Literature DB >> 34875033

Temporal Dynamics of Anti-Type 1 Interferon Autoantibodies in Patients With Coronavirus Disease 2019.

Elana R Shaw¹, Lindsey B Rosen¹, Aristine Cheng^1,2, Kerry Dobbs¹, Ottavia M Delmonte¹, Elise M N Ferré¹, Monica M Schmitt¹, Luisa Imberti³, Virginia Quaresima³, Michail S Lionakis¹, Luigi D Notarangelo¹, Steven M Holland¹, Helen C Su¹.

Abstract

Binding levels and neutralization activity of anti-type 1 interferon autoantibodies peaked during acute coronavirus disease 2019 and markedly decreased thereafter. Most patients maintained some ability to neutralize type 1 interferon into convalescence despite lower levels of binding immunoglobulin G. Identifying these autoantibodies in healthy individuals before the development of critical viral disease may be challenging. Published by Oxford University Press for the Infectious Diseases Society of America 2021.

Entities: Chemical

Keywords: COVID-19; IFN-α; IFN-ω; autoantibodies; convalescence

Mesh：

Substances：

Year: 2022 PMID： 34875033 PMCID： PMC8689695 DOI： 10.1093/cid/ciab1002

Source DB: PubMed Journal: Clin Infect Dis ISSN： 1058-4838 Impact factor: 20.999

Anti-cytokine autoantibodies (autoAbs) can phenocopy mendelian defects in immune-signaling pathways to cause susceptibility to severe disease [1]. It was previously reported that neutralizing autoAbs against type 1 (T1) interferons (IFNs), primarily IFN-α2 and/or IFN-ω, were present in 101 of 987 critically ill patients with coronavirus disease 2019 (COVID-19) from whom plasma or serum samples were obtained during hospitalization for acute disease, but in none of 663 asymptomatic or mildly symptomatic patients [2]. During this initial screening, the anti-T1IFN autoAbs showed high fluorescence intensity (FI) in a multiplex binding assay; patient plasma samples diluted to 10% were able to neutralize ≥10 ng/mL of IFN-α2 and/or IFN-ω. Before the COVID-19 pandemic, neutralizing anti-T1IFN autoAbs of similar potency had been identified in patients with autoimmune polyendocrine syndrome type 1 (APS-1), hypomorphic recombination-activating gene (RAG) mutations, thymoma, and other diseases [3-5]. Within our cohort of patients with acute COVID-19, no causal genetic defect or underlying comorbid conditions has yet been found to account for the anti-T1IFN autoAbs. In 2 critically ill patients with COVID-19 who had samples available from before infection, neutralizing anti-T1IFN autoAbs were already present [2]. However, it is currently not known whether the neutralizing anti-T1IFN autoAbs in most patients predate critical COVID-19 infection as they do in patients with APS-1, RAG-deficient patients, and patients with thymoma, nor is it known whether they persist after acute COVID-19 has resolved.

METHODS

Serum or plasma samples were collected longitudinally from 13 critically ill patients from Italy with acute COVID-19 and from 10 COVID-19–negative patients with either APS-1, RAG deficiency, or thymoma who had detectable autoAbs against IFN-α2 and/or IFN-ω. Twelve of the 13 patients with acute COVID-19 had been included as part of a larger cohort in which single autoAb measurements were reported during early hospitalization [2]. Patients with acute COVID-19 were followed up for an average of 147 days (range, 71–236 days) after hospital admission for COVID-19 and other patients were followed up for an average of 269 days (65-451 days) after their respective diagnoses. Clinical and/or demographic data were collected (Supplementary Tables 1 and 2). All subjects were recruited according to protocols approved by local institutional review boards of Comitato Etico Provinciale (NP 4000–Studio CORONAlab) and the National Institute of Allergy and Infectious Diseases. All protocols followed local ethics recommendations, and informed consent was obtained when required. Patient serum or plasma samples diluted 1:100 in phosphate-buffered saline (PBS) were screened for binding levels of anti-T1IFN autoAbs, using a multiplex particle-based assay in which magnetic beads of differential fluorescence were covalently coupled to recombinant human IFN-α2, IFN-β, or IFN-ω at lysine residues. The FI of the bound phycoerythrin (PE)-conjugated secondary anti-human IgG Fc was previously shown to be proportional to IgG binding levels of anti-T1IFN autoAbs [6]. FI measurements of anti-T1IFN autoAbs were corrected for background FI using a well containing phosphate-buffered saline alone. A corrected FI value over the threshold of 3 standard deviations above the mean for the 1230 healthy controls (HCs) was defined as high (1268 FI for anti-IFN- α2, 1392 FI for anti-IFN-ω autoAbs), as determined in a previous study [2]. Alternatively, to determine Ig isotypes, secondary biotinylated anti-human immunoglobulin (Ig) G, IgM, IgA, or IgE Fc were used, and levels were revealed using phycoerythrin-conjugated streptavidin. The neutralizing activity of anti–T1IFN autoAbs was determined by assessing STAT1 phosphorylation on Y710 (pSTAT1) in HC peripheral blood mononuclear cells after 15 minutes of stimulation with 10 ng/mL of IFN-α2 or IFN-ω in the presence of 10% HC or patient serum or plasma samples. The level of pSTAT1 was assessed in CD14+ monocytes and normalized to that of 10% HC plasma; 0%–20% pSTAT1 was classified as neutralizing, 20%–65% as partially neutralizing, and >65% as not neutralizing [2]. A protein G column was used to deplete IgG from the plasma, the IgG-depleted flow-through fraction was collected, and the pSTAT1 level was assessed and compared with that of total plasma [2]. To determine the median inhibitory concentration (IC50), patient plasma or serum samples collected at a given time point were serially diluted 2–10-fold into human serum AB to assess pSTAT1 in the presence of patient plasma at final concentrations ranging from 10% to 0.000625%. The IC50 was interpolated from the sigmoidal 4-parameter curve, where x = log (concentration). Data were analyzed using FlowJo software, version 10, and graphed using GraphPad Prism 8 software.

RESULTS

Consistent with previous observations of cross-reactivity against structurally and phylogenetically related T1IFN [2], 8 patients with COVID-19 in the current study had autoAbs against both IFN-α2 and IFN-ω, 2 against only IFN-α2, and 3 against only IFN-ω; none had autoAbs against IFN-β (Supplementary Tables 3 and 4). In the critically ill patients with COVID-19 and with anti-T1IFN autoAbs, binding IgG FI peaked during acute infection and markedly decreased thereafter (Figure 1A). The highest binding IgG FI was generally observed on the first available sample, obtained 0–24 days after hospital admission. Binding IgG FI predominated over IgM, while IgA or IgE FI were minimal (Supplementary Figures 1–14). In general, the anti-T1IFN binding IgG FIs in the acute COVID-19 cohort halved every approximately 2 weeks. This contrasted with the stable high FI anti-T1IFN IgG observed in patients with APS-1 or thymoma regardless of B-cell–depleting therapy with rituximab and in RAG-deficient patients despite hematopoietic stem cell transplantation (Figure 1A and Supplementary Tables 3 and 4).

Figure 1.

A, Anti–interferon (IFN) α2 and ω autoantibody (autoAb) binding fluorescence intensity (FI) over time, measured in days since hospital admission for patients with acute coronavirus disease 2019 (COVID-19) (red) and days since diagnosis for patients with autoimmune polyendocrine syndrome type 1 (APS-1) (blue), thymoma (purple), or recombination-activating gene protein (RAG) deficiency (black). B, Neutralizing activity over time in patients with COVID-19 over time against 10 ng/mL of IFN-α2 and/or IFN-ω at a plasma concentration of 10%. Black lines on the graph indicate that binding FI against the respective cytokine remained high throughout the course of follow-up; red lines, that binding FI against the respective cytokine dropped below threshold during follow-up. The STAT1 phosphorylation (pSTAT1) index was normalized against that of 10% health control (HC) plasma in the same experiment. Neutralizing (red region of graph) was defined as 0%–20% pSTAT1, partial neutralizing (yellow region) as 20%–65% pSTAT1, and not neutralizing (blue region) as >65% pSTAT1. C, Inverse median inhibitory concentration (1/IC50) over time for patients with COVID-19 in whom signaling to 10 ng/mL of IFN- α2 or IFN-ω was blocked with 10% plasma at all time points. The neutralizing activity of anti-T1IFN autoAbs in patients with acute COVID-19, normalized to HCs, also tended to decrease over time, tracking with the drop in detectable IgG binding (Supplementary Figures 2–14). Three of the 10 patients who showed high binding FI of anti-IFN-α2 autoAbs during acute illness dropped before threshold in convalescence. Plasma diluted to 10% from 2 of these patients lost the ability to neutralize 10 ng/mL of IFN-α2 by approximately 40 and 54 days into our follow-up. Plasma from the third patient maintained the ability to partially neutralize 10 ng/mL of IFN-α2 up to 218 days after hospital admission, despite having subthreshold binding FI. Three of the 11 patients with high binding FI of anti-IFN-ω autoAbs during acute illness dropped to subthreshold, and 2 of those 3 maintained the ability to neutralize 10 ng/mL of IFN-ω at 10% plasma (Figure 1B and Supplementary Tables 3 and 4). In all 3 patients who lost detectable IgG FI but maintained neutralizing activity, in vitro preincubations to deplete IgG removed the neutralizing activity completely (Supplementary Figure 15). To further characterize changes in neutralizing strength of anti-T1IFN autoAbs in patients with COVID-19 during disease and/or convalescence, IC50 values were determined against 10 ng/mL of the respective cytokine. For most patients, the neutralizing strength of the autoAbs decreased sharply after acute infection (Figure 1C and Supplementary Tables 3 and 4).

DISCUSSION

By following up patients from acute disease through convalescence, we showed that the anti-T1IFN autoAb responses in most of the tested patients with COVID-19 were highly dynamic, in sharp contrast to the stable high FI anti-T1IFN IgG in patients with APS-1 or thymoma and in RAG-deficient patients. Interestingly, the patients with COVID-19 with only anti-IFN-ω autoAbs showed a different pattern, with binding FI and/or neutralizing activity that remained constant or slightly increased over time (Supplementary Table 4), suggesting different inductive conditions. Most patients with COVID-19 maintained some ability to neutralize T1IFN into convalescence. In several patients, this neutralizing activity persisted even after binding FI dropped to below detectable levels. We suspect that their neutralizing autoAbs recognized an epitope on IFN that was blocked by coupling the IFN to beads at lysine residues for our multiplex particle-based assay. Alternative explanations, such as binding IgA FI or autoAbs against the common T1IFN receptor, interferon-α/β receptor (IFNAR) 1/2, seem unlikely, given that neutralizing activity not only was depleted by in vitro preincubation to deplete IgG specifically (Supplementary Figure 15) but also did not extend against all type I IFN tested, including IFN-β (data not shown). Our results suggest that the increase in endogenous IFNs during early viral infection may trigger a memory response of high FI but transient autoAbs. Anti-IFN-α2 and anti-IFN-ω autoAbs in the same patient often followed different trajectories, suggesting a polyclonal response to different triggers (Supplementary Figures 2–14). Moreover, the persistent neutralizing activity despite undetectable binding IgG in several patients suggests that only a small fraction of the polyclonal autoAbs responsible for high binding FI during acute disease contribute to the neutralizing activity. Prospective studies enrolling patients with COVID-19 from the time of their first positive PCR result are needed to better define these potential mechanisms. Our group’s previous report showed that individuals with anti-IFN-α2 and/or IFN-ω autoAbs constitute a group at significant risk for developing critical COVID-19 disease [2]. Identifying these individuals early in the course of disease for targeted intervention with compensatory therapeutics, such as inhaled IFN-β therapy, might alter their course of disease and improve outcomes [7]. However, our findings indicate that the dynamic nature of these autoAbs may make diagnosis difficult in healthy individuals before acute disease, at least if the level of autoAb FI sought for diagnostics is what we observed during acute disease. Neutralization activity may be a more appropriate diagnostic measure than binding FI, because some convalescent patients with subthreshold binding FI against T1IFN during convalescence continued to potently neutralize supraphysiological amounts of the respective IFN. Accordingly, a high-throughput method for detecting neutralizing activity against more physiological levels of IFN, which has been recently validated in patients with COVID-19, may be useful and appropriate [8].

Supplementary Data

Supplementary materials are available at Clinical Infectious Diseases online. Consisting of data provided by the authors to benefit the reader, the posted materials are not copyedited and are the sole responsibility of the authors, so questions or comments should be addressed to the corresponding author. Click here for additional data file.

8 in total

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3. Anti-cytokine autoantibodies are associated with opportunistic infection in patients with thymic neoplasia.

Authors: Peter D Burbelo; Sarah K Browne; Elizabeth P Sampaio; Giuseppe Giaccone; Rifat Zaman; Ervand Kristosturyan; Arun Rajan; Li Ding; Kathryn H Ching; Arlene Berman; Joao B Oliveira; Amy P Hsu; Caitlin M Klimavicz; Michael J Iadarola; Steven M Holland
Journal: Blood Date: 2010-08-17 Impact factor: 22.113

4. Autoantibodies neutralizing type I IFNs are present in ~4% of uninfected individuals over 70 years old and account for ~20% of COVID-19 deaths.

Authors: Adrian Gervais; Tom Le Voyer; Jérémie Rosain; Quentin Philippot; Jérémy Manry; Eleftherios Michailidis; Hans-Heinrich Hoffmann; Shohei Eto; Marina Garcia-Prat; Lucy Bizien; Alba Parra-Martínez; Rui Yang; Liis Haljasmägi; Mélanie Migaud; Karita Särekannu; Julia Maslovskaja; Evangelos Vandreakos; Olivier Hermine; Aurora Pujol; Pärt Peterson; Trine H Mogensen; Lee Rowen; James Mond; Xavier de Lamballerie; Xavier Duval; France Mentré; Marie Zins; Pere Soler-Palacin; Roger Colobran; Guy Gorochov; Xavier Solanich; Sophie Susen; Javier Martinez-Picado; Didier Raoult; Marc Vasse; Peter K Gregersen; Lorenzo Piemonti; Carlos Rodríguez-Gallego; Luigi D Notarangelo; Helen C Su; Kai Kisand; Satoshi Okada; Anne Puel; Emmanuelle Jouanguy; Charles M Rice; Pierre Tiberghien; Qian Zhang; Aurélie Cobat; Laurent Abel; Jean-Laurent Casanova; Paul Bastard; Nicolas de Prost; Yacine Tandjaoui-Lambiotte; Charles-Edouard Luyt; Blanca Amador-Borrero; Alexandre Gaudet; Julien Poissy; Pascal Morel; Pascale Richard; Fabrice Cognasse; Jesus Troya; Sophie Trouillet-Assant; Alexandre Belot; Kahina Saker; Pierre Garçon; Jacques G Rivière; Jean-Christophe Lagier; Stéphanie Gentile; Lindsey B Rosen; Elana Shaw; Tomohiro Morio; Junko Tanaka; David Dalmau; Pierre-Louis Tharaux; Damien Sene; Alain Stepanian; Bruno Megarbane; Vasiliki Triantafyllia; Arnaud Fekkar; James R Heath; José Luis Franco; Juan-Manuel Anaya; Jordi Solé-Violán; Luisa Imberti; Andrea Biondi; Paolo Bonfanti; Riccardo Castagnoli; Ottavia M Delmonte; Yu Zhang; Andrew L Snow; Steven M Holland; Catherine Biggs; Marcela Moncada-Vélez; Andrés Augusto Arias; Lazaro Lorenzo; Soraya Boucherit; Boubacar Coulibaly; Dany Anglicheau; Anna M Planas; Filomeen Haerynck; Sotirija Duvlis; Robert L Nussbaum; Tayfun Ozcelik; Sevgi Keles; Ahmed A Bousfiha; Jalila El Bakkouri; Carolina Ramirez-Santana; Stéphane Paul; Qiang Pan-Hammarström; Lennart Hammarström; Annabelle Dupont; Alina Kurolap; Christine N Metz; Alessandro Aiuti; Giorgio Casari; Vito Lampasona; Fabio Ciceri; Lucila A Barreiros; Elena Dominguez-Garrido; Mateus Vidigal; Mayana Zatz; Diederik van de Beek; Sabina Sahanic; Ivan Tancevski; Yurii Stepanovskyy; Oksana Boyarchuk; Yoko Nukui; Miyuki Tsumura; Loreto Vidaur; Stuart G Tangye; Sonia Burrel; Darragh Duffy; Lluis Quintana-Murci; Adam Klocperk; Nelli Y Kann; Anna Shcherbina; Yu-Lung Lau; Daniel Leung; Matthieu Coulongeat; Julien Marlet; Rutger Koning; Luis Felipe Reyes; Angélique Chauvineau-Grenier; Fabienne Venet; Guillaume Monneret; Michel C Nussenzweig; Romain Arrestier; Idris Boudhabhay; Hagit Baris-Feldman; David Hagin; Joost Wauters; Isabelle Meyts; Adam H Dyer; Sean P Kennelly; Nollaig M Bourke; Rabih Halwani; Narjes Saheb Sharif-Askari; Karim Dorgham; Jérome Sallette; Souad Mehlal Sedkaoui; Suzan AlKhater; Raúl Rigo-Bonnin; Francisco Morandeira; Lucie Roussel; Donald C Vinh; Sisse Rye Ostrowski; Antonio Condino-Neto; Carolina Prando; Anastasiia Bonradenko; András N Spaan; Laurent Gilardin; Jacques Fellay; Stanislas Lyonnet; Kaya Bilguvar; Richard P Lifton; Shrikant Mane; Mark S Anderson; Bertrand Boisson; Vivien Béziat; Shen-Ying Zhang; Stéphanie Debette
Journal: Sci Immunol Date: 2021-08-19

5. Broad-spectrum antibodies against self-antigens and cytokines in RAG deficiency.

Authors: Jolan E Walter; Lindsey B Rosen; Krisztian Csomos; Jacob M Rosenberg; Divij Mathew; Marton Keszei; Boglarka Ujhazi; Karin Chen; Yu Nee Lee; Irit Tirosh; Kerry Dobbs; Waleed Al-Herz; Morton J Cowan; Jennifer Puck; Jack J Bleesing; Michael S Grimley; Harry Malech; Suk See De Ravin; Andrew R Gennery; Roshini S Abraham; Avni Y Joshi; Thomas G Boyce; Manish J Butte; Kari C Nadeau; Imelda Balboni; Kathleen E Sullivan; Javeed Akhter; Mehdi Adeli; Reem A El-Feky; Dalia H El-Ghoneimy; Ghassan Dbaibo; Rima Wakim; Chiara Azzari; Paolo Palma; Caterina Cancrini; Kelly Capuder; Antonio Condino-Neto; Beatriz T Costa-Carvalho; Joao Bosco Oliveira; Chaim Roifman; David Buchbinder; Attila Kumanovics; Jose Luis Franco; Tim Niehues; Catharina Schuetz; Taco Kuijpers; Christina Yee; Janet Chou; Michel J Masaad; Raif Geha; Gulbu Uzel; Rebecca Gelman; Steven M Holland; Mike Recher; Paul J Utz; Sarah K Browne; Luigi D Notarangelo
Journal: J Clin Invest Date: 2015-10-12 Impact factor: 14.808

6. Anti-interferon autoantibodies in autoimmune polyendocrinopathy syndrome type 1.

Authors: Anthony Meager; Kumuthini Visvalingam; Pärt Peterson; Kaidi Möll; Astrid Murumägi; Kai Krohn; Petra Eskelin; Jaakko Perheentupa; Eystein Husebye; Yoshihisa Kadota; Nick Willcox
Journal: PLoS Med Date: 2006-07 Impact factor: 11.069

7. Safety and efficacy of inhaled nebulised interferon beta-1a (SNG001) for treatment of SARS-CoV-2 infection: a randomised, double-blind, placebo-controlled, phase 2 trial.

Authors: Phillip D Monk; Richard J Marsden; Victoria J Tear; Jody Brookes; Toby N Batten; Marcin Mankowski; Felicity J Gabbay; Donna E Davies; Stephen T Holgate; Ling-Pei Ho; Tristan Clark; Ratko Djukanovic; Tom M A Wilkinson
Journal: Lancet Respir Med Date: 2020-11-12 Impact factor: 30.700

8. Autoantibodies against type I IFNs in patients with life-threatening COVID-19.

Authors: Paul Bastard; Lindsey B Rosen; Qian Zhang; Eleftherios Michailidis; Hans-Heinrich Hoffmann; Yu Zhang; Karim Dorgham; Quentin Philippot; Jérémie Rosain; Vivien Béziat; Steven M Holland; Guy Gorochov; Emmanuelle Jouanguy; Charles M Rice; Aurélie Cobat; Luigi D Notarangelo; Laurent Abel; Helen C Su; Jean-Laurent Casanova; Jérémy Manry; Elana Shaw; Liis Haljasmägi; Pärt Peterson; Lazaro Lorenzo; Lucy Bizien; Sophie Trouillet-Assant; Kerry Dobbs; Adriana Almeida de Jesus; Alexandre Belot; Anne Kallaste; Emilie Catherinot; Yacine Tandjaoui-Lambiotte; Jeremie Le Pen; Gaspard Kerner; Benedetta Bigio; Yoann Seeleuthner; Rui Yang; Alexandre Bolze; András N Spaan; Ottavia M Delmonte; Michael S Abers; Alessandro Aiuti; Giorgio Casari; Vito Lampasona; Lorenzo Piemonti; Fabio Ciceri; Kaya Bilguvar; Richard P Lifton; Marc Vasse; David M Smadja; Mélanie Migaud; Jérome Hadjadj; Benjamin Terrier; Darragh Duffy; Lluis Quintana-Murci; Diederik van de Beek; Lucie Roussel; Donald C Vinh; Stuart G Tangye; Filomeen Haerynck; David Dalmau; Javier Martinez-Picado; Petter Brodin; Michel C Nussenzweig; Stéphanie Boisson-Dupuis; Carlos Rodríguez-Gallego; Guillaume Vogt; Trine H Mogensen; Andrew J Oler; Jingwen Gu; Peter D Burbelo; Jeffrey I Cohen; Andrea Biondi; Laura Rachele Bettini; Mariella D'Angio; Paolo Bonfanti; Patrick Rossignol; Julien Mayaux; Frédéric Rieux-Laucat; Eystein S Husebye; Francesca Fusco; Matilde Valeria Ursini; Luisa Imberti; Alessandra Sottini; Simone Paghera; Eugenia Quiros-Roldan; Camillo Rossi; Riccardo Castagnoli; Daniela Montagna; Amelia Licari; Gian Luigi Marseglia; Xavier Duval; Jade Ghosn; John S Tsang; Raphaela Goldbach-Mansky; Kai Kisand; Michail S Lionakis; Anne Puel; Shen-Ying Zhang
Journal: Science Date: 2020-09-24 Impact factor: 63.714

8 in total

7 in total

1. Autoantibodies targeting cytokines and connective tissue disease autoantigens are common in acute non-SARS-CoV-2 infections.

Authors: Allan Feng; Emily Yang; Andrew Moore; Shaurya Dhingra; Sarah Chang; Xihui Yin; Ruoxi Pi; Elisabeth Mack; Sara Völkel; Reinhard Geßner; Margrit Gundisch; Andreas Neubauer; Harald Renz; Sotirios Tsiodras; Paraskevi Fragkou; Adijat Asuni; Joseph Levitt; Jennifer Wilson; Michelle Leong; Jennifer Lumb; Rong Mao; Kassandra Pinedo; Jonasel Roque; Christopher Richards; Mikayla Stabile; Gayathri Swaminathan; Maria Salagianni; Vasiliki Triantafyllia; Wilhelm Bertrams; Catherine Blish; Jan Carette; Jennifer Frankovich; Eric Meffre; Kari C Nadeau; Upinder Singh; Taia Wang; Eline Luning Prak; Susanne Herold; Evangelos Andreakos; Bernd Schmeck; Chrysanthi Skevaki; Angela Rogers; Paul Utz
Journal: Res Sq Date: 2022-01-20

2. Detection of Neutralizing Anti-Type 1 Interferon Autoantibodies.

Authors: Elana R Shaw; Lindsey B Rosen; Li Ding; Steven M Holland; Helen C Su
Journal: Curr Protoc Date: 2022-08

3. The risk of COVID-19 death is much greater and age dependent with type I IFN autoantibodies.

Authors: Jérémy Manry; Paul Bastard; Adrian Gervais; Tom Le Voyer; Jérémie Rosain; Quentin Philippot; Eleftherios Michailidis; Hans-Heinrich Hoffmann; Shohei Eto; Marina Garcia-Prat; Lucy Bizien; Alba Parra-Martínez; Rui Yang; Liis Haljasmägi; Mélanie Migaud; Karita Särekannu; Julia Maslovskaja; Nicolas de Prost; Yacine Tandjaoui-Lambiotte; Charles-Edouard Luyt; Blanca Amador-Borrero; Alexandre Gaudet; Julien Poissy; Pascal Morel; Pascale Richard; Fabrice Cognasse; Jesús Troya; Sophie Trouillet-Assant; Alexandre Belot; Kahina Saker; Pierre Garçon; Jacques G Rivière; Jean-Christophe Lagier; Stéphanie Gentile; Lindsey B Rosen; Elana Shaw; Tomohiro Morio; Junko Tanaka; David Dalmau; Pierre-Louis Tharaux; Damien Sene; Alain Stepanian; Bruno Mégarbane; Vasiliki Triantafyllia; Arnaud Fekkar; James R Heath; José Luis Franco; Juan-Manuel Anaya; Jordi Solé-Violán; Luisa Imberti; Andrea Biondi; Paolo Bonfanti; Riccardo Castagnoli; Ottavia M Delmonte; Yu Zhang; Andrew L Snow; Steven M Holland; Catherine M Biggs; Marcela Moncada-Vélez; Andrés Augusto Arias; Lazaro Lorenzo; Soraya Boucherit; Dany Anglicheau; Anna M Planas; Filomeen Haerynck; Sotirija Duvlis; Tayfun Ozcelik; Sevgi Keles; Ahmed A Bousfiha; Jalila El Bakkouri; Carolina Ramirez-Santana; Stéphane Paul; Qiang Pan-Hammarström; Lennart Hammarström; Annabelle Dupont; Alina Kurolap; Christine N Metz; Alessandro Aiuti; Giorgio Casari; Vito Lampasona; Fabio Ciceri; Lucila A Barreiros; Elena Dominguez-Garrido; Mateus Vidigal; Mayana Zatz; Diederik van de Beek; Sabina Sahanic; Ivan Tancevski; Yurii Stepanovskyy; Oksana Boyarchuk; Yoko Nukui; Miyuki Tsumura; Loreto Vidaur; Stuart G Tangye; Sonia Burrel; Darragh Duffy; Lluis Quintana-Murci; Adam Klocperk; Nelli Y Kann; Anna Shcherbina; Yu-Lung Lau; Daniel Leung; Matthieu Coulongeat; Julien Marlet; Rutger Koning; Luis Felipe Reyes; Angélique Chauvineau-Grenier; Fabienne Venet; Guillaume Monneret; Michel C Nussenzweig; Romain Arrestier; Idris Boudhabhay; Hagit Baris-Feldman; David Hagin; Joost Wauters; Isabelle Meyts; Adam H Dyer; Sean P Kennelly; Nollaig M Bourke; Rabih Halwani; Fatemeh Saheb Sharif-Askari; Karim Dorgham; Jérôme Sallette; Souad Mehlal Sedkaoui; Suzan AlKhater; Raúl Rigo-Bonnin; Francisco Morandeira; Lucie Roussel; Donald C Vinh; Christian Erikstrup; Antonio Condino-Neto; Carolina Prando; Anastasiia Bondarenko; András N Spaan; Laurent Gilardin; Jacques Fellay; Stanislas Lyonnet; Kaya Bilguvar; Richard P Lifton; Shrikant Mane; Mark S Anderson; Bertrand Boisson; Vivien Béziat; Shen-Ying Zhang; Evangelos Andreakos; Olivier Hermine; Aurora Pujol; Pärt Peterson; Trine H Mogensen; Lee Rowen; James Mond; Stéphanie Debette; Xavier de Lamballerie; Charles Burdet; Lila Bouadma; Marie Zins; Pere Soler-Palacin; Roger Colobran; Guy Gorochov; Xavier Solanich; Sophie Susen; Javier Martinez-Picado; Didier Raoult; Marc Vasse; Peter K Gregersen; Lorenzo Piemonti; Carlos Rodríguez-Gallego; Luigi D Notarangelo; Helen C Su; Kai Kisand; Satoshi Okada; Anne Puel; Emmanuelle Jouanguy; Charles M Rice; Pierre Tiberghien; Qian Zhang; Jean-Laurent Casanova; Laurent Abel; Aurélie Cobat
Journal: Proc Natl Acad Sci U S A Date: 2022-05-16 Impact factor: 12.779

4. Anti-IFN-α/-ω neutralizing antibodies from COVID-19 patients correlate with downregulation of IFN response and laboratory biomarkers of disease severity.

Authors: Federica Frasca; Mirko Scordio; Letizia Santinelli; Lucia Gabriele; Orietta Gandini; Anna Criniti; Alessandra Pierangeli; Antonio Angeloni; Claudio M Mastroianni; Gabriella d'Ettorre; Raphael P Viscidi; Guido Antonelli; Carolina Scagnolari
Journal: Eur J Immunol Date: 2022-04-28 Impact factor: 6.688

Review 5. Clinical implications of host genetic variation and susceptibility to severe or critical COVID-19.

Authors: Caspar I van der Made; Mihai G Netea; Frank L van der Veerdonk; Alexander Hoischen
Journal: Genome Med Date: 2022-08-19 Impact factor: 15.266

Review 6. Interferon induction, evasion, and paradoxical roles during SARS-CoV-2 infection.

Authors: Carolina Chiale; Trever T Greene; Elina I Zuniga
Journal: Immunol Rev Date: 2022-07-01 Impact factor: 10.983

7. Autoantibodies against type I IFNs in patients with critical influenza pneumonia.

Authors: Qian Zhang; Andrés Pizzorno; Lisa Miorin; Paul Bastard; Adrian Gervais; Tom Le Voyer; Lucy Bizien; Kai Kisand; Anne Puel; Emmanuelle Jouanguy; Laurent Abel; Aurélie Cobat; Sophie Trouillet-Assant; Adolfo García-Sastre; Jean-Laurent Casanova; Jeremy Manry; Jérémie Rosain; Quentin Philippot; Kelian Goavec; Blandine Padey; Anastasija Cupic; Emilie Laurent; Kahina Saker; Martti Vanker; Karita Särekannu; Tamara García-Salum; Marcela Ferres; Nicole Le Corre; Javier Sánchez-Céspedes; María Balsera-Manzanero; Jordi Carratala; Pilar Retamar-Gentil; Gabriela Abelenda-Alonso; Adoración Valiente; Pierre Tiberghien; Marie Zins; Stéphanie Debette; Isabelle Meyts; Filomeen Haerynck; Riccardo Castagnoli; Luigi D Notarangelo; Luis I Gonzalez-Granado; Nerea Dominguez-Pinilla; Evangelos Andreakos; Vasiliki Triantafyllia; Carlos Rodríguez-Gallego; Jordi Solé-Violán; José Juan Ruiz-Hernandez; Felipe Rodríguez de Castro; José Ferreres; Marisa Briones; Joost Wauters; Lore Vanderbeke; Simon Feys; Chen-Yen Kuo; Wei-Te Lei; Cheng-Lung Ku; Galit Tal; Amos Etzioni; Suhair Hanna; Thomas Fournet; Jean-Sebastien Casalegno; Gregory Queromes; Laurent Argaud; Etienne Javouhey; Manuel Rosa-Calatrava; Elisa Cordero; Teresa Aydillo; Rafael A Medina
Journal: J Exp Med Date: 2022-09-16 Impact factor: 17.579

7 in total