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.     

T lymphocytes in rat germinal centres belong to an ER3+ subpopulation of CD4+ cells.

Two-colour immunofluorescence histochemistry showed directly that greater than 90% of CD4+ germinal centre T cells in rat spleen or lymph node examined 7 days after immunization bear the antigen recognized by the monoclonal antibody (mAb) ER3. By contrast, only 30-40% of all thoracic duct or lymph node CD4+ cells were ER3+, as determined by two-colour flow cytometry. CD8+ cells were ER3+, but nearly all B cells were ER3-. Thus, germinal centre T cells belong to a subpopulation of CD4+ cells. Because only 25-30% of CD4+ cells that lack higher molecular weight forms of CD45 (i.e. mAb MRC OX32 cells, equivalent to MRC OX22 cells) express ER3, the CD4+ subpopulations defined by ER3 are neither identical nor complementary to the subsets defined by restricted expression of CD45 epitopes.     

Memory CD4+ T cells in man form two distinct subpopulations, defined by their expression of isoforms of the leucocyte common antigen, CD45.

The leucocyte common antigen, CD45 (T200, Ly-5), exists in a number of isoforms generated by differential usage of three exons that code for an extracellular region close to the NH2 terminus. Use of antibodies to different isoforms of CD45 has lead to the identification of two subsets of CD4+ T cells in rat, man and mouse. Data on the functions of the two rat CD4+ T-cell subsets isolated on the basis of different levels of expression of exon B (and/or C) are largely concordant with those obtained from the two subsets of human CD4+ T cells defined by their levels of expression of exon A. However, results presented in this paper on the CD45 phenotype of rat T cells that produce interferon-gamma (IFN-gamma) are not compatible with the human data, if it is assumed that there are only two functional subsets of CD4+ T cells. The data could, in principle, be reconciled if the expression of exons A and B defined three rather than two subsets, and this possibility has now been examined in man where monoclonal antibodies against both A and B exon products are available. The results show the presence of a third CD4+ T-cell subset and that this extra subset is contained within the population originally shown to provide memory T-cell function.     

Isoform-specific associations of CD45 with accessory molecules in human T lymphocytes.

Association of CD45 with surface molecules was investigated in human T lymphocytes by co-capping. CD45 appeared to be associated with the CD3/T cell receptor complex and with CD4 or CD8 molecules in memory, but not in naive T cells, as previously reported in the mouse. Associations of CD45 isoforms with accessory molecules were then identified with seven anti-CD45R monoclonal antibodies (mAb). An isoform-specific association pattern was observed: CD2 co-capped with CD45 molecules recognized by UCHL1 mAb (CD45R0). LFA-1 with molecules bound by 2H4 mAb (CD45RA), and both CD4 and CD8 with molecules reacting with MCA.347 mAb (whose isoform specificity was not known). Further information on the CD45 isoform(s) associated to CD4 and CD8 was sought by assessing the isoform specificity of MCA.347. Cross-competition experiments showed that it reacts with an epitope clearly different from those recognized by 2H4 and UCHL1, and only partially overlapping the PD7/26 epitope (CD45RB). Moreover, the competition between MCA.347 and PD7/26 was maximal in naive T cells and minimal both in memory T cells and in a subset expressing CD11b, a marker of granular lymphocytes. Immunoprecipitation experiments showed that MCA.347 binds to CD45 molecules with a molecular mass of 220, 205 and 190 kDa, the 190-kDa molecules not being recognized by 2H4, PD7/26 or UCHL1. These data indicate that MCA.347 recognizes amino acid sequences different from those coded by the exon A or B of the gene, and not expressed by CD45R0, suggesting that it binds to sequences coded by the exon C. In conclusion, this work shows that in human T cells different CD45 isoforms are associated to different surface molecules: LFA-1 is associated to CD45RA, CD2 to CD45R0 and CD4 and CD8 presumably to CD45RC. This peculiar behavior of CD45 suggests that it may play a crucial role in lymphocyte activation, probably by modulating the signals delivered to the cell by different receptor systems.     

Expression of the CDw75 (beta-galactoside alpha 2,6-sialyltransferase) antigen on normal blood cells and in B-cell chronic lymphocytic leukaemia.

Using monoclonal antibodies (mAb) characterized at the last International Workshop on Human Leucocyte Antigens, we examined the expression of CDw75 antigens (beta-galactoside alpha 2,6-sialyltransferase) on normal peripheral blood cells and on cells from patients with B-cell chronic lymphocytic leukaemia (CLL). The mAb used (HH2, EBU.65, EBU.141 and OKB4) detect different epitopes of CDw75. Normal peripheral blood B cells expressed high levels of CDw75 detectable with HH2, EBU.65 and EBU.141 but did not react with OKB4. Cells from patients with B-cell CLL closely resembled normal B cells. All CDw75 epitopes, including OKB4, were strongly expressed on some Namalwa variant Burkitt lymphoma cell lines. The OKB4 epitope was also present on red cells from all normal donors. The other CDw75 mAb were unreactive with red cells from some normal donors. The CDw75 epitope detected with EBU.65 was present on most CD4+ T cells and on a minority of CD8+ cells. HH2 and EBU.141 stained only small numbers of T lymphocytes. OKB4 did not react with T cells. EBU.65+, CD4+ T cells had low levels of expression of CD45R0, CD29, CD54 and CD58, and had high levels of CD45RA antigen. Phytohaemagglutinin (PHA) activation of cells led to the loss of EBU.65 binding. These results suggest that the CDw75 epitope recognized by the EBU.65 mAb is a marker of native T lymphocytes. On B CLL cells the epitopes detected with HH2, EBU.65 and EBU.141 were destroyed by treatment with neuraminidase. Treatment of B-CLL cells and red cells with neuraminidase increased the binding of OKB4, suggesting that this epitope is masked by sialic acid. The results suggest that CDw75 is a sialylated cell-surface antigen expressed in a number of tissue-specific isoforms.     

A point mutation in the human CD45 gene associated with defective splicing of exon A

CD45 is a receptor-type protein tyrosine phosphatase involved in the regulation of lymphocyte activation. Different CD45 isoforms are generated by alternative splicing of three variable exons (A, B and C). The pattern of CD45 splicing depends upon cell type and state of activation. CD45RA isoforms (containing exon A-encoded sequences) can usually be found on a subset of resting T cells, but not on activated T cells. We have recently described a variant pattern of CD45RA expression which is characterized by continuous expression of CD45RA molecules on activated and memory T cells. Here, we demonstrate that this phenotype is associated with heterozygosity for a point mutation at nucleotide position 77 of exon A, leading to a C → G transition. This mutation does not change the protein sequence of the CD45RA isoform. We conclude that position 77 is part of a motif necessary for splicing of exon A, which supports the hypothesis that sequences within exons have significant effects on alternative splicing. The mutation of this motif might prevent binding of a transacting splice factor. In the heterozygous state, this mutation is not associated with impaired T cell reactivity. Functional consequences of the homozygous state remain to be elucidated.     

Monoclonal antibodies to epitope of CD45R (B220) inhibit interleukin 4-mediated B cell proliferation and differentiation.

A mAb, ALP-2, produced by immunizing rats with proliferating lymph node cells from MRL/Mp-lpr/lpr mice, had an inhibitory effect on recombinant interleukin 4 (rIL-4)-mediated proliferation and differentiation of murine B cells. Kinetic analysis revealed that the ALP-2 exerted these inhibitory effects at an early phase of B cell proliferation and differentiation. Nevertheless, the proliferative response of thymocytes to rIL-4 was not inhibited by ALP-2. In addition, ALP-2 inhibited neither the B cell proliferation induced by interleukin 2 nor the B cell differentiation by interleukin 5. Cross-inhibition experiments, together with immunoblotting analysis, revealed that the LP-2 recognized by ALP-2 appears to be an epitope of CD45R (B220) molecule(s), the isoform(s) of the Ly-5 antigen system. Epitope mapping analysis using CD45 gene transfectants showed that Lp-2 epitope is dependent upon the expression of the first alternatively spliced exon of CD45 gene. Functional studies showed that the mAb to an epitope of CD45R, RA3-2C2, but not RA3-6B2, had similar inhibitory effects on the IL-4-mediated proliferative response of B cells. These findings suggest that the CD45R molecules associated with Lp-2 and RA3-2C2 epitopes are probably related to a signal transduction provided by IL-4 in B cells. The possibility that different pathways are operative for IL-4-mediated signaling between B and T cells has to be considered.     

The monoclonal antibody CZ-1 identifies a mouse CD45-associated epitope expressed on interleukin-2-responsive cells

We have previously described a monoclonal antibody (mAb), CZ-1, which reacts with an epitope expressed on most peripheral basophils, natural killer cells, B cells, and CD8⁺ T cells, but not with most thymocytes or peripheral CD4⁺ T cells. Here we show that mAb CZ-1 defines a sialic acid-dependent epitope associated with a subpopulation of CD45 molecules. This conclusion is based on the ability to block binding of mAb CZ-1 by sialic acid, neuramin-lactose, neuraminidase, and mAb to CD45RB, and by expression of the epitope on transfected W2 cells expressing exon B of CD45. The results suggest that the CZ-1 epitope is a post-translational modification expressed on a subpopulation of the CD45 molecules also expressing the B exon. Expression of the CZ-1 epitope was required for freshly isolated lymphocytes to respond to interleukin-2 (IL-2). Depletion of CZ-1⁺ cells by C or by cell sorting of thymocytes or splenocytes eliminated the IL-2 responsive cells. The subpopulations of thymocytes and CD4⁺ splenocytes responding to IL-2 were exclusively within the small CZ-1⁺ subpopulation. mAb CZ-1 was also used to subdivide CD45⁺ and CD45RB⁺ splenocytes into IL-2-responsive and -nonresponsive subpopulations. The CZ-1 epitope was also expressed on virtually all lymphokine-activated killer cell precursors. These data, thus, indicate that cells responsive to IL-2 express this sialated modification of CD45.     

Subpopulations of guinea-pig T lymphocytes defined by isoforms of the leucocyte common antigen.

This report presents the characterization of three mouse monoclonal antibodies (mAb) reactive with the guinea-pig leucocyte common antigen (LCA); CD45 in the human nomenclature. One, IH-1, reacted with LCA on all leucocytes. The other two were more restricted: IH-2 recognized only the 220,000, 210,000 and 195,000 MW isoforms, and IH-4 the 220,000, 210,000 MW isoforms. Both IH-2 and IH-4 reacted with all B cells and all Kurloff cells [the putative guinea-pig natural killer (NK) cell]. IH-2, but not IH-4, reacted with monocytes and macrophages. Neither reacted with neutrophils. Most thymocytes expressed low levels of the IH-2 and IH-4 epitopes, with those expressing high levels located predominantly within the medulla. Most (90%) CD4+ T cells from newborn guinea-pigs expressed high levels of the IH-2 and IH-4 epitopes; this percentage decreased with age to 70% in 2-year-old animals. We have demonstrated that CD4+ T cells which express low levels of the IH-2 epitope also express low levels of the IH-4 epitope. CD8+ T cells can be divided into two subsets by IH-4 but not IH-2. The reactivities of IH-2 and IH-4 are remarkably similar to those of human anti-CD45RB and anti-CD45RA antibodies respectively. Analogies with man and other species suggest important functional differences for subpopulations of guinea-pig T lymphocytes defined by anti-CD45R antibodies.     

The monoclonal antibody, UCHL1, recognizes a 180,000 MW component of the human leucocyte-common antigen, CD45.

The leucocyte-common antigen (L-CA or CD45) is a family of high molecular weight glycoproteins, ranging from 180,000 to 220,000 MW that are expressed only on cells of lymphoid and myeloid origin. CD45 monoclonal antibodies (mAbs) recognize epitopes present on all polypeptides of the family, while other mAbs, termed CD45R, recognize determinants found only on the 220,000 MW and 200,000 MW polypeptides. In contrast the mAb UCHL1 recognizes a 180,000 MW antigen. UCHL1-coupled Sepharose beads were used to absorb antigen from lysates of cell lines. CD45 mAbs bound to this immobilized antigen. Antigen immobilized with CD45 mAb-coupled Sepharose beads bound UCHL1. Antigen purified by absorption and elution from the MOLT-4 cell line with CD45 mAb-coupled beads yielded molecules of 180,000 and 190,000 MW. Reprecipitation of the eluted antigen with UCHL1 resulted in a 180,000 MW band only. In a reciprocal experiment, CD45 mAb reprecipitated a 180,000 MW molecule from purified UCHL1 antigen. UCHL1 and the CD45R mAb 2H4 showed a mutually exclusive pattern of reactivity with human T- and B-cell lines, but co-expression of the antigens was seen on two myeloid and one erythroleukaemic cell line. In contrast, epitopes recognized by other putative CD45R mAbs were co-expressed with UCHL1 both on myeloid, erythroid and many T- and B-cell lines. We conclude that UCHL1 recognizes an epitope present only on the 180,000 MW polypeptide of CD45. Expression of this antigen is essentially reciprocal to the epitope detected by the CD45R mAb 2H4.     

CD45 epitope mapping of human CD1a+ dendritic cells and peripheral blood dendritic cells.

The authors studied the pattern of leukocyte common antigen (CD45) epitope expression on dendritic cells in sections of human epidermis, tonsillar epithelium, dermatopathic lymph nodes, and in isolates from blood. The monoclonal antibodies (MAb) used were specific for all known CD45 epitopes, including the seven different CD45 common epitopes as well as the four known CD45R epitopes (two CD45RA, one CD45RB, and one CD45RO). Dendritic cells in all sites were uniformly reactive for the CD45 common epitopes tested except 2B11, which may recognize a CD45R rather than CD45 epitope. By single-label immunoperoxidase and double-label immunofluorescence epitope mapping of CD1a+ dendritic cells in tissue sections, it was generally difficult or impossible to detect expression of CD45RA, CD45RB, CD45RO, or 2B11. In blood dendritic cells, however, low levels of these CD45R epitopes were detected consistently using single-label immunoperoxidase staining of cytocentrifuge preparations. Monocytes were similar to blood dendritic cells except that the staining with MAb to CD45RO and 2B11 was slightly stronger. The authors conclude that dendritic cells differ from most subpopulations of lymphocytes in that CD45 common epitopes are readily detectable but the existing RA, RB, and RO epitopes are either undetectable or expressed at relatively low levels. These studies raise the possibility that CD1a+ dendritic cells may express a novel dominant CD45 isoform.     

The importance of cross-linking in the homotypic aggregation of lymphocytes induced by anti-leukosialin (CD43) antibodies.

Leukosialin (CD43) is a major glycoprotein of T lymphocytes which has an extracellular domain of 45 nm in length that is heavily O-glycosylated. Monoclonal antibodies (mAb) to the extracellular domain of human leukosialin induce aggregation of T lymphocytes, monocytes and some cell lines that express leukosialin. The aggregation was reported in one case to be inducible by Fab fragments. In the present study, nine mAb specific for rat leukosialin were tested as inducers of thymocyte aggregation and all were effective. The level of aggregation was reduced by metabolic and cytoskeletal inhibitors, by removal of divalent cations and by reducing the temperature from 37 degrees C to 4 degrees C. The aggregation produced by mAb specific for certain epitopes was less sensitive to these inhibitors than aggregation induced by mAb to other epitopes. To examine the requirement for cross-linking, Fab fragments of four of the antibodies were tested and found to be inactive except for those derived from the OX75 mAb. However, OX75 Fab showed a tendency to dimerize, and monomeric OX75 Fab obtained directly after gel filtration was unable to induce aggregation. Thus induction of rat thymocyte aggregation by anti-leukosialin antibodies requires bivalent cross-linking and maximal aggregation is dependent on energy and an intact cytoskeleton. Mechanisms of antibody-induced aggregation are considered and it is proposed that in the case of leukosialin the antibodies may cross-link cells to overcome inherent repulsion between them and that subsequently other adhesion molecules complete the clustering process.     

Pivotal advance: CD45RB glycosylation is specifically regulated during human peripheral B cell differentiation

A screen of cell surface markers differentially expressed during peripheral B cell differentiation identified that the CD45RB epitope detected by the mAb MEM-55 was highly expressed on CD27(+) memory B cells and absent on CD27(-) na?ve B cells. IgG(+)CD27(-) memory and a previously unacknowledged CD27(-) population in blood also expressed high levels of CD45RB(MEM55). Na?ve and memory B cells from tonsils followed the pattern observed in blood, and CD38(high) B cells had a bimodal expression pattern when analyzed using flow cytometry. No CD38(high) GC B cells, however, expressed the CD45RB(MEM55) epitope when assayed using immunohistochemistry. Rather, CD38(high)CD45RB(MEM55high) B cells had a distinct cellular phenotype and were localized outside of GCs. CD45RB epitopes, detected by other antibody clones, were expressed at high levels through B cell differentiation, and no changes in splicing of the CD45RB exon were observed during B cell differentiation. Instead, B cells regulated their expression of the CD45RB(MEM55) epitope through site-specific modifications of an O-linked glycochain. CD4(+) T cells differentially spliced CD45 but did not vary the glycosylation of the CD45RB(MEM55) epitope, and CD8(+) cells modified CD45RB(MEM55) expression in a similar manner as B cells. Monocytes expressed the CD45RB exon but not the CD45RB(MEM55) epitope. As CD45 is a highly expressed tyrosine phosphatase that regulates antigen receptor signaling strength in lymphocytes, we conclude that regulated O-linked glycosylation of CD45RB can be used to follow B cell differentiation and that this regulation may be involved in fine-tuning antigen signaling in the cell.     

SF2 and SRp55 regulation of CD45 exon 4 skipping during T cell activation

CD45 is an alternatively spliced membrane phosphatase required for T cell activation. Exons 4, 5 and 6 can be included or skipped from spliced mRNA resulting in several protein isoforms that include or exclude epitopes referred to as RA, RB or RC, respectively. T cells reciprocally express CD45RA or CD45RO (lacking all three exons), corresponding to naive versus memory T cells. Overexpression of the alternative splicing regulators, SF2 or SWAP, induces skipping of CD45 exon 4 in transfected COS cells. We show here that the arginine/serine-rich domain of SWAP and the RNA recognition motifs of SF2 are required for skipping of CD45 exon 4. Unlike SWAP, SF2 specifically regulated alternative splicing of CD45 exon 4, having no effect on a non-regulated exon of CD45 (exon 9). Like SF2 and SWAP, the SR proteins SC35, SRp40 and SRp75, but not SRp55 also induced CD45 exon 4 skipping. In contrast, antisense inhibition of SRp55 induced exon 4 skipping. SF2 and SRp55 proteins were not detectable or expressed at a very low level in freshly isolated CD45RA+ and CD45RO+ T cells. Activation of CD45RA+ T cells shifted CD45 expression from CD45RA to CD45RO, and induced a large increase in expression of both SF2 and SRp55. Thus, SF2 at least in part determines splicing of CD45 exon 4 during T cell activation. SRp55, SR protein phosphorylation, or other splicing factors likely regulate CD45 splicing in CD45RO+ memory T cells. The different SR proteins expressed by memory and activated T cells emphasize the different phenotypes of these cell types that both express CD45RO.     

CD45R CD4 T cell subset-reconstituted nude rats: subset-dependent survival of recipients and bi-directional isoform switching.

High and low molecular weight variants (CD45R) of the leukocyte common antigen (CD45) divide CD4 T helper cells into subpopulations which display distinct characteristics. In vitro and in vivo evidence suggested that the presence of the high molecular weight splice variants CD45RA or CD45RB distinguished naive CD4 T cells from memory T cells which underwent an irreversible switch to the low molecular weight isoform as a consequence of antigen encounter. In the rat monoclonal antibody MRC OX22 identifies an epitope on the CD45RB molecule. We investigated this proposed differentiation pathway by reconstituting athymic nude rats with highly purified OX22+ or OX22- CD4 T lymphocyte subsets obtained from the thoracic duct (TDL) of euthymic, congenic, allotype-marked donors. Injection of CD4+CD45RB- (45R-) cells ensured long-term survival of nude recipients; recipients of CD4+CD45R+ (45R+) cells died within 2-3 months of injection. Early after transfer (3-4 weeks) the progeny of both 45R+ and 45R- TDL were uniformly 45R-. With time (by 2 months) progeny of both parental types expressed the high molecular weight CD45RB isoform. Nude recipients of 45R- TDL always generated progeny a proportion of which bore the 45R+ phenotype; 3 months to 2 years post-injection, 30%-50% of the donor-derived CD4 T cells were 45R+, 45R- progeny isolated from primary recipients of either 45R- or 45R+ cells transferred into secondary nude recipients induced skin allograft rejection with equal effectiveness and also generated 45R+ offspring. The results indicated that CD4 T cell subsets switched between CD45R isoforms and that the change between high and low molecular weight expression was bi-directional. The splice variants apparently are not lineage or maturation markers, but rather identify CD4 T cells that exist transiently in different functional states.     

Antigenic determinants encoded by alternatively spliced exons of CD45 are determined by the polypeptide but influenced by glycosylation

Antibodies recognising the products of alternatively splicedexons near the N-terminus of the leukocyte common antigen, CD45,have been widely used to distinguish populations of lymphocyteswith different functional properties. These alternatively splicedregions contain a high content of serine and threonine residues(average 35%) and are heavily O-glycosylated. Despite evidencethat the O-glycosylation contributes significantly to the antigeniccharacter of this region of CD45, work with leukosiailn andmucln glycoproteins toads to the prediction that the majorityof epttopes in the N-terminal exons should be linear proteindeterminants. In this study the exons of CD45 were expressedin Eachmrlchla coll as non-glycosylated proteins fused to glutathioneS-transferase (GST). Fourteen out of 17 mAbs specific for humanCD45R reacted with a fusion protein containing exons 4, 5 and6 (ABC) of human CD45, and four out of six mAbs specific forrat CD45R reacted with an equivalent rat protein. mAbs recognisingthe product of rat exon B are reported for the first time. Kineticanalysis of MRC OX22 antibody binding to spleen CD45 and toGST fusion proteins showed that the carbohydrate affected thekinetics of binding of antibodies to the protein backbone. Inconclusion, heterogeneity in the glycosylation of heavily O-glycosylatedcell surface proteins can affect interactions of these proteinsboth directly through the carbohydrate and indirectly througheffects on the protein backbone.