Quantification of T-cell dynamics: From telomeres to DNA labelling
Publication date
2007
Authors
Borghans, J.A.M.
Boer, R.J. de
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Document Type
Article
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Abstract
Immunology has traditionally been a qualitative science
describing the cellular and molecular components of the immune system
and their functions. Only quite recently have new experimental techniques
paved the way for a more quantitative approach of immunology.
Lymphocyte telomere lengths have been measured to get insights into
the proliferation rate of different lymphocyte subsets, T-cell receptor
excision circles have been used to quantify the daily output of new T cells
from the thymus, and bromodeoxyuridine and stable isotope labeling have
been applied to measure proliferation and death rates of naive and memory
lymphocytes. A common problem of the above techniques is the translation
of the resulting data into relevant parameters, such as the typical division
and death rate of the different lymphocyte populations. Theoretical
immunology has contributed significantly to the interpretation of such
quantitative experimental data, thereby resolving diverse controversies
and, most importantly, has suggested novel experiments, allowing for
more conclusive and quantitative interpretations. In this article, we review
a variety of different models that have been used to interpret data on
lymphocyte kinetics in healthy human subjects and discuss their
contributions and limitations.
Keywords
T-cell dynamics, telomeres, TREC, BrdU, stable isotopes, mathematical modeling