Johannes C. Hellmuth scite author profile

Background: Coronavirus disease 2019 (COVID-19) can manifest as a viral-induced hyperinflammation with multiorgan involvement. Such patients often experience rapid deterioration and need for mechanical ventilation. Currently, no prospectively validated biomarker of impending respiratory failure is available. Objective: We aimed to identify and prospectively validate biomarkers that allow the identification of patients in need of impending mechanical ventilation. Methods: Patients with COVID-19 who were hospitalized from February 29 to April 9, 2020, were analyzed for baseline clinical and laboratory findings at admission and during the disease. Data from 89 evaluable patients were available for the purpose of analysis comprising an initial evaluation cohort (n 5 40) followed by a temporally separated validation cohort (n 5 49). Results: We identified markers of inflammation, lactate dehydrogenase, and creatinine as the variables most predictive of respiratory failure in the evaluation cohort. Maximal IL-6 level before intubation showed the strongest association with the need for mechanical ventilation, followed by maximal CRP level. The respective AUC values for IL-6 and CRP levels in the evaluation cohort were 0.97 and 0.86, and they were similar in the validation cohort (0.90 and 0.83, respectively). The calculated optimal cutoff values during the course of disease from the evaluation cohort (IL-6 level > 80 pg/mL and CRP level > 97 mg/L) both correctly classified 80% of patients in the validation cohort regarding their risk of respiratory failure. Conclusion: The maximal level of IL-6, followed by CRP level, was highly predictive of the need for mechanical ventilation. This suggests the possibility of using IL-6 or CRP level to guide escalation of treatment in patients with COVID-19-related hyperinflammatory syndrome.

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Immunothrombotic Dysregulation in COVID-19 Pneumonia Is Associated With Respiratory Failure and Coagulopathy

Nicolai

et al. 2020

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Background: SARS-CoV-2 infection causes severe pneumonia (COVID-19), but the mechanisms of subsequent respiratory failure and complicating renal and myocardial involvement are poorly understood. In addition, a systemic prothrombotic phenotype has been reported in COVID-19 patients. Methods: A total of 62 subjects were included in our study (n=38 patients with RT-PCR confirmed COVID-19 and n=24 non-COVID-19 controls). We performed histopathological assessment of autopsy cases, surface-marker based phenotyping of neutrophils and platelets, and functional assays for platelet, neutrophil functions as well as coagulation tests. Results: We provide evidence that organ involvement and prothrombotic features in COVID-19 are linked by immunothrombosis. We show that in COVID-19 inflammatory microvascular thrombi are present in the lung, kidney, and heart, containing neutrophil extracellular traps associated with platelets and fibrin. COVID-19 patients also present with neutrophil-platelet aggregates and a distinct neutrophil and platelet activation pattern in blood, which changes with disease severity. Whereas cases of intermediate severity show an exhausted platelet and hyporeactive neutrophil phenotype, severely affected COVID-19 patients are characterized by excessive platelet and neutrophil activation compared to healthy controls and non-COVID-19 pneumonia. Dysregulated immunothrombosis in SARS-CoV-2 pneumonia is linked to both ARDS and systemic hypercoagulability. Conclusions: Taken together, our data point to immunothrombotic dysregulation as a key marker of disease severity in COVID-19. Further work is necessary to determine the role of immunothrombosis in COVID-19.

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5′-triphosphate-siRNA: turning gene silencing and Rig-I activation against melanoma

Poeck

Besch

Maihöfer

et al. 2008

Nat Med

357

386

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Genetic and epigenetic plasticity allows tumors to evade single-targeted treatments. Here we direct Bcl2-specific short interfering RNA (siRNA) with 5'-triphosphate ends (3p-siRNA) against melanoma. Recognition of 5'-triphosphate by the cytosolic antiviral helicase retinoic acid-induced protein I (Rig-I, encoded by Ddx58) activated innate immune cells such as dendritic cells and directly induced expression of interferons (IFNs) and apoptosis in tumor cells. These Rig-I-mediated activities synergized with siRNA-mediated Bcl2 silencing to provoke massive apoptosis of tumor cells in lung metastases in vivo. The therapeutic activity required natural killer cells and IFN, as well as silencing of Bcl2, as evidenced by rescue with a mutated Bcl2 target, by site-specific cleavage of Bcl2 messenger RNA in lung metastases and downregulation of Bcl-2 protein in tumor cells in vivo. Together, 3p-siRNA represents a single molecule-based approach in which Rig-I activation on both the immune- and tumor cell level corrects immune ignorance and in which gene silencing corrects key molecular events that govern tumor cell survival.

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5′-triphosphate RNA requires base-paired structures to activate antiviral signaling via RIG-I

Schmidt

Schwerd²,

Hamm³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

352

337

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The ATPase retinoid acid-inducible gene (RIG)-I senses viral RNA in the cytoplasm of infected cells and subsequently activates cellular antiviral defense mechanisms. RIG-I recognizes molecular structures that discriminate viral from host RNA. Here, we show that RIG-I ligands require base-paired structures in conjunction with a free 5-triphosphate to trigger antiviral signaling. Hitherto unavailable chemically synthesized 5-triphosphate RNA ligands do not trigger RIG-I-dependent IFN production in cells, and they are unable to trigger the ATPase activity of RIG-I without a base-paired stretch. Consistently, immunostimulatory RNA from cells infected with a virus recognized by RIG-I is sensitive to double-strand, but not single-strand, specific RNases. In vitro, base-paired stretches and the 5-triphosphate bind to distinct sites of RIG-I and synergize to trigger the induction of signaling competent RIG-I multimers. Strengthening our model of a bipartite molecular pattern for RIG-I activation, we show that the activity of supposedly ''single-stranded'' 5-triphosphate RNAs generated by in vitro transcription depends on extended and base-paired by-products inadvertently, but commonly, produced by this method. Together, our findings accurately define a minimal molecular pattern sufficient to activate RIG-I that can be found in viral genomes or transcripts.immunostimulatory RNA ͉ melanoma differentiation-associated protein 5 ͉ retinoid acid-inducible gene-I-like helicases ͉ virus infection ͉ interferon production

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