Your search keyword '"Translocase"' showing total 566 results

1. Structure-function studies of the bacterial dsDNA translocase FtsK

Author

Graham, James Edward, Sherratt, David John, and Turberfield, Andrew J.

Subjects

572.85, Molecular biophysics (biochemistry), Escherichia coli, helicase, translocase, triplex displacement, biophysics, structural biology, chromosome segregation

Abstract

DNA translocases are molecular motors that use energy from nucleotide triphosphate (NTP) hydrolysis to move along, pump, remodel or clear DNA. Unlike helicases, double-stranded DNA (dsDNA) translocases do not unwind DNA; their action has no net product apart from inducing supercoils as a result of groove-tracking, which has hampered their characterisation. Many dsDNA translocases appear to have biased directionality. However, the inherent symmetry of dsDNA requires that translocase activity is regulated by specific sequences or through modulation by interaction partners. FtsK is a highly conserved bacterial cell-division protein, localised to the dividing septum, that coordinates chromosome segregation with cytokinesis. It is responsible for the resolution of chromosome dimers by activating the tyrosine recombinases XerCD bound to the 28bp chromosomal site dif. The C-terminal domain of FtsK (FtsKC) is a dsDNA translocase (speed ~5 kb/s, stall force ~60 pN) most closely related to superfamily 4 helicases and is active as a hexameric ring. A winged-helix subdomain at the C-terminus of FtsKC, FtsKgamma, binds to specific 8 bp sequences, KOPS, that are polarised in the bacterial chromosome from the origin to towards dif. FtsKgamma also interacts with XerD, activating it for catalysis. Studies of FtsK translocation have differed over whether KOPS act as a loading or a reversal sequence for FtsK. In Chapter 2, I use a continuous ensemble assay for dsDNA translocation to show that FtsK initiates rapidly at KOPS, with loading dependent on FtsKgamma. Translocation requires moderately cooperative ATP binding, while ATP hydrolysis has a more relaxed cooperativity. I have determined the ATP coupling efficiency of translocation to be ~1.6 bp/ATP, in line with theoretical estimates. Though FtsK probably strips most proteins from DNA, I show in Chapter 3 that FtsK stops translocating when it encounters XerCD bound to dif. The interaction is most likely a specific down-regulation, but surprisingly does not depend on FtsKgamma or on the catalytic or synaptic activity of XerCD. In Chapter 4, I show some preliminary structural data of FtsKC bound to dsDNA, with the aim of determining the first high resolution structure of a ring dsDNA translocase bound to nucleic acid.

Published

2010

2. Helical inchworming: a novel translocation mechanism for a ring ATPase

Author

Alexander B. Tong and Carlos Bustamante

Subjects

Ring atpase, biology, Chemistry, ATPase, Biophysics, Membrane biology, Optical tweezers, Chromosomal translocation, Ring (chemistry), biology.organism_classification, Bacteriophage, Structural Biology, Translocase, Commentary, Molecular motor, biology.protein, Cryo-electron microscopy, Molecular Biology, Function (biology)

Abstract

Ring ATPases perform a variety of tasks in the cell. Their function involves complex communication and coordination among the often identical subunits. Translocases in this group are of particular interest as they involve both chemical and mechanical actions in their operation. We study the DNA packaging motor of bacteriophage φ29, and using single-molecule optical tweezers and single-particle cryo-electron microscopy, have discovered a novel translocation mechanism for a molecular motor.

Published

2021

3. Structures of AAA protein translocase Bcs1 suggest translocation mechanism of a folded protein

Author

Lothar Esser, W.K. Tang, Tara Fox, N. de Val, Di Xia, Allen L. Hsu, and Mario J. Borgnia

Subjects

Adenosine Triphosphatases, Protein Folding, 0303 health sciences, biology, Chemistry, Protein subunit, Protein domain, Proteins, Article, Translocation, Genetic, Transport protein, 03 medical and health sciences, 0302 clinical medicine, Protein structure, Structural Biology, Chaperone (protein), biology.protein, Biophysics, Humans, Translocase, Protein folding, Inner mitochondrial membrane, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

The mitochondrial membrane-bound AAA protein Bcs1 translocate substrates across the mitochondrial inner membrane with-out previous unfolding. One substrate of Bcs1 is the iron–sulfur protein (ISP), a subunit of the respiratory Complex III. How Bcs1 translocates ISP across the membrane is unknown. Here we report structures of mouse Bcs1 in two different conformations, representing three nucleotide states. The apo and ADP-bound structures reveal a homo-heptamer and show a large putative substrate-binding cavity accessible to the matrix space. ATP binding drives a contraction of the cavity by concerted motion of the ATPase domains, which could push substrate across the membrane. Our findings shed light on the potential mechanism of translocating folded proteins across a membrane, offer insights into the assembly process of Complex III and allow mapping of human disease-associated mutations onto the Bcs1 structure.

Published

2020

4. Structure of HIRAN domain of human HLTF bound to duplex DNA provides structural basis for DNA unwinding to initiate replication fork regression

Author

Mamoru Sato, Asami Hishiki, and Hiroshi Hashimoto

Subjects

DNA Replication, Protein Conformation, Biochemistry, Nucleobase, chemistry.chemical_compound, Protein Domains, X-Ray Diffraction, Humans, Translocase, Protein–DNA interaction, HLTF, Molecular Biology, Transcription factor, biology, Chemistry, DNA Helicases, DNA, General Medicine, DNA Replication Fork, DNA-Binding Proteins, Duplex (building), Biophysics, biology.protein, Crystallization, DNA Damage, Protein Binding, Transcription Factors

Abstract

Replication fork regression is a mechanism to rescue a stalled fork by various replication stresses, such as DNA lesions. Helicase-like transcription factor, a SNF2 translocase, plays a central role in the fork regression and its N-terminal domain, HIRAN (HIP116 and Rad5 N-terminal), binds the 3’-hydroxy group of single-stranded DNA. Furthermore, HIRAN is supposed to bind double-stranded DNA (dsDNA) and involved in strand separation in the fork regression, whereas structural basis for mechanisms underlying dsDNA binding and strand separation by HIRAN are still unclear. Here, we report the crystal structure of HIRAN bound to duplex DNA. The structure reveals that HIRAN binds the 3’-hydroxy group of DNA and unexpectedly unwinds three nucleobases of the duplex. Phe-142 is involved in the dsDNA binding and the strand separation. In addition, the structure unravels the mechanism underlying sequence-independent recognition for purine bases by HIRAN, where the N-glycosidic bond adopts syn conformation. Our findings indicate direct involvement of HIRAN in the fork regression by separating of the daughter strand from the parental template.

Published

2020

5. INO80 and SWR1 complexes: the non-identical twins of chromatin remodelling

Author

Dale B. Wigley, Oliver Willhoft, Wellcome Trust, Cancer Research UK, and Medical Research Council (MRC)

Subjects

Protein Conformation, Biophysics, Molecular Dynamics Simulation, 0601 Biochemistry and Cell Biology, Chromatin remodelling, Article, Fungal Proteins, 03 medical and health sciences, chemistry.chemical_compound, Structure-Activity Relationship, 0302 clinical medicine, Structural Biology, 0801 Artificial Intelligence and Image Processing, Translocase, Nucleosome, Humans, Amino Acid Sequence, Molecular Biology, Actin, 030304 developmental biology, Adenosine Triphosphatases, 0303 health sciences, Binding Sites, 0304 Medicinal and Biomolecular Chemistry, biology, Chemistry, Chromatin Assembly and Disassembly, Chromatin, Cell biology, Nucleosomes, DNA-Binding Proteins, Molecular Docking Simulation, Histone, Gene Expression Regulation, Multiprotein Complexes, biology.protein, ATPases Associated with Diverse Cellular Activities, 030217 neurology & neurosurgery, DNA, Function (biology), Protein Binding

Abstract

The INO80 family of chromatin remodellers are multisubunit complexes that perform a variety of tasks on nucleosomes. Family members are built around a heterohexamer of RuvB-like protein, an ATP-dependent DNA translocase,nuclear actin and actin-related proteins, and a few complex-specific subunits. They modify chromatin in a number of ways including nucleosome sliding and exchange of variant histones. Recent structural information on INO80 and SWR1 complexes has revealed similarities in the basic architecture of the complexes. However, structural and biochemical data on the complexes bound to nucleosomes reveal these similarities to be somewhat superficial and their biochemical activities and mechanisms are very different. Consequently, the INO80 family displays a surprising diversity of function that is based upon a similar structural framework.

Published

2020

6. Unsaturated fatty acids augment protein transport via the SecA:SecYEG translocon

Author

Stephan Schott-Verdugo, Michael Kamel, Holger Gohlke, Maryna Löwe, and Alexej Kedrov

Subjects

Cardiolipins, ATPase, Lipid Bilayers, Biochemistry, environment and public health, Escherichia coli, Translocase, Secretion, ddc:610, Lipid bilayer, Molecular Biology, Phospholipids, chemistry.chemical_classification, Adenosine Triphosphatases, SecYEG Translocon, SecA Proteins, biology, Escherichia coli Proteins, Fatty acid, Membrane Proteins, Cell Biology, Tetracycline, Translocon, Transport protein, Protein Transport, Membrane, Secretory protein, chemistry, biology.protein, Biophysics, Fatty Acids, Unsaturated, bacteria, lipids (amino acids, peptides, and proteins), Cell envelope, SEC Translocation Channels, Oleandomycin

Abstract

The translocon SecYEG forms the primary protein-conducting channel in the cytoplasmic membrane of bacteria, and the associated ATPase SecA provides the energy for the transport of secretory and cell envelope protein precursors. The translocation requires negative charge at the lipid membrane surface, but its dependence on the properties of the membrane hydrophobic core is not known. Here, we demonstrate that SecA:SecYEG-mediated protein transport is immensely stimulated by unsaturated fatty acids (UFAs). Furthermore, UFA-rich tetraoleoyl-cardiolipin, but not bis(palmitoyloleoyl)-cardiolipin, facilitate the translocation via the monomeric translocon. Biophysical analysis and molecular dynamics simulations show that UFAs determine the loosely packed membrane interface, where the N-terminal amphipathic helix of SecA docks. While UFAs do not affect the translocon folding, they promote SecA binding to the membrane, and the effect is enhanced manifold at elevated ionic strength. Tight SecA:lipid interactions convert into the augmented translocation. As bacterial cells actively change their membrane composition in response to their habitat, the modulation of SecA:SecYEG activity via the fatty acids may be crucial for protein secretion over a broad range of environmental conditions.

Published

2022

7. Preproteins couple the intrinsic dynamics of SecA to its ATPase cycle to translocate via a catch and release mechanism

Author

Srinath Krishnamurthy, Anastassios Economou, Jochem H. Smit, Athina G. Portaliou, Spyridoula Karamanou, Giorgos Gouridis, Katerina E. Chatzi, Ana-Nicoleta Bondar, Marios Frantzeskos Sardis, Nikolaos Eleftheriadis, Konstantina Karathanou, and Molecular Biophysics

Subjects

SecA, Signal peptide, QH301-705.5, Protein Conformation, secretory clients, ATPase, Protein Sorting Signals, General Biochemistry, Genetics and Molecular Biology, SecYEG channel, translocase, Bacterial Proteins, protein secretion, Escherichia coli, Translocase, signal peptide, ddc:610, Biology (General), HDX-MS, Adenosine Triphosphatases, SecA Proteins, biology, Chemistry, Escherichia coli Proteins, Cell Membrane, Dynamics (mechanics), Membrane Transport Proteins, Biological Transport, enzyme activation, 500 Naturwissenschaften und Mathematik::570 Biowissenschaften, Biologie::570 Biowissenschaften, Biologie, Limiting, smFRET, intrinsic dynamics, molecular dynamics, Cytoplasm, biology.protein, Biophysics, SEC Translocation Channels

Abstract

Protein machines undergo conformational motions to interact with and manipulate polymeric substrates. The Sec translocase promiscuously recognizes, becomes activated, and secretes >500 non-folded preprotein clients across bacterial cytoplasmic membranes. Here, we reveal that the intrinsic dynamics of the translocase ATPase, SecA, and of preproteins combine to achieve translocation. SecA possesses an intrinsically dynamic preprotein clamp attached to an equally dynamic ATPase motor. Alternating motor conformations are finely controlled by the γ-phosphate of ATP, while ADP causes motor stalling, independently of clamp motions. Functional preproteins physically bridge these independent dynamics. Their signal peptides promote clamp closing; their mature domain overcomes the rate-limiting ADP release. While repeated ATP cycles shift the motor between unique states, multiple conformationally frustrated prongs in the clamp repeatedly "catch and release" trapped preprotein segments until translocation completion. This universal mechanism allows any preprotein to promiscuously recognize the translocase, usurp its intrinsic dynamics, and become secreted. ispartof: CELL REPORTS vol:38 issue:6 ispartof: location:United States status: published

Published

2022

8. Structural mechanism of GTPase-powered ribosome-tRNA movement

Author

Frank Peske, Valentyn Petrychenko, Niels Fischer, Marina V. Rodnina, Bee-Zen Peng, and Ana C. de A. P. Schwarzer

Subjects

Models, Molecular, Protein Conformation, alpha-Helical, Protein Folding, Cell signaling, Protein subunit, Science, General Physics and Astronomy, GTPase, Ribosome, Article, General Biochemistry, Genetics and Molecular Biology, RNA, Transfer, 23S ribosomal RNA, Escherichia coli, Translocase, Protein Interaction Domains and Motifs, RNA, Messenger, Molecular switch, Messenger RNA, Binding Sites, Multidisciplinary, biology, Chemistry, Hydrolysis, Cryoelectron Microscopy, General Chemistry, Ribosomal RNA, Peptide Elongation Factor G, Biomechanical Phenomena, Kinetics, RNA, Ribosomal, 23S, Protein Biosynthesis, Transfer RNA, Biophysics, biology.protein, Thermodynamics, Protein Conformation, beta-Strand, Guanosine Triphosphate, Ribosomes, Protein Binding

Abstract

GTPases are regulators of cell signaling acting as molecular switches. The translational GTPase EF-G stands out, as it uses GTP hydrolysis to generate force and promote the movement of the ribosome along the mRNA. The key unresolved question is how GTP hydrolysis drives molecular movement. Here, we visualize the GTPase-powered step of ongoing translocation by time-resolved cryo-EM. EF-G in the active GDP–Pi form stabilizes the rotated conformation of ribosomal subunits and induces twisting of the sarcin-ricin loop of the 23 S rRNA. Refolding of the GTPase switch regions upon Pi release initiates a large-scale rigid-body rotation of EF-G pivoting around the sarcin-ricin loop that facilitates back rotation of the ribosomal subunits and forward swiveling of the head domain of the small subunit, ultimately driving tRNA forward movement. The findings demonstrate how a GTPase orchestrates spontaneous thermal fluctuations of a large RNA-protein complex into force-generating molecular movement., Movement of the ribosome along an mRNA requires the universally-conserved translocase (EF-G in bacteria) that couples GTP hydrolysis to directed movement. Here the authors use time-resolved Cryo-EM to visualize the GTPase-powered step on native translocating ribosomes and capture key translocation intermediates.

Published

2021

9. Open, engage, bind, translocate: The multi-level dynamics of bacterial protein translocation

Author

Wei Chen and Elizabeth A. Komives

Subjects

Adenosine Triphosphatases, SecA Proteins, biology, Chemistry, Dynamics (mechanics), Membrane Transport Proteins, Chromosomal translocation, Motor protein, Bacterial protein, Protein Transport, Bacterial Proteins, Structural Biology, Biophysics, biology.protein, Translocase, Molecular Biology, SEC Translocation Channels

Abstract

The bacterial Sec translocase transports unfolded proteins across membranes. In this issue of Structure, Krishnamurthy et al. (2021) report a nexus of conformational dynamics in the translocase motor protein, SecA. Their findings shed light on the Sec activation mechanism and suggest a general role for multi-level dynamics in protein functions.

Published

2021

10. Structure of PINK1 reveals autophosphorylation dimer and provides insights into binding to the TOM complex

Author

Simon Veyron, Edward A. Fon, Naoto Soya, Jean-François Trempe, Shafqat Rasool, Gergely L. Lukacs, and Mohamed A. Eldeeb

Subjects

chemistry.chemical_compound, Ubiquitin, biology, Chemistry, Dimer, Autophosphorylation, biology.protein, Biophysics, Phosphorylation, Translocase, PINK1, TIM/TOM complex, Kinase activity

Abstract

SummaryMutations in PINK1 causes autosomal-recessive Parkinson’s disease. Mitochondrial damage results in PINK1 import arrest on the Translocase of the Outer Mitochondrial Membrane (TOM) complex, resulting in the activation of its ubiquitin kinase activity by autophosphorylation and initiation of Parkin-dependent mitochondrial clearance. Herein we report crystal structures of the entire cytosolic domain of insect PINK1. Our structures reveal a dimeric autophosphorylation complex targeting phosphorylation at the invariant Ser205 (human Ser228). The dimer interface requires insert 2, which is unique to PINK1. The structures also reveal how an N-terminal helix binds to the C-terminal extension and provide insights into stabilization of PINK1 on the core TOM complex.

Published

2021

11. Rad52 Oligomeric N-Terminal Domain Stabilizes Rad51 Nucleoprotein Filaments and Contributes to Their Protection against Srs2

Author

Eric Coïc, Laurent Maloisel, Léa Le Falher, Raphael Guerois, and Emilie Ma

Subjects

DNA damage, QH301-705.5, RAD52, Saccharomyces cerevisiae, genetic processes, RAD51, DNA repair, Article, Protein filament, Recombinase, Translocase, Biology (General), Homologous Recombination, Srs2, biology, Chemistry, fungi, biology.organism_classification, enzymes and coenzymes (carbohydrates), Rad52, biology.protein, Biophysics, Rad51, biological phenomena, cell phenomena, and immunity, Homologous recombination, genome stability

Abstract

Homologous recombination (HR) depends on the formation of a nucleoprotein filament of the recombinase Rad51 to scan the genome and invade the homologous sequence used as template for DNA repair synthesis. Therefore, HR is highly accurate and crucial for genome stability. Rad51 filament formation is controlled by positive and negative factors. In Saccharomyces cerevisiae, the mediator protein Rad52 catalyzes Rad51 filament formation and stabilizes them, mostly by counteracting the disruptive activity of the translocase Srs2. Srs2 activity is essential to avoid the formation of toxic Rad51 filaments, as revealed by Srs2-deficient cells. We previously reported that Rad52 SUMOylation or mutations disrupting the Rad52-Rad51 interaction suppress Rad51 filament toxicity because they disengage Rad52 from Rad51 filaments and reduce their stability. Here, we found that mutations in Rad52 N-terminal domain also suppress the DNA damage sensitivity of Srs2-deficient cells. Structural studies showed that these mutations affect the Rad52 oligomeric ring structure. Overall, in vivo and in vitro analyzes of these mutants indicate that Rad52 ring structure is important for protecting Rad51 filaments from Srs2, but can increase Rad51 filament stability and toxicity in Srs2-deficient cells. This stabilization function is distinct from Rad52 mediator and annealing activities.

Published

2021

12. Shedding light on the mitochondrial matrix through a functional membrane transporter

Author

Inmaculada García-Moreno, María D. Chiara, Jose Luis Chiara, Alberto Blázquez-Moraleja, Virginia Martínez-Martínez, Delia Álvarez-Fernández, Iñigo López Arbeloa, Ruth Prieto-Montero, Ines Sáenz-de-Santa María, Agencia Estatal de Investigación (España), Ministerio de Ciencia, Innovación y Universidades (España), European Commission, Eusko Jaurlaritza, Instituto de Salud Carlos III, Blázquez, Alberto, Sáenz-deChiara-Santa María, Inés, Chiara, María D., García-Moreno, Inmaculada, Prieto-Montero, Ruth, Martínez-Martínez, Virginia, López Arbeloa, Iñigo, Chiara, José Luis, Blázquez, Alberto [0000-0003-1375-930X], Sáenz-deChiara-Santa María, Inés [0000-0002-1868-3001], Chiara, María D. [0000-0002-1112-1583], García-Moreno, Inmaculada [0000-0002-8682-3715], Prieto-Montero, Ruth [0000-0001-6372-563X], Martínez-Martínez, Virginia [0000-0001-7551-3714], López Arbeloa, Iñigo [0000-0002-8440-6600], and Chiara, José Luis [0000-0002-8153-1852]

Subjects

BODIPY dyes, biology, Chemistry, MItochondria, Transporter, General Chemistry, Carnitine shuttle, Mitochondrion, Fluorescent dyes, Transport protein, chemistry.chemical_compound, Cell microscopy, Biomimetics, biology.protein, medicine, Biophysics, Translocase, Carnitine, BODIPY, Inner mitochondrial membrane, medicine.drug

Abstract

Electronic Supplementary Information (ESI) available: Supplementary figures and tables and copies of the 1H and 13C NMR (1D and 2D) spectra of the new compounds., The first fluorescent probes that are actively channeled into the mitochondrial matrix by a specific mitochondrial membrane transporter in living cells have been developed. The new functional probes (BCT) have a minimalist structural design based on the highly efficient and photostable BODIPY chromophore and carnitine as a biotargeting element. Both units are orthogonally bonded through the common boron atom, thus avoiding the use of complex polyatomic connectors. In contrast to known mitochondria-specific dyes, BCTs selectively label these organelles regardless of their transmembrane potential and in an enantioselective way. The obtained experimental evidence supports carnitine-acylcarnitine translocase (CACT) as the key transporter protein for BCTs, which behave therefore as acylcarnitine biomimetics. This simple structural design can be readily extended to other structurally diverse starting FBODIPYs to obtain BCTs with varied emission wavelengths along the visible and NIR spectral regions and with multifunctional capabilities. BCTs are the first fluorescent derivatives of carnitine to be used in cell microscopy and stand as promising research tools to explore the role of the carnitine shuttle system in cancer and metabolic diseases. Extension of this approach to other small-molecule mitochondrial transporters is envisaged., We gratefully acknowledge the Spanish Ministerio de Ciencia, Innovación y Universidades (MCIU), Agencia Estatal de Investigación (AEI), and European Regional Development Fund (ERDF) (projects MAT2017-83856-C3-1-P, MAT2017-83856-C3-3-P, and MAT2015-68837-REDT), Gobierno Vasco (IT912-16), and the Instituto de Salud Carlos III-Fondo de Investigación Sanitaria (CIBERONC and PI17/01901) for financial support. A. B.-M. and R. P. M. thank MCIU, AEI and ERDF, and UPV-EHU for a FPI predoctoral contract and predoctoral fellowship, respectively

Published

2021

13. Surface-exposed domains of TatB involved in the structural and functional assembly of the Tat translocase in Escherichia coli

Author

Matthias Müller, Friedel Drepper, Julia Fröbel, Anne-Sophie Blümmel, and Bettina Warscheid

Subjects

0301 basic medicine, Receptor complex, 030102 biochemistry & molecular biology, biology, Chemistry, Cell Biology, Membrane transport, Biochemistry, Twin-arginine translocation pathway, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Membrane protein, TATB, Biophysics, biology.protein, Translocase, Binding site, Molecular Biology, Linker

Abstract

Twin-arginine-dependent translocases transport folded proteins across bacterial, archaeal, and chloroplast membranes. Upon substrate binding, they assemble from hexahelical TatC and single-spanning TatA and TatB membrane proteins. Although structural and functional details of individual Tat subunits have been reported previously, the sequence and dynamics of Tat translocase assembly remain to be determined. Employing the zero-space cross-linker N,N′-dicyclohexylcarbodiimide (DCCD) in combination with LC-MS/MS, we identified as yet unknown intra- and intermolecular contact sites of TatB and TatC. In addition to their established intramembrane binding sites, both proteins were thus found to contact each other through the soluble N terminus of TatC and the interhelical linker region around the conserved glutamyl residue Glu49 of TatB from Escherichia coli. Functional analyses suggested that by interacting with the TatC N terminus, TatB improves the formation of a proficient substrate recognition site of TatC. The Glu49 region of TatB was found also to contact distinct downstream sites of a neighboring TatB molecule and to thereby mediate oligomerization of TatB within the TatBC receptor complex. Finally, we show that global DCCD-mediated cross-linking of TatB and TatC in membrane vesicles or, alternatively, creating covalently linked TatC oligomers prevents TatA from occupying a position close to the TatBC-bound substrate. Collectively, our results are consistent with a circular arrangement of the TatB and TatC units within the TatBC receptor complex and with TatA entering the interior TatBC-binding cavity through lateral gates between TatBC protomers.

Published

2019

14. Protein Translocation Activity in Surface-Supported Lipid Bilayers

Author

Kanokporn Chattrakun, Linda L. Randall, David P. Hoogerheide, Chunfeng Mao, and Gavin M. King

Subjects

Surface Properties, Lipid Bilayers, Population, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Adenosine Triphosphate, ATP hydrolysis, Electrochemistry, Translocase, General Materials Science, Lipid bilayer, education, Spectroscopy, education.field_of_study, biology, Chemistry, Bilayer, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, Transport protein, Enzyme Activation, Protein Transport, Membrane, Membrane protein, Biophysics, biology.protein, 0210 nano-technology, Mitochondrial ADP, ATP Translocases

Abstract

Surface-supported lipid bilayers are used widely throughout the nanoscience community as cellular membrane mimics. For example, they are frequently employed in single-molecule atomic force microscopy (AFM) studies to shed light on membrane protein conformational dynamics and folding. However, in AFM as well as in other surface-sensing techniques, the close proximity of the supporting surface raises questions about preservation of the biochemical activity. Employing the model translocase from the general secretory (Sec) system of Escherichia coli, here we quantify the activity via two biochemical assays in surface-supported bilayers. The first assesses ATP hydrolysis and the second assesses polypeptide translocation across the membrane via protection from added protease. Hydrolysis assays revealed distinct levels of activation ranging from medium (translocase-activated) to high (translocation-associated) that were similar to traditional solution experiments and further identified an adenosine triphosphatase population exhibiting characteristics of conformational hysteresis. Translocation assays revealed turn over numbers that were comparable to solution but with a 10-fold reduction in apparent rate constant. Despite differences in kinetics, the chemomechanical coupling (ATP hydrolyzed per residue translocated) only varied twofold on glass compared to solution. The activity changed with the topographic complexity of the underlying surface. Rough glass coverslips were favored over atomically flat mica, likely due to differences in frictional coupling between the translocating polypeptide and surface. Neutron reflectometry and AFM corroborated the biochemical measurements and provided structural characterization of the submembrane space and upper surface of the bilayer. Overall, the translocation activity was maintained for the surface-adsorbed Sec system, albeit with a slower rate-limiting step. More generally, polypeptide translocation activity measurements yield valuable quantitative metrics to assess the local environment about surface-supported lipid bilayers.

Published

2019

15. Direct quantification of the translocation activities of Saccharomyces cerevisiae Pif1 helicase

Author

Chen Lu, Jin Chen, Jie Yan, Shimin Le, Alicia K. Byrd, Daniela Rhodes, Kevin D. Raney, and School of Biological Sciences

Subjects

Saccharomyces cerevisiae Proteins, viruses, genetic processes, Saccharomyces cerevisiae, DNA, Single-Stranded, Chromosomal translocation, environment and public health, Models, Biological, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Genetics, Translocase, Molecular Biology, 030304 developmental biology, 0303 health sciences, Base Sequence, biology, Saccharomyces Cerevisiae Pif1 (ScPif1), 030302 biochemistry & molecular biology, DNA Helicases, DNA replication, Biological sciences [Science], Helicase, biology.organism_classification, Telomere, Protein Transport, enzymes and coenzymes (carbohydrates), DNA helicase activity, chemistry, health occupations, biology.protein, Biophysics, Nucleic Acid Conformation, Stress, Mechanical, ATP-dependent DNA Helicase, DNA

Abstract

Saccharomyces cerevisiae Pif1 (ScPif1) is known as an ATP-dependent DNA helicase that plays critical roles in a number of important biological processes such as DNA replication, telomere maintenance and genome stability maintenance. Besides its DNA helicase activity, ScPif1 is also known as a single-stranded DNA (ssDNA) translocase, while how ScPif1 translocates on ssDNA is unclear. Here, by measuring the translocation activity of individual ScPif1 molecules on ssDNA extended by mechanical force, we identified two distinct types of ssDNA translocation. In one type, ScPif1 moves along the ssDNA track with a rate of ∼140 nt/s in 100 μM ATP, whereas in the other type, ScPif1 is immobilized to a fixed location of ssDNA and generates ssDNA loops against force. Between the two, the mobile translocation is the major form at nanomolar ScPif1 concentrations although patrolling becomes more frequent at micromolar concentrations. Together, our results suggest that ScPif1 translocates on extended ssDNA in two distinct modes, primarily in a ‘mobile’ manner. MOE (Min. of Education, S’pore) Published version

Published

2019

16. New Insights into Amino-Terminal Translocation as Revealed by the Use of YidC and Sec Depletion Strains

Author

Alexandra Belardo, Nicholas Backes, Ross E. Dalbey, Gregory J. Phillips, Yuanyuan Chen, and Sri Karthika Shanmugam

Subjects

Amino terminal, Chromosomal translocation, medicine.disease_cause, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Escherichia coli, medicine, Translocase, Molecular Biology, 030304 developmental biology, 0303 health sciences, Strain (chemistry), biology, Chemistry, Escherichia coli Proteins, Cell Membrane, Membrane Proteins, Membrane Transport Proteins, Charge density, Fusion protein, Protein Transport, Membrane protein, Biophysics, biology.protein, SEC Translocation Channels, 030217 neurology & neurosurgery

Abstract

Different attributes of membrane protein substrates have been proposed and characterized as translocation-pathway determinants. However, several gaps in our understanding of the mechanism of targeting, insertion, and assembly of inner-membrane proteins exist. Specifically, the role played by hydrophilic N-terminal tails in pathway selection is unclear. In this study, we have evaluated length and charge density as translocase determinants using model proteins. Strikingly, the 36-residue N-tail of 2Pf3-Lep translocates independent of YidC-Sec. This is the longest known substrate of this pathway. We confirmed this using a newly constructed YidC-Sec double-depletion strain. Increasing its N-tail length with uncharged spacer peptides led to YidC dependence and eventually YidC-Sec dependence, hence establishing that length has a linear effect on translocase dependence. Tails longer than 60 residues were not inserted; however, an MBP-2Pf3-Lep fusion protein could be ranslocated. This suggests that longer N-tails can be translocated if it can engage SecA. In addition, we have examined how the positioning of charges within the translocated N-tail affects the insertion pathway. Additional charges can be translocated by the Lep TM when the charges are distributed across a longer N-tail. We tested charge density as a translocase determinant and confirmed that the addition of positive or negatives charges led to a greater dependence on YidC-Sec when they were placed close to each other than away. Findings from this work make an important advance in our existing knowledge about the different insertion mechanisms of membrane proteins in Escherichia coli.

Published

2019

17. Human HELB is a processive motor protein which catalyses RPA clearance from single-stranded DNA

Author

Hormeno S, Mark S. Dillingham, Sahiti Kuppa, Oliver J Wilkinson, Clara Aicart-Ramos, Fernando Moreno-Herrero, and Edwin Antony

Subjects

chemistry.chemical_classification, biology, DNA replication, Helicase, complex mixtures, Motor protein, enzymes and coenzymes (carbohydrates), A-site, chemistry.chemical_compound, chemistry, ATP hydrolysis, biology.protein, Biophysics, Translocase, Nucleotide, DNA

Abstract

Human HELB is a poorly-characterised helicase suggested to play both positive and negative regulatory roles in DNA replication and recombination. In this work, we used bulk and single molecule approaches to characterise the biochemical activities of HELB protein with a particular focus on its interactions with RPA and RPA-ssDNA filaments. HELB is a monomeric protein which binds tightly to ssDNA with a site size of ~20 nucleotides. It couples ATP hydrolysis to translocation along ssDNA in the 5′-to-3′ direction accompanied by the formation of DNA loops and with an efficiency of 1 ATP per base. HELB also displays classical helicase activity but this is very weak in the absence of an assisting force. HELB binds specifically to human RPA which enhances its ATPase and ssDNA translocase activities but inhibits DNA unwinding. Direct observation of HELB on RPA nucleoprotein filaments shows that translocating HELB concomitantly clears RPA from single-stranded DNA.

Published

2021

18. Anthrax toxin channel: What we know based on over 30 years of research

Author

Wenxing Liu and Ekaterina M. Nestorovich

Subjects

Pore-forming toxin, Antigens, Bacterial, Host cell cytosol, biology, Chemistry, Toxin, Protein Conformation, Anthrax toxin, Bacterial Toxins, Lipid Bilayers, Biophysics, Cell Biology, Hydrogen-Ion Concentration, medicine.disease_cause, Biochemistry, Cell biology, Cytosol, Protein Transport, medicine, biology.protein, Translocase, Lipid bilayer, Exotoxin

Abstract

Protective antigen channel is the central component of the deadly anthrax exotoxin responsible for binding and delivery of the toxin's enzymatic lethal and edema factor components into the cytosol. The channel, which is more than three times longer than the lipid bilayer membrane thickness and has a 6-A limiting diameter, is believed to provide a sophisticated unfoldase and translocase machinery for the foreign protein transport into the host cell cytosol. The tripartite toxin can be reengineered, one component at a time or collectively, to adapt it for the targeted cancer therapeutic treatments. In this review, we focus on the biophysical studies of the protective antigen channel-forming activity, small ion transport properties, enzymatic factor translocation, and blockage comparing it with the related clostridial binary toxin channels. We address issues linked to the anthrax toxin channel structural dynamics and lipid dependence, which are yet to become generally recognized as parts of the toxin translocation machinery.

Published

2021

19. Structural and Mechanistic Insights into a Specialized Secretion System Necessary for M. tuberculosis Virulence

Author

Dovala, Dustin Leard

Subjects

Biochemistry, Genetics, Biophysics, EccC, ESX, Secretion, Translocase, Tuberculosis, Type VII Secretion

Abstract

Mycobacterium tuberculosis utilizes a specialized secretion system, known as Type VII Secretion (T7S) to translocate virulence factors into the host cell. T7S is absolutely necessary for virulence of M. tuberculosis, as well as other pathogens such as S. aureus. Intriguingly, T7S systems are broadly conserved amongst all Gram-positive bacteria, and likely play diverse roles in bacterial physiology. In this work, we focused on the two conserved components present in all T7S systems: the FtsK-like ATPase EccC and the WXG-100 substrate EsxB. We developed a biochemical model system to answer questions about the structure and molecular mechanisms of these two protein components, and confirm our results using genetics in M. tuberculosis. Using this system, we i) identified the substrate-binding pocket on EccC, ii) identified the non-canonical "signal sequence" on the EsxB substrate, iii) determined the molecular basis of substrate specificity, iv) solved the structure of the EccC ATPase both bound and unbound to signal sequence, as well as the EssC homolog from Geobacillus thermodenitrificans, v) determined a molecular mechanism of EccC autoinhibition, and vi) uncovered a mechanism by which substrates control activity of EccC through multimerization. Overall, this work generated the first biochemical model for T7S.

Published

2014

20. TtOmp85, a single Omp85 member protein functions as a β-barrel protein insertase and an autotransporter translocase without any accessory proteins

Author

Enguo Fan, Sebastian Weigold, Yindi Chu, Zhe Wang, and Derrick Norrell

Subjects

0301 basic medicine, Protein Folding, Biophysics, medicine.disease_cause, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, Bacterial Proteins, Bama, medicine, Translocase, Molecular Biology, Escherichia coli, biology, Chemistry, Escherichia coli Proteins, Thermus thermophilus, Cell Membrane, food and beverages, Membrane Transport Proteins, Cell Biology, biology.organism_classification, Cell biology, Barrel, 030104 developmental biology, 030220 oncology & carcinogenesis, Mutation, biology.protein, bacteria, Bacterial outer membrane, Biogenesis, Function (biology), Bacterial Outer Membrane Proteins

Abstract

The biogenesis of outer membrane proteins requires the function of β-barrel assembly machinery (BAM), whose function is highly conserved while its composition is variable. The Escherichia coli BAM is composed of five subunits, while Thermus thermophilus seems to contain a single BAM protein, named TtOmp85. To search for the primitive form of a functional BAM, we investigated and compared the function of TtOmp85 and E. coli BAM by use of a reconstitution assay that examines the integration of OmpA and BamA from E. coli and TtoA from T. thermophilus, as well as the translocation of the E. coli Ag43. Our results show that a single TtOmp85 protein can substitute for the collective function of the five subunits constituting E. coli BAM.

Published

2021

21. Molecular communication of the membrane insertase YidC with translocase SecYEG affects client proteins

Author

Anja Steudle, Andreas Kuhn, Eva Pross, Dirk Spann, Ross E. Dalbey, and Sri Karthika Shanmugam

Subjects

0301 basic medicine, Molecular biology, Science, Proteolipids, Protein subunit, Biophysics, medicine.disease_cause, Biochemistry, Microbiology, Article, 03 medical and health sciences, 0302 clinical medicine, Escherichia coli, medicine, Translocase, Mutation, Multidisciplinary, biology, ATP synthase, Chemistry, Escherichia coli Proteins, Wild type, Membrane Transport Proteins, Transmembrane protein, Cell biology, 030104 developmental biology, Membrane, biology.protein, Medicine, SEC Translocation Channels, 030217 neurology & neurosurgery

Abstract

The membrane insertase YidC inserts newly synthesized proteins by its hydrophobic slide consisting of the two transmembrane (TM) segments TM3 and TM5. Mutations in this part of the protein affect the insertion of the client proteins. We show here that a quintuple mutation, termed YidC-5S, inhibits the insertion of the subunit a of the FoF1 ATP synthase but has no effect on the insertion of the Sec-independent M13 procoat protein and the C-tail protein SciP. Further investigations show that the interaction of YidC-5S with SecY is inhibited. The purified and fluorescently labeled YidC-5S did not approach SecYEG when both were co-reconstituted in proteoliposomes in contrast to the co-reconstituted YidC wild type. These results suggest that TM3 and TM5 are involved in the formation of a common YidC-SecYEG complex that is required for the insertion of Sec/YidC-dependent client proteins.

Published

2021

22. A Gel-Based Assay for Probing Protein Translocation on dsDNA

Author

Christiane Brugger and Alexandra M. Deaconescu

Subjects

chemistry.chemical_classification, biology, Oligonucleotide, Strategy and Management, Mechanical Engineering, Metals and Alloys, Helicase, Industrial and Manufacturing Engineering, Chromatin, chemistry.chemical_compound, chemistry, Methods Article, biology.protein, Biophysics, Translocase, Protein–DNA interaction, A-DNA, Nucleotide, DNA

Abstract

Protein translocation on DNA represents the key biochemical activity of ssDNA translocases (aka helicases) and dsDNA translocases such as chromatin remodelers. Translocation depends on DNA binding but is a distinct process as it typically involves multiple DNA binding states, which are usually dependent on nucleotide binding/hydrolysis and are characterized by different affinities for the DNA. Several translocation assays have been described to distinguish between these two modes of action, simple binding as opposed to directional movement on dsDNA. Perhaps the most widely used is the triplex-forming oligonucleotide displacement assay. Traditionally, this assay relies on the formation of a DNA triplex from a dsDNA segment and a short radioactively labeled oligonucleotide. Upon translocation of the protein of interest along the DNA substrate, the third DNA strand is destabilized and eventually released off the DNA duplex. This process can be visualized and quantitated by polyacrylamide electrophoresis. Here, we present an effective, sensitive, and convenient variation of this assay that utilizes a fluorescently labeled oligonucleotide, eliminating the need to radioactively label DNA. In short, our protocol provides a safe and user-friendly alternative. Graphical abstract: Figure 1.Schematic of the triplex-forming oligonucleotide displacement assay.

Published

2021

23. Structural snapshot of the mitochondrial protein import gate

Author

Yuhei Araiso, Toshiya Endo, and Kenichiro Imai

Subjects

0301 basic medicine, Protein Conformation, alpha-Helical, Saccharomyces cerevisiae Proteins, Protein Conformation, Protein subunit, TIM/TOM complex, Trimer, Saccharomyces cerevisiae, Mitochondrion, Biochemistry, Mitochondrial Membrane Transport Proteins, Mitochondrial Proteins, 03 medical and health sciences, 0302 clinical medicine, Mitochondrial Precursor Protein Import Complex Proteins, Translocase, Molecular Biology, biology, Chemistry, Cell Biology, Transmembrane protein, Mitochondria, Protein Transport, 030104 developmental biology, Membrane protein complex, 030220 oncology & carcinogenesis, Multiprotein Complexes, biology.protein, Biophysics, Protein Conformation, beta-Strand, Bacterial outer membrane, Carrier Proteins

Abstract

The translocase of the outer mitochondrial membrane (TOM) complex is the main entry gate for most mitochondrial proteins. The TOM complex is a multisubunit membrane protein complex consisting of a β-barrel protein Tom40 and six α-helical transmembrane (TM) proteins, receptor subunits Tom20, Tom22, and Tom70, and regulatory subunits Tom5, Tom6, and Tom7. Although nearly 30 years have passed since the main components of the TOM complex were identified and characterized, the structural details of the TOM complex remained poorly understood until recently. Thanks to the rapid development of the cryoelectron microscopy (EM) technology, high-resolution structures of the yeast TOM complex have become available. The identified structures showed a symmetric dimer containing five different subunits including Tom22. Biochemical and mutational analyses based on the TOM complex structure revealed the presence of different translocation paths within the Tom40 import channel for different classes of translocating precursor proteins. Previous studies including our cross-linking analyses indicated that the TOM complex in intact mitochondria is present as a mixture of the trimeric complex containing Tom22. Furthermore, the dimeric complex lacking Tom22, and the trimer and dimer may handle different sets of mitochondrial precursor proteins for translocation across the outer membrane. In this Structural Snapshot, we will discuss possible rearrangement of the subunit interactions upon dynamic conversion of the TOM complex between the different subunit assembly states, the Tom22-containing core dimer and trimer.

Published

2020

24. Modular and coordinated activity of AAA+ active sites in the double-ring ClpA unfoldase of the ClpAP protease

Author

Tania A. Baker, Robert T. Sauer, and Kristin L Zuromski

Subjects

Models, Molecular, Protein Conformation, ATPase, medicine.medical_treatment, Ring (chemistry), Biochemistry, Gene Expression Regulation, Enzymologic, Adenosine Triphosphate, ATP hydrolysis, medicine, Escherichia coli, Translocase, ClpAP, double-ring ATPase, molecular machine, Multidisciplinary, Protease, biology, Chemistry, Escherichia coli Proteins, Genetic Variation, Processivity, Endopeptidase Clp, Biological Sciences, Molecular machine, Mutation, Biophysics, biology.protein, cysteine cross-linking, AAA+ protease, Function (biology)

Abstract

Significance Understanding of how ClpA and other double-ring AAA+ enzymes perform mechanical work is limited. Using site-specific cross-linking and mutagenesis, we introduced ATPase-inactive AAA+ modules at alternating positions in individual ClpA rings, or in both rings, to investigate potential active-site coordination during ClpAP degradation. ClpA variants containing alternating active/inactive ATPase modules processively unfolded, translocated, and supported ClpP degradation of protein substrates with energetic efficiencies similar to, or higher than, completely active ClpA. These results impact current models describing the mechanisms of AAA+ family enzymes. The cross-linking/mutagenesis method we employed will also be useful for answering other structure-function questions about ClpA and related double-ring enzymes., ClpA is a hexameric double-ring AAA+ unfoldase/translocase that functions with the ClpP peptidase to degrade proteins that are damaged or unneeded. How the 12 ATPase active sites of ClpA, 6 in the D1 ring and 6 in the D2 ring, work together to fuel ATP-dependent degradation is not understood. We use site-specific cross-linking to engineer ClpA hexamers with alternating ATPase-active and ATPase-inactive modules in the D1 ring, the D2 ring, or both rings to determine if these active sites function together. Our results demonstrate that D2 modules coordinate with D1 modules and ClpP during mechanical work. However, there is no requirement for adjacent modules in either ring to be active for efficient enzyme function. Notably, ClpAP variants with just three alternating active D2 modules are robust protein translocases and function with double the energetic efficiency of ClpAP variants with completely active D2 rings. Although D2 is the more powerful motor, three or six active D1 modules are important for high enzyme processivity, which depends on D1 and D2 acting coordinately. These results challenge sequential models of ATP hydrolysis and coupled mechanical work by ClpAP and provide an engineering strategy that will be useful in testing other aspects of ClpAP mechanism.

Published

2020

25. Atomic structure of human TOM core complex

Author

Jingbo Yi, Laixing Zhang, Xudong Chen, Jian Yin, Wenhe Wang, Maojun Yang, Jinke Gu, Wei Zhuo, and Qingxi Ma

Subjects

biology, lcsh:Cytology, Chemistry, Dimer, Cell Biology, Biochemistry, Ribosome, Article, Cytosol, chemistry.chemical_compound, Tetramer, Structural biology, Cryoelectron microscopy, Genetics, biology.protein, Biophysics, Translocase, lcsh:QH573-671, Intermembrane space, Molecular Biology, Mitochondrial protein

Abstract

The translocase of the outer mitochondrial membrane (TOM) complex is the main entry gate for mitochondrial precursor proteins synthesized on cytosolic ribosomes. Here we report the single-particle cryo-electron microscopy (cryo-EM) structure of the dimeric human TOM core complex (TOM-CC). Two Tom40 β-barrel proteins, connected by two Tom22 receptor subunits and one phospholipid, form the protein-conducting channels. The small Tom proteins Tom5, Tom6, and Tom7 surround the channel and have notable configurations. The distinct electrostatic features of the complex, including the pronounced negative interior and the positive regions at the periphery and center of the dimer on the intermembrane space (IMS) side, provide insight into the preprotein translocation mechanism. Further, two dimeric TOM complexes may associate to form tetramer in the shape of a parallelogram, offering a potential explanation into the unusual structural features of Tom subunits and a new perspective of viewing the import of mitochondrial proteins.

Published

2020

26. Biophysical parameters of the Sec14 phospholipid exchange cycle – Effect of lipid packing in membranes

Author

Hiroyuki Nakao, Minoru Nakano, Vytas A. Bankaitis, Taichi Sugiura, Aaron H. Nile, Keisuke Ikeda, and Danish Khan

Subjects

Saccharomyces cerevisiae Proteins, Biophysics, Phospholipid, Saccharomyces cerevisiae, Biochemistry, Article, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Protein Domains, Phosphatidylcholine, Translocase, Phosphatidylinositol, Phospholipid Transfer Proteins, Phospholipids, 030304 developmental biology, Phosphatidylethanolamine, 0303 health sciences, biology, Phosphatidylcholine transfer protein, Membranes, Artificial, Cell Biology, Membrane, chemistry, Membrane curvature, biology.protein, lipids (amino acids, peptides, and proteins), 030217 neurology & neurosurgery

Abstract

Sec14, a yeast phosphatidylinositol/phosphatidylcholine transfer protein, functions at the trans-Golgi membranes. It lacks domains involved in protein-protein or protein-lipid interactions and consists solely of the Sec14 domain; hence, the mechanism underlying Sec14 function at proper sites remains unclear. In this study, we focused on the lipid packing of membranes and evaluated its association with in vitro Sec14 lipid transfer activity. Phospholipid transfer assays using pyrene-labelled phosphatidylcholine suggested that increased membrane curvature as well as the incorporation of phosphatidylethanolamine accelerated the lipid transfer. The quantity of membrane-bound Sec14 significantly increased in these membranes, indicating that "packing defects" of the membranes promote the membrane binding and phospholipid transfer of Sec14. Increased levels of phospholipid unsaturation promoted Sec14-mediated PC transfer, but had little effect on the membrane binding of the protein. Our results demonstrate the possibility that the location and function of Sec14 are regulated by the lipid packing states produced by a translocase activity at the trans-Golgi network.

Published

2020

27. Cryo-EM structure of the fully-loaded asymmetric anthrax lethal toxin in its heptameric pre-pore state

Author

Claudia Antoni, Dennis Quentin, Stefan Raunser, Christos Gatsogiannis, Alexander E. Lang, and Klaus Aktories

Subjects

Bacterial Diseases, Bacterial Lethality, Models, Molecular, Protein Conformation, Cryo-electron microscopy, Chromosomal translocation, Toxicology, Pathology and Laboratory Medicine, medicine.disease_cause, Biochemistry, Negative Staining, Virulence factor, Medical Conditions, 0302 clinical medicine, Zoonoses, Medicine and Health Sciences, Toxins, Power Distribution, Translocase, Electron Microscopy, Biology (General), Staining, Microscopy, 0303 health sciences, Crystallography, biology, Chemistry, Physics, 030302 biochemistry & molecular biology, Condensed Matter Physics, Lipids, Negative stain, Bacillus anthracis, Infectious Diseases, Physical Sciences, Crystal Structure, Engineering and Technology, Research Article, Power Grids, QH301-705.5, Anthrax toxin, Toxic Agents, Bacterial Toxins, Immunology, Research and Analysis Methods, Microbiology, Anthrax, 03 medical and health sciences, Virology, Genetics, medicine, Solid State Physics, Animals, Humans, Binding site, Molecular Biology, 030304 developmental biology, Antigens, Bacterial, Toxin, Cryoelectron Microscopy, Biology and Life Sciences, Electron Cryo-Microscopy, Bacteriology, RC581-607, biology.organism_classification, Energy and Power, Specimen Preparation and Treatment, Biophysics, biology.protein, Parasitology, Immunologic diseases. Allergy, 030217 neurology & neurosurgery

Abstract

Anthrax toxin is the major virulence factor secreted by Bacillus anthracis, causing high mortality in humans and other mammals. It consists of a membrane translocase, known as protective antigen (PA), that catalyzes the unfolding of its cytotoxic substrates lethal factor (LF) and edema factor (EF), followed by translocation into the host cell. Substrate recruitment to the heptameric PA pre-pore and subsequent translocation, however, are not well understood. Here, we report three high-resolution cryo-EM structures of the fully-loaded anthrax lethal toxin in its heptameric pre-pore state, which differ in the position and conformation of LFs. The structures reveal that three LFs interact with the heptameric PA and upon binding change their conformation to form a continuous chain of head-to-tail interactions. As a result of the underlying symmetry mismatch, one LF binding site in PA remains unoccupied. Whereas one LF directly interacts with a part of PA called α-clamp, the others do not interact with this region, indicating an intermediate state between toxin assembly and translocation. Interestingly, the interaction of the N-terminal domain with the α-clamp correlates with a higher flexibility in the C-terminal domain of the protein. Based on our data, we propose a model for toxin assembly, in which the relative position of the N-terminal α-helices in the three LFs determines which factor is translocated first., Author summary Anthrax is a life-threatening infectious disease that affects primarily livestock and wild animals, but can also cause high mortality in humans. Due to its suitability as a bioweapon and the search for an antidote, it is important to understand the molecular mechanism of infection of the anthrax pathogen and in particular of the anthrax toxin. Although the process of poisoning by anthrax toxin has been extensively investigated, many details are still missing that are required to understand the mechanism of action in molecular detail. Here, we used single-particle electron cryo microscopy to determine structures of the fully-loaded asymmetric anthrax lethal toxin in its heptameric pre-pore state. The structures reveal that three lethal factors interact with the heptameric protective antigen and upon binding change their conformation to form a continuous chain of head-to-tail interactions. Based on our data, we propose a model for toxin assembly, in which the relative position of the N-terminal region in the three lethal factors determines which factor is translocated first. Our studies provide novel insights into the organization of the anthrax lethal toxin and advance our understanding of toxin assembly and translocation.

Published

2020

28. ClpAP proteolysis does not require rotation of the ClpA unfoldase relative to ClpP

Author

Sora Kim, Kristin L Zuromski, Tristan A Bell, Robert T Sauer, and Tania A Baker

Subjects

Models, Molecular, Protein Folding, Proteases, Protein Conformation, QH301-705.5, Structural Biology and Molecular Biophysics, Science, medicine.medical_treatment, Proteolysis, Short Report, aaa+ protease, ClpXP, macromolecular substances, Protein degradation, General Biochemistry, Genetics and Molecular Biology, Biochemistry and Chemical Biology, Escherichia coli, medicine, Translocase, Biology (General), ClpAP, Protease, General Immunology and Microbiology, biology, medicine.diagnostic_test, Chemistry, Escherichia coli Proteins, General Neuroscience, E. coli, Endopeptidase Clp, General Medicine, AAA proteins, Cross-Linking Reagents, Structural biology, aaa+ atpase, biology.protein, Biophysics, Medicine

Abstract

AAA+ proteases, which perform regulated protein degradation in all kingdoms of life, consist of a hexameric AAA+ unfoldase/translocase in complex with a self-compartmentalized peptidase. Based on asymmetric features of cryo-EM structures and a sequential hand-over-hand model of substrate translocation, recent publications have proposed that the AAA+ unfoldases ClpA and ClpX must rotate with respect to their partner peptidase ClpP to allow function. Here, we test this model by covalently crosslinking ClpA to ClpP to prevent rotation. We find that crosslinked ClpAP omplexes unfold, translocate, and degrade protein substrates, albeit modestly slower han uncrosslinked enzyme controls. Rotation of ClpA with respect to ClpP therefore is ot required for ClpAP protease activity, although some flexibility in how the AAA+ ring ocks on ClpP may be necessary for optimal function.

Published

2020

29. Polarity/charge as a determinant of translocase requirements for membrane protein insertion

Author

Ross E. Dalbey, Andreas Kuhn, Eva Pross, Balasubramani Hariharan, Raunak Soman, and Sharbani Kaushik

Subjects

Polarity (physics), Biophysics, medicine.disease_cause, Biochemistry, Protein Structure, Secondary, Cell Line, 03 medical and health sciences, Mice, medicine, Escherichia coli, Translocase, Animals, 030304 developmental biology, Alanine, chemistry.chemical_classification, 0303 health sciences, biology, Chemistry, Escherichia coli Proteins, 030302 biochemistry & molecular biology, Cell Membrane, Membrane Transport Proteins, Cell Biology, Periplasmic space, Amino acid, Membrane protein, Periplasm, biology.protein, SEC Translocation Channels

Abstract

The YidC insertase of Escherichia coli inserts membrane proteins with small periplasmic loops (~20 residues). However, it has difficulty transporting loops that contain positively charged residues compared to negatively charged residues and, as a result, increasing the positive charge has an increased requirement for the Sec machinery as compared to negatively charged loops (Zhu et al., 2013; Soman et al., 2014). This suggested that the polarity and charge of the periplasmic regions of membrane proteins determine the YidC and Sec translocase requirements for insertion. Here we tested this polarity/charge hypothesis by showing that insertion of our model substrate protein procoat-Lep can become YidC/Sec dependent when the periplasmic loop was converted to highly polar even in the absence of any charged residues. Moreover, adding a number of hydrophobic amino acids to a highly polar loop can decrease the Sec-dependence of the otherwise strictly Sec-dependent membrane proteins. We also demonstrate that the length of the procoat-Lep loop is indeed a determinant for Sec-dependence by inserting alanine residues that do not markedly change the overall hydrophilicity of the periplasmic loop. Taken together, the results support the polarity/charge hypothesis as a determinant for the translocase requirement for procoat insertion.

Published

2020

30. A DNA translocase operates by cycling between planar and lock-washer structures

Author

Paul J. Jardine, Sara Tafoya, Juan P. Castillo, Carlos Bustamante, and Alexander B. Tong

Subjects

Materials science, biology, Ring (chemistry), Turn (biochemistry), Mechanism (engineering), chemistry.chemical_compound, Planar, chemistry, Helix, Biophysics, biology.protein, Translocase, A-DNA, DNA

Abstract

Ring ATPases that translocate disordered polymers possess lock-washer architectures that they impose on their substrates during transport via a hand-over-hand mechanism. Here, we investigate the operation of ring motors that transport substrates possessing a preexisting helical structure, such as the bacteriophage ϕ29 dsDNA packaging motor. During each cycle, this pentameric motor tracks one helix strand (the ‘tracking strand’), and alternates between two segregated phases: a dwell in which it exchanges ADP for ATP and a burst in which it packages a full turn of DNA in four steps. We challenge this motor with DNA-RNA hybrids and dsRNA substrates and find that it adapts the size of its burst to the corresponding shorter helical pitches by keeping three of its power strokes invariant while shortening the fourth. Intermittently, the motor loses grip when the tracking strand is RNA, indicating that it makes load-bearing contacts with the substrate that are optimal with dsDNA. The motor possesses weaker grip when ADP-bound at the end of the burst. To rationalize all these observations, we propose a helical inchworm translocation mechanism in which the motor increasingly adopts a lock-washer structure during the ATP loading dwell and successively regains its planar form with each power stroke during the burst.

Published

2020

31. Twin-arginine translocase component TatB performs folding quality control via a general chaperone activity

Author

Dujduan Waraho-Zhmayev, Jason T. Boock, Matthew P. DeLisa, May N. Taw, Daniel Kim, and Mark A. Rocco

Subjects

0303 health sciences, biology, 030302 biochemistry & molecular biology, Folding (chemistry), 03 medical and health sciences, chemistry.chemical_compound, chemistry, TATB, Cytoplasm, biology.protein, Biophysics, Translocase, Proofreading, Citrate synthase, Protein folding, Lipid bilayer, 030304 developmental biology

Abstract

The twin-arginine translocation (Tat) pathway involves an inbuilt quality control (QC) system that synchronizes proofreading of substrate protein folding with lipid bilayer transport. However, the molecular details of this QC mechanism remain poorly understood. Here, we hypothesized that the conformational state of Tat substrates is directly sensed by the TatB component of the bacterial Tat translocase. In support of this hypothesis, several TatB variants in which the cytoplasmic membrane-extrinsic domain was either truncated or mutated in the vicinity of a conserved, highly flexible α-helical domain were observed to form functional translocases in vivo that had compromised QC activity as evidenced by the uncharacteristic export of several misfolded protein substrates. In vitro folding experiments revealed that the membrane-extrinsic domain of TatB possessed general chaperone activity, transiently binding to highly structured, partially unfolded intermediates of a model protein, citrate synthase, thereby preventing its irreversible aggregation and stabilizing the active species. Collectively, these results suggest that the Tat translocase may use chaperone-like client recognition to monitor the conformational status of its substrates.

Published

2020

32. Insights into substrate-mediated assembly of the chloroplast TAT receptor complex

Author

Christopher Paul New, Carole Dabney-Smith, and Qianqian Ma

Subjects

Chloroplast, Signal peptide, Transmembrane domain, Receptor complex, Arginine transport, biology, Cytoplasm, Chemistry, Thylakoid, Biophysics, biology.protein, Translocase

Abstract

TheTwinArginineTransport (TAT) system translocates fully folded proteins across the thylakoid membrane in the chloroplast (cp) and the cytoplasmic membrane of bacteria. In chloroplasts, cpTAT transport is achieved by three components: Tha4, Hcf106, and cpTatC. Hcf106 and cpTatC function as the substrate recognition/binding complex while Tha4 is thought to play a significant role in forming the translocation pore. Recent studies challenged this idea by suggesting that cpTatC-Hcf106-Tha4 function together in the active translocase. Here, we have mapped the inter-subunit contacts of cpTatC-Hcf106 during the resting state and built a cpTatC-Hcf106 structural model based on our crosslinking data. In addition, we have identified a substrate-mediated reorganization of cpTatC-Hcf106 contact sites during active substrate translocation. The proximity of Tha4 to the cpTatC-Hcf106 complex was also identified. Our data suggest a model for cpTAT function in which the transmembrane helices of Hcf106 and Tha4 may each contact the fifth transmembrane helix of cpTatC while the insertion of the substrate signal peptide may rearrange the cpTatC-Hcf106-Tha4 complex and initiate the translocation event.One sentence summaryProtein subunits of the thylakoidal twin arginine transport complex function together during substrate recognition and translocase assembly.

Published

2020

33. Characterizing the Locus of a Peripheral Membrane Protein-Lipid Bilayer Interaction Underlying Protein Export Activity in

Author

Ioan Kosztin, Milica Utjesanovic, Krishna P. Sigdel, Tina R. Matin, Virginia F. Smith, and Gavin M. King

Subjects

Circular dichroism, Lipid Bilayers, 02 engineering and technology, 010402 general chemistry, medicine.disease_cause, 01 natural sciences, Bacterial Proteins, Protein targeting, Electrochemistry, medicine, Escherichia coli, Inner membrane, Translocase, General Materials Science, Lipid bilayer, Protein secondary structure, Spectroscopy, Adenosine Triphosphatases, SecA Proteins, biology, Chemistry, Bilayer, Escherichia coli Proteins, Peripheral membrane protein, Surfaces and Interfaces, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 0104 chemical sciences, biology.protein, Biophysics, 0210 nano-technology, SEC Translocation Channels

Abstract

Quantitative characterization of the strength of peripheral membrane protein-lipid bilayer interactions is fundamental in the understanding of many protein targeting pathways. SecA is a peripheral membrane protein that plays a central role in translocating precursor proteins across the inner membrane of E. coli. The membrane binding activity of the extreme N-terminus of SecA is critical for translocase function. Yet, the mechanical strength of the interaction and the kinetic pathways that this segment of SecA experiences when in proximity of an E. coli polar lipid bilayer has not been characterized. We directly measured the N-terminal SecA-lipid bilayer interaction using precision single molecule atomic force microscope (AFM)-based dynamic force spectroscopy. To provide conformational data inaccessible to AFM, we also performed all-atom molecular dynamics simulations and circular dichroism measurements. The N-terminal 10 amino acids of SecA have little secondary structure when bound to zwitterionic lipid head groups, but secondary structure, which rigidifies the lipid-bound protein segment, emerges when negatively charged lipids are present. Analysis of the single molecule protein-lipid dissociation data converged to a well-defined lipid-bound-state lifetime in the absence of force, τ0lipid = 0.9 s, which is well separated from and longer than the fundamental time scale of the secretion process, defined as the time required to translocate a single amino acid residue (∼50 ms). This value of τ0lipid is likely to represent a lower limit of the in vivo membrane-bound lifetime due to factors including the minimal system employed here.

Published

2020

34. The interaction of the mitochondrial protein importer TOMM34 with HSP70 is regulated by TOMM34 phosphorylation and binding to 14-3-3 adaptors

Author

Oliver Simoncik, Daniel Kavan, Pavla Vankova, Petr Müller, Petr Man, Filip Trčka, Michal Durech, Borivoj Vojtesek, and Veronika Vandová

Subjects

0301 basic medicine, HSP72 Heat-Shock Proteins, Plasma protein binding, Biochemistry, Mitochondrial Membrane Transport Proteins, Protein–protein interaction, Mitochondrial Proteins, 03 medical and health sciences, Mitochondrial Precursor Protein Import Complex Proteins, Translocase, Humans, HSP70 Heat-Shock Proteins, HSP90 Heat-Shock Proteins, Phosphorylation, Protein kinase A, Molecular Biology, 030102 biochemistry & molecular biology, biology, Chemistry, Cell Biology, Cyclic AMP-Dependent Protein Kinases, Transport protein, DNA-Binding Proteins, Tetratricopeptide, 030104 developmental biology, 14-3-3 Proteins, Mitochondrial Membranes, Protein Structure and Folding, biology.protein, Biophysics, MCF-7 Cells, Protein folding, Molecular Chaperones, Protein Binding, Signal Transduction, Transcription Factors

Abstract

Translocase of outer mitochondrial membrane 34 (TOMM34) orchestrates heat shock protein 70 (HSP70)/HSP90–mediated transport of mitochondrial precursor proteins. Here, using in vitro phosphorylation and refolding assays, analytical size-exclusion chromatography, and hydrogen/deuterium exchange MS, we found that TOMM34 associates with 14-3-3 proteins after its phosphorylation by protein kinase A (PKA). PKA preferentially targeted two serine residues in TOMM34: Ser(93) and Ser(160), located in the tetratricopeptide repeat 1 (TPR1) domain and the interdomain linker, respectively. Both of these residues were necessary for efficient 14-3-3 protein binding. We determined that phosphorylation-induced structural changes in TOMM34 are further augmented by binding to 14-3-3, leading to destabilization of TOMM34's secondary structure. We also observed that this interaction with 14-3-3 occludes the TOMM34 interaction interface with ATP-bound HSP70 dimers, which leaves them intact and thereby eliminates an inhibitory effect of TOMM34 on HSP70-mediated refolding in vitro. In contrast, we noted that TOMM34 in complex with 14-3-3 could bind HSP90. Both TOMM34 and 14-3-3 participated in cytosolic precursor protein transport mediated by the coordinated activities of HSP70 and HSP90. Our results provide important insights into how PKA-mediated phosphorylation and 14-3-3 binding regulate the availability of TOMM34 for its interaction with HSP70.

Published

2020

35. The structure of the TOM core complex in the mitochondrial outer membrane

Author

Stephan Nussberger, Jie Liang, Hammad Naveed, and Thomas Bausewein

Subjects

0301 basic medicine, Protein Conformation, Protein subunit, Clinical Biochemistry, TIM/TOM complex, Saccharomyces cerevisiae, Biochemistry, Neurospora crassa, 03 medical and health sciences, 0302 clinical medicine, Mitochondrial Precursor Protein Import Complex Proteins, Translocase, Molecular Biology, biology, Chemistry, biology.organism_classification, Transmembrane protein, Transport protein, Mitochondria, 030104 developmental biology, Membrane protein, Mitochondrial Membranes, biology.protein, Biophysics, Bacterial outer membrane, Carrier Proteins, 030217 neurology & neurosurgery

Abstract

In the past three decades, significant advances have been made in providing the biochemical background of TOM (translocase of the outer mitochondrial membrane)-mediated protein translocation into mitochondria. In the light of recent cryoelectron microscopy-derived structures of TOM isolated from Neurospora crassa and Saccharomyces cerevisiae, the interpretation of biochemical and biophysical studies of TOM-mediated protein transport into mitochondria now rests on a solid basis. In this review, we compare the subnanometer structure of N. crassa TOM core complex with that of yeast. Both structures reveal remarkably well-conserved symmetrical dimers of 10 membrane protein subunits. The structural data also validate predictions of weakly stable regions in the transmembrane β-barrel domains of the protein-conducting subunit Tom40, which signal the existence of β-strands located in interfaces of protein-protein interactions.

Published

2020

36. Cryo-EM Structure of the Human Mitochondrial Translocase TIM22 Complex

Author

Qiang Wang, Jianbo Cao, Zeyuan Guan, Liangbo Qi, Ping Yin, Xing Zhang, Yan Wu, and Chuangye Yan

Subjects

Transmembrane domain, biology, Chemistry, Chaperone (protein), biology.protein, Biophysics, Inner membrane, Translocase, Random hexamer, Intermembrane space, Lipid bilayer, Transmembrane protein

Abstract

Mitochondria play vital functions in cellular metabolism, homeostasis, and apoptosis1-3. Most of the mitochondrial proteins are synthesized as precursors in the cytosol and imported into mitochondria for folding or maturation4,5. The translocase TIM22 complex is responsible for the import of multiple hydrophobic carrier proteins that are then folded in the inner membrane of mitochondria6-8. In mammalian cells, the TIM22 complex consists of at least six components, Tim22, Tim29, AGK, and three Tim chaperones (Tim9, Tim10a and Tim10b)9-14. Here, we report the cryo-EM structure of the human translocase TIM22 complex at an overall resolution of 3.7 angstrom. The core subunit, Tim22, contains four transmembrane helices, forming a partial pore that is open to the lipid bilayer. Tim29 is a single transmembrane protein that provides an N-terminal helix to stabilize Tim22 and a C-terminal intermembrane space (IMS) domain to connect AGK and two TIM chaperone hexamers to maintain complex integrity. One TIM hexamer comprises Tim9 and Tim10a in a 3:3 molar ratio, and the other consists of two Tim9 units, three Tim10a units, and one Tim10b unit. The latter hexamer faces the intramembrane region of Tim22, likely providing the dock to load the precursors to the partial pore of Tim22. Our structure serves as a molecular basis for the mechanistic understanding of TIM22 complex function.

Published

2019

37. Routing of thylakoid lumen proteins by the chloroplast twin arginine transport pathway

Author

Qianqian Ma, Carole Dabney-Smith, and Christopher Paul New

Subjects

Models, Molecular, 0301 basic medicine, Protein domain, Plant Science, Thylakoids, Biochemistry, Chloroplast Proteins, 03 medical and health sciences, Translocase, Amino Acid Sequence, Twin-Arginine-Translocation System, Arginine transport, biology, Chemiosmosis, Chemistry, food and beverages, Cell Biology, General Medicine, Transport protein, Chloroplast, Protein Transport, 030104 developmental biology, Membrane, Thylakoid, Biophysics, biology.protein

Abstract

Thylakoids are complex sub-organellar membrane systems whose role in photosynthesis makes them critical to life. Thylakoids require the coordinated expression of both nuclear- and plastid-encoded proteins to allow rapid response to changing environmental conditions. Transport of cytoplasmically synthesized proteins to thylakoids or the thylakoid lumen is complex; the process involves transport across up to three membrane systems with routing through three aqueous compartments. Protein transport in thylakoids is accomplished by conserved ancestral prokaryotic plasma membrane translocases containing novel adaptations for the sub-organellar location. This review focuses on the evolutionarily conserved chloroplast twin arginine transport (cpTat) pathway. An overview is provided of known aspects of the cpTat components, energy requirements, and mechanisms with a focus on recent discoveries. Some of the most exciting new studies have been in determining the structural architecture of the membrane complex involved in forming the point of passage for the precursor and binding features of the translocase components. The cpTat system is of particular interest because it transports folded protein domains using only the proton motive force for energy. The implications for mechanism of translocation by recent studies focusing on interactions between membrane Tat components and with the translocating precursor will be discussed.

Published

2018

38. Structure and dynamics of plant TatA in micelles and lipid bilayers studied by solution <scp>NMR</scp>

Author

Franzisca Tannert, Weihua Ye, Pontus Pettersson, Ralf Bernd Klösgen, Lena Mäler, and Mario Jakob

Subjects

0301 basic medicine, Magnetic Resonance Spectroscopy, Lipid Bilayers, Arabidopsis, Model lipid bilayer, Biochemistry, Twin-arginine translocation pathway, 03 medical and health sciences, Translocase, Amino Acid Sequence, Lipid bilayer, Molecular Biology, Micelles, Twin-Arginine-Translocation System, Sequence Homology, Amino Acid, biology, Arabidopsis Proteins, Chemistry, Vesicle, Biological Transport, Cell Biology, Translocon, Adaptation, Physiological, Lipids, Transmembrane domain, 030104 developmental biology, Helix, Solvents, biology.protein, Biophysics

Abstract

The twin-arginine translocase (Tat) transports folded proteins across the cytoplasmic membrane of prokaryotes and the thylakoid membrane of plant chloroplasts. In Gram-negative bacteria and chloroplasts, the translocon consists of three subunits, TatA, TatB, and TatC, of which TatA is responsible for the actual membrane translocation of the substrate. Herein we report on the structure, dynamics, and lipid interactions of a fully functional C-terminally truncated 'core TatA' from Arabidopsis thaliana using solution-state NMR. Our results show that TatA consists of a short N-terminal transmembrane helix (TMH), a short connecting linker (hinge) and a long region with propensity to form an amphiphilic helix (APH). The dynamics of TatA were characterized using 15 N relaxation NMR in combination with model-free analysis. The TMH has order parameters characteristic of a well-structured helix, the hinge is somewhat less rigid, while the APH has lower order parameters indicating structural flexibility. The TMH is short with a surprisingly low protection from solvent, and only the first part of the APH is protected to some extent. In order to uncover possible differences in TatA's structure and dynamics in detergent compared to in a lipid bilayer, fast-tumbling bicelles and large unilamellar vesicles were used. Results indicate that the helicity of TatA increases in both the TMH and APH in the presence of lipids, and that the N-terminal part of the TMH is significantly more rigid. The results indicate that plant TatA has a significant structural plasticity and a capability to adapt to local environments.

Published

2018

39. Structural Dynamics of the Functional Nonameric Type III Translocase Export Gate

Author

Yichen Li, Franck Duong Van Hoa, Harveer Singh Dhupar, Maria S Loos, Rinky Parakra, Anastassios Economou, Jiri Wald, Biao Yuan, Athina G. Portaliou, Spyridoula Karamanou, Thomas C. Marlovits, Charalampos G. Kalodimos, Jochem H. Smit, Thorben Cordes, Bindu Y. Srinivasu, Dirk Fahrenkamp, Molecular Biophysics, and Enzymology

Subjects

Models, Molecular, Protein Conformation, alpha-Helical, Protein subunit, ATPase, Genetic Vectors, Gene Expression, Protomer, Ring (chemistry), Mass Spectrometry, Substrate Specificity, Enteropathogenic Escherichia coli, Allosteric Regulation, type III secretion, Structural Biology, Type III Secretion Systems, Translocase, Inner membrane, Protein Interaction Domains and Motifs, Cloning, Molecular, Binding site, Molecular Biology, Adenosine Triphosphatases, EPEC, Binding Sites, biology, Chemistry, Escherichia coli Proteins, export apparatus, Cryoelectron Microscopy, Deuterium Exchange Measurement, Gene Expression Regulation, Bacterial, Recombinant Proteins, Kinetics, Protein Subunits, Flagella, Chaperone (protein), protein dynamics, biology.protein, Biophysics, Protein Conformation, beta-Strand, SctV-C structure, Linker, SEC Translocation Channels, Molecular Chaperones, Protein Binding

Abstract

Type III protein secretion is widespread in Gram-negative pathogens. It comprises the injectisome with a surface-exposed needle and an inner membrane translocase. The translocase contains the SctRSTU export channel enveloped by the export gate subunit SctV that binds chaperone/exported clients and forms a putative ante- chamber. We probed the assembly, function, structure and dynamics of SctV from enteropathogenic E.coli (EPEC). In both EPEC and E.coli lab strains, SctV forms peripheral oligomeric clusters that are detergent-extracted as homo-nonamers. Membrane-embedded SctV9 is necessary and sufficient to act as a receptor for different chaperone/exported protein pairs with distinct C-domain binding sites that are essential for secretion. Negative staining electron microscopy revealed that peptidisc-reconstituted His-SctV9 forms a tripartite particle of ∼22 nm with a N- terminal domain connected by a short linker to a C-domain ring structure with a ∼5 nm-wide inner opening. The isolated C-domain ring was resolved with cryo-EM at 3.1 Å and structurally compared to other SctV homologues. Its four sub-domains undergo a three-stage “pinching” motion. Hydrogen-deuterium exchange mass spectrometry revealed this to involve dynamic and rigid hinges and a hyper-flexible sub-domain that flips out of the ring periphery and binds chaperones on and between adjacent protomers. These motions are coincident with pore surface and ring entry mouth local conformational changes that are also modulated by the ATPase inner stalk. We propose a model that the intrinsic dynamics of the SctV protomer are modulated by chaperones and the ATPase and could affect allosterically the other subunits of the nonameric ring during secretion.

Published

2021

40. A nexus of intrinsic dynamics underlies translocase priming

Author

Athina G. Portaliou, Giorgos Gouridis, Srinath Krishnamurthy, Ana-Nicoleta Bondar, Anastassios Economou, Konstantina Karathanou, Jochem H. Smit, Katerina E. Chatzi, Nikolaos Eleftheriadis, and Spyridoula Karamanou

Subjects

Models, Molecular, SecA, Signal peptide, Protein Conformation, ATPase, Priming (immunology), Molecular Dynamics Simulation, SecYEG channel, translocase, 03 medical and health sciences, Bacterial Proteins, Protein Domains, Structural Biology, Catalytic Domain, protein secretion, Translocase, signal peptide, HDX-MS, Molecular Biology, Preprotein binding, 030304 developmental biology, 0303 health sciences, SecA Proteins, biology, Chemistry, 030302 biochemistry & molecular biology, Dynamics (mechanics), Helicase, Hydrogen Bonding, MD simulation, Single-molecule FRET, smFRET, intrinsic dynamics, graph analysis, Cytoplasm, Multiprotein Complexes, Biophysics, biology.protein, Hydrogen–deuterium exchange, SEC Translocation Channels, Nexus (standard), Function (biology), Bacillus subtilis, Protein Binding

Abstract

SummaryThe cytoplasmic ATPase SecA and the membrane-embedded SecYEG channel assemble to form the functional Sec translocase. How this interaction primes and catalytically activates the translocase remains unclear. We now show that priming exploits a sophisticated nexus of intrinsic dynamics in SecA. Using atomistic simulations, single molecule FRET and hydrogen/deuterium exchange mass spectrometry we reveal multiple distributed dynamic islands that cross-talk with domain and quaternary motions. These dynamic elements are highly conserved and essential for function. Central to the nexus is a slender Stem through which, motions in the helicase ATPase domain of SecA biases how the preprotein binding domain rotates between open-closed clamping states. Multi-tier dynamics are enabled by an H-bonded framework covering most of the SecA structure and allowing conformational alterations with minimal energy inputs. As a result, dimerization, the channel and nucleotides select pre-existing conformations, and alter local dynamics to restrict or promote catalytic activity and clamp motions. These events prime the translocase for high affinity reception of non-folded preprotein clients. Such dynamics nexuses are likely universal and essential in multi-liganded protein machines.

Published

2021

41. Membrane Insertion of the M13 Minor Coat Protein G3p Is Dependent on YidC and the SecAYEG Translocase

Author

Andreas Kuhn and Farina Kleinbeck

Subjects

Signal peptide, ribosome-nascent chain, phage assembly, Sequence (biology), medicine.disease_cause, Microbiology, Article, membrane protein insertion, disulphide crosslinking, Bacteriophage, Viral Proteins, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Biosynthesis, Virology, Escherichia coli, medicine, Translocase, membrane insertase YidC, bacteriophage M13, 030304 developmental biology, 0303 health sciences, biology, Chemistry, Escherichia coli Proteins, Virus Assembly, Membrane Transport Proteins, Periplasmic space, biology.organism_classification, QR1-502, translocase SecYEG, Infectious Diseases, Cytoplasm, biology.protein, Biophysics, membrane potential, SEC Translocation Channels, 030217 neurology & neurosurgery

Abstract

The minor coat protein G3p of bacteriophage M13 is the key component for the host interaction of this virus and binds to Escherichia coli at the tip of the F pili. As we show here, during the biosynthesis of G3p as a preprotein, the signal sequence interacts primarily with SecY, whereas the hydrophobic anchor sequence at the C-terminus interacts with YidC. Using arrested nascent chains and thiol crosslinking, we show here that the ribosome-exposed signal sequence is first contacted by SecY but not by YidC, suggesting that only SecYEG is involved at this early stage. The protein has a large periplasmic domain, a hydrophobic anchor sequence of 21 residues and a short C-terminal tail that remains in the cytoplasm. During the later synthesis of the entire G3p, the residues 387, 389 and 392 in anchor domain contact YidC in its hydrophobic slide to hold translocation of the C-terminal tail. Finally, the protein is processed by leader peptidase and assembled into new progeny phage particles that are extruded out of the cell.

Published

2021

42. Modulation of Escherichia coli UvrD Single-Stranded DNA Translocation by DNA Base Composition

Author

Timothy M. Lohman and Eric J. Tomko

Subjects

0301 basic medicine, Biophysics, DNA, Single-Stranded, Chromosomal translocation, medicine.disease_cause, Polyethylene Glycols, 03 medical and health sciences, chemistry.chemical_compound, Plasmid, Escherichia coli, medicine, Translocase, Base Composition, Nucleic Acids and Genome Biophysics, biology, Escherichia coli Proteins, DNA Helicases, Helicase, Processivity, Kinetics, Pyrimidines, 030104 developmental biology, Monomer, Biochemistry, chemistry, Purines, biology.protein, DNA

Abstract

Escherichia coli UvrD is an SF1A DNA helicase/translocase that functions in chromosomal DNA repair and replication of some plasmids. UvrD can also displace proteins such as RecA from DNA in its capacity as an anti-recombinase. Central to all of these activities is its ATP-driven 3'-5' single-stranded (ss) DNA translocation activity. Previous ensemble transient kinetic studies have estimated the average translocation rate of a UvrD monomer on ssDNA composed solely of deoxythymidylates. Here we show that the rate of UvrD monomer translocation along ssDNA is influenced by DNA base composition, with UvrD having the fastest rate along polypyrimidines although decreasing nearly twofold on ssDNA containing equal amounts of the four bases. Experiments with DNA containing abasic sites and polyethylene glycol spacers show that the ssDNA base also influences translocation processivity. These results indicate that changes in base composition and backbone insertions influence the translocation rates, with increased ssDNA base stacking correlated with decreased translocation rates, supporting the proposal that base-stacking interactions are involved in the translocation mechanism.

Published

2017

43. An alternate mode of oligomerization for E. coli SecA

Author

Brian H. Shilton, Grant C. Vezina, and Aliakbar Khalili Yazdi

Subjects

0301 basic medicine, Dimer, Protein subunit, Protein domain, lcsh:Medicine, Crystallography, X-Ray, environment and public health, Article, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Tetramer, Bacterial Proteins, Protein Domains, Escherichia coli, Translocase, Protein Structure, Quaternary, lcsh:Science, Adenosine Triphosphatases, Multidisciplinary, SecA Proteins, 030102 biochemistry & molecular biology, biology, Small-angle X-ray scattering, lcsh:R, 030104 developmental biology, Monomer, chemistry, Biochemistry, biology.protein, Biophysics, bacteria, lcsh:Q, Protein Multimerization, SEC Translocation Channels

Abstract

SecA is the ATPase of preprotein translocase. SecA is a dimer in solution and changes in its oligomeric state may function in preprotein translocation. The SecA-N68 construct, in which the C-terminal helical domains of SecA are deleted, was used to investigate the mechanism of SecA oligomerization. SecA-N68 is in equilibrium between monomers, dimers, and tetramers. Subunit interactions in the SecA-N68 tetramer are mediated entirely by unstructured regions at its N- and C-termini: when the termini are deleted to yield SecA-N68∆NC, the construct is completely monomeric. This monomeric construct yielded crystals diffracting to 2.6 Å that were used to solve the structure of SecA-N68, including the “preprotein crosslinking domain” (PPXD) that was missing from previous E. coli SecA structures. The SecA-N68 structure was combined with small angle X-ray scattering (SAXS) data to construct a model of the SecA-N68 tetramer that is consistent with the essential roles of the extreme N- and C-termini in oligomerization. This mode of oligomerization, which depends on binding of the extreme N-terminus to the DEAD motor domains, NBD1 and NBD2, was used to model a novel parallel and flexible SecA solution dimer that agrees well with SAXS data.

Published

2017

44. Single‐molecule imaging reveals the translocation and DNA looping dynamics of hepatitis C virus NS3 helicase

Author

Felix Tritschler, Kyung S. Lee, Chang Ting Lin, Taekjip Ha, Charles M. Rice, and Meigang Gu

Subjects

0301 basic medicine, DNA, Single-Stranded, Chromosomal translocation, Hepacivirus, Viral Nonstructural Proteins, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Protein Domains, Fluorescence Resonance Energy Transfer, Translocase, Nucleotide, Binding site, Molecular Biology, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, RNA, Articles, Molecular biology, 030104 developmental biology, Förster resonance energy transfer, Models, Chemical, chemistry, Nucleic acid, biology.protein, Biophysics, RNA, Viral, RNA Helicases, DNA

Abstract

Non-structural protein 3 (NS3) is an essential enzyme and a therapeutic target of hepatitis C virus (HCV). Compared to NS3-catalyzed nucleic acids unwinding, its translation on single stranded nucleic acids have received relatively little attention. To investigate the NS3h translocation with single-stranded nucleic acids substrates directly, we have applied a hybrid platform of single-molecule fluorescence detection combined with optical trapping. With the aid of mechanical manipulation and fluorescence localization, we probed the translocase activity of NS3h on laterally stretched, kilobase-size single-stranded DNA and RNA. We observed that the translocation rate of NS3h on ssDNA at a rate of 24.4 nucleotides per second, and NS3h translocates about three time faster on ssRNA, 74 nucleotides per second. The translocation speed was minimally affected by the applied force. A subpopulation of NS3h underwent a novel translocation mode on ssDNA where the stretched DNA shortened gradually and then recovers its original length abruptly before repeating the cycle repetitively. The speed of this mode of translocation was reduced with increasing force. With corroborating data from single-molecule fluorescence resonance energy transfer (smFRET) experiments, we proposed that NS3h can cause repetitive looping of DNA. The smFRET dwell time analysis showed similar translocation time between sole translocation mode versus repetitive looping mode, suggesting that the motor domain exhibits indistinguishable enzymatic activities between the two translocation modes. We propose a potential secondary nucleic acids binding site at NS3h which might function as an anchor point for translocation-coupled looping.

Published

2017

45. Development of a convenient and supersensitive high-throughput screening system for genetically encoded fluorescent probes of small molecules using a confocal microscope

Author

Kotomi Sugiura, Akitoshi Miyamoto, and Katsukiko Mikoshiba

Subjects

0301 basic medicine, Cell signaling, Microscope, Physiology, High-throughput screening, Confocal, Biology, Fluorescence, law.invention, Small Molecule Libraries, 03 medical and health sciences, law, Confocal microscopy, Escherichia coli, Translocase, Molecular Biology, Fluorescent Dyes, Microscopy, Confocal, Cell Biology, Small molecule, Molecular biology, High-Throughput Screening Assays, 030104 developmental biology, Microscopy, Fluorescence, Biophysics, biology.protein, Calcium

Abstract

Monitoring the dynamic patterns of intracellular signaling molecules, such as inositol 1,4,5-trisphosphate (IP3) and Ca2+, that control many diverse cellular processes, provides us significant information to understand the regulatory mechanism of cellular functions. For searching more sensitive and higher dynamic range probes for signaling molecules, convenient and supersensitive high throughput screening systems are required. Here we show the optimal "in Escherichia coli (E. coli) colony" screening method based on the twin-arginine translocase (Tat) pathway and introduce a novel application of a confocal microscope as a supersensitive detection system to measure changes in the fluorescence intensity of fluorescent probes in E. coli grown on an agar plate. To verify the performance of the novel detection system, we compared the changes detected in the fluorescent intensity of genetically encoded Ca2+ indicator after Ca2+ exposure to two kinds of conventional fluorescence detection systems (luminescent image analyzer and fluorescence stereomicroscope). The rate of fluorescence change between Ca2+ binding and unbinding detected by novel supersensitive detection system was almost double than those measured by conventional detection systems. We also confirmed that the Tat pathway-based screening method is applicable to the development of genetically encoded probes for IP3. Our convenient and supersensitive screening system improves the speed of developing florescent probes for small molecules.

Published

2017

46. Structural and mechanistic insights into Hsp104 function revealed by synchrotron X-ray footprinting

Author

Matthew A. Sochor, Michelle S. Go, James Shorter, Amber Tariq, Leland Mayne, Esin Gurpinar, S. Walter Englander, Elizabeth A. Sweeny, and Zhong-yuan Kan

Subjects

0301 basic medicine, Models, Molecular, Saccharomyces cerevisiae Proteins, Protein Conformation, Saccharomyces cerevisiae, Ring (chemistry), Biochemistry, 03 medical and health sciences, Protein Aggregates, Adenosine Triphosphate, Translocase, Nucleotide, Molecular Biology, Heat-Shock Proteins, chemistry.chemical_classification, 030102 biochemistry & molecular biology, biology, Chemistry, X-Rays, Mutagenesis, Cell Biology, Protein engineering, Footprinting, 030104 developmental biology, Protein Structure and Folding, Biophysics, biology.protein, Protein Multimerization, Linker, Function (biology), Synchrotrons

Abstract

Hsp104 is a hexameric AAA(+) ring translocase, which drives protein disaggregation in nonmetazoan eukaryotes. Cryo-EM structures of Hsp104 have suggested potential mechanisms of substrate translocation, but precisely how Hsp104 hexamers disaggregate proteins remains incompletely understood. Here, we employed synchrotron X-ray footprinting to probe the solution-state structures of Hsp104 monomers in the absence of nucleotide and Hsp104 hexamers in the presence of ADP or ATPγS (adenosine 5′-O-(thiotriphosphate)). Comparing side-chain solvent accessibilities between these three states illuminated aspects of Hsp104 structure and guided design of Hsp104 variants to probe the disaggregase mechanism in vitro and in vivo. We established that Hsp104 hexamers switch from a more-solvated state in ADP to a less-solvated state in ATPγS, consistent with switching from an open spiral to a closed ring visualized by cryo-EM. We pinpointed critical N-terminal domain (NTD), NTD-nucleotide–binding domain 1 (NBD1) linker, NBD1, and middle domain (MD) residues that enable intrinsic disaggregase activity and Hsp70 collaboration. We uncovered NTD residues in the loop between helices A1 and A2 that can be substituted to enhance disaggregase activity. We elucidated a novel potentiated Hsp104 MD variant, Hsp104–RYD, which suppresses α-synuclein, fused in sarcoma (FUS), and TDP-43 toxicity. We disambiguated a secondary pore-loop in NBD1, which collaborates with the NTD and NBD1 tyrosine-bearing pore-loop to drive protein disaggregation. Finally, we defined Leu-601 in NBD2 as crucial for Hsp104 hexamerization. Collectively, our findings unveil new facets of Hsp104 structure and mechanism. They also connect regions undergoing large changes in solvation to functionality, which could have profound implications for protein engineering.

Published

2019

47. Mitophagy is involved in chromium (VI)-induced mitochondria damage in DF-1 cells

Author

Yongxia Liu, Xiaozhou Wang, Shuo Zhang, Na Geng, Yiran Zhu, Jianzhu Liu, and Yuliang Xu

Subjects

Chromium, Health, Toxicology and Mutagenesis, Chick Embryo, Mitochondrion, Flow cytometry, Cell Line, Mitophagy, medicine, Autophagy, Translocase, Animals, Membrane potential, Membrane Potential, Mitochondrial, biology, medicine.diagnostic_test, Chemistry, Public Health, Environmental and Occupational Health, Depolarization, General Medicine, Fibroblasts, Pollution, Mitochondria, biology.protein, Biophysics, Environmental Pollutants, Bacterial outer membrane

Abstract

Cr (VI), which is a common heavy metal pollutant with strong oxidizing property, exists widely in nature. Organisms can be exposed to Cr (VI) through various means. Cr (VI) causes mitochondrial dysfunction after being absorbed by cells. Whether Cr (VI) induces the selective autophagic degradation of mitochondria, which is a biological process called mitophagy, remains unclear. Mitophagy not only recycles intracellularly damaged mitochondria to compensate for nutrient deprivation but also is involved in mitochondria quality control. Thus, this study investigated whether Cr (VI) could induce mitophagy in DF-1 cells. Carbonyl cyanide m-chlorophenylhydrazone, which is a mitochondrial-uncoupling reagent that induces mitophagy, was used. DF-1 cells were incubated with different doses of Cr (VI) for varying durations. The autophagy-related proteins LC3-II and p62 levels decreased after 6 h of Cr (VI) treatment but recovered within 24 h. The mitochondrial membrane potential, which is an indicator of mitochondrial damage, was detected by flow cytometry. We found that different durations of Cr (VI) treatment induced mitochondrial mass decrease and depolarization. Furthermore, the expression of the protein translocase of outer mitochondrial membrane 20 (TOMM20), which is a mitochondrial outer membrane protein, was decreased significantly in the presence of Cr (VI). Our findings indicate that Cr (VI) may contribute to the mitochondrial morphology and function damage and may therefore lead to the autophagic clearance of mitochondria.

Published

2019

48. Autoinhibition and activation mechanisms of the eukaryotic lipid flippase Drs2p-Cdc50p

Author

Hao-Chi Hsu, Gongpu Zhao, Lin Bai, Amanda Kovach, Huilin Li, and Qinglong You

Subjects

Models, Molecular, 0301 basic medicine, Enzyme complex, Saccharomyces cerevisiae Proteins, Protein Conformation, Science, Biophysics, General Physics and Astronomy, Calcium-Transporting ATPases, Saccharomyces cerevisiae, Article, General Biochemistry, Genetics and Molecular Biology, Substrate Specificity, Cell membrane, 03 medical and health sciences, Adenosine Triphosphate, Protein structure, Phosphatidylinositol Phosphates, Cryoelectron microscopy, Membrane region, Membrane proteins, medicine, Translocase, Binding site, lcsh:Science, Binding Sites, Multidisciplinary, 030102 biochemistry & molecular biology, biology, Chemistry, Activator (genetics), General Chemistry, Flippase, Lipids, 3. Good health, Cell biology, 030104 developmental biology, medicine.anatomical_structure, biology.protein, lcsh:Q

Abstract

The heterodimeric eukaryotic Drs2p-Cdc50p complex is a lipid flippase that maintains cell membrane asymmetry. The enzyme complex exists in an autoinhibited form in the absence of an activator and is specifically activated by phosphatidylinositol-4-phosphate (PI4P), although the underlying mechanisms have been unclear. Here we report the cryo-EM structures of intact Drs2p-Cdc50p isolated from S. cerevisiae in apo form and in the PI4P-activated form at 2.8 Å and 3.3 Å resolution, respectively. The structures reveal that the Drs2p C-terminus lines a long groove in the cytosolic regulatory region to inhibit the flippase activity. PIP4 binding in a cytosol-proximal membrane region triggers a 90° rotation of a cytosolic helix switch that is located just upstream of the inhibitory C-terminal peptide. The rotation of the helix switch dislodges the C-terminus from the regulatory region, activating the flippase., The heterodimeric eukaryotic Drs2p-Cdc50p complex is a lipid flippase that maintains cell membrane asymmetry and its autoinhibition is released by PI4P binding. Here authors show cryo-EM structures of Drs2p-Cdc50p in apo and PI4P-activated form which reveal the structural changes upon PI4P binding.

Published

2019

49. Structural insights into the molecular mechanisms of the Mycobacterium evolvability factor Mfd

Author

Desirazu N. Rao, Gavin C. Fox, Vinayak Bhat, Sivasankar Putta, Martin A. Walsh, Swayam Prabha, Ramanathan Natesh, and Valakunja Nagaraja

Subjects

chemistry.chemical_classification, biology, Chemistry, Mycobacterium smegmatis, Walker motifs, T-cell receptor, biology.organism_classification, chemistry.chemical_compound, biology.protein, Biophysics, Translocase, Nucleotide, Linker, DNA, Mycobacterium

Abstract

Mfd is a highly conserved ATP dependent DNA translocase that mediates the role of Transcription-Coupled-DNA-Repair(TCR) in bacteria. The molecular mechanisms and conformational remodelling that occurs in Mfd upon ATP binding, hydrolysis, and DNA translocation are poorly defined. Here we report a series of crystal and electron microscopy(EM) structures of Mfd from Mycobacterium tuberculosis (MtbMfd) and Mycobacterium smegmatis Mfd, solved in both the apo and nucleotide-bound states. The structures reveal the mechanism of nucleotide-binding, which lead to the remodeling of the Walker A motif at the catalytic pocket, inducing a flip-flop action of the hinge and flexible linker regions. Specifically, nucleotide binding unlocks the Translocation in RecG motif of the D6-domain to induce a ratchet-like motion. Functional studies of MtbMfd-RNAP complexes show that MtbMfd rescues stalled Transcription Elongation Complexes. We also report negative-stain and cryo-EM single particle reconstructions of MtbMfd higher order oligomer, that reveal an unexpected dodecameric assembly state. Given that Mfd accelerates the evolution of antimicrobial resistance(AMR), our results establish a framework for the design of new “anti-evolution” therapeutics to counter AMR.

Published

2019

50. UvrD helicase activation by MutL involves rotation of its 2B subdomain

Author

Timothy M. Lohman, Binh Nguyen, Alexander G. Kozlov, Haifeng Jia, and Yerdos Ordabayev

Subjects

DNA Repair, DNA repair, Protein Conformation, Dimer, DNA, Single-Stranded, medicine.disease_cause, chemistry.chemical_compound, Protein Domains, medicine, Escherichia coli, Fluorescence Resonance Energy Transfer, Translocase, Multidisciplinary, biology, Chemistry, Escherichia coli Proteins, DNA Helicases, Helicase, Biological Sciences, Single Molecule Imaging, DNA-Binding Proteins, Kinetics, Förster resonance energy transfer, MutL Proteins, biology.protein, Biophysics, DNA mismatch repair, DNA

Abstract

Escherichia coli UvrD is a superfamily 1 helicase/translocase that functions in DNA repair, replication, and recombination. Although a UvrD monomer can translocate along single-stranded DNA, self-assembly or interaction with an accessory protein is needed to activate its helicase activity in vitro. Our previous studies have shown that an Escherichia coli MutL dimer can activate the UvrD monomer helicase in vitro, but the mechanism is not known. The UvrD 2B subdomain is regulatory and can exist in extreme rotational conformational states. By using single-molecule FRET approaches, we show that the 2B subdomain of a UvrD monomer bound to DNA exists in equilibrium between open and closed states, but predominantly in an open conformation. However, upon MutL binding to a UvrD monomer-DNA complex, a rotational conformational state is favored that is intermediate between the open and closed states. Parallel kinetic studies of MutL activation of the UvrD helicase and of MutL-dependent changes in the UvrD 2B subdomain show that the transition from an open to an intermediate 2B subdomain state is on the pathway to helicase activation. We further show that MutL is unable to activate the helicase activity of a chimeric UvrD containing the 2B subdomain of the structurally similar Rep helicase. Hence, MutL activation of the monomeric UvrD helicase is regulated specifically by its 2B subdomain.

Published

2019