Transcriptional atlas of the human immune response to 13 vaccines reveals a common predictor of vaccine-induced antibody responses

Thomas Hagan; Bram Gerritsen; Lewis E. Tomalin; Slim Fourati; Matthew P. Mulè; Daniel G. Chawla; Dmitri Rychkov; Evan Henrich; Helen E. R. Miller; Joann Diray‐Arce; Patrick Dunn; Audrey Lee; Alison Deckhut-Augustine; Raphaël Gottardo; Elias K. Haddad; David A. Hafler; Eva Harris; Donna L. Färber; Steven H. Kleinstein; Ofer Levy; M. Juliana McElrath; Ruth R. Montgomery; Bjoern Peters; Bali Pulendran; Adeeb Rahman; Elaine F. Reed; Nadine Rouphael; Minne M. Sarwal; Rafick‐Pierre Sékaly; Ana Fernández-Sesma; Alessandro Sette; Ken Stuart; Alkis Togias; John S. Tsang; Ofer Levy; Raphaël Gottardo; Minne M. Sarwal; John S. Tsang; Mayte Suárez‐Fariñas; Rafick‐Pierre Sékaly; Steven H. Kleinstein; Bali Pulendran

doi:10.1038/s41590-022-01328-6

Transcriptional atlas of the human immune response to 13 vaccines reveals a common predictor of vaccine-induced antibody responses

Thomas Hagan(Cincinnati Children's Hospital Medical Center), Bram Gerritsen(Yale University), Lewis E. Tomalin(Icahn School of Medicine at Mount Sinai), Slim Fourati(Emory University), Matthew P. Mulè(Bridge University), Daniel G. Chawla(Yale University), Dmitri Rychkov(University of California, San Francisco), Evan Henrich(Fred Hutch Cancer Center), Helen E. R. Miller(Fred Hutch Cancer Center), Joann Diray‐Arce(Boston Children's Hospital), Patrick Dunn, Audrey Lee(Stanford University), Alison Deckhut-Augustine, Raphaël Gottardo(SIB Swiss Institute of Bioinformatics), Elias K. Haddad(Drexel University), David A. Hafler(Yale University), Eva Harris(University of California, Berkeley), Donna L. Färber(Columbia University Irving Medical Center), Steven H. Kleinstein(Yale University), Ofer Levy(Broad Institute), M. Juliana McElrath(Fred Hutch Cancer Center), Ruth R. Montgomery(Yale University), Bjoern Peters(La Jolla Institute for Immunology), Bali Pulendran(Stanford University), Adeeb Rahman(Icahn School of Medicine at Mount Sinai), Elaine F. Reed(University of California, Los Angeles), Nadine Rouphael(Emory University), Minne M. Sarwal(University of California, San Francisco), Rafick‐Pierre Sékaly(Emory University), Ana Fernández-Sesma(Icahn School of Medicine at Mount Sinai), Alessandro Sette(La Jolla Institute for Immunology), Ken Stuart(Infectious Disease Research Institute), Alkis Togias(Broad Institute), John S. Tsang, Ofer Levy(Broad Institute), Raphaël Gottardo(SIB Swiss Institute of Bioinformatics), Minne M. Sarwal(University of California, San Francisco), John S. Tsang, Mayte Suárez‐Fariñas(Icahn School of Medicine at Mount Sinai), Rafick‐Pierre Sékaly(Emory University), Steven H. Kleinstein(Yale University), Bali Pulendran(Stanford University)

Nature Immunology

October 31, 2022

10.1038/s41590-022-01328-6

Cited by 138Open Access

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Abstract

Systems vaccinology has defined molecular signatures and mechanisms of immunity to vaccination. However, comparative analysis of immunity to different vaccines is lacking. We integrated transcriptional data of over 3,000 samples, from 820 adults across 28 studies of 13 vaccines and analyzed vaccination-induced signatures of antibody responses. Most vaccines induced signatures of innate immunity and plasmablasts at days 1 and 7, respectively, after vaccination. However, the yellow fever vaccine induced an early transient signature of T and B cell activation at day 1, followed by delayed antiviral/interferon and plasmablast signatures that peaked at days 7 and 14–21, respectively. Thus, there was no evidence for a ‘universal signature’ that predicted antibody response to all vaccines. However, accounting for the asynchronous nature of responses, we defined a time-adjusted signature that predicted antibody responses across vaccines. These results provide a transcriptional atlas of immunity to vaccination and define a common, time-adjusted signature of antibody responses. Pulendran and colleagues perform a comparative analysis of transcriptional responses of healthy young adults across 13 different vaccines. They find that while a common transcriptional program is shared across many vaccines, there is significant heterogeneity especially in the kinetics of immune responses.

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