Quantification of T-cell dynamics during latent cytomegalovirus infection in humans

Berg, Sara P. H. van den; Derksen, Lyanne Y; Drylewicz, Julia; Nanlohy, Nening M.; Beckers, Lisa; Lanfermeijer, Josien; Gessel, Stephanie; Vos, Martijn; Otto, Sigrid A.; Boer, Rob J. de; Tesselaar, Kiki; Borghans, José A. M.; Baarle, Debbie van

doi:10.1371/journal.ppat.1010152

Cited by 18 publications

(20 citation statements)

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“…This is contributed by the existence of memory cells [ 38 ]. Immunologists regarded the long-lasting B-cells or T-cells as “memory cells.” Experiments gradually demonstrated that although the so-called “memory cells” are some specific forms of immune cells [ 39 , 40 ], they have similar half-lives as normal CD8+ cells [ 41 ]. Therefore, maintaining antibody levels in “memory cells” should be explained as a state of equilibrium between decay and regeneration.…”

Section: Resultsmentioning

confidence: 99%

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

Wei

Zhang

et al. 2023

Viruses

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Infectious diseases such as SARS-CoV-2 pose a considerable threat to public health. Constructing a reliable mathematical model helps us quantitatively explain the kinetic characteristics of antibody-virus interactions. A novel and robust model is developed to integrate antibody dynamics with virus dynamics based on a comprehensive understanding of immunology principles. This model explicitly formulizes the pernicious effect of the antibody, together with a positive feedback stimulation of the virus–antibody complex on the antibody regeneration. Besides providing quantitative insights into antibody and virus dynamics, it demonstrates good adaptivity in recapturing the virus-antibody interaction. It is proposed that the environmental antigenic substances help maintain the memory cell level and the corresponding neutralizing antibodies secreted by those memory cells. A broader application is also visualized in predicting the antibody protection time caused by a natural infection. Suitable binding antibodies and the presence of massive environmental antigenic substances would prolong the protection time against breakthrough infection. The model also displays excellent fitness and provides good explanations for antibody selection, antibody interference, and self-reinfection. It helps elucidate how our immune system efficiently develops neutralizing antibodies with good binding kinetics. It provides a reasonable explanation for the lower SARS-CoV-2 mortality in the population that was vaccinated with other vaccines. It is inferred that the best strategy for prolonging the vaccine protection time is not repeated inoculation but a directed induction of fast-binding antibodies. Eventually, this model will inform the future construction of an optimal mathematical model and help us fight against those infectious diseases.

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Section: Resultsmentioning

confidence: 99%

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

Wei

Zhang

et al. 2023

Viruses

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“…The prevalence of CMV infection correlates with age and significantly impact the T cell compartment. ( 16 , 17 ) To enable us to compare age-related changes with those induced by CMV infection, our cohort was equally balanced by age and CMV infection status. Large shifts in cell type composition were correlated with CMV infection status, as highlighted by increased proportion of effector populations.…”

Section: Resultsmentioning

confidence: 99%

Distinct Heterogeneity in the Naive T cell Compartments of Children and Adults

Gustafson

Thomson

et al. 2022

Preprint

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The naive T cell compartment undergoes multiple changes across age that associate with altered susceptibility to infection and autoimmunity. In addition to the acquisition of naive-like memory T cell subsets, mouse studies describe substantial molecular reprogramming of the naive compartment in adults compared with adolescents. However, these alterations are not well delineated in human aging. Using a new trimodal single cell technology (TEA-seq), we discovered that the composition and transcriptional and epigenetic programming of the naive T cell compartment in children (11-13 yrs) is distinct from that of older adults (55-65 yrs). Naive CD4 T cells, previously considered relatively resistant to aging, exhibited far more pronounced molecular reprogramming than naive CD8 T cells, in which alterations are preferentially driven by shifts in naive-like memory subsets. These data reveal the complex nature of the naive T cell compartment that may contribute to differential immune responses across the spectrum of human age.

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“…The frequent CMV activation induces antibodies and T‐cell clones to the virus, which are mostly of CD8 + EM and TEMRA origin (Fuchs et al, 2019 ). A recent study, however, showed that the changes in the T‐cell pool of CMV‐infected individuals cannot be explained by the presence of large numbers of CMV‐specific T‐cells suggesting that CMV infection may also affect the phenotype of non‐CMV specific CD8 + T‐cells (van den Berg et al, 2021 ).…”

Section: Discussionmentioning

confidence: 99%

Epigenetic quantification of immunosenescent CD8⁺ TEMRA cells in human blood

et al. 2022

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Age‐related changes in human T‐cell populations are important contributors to immunosenescence. In particular, terminally differentiated CD8+ effector memory CD45RA+ TEMRA cells and their subsets have characteristics of cellular senescence, accumulate in older individuals, and are increased in age‐related chronic inflammatory diseases. In a detailed T‐cell profiling among individuals over 65 years of age, we found a high interindividual variation among CD8+ TEMRA populations. CD8+ TEMRA proportions correlated positively with cytomegalovirus (CMV) antibody levels, however, not with the chronological age. In the analysis of over 90 inflammation proteins, we identified plasma TRANCE/RANKL levels to associate with several differentiated T‐cell populations, including CD8+ TEMRA and its CD28− subsets. Given the strong potential of CD8+ TEMRA cells as a biomarker for immunosenescence, we used deep‐amplicon bisulfite sequencing to match their frequencies in flow cytometry with CpG site methylation levels and developed a computational model to predict CD8+ TEMRA cell proportions from whole blood genomic DNA. Our findings confirm the association of CD8+ TEMRA and its subsets with CMV infection and provide a novel tool for their high throughput epigenetic quantification as a biomarker of immunosenescence.

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Quantification of T-cell dynamics during latent cytomegalovirus infection in humans

Cited by 18 publications

References 50 publications

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

Distinct Heterogeneity in the Naive T cell Compartments of Children and Adults

Epigenetic quantification of immunosenescent CD8⁺ TEMRA cells in human blood

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Quantification of T-cell dynamics during latent cytomegalovirus infection in humans

Cited by 18 publications

References 50 publications

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

A Novel Mathematical Model That Predicts the Protection Time of SARS-CoV-2 Antibodies

Distinct Heterogeneity in the Naive T cell Compartments of Children and Adults

Epigenetic quantification of immunosenescent CD8+ TEMRA cells in human blood

Contact Info

Product

Resources

About

Epigenetic quantification of immunosenescent CD8⁺ TEMRA cells in human blood