Your search keyword '"Tsatskis Y"' showing total 10 results

1. Intracellular manipulation and measurement with multipole magnetic tweezers

Author

Wang, X., primary, Ho, C., additional, Tsatskis, Y., additional, Law, J., additional, Zhang, Z., additional, Zhu, M., additional, Dai, C., additional, Wang, F., additional, Tan, M., additional, Hopyan, S., additional, McNeill, H., additional, and Sun, Y., additional

Published

2019

2. The inner nuclear membrane protein NEMP1 supports nuclear envelope openings and enucleation of erythroblasts.

Author

Hodzic D, Wu J, Krchma K, Jurisicova A, Tsatskis Y, Liu Y, Ji P, Choi K, and McNeill H

Subjects

Mice, Animals, Erythroblasts metabolism, Cell Nucleus metabolism, Erythropoiesis genetics, Membrane Proteins genetics, Membrane Proteins metabolism, Mice, Knockout, Nuclear Envelope, Splenomegaly

Abstract

Nuclear envelope membrane proteins (NEMPs) are a conserved family of nuclear envelope (NE) proteins that reside within the inner nuclear membrane (INM). Even though Nemp1 knockout (KO) mice are overtly normal, they display a pronounced splenomegaly. This phenotype and recent reports describing a requirement for NE openings during erythroblasts terminal maturation led us to examine a potential role for Nemp1 in erythropoiesis. Here, we report that Nemp1 KO mice show peripheral blood defects, anemia in neonates, ineffective erythropoiesis, splenomegaly, and stress erythropoiesis. The erythroid lineage of Nemp1 KO mice is overrepresented until the pronounced apoptosis of polychromatophilic erythroblasts. We show that NEMP1 localizes to the NE of erythroblasts and their progenitors. Mechanistically, we discovered that NEMP1 accumulates into aggregates that localize near or at the edge of NE openings and Nemp1 deficiency leads to a marked decrease of both NE openings and ensuing enucleation. Together, our results for the first time demonstrate that NEMP1 is essential for NE openings and erythropoietic maturation in vivo and provide the first mouse model of defective erythropoiesis directly linked to the loss of an INM protein., Competing Interests: The authors have declared that no competing interests exist.

Published

2022

3. The NEMP family supports metazoan fertility and nuclear envelope stiffness.

Author

Tsatskis Y, Rosenfeld R, Pearson JD, Boswell C, Qu Y, Kim K, Fabian L, Mohammad A, Wang X, Robson MI, Krchma K, Wu J, Gonçalves J, Hodzic D, Wu S, Potter D, Pelletier L, Dunham WH, Gingras AC, Sun Y, Meng J, Godt D, Schedl T, Ciruna B, Choi K, Perry JRB, Bremner R, Schirmer EC, Brill JA, Jurisicova A, and McNeill H

Abstract

Human genome-wide association studies have linked single-nucleotide polymorphisms (SNPs) in NEMP1 ( nuclear envelope membrane protein 1 ) with early menopause; however, it is unclear whether NEMP1 has any role in fertility. We show that whole-animal loss of NEMP1 homologs in Drosophila , Caenorhabditis elegans , zebrafish, and mice leads to sterility or early loss of fertility. Loss of Nemp leads to nuclear shaping defects, most prominently in the germ line. Biochemical, biophysical, and genetic studies reveal that NEMP proteins support the mechanical stiffness of the germline nuclear envelope via formation of a NEMP-EMERIN complex. These data indicate that the germline nuclear envelope has specialized mechanical properties and that NEMP proteins play essential and conserved roles in fertility., (Copyright © 2020 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).)

Published

2020

4. Mechanical stability of the cell nucleus - roles played by the cytoskeleton in nuclear deformation and strain recovery.

Author

Wang X, Liu H, Zhu M, Cao C, Xu Z, Tsatskis Y, Lau K, Kuok C, Filleter T, McNeill H, Simmons CA, Hopyan S, and Sun Y

Subjects

Cell Line, Cell Membrane chemistry, Cell Membrane genetics, Cell Membrane metabolism, Cell Nucleus genetics, Cell Nucleus metabolism, Cell Nucleus Shape, Cytoskeleton chemistry, Cytoskeleton genetics, Cytoskeleton metabolism, Humans, Nuclear Envelope chemistry, Nuclear Envelope genetics, Nuclear Envelope metabolism, Stress, Mechanical, Cell Nucleus chemistry

Abstract

Extracellular forces transmitted through the cytoskeleton can deform the cell nucleus. Large nuclear deformations increase the risk of disrupting the integrity of the nuclear envelope and causing DNA damage. The mechanical stability of the nucleus defines its capability to maintain nuclear shape by minimizing nuclear deformation and allowing strain to be minimized when deformed. Understanding the deformation and recovery behavior of the nucleus requires characterization of nuclear viscoelastic properties. Here, we quantified the decoupled viscoelastic parameters of the cell membrane, cytoskeleton, and the nucleus. The results indicate that the cytoskeleton enhances nuclear mechanical stability by lowering the effective deformability of the nucleus while maintaining nuclear sensitivity to mechanical stimuli. Additionally, the cytoskeleton decreases the strain energy release rate of the nucleus and might thus prevent shape change-induced structural damage to chromatin., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

5. Atrophin controls developmental signaling pathways via interactions with Trithorax-like.

Author

Yeung K, Boija A, Karlsson E, Holmqvist PH, Tsatskis Y, Nisoli I, Yap D, Lorzadeh A, Moksa M, Hirst M, Aparicio S, Fanto M, Stenberg P, Mannervik M, and McNeill H

Subjects

Animals, Chromatin Immunoprecipitation, Protein Interaction Mapping, Sequence Analysis, DNA, DNA-Binding Proteins metabolism, Drosophila embryology, Drosophila Proteins metabolism, Gene Expression Regulation, Developmental, Signal Transduction, Transcription Factors metabolism

Abstract

Mutations in human Atrophin1 , a transcriptional corepressor, cause dentatorubral-pallidoluysian atrophy, a neurodegenerative disease. Drosophila Atrophin ( Atro ) mutants display many phenotypes, including neurodegeneration, segmentation, patterning and planar polarity defects. Despite Atro's critical role in development and disease, relatively little is known about Atro's binding partners and downstream targets. We present the first genomic analysis of Atro using ChIP-seq against endogenous Atro. ChIP-seq identified 1300 potential direct targets of Atro including engrailed , and components of the Dpp and Notch signaling pathways. We show that Atro regulates Dpp and Notch signaling in larval imaginal discs, at least partially via regulation of thickveins and fringe . In addition, bioinformatics analyses, sequential ChIP and coimmunoprecipitation experiments reveal that Atro interacts with the Drosophila GAGA Factor, Trithorax-like (Trl), and they bind to the same loci simultaneously. Phenotypic analyses of Trl and Atro clones suggest that Atro is required to modulate the transcription activation by Trl in larval imaginal discs. Taken together, these data indicate that Atro is a major Trl cofactor that functions to moderate developmental gene transcription.

Published

2017

6. Drosophila insulin release is triggered by adipose Stunted ligand to brain Methuselah receptor.

Author

Delanoue R, Meschi E, Agrawal N, Mauri A, Tsatskis Y, McNeill H, and Léopold P

Subjects

Animals, Drosophila Proteins genetics, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Eating, Fasting metabolism, Fat Body metabolism, Food, Hemolymph metabolism, Incretins metabolism, Inhibitor of Apoptosis Proteins metabolism, Ligands, Membrane Proteins genetics, Organ Culture Techniques, Positive Transcriptional Elongation Factor B metabolism, Pupa genetics, Pupa growth & development, Pupa metabolism, Receptors, G-Protein-Coupled genetics, Receptors, Gastrointestinal Hormone genetics, TOR Serine-Threonine Kinases metabolism, Adipose Tissue metabolism, Brain metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Insulin metabolism, Membrane Proteins metabolism, Receptors, G-Protein-Coupled metabolism, Receptors, Gastrointestinal Hormone metabolism

Abstract

Animals adapt their growth rate and body size to available nutrients by a general modulation of insulin-insulin-like growth factor signaling. In Drosophila, dietary amino acids promote the release in the hemolymph of brain insulin-like peptides (Dilps), which in turn activate systemic organ growth. Dilp secretion by insulin-producing cells involves a relay through unknown cytokines produced by fat cells. Here, we identify Methuselah (Mth) as a secretin-incretin receptor subfamily member required in the insulin-producing cells for proper nutrient coupling. We further show, using genetic and ex vivo organ culture experiments, that the Mth ligand Stunted (Sun) is a circulating insulinotropic peptide produced by fat cells. Therefore, Sun and Mth define a new cross-organ circuitry that modulates physiological insulin levels in response to nutrients., (Copyright © 2016, American Association for the Advancement of Science.)

Published

2016

7. The atypical cadherin fat directly regulates mitochondrial function and metabolic state.

Author

Sing A, Tsatskis Y, Fabian L, Hester I, Rosenfeld R, Serricchio M, Yau N, Bietenhader M, Shanbhag R, Jurisicova A, Brill JA, McQuibban GA, and McNeill H

Subjects

Amino Acid Sequence, Animals, Cell Adhesion Molecules chemistry, Cell Polarity, Drosophila Proteins chemistry, Electron Transport Chain Complex Proteins metabolism, Electron Transport Complex I metabolism, Eye growth & development, Genes, Tumor Suppressor, Humans, MAP Kinase Kinase 4 metabolism, Molecular Sequence Data, Protein Transport, Reactive Oxygen Species metabolism, Wings, Animal growth & development, Cadherins metabolism, Cell Adhesion Molecules metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Mitochondria metabolism

Abstract

Fat (Ft) cadherins are enormous cell adhesion molecules that function at the cell surface to regulate the tumor-suppressive Hippo signaling pathway and planar cell polarity (PCP) tissue organization. Mutations in Ft cadherins are found in a variety of tumors, and it is presumed that this is due to defects in either Hippo signaling or PCP. Here, we show Drosophila Ft functions in mitochondria to directly regulate mitochondrial electron transport chain integrity and promote oxidative phosphorylation. Proteolytic cleavage releases a soluble 68 kDa fragment (Ft(mito)) that is imported into mitochondria. Ft(mito) binds directly to NADH dehydrogenase ubiquinone flavoprotein 2 (Ndufv2), a core component of complex I, stabilizing the holoenzyme. Loss of Ft leads to loss of complex I activity, increases in reactive oxygen species, and a switch to aerobic glycolysis. Defects in mitochondrial activity in ft mutants are independent of Hippo and PCP signaling and are reminiscent of the Warburg effect., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

8. Core residue replacements cause coiled-coil orientation switching in vitro and in vivo: structure-function correlations for osmosensory transporter ProP.

Author

Tsatskis Y, Kwok SC, Becker E, Gill C, Smith MN, Keates RA, Hodges RS, and Wood JM

Subjects

Agrobacterium tumefaciens genetics, Agrobacterium tumefaciens metabolism, Amino Acid Sequence, Blotting, Western, Circular Dichroism, Dimerization, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Hydrophobic and Hydrophilic Interactions, Models, Biological, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Mutant Proteins genetics, Mutant Proteins metabolism, Mutation, Osmolar Concentration, Peptides chemical synthesis, Peptides chemistry, Peptides metabolism, Protein Binding, Protein Structure, Secondary, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Structure-Activity Relationship, Symporters genetics, Symporters metabolism, Escherichia coli Proteins chemistry, Mutant Proteins chemistry, Symporters chemistry

Abstract

Protein ProP acts as an osmosensory transporter in diverse bacteria. C-Terminal residues 468-497 of Escherichia coli ProP (ProPEc) form a four-heptad homodimeric alpha-helical coiled coil. Arg 488, at a core heptad a position, causes it to assume an antiparallel orientation. Arg in the hydrophobic core of coiled coils is destabilizing, but Arg 488 forms stabilizing interstrand salt bridges with Asp 475 and Asp 478. Mutation R488I destabilizes the coiled coil and elevates the osmotic pressure at which ProPEc activates. It may switch the coiled-coil orientation to parallel by eliminating the salt bridges and increasing the hydrophobicity of the core. In this study, mutations D475A and D478A, which disrupt the salt bridges without increasing the hydrophobicity of the coiled-coil core, had the expected modest impacts on the osmotic activation of ProPEc. The five-heptad coiled coil of Agrobacterium tumefaciens ProP (ProPAt) has K498 and R505 at a positions. Mutation K498I had little effect on the osmotic activation of ProPAt, and ProPAt-R505I was activated only at high osmotic pressure; on the other hand, the double mutant was refractory to osmotic activation. Both a synthetic peptide corresponding to ProPAt residues 478-516 and its K498I variant maintained the antiparallel orientation. The single R505I substitution created an unstable coiled coil with little orientation preference. Double mutation K498I/R505I switched the alignment, creating a stable parallel coiled coil. In vivo cross-linking showed that the C-termini of ProPAt and ProPAt-K498I/R505I were antiparallel and parallel, respectively. Thus, the antiparallel orientation of the ProP coiled coil is contingent on Arg in the hydrophobic core and interchain salt bridges. Two key amino acid replacements can convert it to a stable parallel structure, in vitro and in vivo. An intermolecular antiparallel coiled coil, present on only some orthologues, lowers the osmotic pressure required to activate ProP. Formation of a parallel coiled coil renders ProP inactive.

Published

2008

9. The tumor-suppressor gene fat controls tissue growth upstream of expanded in the hippo signaling pathway.

Author

Silva E, Tsatskis Y, Gardano L, Tapon N, and McNeill H

Subjects

Animals, Apoptosis, Cadherins genetics, Cadherins physiology, Cyclin E metabolism, Drosophila growth & development, Drosophila physiology, Eye embryology, Inhibitor of Apoptosis Proteins metabolism, Intracellular Signaling Peptides and Proteins, Membrane Proteins metabolism, RNA Processing, Post-Transcriptional, Cell Adhesion Molecules genetics, Cell Adhesion Molecules physiology, Cell Proliferation, Drosophila genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila Proteins physiology, Genes, Tumor Suppressor, Protein Serine-Threonine Kinases metabolism, Signal Transduction

Abstract

Background: The tight control of cell proliferation and cell death is essential to normal tissue development, and the loss of this control is a hallmark of cancers. Cell growth and cell death are coordinately regulated during development by the Hippo signaling pathway. The Hippo pathway consists of the Ste20 family kinase Hippo, the WW adaptor protein Salvador, and the NDR kinase Warts. Loss of Hippo signaling in Drosophila leads to enhanced cell proliferation and decreased apoptosis, resulting in massive tissue overgrowth through increased expression of targets such as Cyclin E and Diap1. The cytoskeletal proteins Merlin and Expanded colocalize at apical junctions and function redundantly upstream of Hippo. It is not clear how they regulate growth or how they are localized to apical junctions., Results: We find that another Drosophila tumor-suppressor gene, the atypical cadherin fat, regulates both cell proliferation and cell death in developing imaginal discs. Loss of fat leads to increased Cyclin E and Diap1 expression, phenocopying loss of Hippo signaling. Ft can regulate Hippo phosphorylation, a measure of its activation, in tissue culture. Importantly, fat is needed for normal localization of Expanded at apical junctions in vivo. Genetic-epistasis experiments place fat with expanded in the Hippo pathway., Conclusions: Together, these data suggest that Fat functions as a cell-surface receptor for the Expanded branch of the conserved Hippo growth control pathway.

Published

2006

10. The osmotic activation of transporter ProP is tuned by both its C-terminal coiled-coil and osmotically induced changes in phospholipid composition.

Author

Tsatskis Y, Khambati J, Dobson M, Bogdanov M, Dowhan W, and Wood JM

Subjects

Amino Acid Sequence, Arginine chemistry, Aspartic Acid chemistry, Binding Sites, Biological Transport, Blotting, Western, Cardiolipins metabolism, Cell Membrane metabolism, Codon, Terminator, Culture Media metabolism, Culture Media pharmacology, Dose-Response Relationship, Drug, Escherichia coli metabolism, Escherichia coli Proteins metabolism, Gene Deletion, Ions, Ligands, Lipids chemistry, Magnetic Resonance Spectroscopy, Membrane Transport Proteins metabolism, Models, Chemical, Molecular Sequence Data, Mutagenesis, Site-Directed, Osmolar Concentration, Phospholipids chemistry, Plasmids metabolism, Potassium chemistry, Protein Binding, Protein Conformation, Protein Structure, Secondary, Protein Structure, Tertiary, Receptors, Scavenger metabolism, Symporters metabolism, Escherichia coli Proteins physiology, Osmosis, Phospholipids metabolism, Symporters physiology

Abstract

Transporter ProP of Escherichia coli (ProPEc) senses extracellular osmolality and mediates osmoprotectant uptake when it is rising or high. A replica of the ProPEc C terminus (Asp468-Arg497) forms an intermolecular alpha-helical coiled-coil. This structure is implicated in the osmoregulation of intact ProPEc, in vivo. Like that from Corynebacterium glutamicum (ProPCg), the ProP orthologue from Agrobacterium tumefaciens (ProPAt) sensed and responded to extracellular osmolality after expression in E. coli. The osmotic activation profiles of all three orthologues depended on the osmolality of the bacterial growth medium, the osmolality required for activation rising as the growth osmolality approached 0.7 mol/kg. Thus, each could undergo osmotic adaptation. The proportion of cardiolipin in a polar lipid extract from E. coli increased with extracellular osmolality so that the osmolality activating ProPEc was a direct function of membrane cardiolipin content. Group A ProP orthologues (ProPEc, ProPAt) share the C-terminal coiled-coil domain and were activated at low osmolalities. Like variant ProPEc-R488I, in which the C-terminal coiled-coil is disrupted, ProPEc derivatives that lack the coiled-coil and Group B orthologue ProPCg required a higher osmolality to activate. The amplitude of ProPEc activation was reduced 10-fold in its deletion derivatives. The coiled-coil structure is not essential for osmotic activation of ProP per se. However, it tunes Group A orthologues to osmoregulate over a low osmolality range. Coiled-coil lesions may impair both coiled-coil formation and interaction of ProPEc with amplifier protein ProQ. Cardiolipin may contribute to ProP adaptation by altering bulk membrane properties or by acting as a ProP ligand.

Published

2005