Your search keyword '"Costa Del Amo P"' showing total 5 results

1. The Rules of Human T Cell Fate in vivo

Author

Pedro Costa del Amo, Bisrat Debebe, Milad Razavi-Mohseni, Shinji Nakaoka, Andrew Worth, Diana Wallace, Peter Beverley, Derek Macallan, and Becca Asquith

Subjects

lymphocyte, fate, decision, proliferation, lifespan, mathematical model, Immunologic diseases. Allergy, RC581-607

Abstract

The processes governing lymphocyte fate (division, differentiation, and death), are typically assumed to be independent of cell age. This assumption has been challenged by a series of elegant studies which clearly show that, for murine cells in vitro, lymphocyte fate is age-dependent and that younger cells (i.e., cells which have recently divided) are less likely to divide or die. Here we investigate whether the same rules determine human T cell fate in vivo. We combined data from in vivo stable isotope labeling in healthy humans with stochastic, agent-based mathematical modeling. We show firstly that the choice of model paradigm has a large impact on parameter estimates obtained using stable isotope labeling i.e., different models fitted to the same data can yield very different estimates of T cell lifespan. Secondly, we found no evidence in humans in vivo to support the model in which younger T cells are less likely to divide or die. This age-dependent model never provided the best description of isotope labeling; this was true for naïve and memory, CD4+ and CD8+ T cells. Furthermore, this age-dependent model also failed to predict an independent data set in which the link between division and death was explored using Annexin V and deuterated glucose. In contrast, the age-independent model provided the best description of both naïve and memory T cell dynamics and was also able to predict the independent dataset.

Published

2020

2. Human TSCM cell dynamics in vivo are compatible with long-lived immunological memory and stemness.

Author

Pedro Costa Del Amo, Julio Lahoz-Beneytez, Lies Boelen, Raya Ahmed, Kelly L Miners, Yan Zhang, Laureline Roger, Rhiannon E Jones, Silvia A Fuertes Marraco, Daniel E Speiser, Duncan M Baird, David A Price, Kristin Ladell, Derek Macallan, and Becca Asquith

Subjects

Biology (General), QH301-705.5

Abstract

Adaptive immunity relies on the generation and maintenance of memory T cells to provide protection against repeated antigen exposure. It has been hypothesised that a self-renewing population of T cells, named stem cell-like memory T (TSCM) cells, are responsible for maintaining memory. However, it is not clear if the dynamics of TSCM cells in vivo are compatible with this hypothesis. To address this issue, we investigated the dynamics of TSCM cells under physiological conditions in humans in vivo using a multidisciplinary approach that combines mathematical modelling, stable isotope labelling, telomere length analysis, and cross-sectional data from vaccine recipients. We show that, unexpectedly, the average longevity of a TSCM clone is very short (half-life < 1 year, degree of self-renewal = 430 days): far too short to constitute a stem cell population. However, we also find that the TSCM population is comprised of at least 2 kinetically distinct subpopulations that turn over at different rates. Whilst one subpopulation is rapidly replaced (half-life = 5 months) and explains the rapid average turnover of the bulk TSCM population, the half-life of the other TSCM subpopulation is approximately 9 years, consistent with the longevity of the recall response. We also show that this latter population exhibited a high degree of self-renewal, with a cell residing without dying or differentiating for 15% of our lifetime. Finally, although small, the population was not subject to excessive stochasticity. We conclude that the majority of TSCM cells are not stem cell-like but that there is a subpopulation of TSCM cells whose dynamics are compatible with their putative role in the maintenance of T cell memory.

Published

2018

3. Human Stem Cell-like Memory T Cells Are Maintained in a State of Dynamic Flux

Author

Ahmed, Raya, Roger, Laureline, Costa del Amo, Pedro, Miners, Kelly L., Jones, Rhiannon E., Boelen, Lies, Fali, Tinhinane, Elemans, Marjet, Zhang, Yan, Appay, Victor, Baird, Duncan M., Asquith, Becca, Price, David A., Macallan, Derek C., and Ladell, Kristin

Abstract

Adaptive immunity requires the generation of memory T cells from naive precursors selected in the thymus. The key intermediaries in this process are stem cell-like memory T (TSCM) cells, multipotent progenitors that can both self-renew and replenish more differentiated subsets of memory T cells. In theory, antigen specificity within the TSCMpool may be imprinted statically as a function of largely dormant cells and/or retained dynamically by more transitory subpopulations. To explore the origins of immunological memory, we measured the turnover of TSCMcells in vivo using stable isotope labeling with heavy water. The data indicate that TSCMcells in both young and elderly subjects are maintained by ongoing proliferation. In line with this finding, TSCMcells displayed limited telomere length erosion coupled with high expression levels of active telomerase and Ki67. Collectively, these observations show that TSCMcells exist in a state of perpetual flux throughout the human lifespan.

Published

2016

4. The Rules of Human T Cell Fate in vivo .

Author

Costa Del Amo P, Debebe B, Razavi-Mohseni M, Nakaoka S, Worth A, Wallace D, Beverley P, Macallan D, and Asquith B

Subjects

Cell Death immunology, Cell Differentiation immunology, Cell Division immunology, Humans, Models, Theoretical, T-Lymphocytes immunology

Abstract

The processes governing lymphocyte fate (division, differentiation, and death), are typically assumed to be independent of cell age. This assumption has been challenged by a series of elegant studies which clearly show that, for murine cells in vitro , lymphocyte fate is age-dependent and that younger cells (i.e., cells which have recently divided) are less likely to divide or die. Here we investigate whether the same rules determine human T cell fate in vivo . We combined data from in vivo stable isotope labeling in healthy humans with stochastic, agent-based mathematical modeling. We show firstly that the choice of model paradigm has a large impact on parameter estimates obtained using stable isotope labeling i.e., different models fitted to the same data can yield very different estimates of T cell lifespan. Secondly, we found no evidence in humans in vivo to support the model in which younger T cells are less likely to divide or die. This age-dependent model never provided the best description of isotope labeling; this was true for naïve and memory, CD4 + and CD8 + T cells. Furthermore, this age-dependent model also failed to predict an independent data set in which the link between division and death was explored using Annexin V and deuterated glucose. In contrast, the age-independent model provided the best description of both naïve and memory T cell dynamics and was also able to predict the independent dataset., (Copyright © 2020 Costa del Amo, Debebe, Razavi-Mohseni, Nakaoka, Worth, Wallace, Beverley, Macallan and Asquith.)

Published

2020

5. Human TSCM cell dynamics in vivo are compatible with long-lived immunological memory and stemness.

Author

Costa Del Amo P, Lahoz-Beneytez J, Boelen L, Ahmed R, Miners KL, Zhang Y, Roger L, Jones RE, Marraco SAF, Speiser DE, Baird DM, Price DA, Ladell K, Macallan D, and Asquith B

Subjects

Adult, Aged, 80 and over, CD4-Positive T-Lymphocytes cytology, CD4-Positive T-Lymphocytes immunology, CD8-Positive T-Lymphocytes cytology, CD8-Positive T-Lymphocytes immunology, Humans, Kinetics, Mathematical Concepts, Middle Aged, Models, Immunological, T-Lymphocyte Subsets cytology, Telomere Homeostasis immunology, Yellow fever virus immunology, Cell Self Renewal immunology, Immunologic Memory, T-Lymphocyte Subsets immunology

Abstract

Adaptive immunity relies on the generation and maintenance of memory T cells to provide protection against repeated antigen exposure. It has been hypothesised that a self-renewing population of T cells, named stem cell-like memory T (TSCM) cells, are responsible for maintaining memory. However, it is not clear if the dynamics of TSCM cells in vivo are compatible with this hypothesis. To address this issue, we investigated the dynamics of TSCM cells under physiological conditions in humans in vivo using a multidisciplinary approach that combines mathematical modelling, stable isotope labelling, telomere length analysis, and cross-sectional data from vaccine recipients. We show that, unexpectedly, the average longevity of a TSCM clone is very short (half-life < 1 year, degree of self-renewal = 430 days): far too short to constitute a stem cell population. However, we also find that the TSCM population is comprised of at least 2 kinetically distinct subpopulations that turn over at different rates. Whilst one subpopulation is rapidly replaced (half-life = 5 months) and explains the rapid average turnover of the bulk TSCM population, the half-life of the other TSCM subpopulation is approximately 9 years, consistent with the longevity of the recall response. We also show that this latter population exhibited a high degree of self-renewal, with a cell residing without dying or differentiating for 15% of our lifetime. Finally, although small, the population was not subject to excessive stochasticity. We conclude that the majority of TSCM cells are not stem cell-like but that there is a subpopulation of TSCM cells whose dynamics are compatible with their putative role in the maintenance of T cell memory., Competing Interests: The authors have declared that no competing interests exist.

Published

2018