ABSTRACT
BACKGROUND AND AIMS Replication of the enveloped SARS-COV2 virus can alter lipidomic composition and metabolism of infected cells [1]. These alterations commonly result in a decline in HDL, total cholesterol and LDL, and an increase in triglyceride levels in COVID-19 patients. Furthermore, the ‘cytokine storm’ subsequent to release of inflammatory cytokines can severely impair lipid homeostasis. Importantly, decreased HDL-cholesterol correlates with severity of COVID-19 infection and represents a significant prognostic factor in predicting poor clinical outcomes [2]. Similarly, it has been observed that COVID-19 patients’ recovery is accompanied by a rise in serum HDL levels. Pharmacological intervention that aims to restore ApoA-1 or functional HDL particles may have beneficial roles for clinical outcome of COVID-19 patients and has recently been approved for compassionate use [3]. SARS-CoV 2 spike proteins S1 and S2 can bind free cholesterol and HDL-bound cholesterol, facilitating virus entry by binding the ACE2 co-receptor Scavenger Receptor-BI (SR-BI) [4]. When activated at the trans-membrane level, SR-BI signalling culminates in Ser1173-eNOS phosphorylation with both anti-inflammatory and anti-apoptotic effect. We hypothesized that SARS-COV2 binding promoted SR-BI internalization, so that it could not exert its essential protective function. Therefore, the aim of this study is to evaluate the effects of CER-001, a mimetic HDL, in antagonizing this process. METHOD Endothelial and tubular (RPTEC) cells were exposed to S1, S2 and S1 + S2 (50–250 nM) with or without CER-001 (CER-001 50–500 ug/mL) and cholesterol (10–50 uM). Apoptosis tests (MTT and AnnV/PI) were performed. Internalization of SR-BI, ACE2 with S1 and activation of eNOS was evaluated by FACS analysis. SR-BI and ACE2 expression were evaluated on kidney biopsies from COVID-19 patients. RESULTS At concentrations used, the exposition of S1, S2 and S1 + S2 in the presence of CER-001 and cholesterol did not induce apoptosis of endothelial cells and RPTEC. Endothelial and tubular cells stimulated by S1, in presence of cholesterol, showed an increased intracellular level of SR-BI and ACE-2, with significantly reduced eNOS phosphorylation compared to baseline (P < 0.05). The treatment with CER-001 reversed trans-membrane SR-BI levels and eNOS phosphorylation to baseline values. The detection of S1 spike protein by endothelial cells immunohistochemistry revealed an increased level in S1-exposed cells with cholesterol and reduced S1 intracellular positive staining in CER-001-exposed cells (P < 0.05). Interestingly, S1-exposed cells without cholesterol appeared not to be capable of mediating S1 spike protein internalization. Consistent with in vitro results, analysis of renal biopsies from COVID-19 patients with proteinuria showed increased SR-BI and ACE-2 cytoplasmic signals and reduced expression at the apical domain of injured tubules. CONCLUSION Our data confirmed the key role of lipid profile in SARS-COV2 infection, evaluating the molecular signalling involved in HDL metabolism and inflammatory processes, and could offer new therapeutic strategies for COVID-19 patients.