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Protamine is administered as protamine sulfate to reverse the anticoagulant effect of heparin following cardiopulmonary bypass surgery. Immunogenicity of protamine has been recognized for decades in several patient groups including vasectomized men, diabetic patients on protamine-containing insulin and patients undergoing cardiopulmonary bypass surgery. Anti-protamine/heparin antibodies are a newly described class of heparin-dependent antibodies found in about 30% of patients exposed to protamine and heparin during cardiac surgery. A subset of seropositive patients especially who tested positive for platelet-activating anti-protamine/heparin immunoglobulin G (IgG) antibodies before surgery have prolonged postoperative thrombocytopenia with an increased risk for arterial occlusions. Studies presented in this thesis shed light on potential approaches that may prevent antibody-mediated platelet activation by anti-protamine/heparin antibodies. Two approaches are presented in this thesis, partially desulfated heparin (ODSH) and low molecular weight protamine (LMWP). Our studies demonstrated the ability of ODSH to inhibit anti-protamine/heparin antibody-mediated platelet destruction in the NOD/SCID mouse model by: i) reduction of antibody binding to preformed protamine/heparin complexes, as shown by enzyme immunoassay, ii) interfering with the binding of protamine/heparin complexes to platelets as shown by flow cytometry and fluorescence microscopy, and iii) inhibition of antibody-mediated platelet activation. Interestingly, ODSH was also able to block ongoing platelet destruction by displacing pre-bound complexes from the platelet surface. In addition, our data suggest the use of synthesized LMWP as a substitute for protamine in heparin reversal. The in vitro investigations showed that synthesized LMWP efficiently neutralizes heparin using the activated partial thromboplastin time. Anti-protamine/heparin antibodies have low binding properties to LMWP/heparin complexes as indicated in enzyme immunoassay. The ability of platelet-activating anti-protamine/heparin antibodies to induce platelet activation in the functional assay was significantly reduced in the presence of LMWP/heparin compared to protamine/heparin complexes. Owing to findings obtained in our studies, both approaches might be a promising future option to reduce anti-protamine/heparin antibody-mediated adverse effects.
The central aim of this thesis was the investigation of protein/polyanion interaction using circular dichroism (CD) spectroscopy, enzyme immune assay (EIA), isothermal titration calorimetry (ITC) and flow cytometry (FC). A further aim was to understand why an endogenous protein becomes immuno-genic when forming a complex. The focus was on the protein platelet factor (PF4), which gained wide interest in the clinical field, due to its role in the life-threatening, immune-driven, adverse drug effect heparin-induced thrombocytopenia (HIT). PF4 is a small homotetrameric chemokine with several basic amino acids on its surface, forming a positively charged ring. The antibodies that are formed during HIT recognize an epitope exposed on PF4, when it is in a complex with heparin at a certain molar ratio at which, PF4 tetramers are aligned on the heparin and forced into close approximation. The main results and conclusions of the thesis are summarized below: 5.1 Evolutionary Conservation of PF4 (Paper I – PF4/Evolution) By carrying out an amino acid sequence survey we found that the positively charged amino acids contributing to the heparin binding site on the surface of PF4 and related proteins are highly conserved in all vertebrates, including fish species. PF4 interacts with the phospholipid lipid A, the innermost part of the lipopolysaccharide (LPS) of Gram negative bacteria. We showed that the shorter the sugar chain of the O antigen, outer and inner core of the LPS were the more PF4 was binding. The interaction of PF4 with lipid A is inhibited by heparin, suggesting that the amino acids known to contribute to heparin binding are also involved in binding to lipid A. 5.2 PF4 Interaction with Polyanions (PA) of varying Length and Degree of Sulfation (Paper II – PF4/PA) CD spectroscopy was found to be a powerful technique to monitor structural changes of PF4 caused by binding to various clinically relevant polyanions. Therefore PF4 was titrated with different PA to investigate the dependencies: i. impact of the PF4:PA molar ratio, ii. degree of polymerization of the PA and iii. degree of sulfation of the PA. In all cases, exposure of HIT-relevant epitope(s) was only observed for PA that also induced changes in secondary structure of PF4. A comparison of results of an immune ¬assay with CD spectroscopic data showed that the extent of complex anti¬genicity correlates well with the magnitude of changes in PF4 secondary structure, and that the structural changes of PF4 have to exceed a certain threshold to achieve PF4/PA complex antigenicity. These findings allowed us to calculate expectation intervals for complex antigenicity solely using CD spectroscopic data. To our knowledge, this was the first demonstration that the capability of drugs to induce antigenicity of PF4 can be assessed without the necessity of in vivo studies or the use of antibodies obtained from immunized patients specific for the antigens. The antigenicity of PF4 in complex is not restricted to negative charges originating from sulfate groups, PA with phosphate groups are also capable (binding to phospholipids). We investigated inorganic polyphosphates (polyP) with a chain length of 75 Pi and showed that the induced secondary structural changes are even higher compared to the changes induced by the different heparins and that the PF4/P75 complexes are antigenic as well. 5.3 PF4 Interaction with defined oligomeric Heparins (Paper III – PF4/defined Heparins) We tested highly purified, monodisperse heparins. In contrast to the clinically relevant but relatively undefined (high polydispersity index) glycosamino glycans reported in paper II (PF4/PA). The defined heparins induced higher secondary structural changes. Here we showed for the first time that strong conformational changes during PF4/PA complex formation are necessary but not sufficient for to the expression of the anti-PF4/heparin antibody binding site. Also, the size of the complexes is not the only prerequisite for anti-PF4/heparin antibody binding (tested by atomic force microscopy). By ITC we found that antigenicity is only induced if the PF4/PA complex has a high binding enthalpy and the complex formation leads to a negative change in entropy. 5.4 PF4/Polyphosphates (polyP) Complex Antigenicity and Interaction with Escherichia coli (E. coli, Paper IV – PF4/polyP) PolyP with chain lengths of 45 Pi and 75 Pi induced remarkable secondary structural changes in the PF4 molecule, thereby exposing the epitope recognized by anti-PF4/heparin antibodies. The induced conformational changes were similar to the changes induced by the defined heparins. Again a high binding enthalpy was observed but here in connection with a positive change in entropy. Further we showed that polyP (≥45 Pi) enhance PF4 binding to the surface of Gram negative E. coli at intermediate concentration and disrupt the binding at elevated polyP concentrations. The increased amounts of PF4 on the bacterial surface also improved the binding of anti-PF4/heparin antibodies and thereby the phagocytosis of the bacteria by poly¬morpho¬nuclear leucocytes. 5.5 Nucleic acid based Aptamers induce structural Changes in the PF4 Molecule (Paper V – PF4/Aptamer) Nucleic acids are another class of molecules containing phosphate groups. Especially after cell damage their extra¬cellular concentration can be locally quite high (>2 mg/ml). We found that certain aptamers form complexes with PF4 and thereby inducing anti-PF4/aptamer antibodies which cross-react with PF4/heparin complexes. Moreover by CD spectroscopy we showed that the protein C-aptamer caused similar secondary structural changes of PF4 like heparin, but already at much lower concentration. The maximally induced changes by the protein-C aptamer were even higher and persisted over a broader concentration range. 5.6 Protamine Interaction with Heparin (Paper VI – PS/Heparin) After the intensive investigation of the complex formation between PF4 and many different classes of PA we assessed another protein for structural changes upon complex formation with heparin. Protamine (PS) a protein in routinely used in post-cardiac surgery to reverse the anticoagulant effects of heparin was found to unfold but not to refold with increasing concentration of PA in solution. 5.7 Conclusion and Outlook When starting this thesis, it was believed that repetitive structures formed by PF4 on a heparin chain mold the epitope recognized by antibodies inducing HIT. These repetitive structures might exhibit similarities with viral capsids and are therefore recognized by the immune system of some patients. We found that induced by the close approximation PF4 changes its conformation, thereby exposing a neoepitope. The conserved positively charged amino acids of the heparin binding site and the involvement of these amino acids in the binding to lipid A confirm our hypothesis of PF4 as part of an ancient immune-mediated host defense mechanism. As possible consequence of the “primitive mechanism of defense” the highly variable O-antigens of LPS might have significantly contributed to an efficient escape mechanism by hiding the structures that made the bacteria vulnerable. In turn polyP might be an adaption of the host improve pathogen recognition by PF4 and further by antibodies inducing phagocytosis of the PF4-marked objects. Although shown only for PF4 and PS, our findings might be applicable to other proteins that also express epitopes upon changes in their secondary structure. Our physicochemical methods may further be applied: i. to drug development for the prediction of antigenicity induced by polyanionic drugs, ii. to guide the development of synthetic heparins and other polyanion based drugs, e.g. aptamers, that do not lead to HIT and iii. to provide relevant aspects for other biological functions of heparins.
Heparin is an anticoagulant drug. It is important in the treatment of deep vein thrombosis,pulmonary embolism and during surgeries. Heparin-induced thrombocytopenia (HIT) is a severe adverse reaction caused by the formation of ultralarge complexes of platelet factor 4 (PF4) with unfractionated heparin (UFH). It can lead to limb loss or fatal events like stroke, myocardial infarction or pulmonary embolism. HIT has an incidence of about 3% in patients receiving anticoagulative heparin treatment. PF4 is a tetrameric protein, released from the α-granules of platelets upon activation. PF4 is known to form antigenic complexes with UFH accompanied by structural changes of PF4. In this thesis, the size and size distribution of PF4 and PF4/heparin complexes were analyzed using asymmetrical flow field-flow-fractionation (AF4), photon correlation spectroscopy (PCS) and atomic force microscopy (AFM). PF4 tends to form auto-aggregates and to adsorb to different surfaces, including regenerated cellulose, polyethersulfone, quartz and glass. The aggregates are less pronounced in solutions at isotonic NaCl concentration. Arginine and Tween 20 were identified as possible ingredients to hinder the auto-aggregation of PF4. Also, it is shown by combining circular dichroism (CD) spectroscopy, atomic force microscopy (AFM) and isothermal titration calorimetry (ITC) with UFH and defined chain length (16-, 8-, 6-, 5-mer) heparins that structural changes (i.e., increase in β-sheets) alone are not sufficient to induce antigenicity. While UFH, 16-, 8-, and 6-mer heparins all induced an increase in the antiparallel β-sheet content to > 30% (as determined by CD spectroscopy), complex antigenicity as measured by anti-PF4/heparin antibody binding in an enzyme-linked immunosorbent assay (EIA) was only induced by UFH and 16-mer heparin. Fondaparinux (5-mer heparin), which forms in vitro non-antigenic complexes with PF4, did not induce structural changes of PF4. Interestingly, the structural changes induced by antigenic UFH and 16-mer heparin but not by non-antigenic shorter heparins were reversible at higher heparin concentrations. Furthermore, the complexes formed by PF4 with longer heparins were larger than those formed with shorter heparins as shown by atomic force microscopy (AFM). UFH, HO16 and HO08 are able to form ultralarge multimolecular complexes with PF4. ITC data indicated strong electrostatic interactions and energetically unfavorable conformational changes of PF4 with longer heparins, while for the short heparins, favorable conformational changes in the structure of PF4 are induced. This explains the reversibility of the structural changes seen for UFH and HO16 upon addition of an over-saturating amount of heparin. Finally, using differential scanning calorimetry (DSC) the thermal stability of PF4 and PF4/heparin complexes was assessed. Despite its tendency to form auto-aggregates, PF4 is a heat-stable protein. This stability is, length dependently, even increased in complex with heparins. This work shows important differences in the binding between PF4 and heparins of different chain length and might be relevant for the understanding of other biological functions of heparins (e.g., involvement in allergic and inflammatory reactions).