Biochemical association of CD45 with the T cell receptor complex: regulation by CD45 isoform and during T cell activation.

CD45 is the predominant transmembrane tyrosine phosphatase in lymphocytes and is required for the efficient induction of T cell receptor signaling and activation. However, the regulation of CD45 activity and substrate specificity are poorly understood. In the present study, we demonstrate a basal biochemical association of CD45 with the T cell receptor complex that is regulated in part by CD45 isoform expression. Further, maintenance of CD45/TCR association is differentially regulated following TCR ligation with peptide: a partial agonist peptide induces CD45/TCR dissociation while an agonist peptide promotes sustained association in a CD4-dependent manner. These data suggest that T cell receptor signaling pathways may be modulated by altering access of CD45 to TCR-associated substrates involved in T cell activation.     

CD4+ T cell hyper-responsiveness in CD45 transgenic mice is independent of isoform

The CD45 tyrosine phosphatase is required for T cell development and function by virtue of its role as a positive regulator of src family kinase activity. In addition, recent data have highlighted that CD45 also acts as a negative regulator of Lck function by dephosphorylation of critical tyrosine residues. Lck functionality and TCR responsiveness are elevated in transgenic mice expressing the CD45RO isoform at 'intermediate' (10-40% of wild type) levels, indicating that the expression level of CD45 is critical in determining the sensitivity of T cells to TCR stimulation. However, it is unclear whether such a phenotype is specific for the CD45RO isoform, typically expressed by activated T cells. In the present work, the roles of three isoforms of CD45, RO, RB and RABC, in thymocyte development, T cell responses and TCR signalling pathways were directly compared. The data demonstrate that expression of CD45RB or CD45RABC at intermediate levels also results in CD4(+) T cell hyper-reactivity, as previously published for CD45RO. These data emphasize the dual functions of CD45 as both a positive and a negative regulators of TCR signalling irrespective of specific isoform expression.     

CD45 isoform expression during T cell development in the thymus.

Various isoforms of leukocyte common antigen, or CD45, are expressed differentially on T cells at different stages of development and activation. We report studies on CD45 isoform expression on various subsets of human T cells using two- and three-color flow cytometry and cell depletion. Bone marrow cells that were depleted of CD3+ and HLA-DR+ cells were CD45RA-RO-. The earliest CD3-CD4-CD8-CD19- thymocytes were CD45RO- with 20%-30% CD45RA+ cells. The most prominent population of CD4+CD8+ double-positive thymocytes were CD45RA-RO+. Even the CD4+CD8+ blasts were greater than 90% CD45RO+. About 80% of single-positive thymocytes (CD4+CD8- or CD4-CD8+) were also CD45RO+. Only 4.3% of CD4+ and 18% of CD8+ single-positive thymocytes were CD45RA+. In contrast, cord blood T cells which represent the stage that immediately follows single-positive thymocytes, contained 90% CD45RA+ cells. Thus, in terms of CD45 isoform expression, single-positive thymocytes are more like double-positive cells than cord blood T cells. These results suggest the following sequence of CD45 isoform switching during T cell development: CD45RA-RO- or RA+RO- (double-negative thymocytes)----RA-RO+ (double-positive and most single-positive thymocytes)----RA+RO- (cord blood T cells), the last switch from CD45RO to CD45RA occurring as a final step of maturation in the thymus.     

Membrane CD45R isoform exchange on CD4 T cells is rapid,frequent and dynamic in vivo

CD4 T cells bearing high (240–190 kDa) and low (180 kDa) molecular mass isoforms of the leukocyte common antigen CD45 define functionally distinct subsets which have been equated with naive and memory T cells. In the rat, CD4 T cells expressing a high molecular mass isoform [identified by monoclonal antibody MRC-OX22 (anti-CD45RC)] exchange this for the 180 kDa molecule (CD45RC^?) when stimulated by antigen. Here we show, by transferring mature allotype-marked CD45RC^? CD4 T cells (depleted of immature Thy-1⁺ CD45RC^? recent thymic emigrants) into normal euthymic recipients, that many T cells re-express the high molecular mass isoform in less than 6 h. By 24 h, 30–60% of CD45RC^? CD4 T cells became CD45RC⁺; within a week the entire cohort appeared to exchange the low for the high molecular mass isoform. Isoform exchange was dynamic and many CD4 T cells returned once again to the CD45RC^? state. CD45RC^? CD4 T cells declined in number more rapidly than the CD45RC⁺ subset after transfer. The results suggest that CD45R isoforms distinguish between resting T cells (CD45RC⁺) and those which have encountered antigen in the recent past. CD45R isoforms would appear to be unsuitable markers of naive and memory T cells.     

Functional analysis of human T cell subsets defined by CD45 isoform expression.

The properties of human CD45RA and CD45RO T cells are described. CD45RO cells respond to recall antigens and provide help for B lymphocytes. They produce a wide variety of cytokines including IL-2, IL-4 and IFN-gamma. CD45RA T cells respond poorly to recall antigens and produce mainly IL-2. The phenotype of CD45RO cells suggests that they may be in cycle and in vivo data shows that they have a short lifespan while CD45RA cells are long-lived. The lineage relationship of the two subsets is not clear but in vivo and in vitro evidence suggests bi-directional conversion between CD45RA and CD45RO phenotypes.     

CD45 isoform phenotypes of human T cells: CD4(+)CD45RA(-)RO(+) memory T cells re-acquire CD45RA without losing CD45RO

We have studied the alterations in CD45R phenotypes of CD4(+)CD45RA(-)RO(+) T cells in recipients of T cell-depleted bone marrow grafts. These patients are convenient models because early after transplantation, their T cell compartment is repopulated through expansion of mature T cells and contains only cells with a memory phenotype. In addition, re-expression of CD45RA by former CD4(+)CD45RA(-) T cells can be accurately monitored in the pool of recipient T cells that, in the absence of recipient stem cells, can not be replenished with CD45RA(+) T cells through the thymic pathway. We found that CD4(+)CD45RA(-)RO(+) recipient T cells could re-express CD45RA but never reverted to a genuine CD4(+)CD45RA(+)RO(-) naive phenotype. Even 5 years after transplantation, they still co-expressed CD45RO. In addition, the level of CD45RA and CD45RC expression was lower ( approximately 35 %) than that of naive cells. In contrast, the level of CD45RB expression was comparable to that of naive cells. We conclude that CD4(+)CD45RA(-)RO(+) T cells may re-express CD45(high) isoforms but remain distinguishable from naive cells by their lower expression of CD45RA / RC and co-expression of CD45RO. Therefore, it is likely that the long-lived memory T cell will be found in the population expressing both low and high molecular CD45 isoforms.     

Identical expression of CD45R isoforms by CD45RC+ 'revertant' memory and CD45RC+ naive CD4 T cells.

Naive and memory CD4 T cells are frequently defined by exon-specific monoclonal antibodies (mAb) which stain (or not) high- or low-molecular-weight (MW) isoforms of the leucocyte common antigen CD45. The link between isoform and the naive/memory designation is complicated by the fact that CD4 T cells with a 'memory' phenotype (CD45RA-, RB-, RC-, or CD45RO+) may revert ('revertants') and re-express the high mw isoform (CD45RA+, RB+, RC+). Isoform expression also changes during normal T-cell development. Furthermore, the picture may be incomplete since an exon-specific mAb will not detect all possible isoforms on a cell. We have used molecular techniques to determine whether revertant CD4 memory T cells were different from naive T cells with respect to CD45R isoform expression. Using the anti-CD45RC mAb OX22 to purify rat lymphocyte subsets, CD45R isoform expression was examined at the mRNA level in CD4 T cells at different stages of development and compared with that of B cells and unseparated lymphocytes. B cells contained abundant message for the highest MW 3-exon isoform ABC, the 2-exon isoforms AB and BC, and the null isoform O. Both immature CD45RC- (i.e. CD4+8- 'single positive' thymocytes, and peripheral Thy-1+ recent thymic emigrants) and mature CD45RC- 'antigen-experienced' CD4 T cells had message for single-exons B, possibly C and for the O exon. In contrast, CD45RC+ CD4 T cells contained mRNA coding for ABC (low level), AB, BC, B, C (low level) and O (low level). Importantly, there was no difference between CD45RC+ T cells that had not seen antigen ('truly native') and CD45RC+ antigen-experienced revertant memory T cells. This observation has implications for understanding long-term immunological memory.     

Human CD4+CD45R0+ and CD4+CD45RA+ T cells synergize in response to alloantigens.

Alloantigens, unlike recall antigens, activate both CD45RA+ (naive) and CD45R0+ (memory) CD4+ cells to the same extent. These T cell subsets may therefore interact with each other in response to alloantigens on transplanted grafts. We have investigated if the ability of activated CD4+CD45RA+ and CD4+CD45R0+ T cells to produce and respond to interleukin 2 (IL2) and IL4 may be involved in this interaction. After activation, both subsets up-regulate their IL2 receptor (IL2R) and IL4R expression, yet IL4 substantially enhanced the proliferation of the CD4+CD45RA+ but not of the CD4+CD45R0+ T cell subset, while IL2 increased the proliferation of CD4+CD45R0+ but not of the CD4+CD45RA+ T cells. Significantly, the CD4+CD45RA+ T cells synthesized two- to threefold more mRNA for IL2 than the CD4+CD45R0+ subset, while the CD4+CD45R0+ T cells synthesized mRNA for IL4 and interferon-gamma exclusively. The addition of IL2 to alloactivated CD4+CD45R0+ T cells further up-regulated their production of all three lymphokine mRNA; in contrast, IL4 induced an increase in mRNA for IL2 in only the alloactivated CD4+CD45RA+ subset. The reciprocity in the ability of both these CD4+ T cells to synthesize and respond to IL2 and IL4 may provide a rationale for the regulation of lymphokine interactions in vivo. Furthermore, the synergy between these subsets in response to alloantigens, which was directly quantitated by co-culturing CD4+CD45RA+ and CD4+CD45R0+ cells together prior to activation, may potentiate the alloreactivity against transplanted grafts in vivo.     

Imbalance of CD4+CD45R+ and CD4+CD29+ T helper cell subsets in patients with atopic diseases.

To evaluate the proportion of helper cell subsets we studied 18 children with atopic dermatitis, 30 patients with asthma, 27 healthy age-matched controls aged 1 to 17 years and 11 atopic controls without symptoms related to atopy, aged 9-22 years. Lymphocytes were isolated from heparinized peripheral blood and the proportion of CD4+CD29+ and CD4+CD45R+ cells was determined by double-labelling immunofluorescence. Children with atopic dermatitis yielded a significantly (P less than 0.01) higher proportion of CD4+CD45R+ (median 75%) cells compared with normal controls (median 66.6%), whereas the proportion of CD4+CD29+ cells was significantly (P less than 0.01) lower in patients with atopic dermatitis (median 20.4 versus 29.6%). Interestingly, the percentage of CD4+CD45R+ cells shows an age-dependent decline (r = -0.67, P less than 0.01) in the control group, which is not found in the patient group.     

CD45 isoform switching precedes the activation-driven death of human thymocytes by apoptosis.

A recently described chimaeric organ culture system is employed to investigate the effects of antibodies to the CD3 and CD2 cell surface structures on the fate of developing human thymocyte populations. Engagement of CD3 as well as CD2 with reagents that stimulate peripheral human T cell results in the activation-induced death of human thymocytes in organ culture. Death is preceded by a characteristic phenotypic change; thymocytes that bear CD45RA (determinants associated with high-molecular-mass isoforms of the leukocyte common antigen family, CD45) are first induced to co-express CD45RO (the low-molecular-mass isoform of CD45), and subsequently lose CD45RA expression. This antigenic change is followed by cellular DNA fragmentation, characteristic of apoptosis. We conclude that engagement of CD3 as well as CD2 can recruit human CD45RA+ thymocytes into the CD45RO+ population, where cell death occurs. Our results suggest that this phenotype conversion is a marker for thymocytes destined for programmed cell death.     

Protein kinase C isoform expression in CD45RA+ and CD45RO+ T lymphocytes.

Differences in levels of specific enzymes utilized in intracellular signalling could be a factor in the distinct signalling properties observed in memory and naive T cells. We have studied the expression of both classical and non-classical protein kinase of C (PKC) isoenzymes in CD45RA and CD45RO cells using a combination of Western blot and flow cytometric analysis. These data indicate that CD45RA cells express higher levels of PKC alpha, PKC beta and PKC delta than CD45RO cells. In addition, CD45RA+ cells show greater proliferative activity when stimulated with phorbol myristate acetate (PMA) and calcium ionophore than their CD45RO+ counterparts. Variations in the levels of these isoenzymes could be implicated in functional differences, such as proliferation and cytokine production, in these cell subsets.     

Differential effects of CD45 CD45R and CD45R0 monoclonal antibodies in modulating human B cell activation.

We have examined the effect of monoclonal antibodies (MoAbs) to different epitopes of the leucocyte common antigen (LCA), CD45, on anti-human immunoglobulin-primed B cell activation. Binding of MoAbs to restricted epitopes present on CD45 glycoproteins of 180 kD and 220 kD (designated CD45R0 and CD45R, respectively) was found to promote B cell proliferation in the presence of T cells. CD45 MoAbs reactive with 'public' determinants on all four constituent members of the LCA family (180, 190, 205, and 220 kD) had either little effect or inhibited the basal B cell response to anti-immunoglobulin priming. Simultaneous immunofluorescent analysis of 5-bromodeoxyuridine incorporation and the expression of CD19 (B cell specific) or CD2 (T cell specific) identified the majority of responder cells as B lymphocytes. CD45R MoAbs significantly enhanced the B cell response to sub-optimal concentrations of interleukin-2. CD45 and CD45R0 MoAbs failed to elicit a similar response. Antibody to the interleukin-2 receptor (anti-Tac) partially blocked the CD45R-driven, T cell-dependent B cell proliferation.     

Glycosylation of CD45: carbohydrate composition and its role in acquisition of CD45R0 and CD45RB T cell maturation-related antigen specificities during biosynthesis.

The contribution of oligosaccharides to the biochemical composition and antigen heterogeneity of the phosphotyrosine phosphatase CD45 glycoproteins has been studied on the K-562 erythroleukemic cell line. Treatment of immunoprecipitated CD45 glycoproteins with distinct exo- and endoglycosidases revealed the presence of highly sialylated O- and N-linked complex carbohydrates in the composition of mature CD45 glycoproteins. Incubation of K-562 cells with the N-glycosylation inhibitor tunicamycin blocked carbohydrate processing during biosynthesis of CD45 proteins, generating unglycosylated polypeptides similar in size to those resulting from digestion of CD45 proteins with a mixture of both N- and O-glycanases. Epitopes defining the T cell maturation related CD45R0 and CD45RB antigen specificities were present on the mature 180- and 190-kDa K-562 CD45 proteins, respectively. However, the CD45R0 and CD45RB epitopes were not detected on the high mannose biosynthetic CD45 precursors. Furthermore, treatment of CD45 proteins with O-glycanase or neuraminidase resulted in the loss of both CD45R0 and CD45RB epitopes, although reactivity of the anti-CD45R0 and anti-CD45RB mAb was not affected by mAb preincubation with either sialic acids or sialyllactose in solution. From these results we conclude that the blockade of early steps of N-glycosylation during carbohydrate processing resulted in the inhibition of subsequent incorporation of O-linked sugars on CD45 polypeptides, thus preventing the late acquisition of the CD45R0 and CD45RB determinants on the 180- and 190-kDa CD45 polypeptides.     

A monoclonal antibody to murine CD45R distinguishes CD4 T cell populations that produce different cytokines

CD4 T cell clones have been shown to be functionally heterogeneous in the mouse. However, it is not known if normal CD4 T cells are also functionally heterogeneous, or whether functional specialization is a result of cloning and long-term culture. To approach this question, a monoclonal antibody reacting with a subset of CD4 T cells has been prepared by immunization of rats with different cloned T cell lines all sharing the same functional activity. This monoclonal antibody reacts with a subset of CD45 (T200) molecules by binding to a determinant requiring the expression of the second variable exon of the CD45 molecule. Some CD4 T cells bear high levels of this marker, while others react only weakly. This antibody was used to separate CD4 T cells into two subpopulations. The brightly staining population was found to produce interleukin (IL) 2 and not IL 4, while the weakly staining population produced IL 4 and not IL 2. These data demonstrate that CD4 T cells in normal mice are already functionally committed, and that they differentially express forms of CD45 that contain the second variable exon.     

Allorecognition of HLA-DR and -DQ transfectants by human CD45RA and CD45R0 CD4 T cells: repertoire analysis and activation requirements.

We have investigated the requirements for allogeneic stimulation of human CD4 T cells using HLA class II products expressed on various cellular backgrounds. Human (class II-negative RJ2.2.5 mutant) B cell lines transfected with HLA-DR or -DQ cDNA clones were efficient stimulators for highly purified CD4 T cells. HLA-DR-transfected mouse L cells or IFN-γ-induced human fibroblasts, although able to function as accessory cells for T cell responses to the mitogen PHA, failed to stimulate strong T cell alloresponses. On the basis of these observations, we have employed class II transfectants to address the following questions: (a) do CD45RA and CD45R0 subpopulations differ in their allogeneic activation requirements, (b) are these subpopulations skewed in their recognition of HLA-DQ vs. HLA-DR in a manner which might support the concept that CD45RA T cells are involved in HLA-DQ-restricted suppressor inducer functions and (c) by using transfectants expressing individual HLA-DR or -DQ heterodimers in combination with limiting dilution analysis, can one for the first time obtain estimates of precursor frequencies for allogeneic cells recognizing each of these class II isotypes? Our results show that CD45RA and CD45R0 T cells respond comparably to optimal numbers of stimulator cells. However, when CD45RA and CD45R0 T cell populations depleted of endogenous accessory cells were cultured with limiting numbers of stimulator cells, CD45R0 cells generally responded more strongly, consistent with the elevated levels of various adhesion molecules known to be expressed by this population. Further, we found a similar representation of responses to HLA-DR and -DQ antigens among populations expressing CD45RA and CD45R0 isoforms. Finally, the precursor frequencies of allogeneic CD4 T cells responding to particular HLA-DQ alleles were higher than to -DQ, but only by a factor of about 1.6, indicating that HLA-DQ recognition may occur more frequently than implied from previous antibody blocking studies.     

Lymphokine gene expression related to CD4 T cell subset (CD45R/CDw29) phenotype conversion

In this study, we investigated whether the phenotype-related differentiation of human 2H4+ (CD45R) naive cells to 2H4- (CDw29) memory CD4 cells corresponded to modulation of interleukin (IL) 2, IL 4, interferon (IFN)-gamma and granulocyte-monocyte colony-stimulating factor (GM-CSF) gene expression, a phenomenon which might correlate to the distinct functional activities of naive cells or memory cells. To mimic in vitro CD4 T cell subset differentiation, freshly isolated 2H4+ and 2H4- CD4 cells were stimulated with the anti-CD3 antibody (Leu-4), expanded in IL 2-containing medium and restimulated with Leu-4 after 7 and 13 days. Absence of monocyte-T cell interaction was compensated by adding monocyte supernatant to the culture medium and by cross-linking the anti-CD3 antibodies with goat anti-mouse antibody coated on culture dishes. It has been previously shown that in vitro stimulated 2H4+ cells acquire CDw29 surface antigens. Measurement of lymphokine gene expression by dot-blot hybridization revealed that although stimulated 2H4+ cells proliferated less than stimulated 2H4- cells, and expressed less actin mRNA, they expressed more IL 2 but less IL 4 and GM-CSF than 2H4- cells. No significant difference was observed between the two subsets for the expression of IFN-gamma. If subsets were restimulated with Leu-4 antibodies, expression of IL 2 was decreased and expression of IL 4 was increased in both subsets; however, the differences among the subsets persisted. They were even more enhanced for IL 2 but less pronounced for GM-CSF. Thus, in spite of phenotype conversion, CD4 T cell subsets maintained a distinct capacity to express IL 2 and IL 4 genes.     

Deficiency of the expression of CD45RA isoform of CD45 common leukocyte antigen in CD4+ T lymphocytes in children with infantile cholestasis

The immunological background of the pathological changes that appear in infantile cholestasis (infections, inflammatory process in the liver) is largely unknown. With the use of double color flow cytometry, we assessed the distribution of functionally different lymphocyte subpopulations in the peripheral blood of 29 infants with extra and intra-hepatic cholestasis (12 and 17 patients, respectively), aged from 1 to 8.6 months. Control group consisted of 15 age-matched, healthy infants. We examined: (1) the expression of CD3, CD4, CD8, CD19 lymphocyte surface receptors; and (2) the distribution of lymphocyte subsets with distinctive surface Ag characteristics of 'naive' (CD45RA+) and 'memory' (CD45RO+) cells in both CD4+ and CD8+ cell populations. The surface markers expression was evaluated in terms of percentage of positive cells and receptor density. The following changes in the expression of lymphocyte surface markers are described: (1) a decrease in the percentage of total CD3+, CD4+ cells but normal percentage of CD8+ cells and elevated proportion of CD19+ B cells; (2) a reduction of the proportion of 'naive' CD4+ lymphocytes but normal percentage of 'naive' CD8+ as well as 'memory' CD4+ and CD8+ cell subsets; (3) a decrease in density of CD3, CD4+, CD8 receptors, and D45RA isoform in a subset of 'naive' CD4+ cells. We conclude that deficiency of 'naive' CD4+ T cell subset which possess important effector and immunoregulatory functions, and low expression of certain lymphocyte receptors known to be engaged in T cell activation, possibly reflect a defect of cell mediated immunity that may account for viral and bacterial infections, often observed in infants with cholestasis.     

Both CD45R(low) and CD45R(high) "revertant" CD4 memory T cells provide help for memory B cells

During a primary response to thymus dependent antigens, B cells undergo a number of qualitative changes to become memory B cells - processes that require co-stimulatory signals and cytokine help from CD4 T cells. The question of whether distinct, antigen-experienced memory CD4 T cells are subsequently needed to program memory B cells into antibody synthesis has not been clearly resolved.Using an adoptive transfer model in which memory but not naive B cells were stimulated, we evaluated CD4 T cell help using lymphocytes obtained from primed or unprimed thymectomized donors and expressing a naive (CD45R(high)) or a memory (CD45R(low)) phenotype. Memory B cells, most of which were committed to the IgG1 (Th2) subclass, could be stimulated to produce antibody using help transferred by the CD45R(high) naive subset of unprimed donors (slow onset of response), the CD45R(low) subset of 7 day primed donors (large, rapid antibody response) or by both the CD45R(low) and the CD45R(high) "revertant" subsets of 6 month primed donors. We found that antigen primed CD45R(low) CD4 T cells reverted (defaulted) with time to a CD45R(high) resting state, a change that was prevented by persisting antigen. The evidence suggests that CD4 memory T cells are partitioned into two different functional states (CD45R(high) and CD45R(low)) and that these determine the characteristics of the memory B cell response in terms of speed, size and longevity.     

CD4+ CD45RA+ and CD4+ CD45RO+ T cells differ in their TCR-associated signaling responses.

Peripheral CD4+ T cells can be divided into two different functional populations based on the expression of distinct isoforms of the surface molecule CD45. We have investigated the differences in the proximal signaling induced by anti-CD3 monoclonal antibody in purified populations of "naive" CD45RA+ and "memory" CD45RO+ human CD4+ T cells. Expression of cell surface CD3, CD4 and CD28 was comparable between RA+ and RO+ cells. However, TCR-directed stimulation in the form of anti-CD3 produced markedly different patterns of intracellular signaling. Greater inositol triphosphate generation occurred in naive cells and the rise in intracellular free calcium was also substantially greater in naive than in memory cells. Cells with the naive phenotype were considerably more active in TCR-dependent tyrosine phosphorylation, both at an overall level and specifically in terms of TCR-zeta and ZAP-70 phosphorylation. Despite these differences in phosphorylation, the amounts of TCR-zeta, ZAP-70 and Ick were equivalent between the two subsets. These findings suggest that the TCR-dependent signaling is differentially regulated in naive and memory CD4+ T cells. This may be due to differences in the way that the two isoforms of the CD45 phosphatase regulate the activity of proximal kinases in the TCR signaling pathway, and could be an important means by which the unique functions of differentiated T cell populations are maintained.