Global ETD Search

261	Analysis and Quantification of Inositol Poly- and Pyrophosphates by NMR Spectroscopy and Mass Spectrometry Puschmann, Robert 22 January 2020 (has links) Inositolpyrophosphate (PP-InsP) sind eine Gruppe sekundärer Signalmoleküle, die in einer Vielzahl zellulärer Prozesse, von Phosphathomeostase über Insulinsignalisierung bis Apoptose eine Rolle spielen. Die Art und Weise, wie PP-InsPs ihre Funktion ausführen, noch weitgehend unbekannt. Deshalb wurden zwei neue analytische Methoden basierend auf Kernspinresonanzspektroskopie und Flüssigchromatographie mit Massenspektrometrie-Kopplung (LCMS) entwickelt. Um die limitierende Sensitivität der Kernresonanzspektroskopie zu umgehen, wurde die Synthese von kernspinresonanzaktivem, 13C-markiertem Inositol optimiert. Des Weiteren wurde eine chemoenzymatische Synthese für alle Säugetier-PP-InsP-Isomere entwickelt, die auf der skalierbaren Ausfällung mittels Mg2+ Ionen basiert. Menschliche Zellen wurden mit 13C-Inositol isotopenmarkiert und in den Spektren der Zellextrakte wurde, basierend auf den PP-InsP-Standards, Fingerabdrucksignale identifiziert mit denen die Konzentrationen der dazugehörigen Moleküle bestimmt werden konnte. Die LCMS basierte Methode wurde auf dem Prinzip der Umsetzung von hochgeladenen Inositolpyrophosphaten zu ihren korrespondieren Methylestern mittels Trimethylsilyldiazomethan geplant. Die ungeladenen, permethylierten PP-InsPs wären geeignet für LC-Auftrennungen und MS-Messungen und sollten eine von Kernspinresonanzspektroskopie nicht erreichbare Sensitivität ermöglichen. Die Methode wurde mittels Inositolhexakisphosphat (InsP6), einem einfacheren PP-InsP-Analog, etabliert und methyliertes InsP6 konnte in Mengen von 10 femtomol detektiert werden. Die Adaption der Methode für die PP-InsPs gestaltete sich jedoch herausfordernd, da der Analyt während der Reaktion zersetzt wurde. Ein Wechsel zu Diazomethan als Methylierungsagens zeigte vielversprechende Resultate. / Inositol pyrophosphates (PP-InsPs) are a well conserved group of second messengers that are involved in a plethora of cellular processes including phosphate homeostasis, insulin signaling, and apoptosis. Despite much effort, it is still mostly unknown how PP-InsPs exert their diverse functions. In order to decipher the mechanisms, researchers have relied either on metabolic labeling with radioactive inositol or on electrophoretic separation on polyacrylamide gels but these methods either lack ease of use or sensitivity. Therefore, two new analytical tools, based on nuclear magnetic resonance (NMR) spectroscopy, and liquid chromatography coupled mass spectrometry (LCMS), were developed. To overcome the limited sensitivity provided by NMR spectroscopy, a high yielding synthesis of NMR-active 13C-labeled inositol was designed and optimized. Furthermore, a chemoenzymatic synthesis of all mammalian PP-InsPs isomers was developed that relied on a scalable purification strategy utilizing precipitation with Mg2+ ions. Human cells were metabolically labeled with 13C-inositol and the prepared PP-InsPs were used as standards to identify peaks in the NMRspectra. These fingerprint signals enabled the quantification of the corresponding molecules. The LCMS-based method was based on the derivatization of the highly charged inositol pyrophosphates to their corresponding methyl esters by trimethylsilyldiazomethane. The permethylated InsPs and PP-InsPs were suitable for LC separation and MS measurement, and provide a sensitivity unmatched by NMR spectroscopy. The method was established using inositol hexakisphosphate, a simpler analog of PP-InsPs, and methylated InsP6 could be detected at quantities as low as 10 femtomole. However, the adaptation of the derivatization for PP-InsPs proved challenging as the reaction caused degradation of the analyte but strategies to circumvent the decay by changing the derivatization agent to diazomethane were promising. Inositolpyrophosphat Inositolpolyphosphat NMR Spektroskopie Massenspektrometrie Metabolomics inositol polyphosphate inositol pyrophosphate NMR spectroscopy Mass spectrometry metabolomics 547 Organische Chemie VK 8807 VG 9807 VG 9507 WD 5000 ddc:547
262	Solid-State NMR Spectroscopic Studies on Phospholamban and Saposin C Proteins in Phospholipid Membranes Abu-Baker, Shadi 31 July 2007 (has links) No description available. Phospholamban Saposin C Solid-state NMR spectroscopy Solid-phase peptide synthesis Protein-membrane interaction multilamellar vesicles Protein side-chain and backbone dynamics Structural topology.
263	Biophysical characterization of heterocyst differentiation regulators, HetR and PatS, from the cyanobacterium, Anabaena sp. strain PCC 7120 and structural biology of bacterial proteins from the Northeast Structural Genomics Consortium Feldmann, Erik A. 25 July 2012 (has links) No description available. Biochemistry Biophysics Chemistry Developmental Biology Anabaena PCC 7120 Nostoc HetR PatS heterocyst differentiation structural genomics NESG EPR spectroscopy ITC calorimetry multidimensional NMR spectroscopy protein NMR
264	Peptide Bond Geometry Studied by Solid-State NMR Spectroscopy Gupta, Chitrak January 2013 (has links) No description available. Chemistry peptide bond geometry cis-peptide bond omega torsional angle solid-state NMR spectroscopy dipolar coupling microwave-assisted synthesis solid phase peptide synthesis
265	Studies of conformational changes and dynamics accompanying substrate recognition, allostery and catalysis in bacteriophage lambda integrase Subramaniam, Srisunder 19 April 2005 (has links) No description available. bacteriophage lambda integrase site specific recombination DNA cleaving enzymes enzyme dynamics enzyme catalysis molecular recognition substrate recognition NMR spectroscopy allostery protein folding binding-coupled protein folding
266	Mapping Allosteric Sites and Pathways in Systems Unamenable to Traditional Structure Determination / Mapping Allostery in Unconventional Systems Boulton, Stephen January 2018 (has links) Allostery is a regulatory process whereby a perturbation by an effector at one discrete locus creates a conformational change that stimulates a functional change at another. The two sites communicate through networks of interacting residues that respond in a concerted manner to the allosteric perturbation. These allosteric networks are traditionally mapped with high resolution structure determination techniques to understand the conformational changes that regulate protein function as well as its modulation by allosteric ligands and its dysfunction caused by disease-related mutations (DRMs). However, high resolution structural determination techniques, such as X-ray crystallography, cryo-electron microscopy and nuclear Overhauser effect NMR spectroscopy are not always amenable for systems plagued by poor solubility and line broadening caused by μs-ms dynamics or systems where allostery relies primarily on dynamical rather than structural changes. This dissertation discusses methodologies to map the allosteric sites and pathways for such challenging systems. The foundation of this approach is to model allosteric pathways in the context of their respective thermodynamic cycles. In chapter 2, the thermodynamic cycle of a DRM in the hyperpolarization-activated cyclic nucleotide-gated ion channel 4 (HCN4) is analyzed with respect to structure, dynamics and kinetics, revealing how the DRM remodels the free energy landscape of HCN4 and results in a loss-of-function disease phenotype. In chapter 3, the mechanism of action of an uncompetitive inhibitor for the exchange protein activated by cAMP is elucidated by characterizing its selectivity for distinct conformations within the thermodynamic cycle that are trapped using a combination of mutations and ligand analogs. In chapter 4, we discuss two new protocols for the chemical shift covariance analysis (CHESCA). The CHESCA is an approach that identifies allosteric signaling pathways by measuring concerted residue responses to a library of chemical perturbations that stabilize conformational equilibria at different positions. Overall, the approaches discussed in this dissertation are widely applicable for mapping the mechanisms of allosteric perturbations that arise from ligand binding, post-translational modifications and mutations, even in systems where traditional structure determination techniques remain challenging to implement. / Thesis / Doctor of Philosophy (PhD) / Allostery is a regulatory mechanism for proteins, which controls functional properties of one distinct site through the perturbation of another distinct, and often distant, site. The two sites are connected via a series of residues that undergo conformational changes once perturbed by the allosteric effector. Mapping these communication pathways reveals mechanisms of protein regulation, which are invaluable for developing pharmacological modulators to target these pathways or for understanding the mechanisms of disease mutations that disrupt these pathways. Allosteric pathways have been traditionally determined using structure determination approaches that provide a static snapshot of the protein’s structure. However, these approaches are typically not effective when allostery relies extensive changes in dynamics. The goal of this thesis was to develop methods to characterize systems that are dynamic or otherwise unsuitable for traditional structure determination. Herein, we utilize NMR spectroscopy to analyze the allosteric mechanisms of three cAMP-binding proteins involved in cardiovascular health. Allostery Protein Regulation Protein-Ligand Interactions Cell Signaling Cyclic Nucleotides NMR Spectroscopy Protein Dynamics Drug Development Disease Mutations Biochemistry Ion Channels Enzyme Inhibition
267	Lithium-ion Behaviour in Hard Carbon Anodes: Insights from 7Li NMR Spectroscopy / Litiumjoners beteende i anoder av hårt kol: Insikter från 7Li NMR-spektroskopi Landström, Adina January 2023 (has links) Litiumjonbatterier (LIB) är viktiga komponenter i dagens teknologi och används för att driva en mängd olika elektroniska system, allt från datorer och mobiltelefoner till bilar och flygplan. Eftersom efterfrågan på effektiv energilagring fortsätter att växa finns ett fortsatt behov för forskning och utveckling inom området. Denna rapport undersöker hårt kol, ett lovande material för anoder i litiumjonbatterier och andra alkali-jon batterier. I likhet med grafit är hårt kol ett kolbaserat material som inte är en väldefinierad allotropp utan en komplex blandning med avseende på både hybridiseringstillstånd och långdistansordning. Därför är den mycket dåligt definierat. Ändå är hårt kol ett önskvärt material eftersom det kan produceras från förnybara resurser samt på grund av dess kompatibilitet med natrium, vilket möjliggör natriumjonbatterier. I den här studien har elektroder av hårt kol syntetiserats och litierats i olika grader och sedan studerats med 7Li NMR-spektroskopi där både spektra och longitudinella relaxationshastigheter mättes. Vid lägre litieringsnivåer observerades tydliga smala 7Li toppar inom intervallet 4-16 ppm, vilket indikerar förekomsten av joniskt litium. Vid högre litieringsnivåer framträdde en bred topp vid 61 ppm. Utseendet av denna topp, tillsammans med en hög Knight-skift, indikerar närvaron av kvasi-metalliskt litium. Det är värt att notera att detta kvasi-metalliska litium finns i de oordnade och porösa områdena hos hård kol. 7Li longitudinella relaxationshastigheter, som rapporterar om jonisk dynamik, registrerades vid olika temperaturer och från det observerade temperaturberoendet beräknades den genomsnittliga aktiveringsenergin för de involverade joniska rörelserna. Intressant nog visade sig denna aktiveringsenergi vara lägre jämfört med den i PAN-baserade kolfibrer och grafit, som båda uppvisar en högre grad av ordning. Denna observation tyder på ett samband mellan lokal oordning och snabbare jondynamik. / Lithium-ion batteries (LIB) are vital components of modern technology, powering a wide range of devices from computers and cell phones to cars and aeroplanes. As the demand for efficient energy storage continues to grow, research and development in the field of lithium-ion batteries remain active. This report focuses on the investigation of hard carbon, a promising anode material for lithium-ion batteries and other alkali-ion batteries. Akin to graphite, hard carbon is a carbon-based material that is not a well-defined allotrope but a complex mixture with regard to both hybridization state and long-range order. Hence it is very poorly defined. Yet, hard carbon is a desirable material as it can be produced from renewable resources and because of its compatibility with sodium, allowing for sodium-ion batteries. In this study, hard carbon electrodes were synthesised and lithiated to various degrees and then studied with 7Li NMR spectroscopy where both spectra and longitudinal relaxation rates were measured. At lower lithiation levels, distinct narrow 7Li peaks were observed within the 4-16 ppm range, indicating the presence of ionic lithium. At higher lithiation levels a broad peak at 61 ppm emerged. The appearance of this peak, along with a high Knight shift, signifies the presence of quasi-metallic lithium, presumably in the more disordered and more porous regions of hard carbon. The 7Li longitudinal relaxation rates, reporting on ionic dynamics, were recorded at different temperature and from the observed temperature dependence the average activation energy for the involved ionic motions was calculated. Interestingly, this activation energy was found to be lower compared to that for PAN-based carbon fibres and graphite, both of which exhibit a higher degree of order. This observation suggests a correlation between local disorder and faster ion dynamics. NMR spectroscopy hard carbon anode lithium-ion battery spin relaxation NMR-spektroskopi hårt kol anod litiumjonbatteri spinnrelaxation Physical Chemistry Fysikalisk kemi
268	Intriguing High Z'' Cocrystals of Emtricitabine Palanisamy, V., Sanphui, P., Bolla, G., Narayan, Aditya, Seaton, Colin C., Vangala, Venu R. 12 August 2020 (has links) Yes / Emtricitabine (ECB) afforded dimorphic cocrystals (Forms I, II) of benzoic acid (BA), whereas with p-hydroxybenzoic acid (PHBA), p-aminobenzoic acid (PABA) are resulted in as high Z'' cocrystals. Intriguingly, the Z'' of cocrystals are trends from two to fourteen based on the manipulation of functional groups on the para position of BA (where H atom is replaced with that of OH or NH2 group). ECB‒PABA cocrystal consists of six molecules each and two water molecules in the asymmetric unit (Z''=14) with 2D planar sheets represents the rare pharmaceutical cocrystal. The findings suggest that the increment of H bond donor(s) systematically via a suitable coformer are in correspondence with attaining high Z'' cocrystals. Further, solid state NMR spectroscopy in conjunction with single crystal X-ray diffraction are demonstrated as significant tools to enhance the understanding of the number of symmetry independent molecules in the crystalline lattice and provide insights to the mechanistic pathways of crystallization. / Department of Science and Technology (DST) Fund for improvement of S & T Infrastructure (FIST) with grant no. SR/FST/CST-266/2015(c) to PS and VP. AN and VV acknowledge the Government of India under National Overseas Scholarship (2012-13) and High Commission of India, London UK for PhD studentship. Cocrystals High Z' crystals High Z" crystals Anti-retroviral drug Emtricitabine Single crystal X-ray diffraction Solid state NMR spectroscopy
269	NMR Methods For The Study Of Partially Ordered Systems Lobo, Nitin Prakash 07 1900 (has links) (PDF) The work presented in this thesis has two parts. The first part deals with methodological developments in the area of solid-state NMR, relevant to the study of partially ordered systems. Liquid crystals are best examples of such partially ordered systems and they are easily oriented by the magnetic field used for the NMR study. They provide spectra rich in information useful for the study of structure and dynamic s of the oriented molecule. Dipolar couplings and anisotropic chemical shifts are relatively easy to obtain for these systems. However, the methodologies used for extracting the required information are constantly undergoing change, with newer ideas being used for optimal use of the technique and increasing the sensitivity of the methodology. In this thesis, existing methods used for obtaining dipolar couplings from oriented liquid crystalline samples are examined in detail and conditions for optimal use of the methods are investigated. Different approaches for enhancing the sensitivity of the techniques are also proposed. Estimation of chemical shift anisotropy of carbons for a molecule that is used as a building block for several mesogens has been obtained and its utility for estimating the order parameters of the system have been examined. The second part of the thesis deals with the application of solid state NMR methods to the study of a number of novel liquid crystalline systems and for the estimation of dynamics, order and orientation of the mesogenic molecules in the magnetic field. Chapter-2 deals with a detailed and systematic study to improve the sensitivity of cross-polarization based separated local field (SLF) NMR spectroscopy techniques such as PISEMA(Polarization Inversion Spin Exchange at the Magic Angle) and PDLF(Pro-ton Detected Local Field). The chapter has been further divided into three sections. Section-A describes the optimization procedure for cross-polarization period for reducing zero-frequency peaks in SLF experiments. Polarization Inversion(PI) is one of the important components of PISEMA and plays a crucial role in enhancing the dipolar cross-peaks and suppressing the axial-peaks. Shortening this period has the advantage of less r.f. power input into the system, thus less susceptibility to sample heating. Therefore it is crucial to arrive at the optimum condition for which maximum sensitivity and resolution are obtained. A detailed experimental investigation of the role of the initial po1arization period has been carried out for two different samples of static oriented liquid crystalline material at two different temperatures and a contact time of 2ms has been found to be optimal for such samples. Insection-B of this chapter, the initial preparation period of the experiment is considered as a possible means of increasing the sensitivity of the experiment. Thus the use of cross-polarization via the dipolar bath by the use of a diabatic demagnetization in the rotating frame(ADRF-CP) has been proposed to be incorporated into PISEMA. To understand the CP dynamics, magnetization in double-and zero-quantum reservoirs of an ensemble of spin-1/2 nuclei and their role in determining the sensitivity the experiments have been theoretically examined. Experimentally, a modification incorporating ADRF-CP is shown to result in enhancement of signal-to-noise by as much as 90% in the case of rigid single crystals of a model peptide and up to 50% in non-rigid, partially ordered liquid crystalline systems. In section-C another useful SLF technique known as PDLF spectroscopy has also been examined. In this case a sweep of one of the r.f. amplitudes(RAMP-CP),rather than ADRF is found to work well. The reason for the different behaviours has been discussed. Chapter-3 highlights two experimental approaches used to extract the chemical shift anisotropy(CSA) tensor information from rotating solids. Section-A is devoted to the measurement of the CSA values of thiophene by using MAS side band analysis, by extracting the principal values from the intensities of just a few spinning side bands. Experiments have been performed on thiophene-2 carboxylic acid and thiophene-3 carboxylic acid samples and the carbon CSA values have been obtained. In section-B, CSA values of carbons of the core unit of the liquid crystal4- hexyloxybenzoic acid (HBA) have been obtained by using the recoupling pulse sequence SUPER(Separation of Undistorted Powder patterns by Effortless Recoupling).HBA belongs to an important class of thermotropic liquid crystals which are structurally simple and often used as starting materials for many novel mesogens. As this molecule could serve as an ideal model compound, high resolution13C NMR studies of HBA in solution, solid and liquid crystalline phases have been also undertaken. The CSA values obtained from the 2D SUPER experiment showed good agreement to those computed by DFT calculations. The CSA values were used for obtaining the order parameter of the system at different temperatures. These matched well the order parameter obtained from the 13C-1 H dipolar couplings in the nematic phase determined by SLF spectroscopy at various temperatures. A knowledge of the CSA of the carbons is thus very useful, as they can be used for gaining knowledge about the system from the chemical shifts obtained from a simple 1D spectrum. In chapter-4, 1-and 2-dimensional13CNMR techniques have been utilized to obtain extensive information about some novel mesogenic molecules. Four molecules of different structure and topology have been taken up for study. These molecules have the following features. Mesogen-1 has a terminal hydroxyl group. Such systems with further modification can result in mesogenic monomers for side chain liquid crystalline polymers. Mesogen-2 has a dimethyl amino group at one end and has three phenyl groups connected by appropriate linking units that form the core. In the third case, mesogen-3, the terminal hydroxyl group of mesogen-1 is replaced with a hydrogen such that13C-1 H dipolar couplings provide directly information on molecular ordering and orientation. In the fourth case, mesogen-4, the core is built with four phenyl rings. Here the fourth ring is linked to other three rings via a flexible chain unit. In each of these cases the 2DSLFNMR experiments have been carried out where13C-1 H dipolar couplings as well as13C chemical shifts were used for obtaining the order parameters of various segments of the molecule. The data provide useful insight into the phase behaviour, ordering and orientation of the molecules. Chapter-5 discusses the applications of the natural abundance 13CNMR techniques to thiophene based mesogens, that have the potential for use in molecular electronics material. Typically, these molecules consist of phenyl rings appropriately connected by linking units with thiophene. Different core units as well as different linking units to thiophene have been considered. The six mesogens thus obtained have been investigated in detail using 1D and 2D NMR methods.13C-1 H dipolar couplings have been used to obtain ordering information, that show interesting correlation to the molecular orientation and dynamics. Hamiltonian Systems Partially Ordered Systems Nuclear Magnetic Resonance Solid State Nuclear Magnetic Resonance Mesogens - Nuclear Magnetic Resonance Nuclear Spin Hamiltonian Dipolar Coupling Chemical Shift Anisotropy Nuclear Magnetic Resonance Spectroscopy 13C NMR Spectroscopy Thiophene 13CNMR Magnetism
270	Deciphering Structure-Function Relationships in a Two-Subunit-Type GMP Synthetase by Solution NMR Spectroscopy Ali, Rustam January 2013 (has links) (PDF) The guanosine monophosphate synthetase (GMPS) is a class I glutamine amidotransferase, involved in the de-novo purine nucleotide biosynthesis. The enzyme catalyzes the biochemical transformation of xantosine (XMP) into guanosine monophosphate (GMP) in presence of ATP, Mg2+ and glutamine. All GMPSs consist of two catalytic sites 1) for GATase activity 2) for the ATPPase activity. The two catalytic sites may be housed in the same polypeptide (two-domain-type) or in separate polypeptides (two-subunit-type). Most of the studies have been performed on two-domain-type GMPSs, while only one study has been reported from two-subunit-type GMPS (Maruoka et al. 2009). The two-subunit-type GMPS presents an example where the component reactions of a single enzymatic reaction are carried out by two distinct subunits. In order to get better understanding of structural aspects and mechanistic principle that governs the GMPS activity in two-subunit-type GMPSs, we initiated the study by taking GMPS of Methanocaldococcus jannaschii as a model system. The GMPS of M. jannaschii (Mj) is a two-subunit-type protein. The GATase subunit catalyzes the hydrolysis of glutamine to produce glutamate and ammonia. The ATPPase subunit catalyses the amination of XMP to produce GMP using the ammonia generated in GATase subunit. Since the two component reactions are catalysed by two separate subunits and are coupled in the way that product of one reaction (ammonia) acts as a nucleophile in the second reaction. The cross-talk between these two subunits in order to maximise the efficiency of overall GMPS warrants investigation. The GATase activity is tightly regulated by the interaction with ATPPase domain/subunit, in all GMPS except in the case of P. falciparum. This interaction is facilitated by substrate binding to the ATPPase domain/subunit. Though, the conditions for the interaction between two subunits is known in a two-subunit-type GMP synthetase from P. horikoshii, the structural basis of substrate dependent interaction is not known. As a first step to understand the structural basis of interaction between the Mj GATase and Mj ATPPase subunits, we have determined the structure of Mj GATase (21 kDa) subunit using high resolution, multinuclear, multidimensional NMR spectroscopy. Sequence specific resonance assignments were obtained through analysis of various 2D and 3D hetero-nuclear multidimensional NMR experiments. NMR based distance restraints were obtained from assignment of correlations observed in NOE based experiments. Data were acquired on isotopically enriched samples of Mj GATase. The structure of Mj GATase (2lxn) was solved by using cyana-3.0 using NMR based restraints as input for the structure calculation. The ensemble of 20 lowest-energy structures showed root-mean-square deviations of 0.35±0.06 Å for backbone atoms and 0.8±0.06 Å for all heavy atoms. Attempts were also made to obtain assignments for the 69.6 kDa dimeric ATPPase subunit. Partial assignments have been obtained for this subunit. The GATase subunit is catalytically inactive. So far, there has been only one published report on a two-subunit-type GMPS from P. horikashii. The study has shown that the catalytic activity of GATase is regulated by the GATase-ATPPase interaction which is facilitated by the substrate binding to the ATPPase subunit. For the first time, we have provided the structural basis of interaction between GATase-ATPPase (112 kDa) in a two-subunit-type GMPS. Observed line width changes were used to identify residues in GATase residues that are involved in the Mj GATase-ATPPase interaction. Our data provides a possible explanation for conformational changes observed in the Mj GATase subunit upon GATase-ATPPase interaction that lead to GATase activation. Ammonia is generated in GATase subunit and is very reactive and labile. Thus, the faithful transportation of ammonia from GATase to ATPPase subunit is very crucial for optimal GMPS activity. Till date, a PDB query for GMPS retrieves only one structure which belongs to two-subunit-type GMPS, where authors have determined the structures of GATase and ATPPase subunits separately. However, the structure of holo-GMPS is not determined yet. Using interface information from experimental data and HADDOCK, we have constructed a model for the holo-GMPS from M. jannaschii. A possible ammonia channel has been deduced using the programs MOLE 2.0 and CAVER 2.0. This ammonia channel has a length of 46 Å, which is well within the range of the lengths calculated for similar channels in other glutamine amidotransferase. It had been suggested earlier that in addition to the magnesium required for charge stabilization of ATP, additional binding sites were present on GMPS. The effect of excess Mg2+ requirement on the GMPS activity has been studied in two-domain-type GMPS. However, the interaction between GATase and Mg2+ has been not investigated in any GMPS. This prompted us to investigate the effect of MgCl2 on Mj GATase subunit. For the first time, using chemical shift perturbation, we have established interaction between Mj GATase and Mg2+. The dissociation constant (Kd) of the Mj GATase-Mg2+ interaction was determined. The Kd value was found to be 1 mM, which indicates a very weak interaction. The substrate of the GATase subunit is glutamine. The condition of the hydrolysis of the glutamine is known in GMPS. However, the binding of the glutamine and associated conformational changes in GATase have been not studied in GMPS. Furthermore, till date there is no structure available for the glutamine bound GMPS/GATase. Using isotope edited one dimensional and two-dimensional NMR spectroscopy; we have shown that the Mj GATase catalytic residues are not in a compatible conformation to bind with glutamine. Thus, a conformational change in Mj GATase subunit is a pre-requisite condition for the binding of glutamine. These conformational changes are brought by the Mj GATase-ATPPase interaction. Glutamine Aminotrasferases (GATs) Guanosine Monophosphate Synthetase GMP Synthetase - Structural Properties GMP Synthetase - Functional Properties Protein-Ligand Interactions Solution NMR Spectroscopy GMP Synthetase (GMPS) Mj GATase Subunit Mj GMP Synthetase Glutamine Amido Transferase Methanocaldococcus jannaschii Biochemistry

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