Your search keyword '"Jan Philip Wurm"' showing total 20 results

1. Conformational Modulation of a Mobile Loop Controls Catalysis in the (βα)8‑Barrel Enzyme of Histidine Biosynthesis HisF

Author

Enrico Hupfeld, Sandra Schlee, Jan Philip Wurm, Chitra Rajendran, Dariia Yehorova, Eva Vos, Dinesh Ravindra Raju, Shina Caroline Lynn Kamerlin, Remco Sprangers, and Reinhard Sterner

Subjects

Chemistry, QD1-999

Published

2024

2. Molecular basis for the allosteric activation mechanism of the heterodimeric imidazole glycerol phosphate synthase complex

Author

Jan Philip Wurm, Sihyun Sung, Andrea Christa Kneuttinger, Enrico Hupfeld, Reinhard Sterner, Matthias Wilmanns, and Remco Sprangers

Subjects

Science

Abstract

The allosteric regulation of the bienzyme complex imidazole glycerol phosphate synthase (HisFH) remains to be elucidated. Here, the authors provide structural insights into the dynamic allosteric mechanism by which ligand binding to the cyclase and glutaminase active sites of HisFH regulate enzyme activation.

Published

2021

3. Crystal structure of the translation recovery factor Trf from Sulfolobus solfataricus

Author

Marco Kaiser, Jan Philip Wurm, Birgit Märtens, Udo Bläsi, Denys Pogoryelov, and Jens Wöhnert

Subjects

DUF35, ribosome, Sulfolobus solfataricus, translation initiation, translation recovery factor Trf, Biology (General), QH301-705.5

Abstract

During translation initiation, the heterotrimeric archaeal translation initiation factor 2 (aIF2) recruits the initiator tRNAi to the small ribosomal subunit. In the stationary growth phase and/or during nutrient stress, Sulfolobus solfataricus aIF2 has a second function: It protects leaderless mRNAs against degradation by binding to their 5′‐ends. The S. solfataricus protein Sso2509 is a translation recovery factor (Trf) that interacts with aIF2 and is responsible for the release of aIF2 from bound mRNAs, thereby enabling translation re‐initiation. It is a member of the domain of unknown function 35 (DUF35) protein family and is conserved in Sulfolobales as well as in other archaea. Here, we present the X‐ray structure of S. solfataricus Trf solved to a resolution of 1.65 Å. Trf is composed of an N‐terminal rubredoxin‐like domain containing a bound zinc ion and a C‐terminal oligosaccharide/oligonucleotide binding fold domain. The Trf structure reveals putative mRNA binding sites in both domains. Surprisingly, the Trf protein is structurally but not sequentially very similar to proteins linked to acyl‐CoA utilization—for example, the Sso2064 protein from S. solfataricus—as well as to scaffold proteins found in the acetoacetyl‐CoA thiolase/high‐mobility group‐CoA synthase complex of the archaeon Methanothermococcus thermolithotrophicus and in a steroid side‐chain‐cleaving aldolase complex from the bacterium Thermomonospora curvata. This suggests that members of the DUF35 protein family are able to act as scaffolding and binding proteins in a wide variety of biological processes.

Published

2020

4. Structure-based redesign of docking domain interactions modulates the product spectrum of a rhabdopeptide-synthesizing NRPS

Author

Carolin Hacker, Xiaofeng Cai, Carsten Kegler, Lei Zhao, A. Katharina Weickhmann, Jan Philip Wurm, Helge B. Bode, and Jens Wöhnert

Subjects

Science

Abstract

Rhabdopeptides are synthesized by non-ribosomal peptide synthetases (NRPSs) and the multiple NRPS subunits interact through docking domains (DD). Here the authors provide insights into DD interaction patterns and present the structures of three N-terminal docking domains (NDD) and a NDD-CDD complex and derive a set of recognition rules for DD interactions.

Published

2018

5. Observation of conformational changes that underlie the catalytic cycle of Xrn2

Author

Jan H. Overbeck, David Stelzig, Anna-Lisa Fuchs, Jan Philip Wurm, and Remco Sprangers

Subjects

Exoribonucleases, 570 Biowissenschaften, Biologie, Magnesium, Fluorine, Cell Biology, ddc:570, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology, Catalysis

Abstract

Nuclear magnetic resonance (NMR) methods that quantitatively probe motions on molecular and atomic levels have propelled the understanding of biomolecular processes for which static structures cannot provide a satisfactory description. In this work, we studied the structure and dynamics of the essential 100-kDa eukaryotic 5′→3′ exoribonuclease Xrn2. A combination of complementary fluorine and methyl-TROSY NMR spectroscopy reveals that the apo enzyme is highly dynamic around the catalytic center. These observed dynamics are in agreement with a transition of the enzyme from the ground state into a catalytically competent state. We show that the conformational equilibrium in Xrn2 shifts substantially toward the active state in the presence of substrate and magnesium. Finally, our data reveal that the dynamics in Xrn2 correlate with the RNA degradation rate, as a mutation that attenuates motions also affects catalytic activity. In that light, our results stress the importance of studies that go beyond static structural information.

Published

2022

6. Assignment of the Ile, Leu, Val, Met and Ala methyl group resonances of the DEAD-box RNA helicase DbpA from E. coli

Author

Jan Philip Wurm

Subjects

DEAD-box helicase, DEAD box, Stereochemistry, DEAD-box helicase · Ribosome assembly · RNA · Methyl group assignment, Biochemistry, Ribosome, Article, Ribosome assembly, 03 medical and health sciences, Structural Biology, Escherichia coli, 570 Biowissenschaften, Biologie, Nuclear Magnetic Resonance, Biomolecular, 030304 developmental biology, Alanine, 0303 health sciences, biology, RNA recognition motif, Chemistry, Escherichia coli Proteins, 030302 biochemistry & molecular biology, Helicase, RNA, RNA Helicase A, biology.protein, ddc:570, Methyl group assignment

Abstract

ATP-dependent DEAD-box helicases constitute one of the largest families of RNA helicases and are important regulators of most RNA-dependent cellular processes. The functional core of these enzymes consists of two RecA-like domains. Changes in the interdomain orientation of these domains upon ATP and RNA binding result in the unwinding of double-stranded RNA. The DEAD-box helicase DbpA from E. coli is involved in ribosome maturation. It possesses a C-terminal RNA recognition motif (RRM) in addition to the canonical RecA-like domains. The RRM recruits DbpA to nascent ribosomes by binding to hairpin 92 of the 23S rRNA. To follow the conformational changes of Dbpa during the catalytic cycle we initiated solution state NMR studies. We use a divide and conquer approach to obtain an almost complete resonance assignment of the isoleucine, leucine, valine, methionine and alanine methyl group signals of full length DbpA (49 kDa). In addition, we also report the backbone resonance assignments of two fragments of DbpA that were used in the course of the methyl group assignment. These assignments are the first step towards a better understanding of the molecular mechanism behind the ATP-dependent RNA unwinding process catalyzed by DEAD-box helicases.

Published

2020

7. Molecular basis of the selective processing of short mRNA substrates by the DcpS mRNA decapping enzyme

Author

Ancilla Neu, Jan Philip Wurm, Remco Sprangers, and Anna-Lisa Fuchs

Subjects

RNA Caps, Exosome complex, RNA Stability, DCPS, 010402 general chemistry, Crystallography, X-Ray, 01 natural sciences, Exosome, 03 medical and health sciences, NMR spectroscopy, mRNA decay, Endoribonucleases, Humans, Nucleotide, Amino Acid Sequence, RNA, Messenger, conformational changes, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Messenger RNA, Multidisciplinary, biology, Active site, Translation (biology), Biological Sciences, scavenger decapping enzyme, 0104 chemical sciences, Cell biology, Biophysics and Computational Biology, Enzyme, chemistry, biology.protein, enzyme regulation

Abstract

Significance In eukoryotes, 3′ to 5′ mRNA degradation is a major pathway to reduce mRNA levels and, thus, an important means to regulate gene expression. Herein, messenger RNA (mRNA) is hydrolyzed from the 3′ end by the exosome complex, producing short capped RNA fragments, which are decapped by DcpS. Our data show that DcpS is only active on mRNA that have undergone prior processing by the exosome. This DcpS selection mechanism is conserved from yeast to humans and is caused by the inability of the enzyme to undergo structural changes that are required for the formation of a catalytically active state around long mRNA transcripts. Our work thus reveals the mechanistic basis that ensures an efficient interplay between DcpS and the exosome., The 5′ messenger RNA (mRNA) cap structure enhances translation and protects the transcript against exonucleolytic degradation. During mRNA turnover, this cap is removed from the mRNA. This decapping step is catalyzed by the Scavenger Decapping Enzyme (DcpS), in case the mRNA has been exonucleolyticly shortened from the 3′ end by the exosome complex. Here, we show that DcpS only processes mRNA fragments that are shorter than three nucleotides in length. Based on a combination of methyl transverse relaxation optimized (TROSY) NMR spectroscopy and X-ray crystallography, we established that the DcpS substrate length-sensing mechanism is based on steric clashes between the enzyme and the third nucleotide of a capped mRNA. For longer mRNA substrates, these clashes prevent conformational changes in DcpS that are required for the formation of a catalytically competent active site. Point mutations that enlarge the space for the third nucleotide in the mRNA body enhance the activity of DcpS on longer mRNA species. We find that this mechanism to ensure that the enzyme is not active on translating long mRNAs is conserved from yeast to humans. Finally, we show that the products that the exosome releases after 3′ to 5′ degradation of the mRNA body are indeed short enough to be decapped by DcpS. Our data thus directly confirms the notion that mRNA products of the exosome are direct substrates for DcpS. In summary, we demonstrate a direct relationship between conformational changes and enzyme activity that is exploited to achieve substrate selectivity.

Published

2020

8. Structural basis for the activation of the DEAD-box RNA helicase DbpA by the nascent ribosome

Author

Katarzyna-Anna Glowacz, Remco Sprangers, and Jan Philip Wurm

Subjects

DEAD-box helicase, DEAD box, Protein Conformation, Ribosome biogenesis, Ribosome, Ribosome assembly, DEAD-box RNA Helicases, Adenosine Triphosphate, NMR spectroscopy, Escherichia coli, 50S, Multidisciplinary, RNA recognition motif, Chemistry, Escherichia coli Proteins, RNA, Biological Sciences, RNA Helicase A, Cell biology, Kinetics, RNA, Ribosomal, 23S, Biophysics and Computational Biology, Nucleic Acid Conformation, enzyme regulation, molecular mechanism, ribosome assembly, Ribosomes

Abstract

Significance DEAD-box RNA helicases are essential cellular enzymes that remodel misfolded RNA structures in an adenosine triphosphate (ATP)-dependent process. The DEAD-box helicase DbpA is involved in the complex and highly regulated process of ribosome maturation. To prevent wasteful hydrolysis of ATP by DbpA, the enzyme is only active when bound to maturing ribosomes. Here, we elucidate the structural basis behind this important regulatory mechanism and find that the recruited ribosome substrate is able to stabilize the catalytically important closed state of the helicase. In addition, our data identify the natural site of action for DbpA in the maturing ribosome and provide a molecular explanation for the observed ribosome maturation defects that result from the overexpression of a DbpA mutant form., The adenosine triphosphate (ATP)-dependent DEAD-box RNA helicase DbpA from Escherichia coli functions in ribosome biogenesis. DbpA is targeted to the nascent 50S subunit by an ancillary, carboxyl-terminal RNA recognition motif (RRM) that specifically binds to hairpin 92 (HP92) of the 23S ribosomal RNA (rRNA). The interaction between HP92 and the RRM is required for the helicase activity of the RecA-like core domains of DbpA. Here, we elucidate the structural basis by which DbpA activity is endorsed when the enzyme interacts with the maturing ribosome. We used nuclear magnetic resonance (NMR) spectroscopy to show that the RRM and the carboxyl-terminal RecA-like domain tightly interact. This orients HP92 such that this RNA hairpin can form electrostatic interactions with a positively charged patch in the N-terminal RecA-like domain. Consequently, the enzyme can stably adopt the catalytically important, closed conformation. The substrate binding mode in this complex reveals that a region 5′ to helix 90 in the maturing ribosome is specifically targeted by DbpA. Finally, our results indicate that the ribosome maturation defects induced by a dominant negative DbpA mutation are caused by a delayed dissociation of DbpA from the nascent ribosome. Taken together, our findings provide unique insights into the important regulatory mechanism that modulates the activity of DbpA.

Published

2021

9. Dcp2: an mRNA decapping enzyme that adopts many different shapes and forms

Author

Jan Philip Wurm and Remco Sprangers

Subjects

Models, Molecular, RNA Caps, Molecular Conformation, Article, Phase Transition, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, Endoribonucleases, Humans, Protein Interaction Maps, RNA, Messenger, Molecular Biology, ComputingMethodologies_COMPUTERGRAPHICS, 030304 developmental biology, Decapping enzyme, Decapping, chemistry.chemical_classification, 0303 health sciences, Messenger RNA, Binding Sites, Chemistry, MRNA decapping complex, Cell biology, Enzyme, Mrna level, 030217 neurology & neurosurgery, Protein Binding

Abstract

Graphical abstract, Highlights • Structure of the active state of the Dcp2 decapping enzyme. • Insights into the structural states that are sampled in solution. • Details regarding the intermolecular network that Dcp2 is embedded in., Eukaryotic mRNAs contain a 5’ cap structure that protects the transcript against rapid exonucleolytic degradation. The regulation of cellular mRNA levels therefore depends on a precise control of the mRNA decapping pathways. The major mRNA decapping enzyme in eukaryotic cells is Dcp2. It is regulated by interactions with several activators, including Dcp1, Edc1, and Edc3, as well as by an autoinhibition mechanism. The structural and mechanistical characterization of Dcp2 complexes has long been impeded by the high flexibility and dynamic nature of the enzyme. Here we review recent insights into the catalytically active conformation of the mRNA decapping complex, the mode of action of decapping activators and the large interactions network that Dcp2 is embedded in.

Published

2019

10. Molecular basis for the allosteric activation mechanism of the heterodimeric imidazole glycerol phosphate synthase complex

Author

Enrico Hupfeld, Matthias Wilmanns, Andrea C. Kneuttinger, Jan Philip Wurm, Remco Sprangers, Sihyun Sung, and Reinhard Sterner

Subjects

0301 basic medicine, Magnetic Resonance Spectroscopy, Protein Conformation, Stereochemistry, Glutamine, Science, Population, Allosteric regulation, General Physics and Astronomy, Crystallography, X-Ray, Cyclase, Catalysis, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Protein structure, Allosteric Regulation, Aminohydrolases, Multienzyme Complexes, Catalytic Domain, 570 Biowissenschaften, Biologie, Thermotoga maritima, Binding site, education, education.field_of_study, Binding Sites, Multidisciplinary, 030102 biochemistry & molecular biology, ATP synthase, biology, Chemistry, Hydrolysis, Imidazoles, Active site, General Chemistry, Ribonucleotides, 030104 developmental biology, Mutation, biology.protein, ddc:570, ddc:500, Oxyanion hole

Abstract

Nature Communications 12(1), 2748 (2021). doi:10.1038/s41467-021-22968-6, Imidazole glycerol phosphate synthase (HisFH) is a heterodimeric bienzyme complex operating at a central branch point of metabolism. HisFH is responsible for the HisH-catalyzed hydrolysis of glutamine to glutamate and ammonia, which is then used for a cyclase reaction by HisF. The HisFH complex is allosterically regulated but the underlying mechanism is not well understood. Here, we elucidate the molecular basis of the long range, allosteric activation of HisFH. We establish that the catalytically active HisFH conformation is only formed when the substrates of both HisH and HisF are bound. We show that in this conformation an oxyanion hole in the HisH active site is established, which rationalizes the observed 4500-fold allosteric activation compared to the inactive conformation. In solution, the inactive and active conformations are in a dynamic equilibrium and the HisFH turnover rates correlate with the population of the active conformation, which is in accordance with the ensemble model of allostery., Published by Nature Publishing Group UK, [London]

Published

2021

11. NMR resonance assignments for the SAM/SAH-binding riboswitch RNA bound to S-adenosylhomocysteine

Author

Heiko Keller, Jens Wöhnert, Michael Andreas Juen, Christoph Kreutz, Elke Duchardt-Ferner, Elisabeth Strebitzer, Johannes Kremser, Jan Philip Wurm, and A. Katharina Weickhmann

Subjects

0301 basic medicine, Riboswitch, S-Adenosylmethionine, Chemistry, Stereochemistry, RNA, Nuclear magnetic resonance spectroscopy, SAH riboswitch, S-Adenosylhomocysteine, Biochemistry, Small molecule, nervous system diseases, 03 medical and health sciences, 030104 developmental biology, Structural Biology, Transcription (biology), Triple-resonance nuclear magnetic resonance spectroscopy, Nucleic Acid Conformation, cardiovascular diseases, Nuclear Magnetic Resonance, Biomolecular, Protein secondary structure

Abstract

Riboswitches are structured RNA elements in the 5'-untranslated regions of bacterial mRNAs that are able to control the transcription or translation of these mRNAs in response to the specific binding of small molecules such as certain metabolites. Riboswitches that bind with high specificity to either S-adenosylmethionine (SAM) or S-adenosylhomocysteine (SAH) are widespread in bacteria. Based on differences in secondary structure and sequence these riboswitches can be grouped into a number of distinct classes. X-ray structures for riboswitch RNAs in complex with SAM or SAH established a structural basis for understanding ligand recognition and discrimination in many of these riboswitch classes. One class of riboswitches-the so-called SAM/SAH riboswitch class-binds SAM and SAH with similar affinity. However, this class of riboswitches is structurally not yet characterized and the structural basis for its unusual bispecificity is not established. In order to understand the ligand recognition mode that enables this riboswitch to bind both SAM and SAH with similar affinities, we are currently determining its structure in complex with SAH using NMR spectroscopy. Here, we present the NMR resonance assignment of the SAM/SAH binding riboswitch (env9b) in complex with SAH as a prerequisite for a solution NMR-based high-resolution structure determination.

Published

2018

12. The Rrp4–exosome complex recruits and channels substrate RNA by a unique mechanism

Author

Stefan Schütz, Maxime J. C. Audin, Remco Sprangers, Jan Philip Wurm, and Milos A. Cvetkovic

Subjects

0301 basic medicine, Enzyme complex, Exosome complex, Stereochemistry, Archaeal Proteins, Substrate (chemistry), RNA, RNA, Archaeal, Cell Biology, Protomer, Biology, Exosomes, Article, Molecular machine, 03 medical and health sciences, 030104 developmental biology, Sulfolobus solfataricus, Biophysics, Nucleic acid, Nucleic acid structure, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology

Abstract

The exosome is a large molecular machine that is involved in RNA degradation and processing. Here, we address how the trimeric Rrp4 cap enhances the activity of the archaeal enzyme complex. Using methyl TROSY NMR methods we identified a 50 Å long RNA binding path on each Rrp4 protomer. We show that the Rrp4 cap can thus recruit three substrates simultaneously, one of which is degraded in the core while two others are positioned for subsequent degradation rounds. The local interaction energy between the substrate and the Rrp4-exosome increases from the periphery of the complex towards the active sites. Importantly, the intrinsic interaction strength between the cap and the substrate is weakened as soon as substrates enter the catalytic barrel, which provides a means to reduce friction during substrate movements towards the active sites. Our data thus reveal a sophisticated exosome–substrate interaction mechanism that enables efficient RNA degradation.

Published

2017

13. An intermolecular G-quadruplex as the basis for GTP recognition in the class V–GTP aptamer

Author

Jens Wöhnert, A.K. Weickhmann, Amir H. Nasiri, Carina Immer, and Jan Philip Wurm

Subjects

0301 basic medicine, GTP', Stereochemistry, Guanine, Aptamer, Guanosine, Biology, 010402 general chemistry, G-quadruplex, 01 natural sciences, Article, 03 medical and health sciences, chemistry.chemical_compound, ddc:570, Nucleic acid structure, Nuclear Magnetic Resonance, Biomolecular, Molecular Biology, Protein secondary structure, Binding Sites, Aptamers, Nucleotide, Cations, Monovalent, Ligand (biochemistry), 0104 chemical sciences, G-Quadruplexes, 030104 developmental biology, Biochemistry, chemistry, Guanosine Triphosphate

Abstract

Many naturally occurring or artificially created RNAs are capable of binding to guanine or guanine derivatives with high affinity and selectivity. They bind their ligands using very different recognition modes involving a diverse set of hydrogen bonding and stacking interactions. Apparently, the potential structural diversity for guanine, guanosine, and guanine nucleotide binding motifs is far from being fully explored. Szostak and coworkers have derived a large set of different GTP-binding aptamer families differing widely in sequence, secondary structure, and ligand specificity. The so-called class V–GTP aptamer from this set binds GTP with very high affinity and has a complex secondary structure. Here we use solution NMR spectroscopy to demonstrate that the class V aptamer binds GTP through the formation of an intermolecular two-layered G-quadruplex structure that directly incorporates the ligand and folds only upon ligand addition. Ligand binding and G-quadruplex formation depend strongly on the identity of monovalent cations present with a clear preference for potassium ions. GTP binding through direct insertion into an intermolecular G-quadruplex is a previously unobserved structural variation for ligand-binding RNA motifs and rationalizes the previously observed specificity pattern of the class V aptamer for GTP analogs.

Published

2016

14. Ribosome biogenesis factor Tsr3 is the aminocarboxypropyl transferase responsible for 18S rRNA hypermodification in yeast and humans

Author

Jan Philip Wurm, Jens Wöhnert, Peter Kötter, Denis L. J. Lafontaine, Sunny Sharma, Carina Immer, Britta Meyer, Denys Pogoryelov, and Karl-Dieter Entian

Subjects

Models, Molecular, 0301 basic medicine, S-Adenosylmethionine, Saccharomyces cerevisiae, Ribosome biogenesis, Crystallography, X-Ray, Ribosome, Pseudouridine, 03 medical and health sciences, chemistry.chemical_compound, 23S ribosomal RNA, Catalytic Domain, RNA, Ribosomal, 18S, Genetics, Humans, Transferase, RNA Processing, Post-Transcriptional, Alkyl and Aryl Transferases, biology, Nucleic Acid Enzymes, Inverted Repeat Sequences, Hydrogen Bonding, Ribosomal RNA, HCT116 Cells, biology.organism_classification, 3. Good health, 030104 developmental biology, Biochemistry, chemistry, Transfer RNA, Biologie, Protein Binding

Abstract

The chemically most complex modification in eukaryotic rRNA is the conserved hypermodified nucleotide N1-methyl-N3-aminocarboxypropyl-pseudouridine (m/acp 3 Ψ) located next to the P-site tRNA on the small subunit 18S rRNA. While S-adenosylmethionine was identified as the source of the aminocarboxypropyl (acp) group more than 40 years ago the enzyme catalyzing the acp transfer remained elusive. Here we identify the cytoplasmic ribosome biogenesis protein Tsr3 as the responsible enzyme in yeast and human cells. In functionally impaired Tsr3-mutants, a reduced level of acp modification directly correlates with increased 20S pre-rRNA accumulation. The crystal structure of archaeal Tsr3 homologs revealed the same fold as in SPOUT-class RNA-methyltransferases but a distinct SAM binding mode. This unique SAM binding mode explains why Tsr3 transfers the acp and not the methyl group of SAM to its substrate. Structurally, Tsr3 therefore represents a novel class of acp transferase enzymes., SCOPUS: ar.j, info:eu-repo/semantics/published

Published

2016

15. The oligomeric architecture of the archaeal exosome is important for processive and efficient RNA degradation

Author

Milos A. Cvetkovic, Remco Sprangers, Maxime J. C. Audin, and Jan Philip Wurm

Subjects

Models, Molecular, 0301 basic medicine, RNA Stability, Archaeal Proteins, Molecular Sequence Data, Gene Expression, RNA-binding protein, RNA, Archaeal, Exosomes, 010402 general chemistry, 01 natural sciences, Protein Structure, Secondary, 03 medical and health sciences, Protein structure, Structural Biology, Catalytic Domain, Gene expression, Escherichia coli, Genetics, Amino Acid Sequence, Cloning, Molecular, Binding site, Binding Sites, Exosome Multienzyme Ribonuclease Complex, biology, RNA-Binding Proteins, Active site, RNA, 15. Life on land, Protein Structure, Tertiary, 0104 chemical sciences, Kinetics, 030104 developmental biology, Biochemistry, Biocatalysis, Sulfolobus solfataricus, biology.protein, Biophysics, Protein Multimerization, Sequence Alignment, Protein Binding

Abstract

The exosome plays an important role in RNA degradation and processing. In archaea, three Rrp41:Rrp42 heterodimers assemble into a barrel like structure that contains a narrow RNA entrance pore and a lumen that contains three active sites. Here, we demonstrate that this quaternary structure of the exosome is important for efficient RNA degradation. We find that the entrance pore of the barrel is required for nM substrate affinity. This strong interaction is crucial for processive substrate degradation and prevents premature release of the RNA from the enzyme. Using methyl TROSY NMR techniques, we establish that the 3' end of the substrate remains highly flexible inside the lumen. As a result, the RNA jumps between the three active sites that all equally participate in substrate degradation. The RNA jumping rate is, however, much faster than the cleavage rate, indicating that not all active site:substrate encounters result in catalysis. Enzymatic turnover therefore benefits from the confinement of the active sites and substrate in the lumen, which ensures that the RNA is at all times bound to one of the active sites. The evolution of the exosome into a hexameric complex and the optimization of its catalytic efficiency were thus likely co-occurring events.

Published

2016

16. What a Difference an OH Makes: Conformational Dynamics as the Basis for the Ligand Specificity of the Neomycin-Sensing Riboswitch

Author

Christian Hammann, Elke Duchardt-Ferner, Jens Wöhnert, Sina R. Gottstein-Schmidtke, Julia E. Weigand, Jan-Philip Wurm, Beatrix Suess, and Oliver Ohlenschläger

Subjects

Models, Molecular, 0301 basic medicine, Riboswitch, Hydroxyl Radical, Stereochemistry, Ligand, Chemistry, Intermolecular force, RNA, Neomycin, General Chemistry, Ligands, Catalysis, 03 medical and health sciences, 030104 developmental biology, Structural biology, Cobalamin riboswitch, Intramolecular force, medicine, medicine.drug

Abstract

To ensure appropriate metabolic regulation, riboswitches must discriminate efficiently between their target ligands and chemically similar molecules that are also present in the cell. A remarkable example of efficient ligand discrimination is a synthetic neomycin-sensing riboswitch. Paromomycin, which differs from neomycin only by the substitution of a single amino group with a hydroxy group, also binds but does not flip the riboswitch. Interestingly, the solution structures of the two riboswitch-ligand complexes are virtually identical. In this work, we demonstrate that the local loss of key intermolecular interactions at the substitution site is translated through a defined network of intramolecular interactions into global changes in RNA conformational dynamics. The remarkable specificity of this riboswitch is thus based on structural dynamics rather than static structural differences. In this respect, the neomycin riboswitch is a model for many of its natural counterparts.

Published

2015

17. Eine OH-Gruppe ändert alles: konformative Dynamik als Grundlage für die Ligandenspezifität des Neomycin-bindenden RNA-Schalters

Author

Beatrix Suess, Christian Hammann, Jan-Philip Wurm, Jens Wöhnert, Julia E. Weigand, Oliver Ohlenschläger, Sina R. Gottstein-Schmidtke, and Elke Duchardt-Ferner

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, Chemistry, General Medicine

Published

2015

18. Structure and Biophysical Characterization of the S-Adenosylmethionine-dependent O-Methyltransferase PaMTH1, a Putative Enzyme Accumulating during Senescence of Podospora anserina

Author

Rupert Abele, Krishna Saxena, Volker Dötsch, Santosh Lakshmi Gande, Harald Schwalbe, Sridhar Sreeramulu, Vladimir V. Rogov, Jens Wöhnert, Heinz D. Osiewacz, Verena Linhard, Ulrich Schieborr, Jan Philip Wurm, Denis Kudlinzki, and Deep Chatterjee

Subjects

S-Adenosylmethionine, Rossmann fold, Methyltransferase, Stereochemistry, Biophysics, Crystallography, X-Ray, Biochemistry, Podospora anserina, Fungal Proteins, chemistry.chemical_compound, Podospora, Molecular Biology, Flavonoids, biology, Active site, Methyltransferases, Cell Biology, Methylation, biology.organism_classification, O-methyltransferase, Oxidative Stress, chemistry, Protein Structure and Folding, biology.protein, Hydroxyl radical, Myricetin

Abstract

Low levels of reactive oxygen species (ROS) act as important signaling molecules, but in excess they can damage biomolecules. ROS regulation is therefore of key importance. Several polyphenols in general and flavonoids in particular have the potential to generate hydroxyl radicals, the most hazardous among all ROS. However, the generation of a hydroxyl radical and subsequent ROS formation can be prevented by methylation of the hydroxyl group of the flavonoids. O-Methylation is performed by O-methyltransferases, members of the S-adenosyl-l-methionine (SAM)-dependent O-methyltransferase superfamily involved in the secondary metabolism of many species across all kingdoms. In the filamentous fungus Podospora anserina, a well established aging model, the O-methyltransferase (PaMTH1) was reported to accumulate in total and mitochondrial protein extracts during aging. In vitro functional studies revealed flavonoids and in particular myricetin as its potential substrate. The molecular architecture of PaMTH1 and the mechanism of the methyl transfer reaction remain unknown. Here, we report the crystal structures of PaMTH1 apoenzyme, PaMTH1-SAM (co-factor), and PaMTH1-S-adenosyl homocysteine (by-product) co-complexes refined to 2.0, 1.9, and 1.9 Å, respectively. PaMTH1 forms a tight dimer through swapping of the N termini. Each monomer adopts the Rossmann fold typical for many SAM-binding methyltransferases. Structural comparisons between different O-methyltransferases reveal a strikingly similar co-factor binding pocket but differences in the substrate binding pocket, indicating specific molecular determinants required for substrate selection. Furthermore, using NMR, mass spectrometry, and site-directed active site mutagenesis, we show that PaMTH1 catalyzes the transfer of the methyl group from SAM to one hydroxyl group of the myricetin in a cation-dependent manner.

Published

2015

19. Changes in conformational equilibria regulate the activity of the Dcp2 decapping enzyme

Author

Jan H. Overbeck, Jan Philip Wurm, Remco Sprangers, Philipp H. O. Mayer, and Iris Holdermann

Subjects

0301 basic medicine, Models, Molecular, RNA Caps, Magnetic Resonance Spectroscopy, Protein Conformation, RNA Stability, RNA-binding protein, Biology, Crystallography, X-Ray, 03 medical and health sciences, Catalytic Domain, Endoribonucleases, Schizosaccharomyces, RNA, Messenger, chemistry.chemical_classification, Messenger RNA, Multidisciplinary, 030102 biochemistry & molecular biology, Activator (genetics), Protein dynamics, Substrate (chemistry), RNA-Binding Proteins, Biological Sciences, 030104 developmental biology, Enzyme, Catalytic cycle, Biochemistry, Proteasome, chemistry, RNA Cap-Binding Proteins, Biophysics, Schizosaccharomyces pombe Proteins

Abstract

Crystal structures of enzymes are indispensable to understanding their mechanisms on a molecular level. It, however, remains challenging to determine which structures are adopted in solution, especially for dynamic complexes. Here, we study the bilobed decapping enzyme Dcp2 that removes the 5′ cap structure from eukaryotic mRNA and thereby efficiently terminates gene expression. The numerous Dcp2 structures can be grouped into six states where the domain orientation between the catalytic and regulatory domains significantly differs. Despite this wealth of structural information it is not possible to correlate these states with the catalytic cycle or the activity of the enzyme. Using methyl transverse relaxation-optimized NMR spectroscopy, we demonstrate that only three of the six domain orientations are present in solution, where Dcp2 adopts an open, a closed, or a catalytically active state. We show how mRNA substrate and the activator proteins Dcp1 and Edc1 influence the dynamic equilibria between these states and how this modulates catalytic activity. Importantly, the active state of the complex is only stably formed in the presence of both activators and the mRNA substrate or the m7GDP decapping product, which we rationalize based on a crystal structure of the Dcp1:Dcp2:Edc1:m7GDP complex. Interestingly, we find that the activating mechanisms in Dcp2 also result in a shift of the substrate specificity from bacterial to eukaryotic mRNA.

Published

2017

20. The S. pombe mRNA decapping complex recruits cofactors and an Edc1-like activator through a single dynamic surface

Author

Jan H. Overbeck, Remco Sprangers, and Jan Philip Wurm

Subjects

0301 basic medicine, Exonuclease, RNA Stability, RNA-binding protein, Protein Serine-Threonine Kinases, Article, 03 medical and health sciences, 0302 clinical medicine, EVH1 domain, Schizosaccharomyces, RNA, Messenger, Binding site, Molecular Biology, Messenger RNA, Cap binding complex, Binding Sites, biology, RNA-Binding Proteins, biology.organism_classification, Cell biology, Decapping complex, 030104 developmental biology, Biochemistry, biology.protein, Schizosaccharomyces pombe Proteins, 030217 neurology & neurosurgery, Protein Binding

Abstract

The removal of the 5′ 7-methylguanosine mRNA cap structure (decapping) is a central step in the 5′–3′ mRNA degradation pathway and is performed by the Dcp1:Dcp2 decapping complex. The activity of this complex is tightly regulated to prevent premature degradation of the transcript. Here, we establish that the aromatic groove of the EVH1 domain of Schizosaccharomyces pombe Dcp1 can interact with proline-rich sequences in the exonuclease Xrn1, the scaffolding protein Pat1, the helicase Dhh1, and the C-terminal disordered region of Dcp2. We show that this region of Dcp1 can also recruit a previously unidentified enhancer of decapping protein (Edc1) and solved the crystal structure of the complex. NMR relaxation dispersion experiments reveal that the Dcp1 binding site can adopt multiple conformations, thus providing the plasticity that is required to accommodate different ligands. We show that the activator Edc1 makes additional contacts with the regulatory domain of Dcp2 and that an activation motif in Edc1 increases the RNA affinity of Dcp1:Dcp2. Our data support a model where Edc1 stabilizes the RNA in the active site, which results in enhanced decapping rates. In summary, we show that multiple decapping factors, including the Dcp2 C-terminal region, compete with Edc1 for Dcp1 binding. Our data thus reveal a network of interactions that can fine-tune the catalytic activity of the decapping complex.

Published

2016