Structure-function studies of the sodium-calcium exchanger isoforms, NCX1 and NCX2

de Moissac, Danielle

30 June 2009

The sodium-calcium exchanger (NCX) is a countertransporter of Na+ and Ca2+ across most cell membranes. It has been identified as an essential component of Ca2+ homeostasis in physiological and disease conditions in both cardiovascular and neurological settings. The exchanger not only transports Na+ and Ca2+, but is also regulated by these ions. Although ionic regulatory profiles differ between NCX isoforms, similar regulatory domains have been identified. Previous structure-function studies have determined key residues within these domains, particularly in the eXchanger Inhibitory Peptide region (XIP) and the Ca2+ binding domains (CBD1/2), which have a direct impact on ionic regulation of the outward exchange currents. Recent structural studies of the Ca2+ binding domains of NCX1 suggest a mechanism by which Ca2+ binding would not only be essential for activation of current but may also influence Na+-dependent inactivation. The alternative splice region is located within the Ca2+ binding domain and may play a role in mediating these regulatory phenotypes. Previous studies have demonstrated that specific combinations of the mutually-exclusive and cassette exons are associated with profound effects on ionic regulation in NCX1. This study focuses on examining the mechanisms by which the alternative splice region, in combination with specific regulatory domains, modulates exchange activity in two isoforms, NCX1 and NCX2. Chimaeric and mutant constructs in the alternative splice region were expressed in Xenopus oocytes and outward Na+-Ca2+ exchange activity was assessed using the giant, excised patch clamp technique. Substitution of the region corresponding to the mutually exclusive exon in either exchanger greatly reduced the extent of Na+-dependent inactivation, independently of intracellular Ca2+ concentrations. However, replacement of both the region corresponding to the mutually exclusive exon A and the XIP region reestablishes a wild-type profile in NCX2. The first mutually exclusive exon is therefore critical in determining Na+ and Ca2+-dependent regulatory properties. Furthermore, non-conserved residues within the XIP region may be essential in maintaining the structural stability of the Na+-dependent inactive state of NCX1, and by interacting with the mutually exclusive exon, may contribute to the structure-function relationship and the distinct regulatory phenotype of each Na+-Ca2+ exchanger variant and isoform.

structure-function

NCX

Structure-function studies of the sodium-calcium exchanger isoforms, NCX1 and NCX2

de Moissac, Danielle

30 June 2009

The sodium-calcium exchanger (NCX) is a countertransporter of Na+ and Ca2+ across most cell membranes. It has been identified as an essential component of Ca2+ homeostasis in physiological and disease conditions in both cardiovascular and neurological settings. The exchanger not only transports Na+ and Ca2+, but is also regulated by these ions. Although ionic regulatory profiles differ between NCX isoforms, similar regulatory domains have been identified. Previous structure-function studies have determined key residues within these domains, particularly in the eXchanger Inhibitory Peptide region (XIP) and the Ca2+ binding domains (CBD1/2), which have a direct impact on ionic regulation of the outward exchange currents. Recent structural studies of the Ca2+ binding domains of NCX1 suggest a mechanism by which Ca2+ binding would not only be essential for activation of current but may also influence Na+-dependent inactivation. The alternative splice region is located within the Ca2+ binding domain and may play a role in mediating these regulatory phenotypes. Previous studies have demonstrated that specific combinations of the mutually-exclusive and cassette exons are associated with profound effects on ionic regulation in NCX1. This study focuses on examining the mechanisms by which the alternative splice region, in combination with specific regulatory domains, modulates exchange activity in two isoforms, NCX1 and NCX2. Chimaeric and mutant constructs in the alternative splice region were expressed in Xenopus oocytes and outward Na+-Ca2+ exchange activity was assessed using the giant, excised patch clamp technique. Substitution of the region corresponding to the mutually exclusive exon in either exchanger greatly reduced the extent of Na+-dependent inactivation, independently of intracellular Ca2+ concentrations. However, replacement of both the region corresponding to the mutually exclusive exon A and the XIP region reestablishes a wild-type profile in NCX2. The first mutually exclusive exon is therefore critical in determining Na+ and Ca2+-dependent regulatory properties. Furthermore, non-conserved residues within the XIP region may be essential in maintaining the structural stability of the Na+-dependent inactive state of NCX1, and by interacting with the mutually exclusive exon, may contribute to the structure-function relationship and the distinct regulatory phenotype of each Na+-Ca2+ exchanger variant and isoform.

structure-function

NCX

The Extraction of the Spin Structure Function, G2 (And G1) at Low Bjorken X

Ndukum, Luwani Zurmbonwi

14 August 2015

The Spin Asymmetries of the Nucleon Experiment (SANE) used the Continuous Electron Beam Accelerator Facility at Jefferson Laboratory in Newport News, VA to investigate the spin structure of the proton. The experiment measured inclusive double polarization electron asymmetries using a polarized electron beam, scattered off a solid polarized ammonia target with target polarization aligned longitudinal and near transverse to the electron beam, allowing the extraction of the spin asymmetries A1 and A2, and spin structure functions g1 and g2. Polarized electrons of energies of 4.7 and 5.9 GeV were used. The scattered electrons were detected by a novel, non-magnetic array of detectors observing a four-momentum transfer range of 2.5 to 6.5 GeV*V. This document addresses the extraction of the spin asymmetries and spin structure functions, with a focus on spin structure function, g2 (and g1) at low Bjorken x. The spin structure functions were measured as a function of x and W in four Q square bins. A full understanding of the low x region is necessary to get clean results for SANE and extend our understanding of the kinematic region at low x.

Bjorken

proton

spin structure function

Depolymerisation and re-polymerisation of wheat glutenin during dough processing and effects of low M←r wheat proteins

Weegels, Peter Louis

January 1994

No description available.

664

Implication du glutamate 346 de NHE1 dans le transport du Na⁺ et l'interaction avec les inhibiteurs

Germain, David

January 2006

Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.

NHE

Inhibiteurs

Na⁺

Glutamate

Structure-function

Activité

Studies of structure, function and mechanism in pyrimidine nucleotide biosynthesis

Harris, Katharine Morse

January 2012

Thesis advisor: Evan R. Kantrowitz / Thesis advisor: Mary F. Roberts / Living organisms depend on enzymes for the synthesis using small molecule precursors of cellular building blocks. For example, the amino acid aspartate is synthesized in one step by the amination of oxaloacetate, an intermediate compound produced in the citric acid cycle, exclusively by means of an aminotransferase enzyme. Therefore, function of this aminotransferase is critical to produce the amino acid. In the Kantrowitz Lab, we seek to understand the molecular rational for the function of enzymes that control rates for the biosynthesis of cellular building blocks. If one imagines the above aspartate-synthesis example as a single running conveyer belt, any oxaloacetate that finds its way onto that belt will be chemically transformed to give aspartate. We can extend this notion of a conveyer belt to any enzyme. Therefore, the rate at which the belt moves dictates the rate of synthesis. Now imagine many, many conveyer belts lined in a row to give analogy to a biosynthesis pathway requiring more than one enzyme for complete chemical synthesis. This is such the case for the biosynthesis of nucleotides and glucose. Nature has developed clever tricks to exquisitely control the rate of product output but means of altering the rate of one or some of the belts in the line of many, without affecting the rate of others. This type of biosynthetic rate regulation is termed allostery. Studies described in this dissertation will address questions of allosteric processes and the chemistry performed by two entirely different enzymes and biosynthetic pathways. The first enzyme of interest is fructose-1,6-bisphosphatase (FBPase) and its role in the biosynthesis of glucose. Following FBPase introduction in Chapter One, Chapter Two describes the minimal atomic scaffold necessary in a new class of allosteric type 2 diabetes drug molecules to effect catalytic inhibition of <italic>Homo sapiens</italic> FBPase. Following, is the second enzyme of interest, aspartate transcarbamoylase (ATCase) and its role in the biosynthesis of pyrimidine nucleotides. Succeeding ATCase introduction in Chapter Three, Chapter Four describes a body of work exclusively about the catalysis by ATCase. This work was inspired by the human form of the enzyme following the human genome project completion providing data that show likely <italic>Homo sapiens</italic> ATCase is not allosterically regulated. Chapter Five describes work on a allosterically-regulated, mutant ATCase and provides a biochemical model for the molecular rational for the catalytic inhibition upon cytidine triphosphate (CTP) binding to the allosteric site. The experimental techniques used for answering research questions were enzyme X-ray crystallography, <italic>in silico</italic> docking, kinetic assay experiments, genetic sub-cloning and genetic mutation. / Thesis (PhD) — Boston College, 2012. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

catalytic regulation

enzyme catalysis

enzyme structure/function

Probing the Mechanism of the Allosteric Transition of Aspartate Transcarbamoylase via Fluorescence, Physical Entrapment, and Small-Angle X-Ray Scattering

West, Jay M.

January 2009

Thesis advisor: Evan R. Kantrowitz / The regulatory mechanism of allostery is exhibited by certain proteins such as Escherichia coli aspartate transcarbamoylase (ATCase), and is defined as the change in shape and activity (of enzymes) resulting from the binding of particular molecules at locations distant from the active site. This particular enzyme and the property of allostery in general have been investigated for several decades, yet the molecular mechanisms underlying allosteric regulation remain unclear. Therefore in this thesis we have attempted via several biophysical methods, along with the tools of molecular biology and biochemistry, to correlate the changes in allosteric structure with presence of the allosteric effectors and enzymatic activity. We created a double mutant version of ATCase, in which the only native cysteine residue in the catalytic chain was mutated to alanine and another alanine on a loop was mutated to cysteine, in order to lock the enzyme into the R allosteric state by disulfide bonds. This disulfide locked R state exhibited no regulation by the allosteric effectors ATP and CTP and lost all cooperativity for aspartate, and then regained those regulatory properties after the disulfide links were severed by addition of a reducing agent. This double mutant was then chemically modified by covalent attachment of a fluorescent probe. The T and R allosteric states of this fluorophore-labeled enzyme had dramatically different fluorescence emission spectra, providing a highly sensitive tool for testing the effects of the allosteric effectors on the allosteric state. The changes in the fluorescence spectra, and hence quaternary structure, matched the changes in activity after addition of ATP or CTP. This fluorophore labeled enzyme was also encapsulated within a solgel, changing the time scale of the allosteric transition from milliseconds to several hours. The fluorophore labels allowed monitoring the allosteric state within the sol-gel, and the physically trapped T and R states both showed no regulation by the allosteric effectors ATP and CTP, and no cooperativity for aspartate. The trapped T state had low-affinity for aspartate and low activity, and the trapped R state had high-affinity for aspartate and high activity. Timeresolved small-angle x-ray scattering (TR-SAXS) was used to determine the kinetics of the allosteric transition, and to monitor the structure of the enzyme in real time after the addition of substrates and allosteric effectors. These TR-SAXS studies demonstrated a correlation between the presence of the allosteric effectors, the quaternary allosteric state, and activity, suggesting like the previous studies in this thesis that the behavior of ATCase is well explained by the twostate model. However, the effector ATP appeared to destabilize the T state and CTP to destabilize the R state, suggesting a different allosteric molecular mechanism than that of the two-state model. This thesis demonstrates the validity of many of the concepts of the two-state model, while suggesting minor modifications to that elegantly simple model in order to conform with the complex structure and function of ATCase. / Thesis (PhD) — Boston College, 2009. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

allosteric enzyme

aspartate transcarbamoylase

protein structure-function

Effect of Chemical Parameters on Structure-Function Relationships of Cheese

Pastorino, Andres J.

01 May 2002

The effect of chemical parameters on cheese structure and functionality was studied by modifying the calcium, salt content, and pH of cheese. Cheese blocks were high-pressure injected from zero to five times with water, solutions of different salts, or an acid solution 14 d after manufacture. Successive injections were performed 24 h apart. After 40-42 d of refrigerated storage, cheese structure was studied by using scanning electron microscopy and digital image analysis, and cheese functionality was characterized by texture profile analysis and melting test. Increased salt content of cheese (2.7 versus 0.1%) caused the protein matrix to become more hydrated and to expand (P < 0.1 ), though the occurrence of syneresis resulted in decreased moisture content of cheese (P < 0.05). Salt injection increased cheese hardness and the initial rate of cheese flow, but it decreased cheese cohesiveness (P < 0.05). Increased calcium content (1.8 versus 0.3%) and decreased pH of cheese (4.7 versus 5.3) caused contraction of the protein matrix (P < 0.05) and release of serum. Thus, the matrix became less hydrated, and the moisture content and weight of cheese decreased (P < 0.05). Calcium injection decreased the pH and melting of cheese, but it increased cheese hardness (P < 0.05). Acid injection promoted calcium solubilization and decreased calcium content of cheese (P < 0.05). Above pH 5.0 (5.0-5.3), acid injection decreased cheese hardness and increased the initial rate of cheese flow (P < 0.05). Below pH 5.0 (5.0-4.7), acid injection decreased cheese cohesiveness, and the initial rate and extent of cheese flow (P < 0.05). In conclusion, modifying the chemical composition of cheese alters protein interactions, resulting in cheese with different structural and functional properties. Increased salt content of cheese (up to 2.7%) impairs protein-to-protein interactions, and its effect is most significant when salt content increases from 0 to 0.5%. Below 5.0 (5.0- 4.7), the effect of pH predominates over calcium content, and decreased cheese pH promotes protein-to-protein interactions. Increased calcium content of cheese (up to 1.8%) also promotes protein-to-protein interactions, and the content of protein-bound calcium may be the major factor controlling the functionality of most cheeses.

Chemical parameters

structure function

cheese

Nutrition

The contributions of S₁ site residues to substrate specificity and allosteric behaviour of <i>Lactococcus lactis</i> prolidase

Hu, Keke

19 November 2009

Three residues, Phe190, Leu193 and Val302, which have been proposed to define the S₁ site of prolidase of <i>Lactococcus lactis</i> NRRL B-1821 (<i>L. lactis</i> prolidase), may limit the size and polarity of specific substrates accepted by this enzyme (Yang, S. I., and Tanaka, T. 2008. Characterization of recombinant prolidase from <i>L. lactis</i> changes in substrate specificity by metal cations, and allosteric behavior of the peptidase. FEBS J. 275, 271-280). These residues form a hydrophobic pocket to determine the substrate specificity of <i>L. lactis</i> prolidase towards hydrophobic peptides, such as Leu-Pro and Phe-Pro, while little activity was observed for anionic Asp-Pro and Glu-Pro. It is hypothesized that the substrate specificity of <i>L. lactis</i> prolidase would be changed if these residues are substituted with hydrophilic amino acid residues individually or in combinations by site-directed mutagenesis (SDM). In addition to the changes in substrate specificity, other characteristics of wild type prolidase, such as allosteric behaviour and substrate inhibition may receive influences by the mutations (Yang & Tanaka, 2008). To test this hypothesis, mutations were conducted on these three residues at the S₁ site. Mutated <i>L. lactis</i> prolidases were subsequently analyzed in order to examine the roles of these residues in the substrate specificity, allosteric behaviour, pH dependency, thermal dependency and metal dependency of prolidase. The results showed the significant changes in these kinetic characteristics of single mutants, such as L193E, L193R, V302D and V302K and double mutants, L193E/V302D and L193R/V302D. Leu193 was suggested to be a key residue for substrate binding. The mutants L193R, V302D, L193R/V302D and L193E/V302D lost their allosteric behaviour, and the substrate inhibition of the wild type was no longer observed in V302D and L193E/V302D. The results indicated Val302 to be more important for these properties than other S₁ site residues. Moreover, together with the observations in molecular modelling of the mutants, it was proposed that interactions of Asp302 with Arg293 and His296 caused the loss of allosteric behaviour and substrate inhibition in the V302D mutant. The investigations on the pH dependency suggested that His296 acted as proton acceptor in <i>L. lactis</i> prolidase's catalysis. It was expected that the electrostatic microenvironment surrounding His296 was influenced by the charged mutated residues and side chains of dipeptide substrates, thus the protonation of His296 was affected. It was suggested that the introduced positive charge would stabilize the deprotonated form of His296 thus to maintain the activities of the mutants in more acidic condition compared to wild type prolidase. The study of thermal dependency revealed that all non-allosteric prolidases had higher optimum temperatures, suggesting that the loss of allosteric behaviour resulted in more rigid structures in these prolidases.

Allosteric Behaviour

Hydrophobicity

Prolidase

Structure-Function Relationships

The contributions of S₁ site residues to substrate specificity and allosteric behaviour of <i>Lactococcus lactis</i> prolidase

Hu, Keke

19 November 2009

Three residues, Phe190, Leu193 and Val302, which have been proposed to define the S₁ site of prolidase of <i>Lactococcus lactis</i> NRRL B-1821 (<i>L. lactis</i> prolidase), may limit the size and polarity of specific substrates accepted by this enzyme (Yang, S. I., and Tanaka, T. 2008. Characterization of recombinant prolidase from <i>L. lactis</i> changes in substrate specificity by metal cations, and allosteric behavior of the peptidase. FEBS J. 275, 271-280). These residues form a hydrophobic pocket to determine the substrate specificity of <i>L. lactis</i> prolidase towards hydrophobic peptides, such as Leu-Pro and Phe-Pro, while little activity was observed for anionic Asp-Pro and Glu-Pro. It is hypothesized that the substrate specificity of <i>L. lactis</i> prolidase would be changed if these residues are substituted with hydrophilic amino acid residues individually or in combinations by site-directed mutagenesis (SDM). In addition to the changes in substrate specificity, other characteristics of wild type prolidase, such as allosteric behaviour and substrate inhibition may receive influences by the mutations (Yang & Tanaka, 2008). To test this hypothesis, mutations were conducted on these three residues at the S₁ site. Mutated <i>L. lactis</i> prolidases were subsequently analyzed in order to examine the roles of these residues in the substrate specificity, allosteric behaviour, pH dependency, thermal dependency and metal dependency of prolidase. The results showed the significant changes in these kinetic characteristics of single mutants, such as L193E, L193R, V302D and V302K and double mutants, L193E/V302D and L193R/V302D. Leu193 was suggested to be a key residue for substrate binding. The mutants L193R, V302D, L193R/V302D and L193E/V302D lost their allosteric behaviour, and the substrate inhibition of the wild type was no longer observed in V302D and L193E/V302D. The results indicated Val302 to be more important for these properties than other S₁ site residues. Moreover, together with the observations in molecular modelling of the mutants, it was proposed that interactions of Asp302 with Arg293 and His296 caused the loss of allosteric behaviour and substrate inhibition in the V302D mutant. The investigations on the pH dependency suggested that His296 acted as proton acceptor in <i>L. lactis</i> prolidase's catalysis. It was expected that the electrostatic microenvironment surrounding His296 was influenced by the charged mutated residues and side chains of dipeptide substrates, thus the protonation of His296 was affected. It was suggested that the introduced positive charge would stabilize the deprotonated form of His296 thus to maintain the activities of the mutants in more acidic condition compared to wild type prolidase. The study of thermal dependency revealed that all non-allosteric prolidases had higher optimum temperatures, suggesting that the loss of allosteric behaviour resulted in more rigid structures in these prolidases.

Allosteric Behaviour

Hydrophobicity

Prolidase

Structure-Function Relationships