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NETosis is a special form of programmed cell death in neutrophils, which is characterized by the extrusion of DNA, histones, and antimicrobial proteins in a web-like structure known as neutrophil extracellular traps (NETs)

increased generation of reactive oxygen species (ROS) is a crucial intracellular process that causes NETosis

Another indirect route of SARS-CoV-2-induced NET production is platelet activation

When NETs are activated in the circulation, they can also induce hypercoagulability and thrombosis

In COVID-19, major NET protein cargos of NETs (i.e., NE, MPO, and histones) are significantly elevated.

SARS-CoV-2 can also infect host cells through noncanonical receptors such as C-type lectin receptors

Immunopathological manifestations, including cytokine storms and impaired adaptive immunity, are the primary drivers behind COVID-19, with neutrophil infiltration being suggested as a significant cause

NETosis and NETs are increasingly recognized as causes of vascular injury

SARS-CoV-2 and its components (e.g., spike proteins and viral RNA) attach to platelets and increase their activation and aggregation in COVID-19, resulting in vascular injury and thrombosis, both of which are linked to NET formation

NET formation may be caused by activated platelets rather than SARS-CoV-2 itself

NETosis, leading to aberrant immunity such as cytokine storms, autoimmune disorders, and immunosuppression.

early bacterial coinfections were more prevalent in COVID-19 patients than those infected with other viruses

NETosis and NETs may also have a role in the development of post COVID-19 syndromes, including lung fibrosis, neurological disorders, tumor growth, and worsening of concomitant disease

NETs and other by-products of NETosis have been shown to act as direct inflammation amplifiers. Hyperinflammation

“cytokine storm”

SARS-CoV-2 drives NETosis and NET formation to allow for the release of free DNA and by-products (e.g., elastases and histones). This may trigger surrounding macrophages and endothelial cells to secrete excessive proinflammatory cytokines and chemokines, which, in turn, enhance NET formation and form a positive feedback of cytokine storms in COVID-19

NET release enables self-antigen exposure and autoantibody production, thereby increasing the autoinflammatory response

patients with COVID-19 who have higher anti-NET antibodies are more likely to be detected with positive autoantibodies [e.g., antinuclear antibodies (ANA) and anti-neutrophil cytoplasmic antibodies (ANCA)]

COVID-19 NETs may act as potential inducers for autoimmune responses

have weakened adaptive immunity as well as a high level of inflammation

tumor-associated NETosis and NETs promote an immunosuppressive environment in which anti-tumor immunity is compromised

NETs have also been shown to enhance macrophage pyroptosis in sepsis

facilitating an immunosuppressive microenvironment

persistent immunosuppression may result in bacterial co-infection or secondary infection

can enhance this process by interacting with neutrophils through toll-like receptor 4 (TLR4), platelet factor 4 (PF4), and extracellular vesicle-dependent processes

NET-induced immunosuppression in COVID-19 in the context of co-existing bacterial infection

Following initial onset of COVID-19, an estimated 50% or more of COVID-19 survivors may develop multi-organ problems (e.g., pulmonary dysfunction and neurologic impairment) or have worsening concomitant chronic illness

NETs in the bronchoalveolar lavage fluid of severe COVID-19 patients cause EMT in lung epithelial cells

decreased E-cadherin (an epithelial marker) expression

COVID-19 also has a long-term influence on tumor progression

Patients with tumors have been shown to be more vulnerable to SARS-CoV-2 infection and subsequent development of severe COVID-19

patients who have recovered from COVID-19 may have an increased risk of developing cancer or of cancer progression and metastasis

awaken cancer cells

NETs have been shown to change the tumor microenvironment

enhance tumor progression and metastasis

vitamin C has been tested in phase 2 clinical trials aimed at reducing COVID-19-associated mortality by reducing excessive activation of the inflammatory response

vitamin C is an antioxidant that significantly attenuates PMA-induced NETosis in healthy neutrophils by scavenging ROS

vitamin C may also inhibit NETosis and NET production in COVID-19

Metformin

Vitamin C

pharmacologic ascorbate as a prooxidant drug for therapeutic use.

Recently we reported that pharmacologic ascorbic acid concentrations produced H2O2 concentrations of ≥25 μM, causing cancer cell death in vitro

We found that H2O2 concentrations generated in vivo were those that caused cancer cell death in vitro

When ascorbate was given parenterally, Asc•−, the product of a loss of one electron from ascorbate, was detected preferentially in extracellular fluid compared with blood

Asc•− generation in extracellular fluid depended on the ascorbate dose and the resulting concentrations

With i.v. administration of ascorbate, Asc•− concentrations were as much as 12-fold greater in extracellular fluid compared to blood and approached 250 nM

In blood, such Asc•− concentrations were never produced and were always <50 nM

These data are all consistent with the hypothesis that pharmacologic ascorbate concentrations in vivo serve as a prodrug for selective delivery of H2O2 to the extracellular space

After oral ingestion, control of intracellular and extracellular ascorbate concentrations is mediated by three mechanisms: intestinal absorption, tissue transport, and renal reabsorption

intestinal absorption, or bioavailability, declines at doses >200 mg

corresponding to plasma concentrations of ≈60 μM

at approximately this concentration, the ascorbate tissue transporter SVCT2 approaches Vmax, and tissues appear to be saturated

also at ≈60 μM, renal reabsorption approaches saturation, and excess ascorbate is excreted in urine

Parenteral administration bypasses tight control

When tight control is bypassed, H2O2 forms in the extracellular space

in vivo validation of ascorbate as a prodrug for selective H2O2 formation

Temporarily bypassing tight control with parenteral administration of ascorbate allows H2O2 to form in discrete time periods only, decreasing likelihood of harm, and provides a pharmacologic basis for therapeutic use of i.v. ascorbate

H2O2 formation results in selective cytotoxicity

Tumor cells are killed with exposure to H2O2 for ≤30 min

In vitro, killing is mediated by H2O2 rather than Asc•−

In addition to cancer treatment, another potential therapeutic use is for treatment of infections. H2O2 concentrations of 25–50 μM are bacteriostatic

virally infected cells may also be candidates