In the mouse the maturation stage of the peripheral CD4+ CD45RA+ subset is different from that of the CD8+ CD45RA+ subset

NK1.1+ cells and T-cell activation in euthymic and thymectomized C57Bl/6 mice during acute Trypanosoma cruzi infection

Natural killer (NK) cells may provide the basis for resistance to Trypanosoma cruzi infection, because the depletion of NK1.1 cells causes high levels of parasitemia in young C57Bl/6 mice infected with T. cruzi. Indeed, NK1.1 cells have been implicated in the early production of large amounts of interferon (IFN)-gamma, an important cytokine in host resistance. The NK1.1 marker is also expressed on special subpopulations of T cells. Most NK1.1+ T cells are of thymic origin, and their constant generation may be prevented by thymectomy. This procedure, by itself, decreased parasitemia and increased resistance in young mice. However, the depletion of NK1.1+ cells by the chronic administration of a monoclonal antibody (MoAb) (PK-136) did not increase the parasitemia or mortality in thymectomized C57Bl/6 mice infected with T. cruzi (Tulahuen strain). To study the cross-talk between NK1.1+ cells and conventional T cells in this model, we examined the expression of activation/memory markers (CD45RB) on splenic CD4+ and CD8+ T cells from young euthymic or thymectomized mice with or without depletion of NK1.1+ cells and also in aged mice during acute infection. Resistance to infection correlated with the amount of CD4+ T cells that are already activated at the moment of infection, as judged by the number of splenic CD4+ T cells expressing CD45RB(-). In addition, the specific antibody response to T. cruzi antigens was precocious and an accumulation of immunoglobulin (Ig)M with little isotype switch occurred in euthymic mice depleted of NK1.1+ cells. The data presented here suggest that NK1.1+ cells have important regulatory functions in euthymic, but not in thymectomized mice infected with T. cruzi. These regulatory functions include a helper activity in the generation of effector or activated/memory T cells.

Expression in vivo of CD45RA, CD45RB and CD44 on T cell receptor-transgenic CD8+ T cells following immunization

We used mice transgenic for a major histocompatibility complex class I-restricted T cell receptor to study the changes of phenotype in vivo which follow priming by antigen of CD8 T cells. We show that following priming with peptide, CD44 on CD8 T cells is up-regulated. The change of phenotype was relatively stable, as primed CD8 cells isolated from thymectomized mice 6 weeks after priming still expressed increased levels of CD44. CD8 T cells in these mice are still responsive to peptide and could represent long-lived primed cells. No down-regulation in vivo of the CD45RA or CD45RB isoforms was found, indicating that there is a differential regulation of the expression of CD44 and CD45RB by activated CD8 transgenic T cells. These results contradict earlier studies in vitro which showed that CD8 T cells which have been primed earlier belong to the CD45RA- or CD45RB- subset.

Differential expression of various T cell surface markers in young and elderly subjects

The purpose of this study was to investigate the expression of lymphocyte markers in the peripheral blood of aged individuals and of young healthy blood donors. Results showed significant changes in the distribution of various T cell subpopulations. The CD3, CD4 and CD8 surface expression was not different in the elderly patients when compared to the young subjects. The number of CD4+ T cells expressing CD45 RO isoform (memory cells) was increased in aged people; CD45 RA+ CD4+ cells (naive cells) were decreased. The expression of the CD45 RB on the CD4+ cells was significantly lower in the elderly when compared to the young subjects. In contrast, the surface expression of CD45 RO and CD45 RB in the CD8+ cells was not statistically different in the young and aged subjects. The proportion of CD8+ cells coexpressing CD57 was significantly increased in the elderly subjects. These results indicate age-dependent alterations of various surface markers of T cells. These observations may be of importance in the investigation of immunoregulatory mechanisms in geriatric patients with infection, autoimmune disease or cancer.

Immunophenotypic and DNA genotypic analysis of T-cell and NK-cell subpopulations in patients with B-cell chronic lymphocytic leukaemia (B-CLL)

Absolute numbers and distributions of peripheral blood T-cells and NK cells were immunophenotypically determined in 21 patients with B-CLL and compared with those obtained from a series of 13 elderly normal controls with an age range of 60-87 years. For absolute CD3+, CD4+ and CD8+ T-cell, and CD16+ NK subpopulation numbers, there were no consistent differences between the normal and B-CLL groups although some individual patient variation was seen. Immunophenotypic analyses did however reveal that CD3+ T-cells in almost half (10/21) of the B-CLL patients were Ia+ (defined as > 20% positive cells), compared to 0/13 of the elderly control group (p < 0.001), and that the proportions of CD4+ and CD8+ cells expressing membrane CD45RO were significantly increased compared to the control group. Subdivision of the B-CLL cases into those with low (< 20%) and high (> 20%) proportions of CD3+ T-cells co-expressing Ia further showed that CD45RO expression by CD4+ fractions was particularly prominent in the Ia+ subgroup, and that the relative increase of CD4+CD45RO+ cells was primarily a consequence of decreased absolute numbers of CD4+CD45RA+ lymphocytes. This study also examined extracted DNA from enriched CD3+ T-cell fractions (obtained by immunomagnetic bead selection in 9 of the B-CLL cases) by PCR analysis with two primers for the T-cell gamma gene locus. With the V gamma C (consensus) primer, 8/9 cases were polyclonal and the remaining case was oligoclonal. For comparison, 7/9 CD3+ fractions were oligoclonal with the V gamma 9 primer with the other two cases being polyclonal. No monoclonal CD3+ components were found. It is suggested that the observed increased Ia expression by CD3+ cells and the predominance of CD4+ cells expressing membrane CD45RO in patients with B-CLL may be of potential relevance to understanding the pathogenesis and patterns of disease progression.

Aging and lymphokine production by T cell subsets

From sexual maturity to old age, the mammalian immune system undergoes progressive changes, some of which may predispose individuals to infectious, neoplastic and degenerative diseases. These age-associated changes are prominent in the T lymphocyte compartment and encompass both the CD4+ and CD8+ T cell subpopulations. In this review, we focus on the mouse model system and summarize current information on the existence of functionally distinct subsets within each of the CD4+ and CD8+ cell subpopulations. We describe how the representation of these subsets is altered during the aging process, with consequent changes in the lymphokine production repertoires and other functional attributes of the T cell pool. Lastly, we present evidence showing that similar changes occur in aging humans and discuss the potential impact of these changes on immune responsiveness in late life.

Hyper-reactivity of mouse CD45RA- T cells

Mouse CD4 T cells have been partitioned into CD45RA and CD45RA- subpopulations by means of the monoclonal antibody 14.8. The CD45RA- subpopulation proliferated more actively and generated more interleukin-4 (IL-4) in response to stimulation with anti-CD3 antibody and phytohemagglutinin, and more IL-2 in response to anti-CD3. This subpopulation is therefore hyper-reactive to these polyclonal stimulators, but does not show the bias towards T helper type 2 activity that has been found in studies with other related CD45 isoforms. No evidence of suppression was obtained by comparing proliferation of CD45RA- cells in the presence and absence of CD45RA cells. Thus mouse CD4 T cells behave in these respects similarly to those of man, as is evident in a brief review of the quiescence-activation-quiescence cycle in the two species.

Abnormal CD45R expression in patients with common variable immunodeficiency and X-linked agammaglobulinaemia

This study has investigated the patterns of membrane 2H4 (CD45RA) and UCHL1 (CD45RO) expression by CD4+ and CD8+ lymphocyte subpopulations in 10 adults and seven children with common variable immunodeficiency (CVI) and X-linked hypogammaglobulinaemia (XLA). Of the 10 adults (CVI, n = 8; XLA, n = 2), only one with a diagnosis of CVI showed normal CD45R expression. For the remaining seven adult CVI patients the abnormal CD45R profiles were primarily associated with CD4+ lymphocytes in three and CD8+ lymphocytes in four. Specific increases in CD45RA- CD45RO+ fractions were found in four CVI patients and in all of these there was a concomitant reduction in circulating CD19+ B-cell numbers. Two of the CVI cases were identical twin sisters and both had the same CD45R abnormality. The two adults with XLA also showed abnormal CD45R expression (increased CD45RA+ CD45RO- components) but of particular note, in view of the fact that these were brothers, one was associated with the CD4+ subpopulation and the other with the CD8+ fraction. Similar analyses for the paediatric group revealed, in distinct contrast to the adult patients, no significant abnormalities of CD45R expression suggesting that these defects may not become apparent until a later age. Further investigations of in vitro lymphocyte proliferation (PHA and PWM) in the eight adults with CVI showed a significant correlation between abnormal responses and disordered CD45R expression. It is proposed that these abnormal patterns of CD45R expression by lymphocyte subpopulations in CVI and XLA may be of fundamental importance with respect to the pathogenesis of these particular immunodeficiencies.

The variable occurrence of CD45RA on CD8+ thymocytes correlates with the presence of Mtv sequences; its expression on other thymocytes is rare

While all thymocytes express CD45, only a small fraction (less than 3% in mice) bear the high molecular weight isoform, CD45RA. It has been suggested that these cells alone constitute the generative thymocyte lineage and should, therefore, occur within every ontogenic subset. To test this, we determined CD45RA expression among thymocyte subsets defined by CD4 and CD8. In some strains, exemplified by C57BL/Icrf, very few (less than 0.2%) T thymocytes expressed CD45RA and were mostly CD4-CD8- or CD4+CD8+, inconsistent with them constituting the generative lineage. In others, exemplified by BALB/c, CD45RA was expressed on up to 3% of T thymocytes, which were mostly CD4-CD8+. The limited occurrence of CD4-CD8+CD45RA+ thymocytes suggests that they are a nonconstitutive subset playing a role in the thymus of only some strains. Their occurrence correlates with that of Mtv proviruses within the mouse genome; however, their T cell receptor V beta repertoire is diverse, suggesting they are not uniquely selected by Mtv superantigens. We propose that they may be mature CD8 T cells, possibly responsible for introducing viral superantigens into the thymus.

Memory in helper T cells of minor histocompatibility antigens, revealedin vivo by alloimmunizations in combination with Thy-1 antigen

A cooperative antibody response in which T helper (Th) cells recognize minor histocompatibility antigens (mha) and B cells recognize Thy-1 antigen, is used to explore memory in the T cell compartment. In contrast to B cell memory, Th memory reaches a plateau rapidly, although Th memory of Thy-1 itself (or an associated antigen) behaves exceptionally in this respect. The plateau then extends over several weeks at least. Single mha, among them H-Y, generate detectable memory. Incompatible H-2 antigens, including class I antigens on their own, inhibit this response through what appears to be a mechanism of intracellular antigenic competition. Antigen presentation in this system is by host cells, as judged by lack of donor-specific restriction. Memory resides in both the CD45RA+ and CD45RA- compartments, although the majority of memory Th cells have the latter phenotype.