key: cord-0772594-q32bju25 authors: Battinelli, Elisabeth M. title: COVID-19 concerns aggregate around platelets date: 2020-09-10 journal: Blood DOI: 10.1182/blood.2020007805 sha: 67181332cc6c061c43d556abcb11d8c20b01ffe5 doc_id: 772594 cord_uid: q32bju25 In this issue of Blood, articles by Manne et al and Hottz et al highlight platelet hyperactivity in COVID-19–associated pathophysiology.(1,2) Although the hallmarks of COVID-19 include a brisk inflammatory response and respiratory symptoms, the hematologic manifestations of this infection have also garnered attention, with thrombotic complications taking center stage.(3,4) COVID-19–associated coagulopathy has been characterized by an elevated D-dimer, mild thrombocytopenia, and a prolongation of the activated partial thromboplastin time.(5) Alongside these laboratory abnormalities, patients present with increased rates of thrombosis.(6) The role of platelets in the thrombotic complications of COVID-19 is explored in these 2 articles, establishing that platelet hyperactivity contributes to the coagulopathy seen in COVID-19. LSPCs to nonapoptotic, iron-dependent cell death via ferroptosis. Indeed, ferroptosis inhibition functionally rescued Aldh3A2 loss. Conversely, genetic and pharmacologic inhibition of ferroptosis inhibitory glutathione peroxidase 4 (GPX4) and cytotoxic therapy triggered increased elimination of Aldh3a2-deficient LSPCs and extended AML-free survival in vivo compared with aberrant stem cells expressing the detoxifying enzyme. This finding provides further evidence that AML relies on increased metabolic plasticity, particularly enhanced FA metabolism, for desensitizing leukemic clones to cell death 9 ; it also underscores that distinct metabolic adaptations are likely at play in LSPCs and AML blast cells as suggested by Jordan and colleagues. 10 Future studies are needed to continue identifying LSPC-specific metabolic adaptations and vulnerabilities, particularly in the context of therapeutic interventions for AML. It will also be of critical importance to gain insights into the role of metabolic dependencies in pre-LSPCs, as they are not only the cellular source of primary disease initiation, but they provide a pool of highly transformation-susceptible cells during antileukemic therapy. 3 -associated coagulopathy has been characterized by an elevated D-dimer, mild thrombocytopenia, and a prolongation of the activated partial thromboplastin time. 5 Alongside these laboratory abnormalities, patients present with increased rates of thrombosis. 6 The role of platelets in the thrombotic complications of COVID-19 is explored in these 2 articles, establishing that platelet hyperactivity contributes to the coagulopathy seen in COVID-19. Mounting evidence has demonstrated the far-reaching influence of the platelet beyond mediating hemostasis. Platelets are increasingly recognized as key players in facilitating inflammation. The importance of the platelet in viral infectionmediated thrombosis has been established previously. 7 Endothelial damage, a cornerstone of COVID-19 disease, releases key platelet agonists that send platelets into overdrive. 8 Inflammation may be exacerbated in patients with hypertension, cardiovascular disease, and obesity, all of which are associated with baseline platelet hyperreactivity. 9 Interestingly, studies have shown that patients with these underlying comorbidities suffer more severe COVID-19 complications and have a worse outcome. 10 Understanding the role of the platelet in COVID-19 remains elusive. Because the platelet itself does not express the receptor for SARS-CoV-2 binding (ACE2), more remains to be understood about how the virus interacts with platelets and impacts their function. Propelling the platelet further into the spotlight has been recent evidence demonstrating that megakaryocytes, the precursor cells of the platelet, are present in pulmonary and cardiac tissue from autopsies of patients who have succumbed to COVID-19. 11 It remains unclear whether these megakaryocytes in satellite locations contribute to platelet production. Surprisingly, although COVID-19 is associated with severe inflammation, reactive thrombocytosis has not been demonstrated in infected patients. On the contrary, a mild thrombocytopenia is often present, and a decrease in platelet count has been associated with a poor prognosis. 12 In the first of 2 linked articles, Manne and colleagues demonstrate changes in platelet gene expression and function in COVID-19 patients. 1 Using platelet RNA sequencing, the investigators profile gene expression in the platelets of COVID-19 patients and find altered gene expression profiles in pathways associated with ubiquitination, antigen presentation, and mitochondrial dysfunction. Patients with COVID-19 have higher levels of platelet activation at rest and increased interactions with neutrophils, monocytes, and T cells compared with healthy donors (see figure) . Platelet functionality studies demonstrate hyperactivity, as evidenced by increased aggregation, spreading on fibrinogen and collagen through upregulation of the MAPK pathway, and increased thromboxane generation. Therefore, the investigators extrapolate that hyperactivity of platelets plays a role in the immunemediated thrombotic manifestations seen in patients with COVID-19. What remains to be determined is whether these platelet gene transcript differences and enhanced platelet functionality are uniquely associated with exposure to COVID-19 or whether other similarly inflammatory conditions also reveal comparable changes. Comparisons with other viral illnesses associated with acute respiratory distress syndrome would be helpful in identifying the exclusivity of these platelet manifestations in COVID-19. In the second article, Hottz and colleagues again demonstrate that COVID-19 is associated with increased platelet activation. They show that the platelets of critically ill COVID-19 intensive care unit (ICU) patients exhibit increased platelet aggregation and platelet-monocyte aggregation compared with patients with mild COVID-19 infection (see figure) . These findings are associated with the characteristic coagulation laboratory changes found in patients with COVID-19, including elevated fibrinogen and D-dimer. Further, these changes correlate with a worse outcome, with increased need for invasive mechanical ventilation and increased mortality in those with hyperactive platelets. In this study, changes in platelet activation were associated with increased platelet expression of P-selectin and CD63 in patients with more severe disease in comparison with those with mild manifestations. Platelets from patients with severe COVID-19 infection induce monocytederived tissue factor (TF) expression that is diminished by pretreating COVID-19 patient platelets with an anti-P-selectin neutralizing antibody or the clinically approved anti-aIIb/b3 monoclonal antibody, abciximab. Together, these findings again demonstrate the role of the platelet in COVID-19, linking changes in platelet activation and platelet-dependent monocyte TF expression with disease severity and mortality. Linking platelet-mediated monocyte TF expression to unbridled coagulation and thrombosis remains to be determined. Although both of these articles clearly demonstrate differences in platelets and platelet function in patients with COVID-19, a well-defined connection between platelet hyperactivity and the coagulopathy seen in COVID-19 patients has not been confirmed. Dedicated studies comparing platelet function testing in COVID-19 patients with and without thrombosis have not been performed. Because platelets are already known to be hyperreactive in the setting of inflammation, linking platelet abnormalities directly to thrombotic risk is key to understanding whether the platelet is merely a bystander in the inflammatory milieu or a key pathological regulator of thrombosis in COVID-19. In developed countries, blood centers protect the safety of the blood supply by deferring high-risk donors and screening all donations for HIV and other pathogens using exquisitely sensitive and specific assays. This multilayered approach has been highly successful. In the United States and many other countries, the per-unit risk of HIV transfusiontransmission is ,1 per million. 3 However, policy changes can have unintended consequences. Grebe et al decided to examine whether the switch in the United States from an indefinite deferral to a 12-month deferral led to an increase in higher-risk individuals donating blood and a corresponding increase in the risk of transfusion-transmitted HIV. Using data from several US blood centers, the investigators measured the HIV incidence in first-time blood donors before and after the switch to a 12-month MSM deferral. The incidence of HIV in first-time donors was 2.62/10 5 person-years at baseline and 2.85/10 5 person-years after the 12-month deferral was implemented Aldehyde dehydrogenase 3a2 protects AML cells from oxidative death and the synthetic lethality of ferroptosis inducers Clonal development, stem-cell differentiation, and clinical remissions in acute nonlymphocytic leukemia A new coronavirus associated with human respiratory disease in China COVID-19 and its implications for thrombosis and anticoagulation Abnormal coagulation parameters are associated with poor prognosis in patients with novel coronavirus pneumonia Incidence of venous thromboembolism in hospitalized patients with COVID-19 Platelets and immunity: going viral COVID-19: the vasculature unleashed The metabolic syndrome as a risk factor for venous and arterial thrombosis Clinical characteristics of hospitalized individuals dying with COVID-19 by age group in Italy Megakaryocytes and platelet-fibrin thrombi characterize multi-organ thrombosis at autopsy in COVID-19 Thrombocytopenia and its association with mortality in patients with COVID-19