Examining the interactions of Galahad™ compound with viruses to develop a novel inactivated influenza A virus vaccine.

Galahad™ is a proanthocyanidin complexed with polysaccharides that inactivates viruses and indicates potential for an innovative approach to making protective vaccines. The polysaccharide portion of Galahad™ consists mainly of arabinan and arabinogalactan. In a seven-day toxicity study in rats, it was not toxic even when tested undiluted. Galahad™ inactivated a wide range of DNA and RNA viruses including adenoviruses, corona viruses such as SARS-CoV-2, and influenza viruses. Electron microscopy studies showed that exposure to Galahad™ caused extensive clumping of virions followed by lack of detection of virions after longer periods of exposure. Based on the viral inactivation data, the hypotheses tested is that Galahad™ inactivation of virus can be used to formulate a protective inactivated virus vaccine. To evaluate this hypothesis, infectious influenza A virus (H5N1, Duck/MN/1525/81) with a titer of 105.7 CCID50/0.1 ml was exposed for 10 min to Galahad™. This treatment caused the infectious virus titer to be reduced to below detectable limits. The Galahad™ -inactivated influenza preparation without adjuvant or preservative was given to BALB/c mice using a variety of routes of administration and dosing regimens. The most protective route of administration and dosing regimen was when mice were given the vaccine twice intranasally, the second dose coming 14 days after the primary vaccine dose. All the mice receiving this vaccine regimen survived the virus challenge while only 20% of the mice receiving placebo survived. This suggests that a Galahad™-inactivated influenza virus vaccine can elicit a protective immune response even without the use of an adjuvant. This technology should be investigated further for its potential to make effective human vaccines.

Saturation Mutagenesis of the Antithrombin Reactive Center Loop P14 Residue Supports a Three-step Mechanism of Heparin Allosteric Activation Involving Intermediate and Fully Activated States.

Past studies have suggested that a key feature of the mechanism of heparin allosteric activation of the anticoagulant serpin, antithrombin, is the release of the reactive center loop P14 residue from a native state stabilizing interaction with the hydrophobic core. However, more recent studies have indicated that this structural change plays a secondary role in the activation mechanism. To clarify this role, we expressed and characterized 15 antithrombin P14 variants. The variants exhibited basal reactivities with factors Xa and IXa, heparin affinities and thermal stabilities that were dramatically altered from wild type, consistent with the P14 mutations perturbing native state stability and shifting an allosteric equilibrium between native and activated states. Rapid kinetic studies confirmed that limiting rate constants for heparin allosteric activation of the mutants were altered in conjunction with the observed shifts of the allosteric equilibrium. However, correlations of the P14 mutations' effects on parameters reflecting the allosteric activation state of the serpin were inconsistent with a two-state model of allosteric activation and suggested multiple activated states. Together, these findings support a minimal three-state model of allosteric activation in which the P14 mutations perturb equilibria involving distinct native, intermediate, and fully activated states wherein the P14 residue retains an interaction with the hydrophobic core in the intermediate state but is released from the core in the fully activated state, and the bulk of allosteric activation has occurred in the intermediate.

Disruption of a tight cluster surrounding tyrosine 131 in the native conformation of antithrombin III activates it for factor Xa inhibition.

The native conformation of antithrombin III (ATIII) is a poor inhibitor of its coagulation pathway target enzymes because of the partial insertion of its reactive center loop (RCL) in its central A beta-sheet. This study focused on tyrosine 131, which is located at the helix D-sheet A interface, adjacent to the ATIII pentasaccharide and heparin cofactor-binding sites and some 17A away from the RCL insertion. Crystallographic structures show that the Tyr(131) ring is buried in native ATIII and then becomes exposed when pentasaccharide binds to the inhibitor and activates it. This change suggested that Tyr(131) might serve as a switch for ATIII conformational activation. The hypothesis is supported by results from this study, which progressively removed atoms from the Tyr(131) side chain. Rates of heparin-independent Y131L and Y131A factor Xa inhibition were 25 and 29 times faster than for the control and Y131F, suggesting that Tyr(131) ring interactions with neighboring helix D and strand 2A residues shift the uncatalyzed native-to-activated conformational equilibrium toward the RCL-inserted state. Thermal denaturation experiments showed Y131A and Y131L were less stable than the control and Y131F, implying an increased tendency toward A-sheet mobility in these genetically activated molecules. Thus, the tight Tyr(131)-Asn(127)-Leu(130)-Leu(140)-Ser(142) cluster at the helix D-strand 2A interface of native antithrombin contributes significantly to the stability of the ground state conformation, and tyrosine 131 serves as a heparin-responsive molecular switch during the allosteric activation of ATIII anticoagulant activity.

Roles of N-terminal region residues Lys11, Arg13, and Arg24 of antithrombin in heparin recognition and in promotion and stabilization of the heparin-induced conformational change.

The N-terminal region residues, Lys11, Arg13, and Arg24, of the plasma coagulation inhibitor, antithrombin, have been implicated in binding of the anticoagulant polysaccharide, heparin, from the identification of natural mutants with impaired heparin binding or by the X-ray structure of a complex of the inhibitor with a high-affinity heparin pentasaccharide. Mutations of Lys11 or Arg24 to Ala in this work each reduced the affinity for the pentasaccharide approximately 40-fold, whereas mutation of Arg13 to Ala led to a decrease of only approximately 7-fold. All three substitutions resulted in the loss of one ionic interaction with the pentasaccharide and those of Lys11 or Arg24 also in 3-5-fold losses in affinity of nonionic interactions. Only the mutation of Lys11 affected the initial, weak interaction step of pentasaccharide binding, decreasing the affinity of this step approximately 2-fold. The mutations of Lys11 and Arg13 moderately, 2-7-fold, altered both rate constants of the second, conformational change step, whereas the substitution of Arg24 appreciably, approximately 25-fold, reduced the reverse rate constant of this step. The N-terminal region of antithrombin is thus critical for high-affinity heparin binding, Lys11 and Arg24 being responsible for maintaining appreciable and comparable binding energy, whereas Arg13 is less important. Lys11 is the only one of the three residues that is involved in the initial recognition step, whereas all three residues participate in the conformational change step. Lys11 and Arg13 presumably bind directly to the heparin pentasaccharide by ionic, and in the case of Lys11, also nonionic interactions. However, the role of Arg24 most likely is indirect, to stabilize the heparin-induced P-helix by interacting intramolecularly with Glu113 and Asp117, thereby positioning the crucial Lys114 residue for optimal ionic and nonionic interactions with the pentasaccharide. Together, these findings show that N-terminal residues of antithrombin make markedly different contributions to the energetics and dynamics of binding of the pentasaccharide ligand to the native and activated conformational states of the inhibitor that could not have been predicted from the X-ray structure.

Antithrombin III phenylalanines 122 and 121 contribute to its high affinity for heparin and its conformational activation.

The dissociation equilibrium constant for heparin binding to antithrombin III (ATIII) is a measure of the cofactor's binding to and activation of the proteinase inhibitor, and its salt dependence indicates that ionic and non-ionic interactions contribute approximately 40 and approximately 60% of the binding free energy, respectively. We now report that phenylalanines 121 and 122 (Phe-121 and Phe-122) together contribute 43% of the total binding free energy and 77% of the energy of non-ionic binding interactions. The large contribution of these hydrophobic residues to the binding energy is mediated not by direct interactions with heparin, but indirectly, through contacts between their phenyl rings and the non-polar stems of positively charged heparin binding residues, whose terminal amino and guanidinium groups are thereby organized to form extensive and specific ionic and non-ionic contacts with the pentasaccharide. Investigation of the kinetics of heparin binding demonstrated that Phe-122 is critical for promoting a normal rate of conformational change and stabilizing AT*H, the high affinity-activated binary complex. Kinetic and structural considerations suggest that Phe-122 and Lys-114 act cooperatively through non-ionic interactions to promote P-helix formation and ATIII binding to the pentasaccharide. In summary, although hydrophobic residues Phe-122 and Phe-121 make minimal contact with the pentasaccharide, they play a critical role in heparin binding and activation of antithrombin by coordinating the P-helix-mediated conformational change and organizing an extensive network of ionic and non-ionic interactions between positively charged heparin binding site residues and the cofactor.

Specificity of the basic side chains of Lys114, Lys125, and Arg129 of antithrombin in heparin binding.

The anticoagulant polysaccharide heparin binds and activates the plasma proteinase inhibitor antithrombin through a pentasaccharide sequence. Lys114, Lys125, and Arg129 are the three most important residues of the inhibitor for pentasaccharide binding. To elucidate to what extent another positively charged side chain can fulfill the role of each of these residues, we have mutated Lys114 and Lys125 to Arg and Arg129 to Lys. Lys114 could be reasonably well replaced with Arg with only an approximately 15-fold decrease in pentasaccharide affinity, in contrast to an approximately 10(5)-fold decrease caused by substitution with an noncharged amino acid of comparable size. However, a loss of approximately one ionic interaction on mutation to Arg indicates that the optimal configuration of the network of basic residues of antithrombin that together interact with the pentasaccharide requires a Lys in position 114. Replacement of Lys125 with Arg caused an even smaller, approximately 3-fold, decrease in pentasaccharide affinity, compared with that of approximately 400-fold caused by mutation to a neutral amino acid. An Arg in position 125 is thus essentially equivalent to the wild-type Lys in pentasaccharide binding. Substitution of Arg129 with Lys decreased the pentasaccharide affinity an appreciable approximately 100-fold, a loss approaching that of approximately 400-fold caused by substitution with a neutral amino acid. Arg is thus specifically required in position 129 for high-affinity pentasaccharide binding. This requirement is most likely due to the ability of Arg to interact with other residues of antithrombin, primarily, Glu414 and Thr44, in a manner that appropriately positions the Arg side chain for keeping the pentasaccharide anchored to the activated state of the inhibitor.

Identification of critical molecular interactions mediating heparin activation of antithrombin: implications for the design of improved heparin anticoagulants.

The serpin, antithrombin, and its polysaccharide activator, heparin, are essential anticoagulant regulators of blood-clotting cascade proteases and thereby critical for maintaining hemostasis. The relative importance of the molecular interactions that mediate heparin binding to and activation of antithrombin, and the dynamics of how they are established, have recently been revealed from the effects of mutagenesis of heparin-binding residues of antithrombin and of modifications of the specific pentasaccharide-binding region in heparin. One residue, Lys 125, is pivotal for antithrombin to recognize and bind the nonreducing-end trisaccharide of the pentasaccharide in an initial low-affinity complex. Two other residues, Lys 114 and Arg 129, then cooperate with Lys 125 to induce the low-affinity complex into an activated, high-affinity complex, in which a network of electrostatic interactions between antithrombin and the entire pentasaccharide is established. The identification of three critical basic residues in antithrombin and a trisaccharide in heparin as principal mediators of heparin activation of antithrombin may stimulate the design of small-molecule anticoagulants that mimic the action of heparin and are orally active.

Importance of lysine 125 for heparin binding and activation of antithrombin.

The anticoagulant sulfated polysaccharide, heparin, binds to the plasma coagulation proteinase inhibitor, antithrombin, and activates it by a conformational change that results in a greatly increased rate of inhibition of target proteinases. Lys125 of antithrombin has previously been implicated in this binding by chemical modification and site-directed mutagenesis and by the crystal structure of a complex between antithrombin and a pentasaccharide constituting the antithrombin-binding region of heparin. Replacement of Lys125 with Met or Gln in this work reduced the affinity of antithrombin for full-length heparin or the pentasaccharide by 150-600-fold at I = 0.15, corresponding to a loss of 25-33% of the total binding energy. The affinity decrease was due both to disruption of approximately three ionic interactions, indicating that Lys125 and two other basic residues of antithrombin act cooperatively in binding to heparin, and to weakened nonionic interactions. The mutations caused a 10-17-fold decrease in the affinity of the initial, weak binding step of the two-step mechanism of heparin binding to antithrombin. They also increased the reverse rate constant of the second, conformational change step by 10-50-fold. Lys125 is thus a major heparin-binding residue of antithrombin, contributing an amount of binding energy comparable to that of Arg129, but less energy than Lys114. It is the first residue identified so far that has a critical role in the initial recognition of heparin by antithrombin, but also appreciably stabilizes the heparin-induced activated state of the inhibitor. These effects are exerted by interactions of Lys125 with the nonreducing end of the heparin pentasaccharide.

Elimination of P1 arginine 393 interaction with underlying glutamic acid 255 partially activates antithrombin III for thrombin inhibition but not factor Xa inhibition.

The mechanism for heparin activation of antithrombin III has been postulated to involve disruption of interactions between its reactive loop P1 residue and Glu(255) on the underlying protein surface. To test this hypothesis, the potential P1-constraining Arg(393)-Glu(255) hydrogen bond and ionic interactions were eliminated by converting Glu(255) to alanine. E255A and wild-type ATIIIs have identical reactive loop sequences (including the P1 and P14 residues), but differ in that Glu(255)-mediated, P1-constraining interactions with the underlying surface cannot form in the mutant. Relative to its wild-type parent, E255A had a 5-fold higher affinity for heparin and pentasaccharide. In the absence of cofactor, E255A exhibited a 5-fold activation of thrombin inhibition but no activation of factor Xa inhibition. Pentasaccharide addition elicited no further activation of thrombin inhibition but increased the factor Xa inhibition rate 100-fold. E255A heparin-dependent thrombin and factor Xa inhibition rates were 1000- and 2-fold faster, respectively, than pentasaccharide-catalyzed rates. Although "approximation" is the predominant factor in heparin activation of ATIII thrombin inhibition, and removal of the P1 constraint plays a distinct but minor role, the primary determinant for activation of factor Xa inhibition is the pentasaccharide-induced conformational change, with approximation making a further minor contribution, and removal of the P1 constraint playing no role at all.