The two-dimensional nuclear magnetic resonance spectroscopy analysis of peptides in solution

Smith, K. I.

January 1986

No description available.

572

Peptide in solution NMR study

Occurrence and Function of Hoogsteen Base Pairs in Nucleic Acids

Zhou, Huiqing

January 2016

<p>Nucleic acids (DNA and RNA) play essential roles in the central dogma of biology for the storage and transfer of genetic information. The unique chemical and conformational structures of nucleic acids – the double helix composed of complementary Watson-Crick base pairs, provide the structural basis to carry out their biological functions. DNA double helix can dynamically accommodate Watson-Crick and Hoogsteen base-pairing, in which the purine base is flipped by ~180° degrees to adopt syn rather than anti conformation as in Watson-Crick base pairs. There is growing evidence that Hoogsteen base pairs play important roles in DNA replication, recognition, damage or mispair accommodation and repair. Here, we constructed a database for existing Hoogsteen base pairs in DNA duplexes by a structure-based survey from the Protein Data Bank, and structural analyses based on the resulted Hoogsteen structures revealed that Hoogsteen base pairs occur in a wide variety of biological contexts and can induce DNA kinking towards the major groove. As there were documented difficulties in modeling Hoogsteen or Watson-Crick by crystallography, we collaborated with the Richardsons’ lab and identified potential Hoogsteen base pairs that were mis-modeled as Watson-Crick base pairs which suggested that Hoogsteen can be more prevalent than it was thought to be. We developed solution NMR method combined with the site-specific isotope labeling to characterize the formation of, or conformational exchange with Hoogsteen base pairs in large DNA-protein complexes under solution conditions, in the absence of the crystal packing force. We showed that there are enhanced chemical exchange, potentially between Watson-Crick and Hoogsteen, at a sharp kink site in the complex formed by DNA and the Integration Host Factor protein. In stark contrast to B-form DNA, we found that Hoogsteen base pairs are strongly disfavored in A-form RNA duplex. Chemical modifications N1-methyl adenosine and N1-methyl guanosine that block Watson-Crick base-pairing, can be absorbed as Hoogsteen base pairs in DNA, but rather potently destabilized A-form RNA and caused helix melting. The intrinsic instability of Hoogsteen base pairs in A-form RNA endows the N1-methylation as a functioning post-transcriptional modification that was known to facilitate RNA folding, translation and potentially play roles in the epitranscriptome. On the other hand, the dynamic property of DNA that can accommodate Hoogsteen base pairs could be critical to maintaining the genome stability.</p> / Dissertation

Biochemistry

DNA

Hoogsteen

RNA

solution NMR

structure

Understanding the Role of Human TRPV1 S1-S4 Membrane Domain in Temperature and Ligand Activation

January 2019

abstract: Transient receptor potential vanilloid member 1 (TRPV1) is a membrane protein ion channel that functions as a heat and capsaicin receptor. In addition to activation by hot temperature and vanilloid compounds such as capsaicin, TRPV1 is modulated by various stimuli including acidic pH, endogenous lipids, diverse biological and synthetic chemical ligands, and modulatory proteins. Due to its sensitivity to noxious stimuli such as high temperature and pungent chemicals, there has been significant evidence that TRPV1 participates in a variety of human physiological and pathophysiological pathways, raising the potential of TRPV1 as an attractive therapeutic target. However, the polymodal nature of TRPV1 function has complicated clinical application because the TRPV1 activation mechanisms from different modes have generally been enigmatic. Consequently, tremendous efforts have put into dissecting the mechanisms of different activation modes, but numerous questions remain to be answered. The studies conducted in this dissertation probed the role of the S1-S4 membrane domain in temperature and ligand activation of human TRPV1. Temperature-dependent solution nuclear magnetic resonance (NMR) spectroscopy for thermodynamic and mechanistic studies of the S1-S4 domain. From these results, a potential temperature sensing mechanism of TRPV1, initiated from the S1-S4 domain, was proposed. Additionally, direct binding of various ligands to the S1-S4 domain were used to ascertain the interaction site and the affinities (Kd) of various ligands to this domain. These results are the first to study the isolated S1-S4 domain of human TRPV1 and many results indicate that the S1-S4 domain is crucial for both temperature-sensing and is the general receptor binding site central to chemical activation. / Dissertation/Thesis / Doctoral Dissertation Biochemistry 2019

Biochemistry

Biophysics

Capsaicin

Membrane Protein

Solution NMR

Thermosensing

TRPV1

INVESTIGATION OF PROTEIN STRUCTURE AND DYNAMICS BY NMR SPECTROSCOPY

Unnikrishnan, Aparna

13 November 2020

No description available.

Biochemistry

Biophysics

RAP1-TRIGGERED PATHWAYS FOR TALIN-MEDIATED INTEGRIN ACTIVATION

Zhu, Liang

01 February 2018

No description available.

Biochemistry

Cellular Biology

Molecular Biology

Biophysics

Conformation of Y145Stop Prion Protein in Solution and Amyloid Fibrils Probed by Nuclear Magnetic Resonance Spectroscopy

Xia, Yongjie

12 October 2017

No description available.

Chemistry

Physical Chemistry

Biochemistry

Biophysics

Understanding the Role of N-Methylolacrylamide (Nma) Distribution in Poly(Vinyl Acetate) Latex Adhesives

Brown, Nicole Robitaille

15 April 2004

This work addresses the distribution of N-methylolacrylamide (NMA) units in crosslinking poly(vinyl acetate) (PVAc) adhesives. In this case, distribution refers to the three potential locations of polymerized NMA units in a latex: the water-phase, the surface of polymer particles, and the core of the polymer particles. The objective is to identify the distribution of NMA in three latices and to determine whether NMA distribution correlates with durability related performance. NMA distribution was studied via a series of variable temperature solution NMR experiments, while the durability-related performance was studied via mode I fracture mechanics tests. Studying the distribution of NMA required the use of isotopically labeled NMA. Both 15N-NMA and 13C, 15N-NMA were synthesized. Three NMA/vinyl acetate (VAc) latices were prepared. The NMA feed strategy was varied during each of the three emulsion copolymerizations. Latex characterization methods including differential scanning calorimetry (DSC), rheometry, particle size analysis, and scanning electron microscopy (SEM) were used to study the three latices. The solution NMR method to identify NMA distribution was performed on untreated latices and on washed latices. Washing techniques included membrane dialysis and centrifugation. Results revealed that the three latices had different NMA distributions, and that the distributions were related to the expected differences in microstructure. Latex 3 had ~ 80% core-NMA, while Latex 2 had ~ 80% surface-NMA. Latex 1 had a high proportion of surface-NMA (~60%), but also had the highest proportion of water-phase NMA (~ 20%). This high proportion of water-phase NMA could be responsible for the unique morphology Latex 1 exhibited in SEM studies. Mode I opening fracture mechanics studies were used to study adhesive performance. Specimens were analyzed after exposure to accelerated aging treatments. Latex 2 and Latex 3 exhibited very similar results, despite having very different NMA distributions. All three latices showed good durability related performance. In Latex 2 and Latex 3, the critical strain energy release rates (Gc) after accelerated aging treatments were statistically the same as the Gc of the control specimens. The most interesting finding was that the Latex 1 Gc values were significantly higher after accelerated aging. Latex 1 also had the highest proportion of water-phase NMA. Bondline images and SEM micrographs both indicated that the integrity of Latex 1 was least affected by the accelerated aging treatments. / Ph. D.

N-methylolacrylamide

NMA

13C 15N-NMA

15N-NMA

poly(vinyl acetate)

PVAc

emulsion polymerization

monomer distribution

durability

solution NMR

fracture mechanics

wood adhesives

13C-NMA

Estudo da dinâmica funcional dos domínios regulatórios do trocador de Na+/Ca2+ de Drosophila melanogaster por ressonância magnética nuclear em solução / Functional dynamics of the regulatory domains from the Drosophila melanogaster\'s Na+/Ca2+ exchanger by nuclear magnetic resonance in solution.

Abiko, Layara Akemi

20 March 2015

O trocador de Na+/Ca2+ (NCX) constitui um dos principais mecanismos de extrusão de Ca2+ intracelular em células excitáveis. Foi demonstrado que alterações no funcionamento do NCX estão relacionadas a diversas situações patológicas. Por este motivo, o entendimento do mecanismo molecular da manutenção da concentração de Ca2+ intracelular via NCX é importante para a compreensão do funcionamento do trocador, bem como para o desenvolvimento de fármacos. Além de transportar Na+/Ca2+, o NCX também é regulado por esses íons. Este trocador é composto por dois domínios transmembranares, cada um deles contendo 5 &#945;-hélices (TM), e uma grande alça intracelular que conecta as hélices TM5 e TM6. O domínio transmembranar é responsável por catalisar o transporte de Na+/Ca2+ através da bicamada lipídica, enquanto que a alça citoplasmática está envolvida com a regulação do trocador. Esta alça contém dois domínios sensores de Ca2+ adjacentes, denominados CBD1 e CBD2. Apesar da importância fisiológica do NCX, o mecanismo de regulação alostérica do trocador por Ca2+ intracelular permanece desconhecido. Neste trabalho, a espectroscopia de ressonância magnética nuclear (RMN) de alta resolução foi utilizada para investigar a conformação e a dinâmica de CBD1 e CBD2 do trocador de Na+/Ca2+ de Drosophila melanogaster (CALX), isolados ou conectados covalentemente em uma construção denominada CBD12. Um total de 98% das ressonâncias da cadeia principal de CBD1 isolado na presença de Ca2+ foi assinalado, enquanto que na ausência de Ca2+, assinalamentos para apenas uma parte da cadeia principal puderam ser obtidos. Os assinalamentos adquiridos para CBD12 foram baseados na análise de um conjunto de espectros de RMN tridimensional heteronuclear e por comparação com os espectros dos domínios isolados. Uma análise preliminar dos deslocamentos químicos e dos parâmetros de relaxação de 15N obtidos para CBD1 indicou que este domínio é flexível na ausência de Ca2+, mas torna-se rígido após a adição deste íon. As medidas das velocidades de relaxação de 15N e de acoplamentos dipolares residuais (RDCs) de 1H-15N realizadas para CBD12 nas formas apo e holo indicaram que a ligação de Ca2+ em CBD1 estabiliza uma orientação rígida entre os domínios. A análise dos RDCs de 1H-15N mostrou ainda que a orientação média entre CBD1 e CBD2 é praticamente linear na ausência de Ca2+, enquanto que um ângulo menor é assumido após a adição deste íon. Os dados descritos nesta tese suportam um modelo de regulação alostérica em que a modulação da plasticidade de CBD12 pela ligação de Ca2+ no domínio CBD1 controla a abertura e o fechamento do trocador. / The Na+/Ca2+ exchanger (NCX) is a major mechanism for the extrusion of intracellular Ca2+ in excitable cells. It was demonstrated that altered functioning of this protein is related to various pathological situations. Therefore, the understanding of the molecular mechanism for maintaining the intracellular Ca2+ concentration by means of the NCX is important to understand the functioning of the exchanger and to develop drug-based therapies. Besides transporting Na+/Ca2+, the exchanger is also regulated by these ions. The NCX is composed of two transmembrane domains, each of them containing 5 transmembrane alpha-helices (TM), and a very large cytosolic loop that connects TM5 to TM6. The transmembrane domains are responsible for catalyzing the transport of Na+ and Ca2+ ions across the lipid bilayer, while the cytosolic loop is involved in regulation of the exchanger activity. It contains two regulatory Ca2+- binding domains, called CBD1 and CBD2, that appear in tandem. Despite the physiological importance of the NCX, the mechanism of allosteric regulation of the exchanger by intracellular calcium remains unclear. In this work we used high-resolution NMR spectroscopy to study the conformation and the dynamics of the two Ca2+-binding regulatory domains of Drosophila\'s Na+/Ca2+ exchanger (CALX), CBD1 and CBD2, in isolation as well as in a covalent construct called CBD12. Complete backbone NMR resonance assignments were obtained for the isolated CBD1 domain in the Ca2+-bound state, while partial assignments were obtained for CBD1 in the free state. Partial backbone NMR resonance assignments were obtained for the CBD12 construct through the analysis of a standard set of triple resonance NMR spectra. Additional assignments were obtained by comparison with the isolated CBD1 and CBD2 domains. A preliminary analysis of NMR chemical shifts and 15N relaxation data obtained for CBD1 indicates that this domain displays considerable amount of flexibility in the free state, but becomes more rigid upon Ca2+-binding. NMR 15N relaxation rates and 1H-15N residual dipolar couplings (RDCs) obtained for the Apo and Ca2+-bound states of the CBD12 domain indicate that calcium binding stabilizes a rigid inter-domain orientation. Analysis of 1H-15N RDCs further shows that Drosophila\'s CBD12 domain assumes an almost linear inter-domain orientation in the absence of Ca2+, while a smaller inter-domain angle was found in its presence. These findings support a model in which modulation of CBD12 plasticity by the binding of Ca2+ to the CBD1 domain controls the opening and closing of the exchanger.

15N relaxation

Acoplamentos dipolares residuais

Dinâmica de proteínas

Espectroscopy nuclear magnetic resonance

Na+/Ca2+ exchanger

Protein dynamics

Relaxação de 15N

Residual dipolar couplings

RMN em solução

Solution NMR

Trocador de Na+/Ca2+

Estudo da dinâmica funcional dos domínios regulatórios do trocador de Na+/Ca2+ de Drosophila melanogaster por ressonância magnética nuclear em solução / Functional dynamics of the regulatory domains from the Drosophila melanogaster\'s Na+/Ca2+ exchanger by nuclear magnetic resonance in solution.

Layara Akemi Abiko

20 March 2015

O trocador de Na+/Ca2+ (NCX) constitui um dos principais mecanismos de extrusão de Ca2+ intracelular em células excitáveis. Foi demonstrado que alterações no funcionamento do NCX estão relacionadas a diversas situações patológicas. Por este motivo, o entendimento do mecanismo molecular da manutenção da concentração de Ca2+ intracelular via NCX é importante para a compreensão do funcionamento do trocador, bem como para o desenvolvimento de fármacos. Além de transportar Na+/Ca2+, o NCX também é regulado por esses íons. Este trocador é composto por dois domínios transmembranares, cada um deles contendo 5 &#945;-hélices (TM), e uma grande alça intracelular que conecta as hélices TM5 e TM6. O domínio transmembranar é responsável por catalisar o transporte de Na+/Ca2+ através da bicamada lipídica, enquanto que a alça citoplasmática está envolvida com a regulação do trocador. Esta alça contém dois domínios sensores de Ca2+ adjacentes, denominados CBD1 e CBD2. Apesar da importância fisiológica do NCX, o mecanismo de regulação alostérica do trocador por Ca2+ intracelular permanece desconhecido. Neste trabalho, a espectroscopia de ressonância magnética nuclear (RMN) de alta resolução foi utilizada para investigar a conformação e a dinâmica de CBD1 e CBD2 do trocador de Na+/Ca2+ de Drosophila melanogaster (CALX), isolados ou conectados covalentemente em uma construção denominada CBD12. Um total de 98% das ressonâncias da cadeia principal de CBD1 isolado na presença de Ca2+ foi assinalado, enquanto que na ausência de Ca2+, assinalamentos para apenas uma parte da cadeia principal puderam ser obtidos. Os assinalamentos adquiridos para CBD12 foram baseados na análise de um conjunto de espectros de RMN tridimensional heteronuclear e por comparação com os espectros dos domínios isolados. Uma análise preliminar dos deslocamentos químicos e dos parâmetros de relaxação de 15N obtidos para CBD1 indicou que este domínio é flexível na ausência de Ca2+, mas torna-se rígido após a adição deste íon. As medidas das velocidades de relaxação de 15N e de acoplamentos dipolares residuais (RDCs) de 1H-15N realizadas para CBD12 nas formas apo e holo indicaram que a ligação de Ca2+ em CBD1 estabiliza uma orientação rígida entre os domínios. A análise dos RDCs de 1H-15N mostrou ainda que a orientação média entre CBD1 e CBD2 é praticamente linear na ausência de Ca2+, enquanto que um ângulo menor é assumido após a adição deste íon. Os dados descritos nesta tese suportam um modelo de regulação alostérica em que a modulação da plasticidade de CBD12 pela ligação de Ca2+ no domínio CBD1 controla a abertura e o fechamento do trocador. / The Na+/Ca2+ exchanger (NCX) is a major mechanism for the extrusion of intracellular Ca2+ in excitable cells. It was demonstrated that altered functioning of this protein is related to various pathological situations. Therefore, the understanding of the molecular mechanism for maintaining the intracellular Ca2+ concentration by means of the NCX is important to understand the functioning of the exchanger and to develop drug-based therapies. Besides transporting Na+/Ca2+, the exchanger is also regulated by these ions. The NCX is composed of two transmembrane domains, each of them containing 5 transmembrane alpha-helices (TM), and a very large cytosolic loop that connects TM5 to TM6. The transmembrane domains are responsible for catalyzing the transport of Na+ and Ca2+ ions across the lipid bilayer, while the cytosolic loop is involved in regulation of the exchanger activity. It contains two regulatory Ca2+- binding domains, called CBD1 and CBD2, that appear in tandem. Despite the physiological importance of the NCX, the mechanism of allosteric regulation of the exchanger by intracellular calcium remains unclear. In this work we used high-resolution NMR spectroscopy to study the conformation and the dynamics of the two Ca2+-binding regulatory domains of Drosophila\'s Na+/Ca2+ exchanger (CALX), CBD1 and CBD2, in isolation as well as in a covalent construct called CBD12. Complete backbone NMR resonance assignments were obtained for the isolated CBD1 domain in the Ca2+-bound state, while partial assignments were obtained for CBD1 in the free state. Partial backbone NMR resonance assignments were obtained for the CBD12 construct through the analysis of a standard set of triple resonance NMR spectra. Additional assignments were obtained by comparison with the isolated CBD1 and CBD2 domains. A preliminary analysis of NMR chemical shifts and 15N relaxation data obtained for CBD1 indicates that this domain displays considerable amount of flexibility in the free state, but becomes more rigid upon Ca2+-binding. NMR 15N relaxation rates and 1H-15N residual dipolar couplings (RDCs) obtained for the Apo and Ca2+-bound states of the CBD12 domain indicate that calcium binding stabilizes a rigid inter-domain orientation. Analysis of 1H-15N RDCs further shows that Drosophila\'s CBD12 domain assumes an almost linear inter-domain orientation in the absence of Ca2+, while a smaller inter-domain angle was found in its presence. These findings support a model in which modulation of CBD12 plasticity by the binding of Ca2+ to the CBD1 domain controls the opening and closing of the exchanger.

Acoplamentos dipolares residuais

Dinâmica de proteínas

Relaxação de 15N

RMN em solução

Trocador de Na+/Ca2+

15N relaxation

Espectroscopy nuclear magnetic resonance

Na+/Ca2+ exchanger

Protein dynamics

Residual dipolar couplings

Solution NMR

Deciphering Structure-Function Relationships in a Two-Subunit-Type GMP Synthetase by Solution NMR Spectroscopy

Ali, Rustam

January 2013

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