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Perturbation of the preterm human immune system in early life
Benjamin A. Fensterheim, Michelle L. McKeague, Divij Mathew, Shwetank, Ajinkya Pattekar, Matthew Lee, Zahabia Rangwala, Sean Nasta, Macy C. Kee, Cynthia Clendenin, Zachary Martinez, Caroline Diorio, Allison R. Greenplate, Krithika Lingappan, E. John Wherry
Benjamin A. Fensterheim, Michelle L. McKeague, Divij Mathew, Shwetank, Ajinkya Pattekar, Matthew Lee, Zahabia Rangwala, Sean Nasta, Macy C. Kee, Cynthia Clendenin, Zachary Martinez, Caroline Diorio, Allison R. Greenplate, Krithika Lingappan, E. John Wherry
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Research Article Development Immunology Inflammation

Perturbation of the preterm human immune system in early life

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Abstract

Although inflammatory complications are common in preterm infants, the effects of these conditions on neonatal immune development remain poorly defined. We therefore investigated whether severe bronchopulmonary dysplasia (BPD) and systemic infection, 2 major complications of prematurity, produce distinct immune signatures and change immune composition over time. We performed longitudinal high-dimensional immune profiling of residual whole blood from 38 preterm infants sampled every 2 weeks, along with 10 term infants at birth. Preterm infants with severe BPD showed a progressive increase in Th17-polarized CD4+ T cells, neutrophils, and Th17-related cytokines compared with age-matched infants with moderate BPD. In contrast, some preterm infants with systemic bacterial or viral infections mounted exceptionally robust CD8+, CD4+, and γδ T cell responses, with oligoclonal expansion, terminal differentiation, and coordinated plasma cytokine shifts that persisted well beyond resolution of infection. These findings demonstrate that different preterm comorbidities imprint the neonatal immune system in divergent ways. Thus, comprehensive and longitudinal immune profiling may not only identify connections between clinical inflammatory complications and underlying immune pathways but also reveal potential targets for intervention.

Authors

Benjamin A. Fensterheim, Michelle L. McKeague, Divij Mathew, Shwetank, Ajinkya Pattekar, Matthew Lee, Zahabia Rangwala, Sean Nasta, Macy C. Kee, Cynthia Clendenin, Zachary Martinez, Caroline Diorio, Allison R. Greenplate, Krithika Lingappan, E. John Wherry

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Figure 4

Systemic infection is associated with a sudden, massive, and persistent CD8+ T cell reaction.

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Systemic infection is associated with a sudden, massive, and persistent ...
(A) Schematic representing the progression of the total CD8+ T cell population of 4 infants in the study. Sequential CyTOF plots gated on CD8+ T cells shown for each infant. The day of life each sample was collected is denoted above each plot. For each CyTOF plot, x axis = CD45RA, y axis = CD27, z axis (color) = CCR7. Overview plot to the right of each sequence represents specific CD8+ T cell subpopulations as they change over time including CM, EM1, EM2, EM3, EMRA, and CD57+ cells as a percent of the total CD8+ T cell population. (B) Density UMAP of all CD8+ T cells derived from all samples. Expression of specific markers, IL-7Rα, CCR7, CD27, and CD45RO overlayed on the CD8+ T cell UMAP for reference (red indicates high expression, blue indicates low expression). Density UMAP of all samples with > 85% naive CD8+ T cells (denoted “No Reaction”) and < 85% naive CD8+ T cells (denoted “Reaction”). (C) CD8+ T cell subpopulations found in samples with and without a reaction. Dot color corresponds to samples from the respective color of the infant as presented in A. Samples from infants with no reaction or samples drawn prior to a reaction in gray. *P < 0.05 via BH-adjusted Wilcoxon test.

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