Jay N. Thakkar

Characterization of the plasma and blood anticoagulant potential of structurally and mechanistically novel oligomers of 4-hydroxycinnamic acids

Recently, we designed sulfated dehydropolymers (DHPs) of 4-hydroxycinnamic acids that displayed interesting anticoagulant properties. Structurally and mechanistically, sulfated DHPs are radically different from all the anticoagulants studied to date. To assess whether their unique mechanism and structure is worth exploiting for further rational design of homogeneous DHP-based molecules, we investigated their anticoagulant potential in human plasma and blood using a range of clotting assays. Sulfated DHPs prolong plasma clotting times, prothrombin and activated partial thromboplastin times at concentrations comparable to the clinically used low-molecular-weight heparin, enoxaparin. Fibrin formation studies on human plasma show that there is a structural dependence of anticoagulant action. Human whole blood studies using thromboelastography and hemostasis analysis system indicate that they are 17–140-fold less potent than enoxaparin. These results demonstrate that sulfated DHPs possess good in-vitro and ex-vivo activity, which will likely be improved through a rational design.

Nonsulfated, cinnamic acid-based lignins are potent antagonists of HSV-1 entry into cells.

In an effort to discover macromolecular mimetics of heparan sulfate (HS), we previously designed sulfated lignins (Raghuraman et al. Biomacromolecules 2007, 8, 1759-1763). To probe the relevance of sulfate groups of HS in viral entry, lignins completely devoid of sulfate moieties, and yet possessing an electrostatic surface equivalent to that of HS, were designed. Two carboxylated lignins based on a 4-hydroxy cinnamic acid scaffold were synthesized using enzymatic oxidative coupling in high yields, fractionated according to their sizes, and tested in cellular assays of herpes simplex virus-1 (HSV-1) infection. The two carboxylated lignins were found to not only inhibit HSV-1 entry into mammalian cells (IC(50) = 8-56 nM), but were more potent than sulfated lignins. In addition, shorter carboxylated lignins were found to be as active as the longer chains, suggesting that structural features, in addition to carboxylate groups, may be important. It can be expected that carboxylated lignins also antagonize the entry of other enveloped viruses, for example, HIV-1, Kaposis sarcoma-associated herpes virus, and hepatitis C virus, that utilize HS to gain entry into cells. The results present major opportunities for developing lignin-based antiviral formulations for topical use.

Study of physico-chemical properties of novel highly sulfated, aromatic, mimetics of heparin and heparan sulfate

Heparin (H) and heparan sulfate (HS) play major roles in a number of biological processes. Yet, H/HS-based pharmaceutical agents are also associated with multiple adverse effects. This has led to the concept of designing noncarbohydrate, aromatic mimetics that modulate H/HS function. In this work, we study a library of synthetic, aromatic H/HS mimetics for their capillary electrophoretic profiles, the acid and base stability, and aqueous-organic partitioning property. The nonsugar H/HS mimetics exhibit electrophoretic properties similar to sulfated oligosaccharides suggesting that the mimetics can be rapidly and quantitatively analyzed. Stability studies show that the mimetics are essentially stable under neutral and basic conditions in a manner similar to the heparins, but are considerably unstable under acidic conditions in contrast to heparins. The measurement of partition coefficients show major differences within the sulfated mimetics as well as between the measured and calculated log P values. Understanding these physico-chemical properties is expected to have significant implications in the pharmaceutical development of this growing class of molecules.

Targeting the GPIbα binding site of thrombin to simultaneously induce dual anticoagulant and antiplatelet effects.

Exosite 2 of human thrombin contributes to two opposing pathways, the anticoagulant pathway and the platelet aggregation pathway. We reasoned that an exosite 2 directed allosteric thrombin inhibitor should simultaneously induce anticoagulant and antiplatelet effects. To assess this, we synthesized SbO4L based on the sulfated tyrosine-containing sequence of GPIbα. SbO4L was synthesized in three simple steps in high yield and found to be a highly selective, direct inhibitor of thrombin. Michelis–Menten kinetic studies indicated a noncompetitive mechanism of inhibition. Competitive inhibition studies suggested ideal competition with heparin and glycoprotein Ibα, as predicted. Studies with site-directed mutants of thrombin indicated that SbO4L binds to Arg233, Lys235, and Lys236 of exosite 2. SbO4L prevented thrombin-mediated platelet activation and aggregation as expected on the basis of competition with GPIbα. SbO4L presents a novel paradigm of simultaneous dual anticoagulant and antiplatelet effects achieved through the GPIbα binding site of thrombin.

Dynamic affinity chromatography in the separation of sulfated lignins binding to thrombin

Sulfated low molecular weight lignins (LMWLs), a mixture of chemo-enzymatically prepared oligomers, have been found to be potent antagonists of coagulation. However, structures that induce anticoagulation remain unidentified. The highly polar sulfate groups on these molecules and the thousands of different structures present in these mixtures make traditional chromatographic resolution of sulfated LMWLs difficult. We performed dynamic thrombin affinity chromatography monitored using chromogenic substrate hydrolysis assay to isolate sulfated LMWL fractions that differed significantly in their biophysical and biochemical properties. Three fractions, I(35), I(55) and Peak II, were isolated from the starting complex mixture. Independent plasma clotting assays suggested that I(35) possessed good anticoagulation potential (APTT=4.2μM; PT=6.8μM), while I(55) and Peak II were approximately 10- and 100-fold less potent. The ESI-MS spectrum of this oligomeric fraction showed multiple peaks at 684.8, 610.6, 557.4, 541.4, 536.5, and 519.4m/z, which most probably arise from variably functionalized β-O4β-β-linked trimers and/or a β-O4β-O4-linked dimers. The first direct observation of these structures in sulfated LMWLs will greatly assist in the discovery of more potent sulfated LMWL-based anticoagulants.