The influence of hinge region residue Glu-381 on antithrombin allostery and metastability

Antithrombin becomes an efficient inhibitor of factor Xa and thrombin by binding a specific pentasaccharide sequence found on a small fraction of the heparan sulfate proteoglycans lining the microvaculature. In the structure of native antithrombin, the reactive center loop is restrained due to the insertion of its hinge region into the main beta-sheet A, whereas in the heparin-activated state the reactive center loop is freed from beta-sheet A. In both structures, hinge region residue Glu-381 makes several stabilizing contacts. To determine the role of these contacts in the allosteric mechanism of antithrombin activation, we replaced Glu-381 with an alanine. This variant is less active toward its target proteases than control antithrombin, due to a perturbation of the equilibrium between the two forms, and to an increase in stoichiometry of inhibition. Pentasaccharide binding affinity is reduced 4-fold due to an increase in the off-rate. These data suggest that the main role of Glu-381 is to stabilize the activated conformation. Stability studies also showed that the E381A variant is resistant to continued insertion of its reactive center loop upon incubation at 50 degrees C, suggesting new stabilizing interactions in the native structure. To test this hypothesis, and to aid in the interpretation of the kinetic data we solved to 2.6 A the structure of the variant. We conclude that wild-type Glu-381 interactions stabilize the activated state and decreases the energy barrier to full loop insertion.     

Core particle stability critically depends upon a small number of terminal nucleotides

An apparently homogeneous population of core particles is in fact composed of three subpopulations which behave differently when exposed to a high concentration of ethidium bromide or to 0.6 M NaCl. These subspecies have been identified by the use of several techniques, viz., electron microscopy, sedimentation velocity and circular dichroism. The electrophoretic analysis of their DNA leads to the conclusion that core particle stability critically depends upon a small number of terminal nucleotides.     

Allosteric activation of antithrombin is independent of charge neutralization or reversal in the heparin binding site

We investigate the hypothesis that heparin activates antithrombin (AT) by relieving electrostatic strain within helix D. Mutation of residues K125 and R129 to either Ala or Glu abrogated heparin binding, but did not activate AT towards inhibition of factors IXa or Xa. However, substitution of residues C-terminal to helix D (R132 and K133) to Ala had minimal effect on heparin affinity but resulted in appreciable activation. We conclude that charge neutralization or reversal in the heparin binding site does not drive the activating conformational change of AT, and that the role of helix D elongation is to stabilize the activated state.     

Allosteric activation of a bacterial stress sensor

In Gram-negative bacteria, envelope stress signals such as unfolded outer membrane proteins (OMP) activate the periplasmic protease DegS. This protease then triggers a cellular pathway to alleviate the stress. Now Sohn et al. (2007) show conclusively that inhibition of DegS is relieved allosterically by binding of the C-terminal sequences in unfolded OMPs to the PDZ domain of DegS.     

Allosteric activation of metabotropic glutamate receptor 5

Abstract

Metabotropic glutamate receptor 5 (mGluR5) is a class C G protein-coupled receptor (GPCR) with both an extracellular ligand binding site and an allosteric intrahelical chamber located similarly to the orthosteric ligand binding site of Class A GPCRs. Ligands binding to this ancestral site of mGluR5 can act as positive (PAM), negative (NAM) or silent (SAM) allosteric modulators, and their medicinal chemistry optimization is notoriously difficult, as subtle structural changes may cause significant variation in activity and switch in the functional response. Here we present all atom molecular dynamics simulations of NAM, SAM and PAM complexes formed by closely related ligands and analyse the structural differences of the complexes. Several residues involved in the activation are identified and the formation of a continuous water channel in the active complex but not in the inactive ones is recognized. Our results suggest that the mechanism of mGluR5 activation is similar to that of class A GPCRs.

Communicated by Ramaswamy H. Sarma     

The role of the immunoglobin G "hinge" region in heat aggregation and activation of complex-formation

A high degree of correlation between the capability of subclasses of human immunoglobulins G to form aggregates due to thermal treatment, and their complement-binding activity was established. On the basis of the experimental data obtained by the methods of light scattering, circular dichroism, microcalorimetry, it was supposed that "hinge" region of immunoglobulins G participates in the initial stage of thermal aggregation and in the activation of the process of complement binding.     

Efficiency of Vibrio parahaemolyticus tdh gene expression depends upon two point mutations in its promoter region

A molecular study of Vibrio parahaemolyticus clinical isolates containing the thermostable direct hemolysin (Tdh) gene and the Tdh-related hemolysin (Trh) gene have been conducted. Southern blot hybridization revealed that in the genomes of strains carrying the determinants of both hemolysins (tdh ⁺ trh ⁺) the tdh gene is presented by a single copy while tdh ⁺ trh ^? strains have two copies (tdh1 and tdh2). All investigated tdh ⁺ trh ⁺ and some tdh ⁺ trh ^? strains did not express the tdh gene (Kanagawa-negative, KP^?) or expressed it weakly and inconstantly (Kanagawa-intermediate, KP^±) in contrast to several Kanagawa-positive (KP⁺) strains. To establish the reasons for the KP^?/± phenotypes we sequenced tdh, tdh1 and tdh2 genes of 13 strains isolated in Russia and neighbouring foreign countries followed by bioinformatics analysis of the obtained sequences in comparison with those of a number of strains presented in GenBank. The results revealed that poor expression of the tdh gene depends not only on a single point mutation in the promoter region (substitution of A to G in the ?35 sequence) as it was believed earlier, but to the same extent on a second substitution (G to A at ?3 nucleotide position from the t-10 sequence) which appeared to be sufficient in the absence of the first one. Therefore, a reversion of KP^-/± strains to KP⁺ actually may occur as a result of a single point back mutation, and such strains are to be considered as potentially dangerous. Those bearing both substitutions may reverse with less probability as this process requires two simultaneous mutations.     

Life depends upon two kinds of water

Background

Many well-documented biochemical processes lack a molecular mechanism. Examples are: how ATP hydrolysis and an enzyme contrive to perform work, such as active transport; how peptides are formed from amino acids and DNA from nucleotides; how proteases cleave peptide bonds, how bone mineralises; how enzymes distinguish between sodium and potassium; how chirality of biopolymers was established prebiotically.

Methodology/Principal Findings

It is shown that involvement of water in all these processes is mandatory, but the water must be of the simplified configuration in which there are only two strengths of water-water hydrogen bonds, and in which these two types of water coexist as microdomains throughout the liquid temperature range. Since they have different strengths of hydrogen bonds, the microdomains differ in all their physical and chemical properties. Solutes partition asymmetrically, generating osmotic pressure gradients which must be compensated for or abolished. Displacement of the equilibrium between high and low density waters incurs a thermodynamic cost which limits solubility, depresses ionisation of water, drives protein folding and prevents high density water from boiling at its intrinsic boiling point which appears to be below 0°C. Active processes in biochemistry take place in sequential partial reactions, most of which release small amounts of free energy as heat. This ensures that the system is never far from equilibrium so that efficiency is extremely high. Energy transduction is neither possible and nor necessary. Chirality was probably established in prebiotic clays which must have carried stable populations of high density and low density water domains. Bioactive enantiomorphs partition into low density water in which they polymerise spontaneously.

Conclusions/Significance

The simplified model of water has great explanatory power.     

Non-enzymatic hinge region fragmentation of antibodies in solution

Liquid formulations of monoclonal antibodies (MAbs) typically undergo fragmentation near the papain cleavage site in the hinge region, resulting in Fab and Fab+Fc forms. The purpose of this study was to investigate whether this fragmentation is due to proteases. Four closely-related MAbs were exchanged into a pH 5.2 acetate buffer with NaCl and stored at -20 degrees C, 5 degrees C, 30 degrees C, or 40 degrees C for 1 month. Fragmentation generated size-exclusion chromatography (SEC) peak fractions that were analyzed by electrospray mass spectrometry to identify the cleavage sites. The effects of protein inhibitors or host cell proteins on fragmentation were also studied. The extent of fragmentation was equivalent for all four antibodies, occurring in the heavy chain hinge region Ser-Cys-Asp-Lys-Thr-His-Thr sequence. The fragment due to cleavage of the Asp-Lys bond showed two forms that differ by 18 Da. A synthetic peptide with the hinge region sequence terminating with Asp did not show fragmentation or the loss of 18 Da after incubation. Protease inhibitors did not affect rates of cleavage or modify sites of fragmentation. Degradation was not affected by host cell protein content. Fragmentation appears to be a kinetic process that is not caused by low levels of host cell proteases.     

Allosteric activation of chymotrypsin-catalyzed hydrolysis of specific substrates

The rates of hydrolysis of three specific substrates of chymotrypsin, glutaryl-L-phenylalanine p-nitroanilide, acetyl-DL-tyrosine p-nitroanilide and acetyl-L-tyrosine anilide were enhanced by 2,2′-bis[α-(benzyldimethylammonium)methyl] azobenzene dibromide and less so by related compounds. Detailed studies with glutaryl-L-phenylalanine p-nitroanilide showed a 42-fold increase in k_cat with no change in Km. No acceleration (or inhibition) was noted with esters, hydroxamides or proteins as substrates. Tryptic hydrolysis of benzoyl-DL-arginine p-nitroanilide was unaffected. It was concluded that certain quaternary compounds can act as allosteric effectors of chymotrypsin.     

The conformational activation of antithrombin. A 2.85-A structure of a fluorescein derivative reveals an electrostatic link between the hinge and heparin binding regions

Antithrombin is unique among the serpins in that it circulates in a native conformation that is kinetically inactive toward its target proteinase, factor Xa. Activation occurs upon binding of a specific pentasaccharide sequence found in heparin that results in a rearrangement of the reactive center loop removing constraints on the active center P1 residue. We determined the crystal structure of an activated antithrombin variant, N135Q S380C-fluorescein (P14-fluorescein), in order to see how full activation is achieved in the absence of heparin and how the structural effects of the substitution in the hinge region are translated to the heparin binding region. The crystal structure resembles native antithrombin except in the hinge and heparin binding regions. The absence of global conformational change allows for identification of specific interactions, centered on Glu(381) (P13), that are responsible for maintenance of the solution equilibrium between the native and activated forms and establishes the existence of an electrostatic link between the hinge region and the heparin binding region. A revised model for the mechanism of the allosteric activation of antithrombin is proposed.     

Critical role of the linker region between helix D and strand 2A in heparin activation of antithrombin

The binding of pentasaccharide heparin to antithrombin induces a conformational change that is transmitted to the reactive center loop and increases the rate of inhibition of factor Xa by approximately 300-fold. The mechanism of such transmission is not known. To test the role of residues 134-137, which link helix D to beta-sheet A, in this signal transduction, we created variant antithrombins in which we removed amino acids 134-137 stepwise and cumulatively. Although the deletions did not compromise the fundamental ability of antithrombin to bind to heparin or to inhibit target proteinases thrombin and factor Xa, they did largely decouple conformational changes in the heparin-binding site from conformational activation of the reactive center loop. Because the variant with only Ala(134) removed was as compromised as variants with larger deletions, yet the variant with Ser(137) removed was normal, we concluded that the length of the linker is less important than the precise interrelationship between residues in this region and other residues involved in conformational activation of antithrombin.     

The effect of a reducing-end extension on pentasaccharide binding by antithrombin

Antithrombin requires heparin for efficient inhibition of the final two proteinases of the blood coagulation cascade, factor Xa and thrombin. Antithrombin binds heparin via a specific pentasaccharide domain in a two-step mechanism whereby initial weak binding is followed by a conformational change and subsequent tight binding. The goal of this study is to investigate the role of a reducing-end extension in the binding of the longer oligosaccharides that contain the cognate pentasaccharide sequence. We determined the antithrombin binding properties of a synthetic heptasaccharide containing the natural pentasaccharide sequence (DEFGH) and an additional reducing-end disaccharide (DEFGHG'H'). Binding at low ionic strength is unaffected by the disaccharide addition, but at ionic strengths >/=0.2 the mode of heptasaccharide binding changes resulting in a 2-fold increase in affinity due to a decrease in the off-rate caused by a greater nonionic contribution to binding. Molecular modeling of possible binding modes for the heptasaccharide at high ionic strength indicates a possible shift in position of the pentasaccharide domain to occupy the extended heparin-binding site. This conclusion supports the likely presence of a range of sequences that can bind to and activate antithrombin in the natural heparan sulfates that line the vascular endothelium.     

Adaptive evolution of the IgA hinge region in primates

IgA is a major component that prevents the penetration of pathogenic bacteria into mucosal surfaces. The IgA antibody is cleaved at the IgA hinge region with high specificity by IgA-specific proteases produced by several pathogenic bacteria. We conducted a genomic sequence analysis of the IgA genes of a wide spectrum of primates, including the first intron and second exon, which consist of the hinge region and the CH2 domain, to find evidence of positive selection. Because the hinge region is quite small, we combined the largest collection of sequences that could be clearly aligned and evaluated the total numbers of synonymous and nonsynonymous substitutions on the phylogenetic tree. The nonsynonymous to synonymous substitution ratio (d(N)/d(S) test) showed that hominoids, Old World monkeys, and New World monkeys have d(N)/d(S) ratios of 5.4, 6.3, and 4.2, respectively. Fisher's exact probability tests showed statistical significance for the Old World monkey. Because the substitution rates of the flanking sequences are more or less similar to the synonymous rates of the hinge region, these high values of d(N)/d(S) should be the result of positive selection at the hinge region. Combining the high sequence variability in each population and the highly accelerated nonsynonymous substitution rates in the hinge region, we conclude that this unusual IgA evolution is a molecular evidence of adaptive evolution possibly caused by the host-parasite relationship.     

Roles of hinge region, loops 3 and 4 in the activation of Escherichia coli cyclic AMP receptor protein

The cAMP receptor protein (CRP) requires cAMP for an allosteric change and regulates more than 150 genes in Escherichia coli. In this study, the modular half of cAMP receptor protein was used to investigate the allosteric signal transmission pathway induced by cAMP binding. The activation of CRP upon cAMP binding is indicated to be realignment of the two subunits within the CRP dimer. The interaction of loop 3 and Phe136 do not involve in signal transmission.