The Phosphate Vibration as a Sensor for Ion-Pair Formation Studied by Nonlinear Time-Resolved Vibrational Spectroscopy

Schauss, Jakob

24 August 2022

Die Struktur und Dynamik von Biomolekülen wird durch ein komplexes Wechselspiel mit Ionen und Wassermolekülen der Hydratationshülle beeinflusst. Die Wechselwirkungen sind kaum verstanden, zum Teil weil es an experimentellen molekularen Sonden mangelt. Lokale Schwingungen des RNA-Rückgrats bieten solch nicht-invasive Sonden, empfindlich gegenüber den ersten Schichten der RNA-Solvatationshülle. Die Empfindlichkeit rührt von elektrischen Feldern auf der biomolekularen Oberfläche. Diese Dissertation nutzt die Sensitivität aus, um mit Femtosekunden-2D-IR-Spektroskopie der asymmetrischen Phosphatstreckschwingung die Rolle positiv geladener Ionen, insbesondere Magnesium, Mg2+, zu untersuchen, die negativ geladene Phosphatgruppen des Rückgrats kompensieren. Erste Experimente an Dimethylphosphat, zusammen mit theoretischen Berechnungen, zeigen eine Blauverschiebung der Phosphatmode aufgrund der Bildung von Kontaktionenpaaren. Kurze Abstände zwischen Mg2+ und der Phosphatgruppe führen zu repulsiven Austauschwechselwirkungen, die die Potentialfläche der Schwingung stören. Bei Doppelstrang-RNA zeigt sich eine starke Abhängigkeit der Phosphatschwingung von lokalen Wasserstrukturen. Frequenzverschiebungen durch den Starkeffekt führen zu drei Schwingungsbanden, die unterschiedliche lokale Geometrien widerspiegeln. Elektrische Felder von solvatisierenden Wassermolekülen beeinflussen dabei das Bindungspotential. Abschließend erlaubt es die Blauverschiebung der Phosphatmode, die Bildung von Mg2+/Phosphat Kontaktionenpaaren in Transfer-RNA quantitativ zu verfolgen. Es wird gezeigt, dass diese die Tertiärstruktur der tRNA stabilisieren, indem sie die Coulombabstoßung zwischen negativ geladenen Phosphatgruppen kompensieren, besonders in kompakten Regionen. Die Dissertation demonstriert das Potential zeitaufgelöster Schwingungsspektroskopie, kombiniert mit theoretischen Beschreibungen auf molekularer Ebene, um die komplexen Interaktionen biomolekularer Solvatationsumgebungen zu erforschen. / The structure and dynamics of biomolecules are influenced by a complex interplay with ions and water molecules in the local hydration shell. The underlying interactions are poorly understood, partly because of a lack of experimental probes that can access the molecular scale. Local vibrations of the RNA backbone provide non-invasive probes sensitive to the first hydration layers of the RNA solvation shell via the imposed electric field on the biomolecular surface. This thesis exploits this sensitivity in femtosecond 2D-IR spectroscopy experiments on the asymmetric phosphate stretch vibration to investigate the role of positively charged ions, particularly the magnesium cation Mg2+, in counteracting the negatively charged phosphate backbone. Initial experiments with the model system dimethyl phosphate in combination with theoretical calculations report a frequency blue-shift due to the formation of contact ion pairs. Short distances between Mg2+ and phosphate lead to exchange repulsion interactions that perturb the vibrational potential energy surface. In double helical RNA, a strong dependence of the phosphate mode on the local hydration structure of the phosphate group is found. Three distinct vibrational peaks reflect different hydration geometries as a result of vibrational Stark shifts. Responsible for the frequency shifts are electric fields from solvating water molecules. Ultimately, the blue-shift of the phosphate mode allows to quantitatively follow the formation of Mg2+-phosphate contact pairs in transfer RNA systems. It is shown that these configurations stabilize the tertiary structure of tRNA molecules by efficiently compensating the Coulomb repulsion from negatively charged phosphate groups, particularly in highly congested regions. The thesis demonstrates the potential of time-resolved vibrational spectroscopy combined with theoretical descriptions on the molecular level to probe the complex interactions of biomolecular solvation environments.

Schwingungsspektroskopie

Kontaktionenpaar

Solvatationshülle

tRNA

vibrational spectroscopy

contact ion pair

solvation shell

tRNA

530 Physik

ddc:530

Characterization of substrate specificity and amino acid editing by human ProXp-ala

Abid, Jawad

06 September 2022

No description available.

Biochemistry

Chemistry

The Role in Translation of Editing and Multi-Synthetase Complex Formation by Aminoacyl-tRNA Synthetases

Raina, Medha Vijay

25 September 2014

No description available.

Biochemistry

protein synthesis

tRNA

aminoacyl-tRNA synthetase

multi-synthetase complex

quality control

editing

Beyond Mistranslation: Expanding the Role of Aminoacyl-tRNA Synthetases towards the Maintenance of Cellular Viability

Mohler, Kyle

27 October 2017

No description available.

Microbiology

Cellular Biology

Requirements and rationale for amber translation as pyrrolysine

Longstaff, David Gordon

10 December 2007

No description available.

pyrrolysine

pyrrolysyl-tRNA

pyrrolysyl-tRNA synthetase

pyrrolysine biosynthesis

genetic code expansion

PYLIS element

pyrrolysine function

tRNA Splicing Endonuclease: Novel and Essential Function Beyond tRNA Splicing and Subunit interactions

Dhungel, Nripesh

25 June 2012

No description available.

Biology

Cellular Biology

Genetics

Molecular Biology

tRNA splicing endonuclease

tRNA ligase

phosphotransferase

rRNA processing

pontocerebellar hypoplasia

ROLE OF PHENYLALANYL-TRNA SYNTHETASE IN AMINOACYLATION AND TRANSLATION QUALITY CONTROL

Yadavalli, Srujana Samhita

27 June 2012

No description available.

Biochemistry

Microbiology

protein synthesis

tRNA

aminoacyl-tRNA synthetase

quality control

editing

mitochondrial disease

Structure Function Relationship In Tryptophanyl tRNA Synthetase Through MD Simulations & Quantum Chemical Studies On Unusual Bonds In Biomolecules

Hansia, Priti

02 1900

Biological processes are so complicated that to understand the mechanisms underlying the functioning of biomolecules it is inevitable to study them from various perspectives and with a wide range of tools. Understanding the function at the molecular level obviously requires the knowledge of the three dimensional structure of the biomolecules. Experimentally this can be obtained by techniques such as X‐ray crystallography and NMR studies. Computational biology has also played an important role in elucidating the structure function relationship in biomolecules. Computationally one can obtain the temporal as well as ensemble behavior of biomolecules at atomic level under conditions that are experimentally not accessible. Molecular dynamics(MD) study is a technique that can be used to obtain information of the dynamic behavior of the biomolecules. Dynamics of large systems like proteins can be investigated by classical force fields. However, the changes at the level of covalent bond involve the reorganization of electron density distribution which can be addressed only at Quantum mechanical level. In the present thesis, some of the biological systems have been characterized both at the classical and quantum mechanical level. The systems investigated by MD simulations and the insights brought from these studies are presented in Chapters 3 and 4. The unusual bonds such as pyrophosphate linkage in ATP and short strong hydrogen bonds in proteins, investigated through high level quantum chemical methods, are presented in Chapters 5, 6 and 7. Part of this thesis is aimed to address some important issues related to the dynamics of Tryptophanyl tRNA synthetase (TrpRS) which belongs to classic of aminoacyl‐tRNA synthetases (aaRS). aaRSs are extremely important class of enzymes involved in the translation of genetic code. These enzymes catalyze the aminoacylation of tRNAs to relate the cognate amino acids to the anticodon trinucleotide sequences. aaRSs are modular enzymes with distinct domains on which extensive kinetic and mutational experiments as well as structural analyses have been carried out, highlighting the role of inter‐domain communication (Alexander and Schimmel, 2001). The overall architecture of tRNA synthetases consists of primarily two domains. The active site domain is responsible for the activation of an amino acid with ATP in synthesizing an enzyme‐bound aminoacyl‐adenylate, and transfer of the aminoacyl‐adenylate intermediate to the 3’end of tRNA. The second domain is responsible for selection and binding of the cognate tRNA. aaRSs are allosteric proteins in which the binding of tRNA at the anticodon domain influences the activity at the catalytic region. These two binding sites are separated by a large distance. One of the aims of this thesis is to characterize such long distance communication (allosteric communication) at atomic level in Tryptophanyl tRNA synthetase. This is achieved by generating ensembles of conformations by MD simulations and analyzing the trajectories by novel graph theoretic approach. Graph and network based approaches are well established in the field of protein structure analysis for analyzing protein structure, stability and function (Kannan and Vishveshwara, 1999; Brinda and Vishveshwara, 2005). The parameters such as clusters, hubs and shortest paths provide valuable information on the structure and dynamics of the proteins. In this thesis, network parameters are used for the analysis of molecular dynamics MD) simulation data, to represent the global dynamic behavior of protein in a more elegant way. MD simulations are performed on some available (and modeled) structures of TrpRS bound to a variety of ligands, and the protein structure networks( PSN) of non‐covalent interactions are characterized in dynamical equilibrium. The ligand induced conformational changes are investigated through structure networks. These networks are used to understand the mode of communication between the anticodon domain and the active site. The interface dynamics is crucial for the function of TrpRS (since it is a functional dimer) and it is investigated through interface clusters. The matter embodied in the thesis is presented as 9 chapters. Chapter 1 lays the suitable background and foundation for the study, surveying relevant literature from different fields .Chapter 2 describes in detail the various materials, methods and techniques employed in the different analyses and studies presented in this thesis. A brief description of well‐known methods of molecular dynamics simulations, essential dynamics calculations, cross correlation maps, conformational clustering etc.is presented. The methods for constructing protein structure graphs and networks, developed in our lab, are described in detail. The use of network parameters for the analysis of MD simulation data to address the problem of communication between the two distal sites is also presented. Some descriptions of the ab initio quantum mechanical methods, which are used to investigate the unusual bonds in biomolecules, are also presented in this chapter. Chapter 3 is devoted in discussing the results from several normal as well as high temperature MD simulations of ligand‐free and ligand bound Bacillus stearothermophilus Tryptophanyl‐tRNA synthetase (bsTrpRS). The essential modes of the protein in the presence of different ligands are captured by essential dynamics calculations. Different conformations of the protein associated with the catalysis process of TrpRS, as captured through experiments, are discussed in the context of conformational sampling. High temperature simulations are carried out to explore the larger conformational space. Chapter 4 is focused on the results obtained from the MD simulation of human Tryptophanyl‐tRNA synthetase (hTrpRS). The structure of human TrpRS bound to the activated ligand (TrpAMP) and the cognate tRNA(tRNATRP) is modeled since no structure in the presence of both TrpAMP and tRNATRP is available. MD simulations on these modeled as well as other complexes of hTrpRS are performed to capture the dynamical process of ligand induced conformational changes (Hansiaetal., communicated). Both the local and the global changes in the protein conformation from the protein structure network (PSN) of MD snapshots are analyzed. Several important information such as the ligand induced correlation between different residues of the protein, asymmetric binding of the ligands to the two subunits of the protein, and the path of communication between the anticodon region and the aminoacylation site are obtained. Also, the role of the dimmer interface, from a dynamic perspective, is obtained for the first time. The interface dynamics which stabilize different quaternary structures of lectins (with high sequence and structure similarity) were investigated in a collaborative work (Hansiaetal.,2007). The lectin peanut agglutinin (PNA) is a tetramer with three different types of interfaces. The interface dynamics of this protein in the presence and in the absence of metal ions was investigated and the paper reporting the results from this study is included as appendix in this thesis. Chapter 5 deals with high level ab initio quantum chemical calculations on tri‐ and diphosphate fragments of adenosine triphosphate (ATP). Pyrophosphate prototypes such as methyl triphosphate and methyl diphosphate molecules in their different protonation states have been investigated at high levels of calculations (Hansiaetal., 2006a). The optimized geometries, the thermochemistry of the hydrolysis and the molecular orbitals contributing to the high energy of these compounds have been analyzed. These investigations provide insights into the‘‘highenergy’’character of ATP molecule. Further, the dependence of vibrational frequencies on the number of phosphate groups and the charged states has also been presented. These results aid in the interpretation of spectra obtained by experiments on complexes containing pyrophosphate prototypes. Hydrogen bonding is fundamental in understanding the structure and properties of molecules of biological interest including proteins. A recent analysis carried out in our lab showed that a significant number of short hydrogen bonds (SHB) are present in proteins (Rajagopal and Vishveshwara, 2005). Chapters 6 and 7 elucidate the results obtained from ab initio quantum chemical calculations on some of these SHBs to get aquantitative estimation of their geometry and strength. In chapter 6, asystematic analysis of the geometries and the energetics of possible SHB systems, which are frequently encountered in proteins, are presented at different levels of theory (HF,DFTandMP2). It is found that the SHBs involving both charged residues in the proteins are intrinsic in nature. However, two neutral residues form a SHB in the protein crystal structures either due to geometric constraints or due to the environment of these residues. This analysis enables one to distinguish SHBs which are formed because of geometric constraints from those which are formed because of the inherent property of the chemical groups involved in the hydrogen bonding. These results are useful in refining protein structures determined by crystallographic or NMR methods. In addition, sulfur atom of methionine and cysteinein proteins also participate in SHBs, which are not so well characterized. Chapter 7 presents the similar analysis carried out on short hydrogen bonds in proteins involving sulfur atom. A detailed analysis of SHBs of sulfur containing groups in a data set of proteins has been carried out. Some of the residue pairs from this analysis were considered for ab initio calculations. However, the optimization of these examples resulted in breaking of the hydrogen bonds involving sulfur atoms and formation of new hydrogen bonds with oxygen and/or nitrogen atoms. Hence model systems, which mimic the real examples, were designed to carry out ab initio studies and to investigate the short hydrogen bonds involving sulfur atoms. Another study on the protein‐water interaction, which does not fall under the realm of the main objective of the thesis, is discussed in Chapter 8. Protein–water interaction is crucial for accomplishing many biological functions of proteins. In the recent past, natural probe tryptophan, located at the protein surfaces, has been extensively investigated using femtosecond spectroscopy experiments to understand salvation dynamics (Peonetal.,2002). In this chapter a method is described to follow up the molecular events of the protein–water interactions in detail. Tryptophan–water interaction in the protein Monellin is investigated in order to get the atomic level insights into the hydration dynamics, by carrying out MD simulations on Monellin (Hansiaetal.,2006b). The results are compared with those obtained from femtosecond resolved fluorescence spectroscopy. The time constants of the survival correlation function match well with the reported experimental values.This validates the procedure, adapted here for Monellin, to investigate the hydration dynamics in general. The last chapter (Chapter9) summarizes the results obtained from various studies and discusses the future directions. First part of this thesis aims to present the analysis by carrying out MD simulations on monomeric and dimeric TrpRS protein in order to understand the two steps of the aminoacylation reaction: activation of the aminoacid Trp in the first step and the transfer of the activated amino acid in the next step. In the second part, quantitative estimation of the geometry and the strength of pyrophosphate bond and short hydrogen bonds in proteins are reported in detail by subjecting the systems to high levels of quantum mechanical calculations(QM). The use of ab initio QM/MM calculations by combining the quantum mechanics(QM) with the molecular mechanics(MM) in order to study the enzymatic reactions is discussed as the future

tRNA

Transfer RNA

Tryptophanyl tRNA

Multidimensional Scaling

Human Tryptophanyl tRNA Synthetase

Aminoacyl-tRNA Synthetases (aaRSs)

Short Hydrogen Bonds

Proteins - Molecular Dynamics

Monellin

Adenosine Triphosphate

Biomolecules

Tryptophanyl tRNA synthetase (TrpRS)

Biochemical Genetics

Mécanismes et évolution des complexes ribonucléoprotéiques responsables de la biosynthèse ARNt-dépendante des acides aminés / Mechanisms and evolution of the ribonucleoprotein complexes involved in the tRNA-dependent amino acid biosynthesis

Fischer, Frédéric

28 September 2012

La traduction implique l’utilisation d’aminoacyl-ARNt produits par les aminoacyl-ARNt synthétases (aaRS). Il devrait exister 20 aaRS, une spécifique de chaque acide aminé. Or, les données actuelles montrent qu’une grande majorité des organismes ne possèdent pas l’asparaginyl- (AsnRS) et/ou la glutaminyl-ARNt synthétase (GlnRS). Ils ne peuvent synthétiser l’Asn-ARNtAsn et le Gln-ARNtGln que par l’utilisation de voies impliquant la formation préalable d’aspartyl-ARNtAsn et/ou de glutamyl-ARNtGln. Ces précurseurs « mésacylés » sont synthétisés par une aspartyl-ARNt synthétase et/ou une glutamyl-ARNt synthétase non-discriminantes (AspRS-ND ou GluRS-ND). Ils sont ensuite amidés par une amidotransférase (AdT), pour fournir à la cellule l’Asn-ARNtAsn et/ou le Gln-ARNtGln nécessaires à la traduction des codons Asn et Gln.Ce travail de thèse, effectué dans le contexte biologique de deux organismes différents, Thermus thermophilus et Helicobacter pylori, a permis de montrer que les étapes enzymatiques – formation du précurseur, et amidation par l’AdT – sont réalisées au sein de complexes ribonucléoprotéiques, réunissant l’aaRS-ND, l’ARNtAsn ou l’ARNtGln, et l’AdT : l’Asn-transamidosome ou le Gln-transamidosome. Selon leur origine ou la voie à laquelle ils appartiennent (asparaginylation ou glutaminylation), ces complexes possèdent des particularités mécanistiques et structurales très différentes, mais sont tous adaptés pour éviter la libération des intermédiaires mésacylés toxiques par des stratégies spécifiques. Ce travail permet de mieux comprendre les mécanismes évolutifs qui ont conduit à l’incorporation de l’Asn et de la Gln dans le code génétique. / Protein synthesis requires the biosynthesis of aminoacyl-tRNAs by aminoacyl-tRNA synthétases (aaRS). Since 20 amino acids are présent within the genetic code, 20 aaRS should be used by a single organism. However, the vast majority of organisms found today are deprived of asparaginyl- and/or glutaminyl-tRNA synthetases (Asn- or GlnRS). They can only synthesize Asn-tRNAAsn and/or Gln-tRNAGln through biosynthesis pathways involving the preliminary formation of aspartyl-tRNAAsn and /or glutamyl-tRNAGln. Those « misacylated » precursors are synthesized by so called non-discriminating aspartyl- or glutamyl-tRNA synthetases (ND-AspRS or –GluRS). Then, they are transferred to an amidotransferase (AdT) to provide the Asn-tRNAAsn and/or Gln-tRNAGln species (necessary to fuel protein synthesis) through amidation.This work was performed in the context of two organisms – Thermus thermophilus and Helicobacter pylori. It showed that the two enzymatic steps of asparaginylation and glutaminylation – biosynthesis of the misacylated precursor and amidation by AdT – are carried out within a single ribonucleoprotein complex, namely the (Asn- or Gln-) transamidosome, gathering the ND-aaRS necessary for the misacylation, the tRNA substrate (Asn or Gln) and the AdT. According to their origin or the pathway they originate from (asparaginylation or glutaminylation), those complexes display significant mechanistical and structural peculiarities, but they are all adapted to prevent libération of the toxic misacylated species through specific strategies. This work shed new light on the évolutive mechanisms that led to the incorporation of Asn or Gln into the genetic code.

Transamidosome

Glutamyl-ARNt synthétase

Aspartyl-ARNt synthétase

GatCAB

Thermus thermophilus

Helicobacter pylori

Aminoacylation

Aminoacyl-tRNA synthétases

Glutaminyl-tRNA synthetases

Asparaginyl-tRNA synthetases

Helicobacter pylori

Thermus thermophilus

572.8

STUDIES OF THE PYRROLYSYL-TRNA SYNTHETASE

Jiang, Ruisheng

23 July 2013

No description available.

Biochemistry

Microbiology

Archaeology

pyrrolysine

Amino Acid

Aminoacyl tRNA Synthetase

Archaea

Bacteria

RNA-binding Protein

Transfer RNA (tRNA)

22nd Amino Acid

Genetic Code

Pyrrolysyl-tRNA Synthetase