Article
Phase I/ll study of COVID-19 RNA vaccine BNT162bl in adults
https://doi.org/10.1038/s41586-020-2639-4    Mark J. Mulligan'2'2, Kirsten E. Lyke3'2, Nicholas Kitchin4'2, Judith Absalon5
Received: 29 June 2020
Accepted: 4 August 2020
Published online: 12 August 2020
*>j Check for updates
Alejandra Gurtman5, Stephen Lockhart4, Kathleen Neuzil3, Vanessa Raabe1,2,
Ruth Bailey4, Kena A. Swanson5, Ping Li6, Kenneth Koury5, Warren Kalina5, David Cooper5,
Camila Fontes-Garfias7, Pei-Yong Shi7, Özlem Türeci8, Kristin R. Tompkins5,
Edward E. Walsh910, Robert Frenck", Ann R. Falsey910, Philip R. Dormitzer5, William C. Gruber5,
Ugur Sahin8 & Kathrin U. Jansen5
In March 2020, the World Health Organization (WHO) declared coronavirus disease 2019 (COVID-19), which is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)1, a pandemic. With rapidly accumulating numbers of cases and deaths reported globally2, a vaccine is urgently needed. Here we report the available safety, tolerability and immunogenicity data from an ongoing placebo-controlled, observer-blinded dose-escalation study (ClinicalTrials.gov identifier NCT04368728) among 45 healthy adults (18-55 years of age), who were randomized to receive 2 doses-separated by 21 days-of 10 ng, 30 ng or 100 ng of BNT162bl. BNT162bl is a lipid-nanoparticle-formulated, nucleoside-modifiedmRNA vaccine that encodes the trimerized receptor-binding domain (RBD) of the spike glycoprotein of SARS-CoV-2. Local reactions and systemic events were dose-dependent, generally mild to moderate, and transient. A second vaccination with 100 \ig was not administered because of the increased reactogenicity and a lack of meaningfully increased immunogenicity after a single dose compared with the 30-|ig dose. RBD-binding IgG concentrations and SARS-CoV-2 neutralizing titres in sera increased with dose level and after a second dose. Geometric mean neutralizing titres reached 1.9-4.6-fold that of a panel of COVID-19 convalescent human sera, which were obtained at least 14 days after a positive SARS-CoV-2 PCR. These results support further evaluation of this mRNA vaccine candidate.
In December 2019, a pneumonia outbreakof unknown cause occurred in Wuhan, China. Byjanuary 2020, a new coronavirus was identified as the aetiological agent. Within a month, the genetic sequence of the virus became available (MN908947.3). Infections with SARS-CoV-2 and the resulting disease, COVID-19, have spread globally. On 11 March 2020, the WHO declared the COVID-19 outbreak a pandemic1. So far, the United States has reported the highest number of cases globally23. No vaccines are currently available to prevent SARS-CoV-2 infection or COVID-19.
The RNA vaccine platform has enabled rapid vaccine development in response to this pandemic. RNA vaccines provide flexibility in the design and expression of vaccineantigens that can mimic the structure and expression of the antigen during natural infection. RNAis required for protein synthesis, does not integrate into the genome, is transiently expressed, is metabolized and eliminated by the natural mechanisms of the body and is therefore considered safe47. RNA-based prophylactic infectious-disease vaccines and RNA therapeutic agents have been shown to be safeand well-tolerated in clinical trials. In general, vaccination with RNAelicitsa robust innate immune response. RNAdirects the
expression of the vaccine antigen in host cellsand has intrinsicadjuvant effects8. A strength of the RNA-vaccine manufacturing platform-irrespective of theencoded pathogen antigen-is the ability to rapidly produce large quantities of vaccine doses against a new pathogen910.
Vaccine RNA can be modified by incorporating 1-methyl-pseudouridine, which dampens innate immune sensing and increases mRNAtranslation in vivo11. The BNT162bl vaccine candidate that is currently investigated clinically incorporates such nucleoside-modified mRNA and encodes the RBD of the spike protein of SARS-CoV-2, a key target ofvirus-neutralizingantibodies1214. The RBD antigen expressed by BNT162bl is modified by the addition of a T4fibritin-derived foldon trimerization domain to increase its immunogenicity15 by multivalent display16. The proper folding of the RBDs in the resulting protein construct has been confirmed by high resolution structural analysis (A.B.V. etal., manuscript in preparation). The vaccine RNA isformulated in lipid nanoparticlesfor more-efficient delivery into cells after intramuscular injection17. BNT162bl is one of several RNA-based SARS-CoV-2 vaccine candidates18 that are studied in parallel for selection to advance
'New York University Langone Vaccine Center, New York, NY, USA. 2New York University Grossman School of Medicine, New York, NY, USA. "University of Maryland School of Medicine, Center for Vaccine Development and Global Health, Baltimore, MD, USA. 4Vaccine Research and Development, Pfizer Inc, Hurley, UK. "Vaccine Research and Development, Pfizer Inc, Pearl River, NY, USA. 6Vaccine Research and Development, Pfizer Inc, Collegeville, PA, USA. 7University of Texas Medical Branch, Galveston, TX, USA. "BioNTech, Mainz, Germany. "University of Rochester, Rochester, NY, USA. '"Rochester General Hospital, Rochester, NY, USA. "Cincinnati Children's Hospital, Cincinnati, OH, USA. ,2These authors contributed equally: Mark J. Mulligan, Kirsten E. Lyke, Nicholas Kitchin. ^e-mail: judith.absalon@pfizer.com
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20 participants were not assigned
76 participants screened
45 participants were enrolled and randomized
11 participants did not meet eligibility criteria
12 were assigned to 10^g BNT162b1
3 were assigned to placebo
12 were assigned to 30 ^g BNT162b1
3 were assigned to placebo
12 were assigned to 100^g BNT162b1
3 were assigned to placebo
12 (100.0%) vaccinated with dose 1
3 (100.0%) vaccinated with dose 1
Study ongoing No withdrawals
12 (100.0%) vaccinated with dose 2
12 (100.0%) vaccinated with dose 1
3 (100.0%) vaccinated with dose 2
3(100.0%) vaccinated with dose 1
Study ongoing No withdrawals
12 (100.0%) vaccinated with dose 2
12 (100.0%) vaccinated with dose 1
3(100.0%) vaccinated with dose 2
3 (100.0%) vaccinated with dose 1
Study ongoing No withdrawals
0 vaccinated with dose 2
0 vaccinated with dose 2
Fig. 11 Study design. Participants who were not assigned (n = 20) were screened but not randomized because enrolment had closed.
to a safety and efficacy trial. Here, we present the available data, up to 14 days after a second dose in adults (18-55 years of age) from an ongoing phase I/I I vaccine study with BNT162bl, which is also enrolling adults who are 65-85 years of age (ClinicalTrials.gov identifier, NCT04368728).
Study design and demographics
Between 4 May 2020 and 19June 2020,76 participants were screened, and 45 participants were randomized and vaccinated. Per dose level (10 pg and 30 pg), 12 participants were vaccinated with BNT162bl on days land 21,12 participants received a 100-pg dose on day land
9 participants received placebo (Fig. 1). The study population consisted of healthy male and female participants with a mean age of 35.4 years (range, 19-54 years); 51.1% were male and 48.9% were female. Most participants self-reported as white (82.2%) and non-Hispanic/ non-Latinx (93.3%) (Extended Data Table 1).
Safety and tolerability
In the 7 days after vaccination doses 1 and 2, pain at the injection site was the most-frequent solicited local reaction, reported after the first dose by 58.3% (7 out of 12) in the 10-pg BNT162bl group, 100.0% (12 out of 12 each) in the 30-pg and 100-pg BNT162bl groups, and 22.2% (2 out of 9) in the placebo group. After the second dose, pain was reported by 83.3% (10 out of 12) and 100.0% of individuals who received 10 pg and 30 pg BNT162bl, respectively, and by 16.7% of individuals who received the placebo. All local reactions were mild or moderate in severity except for one report of severe pain after the first dose of 100 pg BNT162bl (Fig. 2).
The most-common systemic events reported in the 7 days after each vaccination in both BNT162bland placebo groups were mild to moderate fatigue and headache. Reports of fatigue and headache were more common in the BNT162bl groups than in the placebo group. In addition, chills, muscle pain and joint pain were reported by individuals who received BNT162bl but not by individuals who received the placebo. Systemic events increased with dose level and were reported in a greater number of participants after the second dose (10-pg and 30-pg groups). After the first dose, fever (defined as >38.0 °C) was reported by 8.3% (1 out of 12) of participants who received 10 pg and 30 pg BNT162bl and by 50.0% (6 out of 12) of individuals who received 100 pg BNT162bl. After the second dose, 8.3% (1 out of 12) of participants who received
10 pg BNT162bl and 75.0% (9 out of 12) of participants who received 30 pg BNT162bl reported fever of >38.0 °C. On the basis of the reacto-genicity reported after the first dose of 100 pg and the second dose of
30 pg, participants who received an initial 100-pg dose did not receive a second 100-pg dose. Fevers generally resolved within 1 day of onset. No grade 4 systemic events or fever were reported (Fig. 3a, b). Most local reactions and systemic events peaked by day 2 after vaccination and resolved by day 7.
Adverse events (Extended Data Table 2) were reported by 50.0% (6 out of 12) of participants who received either 10 or 30 pg of BNT162bl, 58.3% (7 out of 12) of participants who received 100 pg of BNT162bl, and 11.1% (1 out of 9) of placebo recipients. Two participants reported a severe adverse event: grade 3 fever 2 days after vaccination in the 30-pg group, and sleep disturbance 1 day after vaccination in the 100-pg group. Related adverse events were reported by 25% (3 out of 12 in the 10-pg group) to 50% (6 out of 12 each in the 30-pg and 100-pg groups) of individuals who received BNT162bl and by 11.1% (1 out of 9) of participants who received the placebo. No serious adverse events were reported.
No grade 1 or greater change in routine clinical laboratory values or laboratory abnormalities were observed for most participants after either of the BNT162bl vaccinations. Of those with laboratory changes, the largest changes were decreases in the lymphocyte count after the first dose in 8.3% (1 out of 12), 45.5% (5 out of 11) and 50.0% (6 out of 12) of participants who received 10 pg, 30 pg and 100 pg BNT162bl, respectively. One participant each in the 10-pg (8.3% (1 out of 12)) and 30-pg (9.1% (1 out of 11)) groups and 4 participants in the 100-pg group (33.3% (4 out of 12)) had grade 3 decreases in the lymphocyte count. These decreases in lymphocyte count after the first dose were transient and returned to normal 6-8 days after vaccination (Extended Data Fig. 1). In addition, grade-2 neutropenia was noted 6-8 days after the second dose in 1 participant each in the 10-pg and 30-pg BNT162bl groups. These two participants continue to be followed in the study, and no adverse events or clinical manifestations of neutropenia have been reported to date. None of the post-vaccination abnormalities observed were associated with clinical findings.
Immunogenicity
RBD-binding IgG concentrations and SARS-CoV-2-neutralizing titres were assessed at baseline, at 7 and 21 days after the first dose, at 7 days (day 28) and 14 days (day 35) after the second dose of BNT162bl. By 21 days after the first dose (for all three dose levels), geometric mean concentrations (GMCs) of RBD-binding IgG ranged from 534 to 1,778 U mr1 (Fig. 4a). In comparison, a panel of 38 SARS-CoV-2 infection and/or COVID-19 convalescent sera drawn at least 14 days after a PCR-confirmed diagnosis from patients with COVID-19 (18-83 years
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Fig. 21 Local reactions reported within 7 days of vaccination for all dose levels. Solicited injection-site (local) reactions were: pain at injection site (mild, does not interfere with activity; moderate, interferes with activity; severe, prevents daily activity; grade 4, emergency room visit or hospitalization) and redness and swelling (mild, 2.0-5.0 cm in diameter;
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Fig. 31 Systemic events and medication use reported within 7 days after vaccination, a, Systemic events and medication use reported within 7 days after vaccination 1 for all dose levels, b, Systemic events and medication use reported within 7 days after vaccination 2 for the 10-ug and 30-ug dose levels. Solicited systemic events were: fatigue, headache, chills, new or worsened muscle pain, new or worsened joint pain (mild, does not interfere with activity; moderate, some interference with activity; severe, prevents dailyactivity), vomiting (mild, 1-2 times in 24 h; moderate, >2 times in 24 h; severe, requires
intravenous hydration), diarrhoea (mild, 2-3 loose stools in 24 h; moderate, 4-5 loose stools in 24 h; severe: 6 or more loose stools in 24 h); grade 4 for all events: emergency room visit or hospitalization; and fever (mild, 38.0-38.4 °C; moderate, 38.5-38.9 °C; severe, 39.0-40.0 °C; grade 4, >40.0 °C). Medication indicates the proportion of participants who reported the use of antipyretic or pain medication. Data were collected with the use of electronic diaries for 7 days after each vaccination.
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Fig.41 Immunogenicity of BNT162bl. Participants in groups of 15 were vaccinated with the indicated dose levels of BNT162bl (n = 12) or with placebo (n = 3) on days 1 (all dose levels and placebo) and 21 (10-ug and 30-ug dose levels and placebo). Reponses in individuals who received the placebo for each of the dosing groups are combined. The 28- and 35-day blood samples were obtained 7 and 14 days after the second vaccination. Sera were obtained before vaccination (day 1), and 7,21,28 and 35 days after the first vaccination. Human COVID-19 convalescent sera (HCS, n = 38) were obtained at least 14 days after PCR-conf irmed diagnosis and at a time when the donors were asymptomatic, a, GMCs of recombinant RBD-binding IgG. Because the measured antibody concentrations using the Luminex assay are obtained in arbitrary units, they cannot be directly translated into concentrations on a molar or mass basis. The lower limit of quantitation is 1.15. b, The 50% SARS-CoV-2-neutralizingGMTs. Each data point represents a serum sample, and each vertical bar represents a geometric mean with 95% confidence interval. The number above the bars are either the GMC (a) or GMT (b) for the group. Arrows indicate the timing of vaccination (blood was obtained before vaccination on the vaccination days).
of age) had an RBD-binding IgG GMC of 602 U ml"1. (Additional information on the convalescent serum panel is included in the Methods.) By 7 days after the second dose (for the 10-pg and 30-pg dose levels), RBD-binding IgG GMCs had increased to 4,813 and to 27,872 U ml"1, respectively. RBD-binding antibody concentrations among participants who received one dose of 100 ug BNT162bl did not increase further at 21 days after the first vaccination. In the participants who received the 10-pg and 30-pg doses of BNT162bl, highly elevated RBD-binding antibody concentrations persisted to the last time point evaluated (day 35,14 days after the second dose). These RBD-binding antibody concentrations were 5,880-16,166 U ml"1 compared to 602 U ml"1 in the panel of human convalescent sera.
For all doses, small increases in SARS-CoV-2-neutralizing geometric mean titres (GMTs) were observed 21 days after the first dose (Fig. 4b). Substantially greater serum neutralizing GMTs were achieved 7 days afterthe second 10-pgand 30-pg dose, reachingl68-267. Neutralizing GMTs further increased by 14 days after the second dose to 180 (10-pg dose level) and 437 (30-pg dose level), compared to 94 for the panel of human convalescent sera. The kinetics and durability of the neutralizing titres are being monitored.
Discussion
The RNA-based SARS-CoV-2 vaccine candidate BNT162bl, which was administered as 10-pg, 30-pg or 100-pg doses in healthy adults (18-55 years of age),exhibited a tolerability and safety profile consistent with those previously observed for mRNA-based vaccines5. Aclear dose-level response in elicited neutralizing titres was observed after doses 1 and 2 in participants with a particularly steep dose response between the 10 pg and 30 pg dose levels.
On the basis of the tolerability profileof thefirst doseat 100 pg and the second dose at 30 pg, participants randomized to the 100-pg group did not receive a second vaccination. Reactogenicity was generally greater afterthe second dose in the other two dosing levels; however, symptoms were transient and resolved within a few days. Transient decreases in lymphocyte counts (grades 1-3) were observed within a few days after vaccination, and returned to baseline within 6-8 days in all participants. These laboratory abnormalities were not associated with clinical findings. RNAvaccinesare known to induce type-I interferon, which has been associated with transient migration of lymphocytes into tissues19"22.
Robustimmunogenicity was observed aftervaccination with BNT162bl. RBD-binding IgG concentrations were detected at 21 days after the first dose, and these were substantially increased 7 days after the second dose given at day 21. After the first dose, the RBD-binding IgG GMCs (10-pg dose) weresimilartothoseobserved in a panelof 38convalescent human serum samples,obtained at Ieastl4daysafter a PCR-confirmed diagnosis ofSARS-CoV-2 infection and/or COVID-19. Afterthe first dose,GMCs were similar in the 30-pgand 100-pg groupsand higher than thosein the panel of human convalescent sera. After the second dose, with 10 pg or 30 pg BNT162bl, the RBD-binding IgG GMCs were around 8.0-50-fold that of the GMC of the convalescent serum panel.
The higher RBD-binding IgG GMC elicited by the vaccine relative to the GMC of the human convalescent serum panel may be attributed, in part, to antibodies that bind to epitopes that are exposed on the RNA-expressed RBD immunogen and the recombinant RBD target antigen of the binding assay but are buried and inaccessible to antibodies on the RBDs that are incorporated into the spikesofSARS-CoV-2 virions. Neutralization provides a measure of the vaccine-elicited antibody response that is more relevant to potential protection. Neutralization titres were measurable after a single vaccination at day 21 for all dose levels. At day 28 (7 daysafter the second dose), substantial SARS-CoV-2 neutralization titres wereobserved. The virus-neutralizing GMTs after the second dose of 10 pg and 30 pg were, respectively, 1.8-fold and 2.8-fold the GMT of the convalescent serum panel. By day 35 (14 days after the second dose)-despite a decrease in RBD-binding IgG titres since day 28-neutralizing GMTs continued to increase, to 1.9-fold and 4.6-fold the GMT of the convalescent panel for the 10 pg and 30 pg doses, respectively, which is consistent with affinity maturation.
Assuming that the neutralization titres that are induced by natural infection provide protection from COVID-19, comparing vaccine-induced SARS-CoV-2 neutralization titres to those from sera of convalescent humans provides a benchmark for the magnitude of the vaccine-elicited response and the potential of the vaccine to provide protection. Because the titre at which human neutralizing antibodies are protective remains unknown, these findingsare not proof of vaccine efficacy. Efficacy will be determined in a pivotal phase III trial. Because the cohort that received the 100 pg dose level did not receive the booster dose, no data for immunogenicity after a second vaccination at this dose level are available; however, there were no substantial differences in immunogenicity between the 30-pgand 100-pg dose levelsafter the first dose. This observation suggests that a well-tolerated and immunogenic dose level may be between 10 pg and 30 pg for this vaccine candidate.
Our study had several limitations. Although we used convalescent sera as a comparator, the kind of immunity (T cells versus B cells or both) and level of immunity needed to protect from COVID-19 are unknown. Furthermore, this analysis of available data did not assess
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immune responses or safety beyond 2 weeks after the second dose of vaccine. Both are important to inform the public health use of this vaccine. Follow-up will continue for all participants and will include collection of serious adverse events for 6 months and COVID-19 infection and multiple additional immunogenicity measurements for up to 2 years. Although our population of healthy adults up to 55 years of age is appropriate for a phase I/I I study, it does not accurately reflect the population at highest riskfor COVID-19. Adults who are 65 years of age and over have already been enrolled in this study and results will be reported as they become available. Later phases of this study will prioritize enrolment of more diverse populations, including those with chronic underlying health conditions and from racial and ethnic groups that are adversely affected by COVID-1923.
The clinical testing of BNT162bl described here has taken place in the context of a broader, ongoing COVID-19-vaccine-development program. That program includes theclinical testing of three additional vaccine candidates, including candidates that encode the full-length spike protein, and a parallel trial in Germany, in which additional immune responses, including neutralizing responses against variant strainsand cell-mediated responses,arebeingassessed24. The resulting comparative data will allow us to address whether a full-length spike immunogen, which presents additional epitopes, is better able to elicit high virus-neutralizing titres that are robust to potential antigenic drift of SARS-CoV-2 than the relatively small RBD immunogen that is encoded by BNT162bl. Theclinical findings for the BNT162bl RNA-based vaccine candidate are encouraging and strongly support accelerated clinical development, including efficacy testing, and at-risk manufacturing to maximize the opportunity for the rapid production of a SARS-CoV-2 vaccine to prevent COVID-19.
Online content
Any methods, additional references, Nature Research reporting summaries, source data, extended data, supplementary information, acknowledgements, peer review information; details of author contributions and competing interests; and statements of data and code availabilityareavailableat https://doi.org/10.1038/s41586-020-2639-4.
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Methods
Study design
This study was conducted in healthy men and women (who were not pregnant) who were 18-55 years of age to assess the safety, tolerability and immunogenicity of ascending dose levels of various BNT162 mRNA vaccinecandidates. In the part of the study reported here, assessment of three dose levels (10 ng,30 ngor 100 \ig) of the BNT162bl candidate wasconducted at two sites in the USA. This study used a sentinel cohort design with progression and dose escalation taking place after review of data from the sentinel cohort at each dose level. The study is registered at ClinicalTrials.gov (NCT04368728). The phase I portion of this study wasobserver-blinded at the site level. Investigators were blinded to participant-level study intervention assignment; but investigators were not blinded to group-level assignment for the dataset included in this Article.
Eligibility
Key exclusion criteria included individuals with known infection with human immunodeficiency virus, hepatitis C virus or hepatitis B virus; immunocompromised individuals and those with a history of autoimmune disease; and those with increased risk for severe COVID-19, previous clinical or microbiological diagnosis of COVID-19, receiptor medications intended to prevent COVID-19, previous vaccination with any coronavirus vaccine, a positive serological test for SARS-CoV-2 IgM and/or IgG at the screening visit, and a SARS-CoV-2 nucleic acid amplification test-positive nasal swab within 24 h before study vaccination.
The final protocol and informed consent document were approved by institutional review boardsforeachoftheparticipatinginvestigational centres. This study was conducted in compliance with all International Council for Harmonisation good clinical practice guidelines and the ethical principles of the Declaration of Helsinki. A signed and dated informed consent form was required beforeany study-specific activity was performed.
End points
In this report, results from the following study primary end points are presented: the proportion of participants who reported solicited local reactions, systemic events and use of antipyretic and/or pain medication within 7 daysafter vaccination, adverseeventsand serious adverse events (available up to around 45 days after dosel),and the proportion of participants with clinical laboratory abnormalities 1 and 7 days after vaccination and grading shifts in laboratory assessments between baseline and 1 and 7 days after dose 1, and between dose 2 and 7 days after dose2. Secondary end points included: SARS-CoV-2-neutralizing GMTs and SARS-CoV-2 RBD-binding IgG GMCs 7 and 21 days after dose 1, and 7 and 14 days after dose 2.
Procedures
Study participants were randomly assigned to a vaccine group using an interactive web-based response technology system with each group comprising 15 participants (12 active vaccine recipients and 3 placebo recipients). Participants received two 0.5-ml doses of either BNT162bl or placebo, administered by intramuscular injection into the deltoid muscle.
BNT162bl incorporates a good manufacturing practice-grade mRNA drug substance that encodes the trimerized SARS-CoV-2 spike glycoprotein RBD antigen. The coding sequence for the antigen has been deposited with GenBank (accession number, MN908947.3). The mRNA is formulated with lipids as the mRNA-lipidnanoparticle drug product. The vaccine was supplied as a buffered-liquid solution for intramuscular injection and was stored at -80 °C. The placebo was a sterile saline solution for injection (0.9% sodium chloride injection, in a 0.5-ml dose).
Safety assessments
Safety assessments included a 4-h observation after vaccination (for the first 5 participants vaccinated in each group), or a 30-min observation (for the remainder of participants) for immediate adverse events. The safety assessments also included self-reporting of solicited local reactions (redness, swelling and pain at the injection site), systemic events (fever, fatigue, headache, chills, vomiting, diarrhoea, muscle pain and joint pain), the use of antipyretic and/or pain medication in an electronic diary for 7 days after vaccination, and the reporting of unsolicited adverse events and serious adverse events after vaccination. Haematology and chemistry assessments were conducted at screening, 1 and 7 days after the first dose, and 7 days after the second dose.
There were protocol-specified safety stopping rules for all sentinel cohort participants. Both an internal reviewcommitteeand an external data monitoring committee reviewed all safety data. No stopping rules were met before the publication of this report.
Human convalescent serum panel
The 38 human SARS-CoV-2 infection and/or COVID-19 convalescent sera were drawn from participants, who were 18-83yearsof age, at least 14 days after PCR-confirmed diagnosis, and at a time when participants were asymptomatic. The mean age of the donors was 45 years of age. Neutralizing GMTs in subgroupsof the donors were asfollows: <55years of age, 82 (n = 29); >55 years of age,142 (n = 9); symptomatic infections, 90 (n = 35); asymptomatic infections, 156 (ft = 3). The antibody titrefor the one individual who was hospitalized was 618. The sera were obtained from Sanguine Biosciences, the MT Group and Pfizer Occupational Health and Wellness.
Immunogenicity assessments
For immunogenicity assessments, 50 ml of blood was collected before each study vaccination, at 7 and 21 days after the first dose, andat7and 14 days after the second dose. In the RBD-binding IgG assay,a recombinant SARS-CoV-2RBDcontainingaC-terminal Avitag (Aero Biosystems, SPD-C82E9) and no foldon domain was bound to streptavidin-coated Luminex microspheres. In brief, 1.25 x 107 microspheres/ml were coated with streptavidin by l-ethyl-3-[3-dimethylaminopropyl] carbodiim-ide hydrochloride reaction. Recombinant RBD Avitag was coupled to streptavidin beads by incubating for 90 min at room temperature with shaking (35 rpm). Beads were blocked in 1% BSA buffer for 30 min at room temperature. Heat-inactivated serum from participants was diluted 1:500, l:5,000and 1:50,000 in assay buffer (PBS with 0.5% BSA, 0.05% Tween-20 and 0.02% sodium azide). Followinga 16-20-h incubation at 2-8 °C with shaking (300 rpm), plates were washed three times in a solution containing 0.05% Tween-20. An R-phycoerythrin-conjugated goat anti-human polyclonal antibody (Jackson Labs) was then added to plates for 90 min at room temperature with shaking (300 RPM). Plates were then washed a final time in a solution containing 0.05% Tween-20. Data were captured as median fluorescent intensities using a Luminex reader and converted to U/ml antibody concentrations using a reference standard curve with arbitrary assigned concentrations of 100 U/ ml and accountingfor the serum dilution factor. The reference standard was composed of a pool of five COVID-19 convalescent serum samples (>14 days after PCR diagnosis). Three dilutions are used to increase the likelihood that at least one result for any sample will fall within the usable range of the standard curve. Assay results were reported in U/ ml of IgG. The final assay results areexpressed as the CMC of all sample dilutions that produced a valid assay result within the assay range.
The SARS-CoV-2 neutralization assay used a previously described strain of SARS-CoV-2 (USA_WAl/2020) that had been rescued by reverse genetics and engineered by the insertion of an mNeonGreen gene into open-reading frame 7 of the viral genome25. This reporter virus generates similar plaque morphologies and indistinguishable growth curves from the wild-type virus. Viral master stocks (2 * 107
plaque-forming units per ml) used for the neutralization assay were grown in Vero E6 cells as previously described25. When testing patient convalescent serum specimens, the fluorescent neutralization assay produced comparable results as the conventional plaque reduction neutralization assay26. In brief, serial dilutions of heat-inactivated sera from participants were incubated with the reporter virus to yield an infection rate of approximately 10-30% of the Vero monolayer) for 1 h at 37 °C before inoculating Vero CCL81 cell monolayers (targeted to have 8,000-15,000 cells per well) in 96-well plates to enable the accurate quantification of infected cells. Total cell counts per well were enumerated by nuclear stain (Hoechst 33342) and fluorescent virally infected foci were detected 16-24 h after inoculation with a Cytation 7 Cell Imaging Multi-Mode Reader (BioTek) with Gen5 Image Prime v.3.09. Titres were calculated in GraphPad Prism v.8.4.2 by generating a four-parameter logistical fit of the percentage neutralization at each serial serum dilution. The 50% neutralization titre was reported as the interpolated reciprocal of the dilution that yielded a 50% reduction in fluorescent viral foci.
Statistical analysis
The sample size for the reported part of the study was not based on statistical hypothesis testing. The primary safety objective was evaluated by descriptive summary statistics for local reactions, systemic events, abnormal haematology and chemistry laboratory parameters, adverse events and serious adverse events after each vaccine dose for each vaccine group. The secondary immunogenicity objectives were descriptively summarized at the various time points. All participants with data available were included in the safety and immunogenicity analyses.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this paper.
Data availability
Upon request, and subject to review, Pfizer will provide the data that support the findings of this study. Subject tocertain criteria,conditions and exceptions, Pfizer may also provideaccess to the related individual anonymized participant data. See https://www.pfizer.com/science/ clinical-trials/trial-data-and-results for more information. These data
are interim data from an ongoing study for which the database is not locked. Data have not yet been source-verified or subjected to standard quality check procedures that would occur at the timeof database lock and may therefore be subject to change.
25. Xie, X. et al. An infectious cDNA clone of SARS-CoV-2. Cell Host Microbe 27, 841-848 (2020).
26. Muruato, A. E. et al. A high-throughput neutralizing antibody assay for COVID-19 diagnosis and vaccine evaluation. Nat. Commun. 11,4059 (2020).
Acknowledgements We thank C. Monahan and D. Gantt for writing and editorial support; H. Ma, J. Trammel and K. Challagali for statistical ana lysis support in the generation of this manuscript; all of the participants who volunteered for this study; A. Kottkamp, R. Herati, R. Pellet Madan, M. Olson, M. Samanovic-Golden, E. Cohen, A. Cornelius, L. Frye, H. Youn,
B. Fran, K. Ballani, N. Veling, J. Erb, M. Ali, L. Zhao, S. Rettig, H. Khan, H. Lambert, K. Hu, J. Hyde, M. McArthur, J. Ortiz, R. Rapaka, L. Wadsworth, G. Cummings, T. Robinson, N. Greenberg,
L. Chrisley, W. Somrajit, J. Marron, C. Thomas, K. Brooks, L. Turek, P. Farley, S. Eddington, P. Komninou, M. Reymann, K. Strauss, B. Shrestha, S. Joshi, R. Barnes, R. Sukhavasi, M. Lee, A. Kwon, T. Sharp, E. Pierce, M. Criddle, A. Cline, S. Parker, M. Dickey, K. Buschle, A. Cawein, J. L. Perez, H. Seehra, D. Tresnan, R. Maroko, H.Smith, S. Tweedy, A. Jones,G. Adams, R. Malick, E. Worobetz, E. Weaver, L. Zhang, C. Devlin, D. Boyce, E. Harkins Tull, M. Boaz, M. Cruz,
C. Rosenbaum, C. Miculka, A. Kuhn, F. Bates, P. Strecker, A. Kemmer-Bruck, and the Vaccines Clinical Assay Team and Vaccines Assay Development Team for their assistance during this study. Staffing services were supported in part by an NYU CTSA grant (UL1 TR001445) from the National Center for Advancing Translational Sciences, National Institutes of Health. BioNTech is the sponsor of the study. Pfizer was responsible for the design, data collection, data analysis, data interpretation and writing of the report. The corresponding authors had full access to all of the data in the study and had final responsibility for the decision to submit the data for publication. All study data were available to all authors.
Author contributions K.U.J., P.R.D., W.C.G., N.K., S.L., A.G., R.B., O.T. and U.S. were involved in the design of the overall study and strategy. K.N., M.J.M., E.E.W., R.F. and A.R.F. provided feedback on the study design. W.K., D.C., K.A.S., K.R.T., C.F.-G. and P.-Y.S. performed the immunological analyses. M.J.M., K.N., E.E.W., R.F., A.R.F, K.E.L. and V.R. collected data as study investigators. PL. and K.K. developed the statistical design and oversaw the data analysis. J.A., K.U.J., P.R.D. and W.C.G. drafted the initial version of the manuscript. All authors reviewed and edited the manuscript and approved the final version.
Competing interests N.K., J.A., A.G., S.L., R.B., K.A.S., PL., K.K., W.K., DC, K.R.T., P.R.D., W.C.G. and K.U.J, are employees of Pfizer and may hold stock options. U.S. and O.T. are stock owners, management board members and employees at BioNTech and are inventors on patents and patent applications related to RNA technology. M.J.M., K.E.L., K.N., E.E.W., A.R.F, R.F. and V.R. received compensation from Pfizer for their role as study investigators. C.F.-G. and P.-Y.S. received compensation from Pfizer to perform the neutralization assay.
Additional information
Supplementary information is available for this paper at https://doi.org/10.1038/s41586-020-2639-4.
Correspondence and requests for materials should be addressed to J.A.
Peer review information Nature thanks Barbra Richardson and the other, anonymous,
reviewer(s) for their contribution to the peer review of this work.
Reprints and permissions information is available at http://www.nature.com/reprints.
Article
Baseline Dose 1/Day 1-3 Dose 1/Day 6-8 Pre-Dose2 Dose 2/Day 6-8
Dose     □ Placebo   □ 10 ug  □ 30 ug  H 100 ug
Extended Data Fig. 11 Post vaccination changes in lymphocyte count over circle, placebo; plus, 10 \ig; cross, 30 \ig; triangle, 100 \ig. The box-and-whisker
time. The following time points are shown: dose 1/day 1-3, around 1 day after plots show the median (centre), first and third quartiles (lower and upper
dose 1; dose 1/day 6-8, around 7 days after dose 1; pre-dose 2, before dose 2; edges), and minimum and maximum values (lower and upper whiskers), dose 2/day 6-8, around 7 days after dose 2. Symbols denote group means;
Extended Data Table 11 Demographic characteristics
	10 ug (N=12) n (%)	30 ug (N=12) n (%)	100 ug (N=12) n (%)	Placebo (N=9) n (%)	Total (N=45) n (%)
					
Sex					
Male	7(58.3)	6 (50.0)	5 (41.7)	5 (55.6)	23 (51.1)
Female	5 (41.7)	6 (50.0)	7(58.3)	4 (44.4)	22 (48.9)
Race					
White	8 (66.7)	10(83.3)	11 (91.7)	8 (88.9)	37 (82.2)
Black or African American	1 (8.3)	0	0	0	1 (2.2)
Asian	3 (25.0)	2 (16.7)	1 (8.3)	1(11.1)	7(15.6)
					
Ethnicity					
Hispanic/Latino	1 (8.3)	1 (8.3)	0	0	2 (4.4)
Non-Hispanic/non-Latino	11 (91.7)	10(83.3)	12 (100.0)	9(100.0)	42 (93.3)
Not reported	0	1 (8.3)	0	0	1 (2.2)
Age at vaccination (years)					
Mean (SD)	29.4 (6.39)	35.8 (9.96)	38.3 (9.34)	39.0(11.16)	35.4 (9.71)
Median	26.5	33.5	38.0	41.0	33.0
Min, max	(24, 42)	(23, 52)	(25, 53)	(19, 54)	(19, 54)
N, the number of participants in the specified group or the total sample. This value is the denominator for the percentage calculations, n, the number of participants with the specified characteristic.
Article
Extended Data Table 21 Adverse events
				
	10 ug (N=12)	30 ug (N=12)	100 ug (N=12)	Placebo (N=9)
Adverse Event	n (%)	n (%)	n (%)	n (%)
				
Any event	6 (50.0)	6 (50.0)	7 (58.3)	1(11.1)
Related	3 (25.0)	6 (50.0)	6 (50.0)	1(11.1)
Severe	0	1 (8.3)	1 (8.3)	0
Life-threatening	0	0	0	0
Any serious adverse event	0	0	0	0
Related	0	0	0	0
Severe	0	0	0	0
Life-threatening	0	0	0	0
Any adverse event leading to withdrawal	0	0	0	0
Related	0	0	0	0
Severe	0	0	0	0
Life-threatening	0	0	0	0
Death	0	0	0	0
N, the number of participants in the specified group or the total sample. This value is the denominator for the percentage calculations, n, the number of participants who reported at Least one occurrence of the specified adverse event category. For 'any event', n indicates the number of participants who reported at Least one occurrence of any adverse event. Related, assessed by the investigator as related to the investigational product.
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