Activation induced differential regulation of stem cell antigen-1 (Ly-6A/E) expression in murine B cells

Expression of stem cell antigen-1 (Ly-6A/E) is developmentally regulated in murine B cells. However, little is known about its modulation during B cell activation. We report here the differential regulation of Ly-6A/E expression in response to diverse activation signals in mature B cells. Stimulation of resting B cells through the antigen receptor (BCR) inhibited, Ly-6A/E surface expression in dose dependent manner. Activation induced downregulation of Ly-6A/E is specific to BCR mediated signaling events as stimulation of B cells with anti-CD40, lipopolysaccharide or interferon-γ induced upregulation of Ly-6A/E surface expression. The activation induced differential modulation of Ly-6A/E expression is mediated at the mRNA levels. A role for BCR signaling in inhibition of Ly-6A/E expression was further confirmed using STAT-1^−/− B cells, which expressed constitutive, but not inducible Ly-6A/E. The BCR induced inhibition of Ly-6A/E RNA and surface expression was mimicked by ionomycin, but not phorbol myristate acetate, indicating a role for calcium but not protein kinase C dependent signaling events. Inhibition of calcineurin reversed the BCR or ionomycin inhibited Ly-6A/E expression. Interestingly, in vitro differentiation analysis of Ly-6A/E⁺ and Ly-6A/E⁻ splenic B cells revealed the Ly-6A/E⁺ cells to be the major source of antibody production, suggesting a potential role for Ly-6A/E in B cell differentiation. These studies provide the first evidence for activation induced differential modulation and differentiation of Ly-6A/E⁺ B cells.     

Coordinate change in phenotype in a mouse cell line selected forCD8 expression

A CD4⁺, CD8⁺ derivative of the CD4⁺, CD8^– cell line SAKRTLS 12.1 was isolated by fluorescence activated cell sorting for CD8⁺ cells. This derivative showed a co-ordinate change in a number of independent characters: The parental cell line was CD4⁺, CD8^–, CD3⁺, CD5^hi, HSA⁺, DEX^R, CD44^hi, while the derivative was CD4⁺, CD8⁺, CD3^–, CD5¹⁰, HSA⁺, DEX^S, CD44¹⁰. The derivative expressed the Thy-1.1, Ly-2.1, and Ly-3.1 surface antigens, consistent with origin from the SAKRTLS 12.1 parental cell line, and showed a drug resistance profile identical to that of the parent. It was not possible to isolate revertants with a phenotype identical to that of the parental cell line. Activation of the structural gene coding for CD8 chain was correlated with demethylation at several sites. We interpret these results to mean that this CD8⁺ derivative of SAKRTLS 12.1 arose as a result of an alteration of a gene that coordinately regulates multiple genes whose expression changes during thymocyte differentiation. Gene methylation may contribute, directly or indirectly, to some or all of the changes in gene expression observed. Address correspondence and offprint requests to: R. Hyman.     

Positive selection of Tcrb-V10b+ T cells

The Tcrb-V10b⁺ T cell population has been examined with a newly established antibody, KT10b, specific for Tcrb-V10b but not Tcrb-V10a. H-2E⁺ mice have higher levels of Tcrb-V10b⁺ T cells (4.3%–11.%) than H-2E^– mice (2.2%–4.9%). This difference appears to be determined by levels of Tcrb-V10b⁺ T cells in the CD4 population. F₁ mice between H-2E⁺ and H-2E^– mice dominantly express higher levels of Tcrb-V10b⁺ T cells. [NOD (E–) x (NOD x A (E⁺))F₁] backcross mice show positive selection of Tcrb-V10b⁺ CD4⁺ T cells by H-2E. On the other hand other backcross analyses reveal positive selection of Tcrb-V10b⁺ CD8⁺ T cells by certain major histocompatibility class I molecules. Involvement of non-H-2 antigens in these positive selections remain to be determined. Address correspondence and offprint requests to: K. Tomonari.     

Expression of an unusual T cell receptor (TCR)-V beta repertoire by Ly-6C+ subpopulations of CD4+ and/or CD8+ thymocytes. Evidence for a developmental relationship between Ly-6C+ thymocytes and CD4-CD8-TCR-alpha beta+ thymocytes.

A novel thymocyte subpopulation expressing an unusual TCR repertoire was identified by high surface expression of the Ly-6C Ag. Ly-6C+ thymocytes were distributed among all four CD4/CD8 thymocyte subsets, and represented a readily identifiable subpopulation within each one. Ly-6C+ thymocytes express TCR-alpha beta, arise late in ontogeny, and appear in the CD4/CD8 developmental pathway after birth in a sequence that resembles that followed by conventional Ly-6C- cells during fetal ontogeny. Most interestingly, adult Ly-6C+ thymocytes express an unusual TCR-V beta repertoire that is identical to that expressed by CD4-CD8-TCR-alpha beta+ thymocytes in its overexpression of TCR-V beta 8 and in its expression of some potentially autoreactive TCR-V beta specificities. This unusual TCR-V beta repertoire was even expressed by Ly-6C+ thymocytes contained within the CD4+ CD8- 'single positive' thymocyte subset. Thus, expression of this unusual TCR-V beta repertoire is not limited to CD4-CD8-thymocytes, and is unlikely to be a consequence of their double negative phenotype. Rather, we think that Ly-6C+TCR-alpha beta+ thymocytes and CD4-CD8-TCR-alpha beta+ are developmentally interrelated, a conclusion supported by several lines of evidence including the selective failure of both Ly-6C+ and CD4-CD8-TCR-alpha beta+ thymocyte subsets to appear in TCR-beta transgenic mice. In contrast, peripheral Ly-6C+ T cells are developmentally distinct from Ly-6C+ thymocytes in that peripheral Ly-6C+ T cells expressed a conventional TCR-V beta repertoire and developed normally in TCR-beta transgenic mice in which Ly-6C+ thymocytes failed to arise. We conclude that: 1) expression of a skewed TCR-V beta repertoire is a characteristic of Ly-6C+TCR-alpha beta+ thymocytes as well as CD4-CD8-TCR-alpha beta+ thymocytes, and is not unique to thymocytes expressing neither CD4 nor CD8 accessory molecules; and 2) Ly-6C+ thymocytes are developmentally linked to CD4-CD8-TCR-alpha beta+ thymocytes, but not to Ly-6C+ peripheral T cells. We suggest that Ly-6C+TCR-alpha beta+ thymocytes are not the developmental precursors of Ly-6C+ peripheral T cells, but rather may be the developmental precursors of CD4-CD8-TCR-alpha beta+ thymocytes.     

A structural model for the location of the Rodgers and the Chido antigenic determinants and their correlation with the human complement component C4A/C4B isotypes

In this study, the relative mass of the Ly-6A.2 antigen was shown to be 12 000–14 000, in contrast to initial studies which showed the relative mass to be 33 000. Using polymorphic Ly-6-specific antibodies, the 33 000 molecules could be immunoprecipitated from surface-iodinated thymocytes of Ly-6A.2⁺, Ly-6A.2^– strains and a Ly-6A.2^– mutant cell line BW(Thy-1^–e). This clearly demonstrated that 33 000 molecules were not associated with the Ly-6 polymorphism. By contrast, when biosynthetically labeled Ly-6A.2⁺ spleen cell lysates were analyzed, the major species immunoprecipitated by the polymorphic Ly-6A.2-specific antibody was 12000–14000, although a minor 33 000 species were also evident. The Ly-6A-specific antibody D7 which detects a monomorphic epitope on the Ly-6A molecule could immunoprecipilate the 12000–14000 molecules from surface-labeled cells. By contrast, the Ly-6A.2-specific antibodies detecting the polymorphic Ly-6A.2 determinant could not, though the reasons for this difference are not clear. Thus 12 000–14 000 molecules were only immunoprecipitated from Ly-6A.2⁺ cells, whereas 33 000 molecules were precipitated from both Ly-6A.2⁺ cells and Ly-6A.2^– cells. These findings suggest that the 33 000 molecules immunoprecipitated by 5041-24.2 are most likely to be an unrelated protein, possibly cross-reactive with some Ly-6A.2 antibodies.     

A new serologically defined locus,Qa-1, in theTla-region of the mouse

A new cell-surface antigen, specified by a gene betweenH-2D andTla is described. The provisional notationQa-1 is suggested for the locus determining this newly recognized cell surface component. Qa-1 is distinguished from known TL antigens by the following two criteria. Its expression is not confined to thymocytes — it occurs on lymph node cells (LNC) also; and the phenotypes of the new congenic recombinant strains B6.K1 and B6.K2, derived fromH-2D/Tla crossovers, are Qa-1⁺ Qa-2^–TL^– and Qa-l⁺Qa-2⁺TL^–. Qa-1 antigen is defined by reaction of the standard TL typing serum, (B6 × A -Tla ^b)F₁ anti-A strain leukemia ASL1, with lymph node cells (LNC) in the cytotoxicity assay. Qa-1 antigen evidently is expressed, at least, on a subpopulation of T cells as well as on thymocytes. The gene order isH-2D, Qa-1, Qa-2, Tla.Abbreviations used in this paper LNC lymph node cells pooled from inguinal, axillary, brachial, and mesentric nodes - BA⁺ (C57BL/6-Tla^axA)F1 - BA^– (C57BL/6 × A -Tla ^b)F₁ - PBS phosphate buffered saline pH 7.2 - Thy thymocytes - RMIg Rabbit anti-mouse immunoglobulin Please address proofs and communications concerning this paper to Dr. Thomas Stanton, Sloan Kettering Institute, 1275 York Ave., New York, N.Y. 10021     

The Ly-10 antigen is a marker of mouse-activated T lymphocytes

Ly-10.1 is a lymphocyte surface antigen controlled by a gene linked to the Ly-1.1 locus and expressed on activated T helper, T suppressor (Ts), and cytotoxic T lymphocytes (CTL). In this report, we describe the following:

Effects of Chorionic Gonadotropin on Differentiation of Thymocytes in the Presence of Epithelial Thymus Cells

We studied the effects of the main placental hormone, chorionic gonadotropin, on differentiation of human thymocytes in vitro in the presence of thymic epithelial cells. It was shown that the hormone at a high dose (100 IU/ml) enhanced the epithelium-induced phenotypic maturation of thymocytes, which is registered by an increased expression of the membrane marker CD3 and transition of CD4⁺8⁺ thymocytes in the cells with CD4⁺8^– and CD4^–8⁺ phenotypes. In addition, gonadotropin enhanced the proliferative response of thymocytes to the mitogen during their cultivation with the epithelium. The stimulating effect of the hormone on the epithelium-induced differentiation of thymocytes is mediated by the humoral factors of epithelial cells. In addition, gonadotropin at this dose exerts its own differentiating activity with respect to thymocytes and stimulates their phenotypic and functional maturation in a monoculture.     

Definition of new alloantigens encoded by genes in the Ly-6 complex

Three alloantigens encoded by Ly-6-linked genes are defined by monoclonal antibodies. The Ly-27.2 antigen is defined by antibody 5075-19.1, Ly-28.2 by 5075-3.6, -12.1, -16.10 and by 5095-16.6. The strain distribution pattern of these antibodies is the same and identical with Ly-6.2. However the tissue distribution of these antigens is unique and distinguishes these antigens from the Ly-6.2 antigen or any known antigen encoded by Ly-6-linked genes. Ly-27.2 is present on all thymocytes, T cells, and B cells but is absent from bone marrow cells, whereas Ly-28.2 is absent from most thymocytes and is present on a subpopulation of T cells and B cells but is found on 60–70% of bone marrow cells. No recombination between the Ly-6/Ly-27/Ly-28 loci was found in linkage studies using 41 recombinant inbred strains and 57 backcross mice and indicates very close linkage of these genes. In addition, close linkage to 24 minor histocompatibility genes was excluded using the Bailey HW bilineal congenic mice. The data presented indicate that either the Ly-6 complex is composed of a family of tightly linked genes or the antigens are the products of a single gene that undergoes extensive modification during differentiation.     

Cadmium‐induced apoptosis and phenotypic changes in mouse thymocytes

At present cadmium (Cd)induced immunotoxicity and the mechanisms involved have not been fully elucidated. The main objective of the present study is to explore the apoptogenic property of Cd in primary cultured mouse thymocytes and its effect on cell surface marker expression and phenotypic changes. Cdinduced thymocyte apoptosis was determined by TdTmediated dUTP nick end labeling (TUNEL) assay, DNA content/cell cycle analysis and DNA gel electrophoresis. The results showed that Cd was able to cause apoptosis in mouse thymocytes in a time and dosedependent manner. Moreover, different subsets of thymocytes possessed different susceptibility to the apoptotic effect of Cd, in the order of CD8⁺ > CD4^–CD8^– (double negative cells, DN) > CD4⁺CD8⁺ (double positive cells, DP) > CD4⁺. Cd treatment also altered thymocyte surface marker expression, leading to evident phenotypic changes. Such changes were characterized by a decline in DP cells and a marked decrease in CD4⁺/CD8⁺ ratio, mainly due to a significant increase in CD8⁺ subsets. These observations help to obtain a better understanding of the immunotoxic and immunomodulatory effects of Cd.     

Ly-6.2: A new lymphocyte specificity of peripheral T-cells

A new cell-membrane alloantigen determining locus, Ly-6, has recently been described, and the single specificity Ly-6.2 has been defined by the serum (BALB/c× A)F₁ anti-CXBD. Using both fluorescence and cytotoxicity, we found this specificity predominantly on peripheral (extrathymic) T cells, as tissues react thus: thymus, 0–5 percent; spleen, 25 percent; lymph nodes, 69 percent; bone marrow, 15 percent. These reactions agree with the proportion of (Thy⁺, Ig^–) cells present in these tissues. Cortisone-resistant thymus cells were positive. Absorption studies with thymus cells demonstrated the sparse or absent representation of Ly-6.2 on intrathymic T cells. Examination of spleen and lymph node cells from T cell-depleted C57BL/6 mice (after in vitro treatment with anti-Thy-1 serum or examination of tissues of C57BL/6-nu/nu mice) also showed a depletion of Ly-6.2⁺ cells. Conversely, removal of Ig⁺ B cells, which caused a relative increase in the number of T cells in the residual population, also increased the number of Ly-6.2⁺ cells. Additive effects of anti-Thy-1.2 and anti-Ly-6.2 could not be demonstrated, which suggests that the same population was Thy-1.2⁺, Ly-6.2⁺. However, additive effects could be shown with an anti-Ia serum and anti-Ly-6.2. The Ly-6.2 specificity is not found on red cells, liver, brain, or antibody-forming cells, but has been identified on a T-cell (but not B-cell) tumor and on kidney. Ly-6.2 can therefore be considered to be a marker for peripheral T cells, and it differs from the Thy-1 and the Ly-1,2,3, and 5 specificities in its relative absence from the thymus.     

Ly-6 superfamily members Ly-6A/E,Ly-6C,and Ly-6I recognize two potential ligands expressed by B lymphocytes

Most hemopoietic cells express one or more members of the Ly-6 supergene family of small glycosylphosphatidylinositol-linked proteins. Although levels of Ly-6 proteins vary with stages of differentiation and activation, their function largely remains unknown. To ascertain whether ligands for Ly-6 proteins exist, chimeric proteins were constructed in which Ly-6E, Ly-6C, and Ly-6I were fused to the murine IgM heavy chain. These chimeras specifically stained both developing and mature B lymphocytes, as assessed by flow cytometry. Analysis of variants of the CH27 B cell lymphoma revealed that Ly-6A/E and Ly-6I recognized different molecules. CH27 cells with low levels of Ly-6A/E ligand activity also lost expression of CD22, and cells transfected with CD22 gained the ability to bind the Ly-6A/E chimera and, to a lesser extent, the Ly-6C and Ly-6I chimeric proteins. As many mature B cells coexpress Ly-6A/E and CD22, the function of Ly-6 molecules may be to associate with other membrane proteins, possibly concentrating these ligands in lipid rafts, rather than acting directly as cell:cell adhesion molecules.     

Further definition of the Ly-5 system

Ly-5 is expressed by cells of the hematopoietic branch of development. Further serological analysis of the Ly-5 system, aided by Ly-5 monoclonal antibodies and by two Ly-5 congenic mouse strains, reveals two new Ly-5 alloantigens, Ly-5. 3 and Ly-5.4. The data define three thymocyte phenotypes, Ly-5.1,3, Ly-5.2,4, and Ly-5.2,3, and three corresponding genotypes, Ly-5 ^a, Ly-5 ^b, and Ly-5 ^c, respectively. Ly-5 ^ais by far the most common allele. The Ly-5 ^callele is found only in the ST/bJ strain, a finding that accords with the presently unique pattern of restriction fragments previously observed in Southern blotting of ST/bJ DNA with an Ly-5 cDNA probe. Present serological and biochemical data favor the interpretation that the compound Ly-5 phenotype of thymocytes is attributable to two separate Ly-5 molecular isoforms that exhibit a discrete difference in protein composition, bear different Ly-5 antigens, and are produced jointly by thymocytes, unlike other Ly-5 isoforms previously shown to distinguish different hematopoietic cell lineages.     

Cell density during differentiation can alter the phenotype of bone marrow-derived macrophages

Background

Bone marrow-derived macrophages (BMDMs) are widely used primary cells for studying macrophage function. However, despite numerous protocols that are currently available, lack of a notable consensus on generating BMDMs may obscure the reliability in comparing findings from different studies or laboratories.

Findings

In this study, we addressed the effect of cell density on the resulting macrophage population. With reference to previously published methods, bone marrow cells from wild type C57BL/6 mice were plated at either 4?×?10⁵ cells or 5?×?10⁶ cells per 10 cm and cultured in 20% L-cell conditioned media for 7 days, after which they were analyzed for cell surface markers, production of proinflammatory cytokines, and responsiveness to polarizing signals. Reproducibly, cells plated at lower density gave a pure population of CD11b⁺F4/80⁺ macrophages (97.28?±?0.52%) with majority being Ly-6C^-Ly-6G^- and c-Fms⁺, while those plated at higher density produced less CD11b⁺F4/80⁺ cells and a considerably higher proportion of CD11b⁺F4/80⁺CD11c⁺ (68.72?±?2.52%) and Ly-6C^-Ly-6G⁺ (71.10?±?0.90%) cells. BMDMs derived from higher plating density also secreted less proinflammatory cytokines such as IL-6, IL-12 and TNF-α and were less phagocytic, and had a different pattern of expression for M1- and M2-related genes upon LPS or IL-4 stimulation.

Conclusions

Overall, our findings indicate that altering cell density during BMDM differentiation can give rise to distinct macrophage populations that could vary the outcome of a functional study.

     

Absence of cross-reactivity between murine Ly-6C and Ly-6G.

BACKGROUND: The Ly-6 family has many members, including Ly-6C and Ly-6G. A previous study suggested that the anti-Ly-6G antibody, RB6-8C5, may react with Ly-6Chi murine bone marrow (BM) cells. This finding has been interpreted as cross-reactivity of RB6-8C5 with the Ly-6C antigen, and has been generalized to many hematopoietic cell types, using the terminology Ly-6G/C. The present study was undertaken to determine whether anti-Ly-6G antibodies truly cross-react with the Ly-6C antigen on multiple hematopoietic cell types. METHODS: Splenocytes, thymocytes, and BM cells obtained from Ly-6.1 and Ly-6.2 strains of mice were stained with a variety of antibodies to Ly-6C and Ly-6G. Flow cytometric analysis was performed on these populations. RESULTS: Evaluation of anti-Ly-6C and anti-Ly-6G staining showed only Ly-6C expression and no Ly-6G expression on subsets of splenic T and B cells and thymocytes from Ly-6.1 and Ly-6.2 mice. Bone marrow cells were identified that express both Ly-6G and Ly-6C; no Ly-6G+Ly-6C- populations were seen. CONCLUSIONS: Multiple Ly-6C+ hematopoietic cell populations were identified that do not stain with anti-Ly-6G antibodies. This calls into question the use of the Ly-6G/C nomenclature and suggests that epitopes recognized by anti-Ly-6G antibodies should simply be designated Ly-6G.     

Infiltrated Cells in Experimental Allergic Encephalomyelitis by Additional Intracerebral Injection in Myelin-Basic-Protein-SensitizedB6 Mice

We previously reported that murine experimental allergic encephalomyelitis can be induced by an additional intraperitoneal and intracerebral (i.c.) restimulation in resistant B6 mice after standard immunization with myelin antigens in complete Freund's adjuvant andBordetella pertussis coadjuvant. Neutrophils infiltrated into perivascular spaces at 12 h, followed by mononuclear cells 24 h after i.c. injection. In this study, we report that the i.c. injection induced the expression of intercellular adhesion molecule-1 (ICAM-1) and vascular cell adhesion molecule-1 (VCAM-1). The kinetic expression of ICAM-1 or VCAM-1 on brain endothelial cells paralleled the infiltration of neutrophils and mononuclear cells, respectively. The infiltrated lymphocytes also expressed very late antigen-4 (VLA-4) molecules. The microvascular endothelial cells were positive for VCAM-1, whereas the surrounding mononuclear cells were VLA-4 positive. Furthermore, we found a unique subpopulation of cells with characteristics of CD4-CD8-V8⁺ markers. The kinetic studies of this population showed that these cells were transiently depleted from 12 to 24 h after i.c. challenge (before the development of clinical symptoms) in cervical lymph nodes. These CD4-CD8-V8⁺ cells can be expanded by in vitro culture with myelin basic protein or IL-2. No significant changes of CD4⁺/CD8⁺ cells were noted. CD4⁺CD8^–CD3⁺ cells were also found in brain by double histochemical stains and were the major infiltrating cells at 24 or 48 h after i.c. challenge.     

Positive and negative selection of Tcrb-V6+ T cells

Tcrb-V6⁺ T cells are deleted by an endogenous superantigen probably encoded by a mouse mammary tumor provirus (Mtv), Mtv-7, in association with major histocompatibility complex (MHC) class II molecules. In contrast, Tcrb-V6⁺CD4⁺ T cells are positively selected by MHC class II E molecules in Mtv-7 ^– mice. We have examined the levels of Tcrb-V6⁺CD4⁺ and Tcrb-V6⁺CD8⁺ T cells from six combinations of backcross mice. In this paper we show that: 1) Tcrb-V6⁺CD8⁺ T cells can be positively selected by MHC class I molecules; 2) MHC class II A molecules can also influence the levels of Tcrb-V6⁺CD4⁺ T cells; 3) Mtv-7 ^– NZW mice have a new Mtv, Mtv-44, which co-segregates with a gene encoding the partial deletion ligand for Tcrb-V6⁺ T cells; 4) the remaining Tcrb-V6⁺ T cells from mice with partial deletion of these T cells appear not to be anergized in the periphery. Address correspondence and offprint requests to: K. Tomonari.     

Studies of murine lymphocytes and alloantigens: I. Ly-6 mitogen and MLR responses

Antisera to the mouse lymphocyte surface alloantigens Ly-6.1 and Ly-6.2 were used to further study the functional distribution of these antigens. After selective depletion with antiserum + rabbit complement (RC), lymph node or spleen cells from Ly-6 congenic (C3H and C3H.B6-Ly-6^b) and noncongenic strains of mice were tested for: (a) their proliferative responses to T- and B-cell mitogens; and (b) their proliferative responses to alloantigens, or ability to stimulate in the MLR. Lymphoid cells required in the proliferative responses to the mitogens leucoagglutinin, concanavalin A (Con A), lipopolysaccharide (LPS), and pokeweed mitogen (PWM) were Ly-6⁺. Lymph node responder cells in the mixed lymphocyte reaction (MLR) were also Ly-6⁺, whereas spleen stimulator cells were Ly-6^?. Treatment of lymph node cells with anti-Ly-6 sera in the absence of RC had no specific blocking effect on the response to any of these mitogens. The studies indicate that the Ly-6 antigen is a potentially valuable marker for distinguishing between functionally distinct Ly-1⁺ T-cell subsets.     

Characterization of surface alloantigens of murine neutrophils

Serological analysis of highly purified (>97%) mouse peritoneal exudate neutrophils using a protein-A rosetting technique, showed that these cells possessed the surface phenotype: Ig^–, Thy-1^–, Ly-1^–, Ly-2^–, Ly-3^–, Ly-4⁺, Ly-5⁺, Ly-6⁺, Ly-7^–, Ia^–, FcR⁺ and C3R⁺.     

Allele-specific expression of the mouse B-cell surface protein CD72 on T cells

 CD72 is a 45 000 M _r mouse B-cell surface glycoprotein involved in B-cell proliferation and differentiation. Expression of mouse CD72 is thought to be restricted to the B-cell lineage. We recently demonstrated that the monoclonal antibodies K10.6 and B9.689, previously defined as recognizing the mouse lymphocyte alloantigens Ly-19.2 and Ly-32.2, respectively, recognize specific alleles of CD72. Early studies using antibody-mediated cytotoxicity assays demonstrated that K10.6 and B9.689 react with B cells, several T-cell lines, and a subset of peripheral T cells. These findings led us to consider the possibility that CD72 might also be expressed on a subset of T cells. In this report we demonstrate that CD72 is constitutively expressed on a fraction of peripheral T cells isolated from strains of mice expressing the CD72 ^b allele, but not the CD72 ^a or CD72 ^c alleles. Three days after activating T cells with concanavalin A or plate-bound CD3-specific mAb, CD72 is expressed on a larger fraction of peripheral T cells as well as a fraction of thymocytes from mouse strains expressing the CD72 ^b allele. CD72 is expressed on both the CD4⁺ and CD8⁺ thymocyte and peripheral T-cell subsets. No CD72 expression is detected on activated thymocytes or peripheral T cells from mouse strains expressing the CD72 ^a or CD72 ^c alleles. Expression of CD72 ^b on peripheral T cells was confirmed by northern blot analysis demonstrating CD72 mRNA expression. These results demonstrate that CD72 expression is not restricted to B lineage cells in mouse strains expressing the CD72 ^b allele; instead, a population of T lineage cells in these mice also expresses CD72. Received: 18 June 1996 / Revised: 17 September 1996