CD45 isoforms expression on CD4+ and CD8+ T cells throughout life, from newborns to centenarians: implications for T cell memory

CD4+ and CD8+ peripheral blood T lymphocytes show mutually exclusive expression of CD45RA or CD45R0, two isoforms of the common leukocyte antigen that seem to recognize so-called virgin/unprimed and memory/activated T cells. The expression of these isoforms has been studied by three colour cytofluorimetric analysis on CD4+ or CD8+ peripheral blood CD3+ cells from 22 healthy centenarians, analyzed in a context of 202 healthy donors 0-110 years old. An age-related unbalance of virgin and memory cells was found between CD4+ and CD8+ subsets. As expected, at birgh 95-99% of the CD3+ lymphocytes expressed the CD45RA isoform. A rapid increase of CD45R0+ cells was observed in the first 2-3 decades of life, this phenomenon being much more pronounced on CD4+ cells. Subsequently, the increase of the 'memory' compartment was much less rapid, so that in centenarians a consistent reservoire of CD45RA+ among CD4+ cells was still present (about 20%). In these exceptional individuals the percentage of CD45RA+ cells among CD8+ T lymphocytes was even higher (about 50%), and only slightly lower than that of young donors (about 55-60%). Thus, the main changes occurred at a different rate in CD4+ (about 20%). In these exceptional individuals the percentage of CD45RA+ cells among CD8+ T lymphocytes was even higher (about 50%), and only slightly lower than that of young donors (about 55-60%). Thus, the main changes occurred at a different rate in CD4+ and in CD8+ T cells, at an age of between 0 and 30 years, when the thymus is still functionally active. Interestingly, no difference in the usage of CD45 isoforms was observed within T cells bearing four different V beta-T cell receptor (TCR). The significance of this age-related unbalance is unknown. However, the presence of a great number of CD45RA+ T lymphocytes within the CD4+ and the CD8+ T cell subsets even in the peripheral blood of centenarians poses the problem of their origin (thymus? extrathymic sites?), of their functional role and of their lifespan. Moreover, the data on centenarians suggest that they may represent a very selected population where a slowing of immunosenescence occurs.

[1]  G. Santini,et al.  Age-related changes in human lymphocyte subsets: progressive reduction of the CD4 CD45R (suppressor inducer) population. , 1988, Clinical immunology and immunopathology.

[2]  G. Janossy,et al.  Loss of CD45R and gain of UCHL1 reactivity is a feature of primed T cells. , 1988, Journal of immunology.

[3]  G. Hedlund,et al.  Two subsets of human CD4+T helper cells differing in kinetics and capacities to produce interleukin 2 and interferon‐γ can be defined by the Leu‐18 and UCHLl monoclonal antibodies , 1988, European journal of immunology.

[4]  R. Callard,et al.  Functional subsets of human helper-inducer cells defined by a new monoclonal antibody, UCHL1. , 1986, Immunology.

[5]  M. Thomas,et al.  The leukocyte common antigen family. , 1989, Annual review of immunology.

[6]  G. J. V. Nossal,et al.  Negative selection of lymphocytes , 1994, Cell.

[7]  R. Insel,et al.  Alterations in helper-inducer and suppressor-inducer T-cell subsets in human neonatal blood. , 1988, Immunology.

[8]  K. Hirokawa,et al.  Differential age-change in the numbers of CD4+CD45RA+ DC4+CD29+ T cell subsets in human peripheral blood , 1992, Mechanisms of Ageing and Development.

[9]  C. Franceschi,et al.  Genomic Instability and Aging , 1992 .

[10]  G. Kitas,et al.  Production of lymphokine mRNA by CD45R+ and CD45R- helper T cells from human peripheral blood and by human CD4+ T cell clones. , 1989, Journal of immunology.

[11]  M. Salmon,et al.  A possible role for bcl-2 in regulating T-cell memory--a 'balancing act' between cell death and survival. , 1993, Immunology today.

[12]  M. Davis,et al.  T cell receptor gene diversity and selection. , 1990, Annual review of biochemistry.

[13]  C. S. Scott,et al.  Variant CD45R expression with autosomal dominant inheritance affects both helper/inducer (CD4 +) and suppressor/cytotoxic (CD8 +) T cell populations , 1991, Clinical and experimental immunology.

[14]  J. Strominger,et al.  Interaction between CD4 and class II MHC molecules mediates cell adhesion , 1987, Nature.

[15]  C. Morimoto,et al.  Cyclic regulation of CD45 isoform expression in a long term human CD4+CD45RA+ T cell line. , 1991, Journal of immunology.

[16]  J. Vaupel,et al.  Slowing of mortality rates at older ages in large medfly cohorts. , 1992, Science.

[17]  N. Letvin,et al.  The isolation and characterization of the human suppressor inducer T cell subset. , 1985, Journal of immunology.

[18]  D N Posnett,et al.  Clonal populations of T cells in normal elderly humans: the T cell equivalent to "benign monoclonal gammapathy" [published erratum appears in J Exp Med 1994 Mar 1;179(3):1077] , 1994, The Journal of experimental medicine.

[19]  G F Babcock,et al.  Subpopulations of human natural killer cells defined by expression of the Leu-7 (HNK-1) and Leu-11 (NK-15) antigens. , 1983, Journal of immunology.

[20]  C. Mackay,et al.  Naive and memory T cells show distinct pathways of lymphocyte recirculation , 1990, The Journal of experimental medicine.

[21]  H. Macdonald,et al.  The Cellular Basis of T-Cell Memory , 1989 .

[22]  H. Kurahashi,et al.  Age‐related changes in surface antigens on peripheral lymphocytes of healthy children , 1995, Clinical and experimental immunology.

[23]  A. Cossarizza,et al.  Cytofluorimetric identification of two populations of double positive (CD4+,CD8+) T lymphocytes in human peripheral blood. , 1993, Biochemical and biophysical research communications.

[24]  F Celada,et al.  The cellular basis of immunologic memory. , 1971, Progress in allergy.

[25]  H. Müller-Hermelink,et al.  Admission criteria for immunogerontological studies in man: The senieur protocol , 1984, Mechanisms of Ageing and Development.

[26]  C. Franceschi,et al.  Lack of selective Vβ deletion in CD4+ or CD8+ T lymphocytes and functional integrity of T‐cell repertoire during acute HIV syndrome , 1995, AIDS (London).

[27]  C. Mackay,et al.  T-cell memory: the connection between function, phenotype and migration pathways. , 1991, Immunology today.

[28]  N. Letvin,et al.  The isolation and characterization of the human helper inducer T cell subset. , 1985, Journal of immunology.

[29]  Mark M. Davis,et al.  T-cell antigen receptor genes and T-cell recognition , 1988, Nature.

[30]  W. Kindermann,et al.  Age‐related increase of CD45RO+ lymphocytes in physically active adults , 1993, European journal of immunology.

[31]  H. Matsuda,et al.  Both CD45RA+ and CD45RA- subpopulations of CD8+ T cells contain cells with high levels of lymphocyte function-associated antigen-1 expression, a phenotype of primed T cells. , 1993, Journal of immunology.

[32]  P. Pileri,et al.  Antigen-independent activation of naive and memory resting T cells by a cytokine combination , 1994, The Journal of experimental medicine.

[33]  J. Parnes Molecular biology and function of CD4 and CD8. , 1989, Advances in immunology.

[34]  M. Cooper,et al.  Differential activation requirements for virgin and memory T cells. , 1988, Journal of immunology.

[35]  N. Viner,et al.  The progressive differentiation of primed T cells is associated with an increasing susceptibility to apoptosis , 1994, European journal of immunology.

[36]  C. Franceschi,et al.  Immunosenescence in humans: deterioration or remodelling? , 1995, International reviews of immunology.

[37]  B. McManus,et al.  Age-related changes in naive and memory CD4+ T cells in healthy human children. , 1989, Clinical immunology and immunopathology.

[38]  A. Cossarizza,et al.  T cell repertoire usage in humans, from newborns to centenarians. , 1995, International reviews of immunology.

[39]  G. Steinmann,et al.  On a causal mechanism of chronic thymic involution in man , 1994, Mechanisms of Ageing and Development.

[40]  P. Beverley Human T-cell memory. , 1990, Current Topics in Microbiology and Immunology.

[41]  C. Franceschi,et al.  Cell Proliferation and Cell Death in Immunosenescence a , 1992, Annals of the New York Academy of Sciences.

[42]  L. Pilarski,et al.  Selective expression of CD45 isoforms and of maturation antigens during human thymocyte differentiation: observations and hypothesis. , 1989, Immunology letters.

[43]  T. Springer,et al.  Human memory T lymphocytes express increased levels of three cell adhesion molecules (LFA-3, CD2, and LFA-1) and three other molecules (UCHL1, CDw29, and Pgp-1) and have enhanced IFN-gamma production. , 1988, Journal of immunology.

[44]  J. Sprent,et al.  Turnover of Naive-and Memory-phenotype T Cells , 1994 .

[45]  A. Lesk,et al.  The outline structure of the T‐cell alpha beta receptor. , 1988, The EMBO journal.

[46]  R. Coffman,et al.  Heterogeneity of cytokine secretion patterns and functions of helper T cells. , 1989, Advances in immunology.

[47]  T. Wyss,et al.  Lymphokine gene expression related to CD4 T cell subset (CD45R/CDw29) phenotype conversion , 1989, European journal of immunology.

[48]  L. Terry,et al.  Limiting dilution analysis of proliferative responses in human lymphocyte populations defined by the monoclonal antibody UCHL1: implications for differential CD45 expression in T cell memory formation , 1988, European journal of immunology.

[49]  M. Salmon,et al.  The significance of low bcl-2 expression by CD45RO T cells in normal individuals and patients with acute viral infections. The role of apoptosis in T cell memory , 1993, The Journal of experimental medicine.

[50]  H. Matsuda,et al.  Age‐related accumulation of LFA‐1high cells in a CD8+CD45RAhigh T cell population , 1993, European journal of immunology.

[51]  A. Robert,et al.  Age-related changes of the human skin surface microrelief. , 1990, Gerontology.

[52]  G. Núñez,et al.  Bcl-2 and Bcl-x: regulatory switches for lymphoid death and survival. , 1994, Immunology today.

[53]  C. Franceschi,et al.  NK Cell Activity and T‐Lymphocyte Proliferation in Healthy Centenarians a , 1992, Annals of the New York Academy of Sciences.

[54]  T. Braciale,et al.  Recognition of pre-processed endogenous antigen by class I but not class II MHC-restricted T cells , 1989, Nature.

[55]  R. Mylvaganam,et al.  Sex difference in the CD4 + CD45R+ T lymphocytes in normal individuals and its selective decrease in women with idiopathic thrombocytopenic purpura. , 1989, Clinical immunology and immunopathology.

[56]  C. Franceschi,et al.  The immunology of exceptional individuals: the lesson of centenarians. , 1995, Immunology today.

[57]  D. Knook,et al.  Necessity of the assessment of health status in human immunogerontological studies: Evaluation of the senieur protocol , 1990, Mechanisms of Ageing and Development.

[58]  J. Vaupel,et al.  Demography of genotypes: failure of the limited life-span paradigm in Drosophila melanogaster. , 1992, Science.

[59]  A. Theofilopoulos,et al.  V beta gene repertoires in aging mice. , 1992, Journal of immunology.

[60]  H. Boehmer Positive selection of lymphocytes , 1994, Cell.

[61]  C. Franceschi,et al.  THYMIC HORMONE DEFICIENCY IN NORMAL AGEING AND DOWN'S SYNDROME: IS THERE A PRIMARY FAILURE OF THE THYMUS? , 1984, The Lancet.

[62]  E. Clark,et al.  Leukocyte cell surface enzymology: CD45 (LCA, T200) is a protein tyrosine phosphatase. , 1989, Immunology today.

[63]  L. Hood,et al.  The molecular genetics of the T-cell antigen receptor and T-cell antigen recognition. , 1986, Annual review of immunology.

[64]  C. S. Scott,et al.  Relationships between 2H4 (CD45RA) and UCHL1 (CD45RO) expression by normal blood CD4+CD8−, CD4−CD8+, CD4−CD8dim+, CD3+ CD4−CD8− and CD3−CD4−CD8− lymphocytes , 1990, Clinical and experimental immunology.

[65]  A. McLean,et al.  Lifespan of human lymphocyte subsets defined by CD45 isoforms , 1992, Nature.

[66]  P. Beverley,et al.  Ontogeny of expression of UCHL1 antigen on TcR‐1+ (CD4/8) and TcRδ+ T cells , 1989 .

[67]  C. Franceschi,et al.  Introduction: the reshaping of the immune system with age. , 1995, International reviews of immunology.

[68]  C. Franceschi,et al.  Age-related expansion of functionally inefficient cells with markers of natural killer activity in Down's syndrome. , 1991, Blood.

[69]  M. Salmon,et al.  The synergy between naive and memory T cells during activation. , 1991, Immunology today.

[70]  P. Marrack,et al.  Unexpected expansions of CD8-bearing cells in old mice. , 1993, Journal of immunology.

[71]  A. Weiss Molecular and genetic insights into T cell antigen receptor structure and function. , 1991, Annual review of genetics.

[72]  C. Franceschi,et al.  Preferential expression of Vβ6.7 domain on human peripheral CD4+ T cells. Implication for positive selection of T cells in man , 1991 .

[73]  D. Gray,et al.  B-cell memory is short-lived in the absence of antigen. , 1991, Nature.

[74]  P. Marrack,et al.  The T cell receptor. , 1987, Science.

[75]  L. Bradley,et al.  Predominance of T cells that express CD45R in the CD4+ helper/inducer lymphocyte subset of neonates. , 1989, Clinical immunology and immunopathology.

[76]  E. Bell,et al.  Interconversion of CD45R subsets of CD4 T cells in vivo , 1990, Nature.

[77]  P. Beverley,et al.  Is T-cell memory maintained by crossreactive stimulation? , 1990, Immunology today.

[78]  R. Schwinzer,et al.  Genetically determined lack of CD45R- T cells in healthy individuals. Evidence for a regulatory polymorphism of CD45R antigen expression , 1990, The Journal of experimental medicine.

[79]  C. Franceschi,et al.  Massive activation of immune cells with an intact T cell repertoire in acute human immunodeficiency virus syndrome. , 1995, The Journal of infectious diseases.

[80]  D. Hafler,et al.  Lymphokine regulation of CD45R expression on human T cell clones , 1989, The Journal of experimental medicine.

[81]  M. Passeri,et al.  Lymphocyte subsets and natural killer cell activity in healthy old people and centenarians. , 1993, Blood.

[82]  H. Müller-Hermelink,et al.  The Involution of the Ageing Human Thymic Epithelium is Independent of Puberty , 1985, Scandinavian journal of immunology.