Implication of inflammation on Coxsackie virus and Adenovirus receptor expression on cardiomyocytes and the role of platelets in patients with dilated cardiomyopathy.

BACKGROUND: Coxsackie Virus and Adenovirus Receptor (CXADR or CAR) is involved in the pathogenesis of inflammatory dilated cardiomyopathy (DCM). We aimed to examine the relationship of CAR expression on platelets and cardiomyocytes with virus persistence, local and systemic inflammation and platelet activity in patients with DCM. METHODS: Endomyocardial biopsy (EMB) samples of 38 patients (mean age 39.5±11.3 years, 20 male) with DCM were analyzed for CAR expression, local inflammation grade by immunohistochemistry and virus persistence by real-time PCR. Platelet morphology was analyzed in all patients and 30 healthy subjects (HS) using scanning electron microscopy, platelet activity by light transmission aggregation, and CAR persistence by immunofluorescence. Platelets of 20 patients were analyzed for cytomegalovirus and herpes simplex virus 1-2 by immunofluorescence. Serum levels of tumor necrosis factor alpha (TNF α) and Interleukin-6 were assessed using ELISA in all studied subjects. RESULTS: CAR expression in EMB samples was related to the heart failure functional class and the level of IL-6. Platelets from DCM patients showed enhanced spontaneous and ADP induced aggregation. Platelets' CAR expression was >4 fold higher in DCM than HS and was observed predominantly at sites of intercellular communications in microaggregates and leukocyte-platelet aggregates. CAR-positive patients showed significantly higher TNF-α and IL-6 serum levels in CAR-negative patients. Platelets of 6 (30%) DCM patients revealed the mature cytomegalovirus and herpes simplex viruses particles. CONCLUSION: Tight junction protein CAR may serve as a docking pin creating a new type of contact structure that could be responsible for signaling between neighboring cells in pathological conditions.

To clot or not to clot? Ad is the question-Insights on mechanisms related to vaccine-induced thrombotic thrombocytopenia.

Vaccine-induced immune thrombotic thrombocytopenia (VITT) has caused global concern. VITT is characterized by thrombosis and thrombocytopenia following COVID-19 vaccinations with the AstraZeneca ChAdOx1 nCov-19 and the Janssen Ad26.COV2.S vaccines. Patients present with thrombosis, severe thrombocytopenia developing 5-24 days following first dose of vaccine, with elevated D-dimer, and PF4 antibodies, signifying platelet activation. As of June 1, 2021, more than 1.93 billion COVID-19 vaccine doses had been administered worldwide. Currently, 467 VITT cases (0.000024%) have been reported across the UK, Europe, Canada, and Australia. Guidance on diagnosis and management of VITT has been reported but the pathogenic mechanism is yet to be fully elucidated. Here, we propose and discuss potential mechanisms in relation to adenovirus induction of VITT. We provide insights and clues into areas warranting investigation into the mechanistic basis of VITT, highlighting the unanswered questions. Further research is required to help solidify a pathogenic model for this condition.

Platelet-adenovirus vs. inert particles interaction: effect on aggregation and the role of platelet membrane receptors.

Platelets are involved in host defense via clearance of bacteria from the circulation, interaction with virus particles, and uptake of various size particulates. There is a growing interest in micro- and nanoparticles for drug delivery and there is evidence that the properties of these particles critically influence their interaction and uptake by various tissues and cells including platelets. Virus mediated gene therapy applications are still challenged by the resultant thrombocytopenia and the mechanism(s) of platelet-foreign particles interaction remains unclear. We studied the specifics of platelet interaction with an active biological agent (adenovirus) and inert latex microspheres (MS) and investigated the role of platelet proteins in this interaction. We show that activated and not resting platelets internalize MS, without influencing platelet aggregation. In contrast, adenovirus induces and potentiates ADP-induced platelet aggregation and results in rapid expression of P-selectin. Platelets then internalize adenovirus and viral particles appear inside the open canalicular system. Inhibition of platelet αIIbß3, GPIbα, and P-selectin decreases both platelet aggregation and internalization of MS. Inhibition of αIIbß3 and αVß3 does not abolish adenovirus platelet internalization and adenovirus-induced platelet activation is maintained. Our study demonstrates that platelets react differentially with foreign particles and that αIIbß3 is a key player in platelet engulfing of foreign particles but not in mediating adenovirus internalization. Other platelet candidate molecules remain to be investigated as potential targets for management of adenovirus-induced thrombocytopenia.

Human platelets express CAR with localization at the sites of intercellular interaction.

Adenovirus has a wide tissue tropism. The virus attaches to the surface of cells via the fiber protein knob binding to the Coxsackie and Adenovirus receptor known as CAR. Virus entry inside cells is facilitated by integrins αVß3 and αVß5. Mice platelets are shown to be the predominant Ad binding blood cell type and the virus is documented inside platelets. CAR was identified on human platelets in one study yet contradicted in another. The presence of CAR appears to be the most reasonable initial step for virus entry into platelets and is a key to the understanding of platelet adenovirus interaction. This study aimed to re investigate the presence of CAR on human platelets. Platelets were tested by indirect immune-fluorescence using rabbit H-300 polyclonal anti-CAR antibody and goat anti-rabbit IgG F(ab')2 Texas Red antibodies, alongside with CAR positive and negative controls. Platelets were found to express CAR on their surface and in contrast to the previous study only 3.5 ± 1.9% of the tested platelets did express CAR. In addition, CAR was seen within intracellular aggregates localized at the sites of cell-cell contacts indicating that CAR expression might be upregulated in response to platelet stimulation. We confirm the presence of CAR on human platelets, we provide explanation to some of the discrepancies in this regards and we add that this receptor is localized at the sites of intercellular interaction.