disease amyloid beta peptide (Abeta). At present, little is known about the cellular mechanisms that control APP shedding and Abeta generation. Here, we identified a novel protein, transmembrane protein 59 (TMEM59), as a new modulator of APP shedding. TMEM59 was found to be a ubiquitously expressed, Golgi-localized protein. TMEM59 transfection inhibited complex N- and O-glycosylation of APP in cultured cells. Additionally, TMEM59 induced APP retention in the Golgi and inhibited Abeta generation as well as APP cleavage by alpha- and beta-secretase cleavage, which occur at the plasma membrane and in the endosomes, respectively. Moreover, TMEM59 inhibited the complex N-glycosylation of the prion protein, suggesting a more general modulation of Golgi glycosylation reactions. Importantly, TMEM59 did not affect the secretion of soluble proteins or the alpha-secretase like shedding of tumor necrosis factor alpha, demonstrating that TMEM59 did not disturb the general Golgi function. The phenotype of TMEM59 transfection on APP glycosylation and shedding was similar to the one observed in cells lacking conserved oligomeric Golgi (COG) proteins COG1 and COG2. Both proteins are required for normal localization and activity of Golgi glycosylation enzymes. In summary, this study shows that TMEM59 expression modulates complex N- and O-glycosylation and suggests that TMEM59 affects APP shedding by reducing access of APP to the cellular compartments, where it is normally cleaved by alpha- and beta-secretase.

Published

2010