Your search keyword '"Eva L. Morozko"' showing total 8 results

1. PIAS1 modulates striatal transcription, DNA damage repair, and SUMOylation with relevance to Huntington's disease

Author

Eva L. Morozko, Charlene Smith-Geater, Alejandro Mas Monteys, Subrata Pradhan, Ryan G. Lim, Peter Langfelder, Marketta Kachemov, Jayesh A. Kulkarni, Josh Zaifman, Austin Hill, Jennifer T. Stocksdale, Pieter R. Cullis, Jie Wu, Joseph Ochaba, Ricardo Miramontes, Anirban Chakraborty, Tapas K. Hazra, Alice Lau, Sophie St-cyr, Iliana Orellana, Lexi Kopan, Keona Q. Wang, Sylvia Yeung, Blair R. Leavitt, Jack C. Reidling, X. William Yang, Joan S. Steffan, Beverly L. Davidson, Partha S. Sarkar, and Leslie M. Thompson

Subjects

Huntington's Disease, 0301 basic medicine, Male, DNA Repair, Transcription, Genetic, Mutant, SUMO protein, Neurodegenerative, Inbred C57BL, Transgenic, Mice, 0302 clinical medicine, DNA damage repair, 2.1 Biological and endogenous factors, Aetiology, RNA, Small Interfering, Induced pluripotent stem cell, Neurons, Gene knockdown, Huntingtin Protein, Multidisciplinary, Cell Differentiation, Protein Inhibitors of Activated STAT, Ubiquitin ligase, Cell biology, Phosphotransferases (Alcohol Group Acceptor), Huntington Disease, Neurological, Small Ubiquitin-Related Modifier Proteins, Female, Transcription, Pluripotent Stem Cells, PIAS, DNA damage, 1.1 Normal biological development and functioning, Primary Cell Culture, Mice, Transgenic, Biology, Small Interfering, 03 medical and health sciences, Rare Diseases, Genetic, Huntington's disease, Underpinning research, Genetics, medicine, Animals, Humans, PNKP, Gene, Protein Processing, Animal, Post-Translational, Neurosciences, Sumoylation, Correction, DNA, Stem Cell Research, medicine.disease, Brain Disorders, Mice, Inbred C57BL, Disease Models, Animal, 030104 developmental biology, DNA Repair Enzymes, SUMO, Disease Models, biology.protein, RNA, Protein Processing, Post-Translational, 030217 neurology & neurosurgery, DNA Damage

Abstract

DNA damage repair genes are modifiers of disease onset in Huntington's disease (HD), but how this process intersects with associated disease pathways remains unclear. Here we evaluated the mechanistic contributions of protein inhibitor of activated STAT-1 (PIAS1) in HD mice and HD patient-derived induced pluripotent stem cells (iPSCs) and find a link between PIAS1 and DNA damage repair pathways. We show that PIAS1 is a component of the transcription-coupled repair complex, that includes the DNA damage end processing enzyme polynucleotide kinase-phosphatase (PNKP), and that PIAS1 is a SUMO E3 ligase for PNKP. Pias1 knockdown (KD) in HD mice had a normalizing effect on HD transcriptional dysregulation associated with synaptic function and disease-associated transcriptional coexpression modules enriched for DNA damage repair mechanisms as did reduction of PIAS1 in HD iPSC-derived neurons. KD also restored mutant HTT-perturbed enzymatic activity of PNKP and modulated genomic integrity of several transcriptionally normalized genes. The findings here now link SUMO modifying machinery to DNA damage repair responses and transcriptional modulation in neurodegenerative disease.

Published

2021

2. Huntingtin Maintains Mitochondrial Genome Integrity and Function

Author

Leslie M. Thompson, Narattam Sikdar, Rui Gao, Nan Zhang, Subrata Pradhan, Tetsuo Ashizawa, Albert R. La Spada, Sanjeev Choudhary, Keegan M. Bush, Audrey S. Dickey, Tapas K. Hazra, Yogesh P. Wairkar, Partha S. Sarkar, C. Dirk Keene, Subo Yuan, Lisa M. Ellerby, Charlene Smith-Geater, Eva L. Morozko, Jeffrey Snowden, and Anirban Chakraborty

Subjects

chemistry.chemical_compound, Mitochondrial DNA, Huntingtin, chemistry, biology, DNA repair, Transcription (biology), biology.protein, Mitochondrion, Transcription factor, DNA, Polymerase, Cell biology

Abstract

SUMMARYThe function of huntingtin (HTT) is enigmatic in that the native protein provides neuroprotection while mutant HTT (mHTT) carrying an expanded stretch of glutamines triggers neurotoxicity in Huntington’s disease (HD). We recently reported that HTT forms a transcription-coupled DNA repair (TCR) complex with RNA polymerase and DNA repair enzyme polynucleotide-kinase-3'-phosphatase (PNKP). This complex resolves DNA lesions during transcription to maintain genome integrity, while mHTT impairs the activity of this complex, resulting in DNA lesion accumulation, activating the DNA damage-response in HD. Here we report that HTT forms a DNA repair complex within the mitochondria with mitochondrial RNA polymerase, transcription factors, and PNKP. This complex resolves mitochondrial DNA (mtDNA) lesions to preserve mtDNA integrity and function. Pathogenic mHTT reduces the complex activity, resulting in persistence of mtDNA lesions, impairing mitochondrial function in HD. Restoring the activity of the mtDNA repair complex in a Drosophila model of HD dramatically improves mtDNA integrity, and motor defects.

Published

2021

3. Harnessing molecular motors for nanoscale pulldown in live cells

Author

Melanie Barzik, Elizabeth A. Wilson, Spencer M. Goodman, Jonathan E. Bird, Atteeq U. Rehman, Diana Syam, Meghan C. Drummond, Eva L. Morozko, Inna A. Belyantseva, Stacey M. Cole, Tracy S. Fitzgerald, Jennifer M. Skidmore, Alexandra K. Boukhvalova, Erich T. Boger, Donna M. Martin, Thomas B. Friedman, and Daniel C. Sutton

Subjects

0301 basic medicine, Green Fluorescent Proteins, macromolecular substances, Myosins, Biology, 03 medical and health sciences, 0302 clinical medicine, Single-cell analysis, Cell Movement, Methods, Fluorescence microscope, Molecular motor, Protein Interaction Domains and Motifs, Pseudopodia, Molecular Biology, Total internal reflection fluorescence microscope, Molecular Motor Proteins, Articles, Cell Biology, Actin cytoskeleton, Molecular Imaging, Cell biology, Actin Cytoskeleton, Protein Transport, 030104 developmental biology, Microscopy, Fluorescence, Cytoplasm, Single-Cell Analysis, Filopodia, 030217 neurology & neurosurgery

Abstract

Nanoscale pulldown (NanoSPD) miniaturizes the concept of affinity pulldown to detect protein–protein interactions in live cells. NanoSPD hijacks the myosin-based intracellular trafficking machinery to assess interactions under physiological buffer conditions and is microscopy-based, allowing for sensitive detection and quantification., Protein–protein interactions (PPIs) regulate assembly of macromolecular complexes, yet remain challenging to study within the native cytoplasm where they normally exert their biological effect. Here we miniaturize the concept of affinity pulldown, a gold-standard in vitro PPI interrogation technique, to perform nanoscale pulldowns (NanoSPDs) within living cells. NanoSPD hijacks the normal process of intracellular trafficking by myosin motors to forcibly pull fluorescently tagged protein complexes along filopodial actin filaments. Using dual-color total internal reflection fluorescence microscopy, we demonstrate complex formation by showing that bait and prey molecules are simultaneously trafficked and actively concentrated into a nanoscopic volume at the tips of filopodia. The resulting molecular traffic jams at filopodial tips amplify fluorescence intensities and allow PPIs to be interrogated using standard epifluorescence microscopy. A rigorous quantification framework and software tool are provided to statistically evaluate NanoSPD data sets. We demonstrate the capabilities of NanoSPD for a range of nuclear and cytoplasmic PPIs implicated in human deafness, in addition to dissecting these interactions using domain mapping and mutagenesis experiments. The NanoSPD methodology is extensible for use with other fluorescent molecules, in addition to proteins, and the platform can be easily scaled for high-throughput applications.

Published

2017

4. Fractionation for Resolution of Soluble and Insoluble Huntingtin Species

Author

Eva L. Morozko, Jacqueline G. O’Rourke, Leslie M. Thompson, and Joseph Ochaba

Subjects

Huntington's Disease, 0301 basic medicine, Huntingtin, General Chemical Engineering, Neurodegenerative, Biochemistry, Inclusion bodies, Issue 132, Mice, 0302 clinical medicine, Models, Fluorescence microscope, 2.1 Biological and endogenous factors, Psychology, Aetiology, Dose Fractionation, Huntingtin Protein, Radiation, medicine.diagnostic_test, protein fractionation, Chemistry, General Neuroscience, aggregation, Huntington Disease, Neurological, Cognitive Sciences, Protein folding, Intracellular, huntingtin, 1.1 Normal biological development and functioning, Models, Biological, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Rare Diseases, Western blot, Underpinning research, medicine, Animals, Humans, proteostasis, General Immunology and Microbiology, Neurosciences, Biological, insoluble, Brain Disorders, 030104 developmental biology, Proteostasis, Biophysics, Dose Fractionation, Radiation, Biochemistry and Cell Biology, 030217 neurology & neurosurgery

Abstract

The accumulation of misfolded proteins is central to pathology in Huntington's disease (HD) and many other neurodegenerative disorders. Specifically, a key pathological feature of HD is the aberrant accumulation of mutant HTT (mHTT) protein into high molecular weight complexes and intracellular inclusion bodies composed of fragments and other proteins. Conventional methods to measure and understand the contributions of various forms of mHTT-containing aggregates include fluorescence microscopy, western blot analysis, and filter trap assays. However, most of these methods are conformation specific, and therefore may not resolve the full state of mHTT protein flux due to the complex nature of aggregate solubility and resolution. For the identification of aggregated mHTT and various modified forms and complexes, separation and solubilization of the cellular aggregates and fragments is mandatory. Here we describe a method to isolate and visualize soluble mHTT, monomers, oligomers, fragments, and an insoluble high molecular weight (HMW) accumulated mHTT species. HMW mHTT tracks with disease progression, corresponds with mouse behavior readouts, and has been beneficially modulated by certain therapeutic interventions1. This approach can be used with mouse brain, peripheral tissues, and cell culture but may be adapted to other model systems or disease contexts.

Published

2018

5. ILDR1 null mice, a model of human deafness DFNB42, show structural aberrations of tricellular tight junctions and degeneration of auditory hair cells

Author

Neil J. Ingham, Eva L. Morozko, Thomas B. Friedman, Tracy S. Fitzgerald, Elizabeth A. Wilson, Ayako Nishio, Gavin P. Riordan, Rashmi Chandra, Andrew Forge, Karen P. Steel, Elisa Martelletti, Philine Wangemann, Inna A. Belyantseva, Guntram Borck, and Rodger A. Liddle

Subjects

Endocochlear potential, Hearing Loss, Sensorineural, Receptors, Cell Surface, Biology, Cell junction, Tight Junctions, Mice, 03 medical and health sciences, 0302 clinical medicine, Hair Cells, Auditory, otorhinolaryngologic diseases, Genetics, medicine, Animals, Humans, Inner ear, Nonsyndromic deafness, Molecular Biology, Genetics (clinical), Cochlea, 030304 developmental biology, 0303 health sciences, Tight junction, Articles, General Medicine, Anatomy, medicine.disease, 3. Good health, Cell biology, Tissue Degeneration, Disease Models, Animal, MARVEL Domain Containing 2 Protein, medicine.anatomical_structure, Organ of Corti, Mutation, sense organs, 030217 neurology & neurosurgery

Abstract

In the mammalian inner ear, bicellular and tricellular tight junctions (tTJs) seal the paracellular space between epithelial cells. Tricellulin and immunoglobulin-like (Ig-like) domain containing receptor 1 (ILDR1, also referred to as angulin-2) localize to tTJs of the sensory and non-sensory epithelia in the organ of Corti and vestibular end organs. Recessive mutations of TRIC (DFNB49) encoding tricellulin and ILDR1 (DFNB42) cause human nonsyndromic deafness. However, the pathophysiology of DFNB42 deafness remains unknown. ILDR1 was recently reported to be a lipoprotein receptor mediating the secretion of the fat-stimulated cholecystokinin (CCK) hormone in the small intestine, while ILDR1 in EpH4 mouse mammary epithelial cells in vitro was shown to recruit tricellulin to tTJs. Here we show that two different mouse Ildr1 mutant alleles have early-onset severe deafness associated with a rapid degeneration of cochlear hair cells (HCs) but have a normal endocochlear potential. ILDR1 is not required for recruitment of tricellulin to tTJs in the cochlea in vivo; however, tricellulin becomes mislocalized in the inner ear sensory epithelia of ILDR1 null mice after the first postnatal week. As revealed by freeze-fracture electron microscopy, ILDR1 contributes to the ultrastructure of inner ear tTJs. Taken together, our data provide insight into the pathophysiology of human DFNB42 deafness and demonstrate that ILDR1 is crucial for normal hearing by maintaining the structural and functional integrity of tTJs, which are critical for the survival of auditory neurosensory HCs.

Published

2014

6. Solid-phase synthesis, characterization and RNAi activity of branch and hyperbranch siRNAs

Author

Brittany A. Blackman, Christopher J. Parronchi, Allan D. Blake, Anthony Maina, David Sabatino, Maria E. Bender, and Eva L. Morozko

Subjects

Thermal denaturation, Small interfering RNA, Programmed cell death, Circular dichroism, Cell Survival, Clinical Biochemistry, Pharmaceutical Science, Antineoplastic Agents, Biochemistry, Solid-phase synthesis, RNA interference, Drug Discovery, Humans, RNA, Small Interfering, Endoplasmic Reticulum Chaperone BiP, Molecular Biology, Solid-Phase Synthesis Techniques, Microscopy, Confocal, Chemistry, Organic Chemistry, Hep G2 Cells, Molecular biology, Cancer cell, Molecular Medicine, Cancer gene, RNA Interference

Abstract

Linear, branch and hyperbranch siRNAs were effectively prepared for down-regulating GRP78 expression and inducing cell death in HepG2 liver cancer cells. Branch and hyperbranch GRP78 siRNAs were synthesized by automated solid-phase synthesis in good yields (44–78%) and isolated in excellent purities (>99%) following HPLC purification. Moreover, siRNAs adopted stable intramolecular hybrids as discerned by native PAGE and thermal denaturation studies. These sequences also exhibited the pre-requisite A-type helical trajectory for triggering RNAi activity as determined by CD spectroscopy. Biological studies confirmed potent suppression of GRP78 expression (50–60%) while compromising cancer cell viability by ∼20%. Thus, branch and hyperbranch siRNAs may serve as potent siRNA candidates in cancer gene therapy applications.

Published

2013

7. Harnessing Molecular Motors for Nanoscale Pulldown in Live Cells

Author

Eva L. Morozko, Atteeq U. Rehman, Spencer M. Goodman, Tracy S. Fitzgerald, Erich T. Boger, Inna A. Belyantseva, Elizabeth A. Wilson, Diana Syam, Jonathan E. Bird, Jennifer M. Skidmore, Meghan C. Drummond, Stacey M. Cole, Daniel C. Sutton, Melanie Barzik, Donna M. Martin, and Thomas B. Friedman

Subjects

Cytosol, Cytoplasm, Chemistry, Myosin, Biophysics, Molecular motor, Macromolecular Complexes, macromolecular substances, Signal transduction, Nanoscopic scale

Abstract

SUMMARYProtein-protein interactions (PPIs) regulate signal transduction and cellular behavior, yet studying PPIs within live cells remains fundamentally challenging. We have miniaturized the affinity pulldown, a gold-standard PPI interrogation technique, for use within live cells. Our assay hijacks endogenous myosin motors to forcibly traffic, or pulldown, macromolecular complexes within the native cytosolic environment. Macromolecules captured by nanoscale pulldown (NanoSPD) are optically interrogated in situ by tagging individual protein components. Critically, continuous motor trafficking concentrates query complexes into nanoscopic subcellular compartments, providing fluorescence enhancement and allowing nanoscale pulldowns to be visualized and quantified by standard microscopy. Nanoscale pulldown is compatible with nuclear, membrane-associated and cytoplasmic proteins and can investigate functional effects of protein truncations or amino acid substitutions. Moreover, binding hierarchies in larger complexes can be quickly examined within the natural cytosol, making nanoscale pulldown a powerful new optical platform for quantitative high-content screening of known and novel PPIs that act within macromolecular assemblies.

Published

2016

8. Mutant Huntingtin Disrupts the Nuclear Pore Complex

Author

Jenna C. Glatzer, Jennifer Stocksdale, Laura P.W. Ranum, Wenzhen Duan, Nicolas Arbez, Ke Zhang, Jonathan C. Grima, Qi Peng, Juan C. Troncoso, Jeffrey D. Rothstein, Christopher A. Ross, Leslie M. Thompson, Kathleen C. Cunningham, J. Gavin Daigle, Harsh Wadhwa, Ishrat Ahmed, Charlene Geater, Solomon H. Snyder, Eva L. Morozko, Jacqueline T. Pham, Olga Pletnikova, Joseph Ochaba, and Thomas E. Lloyd

Subjects

Male, Huntington's Disease, 0301 basic medicine, induced pluripotent stem cell, Huntingtin, Neurodegenerative, Mice, Drosophila Proteins, 2.1 Biological and endogenous factors, Psychology, Aetiology, Nuclear pore, Huntingtin Protein, nucleocytoplasmic transport, General Neuroscience, Neurodegeneration, neurodegeneration, Middle Aged, Active Transport, Cell biology, Huntington Disease, Neurological, Drosophila, Female, Cognitive Sciences, Nucleoporin, Huntington’s disease, Adult, Induced Pluripotent Stem Cells, Active Transport, Cell Nucleus, Thiamet-G, C9ORF72, Biology, Article, Young Adult, 03 medical and health sciences, Rare Diseases, Huntington's disease, RAN translation, nuclear pore complex, medicine, Animals, Humans, KPT-350, Cell Nucleus, Neurology & Neurosurgery, Animal, Neurosciences, medicine.disease, Molecular biology, Brain Disorders, Nuclear Pore Complex Proteins, Disease Models, Animal, Orphan Drug, 030104 developmental biology, Nucleocytoplasmic Transport, Disease Models, Mutation, Ran, Nuclear Pore, O-GlcNAc

Abstract

Huntington's disease (HD) is caused by an expanded CAG repeat in the Huntingtin (HTT) gene. The mechanism(s) by which mutant HTT (mHTT) causes disease is unclear. Nucleocytoplasmic transport, the trafficking of macromolecules between the nucleus and cytoplasm, is tightly regulated by nuclear porecomplexes (NPCs) made up of nucleoporins (NUPs). Previous studies offered clues that mHTT may disrupt nucleocytoplasmic transport and a mutation of an NUP can cause HD-like pathology. Therefore, we evaluated the NPC and nucleocytoplasmic transport in multiple models of HD, including mouse and fly models, neurons transfected with mHTT, HD iPSC-derived neurons, and human HD brain regions. These studies revealed severe mislocalization and aggregation of NUPs and defective nucleocytoplasmic transport. HD repeat-associated non-ATG (RAN) translation proteins also disrupted nucleocytoplasmic transport. Additionally, overexpression of NUPs and treatment with drugs that prevent aberrant NUP biology also mitigated this transport defect and neurotoxicity, providing future novel therapy targets.

Published

2017