ABSTRACT
Rationale: Individuals with COPD who develop COVID-19 are at increased risk of hospitalization, ICU admission and death. COPD is associated with increased airway epithelial expression of ACE2, the receptor mediating SARS-CoV-2 entry into cells. Hypercapnia commonly develops in advanced COPD and is associated with frequent and potentially fatal pulmonary infections. We previously reported that hypercapnia increases viral replication, lung injury and mortality in mice infected with influenza A virus. Also, global gene expression profiling of primary human bronchial epithelial (HBE) cells showed that elevated CO2 upregulates expression of cholesterol biosynthesis genes, including HMGCS1, and downregulates ATP-binding cassette (ABC) transporters that promote cholesterol efflux. Given that cellular cholesterol is important for entry of viruses into cells, in the current study we assessed the impact of hypercapnia on regulation of cellular cholesterol levels, and resultant effects on expression of ACE2 and entry of Pseudo-SARS-CoV-2 in cultured HBE, BEAS-2B and VERO cells, and airway epithelium of mice. Methods: Differentiated HBE, BEAS-2B or VERO cells were pre-incubated in normocapnia (5% CO2, PCO2 36 mmHg) or hypercapnia (15% CO2, PCO2 108 mmHg), both with normoxia, for 4 days. Expression of ACE2 and sterol regulatory element binding protein 2 (SREPB2), the master regulator of cholesterol synthesis, was assessed by immunoblot or immunofluorescence. Cholesterol was measured in cell lysates by Amplex red assay. Cells cultured in normocapnia or hypercapnia were also infected with Pseudo SARS-CoV-2, a Neon Green reporter baculovirus. For in vivo studies, C57BL/6 mice were exposed to normoxic hypercapnia (10% CO2/21% O2) for 7 days, or air as control, and airway epithelial expression of ACE2, SREBP2, ABCA1, ABCG1 and HMGCS1 was assessed by immunofluorescence. SREBP2 was blocked using the small molecules betulin or AM580, and cellular cholesterol was disrupted using MβCD. Results: Hypercapnia increased expression and activation of SREBP2 and decreased expression of ABC transporters, thereby augmenting epithelial cholesterol levels. Elevated CO2 also augmented ACE2 expression and Pseudo-SARSCoV- 2 entry into epithelial cells in vitro and in vivo. These effects were all reversed by blocking SREBP2 or disrupting cellular cholesterol. Conclusion: Hypercapnia augments cellular cholesterol levels by altering expression of cholesterol biosynthetic enzymes and efflux transporters, leading to increased epithelial expression of ACE2 and entry of Pseudo-SARS-CoV-2 into cells. These findings suggest that ventilatory support to limit hypercapnia or pharmacologic interventions to decrease cellular cholesterol might reduce viral burden and improve clinical outcomes of SARSCoV- 2 infection in advanced COPD and other severe lung diseases.
ABSTRACT
Respiratory viral infections are a major public health concern because of their global occurrence, ease of spread and considerable morbidity and mortality. Medical treatments for viral respiratory diseases primarily involve providing relief from symptoms like pain and discomfort rather than treating the infection. Very few antiviral medications have been approved with restrictive usage, high cost, unwanted side effects and limited availability. Plants with their unique metabolite composition and high remedial values offer unique preventive and therapeutic efficacy in treatment of viral infections. The present review is focused on the types and mode of action of plant secondary metabolites that have been used successfully ί in the treatment of infections caused by respiratory viruses like Influenza, SARS, MERS, RSV etc. Plant metabolites such as phenolics, alkaloids, terpenoids and oligosaccharides inhibit attachment and entry of the virus. Others such as flavonoids, viz quercetin and baicalein, alkaloids viz sanguinarine, berberine and emetine, specific lipids and fatty acids prevent viral replication and protein synthesis. These metabolites have the potential to be used as lead molecules that can be optimized to develop potent drugs for effectively combating pandemics caused by respiratory viruses.
ABSTRACT
Recent data have revealed that fructose-rich diet triggers inflammation and lipid synthesis. Furthermore, lipid metabolism, cholesterol synthesis and sterol regulatory element binding protein-2 (SREBP-2) activation correlates with coronavirus disease 2019 (COVID-19)-induced cytokine storm. High fructose consumption result in SREBPs activation, altered cholesterol and lipid synthesis and may establish an innate immune memory in the cells, leading to severe COVID-19 in patients with obesity.