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Harnessing the immune system to overcome cytokine storm and reduce viral load in COVID-19: a review of the phases of illness and therapeutic agents.
Khadke, S, Ahmed, N, Ahmed, N, Ratts, R, Raju, S, Gallogly, M, de Lima, M, Sohail, MR
Virology journal. 2020;17(1):154
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Severe manifestations of COVID-19 infection and mortality are associated with a cytokine storm. This is an excessive inflammatory response to the infection leading to an overproduction of pro-inflammatory signalling molecules, which consequently contributes to tissue and organ damage. This literature review summarised current knowledge, as of June 2020, about virus-associated cytokine storm, virus-host interactions and immunological mechanism, to gain a better understanding of the phenomena observed in COVID-19 infections and devise better treatment strategies. The review briefly outlines the epidemiology of COVID-19, predictors of severity of disease, mode of transmission, testing, viral structure, mechanism of invasion of the host cell, replication and immune invasion and the progression of the four stages of the cytokine storm. The second part of the review discusses antiviral therapeutics of interest with a table summarising drugs, mechanism and available data. This article may be of interest to those who like to delve further into the mechanisms and immune components involved in a cytokine storm and gain an oversight of the pathways targeted by allopathic agents that have been put forward as treatment options.
Abstract
BACKGROUND Coronavirus disease 2019 (COVID-19) is caused by Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2, previously named 2019-nCov), a novel coronavirus that emerged in China in December 2019 and was declared a global pandemic by World Health Organization by March 11th, 2020. Severe manifestations of COVID-19 are caused by a combination of direct tissue injury by viral replication and associated cytokine storm resulting in progressive organ damage. DISCUSSION We reviewed published literature between January 1st, 2000 and June 30th, 2020, excluding articles focusing on pediatric or obstetric population, with a focus on virus-host interactions and immunological mechanisms responsible for virus associated cytokine release syndrome (CRS). COVID-19 illness encompasses three main phases. In phase 1, SARS-CoV-2 binds with angiotensin converting enzyme (ACE)2 receptor on alveolar macrophages and epithelial cells, triggering toll like receptor (TLR) mediated nuclear factor kappa-light-chain-enhancer of activated B cells (NF-ƙB) signaling. It effectively blunts an early (IFN) response allowing unchecked viral replication. Phase 2 is characterized by hypoxia and innate immunity mediated pneumocyte damage as well as capillary leak. Some patients further progress to phase 3 characterized by cytokine storm with worsening respiratory symptoms, persistent fever, and hemodynamic instability. Important cytokines involved in this phase are interleukin (IL)-6, IL-1β, and tumor necrosis factor (TNF)-α. This is typically followed by a recovery phase with production of antibodies against the virus. We summarize published data regarding virus-host interactions, key immunological mechanisms responsible for virus-associated CRS, and potential opportunities for therapeutic interventions. CONCLUSION Evidence regarding SARS-CoV-2 epidemiology and pathogenesis is rapidly evolving. A better understanding of the pathophysiology and immune system dysregulation associated with CRS and acute respiratory distress syndrome in severe COVID-19 is imperative to identify novel drug targets and other therapeutic interventions.
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COVID-19 infection: the perspectives on immune responses.
Shi, Y, Wang, Y, Shao, C, Huang, J, Gan, J, Huang, X, Bucci, E, Piacentini, M, Ippolito, G, Melino, G
Cell death and differentiation. 2020;27(5):1451-1454
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The SARS-CoV-2 infection triggers an immune response which varies greatly from one person to another. It can be roughly divided into three stages: stage I, an asymptomatic incubation period with or without detectable virus; stage II, non-severe symptomatic period with the presence of virus; stage III, severe respiratory symptomatic stage with high viral load. Currently around 15% of people infected end up in severe stage III. There appears to be a two-phase immune response; an early protective phase and a second inflammation-driven damaging phase. In phase one the adaptive immune system responds to the virus. Being in good general health is important in this phase to limiting the progression of the disease to a more severe stage. In phase two the innate immune system response to tissue damage caused by the virus could lead to widespread inflammation of the lungs and acute respiratory distress syndrome or respiratory failure. Therapeutically this raises the question of whether the immune response should be boosted in phase one and suppressed in phase two. There also appears to be an element of viral relapse in some patients discharged from hospital indicating that a virus-eliminating immune response may be difficult to achieve naturally. These same patients may also not respond to vaccines. Overall, it is still unclear why some people develop severe disease, whilst others do not. Overall immunity alone does not explain the differences in disease presentation.
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Borrelia burgdorferi peptidoglycan is a persistent antigen in patients with Lyme arthritis.
Jutras, BL, Lochhead, RB, Kloos, ZA, Biboy, J, Strle, K, Booth, CJ, Govers, SK, Gray, J, Schumann, P, Vollmer, W, et al
Proceedings of the National Academy of Sciences of the United States of America. 2019;116(27):13498-13507
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Lyme disease is a varied, multisystem disorder caused by the spiral-shaped bacteria Borrelia burgdorferi (Bb). Advanced stages of the disease can present with oligoarthritis, most commonly involving the knee joints. Peptidoglycan (PG) is a compound that makes up the cell envelope of Bb and other bacteria. It acts as a microbe-associated molecular pattern, which can trigger the immune system and induces pro-inflammatory responses. This article summarises a series of cell, human, and animal studies supporting the theory that PG is a contributor to persistent Lyme’s arthritis (LA) far beyond the eradication of the pathogen. Significantly elevated inflammatory markers as well as antibodies to PG and Bb itself have been found in patients with LA before and after antibiotic therapy. The inflammatory response to Bb PG seems to be particularly high when compared to other bacteria. In summary, the authors suggest that PG accumulation in the joints and subsequent persistent inflammation contribute to LA and that targeting the specific inflammatory pathways involved may yield potential therapeutic interventions. This article could be of interest to those looking to understand more about the mechanisms and specific inflammatory responses involved in LA.
Abstract
Lyme disease is a multisystem disorder caused by the spirochete Borrelia burgdorferi A common late-stage complication of this disease is oligoarticular arthritis, often involving the knee. In ∼10% of cases, arthritis persists after appropriate antibiotic treatment, leading to a proliferative synovitis typical of chronic inflammatory arthritides. Here, we provide evidence that peptidoglycan (PG), a major component of the B. burgdorferi cell envelope, may contribute to the development and persistence of Lyme arthritis (LA). We show that B. burgdorferi has a chemically atypical PG (PGBb) that is not recycled during cell-wall turnover. Instead, this pathogen sheds PGBb fragments into its environment during growth. Patients with LA mount a specific immunoglobulin G response against PGBb, which is significantly higher in the synovial fluid than in the serum of the same patient. We also detect PGBb in 94% of synovial fluid samples (32 of 34) from patients with LA, many of whom had undergone oral and intravenous antibiotic treatment. These same synovial fluid samples contain proinflammatory cytokines, similar to those produced by human peripheral blood mononuclear cells stimulated with PGBb In addition, systemic administration of PGBb in BALB/c mice elicits acute arthritis. Altogether, our study identifies PGBb as a likely contributor to inflammatory responses in LA. Persistence of this antigen in the joint may contribute to synovitis after antibiotics eradicate the pathogen. Furthermore, our finding that B. burgdorferi sheds immunogenic PGBb fragments during growth suggests a potential role for PGBb in the immunopathogenesis of other Lyme disease manifestations.
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Longitudinal Study of the Psoriasis-Associated Skin Microbiome during Therapy with Ustekinumab in a Randomized Phase 3b Clinical Trial.
Loesche, MA, Farahi, K, Capone, K, Fakharzadeh, S, Blauvelt, A, Duffin, KC, DePrimo, SE, Muñoz-Elías, EJ, Brodmerkel, C, Dasgupta, B, et al
The Journal of investigative dermatology. 2018;138(9):1973-1981
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Chronic plaque psoriasis is an immune-mediated disease of the skin and joints. A growing appreciation of the role of the innate immune system in psoriasis pathogenesis stems from the prominent role of inflammatory cytokines and cells associated with innate immunity in the disease and associations observed between psoriasis and genetic variations involved in innate immunity. The aim of this study was to assess changes of the skin microbiome in the setting of a longitudinal phase 3b study of patients receiving up to 2 years of ustekinumab therapy. Results show that prior to treatment, there were minor, body-site specific differences in microbial diversity and composition when comparing lesional with non-lesional skin. Microbial heterogeneity was greater in lesional skin than non-lesional skin. During ustekinumab treatment, the composition of microbiota diverged further between lesional and non-lesional skin across body sites. The divergence observed between lesional and non-lesional skin during ustekinumab treatment varied by body site. Authors conclude that their findings may help inform future study design and it may also have medically relevant implications for diagnostics and therapeutics involving the skin microbiome.
Abstract
Plaque psoriasis, a chronic inflammatory disease primarily affecting the skin, is thought to have a multifactorial etiology, including innate immune system dysregulation, environmental triggers, and genetic susceptibility. We sought to further understand the role of skin microbiota in psoriasis pathogenesis, as well as their response to therapy. We systematically analyzed dynamic microbiota colonizing psoriasis lesions and adjacent nonlesional skin in 114 patients prior to and during ustekinumab treatment in a phase 3b clinical trial. By sequencing the bacterial 16S ribosomal RNA gene from skin swab samples obtained at six anatomical sites, we identified minor, site-specific differences in microbial diversity and composition between pretreatment lesional and nonlesional skin. During therapy, microbial communities within lesional and nonlesional skin diverged, and body-site dispersion increased, reflecting microbial skin site-specificity. Microbiota demonstrated greater pretreatment heterogeneity in psoriatic lesions than in nonlesional skin, and variance increased as treatment progressed. Microbiota colonizing recurrent lesions did not overlap with pretreatment lesional microbiota, suggesting colonization patterns varied between initial and recurrent psoriatic lesions. While plaque psoriasis does not appear to be associated with specific microbes and/or microbial diversity, this large dataset provides insight into microbial variation associated with (i) disease in different body locations, (ii) initial versus recurrent lesions, and (iii) anti-IL12/23 therapy.