Immune Cell Dynamics in Response to an Acute Laboratory Stressor: a Within-person Between-group Analysis of the Biological Impact of Early Life Adversity

Overview

Journal Stress

Publisher Informa Healthcare

Specialties Biology
Neurology

Date 2022 Nov 21

PMID 36404775

Authors

Laura Etzel

Abner T Apsley

Brooke C Mattern

Waylon J Hastings

Thomas Heller

Nilam Ram

Sue Rutherford Siegel

Idan Shalev

Affiliations

Soon will be listed here.

Abstract

Early life adversity (ELA) is a risk factor for early onset morbidities and mortality, a relationship that may be driven in part by immune system dysregulation. One mechanism of dysregulation that has yet to be fully examined in the context of ELA is alterations to immune cell dynamics in response to acute stress. Using a within-person between-group experimental design, we investigated stress-induced changes in immune cell populations, and how these changes may be altered in individuals with a history of ELA. Participants were young adults ( = 34, aged 18-25 years, 53% female, 47% with a history of ELA). Complete immune cell counts were measured at four time-points over a 5-hour window across two sessions (Trier Social Stress Test [TSST] vs. no-stress) separated by a week. Across all participants, total white blood cells increased over time ((3,84)=38.97, < .001) with a greater increase in response to the TSST compared to the no-stress condition at 240 minutes post-test ( = 0.43±.19; (179)=2.22, = .027). This pattern was mirrored by neutrophil counts. Lymphocyte counts were initially depressed by TSST exposure ( =-205±.67; (184)=-3.07, = .002) but recovered above baseline. ELA status was associated with higher stress-induced immune cell counts, a difference likely driven by increases in neutrophils ((1,22)=4.45, = .046). Overall, these results indicate differential immune cell dynamics in response to acute stress in individuals with a history of ELA. This points to altered immune system functioning in the context of stress, a finding that may be driving increased morbidity and mortality risk for ELA-exposed individuals.

Citing Articles

Early life adversity is associated with differential gene expression in immune cells: A cluster-based analysis across an acute psychosocial stressor.

Etzel L, Apsley A, Hastings W, Ye Q, Shalev I Brain Behav Immun. 2024; 119:724-733.

PMID: 38663776 PMC: 11190835. DOI: 10.1016/j.bbi.2024.04.035.

Relationships between childhood adversity and inflammatory biomarkers in adulthood: A cross-sectional analysis of a middle-to older-aged population.

Pitts C, Millar S, Perry I, Phillips C SSM Popul Health. 2024; 25:101608.

PMID: 38261965 PMC: 10797532. DOI: 10.1016/j.ssmph.2024.101608.

Biological stability of DNA methylation measurements over varying intervals of time and in the presence of acute stress.

Apsley A, Ye Q, Etzel L, Wolf S, Hastings W, Mattern B Epigenetics. 2023; 18(1):2230686.

PMID: 37393564 PMC: 10316737. DOI: 10.1080/15592294.2023.2230686.

Investigating the effects of maltreatment and acute stress on the concordance of blood and DNA methylation methods of estimating immune cell proportions.

Apsley A, Etzel L, Hastings W, Heim C, Noll J, ODonnell K Clin Epigenetics. 2023; 15(1):33.

PMID: 36855187 PMC: 9976543. DOI: 10.1186/s13148-023-01437-5.

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