TY - JOUR
T1 - Neutralisation of SARS-CoV-2 lineage P.1 by antibodies elicited through natural SARS-CoV-2 infection or vaccination with an inactivated SARS-CoV-2 vaccine
T2 - an immunological study
AU - Souza, William M.
AU - Amorim, Mariene R.
AU - Sesti-Costa, Renata
AU - Coimbra, Lais D.
AU - Brunetti, Natalia S.
AU - Toledo-Teixeira, Daniel A.
AU - de Souza, Gabriela F.
AU - Muraro, Stefanie P.
AU - Parise, Pierina L.
AU - Barbosa, Priscilla P.
AU - Bispo-dos-Santos, Karina
AU - Mofatto, Luciana S.
AU - Simeoni, Camila L.
AU - Claro, Ingra M.
AU - Duarte, Adriana S.S.
AU - Coletti, Thais M.
AU - Zangirolami, Audrey B.
AU - Costa-Lima, Carolina
AU - Gomes, Arilson B.S.P.
AU - Buscaratti, Lucas I.
AU - Sales, Flavia C.
AU - Costa, Vitor A.
AU - Franco, Lucas A.M.
AU - Candido, Darlan S.
AU - Pybus, Oliver G.
AU - de Jesus, Jaqueline G.
AU - Silva, Camila A.M.
AU - Ramundo, Mariana S.
AU - Ferreira, Giulia M.
AU - Pinho, Mariana C.
AU - Souza, Leandro M.
AU - Rocha, Esmenia C.
AU - Andrade, Pamela S.
AU - Crispim, Myuki A.E.
AU - Maktura, Grazielle C.
AU - Manuli, Erika R.
AU - Santos, Magnun N.N.
AU - Camilo, Cecilia C.
AU - Angerami, Rodrigo N.
AU - Moretti, Maria L.
AU - Spilki, Fernando R.
AU - Arns, Clarice W.
AU - Addas-Carvalho, Marcelo
AU - Benites, Bruno D.
AU - Vinolo, Marco A.R.
AU - Mori, Marcelo A.S.
AU - Gaburo, Nelson
AU - Dye, Christopher
AU - Marques-Souza, Henrique
AU - Marques, Rafael E.
AU - Farias, Alessandro S.
AU - Diamond, Michael S.
AU - Faria, Nuno R.
AU - Sabino, Ester C.
AU - Granja, Fabiana
AU - Proença-Módena, Jose Luiz
N1 - Funding Information:
This study was supported by grants from the São Paulo Research Foundation (FAPESP; 2016/00194-8 and 2020/04558-0 ) and Fundo de Apoio ao Ensino, Pesquisa e Extensão (FAEPEX) of UNICAMP (2266/20); by the Brazilian Ministry of Science, Technology, and Innovation (MCTI) through the Rede Corona-ômica Br-MCTI/Financier of Studies and Projects (01.20.0003.00 to REM, affiliated to RedeVírus/MCTI [01.20.0029.000462/20 and 404096/2020-4]); and by the UK Medical Research Council and FAPESP–Brazil–UK Centre for (Arbo)virus Discovery, Diagnosis, Genomics and Epidemiology partnership award (MR/S0195/1 and FAPESP 2018/14389-0). WMS is supported by FAPESP (2017/13981-0 and 2019/24251-9) and the National Council for Scientific and Technological Development (CNPq; 408338/2018-0). HM-S is supported by FAEPEX (2005/20, 2319/20, and 2432/20). SPM is supported by FAPESP (#18/13645-3). GFdS is supported by FAPESP (#18/10224-7). NRF is supported by a Wellcome Trust and Royal Society Sir Henry Dale Fellowship (204311/Z/16/Z). BDB is supported by CNPq (401977/2020). KB-d-S, CLS, and PLP were supported by FAPESP fellowships (2020/02159-0, 2020/02448-2, and 2017/26908-0). MRA and PPB were supported by Coordination for the Improvement of Higher Education Personnel (88887.356527/2019-00) fellowships, and DAT-T and LSM were supported by CNPq fellowships (141844/2019-1 and 382206/2020-7). MSD was supported by a grant from the National Institutes of Health (U01 grant AI151810). We thank Wendy Barclay for helpful discussions; all blood donors, vaccinated individuals, and SARS-CoV-2 patients who provided clinical specimens for this study; Thermo Fisher Scientific for provision of an EVOS inverted microscope for the biosafety level 3 facility at the Emerging Viruses Laboratory; the National Institute of Science and Technology of Photonics Applied to Cell Biology for confocal microscopy analysis; UNICAMP-Task-Force against COVID-19, which facilitated this study; Elzira E Saviani for technical support; all individuals involved in the diagnosis and generation of SARS-CoV-2 sequences as part of the CADDE-Genomic-Network; and the MCTI and all members of the Corona-ômica network for support.
Funding Information:
This study was supported by grants from the São Paulo Research Foundation (FAPESP; 2016/00194-8 and 2020/04558-0) and Fundo de Apoio ao Ensino, Pesquisa e Extensão (FAEPEX) of UNICAMP (2266/20); by the Brazilian Ministry of Science, Technology, and Innovation (MCTI) through the Rede Corona-ômica Br-MCTI/Financier of Studies and Projects (01.20.0003.00 to REM, affiliated to RedeVírus/MCTI [01.20.0029.000462/20 and 404096/2020-4]); and by the UK Medical Research Council and FAPESP–Brazil–UK Centre for (Arbo)virus Discovery, Diagnosis, Genomics and Epidemiology partnership award (MR/S0195/1 and FAPESP 2018/14389-0). WMS is supported by FAPESP (2017/13981-0 and 2019/24251-9) and the National Council for Scientific and Technological Development (CNPq; 408338/2018-0). HM-S is supported by FAEPEX (2005/20, 2319/20, and 2432/20). SPM is supported by FAPESP (#18/13645-3). GFdS is supported by FAPESP (#18/10224-7). NRF is supported by a Wellcome Trust and Royal Society Sir Henry Dale Fellowship (204311/Z/16/Z). BDB is supported by CNPq (401977/2020). KB-d-S, CLS, and PLP were supported by FAPESP fellowships (2020/02159-0, 2020/02448-2, and 2017/26908-0). MRA and PPB were supported by Coordination for the Improvement of Higher Education Personnel (88887.356527/2019-00) fellowships, and DAT-T and LSM were supported by CNPq fellowships (141844/2019-1 and 382206/2020-7). MSD was supported by a grant from the National Institutes of Health (U01 grant AI151810). We thank Wendy Barclay for helpful discussions; all blood donors, vaccinated individuals, and SARS-CoV-2 patients who provided clinical specimens for this study; Thermo Fisher Scientific for provision of an EVOS inverted microscope for the biosafety level 3 facility at the Emerging Viruses Laboratory; the National Institute of Science and Technology of Photonics Applied to Cell Biology for confocal microscopy analysis; UNICAMP-Task-Force against COVID-19, which facilitated this study; Elzira E Saviani for technical support; all individuals involved in the diagnosis and generation of SARS-CoV-2 sequences as part of the CADDE-Genomic-Network; and the MCTI and all members of the Corona-ômica network for support.
Publisher Copyright:
© 2021 The Author(s). Published by Elsevier Ltd. This is an Open Access article under the CC BY-NC-ND 4.0 license
PY - 2021/10
Y1 - 2021/10
N2 - Background: Mutations accrued by SARS-CoV-2 lineage P.1—first detected in Brazil in early January, 2021—include amino acid changes in the receptor-binding domain of the viral spike protein that also are reported in other variants of concern, including B.1.1.7 and B.1.351. We aimed to investigate whether isolates of wild-type P.1 lineage SARS-CoV-2 can escape from neutralising antibodies generated by a polyclonal immune response. Methods: We did an immunological study to assess the neutralising effects of antibodies on lineage P.1 and lineage B isolates of SARS-CoV-2, using plasma samples from patients previously infected with or vaccinated against SARS-CoV-2. Two specimens (P.1/28 and P.1/30) containing SARS-CoV-2 lineage P.1 (as confirmed by viral genome sequencing) were obtained from nasopharyngeal and bronchoalveolar lavage samples collected from patients in Manaus, Brazil, and compared against an isolate of SARS-CoV-2 lineage B (SARS.CoV2/SP02.2020) recovered from a patient in Brazil in February, 2020. Isolates were incubated with plasma samples from 21 blood donors who had previously had COVID-19 and from a total of 53 recipients of the chemically inactivated SARS-CoV-2 vaccine CoronaVac: 18 individuals after receipt of a single dose and an additional 20 individuals (38 in total) after receipt of two doses (collected 17–38 days after the most recent dose); and 15 individuals who received two doses during the phase 3 trial of the vaccine (collected 134–230 days after the second dose). Antibody neutralisation of P.1/28, P.1/30, and B isolates by plasma samples were compared in terms of median virus neutralisation titre (VNT50, defined as the reciprocal value of the sample dilution that showed 50% protection against cytopathic effects). Findings: In terms of VNT50, plasma from individuals previously infected with SARS-CoV-2 had an 8·6 times lower neutralising capacity against the P.1 isolates (median VNT50 30 [IQR <20–45] for P.1/28 and 30 [<20–40] for P.1/30) than against the lineage B isolate (260 [160–400]), with a binominal model showing significant reductions in lineage P.1 isolates compared with the lineage B isolate (p≤0·0001). Efficient neutralisation of P.1 isolates was not seen with plasma samples collected from individuals vaccinated with a first dose of CoronaVac 20–23 days earlier (VNT50s below the limit of detection [<20] for most plasma samples), a second dose 17–38 days earlier (median VNT50 24 [IQR <20–25] for P.1/28 and 28 [<20–25] for P.1/30), or a second dose 134–260 days earlier (all VNT50s below limit of detection). Median VNT50s against the lineage B isolate were 20 (IQR 20–30) after a first dose of CoronaVac 20–23 days earlier, 75 (<20–263) after a second dose 17–38 days earlier, and 20 (<20–30) after a second dose 134–260 days earlier. In plasma collected 17–38 days after a second dose of CoronaVac, neutralising capacity against both P.1 isolates was significantly decreased (p=0·0051 for P.1/28 and p=0·0336 for P.1/30) compared with that against the lineage B isolate. All data were corroborated by results obtained through plaque reduction neutralisation tests. Interpretation: SARS-CoV-2 lineage P.1 might escape neutralisation by antibodies generated in response to polyclonal stimulation against previously circulating variants of SARS-CoV-2. Continuous genomic surveillance of SARS-CoV-2 combined with antibody neutralisation assays could help to guide national immunisation programmes. Funding: São Paulo Research Foundation, Brazilian Ministry of Science, Technology and Innovation and Funding Authority for Studies, Medical Research Council, National Council for Scientific and Technological Development, National Institutes of Health. Translation: For the Portuguese translation of the abstract see Supplementary Materials section.
AB - Background: Mutations accrued by SARS-CoV-2 lineage P.1—first detected in Brazil in early January, 2021—include amino acid changes in the receptor-binding domain of the viral spike protein that also are reported in other variants of concern, including B.1.1.7 and B.1.351. We aimed to investigate whether isolates of wild-type P.1 lineage SARS-CoV-2 can escape from neutralising antibodies generated by a polyclonal immune response. Methods: We did an immunological study to assess the neutralising effects of antibodies on lineage P.1 and lineage B isolates of SARS-CoV-2, using plasma samples from patients previously infected with or vaccinated against SARS-CoV-2. Two specimens (P.1/28 and P.1/30) containing SARS-CoV-2 lineage P.1 (as confirmed by viral genome sequencing) were obtained from nasopharyngeal and bronchoalveolar lavage samples collected from patients in Manaus, Brazil, and compared against an isolate of SARS-CoV-2 lineage B (SARS.CoV2/SP02.2020) recovered from a patient in Brazil in February, 2020. Isolates were incubated with plasma samples from 21 blood donors who had previously had COVID-19 and from a total of 53 recipients of the chemically inactivated SARS-CoV-2 vaccine CoronaVac: 18 individuals after receipt of a single dose and an additional 20 individuals (38 in total) after receipt of two doses (collected 17–38 days after the most recent dose); and 15 individuals who received two doses during the phase 3 trial of the vaccine (collected 134–230 days after the second dose). Antibody neutralisation of P.1/28, P.1/30, and B isolates by plasma samples were compared in terms of median virus neutralisation titre (VNT50, defined as the reciprocal value of the sample dilution that showed 50% protection against cytopathic effects). Findings: In terms of VNT50, plasma from individuals previously infected with SARS-CoV-2 had an 8·6 times lower neutralising capacity against the P.1 isolates (median VNT50 30 [IQR <20–45] for P.1/28 and 30 [<20–40] for P.1/30) than against the lineage B isolate (260 [160–400]), with a binominal model showing significant reductions in lineage P.1 isolates compared with the lineage B isolate (p≤0·0001). Efficient neutralisation of P.1 isolates was not seen with plasma samples collected from individuals vaccinated with a first dose of CoronaVac 20–23 days earlier (VNT50s below the limit of detection [<20] for most plasma samples), a second dose 17–38 days earlier (median VNT50 24 [IQR <20–25] for P.1/28 and 28 [<20–25] for P.1/30), or a second dose 134–260 days earlier (all VNT50s below limit of detection). Median VNT50s against the lineage B isolate were 20 (IQR 20–30) after a first dose of CoronaVac 20–23 days earlier, 75 (<20–263) after a second dose 17–38 days earlier, and 20 (<20–30) after a second dose 134–260 days earlier. In plasma collected 17–38 days after a second dose of CoronaVac, neutralising capacity against both P.1 isolates was significantly decreased (p=0·0051 for P.1/28 and p=0·0336 for P.1/30) compared with that against the lineage B isolate. All data were corroborated by results obtained through plaque reduction neutralisation tests. Interpretation: SARS-CoV-2 lineage P.1 might escape neutralisation by antibodies generated in response to polyclonal stimulation against previously circulating variants of SARS-CoV-2. Continuous genomic surveillance of SARS-CoV-2 combined with antibody neutralisation assays could help to guide national immunisation programmes. Funding: São Paulo Research Foundation, Brazilian Ministry of Science, Technology and Innovation and Funding Authority for Studies, Medical Research Council, National Council for Scientific and Technological Development, National Institutes of Health. Translation: For the Portuguese translation of the abstract see Supplementary Materials section.
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U2 - 10.1016/S2666-5247(21)00129-4
DO - 10.1016/S2666-5247(21)00129-4
M3 - Article
AN - SCOPUS:85113781305
SN - 2666-5247
VL - 2
SP - e527-e535
JO - The Lancet Microbe
JF - The Lancet Microbe
IS - 10
ER -