Your search keyword '"Gladkova C"' showing total 10 results

1. Carriage of Antibiotic-Resistant Streptococcus pneumoniae by Children in Eastern and Central Europe--A Multicenter Study with Use of Standardized Methods

Author

Appelbaum, P. C., primary, Gladkova, C., additional, Hryniewicz, W., additional, Kojouharov, B., additional, Kotulova, D., additional, Mihalcu, F., additional, Schindler, J., additional, Setchanova, L., additional, Semina, N., additional, Trupl, J., additional, Tyski, S., additional, Urbaskova, P., additional, and Jacobs, M. R., additional

Published

1996

2. Rapid deployment of SARS-CoV-2 testing: The CLIAHUB.

Author

Crawford ED, Acosta I, Ahyong V, Anderson EC, Arevalo S, Asarnow D, Axelrod S, Ayscue P, Azimi CS, Azumaya CM, Bachl S, Bachmutsky I, Bhaduri A, Brown JB, Batson J, Behnert A, Boileau RM, Bollam SR, Bonny AR, Booth D, Borja MJB, Brown D, Buie B, Burnett CE, Byrnes LE, Cabral KA, Cabrera JP, Caldera S, Canales G, Castañeda GR, Chan AP, Chang CR, Charles-Orszag A, Cheung C, Chio U, Chow ED, Citron YR, Cohen A, Cohn LB, Chiu C, Cole MA, Conrad DN, Constantino A, Cote A, Crayton-Hall T, Darmanis S, Detweiler AM, Dial RL, Dong S, Duarte EM, Dynerman D, Egger R, Fanton A, Frumm SM, Fu BXH, Garcia VE, Garcia J, Gladkova C, Goldman M, Gomez-Sjoberg R, Gordon MG, Grove JCR, Gupta S, Haddjeri-Hopkins A, Hadley P, Haliburton J, Hao SL, Hartoularos G, Herrera N, Hilberg M, Ho KYE, Hoppe N, Hosseinzadeh S, Howard CJ, Hussmann JA, Hwang E, Ingebrigtsen D, Jackson JR, Jowhar ZM, Kain D, Kim JYS, Kistler A, Kreutzfeld O, Kulsuptrakul J, Kung AF, Langelier C, Laurie MT, Lee L, Leng K, Leon KE, Leonetti MD, Levan SR, Li S, Li AW, Liu J, Lubin HS, Lyden A, Mann J, Mann S, Margulis G, Marquez DM, Marsh BP, Martyn C, McCarthy EE, McGeever A, Merriman AF, Meyer LK, Miller S, Moore MK, Mowery CT, Mukhtar T, Mwakibete LL, Narez N, Neff NF, Osso LA, Oviedo D, Peng S, Phelps M, Phong K, Picard P, Pieper LM, Pincha N, Pisco AO, Pogson A, Pourmal S, Puccinelli RR, Puschnik AS, Rackaityte E, Raghavan P, Raghavan M, Reese J, Replogle JM, Retallack H, Reyes H, Rose D, Rosenberg MF, Sanchez-Guerrero E, Sattler SM, Savy L, See SK, Sellers KK, Serpa PH, Sheehy M, Sheu J, Silas S, Streithorst JA, Strickland J, Stryke D, Sunshine S, Suslow P, Sutanto R, Tamura S, Tan M, Tan J, Tang A, Tato CM, Taylor JC, Tenvooren I, Thompson EM, Thornborrow EC, Tse E, Tung T, Turner ML, Turner VS, Turnham RE, Turocy MJ, Vaidyanathan TV, Vainchtein ID, Vanaerschot M, Vazquez SE, Wandler AM, Wapniarski A, Webber JT, Weinberg ZY, Westbrook A, Wong AW, Wong E, Worthington G, Xie F, Xu A, Yamamoto T, Yang Y, Yarza F, Zaltsman Y, Zheng T, and DeRisi JL

Subjects

Betacoronavirus, COVID-19, COVID-19 Testing, California, Humans, Pandemics, SARS-CoV-2, Workflow, Clinical Laboratory Services supply & distribution, Clinical Laboratory Techniques methods, Coronavirus Infections diagnosis, Pneumonia, Viral diagnosis

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2020

3. Insights into ubiquitin chain architecture using Ub-clipping.

Author

Swatek KN, Usher JL, Kueck AF, Gladkova C, Mevissen TET, Pruneda JN, Skern T, and Komander D

Subjects

Glycine chemistry, Glycine metabolism, HCT116 Cells, HeLa Cells, Humans, Mitophagy, Polyubiquitin chemistry, Polyubiquitin metabolism, Protein Kinases metabolism, Ubiquitin-Protein Ligases metabolism, Ubiquitination, Peptide Hydrolases metabolism, Ubiquitin chemistry, Ubiquitin metabolism

Abstract

Protein ubiquitination is a multi-functional post-translational modification that affects all cellular processes. Its versatility arises from architecturally complex polyubiquitin chains, in which individual ubiquitin moieties may be ubiquitinated on one or multiple residues, and/or modified by phosphorylation and acetylation 1-3 . Advances in mass spectrometry have enabled the mapping of individual ubiquitin modifications that generate the ubiquitin code; however, the architecture of polyubiquitin signals has remained largely inaccessible. Here we introduce Ub-clipping as a methodology by which to understand polyubiquitin signals and architectures. Ub-clipping uses an engineered viral protease, Lb pro ∗, to incompletely remove ubiquitin from substrates and leave the signature C-terminal GlyGly dipeptide attached to the modified residue; this simplifies the direct assessment of protein ubiquitination on substrates and within polyubiquitin. Monoubiquitin generated by Lb pro ∗ retains GlyGly-modified residues, enabling the quantification of multiply GlyGly-modified branch-point ubiquitin. Notably, we find that a large amount (10-20%) of ubiquitin in polymers seems to exist as branched chains. Moreover, Ub-clipping enables the assessment of co-existing ubiquitin modifications. The analysis of depolarized mitochondria reveals that PINK1/parkin-mediated mitophagy predominantly exploits mono- and short-chain polyubiquitin, in which phosphorylated ubiquitin moieties are not further modified. Ub-clipping can therefore provide insight into the combinatorial complexity and architecture of the ubiquitin code.

Published

2019

4. Mechanism of parkin activation by PINK1.

Author

Gladkova C, Maslen SL, Skehel JM, and Komander D

Subjects

Binding Sites, Deuterium Exchange Measurement, Enzyme Activation, Humans, Mass Spectrometry, Models, Molecular, Phosphorylation, Protein Domains, Tumor Suppressor Proteins metabolism, Ubiquitin Thiolesterase metabolism, Ubiquitin-Protein Ligases chemistry, Ubiquitination, Protein Kinases metabolism, Ubiquitin-Protein Ligases metabolism

Abstract

Mutations in the E3 ubiquitin ligase parkin (PARK2, also known as PRKN) and the protein kinase PINK1 (also known as PARK6) are linked to autosomal-recessive juvenile parkinsonism (AR-JP) 1,2 ; at the cellular level, these mutations cause defects in mitophagy, the process that organizes the destruction of damaged mitochondria 3,4 . Parkin is autoinhibited, and requires activation by PINK1, which phosphorylates Ser65 in ubiquitin and in the parkin ubiquitin-like (Ubl) domain. Parkin binds phospho-ubiquitin, which enables efficient parkin phosphorylation; however, the enzyme remains autoinhibited with an inaccessible active site 5,6 . It is unclear how phosphorylation of parkin activates the molecule. Here we follow the activation of full-length human parkin by hydrogen-deuterium exchange mass spectrometry, and reveal large-scale domain rearrangement in the activation process, during which the phospho-Ubl rebinds to the parkin core and releases the catalytic RING2 domain. A 1.8 Å crystal structure of phosphorylated human parkin reveals the binding site of the phospho-Ubl on the unique parkin domain (UPD), involving a phosphate-binding pocket lined by AR-JP mutations. Notably, a conserved linker region between Ubl and the UPD acts as an activating element (ACT) that contributes to RING2 release by mimicking RING2 interactions on the UPD, explaining further AR-JP mutations. Our data show how autoinhibition in parkin is resolved, and suggest a mechanism for how parkin ubiquitinates its substrates via an untethered RING2 domain. These findings open new avenues for the design of parkin activators for clinical use.

Published

2018

5. An invisible ubiquitin conformation is required for efficient phosphorylation by PINK1.

Author

Gladkova C, Schubert AF, Wagstaff JL, Pruneda JN, Freund SM, and Komander D

Subjects

Crystallization, Humans, Magnetic Resonance Spectroscopy, Models, Molecular, Models, Structural, Molecular Conformation, Phosphorylation, Point Mutation, Protein Domains, Protein Kinases genetics, Protein Stability, Substrate Specificity, Ubiquitin chemistry, Ubiquitin genetics, Protein Kinases metabolism, Ubiquitin metabolism

Abstract

The Ser/Thr protein kinase PINK1 phosphorylates the well-folded, globular protein ubiquitin (Ub) at a relatively protected site, Ser65. We previously showed that Ser65 phosphorylation results in a conformational change in which Ub adopts a dynamic equilibrium between the known, common Ub conformation and a distinct, second conformation wherein the last β-strand is retracted to extend the Ser65 loop and shorten the C-terminal tail. We show using chemical exchange saturation transfer (CEST) nuclear magnetic resonance experiments that a similar, C-terminally retracted (Ub-CR) conformation also exists at low population in wild-type Ub. Point mutations in the moving β5 and neighbouring β-strands shift the Ub/Ub-CR equilibrium. This enabled functional studies of the two states, and we show that while the Ub-CR conformation is defective for conjugation, it demonstrates improved binding to PINK1 through its extended Ser65 loop, and is a superior PINK1 substrate. Together our data suggest that PINK1 utilises a lowly populated yet more suitable Ub-CR conformation of Ub for efficient phosphorylation. Our findings could be relevant for many kinases that phosphorylate residues in folded protein domains., (© 2017 MRC Laboratory of Molecular Biology Published under the terms of the CC BY 4.0 license.)

Published

2017

6. Structure of PINK1 in complex with its substrate ubiquitin.

Author

Schubert AF, Gladkova C, Pardon E, Wagstaff JL, Freund SMV, Steyaert J, Maslen SL, and Komander D

Subjects

Animals, Binding Sites, Crystallography, X-Ray, Mitophagy, Models, Molecular, Mutation, Phosphorylation, Protein Kinases genetics, Protein Kinases immunology, Single-Chain Antibodies chemistry, Single-Chain Antibodies immunology, Pediculus enzymology, Protein Kinases chemistry, Protein Kinases metabolism, Ubiquitin chemistry, Ubiquitin metabolism

Abstract

Autosomal-recessive juvenile Parkinsonism (AR-JP) is caused by mutations in a number of PARK genes, in particular the genes encoding the E3 ubiquitin ligase Parkin (PARK2, also known as PRKN) and its upstream protein kinase PINK1 (also known as PARK6). PINK1 phosphorylates both ubiquitin and the ubiquitin-like domain of Parkin on structurally protected Ser65 residues, triggering mitophagy. Here we report a crystal structure of a nanobody-stabilized complex containing Pediculus humanus corporis (Ph)PINK1 bound to ubiquitin in the 'C-terminally retracted' (Ub-CR) conformation. The structure reveals many peculiarities of PINK1, including the architecture of the C-terminal region, and reveals how the N lobe of PINK1 binds ubiquitin via a unique insertion. The flexible Ser65 loop in the Ub-CR conformation contacts the activation segment, facilitating placement of Ser65 in a phosphate-accepting position. The structure also explains how autophosphorylation in the N lobe stabilizes structurally and functionally important insertions, and reveals the molecular basis of AR-JP-causing mutations, some of which disrupt ubiquitin binding.

Published

2017

7. Mechanism and regulation of the Lys6-selective deubiquitinase USP30.

Author

Gersch M, Gladkova C, Schubert AF, Michel MA, Maslen S, and Komander D

Subjects

Humans, Protein Binding, Protein Kinases metabolism, Substrate Specificity, Ubiquitin-Protein Ligases metabolism, Deubiquitinating Enzymes chemistry, Deubiquitinating Enzymes metabolism, Mitochondrial Proteins chemistry, Mitochondrial Proteins metabolism, Thiolester Hydrolases chemistry, Thiolester Hydrolases metabolism, Ubiquitin chemistry, Ubiquitin metabolism

Abstract

Damaged mitochondria undergo mitophagy, a specialized form of autophagy that is initiated by the protein kinase PINK1 and the ubiquitin E3 ligase Parkin. Ubiquitin-specific protease USP30 antagonizes Parkin-mediated ubiquitination events on mitochondria and is a key negative regulator of mitophagy. Parkin and USP30 both show a preference for assembly or disassembly, respectively, of Lys6-linked polyubiquitin, a chain type that has not been well studied. Here we report crystal structures of human USP30 bound to monoubiquitin and Lys6-linked diubiquitin, which explain how USP30 achieves Lys6-linkage preference through unique ubiquitin binding interfaces. We assess the interplay between USP30, PINK1 and Parkin and show that distally phosphorylated ubiquitin chains impair USP30 activity. Lys6-linkage-specific affimers identify numerous mitochondrial substrates for this modification, and we show that USP30 regulates Lys6-polyubiquitinated TOM20. Our work provides insights into the architecture, activity and regulation of USP30, which will aid drug design against this and related enzymes.

Published

2017

8. Protein translocation channel of mitochondrial inner membrane and matrix-exposed import motor communicate via two-domain coupling protein.

Author

Banerjee R, Gladkova C, Mapa K, Witte G, and Mokranjac D

Subjects

Mitochondrial Precursor Protein Import Complex Proteins, Models, Biological, Protein Transport, Saccharomyces cerevisiae metabolism, Membrane Transport Proteins metabolism, Mitochondrial Membrane Transport Proteins metabolism, Mitochondrial Membranes metabolism, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins metabolism

Abstract

The majority of mitochondrial proteins are targeted to mitochondria by N-terminal presequences and use the TIM23 complex for their translocation across the mitochondrial inner membrane. During import, translocation through the channel in the inner membrane is coupled to the ATP-dependent action of an Hsp70-based import motor at the matrix face. How these two processes are coordinated remained unclear. We show here that the two domain structure of Tim44 plays a central role in this process. The N-terminal domain of Tim44 interacts with the components of the import motor, whereas its C-terminal domain interacts with the translocation channel and is in contact with translocating proteins. Our data suggest that the translocation channel and the import motor of the TIM23 complex communicate through rearrangements of the two domains of Tim44 that are stimulated by translocating proteins.

Published

2015

9. Metformin prevents ischemia reperfusion-induced oxidative stress in the fatty liver by attenuation of reactive oxygen species formation.

Author

Cahova M, Palenickova E, Dankova H, Sticova E, Burian M, Drahota Z, Cervinkova Z, Kucera O, Gladkova C, Stopka P, Krizova J, Papackova Z, Oliyarnyk O, and Kazdova L

Subjects

Adenosine Triphosphate metabolism, Animals, Anti-Inflammatory Agents pharmacology, Apoptosis drug effects, Cytoprotection, Diet, High-Fat, Disease Models, Animal, Energy Metabolism drug effects, Inflammation Mediators metabolism, Lipid Peroxidation drug effects, Liver metabolism, Liver pathology, Male, Mitochondria, Liver drug effects, Mitochondria, Liver metabolism, Mitochondria, Liver pathology, Non-alcoholic Fatty Liver Disease etiology, Non-alcoholic Fatty Liver Disease metabolism, Non-alcoholic Fatty Liver Disease pathology, Rats, Wistar, Reperfusion Injury etiology, Reperfusion Injury metabolism, Reperfusion Injury pathology, Time Factors, Antioxidants pharmacology, Liver drug effects, Metformin pharmacology, Non-alcoholic Fatty Liver Disease drug therapy, Oxidative Stress drug effects, Reactive Oxygen Species metabolism, Reperfusion Injury prevention & control

Abstract

Nonalcoholic fatty liver disease is associated with chronic oxidative stress. In our study, we explored the antioxidant effect of antidiabetic metformin on chronic [high-fat diet (HFD)-induced] and acute oxidative stress induced by short-term warm partial ischemia-reperfusion (I/R) or on a combination of both in the liver. Wistar rats were fed a standard diet (SD) or HFD for 10 wk, half of them being administered metformin (150 mg·kg body wt(-1)·day(-1)). Metformin treatment prevented acute stress-induced necroinflammatory reaction, reduced alanine aminotransferase and aspartate aminotransferase serum activity, and diminished lipoperoxidation. The effect was more pronounced in the HFD than in the SD group. The metformin-treated groups exhibited less severe mitochondrial damage (markers: cytochrome c release, citrate synthase activity, mtDNA copy number, mitochondrial respiration) and apoptosis (caspase 9 and caspase 3 activation). Metformin-treated HFD-fed rats subjected to I/R exhibited increased antioxidant enzyme activity as well as attenuated mitochondrial respiratory capacity and ATP resynthesis. The exposure to I/R significantly increased NADH- and succinate-related reactive oxygen species (ROS) mitochondrial production in vitro. The effect of I/R was significantly alleviated by previous metformin treatment. Metformin downregulated the I/R-induced expression of proinflammatory (TNF-α, TLR4, IL-1β, Ccr2) and infiltrating monocyte (Ly6c) and macrophage (CD11b) markers. Our data indicate that metformin reduces mitochondrial performance but concomitantly protects the liver from I/R-induced injury. We propose that the beneficial effect of metformin action is based on a combination of three contributory mechanisms: increased antioxidant enzyme activity, lower mitochondrial ROS production, and reduction of postischemic inflammation., (Copyright © 2015 the American Physiological Society.)

Published

2015

10. Ubiquitin Ser65 phosphorylation affects ubiquitin structure, chain assembly and hydrolysis.

Author

Wauer T, Swatek KN, Wagstaff JL, Gladkova C, Pruneda JN, Michel MA, Gersch M, Johnson CM, Freund SM, and Komander D

Subjects

Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Allosteric Regulation physiology, Endopeptidases genetics, Endopeptidases metabolism, Endosomal Sorting Complexes Required for Transport genetics, Endosomal Sorting Complexes Required for Transport metabolism, Humans, Hydrolysis, Mitochondrial Proteins genetics, Mitochondrial Proteins metabolism, Phosphoproteins genetics, Phosphorylation physiology, Polyubiquitin genetics, Protein Structure, Tertiary, Serine genetics, Serine metabolism, TNF Receptor-Associated Factor 6 genetics, TNF Receptor-Associated Factor 6 metabolism, Thiolester Hydrolases genetics, Thiolester Hydrolases metabolism, Transcription Factors genetics, Transcription Factors metabolism, Ubiquitin Thiolesterase genetics, Ubiquitin Thiolesterase metabolism, Ubiquitin-Conjugating Enzymes genetics, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Ubiquitin-Specific Proteases genetics, Ubiquitin-Specific Proteases metabolism, Phosphoproteins metabolism, Polyubiquitin metabolism, Protein Multimerization physiology, Ubiquitination physiology

Abstract

The protein kinase PINK1 was recently shown to phosphorylate ubiquitin (Ub) on Ser65, and phosphoUb activates the E3 ligase Parkin allosterically. Here, we show that PINK1 can phosphorylate every Ub in Ub chains. Moreover, Ser65 phosphorylation alters Ub structure, generating two conformations in solution. A crystal structure of the major conformation resembles Ub but has altered surface properties. NMR reveals a second phosphoUb conformation in which β5-strand slippage retracts the C-terminal tail by two residues into the Ub core. We further show that phosphoUb has no effect on E1-mediated E2 charging but can affect discharging of E2 enzymes to form polyUb chains. Notably, UBE2R1- (CDC34), UBE2N/UBE2V1- (UBC13/UEV1A), TRAF6- and HOIP-mediated chain assembly is inhibited by phosphoUb. While Lys63-linked poly-phosphoUb is recognized by the TAB2 NZF Ub binding domain (UBD), 10 out of 12 deubiquitinases (DUBs), including USP8, USP15 and USP30, are impaired in hydrolyzing phosphoUb chains. Hence, Ub phosphorylation has repercussions for ubiquitination and deubiquitination cascades beyond Parkin activation and may provide an independent layer of regulation in the Ub system., (© 2014 MRC Laboratory of Molecular Biology. Published under the terms of the CC BY 4.0 license.)

Published

2015