Platelets are central mediators of thrombosis and hemostasis. At the site of vascular injury, platelet accumulation (i.e. adhesion and aggregation) constitutes the first wave of hemostasis. Blood coagulation, initiated by the coagulation cascades, is the second wave of thrombin generation and enhance phosphatidylserine exposure, can markedly potentiate cell-based thrombin generation and enhance blood coagulation. Recently, deposition of plasma fibronectin and other proteins onto the injured vessel wall has been identified as a new “protein wave of hemostasis” that occurs prior to platelet accumulation (i.e. the classical first wave of hemostasis). These three waves of hemostasis, in the event of atherosclerotic plaque rupture, may turn pathogenic, and cause uncontrolled vessel occlusion and thrombotic disorders (e.g. heart attack and stroke). Current anti-platelet therapies have significantly reduced cardiovascular mortality, however, on-treatment thrombotic events, thrombocytopenia, and bleeding complications are still major concerns that continue to motivate innovation and drive therapeutic advances. Emerging evidence has brought platelet adhesion molecules back into the spotlight as targets for the development of novel anti-thrombotic agents. These potential antiplatelet targets mainly include the platelet receptors glycoprotein (GP) Ib-IX-V complex, β3 integrins (αIIb subunit and PSI domain of β3 subunit) and GPVI. Numerous efforts have been made aiming to balance the efficacy of inhibiting thrombosis without compromising hemostasis. This mini-review will update the mechanisms of thrombosis and the current state of antiplatelet therapies, and will focus on platelet adhesion molecules and the novel anti-thrombotic therapies that target them.
Integrins are a large family of heterodimeric transmembrane receptors differentially expressed on almost all metazoan cells. Integrin β subunits contain a highly conserved plexin-semaphorin-integrin (PSI) domain. The CXXC motif, the active site of the protein-disulfide-isomerase (PDI) family, is expressed twice in this domain of all integrins across species. However, the role of the PSI domain in integrins and whether it contains thiol-isomerase activity have not been explored. Here, recombinant PSI domains of murine β3, and human β1 and β2 integrins were generated and their PDI-like activity was demonstrated by refolding of reduced/denatured RNase. We identified that both CXXC motifs of β3 integrin PSI domain are required to maintain its optimal PDI-like activity. Cysteine substitutions (C13A and C26A) of the CXXC motifs also significantly decreased the PDI-like activity of full-length human recombinant β3 subunit. We further developed mouse anti-mouse β3 PSI domain monoclonal antibodies (mAbs) that cross-react with human and other species. These mAbs inhibited αIIbβ3 PDI-like activity and its fibrinogen binding. Using single-molecular Biomembrane-Force-Probe assays, we demonstrated that inhibition of αIIbβ3 endogenous PDI-like activity reduced αIIbβ3-fibrinogen interaction, and these anti-PSI mAbs inhibited fibrinogen binding via different levels of both PDI-like activity-dependent and -independent mechanisms. Importantly, these mAbs inhibited murine/human platelet aggregation in vitro and ex vivo, and murine thrombus formation in vivo, without significantly affecting bleeding time or platelet count. Thus, the PSI domain is a potential regulator of integrin activation and a novel target for antithrombotic therapies. These findings may have broad implications for all integrin functions, and cell-cell and cell-matrix interactions.
: Platelets are small blood cells known primarily for their ability to adhere and aggregate at injured vessels to arrest bleeding. However, when triggered under pathological conditions, the same adaptive mechanism of platelet adhesion and aggregation may cause thrombosis, a primary cause of heart attack and stroke. Over recent decades, research has made considerable progress in uncovering the intricate and dynamic interactions that regulate these processes. Integrins are heterodimeric cell surface receptors expressed on all metazoan cells that facilitate cell adhesion, movement, and signaling, to drive biological and pathological processes such as thrombosis and hemostasis. Recently, our group discovered that the plexinsemaphorin-integrin (PSI) domains of the integrin β subunits exert endogenous thiol isomerase activity derived from their two highly conserved CXXC active site motifs. Given the importance of redox reactions in integrin activation and its location in the knee region, this PSI domain activity may be critically involved in facilitating the interconversions between integrin conformations. Our monoclonal antibodies against the β3 PSI domain inhibited its thiol isomerase activity and proportionally attenuated fibrinogen binding and platelet aggregation. Notably, these antibodies inhibited thrombosis without significantly impairing hemostasis or causing platelet clearance. In this review, we will update mechanisms of thrombosis and hemostasis including platelet versatilities and immune-mediated thrombocytopenia, discuss critical contributions of the newly discovered PSI domain thiol isomerase activity, and its potential as a novel target for anti-thrombotic therapies and beyond.
Introduction Clinical trials, although academically accepted as the most effective treatment available for cancer patients, poor accrual to clinical trials remains a significant problem. A clinical trials navigator (CTN) program was piloted where patients and/or their healthcare professionals could request a search and provide a list of potential cancer clinical trials in which a patient may be eligible based on their current status and disease. Objectives This study examined the outcomes of a pilot program to try to improve clinical trials accrual with a focus on patients at medium to small sized cancer programs. Outcomes examined included patient disposition (referral to and accrual to interventional trials), patient survival, sites of referral to the CTN program. Methods One 0.5 FTE navigator was retained. Stakeholders referred to the CTN through the Canadian Cancer Clinical Trials Network. Demographic and outcomes data were recorded. Results Between March 2019 and February 2020, 118 patients from across Canada used the program. Seven per cent of patients referred were enrolled onto treatment clinical trials. No available trial excluded 39% patients, and 28% had a decline in their health and died before they could be referred or enrolled onto a clinical trial. The median time from referral to death was 109 days in those that passed. Conclusion This novel navigator pilot has the potential to increase patient accrual to clinical trials. The CTN program services the gap in the clinical trials system, helping patients in medium and small sized cancer centres identify potential clinical trials at larger centres.
We report a case of pure white cell aplasia (PWCA) postthymoma resection in a 74-year-old male presenting with a 2-week history of fevers, night sweats, and severe febrile neutropenia. His pure white cell aplasia was treated with intravenous immunoglobulin (IVIg), granulocyte colony-stimulating factor (G-CSF), prednisone, and cyclosporine with a mixed response. He also developed immune thrombocytopenia, which responded well to a short course of eltrombopag. With continued cyclosporine treatment, his platelet counts were stable after stopping eltrombopag. The patient's cyclosporine treatment was complicated by renal failure, resulting in cessation of cyclosporine. His PWCA and immune thrombocytopenia significantly worsened after stopping cyclosporine, and unfortunately, he died from multiorgan failure and sepsis.
Integrin αIIbβ3 plays key roles in thrombosis and hemostasis primarily through mediating platelet adhesion and aggregation. We recently reported that the active site of thiol-isomerase enzymes, CXXC motif, is expressed twice within the plexin-semaphorin-integrin (PSI) domain across all integrins and species, and the PSI domain of β3 integrin possesses endogenous thiol-isomerase activity, which may be a novel target for anti-thrombotic therapy (Blood, 2017). We developed four mouse anti-mouse β3 integrin PSI domain monoclonal antibodies (mAbs). These mAbs cross-react with β3 PSI domains of human, mouse, pig, rat, and rabbit tested but not other regions of β3 integrin, other integrins or other thiol-isomerase enzymes. They inhibit the thiol-isomerase activity of β3 PSI domain, decrease platelet adhesion/aggregation and thrombosis without increasing bleeding. Interestingly, the inhibitory effect of these mAbs on thrombosis in vivo (no anti-coagulant) was 10-20 times greater than their inhibitory effect on platelet aggregation in anti-coagulated platelet-rich plasma in vitro. This motivated us to explore whether this PSI domain contributes to blood coagulation. To asses blood clot formation and retraction, blood was incubated in non-stick tubes for two hours at 37°C in clot retraction assays. These assays showed less clot retraction and significantly lower dry clot weight in human and mouse whole blood treated with these anti-PSI mAbs compared to controls (p<0.05). As a visual representation, laser scanning confocal microscopy of platelet-rich plasma samples with labelled fibrinogen/fibrin showed that fibrin network formation of anti-PSI mAb treated clots was decreased. To measure blood coagulation in a global assay in the presence of platelets and natural blood constituents, thromboelastography (TEG) was performed. Blinded TEG showed that anti-PSI mAb-treated whole blood (human and mouse) and platelet rich plasma (human) decreased in coagulation compared to controls (p<0.05). We further compared our anti-PSI mAbs with other anti-β3 integrin mAbs that inhibit αIIbβ3 ligand binding and platelet aggregation much stronger than the anti-PSI mAbs. In this TEG assay we found that the anti-PSI mAbs were still significantly decreasing platelet coagulation parameters, much more than other inhibitory anti-β3 mAbs including M1 and JAN D1 as well as the Abciximab precursor 7E3 (p<0.05). This suggests the decreased coagulation may result from the anti-thiol-isomerase activity of the anti-PSI mAbs. Disulfide bond exchanges are required for blood coagulation and thiol-isomerase enzymes play important roles in thrombosis. Given that blood coagulation is rapidly amplified on the platelet surface (i.e. cell-based coagulation), many coagulation factors are in close proximity to β3 integrin PSI domains (with thiol-isomerase activity). The study of interaction between β3 PSI domain and coagulation factors is currently being exploring. This is the first evidence of an allosteric therapeutic target of β3 integrin. This work suggests that a novel interaction exists between platelets and the coagulation cascade that requires the β3 integrin PSI domain and its thiol-isomerase activity. Importantly, the PSI domain can be targeted to partially block both platelet aggregation and coagulation, resulting in less bleeding while still providing a strong overall anti-thrombotic effect. Disclosures No relevant conflicts of interest to declare.
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