Your search keyword '"Klostermeier D"' showing total 26 results

1. Single-Molecule Confocal FRET Microscopy to Dissect Conformational Changes in the Catalytic Cycle of DNA Topoisomerases

Author

Hartmann, S., primary, Weidlich, D., additional, and Klostermeier, D., additional

Published

2016

2. HERA HELICASE RNA BINDING DOMAIN with TNCS in P212121

Author

Rudolph, M.G., primary and Klostermeier, D., additional

Published

2016

3. Structure of reverse gyrase with a minimal latch that supports ATP-dependent positive supercoiling without specific interactions with the topoisomerase domain.

Author

Mhaindarkar VP, Rasche R, Kümmel D, Rudolph MG, and Klostermeier D

Subjects

Protein Structure, Tertiary, DNA, Adenosine Triphosphate, DNA Topoisomerases, Type I chemistry, DNA Topoisomerases, Type I genetics, DNA Topoisomerases, Type I metabolism, DNA Helicases chemistry

Abstract

Reverse gyrase is the only topoisomerase that introduces positive supercoils into DNA in an ATP-dependent reaction. Positive DNA supercoiling becomes possible through the functional cooperation of the N-terminal helicase domain of reverse gyrase with its C-terminal type IA topoisomerase domain. This cooperation is mediated by a reverse-gyrase-specific insertion into the helicase domain termed the `latch'. The latch consists of a globular domain inserted at the top of a β-bulge loop that connects this globular part to the helicase domain. While the globular domain shows little conservation in sequence and length and is dispensable for DNA supercoiling, the β-bulge loop is required for supercoiling activity. It has previously been shown that the β-bulge loop constitutes a minimal latch that couples ATP-dependent processes in the helicase domain to DNA processing by the topoisomerase domain. Here, the crystal structure of Thermotoga maritima reverse gyrase with such a β-bulge loop as a minimal latch is reported. It is shown that the β-bulge loop supports ATP-dependent DNA supercoiling of reverse gyrase without engaging in specific interactions with the topoisomerase domain. When only a small latch or no latch is present, a helix in the nearby helicase domain of T. maritima reverse gyrase partially unfolds. Comparison of the sequences and predicted structures of latch regions in other reverse gyrases shows that neither sequence nor structure are decisive factors for latch functionality; instead, the decisive factors are likely to be electrostatics and plain steric bulk., (open access.)

Published

2023

4. Determination of rate constants for conformational changes of RNA helicases by single-molecule FRET TIRF microscopy.

Author

Chakraborty A, Krause L, and Klostermeier D

Subjects

DEAD-box RNA Helicases metabolism, RNA metabolism, Single Molecule Imaging methods, Fluorescence Resonance Energy Transfer methods, Microscopy

Abstract

RNA helicases couple nucleotide-driven conformational changes to the unwinding of RNA duplexes. Interaction partners can regulate helicase activity by altering the rate constants of these conformational changes. Single-molecule FRET experiments on donor/acceptor-labeled, immobilized molecules are ideally suited to monitor conformational changes in real time and to extract rate constants for these processes. This article provides guidance on how to design, perform, and analyze single-molecule FRET experiments by TIRF microscopy. It covers the theoretical background of FRET and single-molecule TIRF microscopy, the considerations to prepare proteins of interest for donor/acceptor labeling and surface immobilization, and the principles and procedures of data analysis, including image analysis and the determination of FRET time traces, the extraction of rate constants from FRET time traces, and the general conclusions that can be drawn from these data. A case study, using the DEAD-box protein eIF4A as an example, highlights how single-molecule FRET studies have been instrumental in understanding the role of conformational changes for duplex unwinding and for the regulation of helicase activities. Selected examples illustrate which conclusions can be drawn from the kinetic data obtained, highlight possible pitfalls in data analysis and interpretation, and outline how kinetic models can be related to functionally relevant states., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2022

5. The domains of yeast eIF4G, eIF4E and the cap fine-tune eIF4A activities through an intricate network of stimulatory and inhibitory effects.

Author

Krause L, Willing F, Andreou AZ, and Klostermeier D

Subjects

Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Eukaryotic Initiation Factor-4A metabolism, Eukaryotic Initiation Factor-4E genetics, Eukaryotic Initiation Factor-4F genetics, Eukaryotic Initiation Factor-4F metabolism, Protein Binding, RNA, Messenger metabolism, Eukaryotic Initiation Factor-4G metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism

Abstract

Translation initiation in eukaryotes starts with the recognition of the mRNA 5'-cap by eIF4F, a hetero-trimeric complex of eIF4E, the cap-binding protein, eIF4A, a DEAD-box helicase, and eIF4G, a scaffold protein. eIF4G comprises eIF4E- and eIF4A-binding domains (4E-BD, 4A-BD) and three RNA-binding regions (RNA1-RNA3), and interacts with eIF4A, eIF4E, and with the mRNA. Within the eIF4F complex, the helicase activity of eIF4A is increased. We showed previously that RNA3 of eIF4G is important for the stimulation of the eIF4A conformational cycle and its ATPase and helicase activities. Here, we dissect the interplay between the eIF4G domains and the role of the eIF4E/cap interaction in eIF4A activation. We show that RNA2 leads to an increase in the fraction of eIF4A in the closed state, an increased RNA affinity, and faster RNA unwinding. This stimulatory effect is partially reduced when the 4E-BD is present. eIF4E binding to the 4E-BD then further inhibits the helicase activity and closing of eIF4A, but does not affect the RNA-stimulated ATPase activity of eIF4A. The 5'-cap renders the functional interaction of mRNA with eIF4A less efficient. Overall, the activity of eIF4A at the 5'-cap is thus fine-tuned by a delicately balanced network of stimulatory and inhibitory interactions., (© The Author(s) 2022. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2022

6. Analysis of the conformational space and dynamics of RNA helicases by single-molecule FRET in solution and on surfaces.

Author

Klostermeier D

Subjects

DNA Helicases metabolism, Molecular Conformation, RNA chemistry, Fluorescence Resonance Energy Transfer, RNA Helicases

Abstract

RNA helicases are a diverse group of enzymes that catalyze the unwinding of RNA duplex regions in an ATP-dependent reaction. Both the helicase itself and its RNA substrate undergo conformational changes during the reaction, which are amenable to Förster resonance energy transfer (FRET) studies. Single-molecule FRET studies in solution by confocal microscopy and on surfaces by total internal reflection microscopy provide information on different conformers present, their fractional populations in equilibrium, and the rate constants of their inter-conversion. Collectively, the information gained can be integrated into a kinetic and thermodynamic framework that quantitatively describes the conformational dynamics of the helicase studied. FRET experiments also provide distance information to map and model the structures of individual conformational states. The integrated model provides a comprehensive description of the structure and dynamics of the helicase, which can be linked to its biological function. Single-molecule FRET studies have tremendous potential to define the relationship between structure, function and dynamics of RNA helicases and to understand the mechanistic basis for their broad range of biological functions. The focus of this chapter is on providing guidance in the design of single-molecule FRET experiments and on the interpretation of the data obtained. Selected examples illustrate important considerations when analyzing single-molecule experiments, as well as their limitations and possible pitfalls., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

7. Conjugates of Ciprofloxacin and Amphiphilic Block Copoly(2-alkyl-2-oxazolines)s Overcome Efflux Pumps and Are Active against CIP-Resistant Bacteria.

Author

Romanovska A, Keil J, Tophoven J, Oruc MF, Schmidt M, Breisch M, Sengstock C, Weidlich D, Klostermeier D, and Tiller JC

Subjects

Anti-Bacterial Agents chemistry, Cells, Cultured, Ciprofloxacin chemistry, Drug Compounding methods, Drug Resistance, Bacterial, Excipients chemistry, Humans, Mesenchymal Stem Cells, Microbial Sensitivity Tests, Anti-Bacterial Agents pharmacology, Ciprofloxacin pharmacology, Escherichia coli drug effects, Oxazoles chemistry, Staphylococcus aureus drug effects

Abstract

Conjugation of antibiotics with polymers is an emerging strategy to improve the performance of these important drugs. Here, the antibiotic ciprofloxacin (CIP) was conjugated with amphiphilic poly(2-oxazoline) (POx) block copolymers to investigate whether the activity of the antibiotic was enhanced due to additionally induced membrane activity. The resulting polymer-antibiotic conjugates (PACs) are an order of magnitude more active against the bacterial strain Staphylococcus aureus than CIP and show high activities against numerous pathogenic bacterial strains. Their high activity depends on an optimal hydrophobic/hydrophilic balance (HHB) of the POx tail. Mechanistic studies revealed that the derivatization of CIP required for the polymer conjugation lowers the affinity of the antibiotic to its target topoisomerase IV. However, the amphiphilic PACs are most likely concentrated within the bacterial cytoplasm, which overcompensates the loss of affinity and results in high antibacterial activity. In addition, the development of resistance in S. aureus and Escherichia coli is slowed down. More importantly, the amphiphilic PACs are active against CIP-resistant S. aureus and E. coli . The PACs with the highest activity are not cytotoxic toward human stem cells and do not lyse blood cells in saturated solution.

Published

2021

8. What makes a type IIA topoisomerase a gyrase or a Topo IV?

Author

Hirsch J and Klostermeier D

Subjects

Bacteria enzymology, DNA chemistry, DNA metabolism, DNA Gyrase genetics, DNA Gyrase metabolism, DNA Topoisomerase IV genetics, DNA Topoisomerase IV metabolism, DNA Topoisomerases, Type II chemistry, Evolution, Molecular, Protein Conformation, Protein Domains, DNA Gyrase chemistry, DNA Topoisomerase IV chemistry

Abstract

Type IIA topoisomerases catalyze a variety of different reactions: eukaryotic topoisomerase II relaxes DNA in an ATP-dependent reaction, whereas the bacterial representatives gyrase and topoisomerase IV (Topo IV) preferentially introduce negative supercoils into DNA (gyrase) or decatenate DNA (Topo IV). Gyrase and Topo IV perform separate, dedicated tasks during replication: gyrase removes positive supercoils in front, Topo IV removes pre-catenanes behind the replication fork. Despite their well-separated cellular functions, gyrase and Topo IV have an overlapping activity spectrum: gyrase is also able to catalyze DNA decatenation, although less efficiently than Topo IV. The balance between supercoiling and decatenation activities is different for gyrases from different organisms. Both enzymes consist of a conserved topoisomerase core and structurally divergent C-terminal domains (CTDs). Deletion of the entire CTD, mutation of a conserved motif and even by just a single point mutation within the CTD converts gyrase into a Topo IV-like enzyme, implicating the CTDs as the major determinant for function. Here, we summarize the structural and mechanistic features that make a type IIA topoisomerase a gyrase or a Topo IV, and discuss the implications for type IIA topoisomerase evolution., (© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2021

9. Highlight: RNA helicases - structure, function, mechanism and regulation.

Author

Klostermeier D

Subjects

Humans, Protein Conformation, RNA Helicases chemistry, RNA Helicases metabolism

Published

2021

10. Towards Conformation-Sensitive Inhibition of Gyrase: Implications of Mechanistic Insight for the Identification and Improvement of Inhibitors.

Author

Klostermeier D

Subjects

Bacteria enzymology, Models, Molecular, Topoisomerase II Inhibitors chemistry, DNA Gyrase metabolism, Topoisomerase II Inhibitors pharmacology

Abstract

Gyrase is a bacterial type IIA topoisomerase that catalyzes negative supercoiling of DNA. The enzyme is essential in bacteria and is a validated drug target in the treatment of bacterial infections. Inhibition of gyrase activity is achieved by competitive inhibitors that interfere with ATP- or DNA-binding, or by gyrase poisons that stabilize cleavage complexes of gyrase covalently bound to the DNA, leading to double-strand breaks and cell death. Many of the current inhibitors suffer from severe side effects, while others rapidly lose their antibiotic activity due to resistance mutations, generating an unmet medical need for novel, improved gyrase inhibitors. DNA supercoiling by gyrase is associated with a series of nucleotide- and DNA-induced conformational changes, yet the full potential of interfering with these conformational changes as a strategy to identify novel, improved gyrase inhibitors has not been explored so far. This review highlights recent insights into the mechanism of DNA supercoiling by gyrase and illustrates the implications for the identification and development of conformation-sensitive and allosteric inhibitors.

Published

2021

11. Regulation of RNA helicase activity: principles and examples.

Author

Donsbach P and Klostermeier D

Subjects

Humans, RNA Helicases chemistry, RNA Helicases metabolism

Abstract

RNA helicases are a ubiquitous class of enzymes involved in virtually all processes of RNA metabolism, from transcription, mRNA splicing and export, mRNA translation and RNA transport to RNA degradation. Although ATP-dependent unwinding of RNA duplexes is their hallmark reaction, not all helicases catalyze unwinding in vitro , and some in vivo functions do not depend on duplex unwinding. RNA helicases are divided into different families that share a common helicase core with a set of helicase signature motives. The core provides the active site for ATP hydrolysis, a binding site for non-sequence-specific interaction with RNA, and in many cases a basal unwinding activity. Its activity is often regulated by flanking domains, by interaction partners, or by self-association. In this review, we summarize the regulatory mechanisms that modulate the activities of the helicase core. Case studies on selected helicases with functions in translation, splicing, and RNA sensing illustrate the various modes and layers of regulation in time and space that harness the helicase core for a wide spectrum of cellular tasks., (© 2021 Walter de Gruyter GmbH, Berlin/Boston.)

Published

2021

12. Probing RNA Helicase Conformational Changes by Single-Molecule FRET Microscopy.

Author

Krause L and Klostermeier D

Subjects

Kinetics, Protein Conformation, DEAD-box RNA Helicases chemistry, Fluorescence Resonance Energy Transfer methods, Single Molecule Imaging methods

Abstract

Förster resonance energy transfer (FRET) is a versatile tool to study the conformational dynamics of proteins. Here, we describe the use of confocal and total internal reflection fluorescence (TIRF) microscopy to follow the conformational cycling of DEAD-box helicases on the single molecule level, using the eukaryotic translation initiation factor eIF4A as an illustrative example. Confocal microscopy enables the study of donor-acceptor-labeled molecules in solution, revealing the population of different conformational states present. With TIRF microscopy, surface-immobilized molecules can be imaged as a function of time, revealing sequences of conformational states and the kinetics of conformational changes.

Published

2021

13. The Thermus thermophilus DEAD-box protein Hera is a general RNA binding protein and plays a key role in tRNA metabolism.

Author

Donsbach P, Yee BA, Sanchez-Hevia D, Berenguer J, Aigner S, Yeo GW, and Klostermeier D

Subjects

Amino Acid Motifs, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Binding Sites, Cold-Shock Response, Models, Molecular, Protein Binding, Protein Domains, Protein Multimerization, Protein Structure, Secondary, RNA, Bacterial chemistry, RNA, Bacterial metabolism, Thermus thermophilus enzymology, Thermus thermophilus genetics, DEAD-box RNA Helicases chemistry, DEAD-box RNA Helicases metabolism, RNA, Transfer chemistry, RNA, Transfer metabolism, Thermus thermophilus growth & development

Abstract

RNA helicases catalyze the ATP-dependent destabilization of RNA duplexes. DEAD-box helicases share a helicase core that mediates ATP binding and hydrolysis, RNA binding and unwinding. Most members of this family contain domains flanking the core that can confer RNA substrate specificity and guide the helicase to a specific RNA. However, the in vivo RNA substrates of most helicases are currently not defined. The DEAD-box helicase Hera from Thermus thermophilus contains a helicase core, followed by a dimerization domain and an RNA binding domain that folds into an RNA recognition motif (RRM). The RRM mediates high affinity binding to an RNA hairpin, and an adjacent duplex is then unwound by the helicase core. Hera is a cold-shock protein, and has been suggested to act as an RNA chaperone under cold-shock conditions. Using crosslinking immunoprecipitation of Hera/RNA complexes and sequencing, we show that Hera binds to a large fraction of T. thermophilus RNAs under normal-growth and cold-shock conditions without a strong sequence preference, in agreement with a structure-specific recognition of RNAs and a general function in RNA metabolism. Under cold-shock conditions, Hera is recruited to RNAs with high propensities to form stable secondary structures. We show that selected RNAs identified, including a set of tRNAs, bind to Hera in vitro, and activate the Hera helicase core. Gene ontology analysis reveals an enrichment of genes related to translation, including mRNAs of ribosomal proteins, tRNAs, tRNA ligases, and tRNA-modifying enzymes, consistent with a key role of Hera in ribosome and tRNA metabolism., (© 2020 Donsbach et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2020

14. A β-hairpin is a Minimal Latch that Supports Positive Supercoiling by Reverse Gyrase.

Author

Collin F, Weisslocker-Schaetzel M, and Klostermeier D

Subjects

Adenosine Triphosphate metabolism, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites, DNA Topoisomerases, Type I genetics, DNA, Bacterial metabolism, Models, Molecular, Protein Domains, Protein Structure, Secondary, Sequence Deletion, Thermotoga maritima chemistry, Thermotoga maritima genetics, DNA Topoisomerases, Type I chemistry, DNA Topoisomerases, Type I metabolism, DNA, Superhelical metabolism, Thermotoga maritima enzymology

Abstract

Reverse gyrase is a unique type I topoisomerase that catalyzes the introduction of positive supercoils into DNA in an ATP-dependent reaction. Supercoiling is the result of a functional cooperation of the N-terminal helicase domain with the C-terminal topoisomerase domain. The helicase domain is a nucleotide-dependent conformational switch that alternates between open and closed states with different affinities for single- and double-stranded DNA. The isolated helicase domain as well as full-length reverse gyrase can transiently unwind double-stranded regions in an ATP-dependent reaction. The latch region of reverse gyrase, an insertion into the helicase domain with little conservation in sequence and length, has been proposed to coordinate events in the helicase domain with strand passage by the topoisomerase domain. Latch deletions lead to a reduction in or complete loss of supercoiling activity. Here we show that the latch consists of two functional parts, a globular domain that is dispensable for DNA supercoiling and a β-hairpin that connects the globular domain to the helicase domain and is required for supercoiling activity. The β-hairpin thus constitutes a minimal latch that couples ATP-dependent processes in the helicase domain to DNA processing by the topoisomerase domain., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

15. Allosteric modulation of the GTPase activity of a bacterial LRRK2 homolog by conformation-specific Nanobodies.

Author

Leemans M, Galicia C, Deyaert E, Daems E, Krause L, Paesmans J, Pardon E, Steyaert J, Kortholt A, Sobott F, Klostermeier D, and Versées W

Subjects

Allosteric Regulation, Animals, Camelids, New World, Drug Design, Escherichia coli metabolism, Hydrolysis, Mutation, Parkinson Disease drug therapy, Parkinson Disease genetics, Protein Multimerization, Bacterial Proteins metabolism, Chlorobi metabolism, GTP Phosphohydrolases metabolism, Leucine-Rich Repeat Serine-Threonine Protein Kinase-2 metabolism, Protein Domains, Single-Domain Antibodies metabolism, ras Proteins chemistry

Abstract

Mutations in the Parkinson's disease (PD)-associated protein leucine-rich repeat kinase 2 (LRRK2) commonly lead to a reduction of GTPase activity and increase in kinase activity. Therefore, strategies for drug development have mainly been focusing on the design of LRRK2 kinase inhibitors. We recently showed that the central RocCOR domains (Roc: Ras of complex proteins; COR: C-terminal of Roc) of a bacterial LRRK2 homolog cycle between a dimeric and monomeric form concomitant with GTP binding and hydrolysis. PD-associated mutations can slow down GTP hydrolysis by stabilizing the protein in its dimeric form. Here, we report the identification of two Nanobodies (NbRoco1 and NbRoco2) that bind the bacterial Roco protein (CtRoco) in a conformation-specific way, with a preference for the GTP-bound state. NbRoco1 considerably increases the GTP turnover rate of CtRoco and reverts the decrease in GTPase activity caused by a PD-analogous mutation. We show that NbRoco1 exerts its effect by allosterically interfering with the CtRoco dimer-monomer cycle through the destabilization of the dimeric form. Hence, we provide the first proof of principle that allosteric modulation of the RocCOR dimer-monomer cycle can alter its GTPase activity, which might present a potential novel strategy to overcome the effect of LRRK2 PD mutations., (© 2020 The Author(s).)

Published

2020

16. Functional interactions between gyrase subunits are optimized in a species-specific manner.

Author

Weidlich D and Klostermeier D

Subjects

Adenosine Triphosphatases metabolism, DNA, Bacterial, DNA, Superhelical, Kinetics, Models, Molecular, Protein Binding, Protein Multimerization, Species Specificity, Structural Homology, Protein, Bacteria enzymology, DNA Gyrase metabolism, Protein Subunits metabolism

Abstract

DNA gyrase is a bacterial DNA topoisomerase that catalyzes ATP-dependent negative DNA supercoiling and DNA decatenation. The enzyme is a heterotetramer comprising two GyrA and two GyrB subunits. Its overall architecture is conserved, but species-specific elements in the two subunits are thought to optimize subunit interaction and enzyme function. Toward understanding the roles of these different elements, we compared the activities of Bacillus subtilis , Escherichia coli , and Mycobacterium tuberculosis gyrases and of heterologous enzymes reconstituted from subunits of two different species. We show that B. subtilis and E. coli gyrases are proficient DNA-stimulated ATPases and efficiently supercoil and decatenate DNA. In contrast, M. tuberculosis gyrase hydrolyzes ATP only slowly and is a poor supercoiling enzyme and decatenase. The heterologous enzymes are generally less active than their homologous counterparts. The only exception is a gyrase reconstituted from mycobacterial GyrA and B. subtilis GyrB, which exceeds the activity of M. tuberculosis gyrase and reaches the activity of the B. subtilis gyrase, indicating that the activities of enzymes containing mycobacterial GyrB are limited by ATP hydrolysis. The activity pattern of heterologous gyrases is in agreement with structural features present: B. subtilis gyrase is a minimal enzyme, and its subunits can functionally interact with subunits from other bacteria. In contrast, the specific insertions in E. coli and mycobacterial gyrase subunits appear to prevent efficient functional interactions with heterologous subunits. Understanding the molecular details of gyrase adaptations to the specific physiological requirements of the respective organism might aid in the development of species-specific gyrase inhibitors., (© 2020 Weidlich and Klostermeier.)

Published

2020

17. Single-stranded regions modulate conformational dynamics and ATPase activity of eIF4A to optimize 5'-UTR unwinding.

Author

Andreou AZ, Harms U, and Klostermeier D

Subjects

Cloning, Molecular, Eukaryotic Initiation Factor-4F genetics, Hydrolysis, Kinetics, Nucleotides genetics, Protein Domains, RNA genetics, RNA Helicases genetics, Saccharomyces cerevisiae Proteins genetics, 5' Untranslated Regions, Adenosine Triphosphatases chemistry, Eukaryotic Initiation Factor-4F chemistry, RNA Helicases chemistry, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins chemistry

Abstract

Eukaryotic translation initiation requires unwinding of secondary structures in the 5'-untranslated region of mRNA. The DEAD-box helicase eIF4A is thought to unwind structural elements in the 5'-UTR in conjunction with eIF4G and eIF4B. Both factors jointly stimulate eIF4A activities by modulation of eIF4A conformational cycling between open and closed states. Here we examine how RNA substrates modulate eIF4A activities. The RNAs fall into two classes: Short RNAs only partially stimulate the eIF4A ATPase activity, and closing is rate-limiting for the conformational cycle. By contrast, longer RNAs maximally stimulate ATP hydrolysis and promote closing of eIF4A. Strikingly, the rate constants of unwinding do not correlate with the length of a single-stranded region preceding a duplex, but reach a maximum for RNA with a single-stranded region of six nucleotides. We propose a model in which RNA substrates affect eIF4A activities by modulating the kinetic partitioning of eIF4A between futile, unproductive, and productive cycles., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2019

18. Gyrase containing a single C-terminal domain catalyzes negative supercoiling of DNA by decreasing the linking number in steps of two.

Author

Stelljes JT, Weidlich D, Gubaev A, and Klostermeier D

Subjects

Adenosine Triphosphate metabolism, Bacillus subtilis enzymology, Biocatalysis, DNA Cleavage, DNA, Superhelical chemistry, Protein Domains, DNA Gyrase chemistry, DNA Gyrase metabolism, DNA, Superhelical metabolism

Abstract

The topological state of DNA in vivo is regulated by topoisomerases. Gyrase is a bacterial topoisomerase that introduces negative supercoils into DNA at the expense of ATP hydrolysis. According to the strand-passage mechanism, a double-strand of the DNA substrate is cleaved, and a second double-stranded segment is passed through the gap, converting a positive DNA node into a negative node. The correct orientation of these DNA segments for strand passage is achieved by wrapping of the DNA around gyrase, which involves the C-terminal domains (CTDs) of both GyrA subunits in the A2B2 heterotetramer. Gyrase lacking both CTDs cannot introduce negative supercoils into DNA. Here, we analyze the requirements for the two CTDs in individual steps in the supercoiling reaction. Gyrase that contains a single CTD binds, distorts, and cleaves DNA similarly to wildtype gyrase. It also shows wildtype-like DNA-dependent ATPase activity, and undergoes DNA-induced movement of the CTD as well as N-gate narrowing. Most importantly, the enzyme still introduces negative supercoils into DNA in an ATP-dependent reaction, with a velocity similar to wildtype gyrase, and decreases the linking number of the DNA in steps of two. One CTD is thus sufficient to support DNA supercoiling.

Published

2018

19. Why Two? On the Role of (A-)Symmetry in Negative Supercoiling of DNA by Gyrase.

Author

Klostermeier D

Subjects

Animals, DNA chemistry, DNA Gyrase chemistry, DNA Topoisomerases, Type II chemistry, DNA Topoisomerases, Type II metabolism, Humans, Protein Subunits metabolism, Structure-Activity Relationship, DNA genetics, DNA metabolism, DNA Gyrase metabolism, Nucleic Acid Conformation

Abstract

Gyrase is a type IIA topoisomerase that catalyzes negative supercoiling of DNA. The enzyme consists of two GyrA and two GyrB subunits. It is believed to introduce negative supercoils into DNA by converting a positive DNA node into a negative node through strand passage: First, it cleaves both DNA strands of a double-stranded DNA, termed the G-segment, and then it passes a second segment of the same DNA molecule, termed the T-segment, through the gap created. As a two-fold symmetric enzyme, gyrase contains two copies of all elements that are key for the supercoiling reaction: The GyrB subunits provide two active sites for ATP binding and hydrolysis. The GyrA subunits contain two C-terminal domains (CTDs) for DNA binding and wrapping to stabilize the positive DNA node, and two catalytic tyrosines for DNA cleavage. While the presence of two catalytic tyrosines has been ascribed to the necessity of cleaving both strands of the G-segment to enable strand passage, the role of the two ATP hydrolysis events and of the two CTDs has been less clear. This review summarizes recent results on the role of these duplicate elements for individual steps of the supercoiling reaction, and discusses the implications for the mechanism of DNA supercoiling.

Published

2018

20. Binding and Hydrolysis of a Single ATP Is Sufficient for N-Gate Closure and DNA Supercoiling by Gyrase.

Author

Hartmann S, Gubaev A, and Klostermeier D

Subjects

Adenosine Triphosphate metabolism, Catalysis, DNA Gyrase chemistry, DNA, Bacterial chemistry, DNA, Superhelical chemistry, Models, Molecular, Protein Binding, Protein Conformation, Bacillus subtilis enzymology, DNA Gyrase metabolism, DNA, Bacterial metabolism, DNA, Superhelical metabolism, Nucleic Acid Conformation

Abstract

Topoisomerases catalyze the relaxation, supercoiling, catenation, and decatenation of DNA. Gyrase is a bacterial topoisomerase that introduces negative supercoils into DNA in an ATP-dependent reaction. The enzyme consists of two GyrB subunits, containing the ATPase domains, and two GyrA subunits. Nucleotide binding to gyrase B GyrB causes closing of the N-gate in gyrase, which orients bound DNA for supercoiling. N-gate re-opening after ATP hydrolysis, at the end of the supercoiling reaction, resets the enzyme for subsequent catalytic cycles. Gyrase binds and hydrolyzes two ATP molecules per catalytic cycle. Here, we dissect the role of these two binding and hydrolysis events using gyrase with one ATP-binding- and hydrolysis-deficient subunit, or with one binding-competent, but hydrolysis-deficient ATPase domain. We show that binding of a single ATP molecule induces N-gate closure. Gyrase that can only bind and hydrolyze a single ATP undergoes opening and closing of the N-gate in synchrony with ATP hydrolysis, and promotes DNA supercoiling under catalytic conditions. In contrast, gyrase that can bind two ATP molecules, but hydrolyzes only one, only supercoils DNA under stoichiometric conditions. Here, ATP bound to the hydrolysis-deficient subunit keeps the N-gate closed after hydrolysis of the other ATP and prevents further turnovers. Gyrase with only one functional ATPase domain hydrolyzes ATP with a similar rate to wild-type, but its supercoiling efficiency is reduced. Binding and hydrolysis of the second ATP may thus ensure efficient coupling of the nucleotide cycle with the supercoiling reaction by stabilizing the closed N-gate and by acting as a timer for N-gate re-opening., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

21. Allosteric regulation of helicase core activities of the DEAD-box helicase YxiN by RNA binding to its RNA recognition motif.

Author

Samatanga B, Andreou AZ, and Klostermeier D

Subjects

Adenosine Triphosphate metabolism, Allosteric Regulation, Amino Acid Sequence, Hydrolysis, Markov Chains, Models, Molecular, Molecular Conformation, Nucleic Acid Conformation, Peptides chemistry, Peptides metabolism, Protein Binding, RNA chemistry, RNA genetics, Binding Sites, DEAD-box RNA Helicases chemistry, DEAD-box RNA Helicases metabolism, RNA metabolism, RNA Recognition Motif

Abstract

DEAD-box proteins share a structurally similar core of two RecA-like domains (RecA_N and RecA_C) that contain the conserved motifs for ATP-dependent RNA unwinding. In many DEAD-box proteins the helicase core is flanked by ancillary domains. To understand the regulation of the DEAD-box helicase YxiN by its C-terminal RNA recognition motif (RRM), we investigated the effect of RNA binding to the RRM on its position relative to the core, and on core activities. RRM/RNA complex formation substantially shifts the RRM from a position close to the RecA_C to the proximity of RecA_N, independent of RNA contacts with the core. RNA binding to the RRM is communicated to the core, and stimulates ATP hydrolysis and RNA unwinding. The conformational space of the core depends on the identity of the RRM-bound RNA. Allosteric regulation of core activities by RNA-induced movement of ancillary domains may constitute a general regulatory mechanism of DEAD-box protein activity., (© The Author(s) 2017. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2017

22. eIF4B stimulates eIF4A ATPase and unwinding activities by direct interaction through its 7-repeats region.

Author

Andreou AZ, Harms U, and Klostermeier D

Subjects

5' Untranslated Regions, Binding Sites, Enzyme Activation, Eukaryotic Initiation Factor-4A chemistry, Eukaryotic Initiation Factors chemistry, Multiprotein Complexes metabolism, Protein Binding, Protein Interaction Domains and Motifs, RNA Helicases metabolism, RNA, Messenger chemistry, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Adenosine Triphosphatases metabolism, Eukaryotic Initiation Factor-4A metabolism, Eukaryotic Initiation Factors metabolism, RNA, Messenger genetics, RNA, Messenger metabolism, Repetitive Sequences, Nucleic Acid

Abstract

Eukaryotic translation initiation starts with binding of the eIF4F complex to the 5'-m 7 G cap of the mRNA. Recruitment of the 43S pre-initiation complex (PIC), formed by the 40S ribosomal subunit and other translation initiation factors, leads to formation of the 48S PIC that then scans the 5'-untranslated region (5'-UTR) toward the start codon. The eIF4F complex consists of eIF4E, the cap binding protein, eIF4A, a DEAD-box RNA helicase that is believed to unwind secondary structures in the 5'-UTR during scanning, and eIF4G, a scaffold protein that binds to both eIF4E and eIF4A. The ATPase and helicase activities of eIF4A are jointly stimulated by eIF4G and the translation initiation factor eIF4B. Yeast eIF4B mediates recruitment of the 43S PIC to the cap-bound eIF4F complex by interacting with the 40S subunit and possibly with eIF4A. However, a direct interaction between yeast eIF4A and eIF4B has not been demonstrated yet. Here we show that eIF4B binds to eIF4A in the presence of RNA and ADPNP, independent of the presence of eIF4G. A stretch of seven moderately conserved repeats, the r1-7 region, is responsible for complex formation, for modulation of the conformational energy landscape of eIF4A by eIF4B, and for stimulating the RNA-dependent ATPase- and ATP-dependent RNA unwinding activities of eIF4A. The isolated r1-7 region only slightly stimulates eIF4A conformational changes and activities, suggesting that communication of the repeats with other regions of eIF4B is required for full stimulation of eIF4A activity, for recruitment of the PIC to the mRNA and for translation initiation.

Published

2017

23. DNA gyrase with a single catalytic tyrosine can catalyze DNA supercoiling by a nicking-closing mechanism.

Author

Gubaev A, Weidlich D, and Klostermeier D

Subjects

Bacillus subtilis enzymology, Catalysis, Hydrolysis, Models, Molecular, Molecular Conformation, Structure-Activity Relationship, Tyrosine chemistry, DNA Gyrase chemistry, DNA Gyrase metabolism, DNA, Superhelical chemistry, DNA, Superhelical metabolism, Tyrosine metabolism

Abstract

The topological state of DNA is important for replication, recombination and transcription, and is regulated in vivo by DNA topoisomerases. Gyrase introduces negative supercoils into DNA at the expense of ATP hydrolysis. It is the accepted view that gyrase achieves supercoiling by a strand passage mechanism, in which double-stranded DNA is cleaved, and a second double-stranded segment is passed through the gap, converting a positive DNA node into a negative node. We show here that gyrase with only one catalytic tyrosine that cleaves a single strand of its DNA substrate can catalyze DNA supercoiling without strand passage. We propose an alternative mechanism for DNA supercoiling via nicking and closing of DNA that involves trapping, segregation and relaxation of two positive supercoils. In contrast to DNA supercoiling, ATP-dependent relaxation and decatenation of DNA by gyrase lacking the C-terminal domains require both tyrosines and strand passage. Our results point towards mechanistic plasticity of gyrase and might pave the way for finding novel and specific mechanism-based gyrase inhibitors., (© The Author(s) 2016. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2016

24. Protein cofactor competition regulates the action of a multifunctional RNA helicase in different pathways.

Author

Heininger AU, Hackert P, Andreou AZ, Boon KL, Memet I, Prior M, Clancy A, Schmidt B, Urlaub H, Schleiff E, Sloan KE, Deckers M, Lührmann R, Enderlein J, Klostermeier D, Rehling P, and Bohnsack MT

Subjects

Apoptosis, Cell Nucleus metabolism, Cytoplasm metabolism, Gene Expression Regulation, Fungal, Mitochondrial Membranes metabolism, Signal Transduction, DEAD-box RNA Helicases metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

A rapidly increasing number of RNA helicases are implicated in several distinct cellular processes, however, the modes of regulation of multifunctional RNA helicases and their recruitment to different target complexes have remained unknown. Here, we show that the distribution of the multifunctional DEAH-box RNA helicase Prp43 between its diverse cellular functions can be regulated by the interplay of its G-patch protein cofactors. We identify the orphan G-patch protein Cmg1 (YLR271W) as a novel cofactor of Prp43 and show that it stimulates the RNA binding and ATPase activity of the helicase. Interestingly, Cmg1 localizes to the cytoplasm and to the intermembrane space of mitochondria and its overexpression promotes apoptosis. Furthermore, our data reveal that different G-patch protein cofactors compete for interaction with Prp43. Changes in the expression levels of Prp43-interacting G-patch proteins modulate the cellular localization of Prp43 and G-patch protein overexpression causes accumulation of the helicase in the cytoplasm or nucleoplasm. Overexpression of several G-patch proteins also leads to defects in ribosome biogenesis that are consistent with withdrawal of the helicase from this pathway. Together, these findings suggest that the availability of cofactors and the sequestering of the helicase are means to regulate the activity of multifunctional RNA helicases and their distribution between different cellular processes.

Published

2016

25. When core competence is not enough: functional interplay of the DEAD-box helicase core with ancillary domains and auxiliary factors in RNA binding and unwinding.

Author

Rudolph MG and Klostermeier D

Subjects

Adenosine Triphosphate metabolism, Binding Sites, Hydrolysis, Nucleic Acid Conformation, Protein Binding, Protein Structure, Tertiary, DEAD-box RNA Helicases metabolism, RNA chemistry, RNA metabolism

Abstract

DEAD-box helicases catalyze RNA duplex unwinding in an ATP-dependent reaction. Members of the DEAD-box helicase family consist of a common helicase core formed by two RecA-like domains. According to the current mechanistic model for DEAD-box mediated RNA unwinding, binding of RNA and ATP triggers a conformational change of the helicase core, and leads to formation of a compact, closed state. In the closed conformation, the two parts of the active site for ATP hydrolysis and of the RNA binding site, residing on the two RecA domains, become aligned. Closing of the helicase core is coupled to a deformation of the RNA backbone and destabilization of the RNA duplex, allowing for dissociation of one of the strands. The second strand remains bound to the helicase core until ATP hydrolysis and product release lead to re-opening of the core. The concomitant disruption of the RNA binding site causes dissociation of the second strand. The activity of the helicase core can be modulated by interaction partners, and by flanking N- and C-terminal domains. A number of C-terminal flanking regions have been implicated in RNA binding: RNA recognition motifs (RRM) typically mediate sequence-specific RNA binding, whereas positively charged, unstructured regions provide binding sites for structured RNA, without sequence-specificity. Interaction partners modulate RNA binding to the core, or bind to RNA regions emanating from the core. The functional interplay of the helicase core and ancillary domains or interaction partners in RNA binding and unwinding is not entirely understood. This review summarizes our current knowledge on RNA binding to the DEAD-box helicase core and the roles of ancillary domains and interaction partners in RNA binding and unwinding by DEAD-box proteins.

Published

2015

26. Nickel quercetinase, a "promiscuous" metalloenzyme: metal incorporation and metal ligand substitution studies.

Author

Nianios D, Thierbach S, Steimer L, Lulchev P, Klostermeier D, and Fetzner S

Subjects

Amino Acid Motifs, Biocatalysis, Dioxygenases genetics, Ligands, Protein Folding, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Streptomyces enzymology, Substrate Specificity, Amino Acid Substitution, Dioxygenases chemistry, Dioxygenases metabolism, Nickel metabolism

Abstract

Background: Quercetinases are metal-dependent dioxygenases of the cupin superfamily. While fungal quercetinases are copper proteins, recombinant Streptomyces quercetinase (QueD) was previously described to be capable of incorporating Ni(2+) and some other divalent metal ions. This raises the questions of which factors determine metal selection, and which metal ion is physiologically relevant., Results: Metal occupancies of heterologously produced QueD proteins followed the order Ni > Co > Fe > Mn. Iron, in contrast to the other metals, does not support catalytic activity. QueD isolated from the wild-type Streptomyces sp. strain FLA contained mainly nickel and zinc. In vitro synthesis of QueD in a cell-free transcription-translation system yielded catalytically active protein when Ni(2+) was present, and comparison of the circular dichroism spectra of in vitro produced proteins suggested that Ni(2+) ions support correct folding. Replacement of individual amino acids of the 3His/1Glu metal binding motif by alanine drastically reduced or abolished quercetinase activity and affected its structural integrity. Only substitution of the glutamate ligand (E76) by histidine resulted in Ni- and Co-QueD variants that retained the native fold and showed residual catalytic activity., Conclusions: Heterologous formation of catalytically active, native QueD holoenzyme requires Ni(2+), Co(2+) or Mn(2+), i.e., metal ions that prefer an octahedral coordination geometry, and an intact 3His/1Glu motif or a 4His environment of the metal. The observed metal occupancies suggest that metal incorporation into QueD is governed by the relative stability of the resulting metal complexes, rather than by metal abundance. Ni(2+) most likely is the physiologically relevant cofactor of QueD of Streptomyces sp. FLA.

Published

2015