Potential role of endothelial cell surface ectopic redox complexes in COVID-19 disease pathogenesis
ABSTRACT
The novel coronavirus infectious disease (COVID-19) has rapidly spread and poses a great challenge to researchers, both in elucidating its pathogenic mechanism and developing effective treatments. It has been recently proposed that COVID-19 is an endothelial disease. Indeed, the COVID-19 virus binds to angiotensin-converting enzyme type 2 (ACE2), which is expressed in endothelial cells. ACE2 could be implicated in the production of reactive oxygen species (ROS) caused by endothelial dysfunction due to viral damage. Consequently, oxidative stress could prime these cells to acquire a pro-thrombotic and pro-inflammatory phenotype, predisposing patients to thromboembolic and vasculitic events and to disseminated intravascular coagulopathy (DIC). This implies a pivotal role played by oxygen in the pathogenetic mechanism of COVID-19 disease, in that its availability would tune the oxidant state and consequent damage.
The role of the endothelium in COVID-19
Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) emerged at the end of 2019 as a new type of highly pathogenic coronavirus of still unclear biological aetiology that rapidly spread around the world. Now COVID-19 illness is recognised as a global epidemic,1 bearing an alarming mortality index and necessitating extensive control measures. However, due to the novelty of this disease in humans, and the lack of definitive clinical, instrumental and autoptic data, the pathogenic mechanisms of COVID-19 disease have not been fully elucidated.
It is clear that COVID-19 is not simply an interstitial pneumonia, because evidence points to its being a systemic thrombotic and thrombo-embolic syndrome affecting both the venous and arterial circulations.2 Many patients display clinical manifestations of shock and symptoms of microcirculation dysfunction. Death often occurs due to thromboembolism, multiple organ failure (MOF) and sepsis associated with disseminated intravascular coagulation (DIC).2
The resting endothelium produces antithrombotic molecules, including nitric oxide (NO) and prostacyclin (PGI2). Endothelial dysfunction (ED) in COVID-193 is primarily caused by oxidative stress,4 a systemic condition associated with decreased NO and expression of prothrombotic and cell-surface adhesion molecules, and which plays a pivotal role in both sepsis and DIC.5 There is a tight relationship between ED, inflammation, reactive oxygen species (ROS) production and increased risk of thromboembolism. ROS stimulate expression of tissue factor (TF) and can also directly inactivate protein C, a major anticoagulant.
Accordingly, it has recently been proposed that COVID-19 primarily targets the endothelium.6 Clinical and preclinical evidence in COVID-19 patients support the hypothesis that the endothelium is a key target organ in the disease, leading to the consequent multi-organ systemic manifestations.6 The hypothesis of COVID-19 as an endothelial disease appears interestingly unifying for its systemic manifestations, as it would account for the involvement of the nervous system, heart, liver and kidney1 in COVID-19, the lung just being the most sensitive target. The virus primary receptor is angiotensin-converting enzyme 2 (ACE2),1 which is expressed in the airway cells, intestinal epithelial cells, kidney cells, cerebral neurons and alveolar monocytes, but also in the endothelial cells (ECs) that line the vascular lumen; these are the most widespread cells in the body and play a pivotal role in vascular homeostasis.5 SARS-CoV-2 binding with ACE2 could cause over-inflammatory and pro-thrombotic disseminated events.
COVID-19 binds to human ACE2 in the general population, with patients with diabetes and cardiovascular disease being at high risk.6 Concern has arisen regarding whether angiotensin receptor blockers (ARBs) and ACE inhibitors (ACEIs) increase the morbidity and mortality of COVID-19, as ARBs and ACEI upregulate ACE2 expression.7 There are conflicting data on this topic: it has recently been suggested that the ARB could play a protective effect against COVID-19 pneumonia. Notably, a confounding parameter is old age, a strong predictor of COVID-19-related death, as elderly people are often treated with ARBs or ACEIs. To date there is no conclusive evidence for ARBs or ACEIs increasing the risk or being beneficial for COVID-19; therefore it is not recommended to discontinue these medications.7
The role of oxidative stress in COVID-19
Oxidative stress and an impaired antioxidant system have been reported to be linked to the pathogenesis and severity of coronavirus infections.8 Redox balance impairment may trigger inflammatory responses. In SARS-CoV-1 infection, the viral 3C-like protease (3CLpro) was demonstrated to increase ROS production in human HL-CZ cells, triggering a 3CLpro-induced apoptosis with the involvement of NF-κB signalling.9
Possible source of oxidative stress
ROS are mainly generated as by-products of cellular aerobic metabolism. The mitochondrial electron transfer chain (ETC) complexes I and III are the major source of ROS.10 Intracellularly, a minor source of ROS production is the activity of cytosolic enzymes, including neutrophil NADPH oxidases. However, the ultimate source of a massive extracellular ROS production is less clear. The ETC and F1Fo-ATP synthase (ATP synthase) are expressed outside the mitochondrion, as suggested by the frequency with which these proteins are found in ectopic locations by proteomics.11 An extra-mitochondrial oxidative phosphorylation has been reported to occur in rod outer segment disks,12 myelin,13 exosomes,14 plasma membranes of cancer cells,15 human umbilical vein endothelial cells (HUVECs)16 and hepatocytes.17 A cell surface ATP synthase was also found in lipid rafts of ECs plasma membranes, where it was active in ATP synthesis.18
Thus, ROS production inside and possibly outside the endothelial cell, enhanced by hyperglycaemia, could cause the systemic damage seen in COVID-19. ED is a key determinant in cardiovascular disease and diabetes mellitus, which are frequent comorbidities in COVID-19 patients. Insulin resistance could cause abnormalities in virus pathogenesis, increasing mortality risk.7 Moreover, SARS-CoV-2 may exert a direct action on the pancreatic beta cells expressing ACE2. Metformin has been shown to improve endothelial function.19 A high percentage of COVID-19 deaths came from patients with altered glucose homeostasis, in turn related to higher expression of IL-6. Such higher plasma IL-6 levels in hyperglycemic patients would be responsible for the reduced effects of tocilizumab, which targets IL-6 receptors, in these patients.20 Optimal glycemic control is a good strategy to ameliorate outcomes in high-risk patents7 and it would be advisable to assess the impact of hypoglycaemic therapies on COVID-19 patients.7
The answer to the question of why viral damage causes microvascular inflammation and thrombosis in predisposed individuals would be that a source of ROS (and oxidative stress) in the vessel lumen is the ETC in the plasma membrane of the ECs. The COVID-19 pathogenic mechanism would be a vascular luminal oxidative stress produced by the ectopic ETC in the plasma membrane of the ECs, impaired by viral damage. This would in turn prime microvascular thrombosis. A pivotal role for oxygen as a trigger of ROS production by the impaired ETC can be therefore envisaged. This would explain the primary involvement of those organs that are more exposed to oxygen: the lung but also the kidney and the nervous system. If oxygen availability to the impaired ectopic ETC expressed in the plasma membrane of the ECs plays a primary role in COVID-19 pathogenesis, mechanical ventilation might require a finer tuning of oxygen fluxes. The use of costly resources such as prolonged invasive ventilation would also benefit, in economic terms, from a deeper knowledge of the pathogenesis of the most severe disease complications.
- © Royal College of Physicians 2020. All rights reserved.
References
- ↵
- ↵
- Ciceri F
- ↵
- ↵
- ↵
- ↵
- Sardu C
- ↵
- Sardu C
- ↵
- ↵
- ↵
- Genova ML
- ↵
- ↵
- Bruschi M
- ↵
- Ravera S
- ↵
- ↵
- ↵
- Arakaki N
- ↵
- ↵
- ↵
- ↵
- Marfella R
Article Tools
Citation Manager Formats
Jump to section
Related Articles
- No related articles found.