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.     

In vivo and in vitro effects of monoclonal antibody to Ly antigens on immunity to infection

Injection of CBA mice with Brucella abortus strain 19 leads to chronic infection during which both cell-mediated immunity (delayed hypersensitivity and macrophage activation) and antibody production occur. Protection was efficiently transferred to naive mice using spleen cells from mice infected 5 or 12 weeks earlier. Selective lysis in vitro of these cells by antibody to cell surface antigens showed that Thy-1⁺ Ly-1⁺2⁺ T lymphocytes were required for transfer. Treatment with anti-Ia serum neither suppressed nor enhanced adoptive transfer. Thus Ia⁺ B lymphocytes were not required, and Ia⁺ suppressor T cells were not active in the response. Three injections per week of anti-Ly-1 monoclonal antibody beginning 5 days before infection led to a 10-fold increase in bacterial numbers 25 days after infection when acquired immunity was well established in untreated mice. The delayed hypersensitivity response was unaffected. In addition cells from these in vivo treated mice were unable to transfer resistance. Beginning the treatment on the day of infection abolished the IgG antibody response without affecting bacterial numbers. The studies emphasize the unique role of Ly-1⁺2⁺ T cells in immunity to Brucella and indicate the usefulness of these techniques in dissecting out those components of the immune response which contribute to recovery from infection.     

Analysis of Ly-6.2-bearing murine lymphocyte subpopulations in relation to the T-lymphocyte markers,Thy-1, Lyt-1, and Lyt-2

Using immunofluorescence with a monoclonal anti-Ly-6.2 antibody and FACS analysis we have confirmed that the Ly-6.2 antigen is present on approximately 70% of mature T cells and B cells but on few immature lymphocytes. There is a wide range of antigen density among the Ly-6.2⁺ populations, with the mean density higher on T cells than B cells. Following Con A activation of splenocytes there was a sixfold increase in Ly-6.2 antigen density though approximately 20% of the activated lymphocytes were Ly-6.2^?. The increase in Ly-6.2 density was specific since similar density increases did not occur for the closely linked antigens ThB and H $\text{9}\text{25}$. By panning a predominantly T-cell population for Lyt-2-bearing cells, it was found that Lyt-2⁺ lymphocytes were either negative or dully staining for Ly-6.2. However, activated cells bearing the Lyt-2 antigen were all Ly-6.2 positive. Double-staining experiments showed that T cells which had high Ly-6.2 antigen densities also had high Thy-1 antigen densities. Corticosteroid-resistant thymocytes were highly enriched for Ly-6.2-bearing cells compared to untreated thymocytes and had staining profiles for Ly-6.2 which were similar to peripheral T cells, supporting the idea that steroid treatment selects for a phenotypically mature thymic population.     

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:

Role of Ly-6A/E and T cell receptor-zeta for IL-2 production. Phosphatidylinositol-anchored Ly-6A/E antagonizes T cell receptor-mediated IL-2 production by a zeta-independent pathway.

Ly-6A/E molecules were originally implicated in regulation of T cell activation because anti-Ly-6A/E mAb induce IL-2 production. More recently we have shown that anti-Ly-6A/E also inhibits IL-2 production induced by anti-CD3. In the present study we used mutant and transfected cell lines that varied in expression of Ly-6A/E or TCR-zeta to test whether the positive and negative modulations of IL-2 production by anti-Ly-6A/E occur by distinct mechanisms. Anti-Ly-6A/E inhibited anti-CD3-induced IL-2 production for Ly-6E.1-transfected EL4J cells, but did not affect IL-2 production of the parental Ly-6A/E-negative EL4J cells. These results indicate that TCR-mediated IL-2 production can occur in the absence of Ly-6A/E expression and establish that anti-Ly-6A/E-induced inhibition of IL-2 production was the result of antibody binding to Ly-6A/E. As expected, MA5.8 (zeta-negative) or CT108 (zeta-truncated) variants of the 2B4.11 T cell hybridoma did not produce IL-2 when stimulated with anti-Thy-1 or anti-Ly-6A/E mAb. In contrast, anti-Ly-6A/E inhibited anti-CD3-induced IL-2 production by MA5.8 and CT108. Furthermore, anti-Ly-6A/E-induced IL-2 production was restored for zeta-transfected MA5.8. Thus, although induction of IL-2 by anti-Ly-6A/E depends on zeta expression, inhibition of IL-2 by anti-Ly-6A/E occurs by a zeta-independent mechanism. Interestingly, anti-Ly-6A/E, but not anti-Thy-1, inhibited anti-CD3-induced IL-2 production by MA5.8 and Ly-6E.1-transfected EL4J. Therefore, inhibition of IL-2 production by anti-Ly-6A/E was not a general property of a mAb binding to a phosphatidylinositol-linked molecule, as has been suggested for induction of IL-2 production. Taken together these data suggest that the molecular mechanisms of induction and inhibition of IL-2 production by anti-Ly-6A/E are separable and expression of TCR-zeta is one variable that distinguishes these two pathways.     

Role of self carriers in the immune response and tolerance. IV. Active T cell suppression in the maintenance of B cell tolerance to a "T-independent" antigen.

Previous studies indicated that T cells are required for tolerance induction by hapten-modified syngeneic spleen cells (TNP-SC) in vivo. The role of T cells in the maintenance of this unresponsive state has been examined herein. By three criteria--limiting dilution precursor analysis, removal of T cells by anti-Thy-1 + C, and direct mixing experiments--we show that T cells are required for the continued suppression of the B cell response to the T-independent antigen, TNP-POL. Suppressor cells can also be induced by TNP-teratoma cells, which lack detectable H-2 antigens. Both anti-Ly-1 + C and anti-Ly-2 + C treatment reversed suppression induced by TNP-SC. These results demonstrate that normal B cell reactivity is present in the spleens of mice rendered tolerant by haptenated self, but that Ly-1,2,3 or Ly-1 + Ly-2,3 suppressor T cells prevent their responsiveness.     

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.     

Regulation of B lymphocyte responses to IL-4 and IFN-gamma by activation through Ly-6A/E molecules

The Ly-6 family of cell surface molecules has previously been shown to participate in T cell activation. We show that Ly-6A/E proteins also modulated the response of normal B lymphocytes in three separate in vitro assays. First, unfractionated or small resting B cells proliferated when cultured with IFN-gamma, IL-4, and an anti-Ly-6A/E mAb. Second, this anti-Ly-6A/E mAb restored B cell proliferation responses that were inhibited when coculturing the B cells in IFN-gamma, IL-4, and anti-IgM. Third, anti-Ly-6A/E specifically up-regulated the cell surface expression of its own Ag, and this response was dependent upon co-stimulation with IFN-gamma. Mixing of T and B cells in culture suggested that T cells did not contribute substantially to the B cell proliferative response. Moreover, up-regulation of Ly-6A/E was observed for one B cell lymphoma, WEHI-231. Therefore, it appeared that modulation of B cell function by anti-Ly-6A/E was due to a direct effect of the mAb binding to the B cells. Taken together, these data suggest Ly-6A/E proteins are functional on B cells and may play a regulatory role in B cell activation.     

Modulation of T-cell functions: I. Effect of 2-mercaptoethanol and macrophages on T-cell proliferation

The in vitro effects of 2-mercaptoethanol (2-ME), macrophages (MØ), and concanavalin A (Con A) on the proliferation of normal spleen cells (NSC), MØ-depleted spleen cells (DSC), T cells, T-cell subpopulations, and B cells were assessed by [³H]thymidine incorporation. 2-ME alone was consistently shown not to be mitogenic for purified T cells; however, 2-ME enhanced the early (Days 1 and 2) Con A (2 μg/ml)-induced response of NSC, DSC, and T-cell preparations, but depressed the late response (Days 4 and 5). 2-ME alone was mitogenic for purified B-cells, as reported previously; and the 2-ME-induced B-cell response was inhibited by Con A. Preincubation of T cells with 2-ME was sufficient for enhanced Con A responsiveness; however, if 2-ME was added 24 hr after the initiation of culture, no alteration of the Con A-induced response was observed. Ly-2,3⁺ T cells were unresponsive to Con A (0.3–20 μg/ml), but the addition of 2-ME or peritoneal cells enhanced the Con A responsiveness of Ly-2,3⁺ T cells over 200-fold. Ly-1⁺ T cells responded with a similar doseresponse and kinetic profile as unselected T cells. Although Ly-1⁺ T cells responded to Con A, unlike Ly-2, 3⁺ T cells, extensive removal of MØ significantly reduced the Con A-induced responsiveness of the Ly-1⁺ T cells. The reactivities of Ly-1⁺ and Ly-2,3⁺ DSC could be reconstituted by the addition of MØ or 2-ME; however, the kinetic response of Ly-1⁺ T cells peaked on Day 2–3, and Ly-2,3⁺ T cells had a delayed response which peaked on Day 4–5. The results indicated that (i) 2-ME and/or MØ accelerate the response kinetics of T-cells to Con A; (ii) T-cell subpopulations have differential requirements for MØ and/or 2-ME in the response to Con A; (iii) T-cell subpopulations exhibit differential dose responsiveness to Con A; and (iiii) 2-ME alters Con A responsiveness by a direct effect on T cells.     

Cellular control of abscess formation: role of T cells in the regulation of abscesses formed in response to Bacteroides fragilis

Although abscesses are a major sequela of infection, little is known about which cellular events initiate and which prevent this pathologic response. These studies are the first to indicate a role for T cells in the important pathogenic process of abscess development and also in immunity to abscesses induced by Bacteroides fragilis. We have shown that T cells initiate the formation of abscesses in mice after i.p. challenge with B. fragilis. These T cells bear both Ly-1 and Ly-2 surface markers. Nude mice (which have been shown by others to have T cell or T cell precursors) are also able to form abscesses. Cyclophosphamide-treated mice (with depressed T cell function) were not capable of developing abscesses. Reconstitution with normal or nude mouse spleen cells restored this ability. However, reconstitution with anti-Thy-1.2-treated, anti-Ly-1, or anti-Ly-2-treated spleen cells (or a mixture of the two cell populations) failed to allow abscess formation after bacterial challenge. Immunity to abscesses caused by B. fragilis requires two T cells. The first Ly-1-2+ T cell has an IJ surface marker and has been shown to release a small m.w. soluble factor (ITF) that is antigen specific. Immunity to abscesses, however, depends on the interaction of ITF with a second Ly-1-2+ T cell, demonstrated in reconstitution experiments with nude mice. The data presented document a critical role for T cells in abscess induction and suggest the existence of a suppressor-like T cell circuit in immunity to abscesses.     

The blocking activity of antisera raised to either tumor antigens or alloantigens in cytotoxicity assays using syngeneic or allogeneic killer cells on the P815 murine mastocytoma target

Methods have been published whereby a tumor-specific antigen associated with membranes of the P815 mastocytoma of DBA/2J mice was purified. Antiserum, raised in rabbits, to this material demonstrated specificity for P815 as opposed to other cells or materials of DBA/2J origin when tested by either complement-mediated target cell lysis or the enzyme-linked immunosorbent assay ELISA. This antiserum was tested for its ability to block killing by in vitro raised syngeneic lymphocytes cytotoxic for P815. It was found that this antiserum as well as antiserum raised in rabbits to normal DBA/2J membrane components and anti-H-2^d antiserum (raised in congenic mice) were all able to block killing when ⁵¹Cr-labeled P815 targets were pretreated with these antisera. On the other hand, only the anti-DBA/2 serum and the anti-H-2^d serum were capable of slightly blocking syngeneic killing of L1210 cells. Similarly, C57B1/6 cytotoxic lymphocytes raised against DBA/2 cells were blocked by pretreatment of ⁵¹Cr-labeled P815 targets with the rabbit anti-DBA/2 serum and the anti-H-2^d serum but not by the anti-P815 serum. The implications of these observations are discussed.     

Lysis of herpes simplex virus-infected targets: II. Nature of the effector cells

Peripheral blood lymphocytes (PBL) from patients with herpes simplex virus (HSV)-1 recurrences in the cornea only (Group I) exhibited reduced lysis of HSV-1-infected targets compared to PBL from patients with oral-facial and corneal HSV recurrences (Group II). The cytotoxic lymphocytes appeared to belong to a subpopulation of natural killer (NK-HSV) cells. Monoclonal antibodies to human lymphocyte differentiation antigens were used to define the surface phenotype of the NK-HSV cells. Most of the NK-HSV activity was mediated by lymphocytes expressing the surface markers Leu-7⁺ (HNK-1), OKT3⁺ (pan T), OKM1⁺ (myeloid and NK), Leu-2^? (cytotoxic/ suppressor T cell), and Leu-8^? (regulatory T cell). In contrast, lysis of K562 cells (NK-K562) was mediated by lymphocytes bearing the surface phenotype Leu-7⁺, OKT3^?, OKM1⁺, Leu-2^+/?, and Leu-8^?. The low level of NK-HSV activity in PBL from Group I donors appeared to be due to active suppression by suppressor T lymphocytes. Depletion of Leu-2⁺ cells from PBL of Group I donors resulted in significant augmentation of NK-HSV activity. Similar treatment of PBL from Group II donors either had no effect or slightly diminished the NK-HSV activity.     

Characterization of an in vitro proliferation response to solubilized Trichinella spiralis antigens: Role of Ia antigens and Ly-1+ T cells

An antigen extract from Trichinella spiralis muscle larvae was prepared and used to immunize strains of mice which were either relatively resistant (B10.S) or susceptible (B10.BR) to oral infection with T. spiralis larvae. Proliferation of cells from the draining lymph nodes was then measured in vitro after stimulation with the T. spiralis extract as well as appropriate control antigens. Primed cells from resistant B10.S mice responded better to challenge than did cells from the susceptible B10.BR strain. Cell-depletion experiments involving B10.S cells indicated that the in vitro cell proliferation response is dependent upon Ly-1⁺ T cells. The data were also consistent with a requirement for Ly-1⁺, -2⁺, and -3⁺ amplifier cells. Administration of anti-I^s serum to the cultures specifically inhibited (nearly 75%) the cell proliferation response. The potential applications of this system as a tool in immunogenetic analyses of immunity to T. spiralis are discussed.     

Immunosuppression induced by staphylococcal enterotoxin B

Staphylococcal enterotoxin B (SEB) is a potent mitogen for both human and murine T lymphocytes. We report here studies which demonstrate that a suppressor cell population, capable of suppressing the primary immune response of normal syngeneic mouse splenocytes to heterologous sheep erythrocytes (SRBC), is activated by SEB. Enterotoxin concentrations ranging from 0.05 to 5.0 Mg ml^?1 are capable of activating this suppressor cell population, and significant suppression can be detected with relatively small numbers of SEB-primed spleen cells (SEB-PSC) in culture. Elimination of macrophages before or after priming splenocytes with SEB does not reduce the suppression of plaque-forming cell (PFC) responses when SEB-PSC are added to normal cells in Mishell-Dutton cultures. Treatment of cells with anti-Thy-1 serum plus complement, after priming with SEB, effectively eliminates the activity of the suppressor cell population. Enrichment for T cells before priming with SEB results in greater suppression of PFC responses than do SEB-PSC generated in cultures of nonfractionated splenocytes. Activation of suppressor cells with SEB in vitro appears to occur through the induction of the T-cell subpopulation expressing the Lyt-1^?,2⁺,3⁺ cell surface phenotype, since selective depletion of this T-cell subpopulation with monoclonal rat anti-mouse Lyt-2 antisera after priming cells with SEB virtually eliminates the suppressor activity.     

Discrimination of suppressor T cells of humoral and cell-mediated immunity by anti-Ly and anti-Ia sera.

Evidence is presented which demonstrates that the T lymphocytes which suppress humoral and cell-mediated immunity in CBA/H mice differ in the cell surface structures they express. The suppressor T cells of delayed-type hypersensitivity are Ly-1⁺, Ly-2^? and Ia^?, whereas the suppressor T cells of antibody formation are Ly-1^?, Ly-2⁺ and Ia⁺.     

Inhibition of the lytic phase of murine T-cell-mediated alloimmune cytotoxicity by a rat antiactivated T-cell antiserum

Antisera produced in rats by immunization with alloimmune murine C57Bl/6 anti-P815 splenic lymphocytes or purified T cells activated in vitro by coculture with phytohemagglutinincoated L-929 cells were found to inhibit the in vitro cytolytic action of in vivo and in vitro alloimmune C57Bl/6 anti-P815 cytotoxic T cells in a 4-hr chromium-51 release assay. The rat anti-murine-activated lymphocyte (anti-MAL) or antiactivated T-cell (anti-ATC) serum inhibited lysis in the absence of exogenously added complement activity and were not directly cytotoxic to CTL. Absorption of anti-MAL with target cells P815, L-929, EL-4, and normal C57Bl/6 lymphocytes removed a limited amount of the CTL-inhibitory activity. In contrast, lectin-activated alloimmune lymphocytes fully absorbed the inhibitory activity indicating these antisera preferentially recognize unique antigenic determinants associated with the activated CTL cell surface. The anti-ATC was found to block alloimmune lysis by CTL from several inbred mouse strains suggesting these antisera recognized antigenic determinants of a common lytic mechanism. A kinetic analysis of the inhibitory activity of the anti-MAL on the CTL reaction scheme revealed this antiserum inhibited lysis at a post-Ca²⁺-dependent step, presumably during the target cell lytic phase. This result suggests the rat antiserum can neutralize the CTL lytic mechanism.     

Studies on non-H-2-linked lymphocyte-activating determinants. IV. Ontogeny of the Mls product on murine B cells.

The minor lymphocyte stimulating (Mls) locus codes for lymphocyte activating determinants (LADs) on murine B lymphocytes, but not T lymphocytes. This observation was strengthened by a series of techniques which allow deletion and addition of T and B cells. These included the use of cytotoxic antisera such as anti-Thy 1.2, anti-MTLA, anti-MBLA, and complement, and the use of a goat anti-μ antisera, and finally the use of a fluorescence activated cell sorter (FACS).The studies in this report document the organ distribution and the ontogenetic appearance of the surface LADs on the surface of B lymphocytes from DBA/2N (H-2^d, Mls^a) and CBA/J (H-2^k, Mls^d) mice. Adult-like ability to stimulate H-2 identical BALB/c (H-2^d, Mls^b) and C3H/He (H-2^k, Mls^c) responder cells appeared at about 4–5 weeks of age. Inability of neonatal cells to induce an Mls-defined MLC was found not to be due to a low frequency of B lymphocytes or to the presence of suppressor cells, but due to the absence of the Mls-coded LADs on their surface. These data support the concept that the Mls-coded LADs are present on adult B lymphocytes and are specific markers of B-cell differentiation, which is preceded by membrane IgM and the δ homologue of human IgD, Ia, and the receptor for the third component of complement.     

Enhanced natural killer (NK) cell activity and NK-sensitive thymic cells in murine muscular dystrophy

Studies have shown that there is an abnormality in the thymus of dystrophic mice with respect to age-dependent thymus weight changes and altered morphology (T. DeKretser and B. Livett, Nature (London), 263, 682, 1976). Recently, others have shown that natural killer (NK) cells can lyse cells of a large, immature, rapidly dividing cell subpopulation within the thymus of normal young (3 weeks of age) mice (M. Hansson, K. Karre, R. Kiessling, J. Roder, B. Anderson, and P. Hayry, J. Immunol., 123, 765, 1979). The NK susceptibility of dystrophic mouse thymocytes as targets was therefore studied. Spleen cells from normal (+/+) and dystrophic ($\text{dy}{}^{\mathrm{2J}}\text{dy}{}^{\mathrm{2J}}$) male C57BL/6J mice 8–10 weeks old were passed over nylon wool and the nonadherent cells were incubated with ⁵¹Cr-labeled YAC-1 lymphoma target cells or thymocytes in a ⁵¹Cr-release assay. Spleen cells from dystrophic mice killed twofold more YAC-1 target cells than did spleen cells from normal mice. Thymocytes from 3- to 4-week-old dystrophic mice were three to four times more susceptible to NK lysis by dystrophic mouse spleen cells as compared with normal mouse spleen cells. Spleen cells from dystrophic mice had the same NK activity against dystrophic and normal mouse thymocytes as targets. Normal mouse spleen cells killed three- to fourfold more dystrophic mouse thymocytes than that of normal mouse thymocytes as targets. Target cellbinding studies revealed that conjugate-forming cells from nylon nonadherent dystrophic mouse spleen cells were found to be two- to fourfold greater than for normal mouse spleen cells using YAC-1 tumor cells as targets. The number of lymphocytes bound per YAC-1 target cell ranged from 2 to 5 for dystrophic mouse spleen cells as compared with 1 to 2 for the normal control group. Using both normal and dystrophic mouse thymocytes as targets, the conjugate-forming cells from dystrophic mouse spleen cells were also found to be twofold greater than in the normal control group. Cold target inhibition studies revealed that the natural killing of dystrophic mouse thymocytes was due to a YAC-1-reactive NK cell. Effector cell depletion studies using monoclonal anti-Thy-1.2 plus complement treatment and plastic petri dish adherence also revealed that the natural killing of dystrophic mouse thymocytes was not due to either T lymphocytes or macrophages. Taken together, these results show an increase in NK-sensitive thymocyte targets in dystrophic mice, in combination with an increase in splenic NK activity.     

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.     

Ly-4.2: Doubts concerning its validity as a B-cell marker

The serum used to define Ly-4.2, (BALB/c × SWR/J)F₁ anti-B10D2/n, was found to react equally with both donor B and T cells, contrary to the findings of McKenzie and Snell (1975) that the serum reacted mainly with B cells. The reaction with both B and T cells was demonstrated by a 90 to 100 percent killing of spleen, lymph node, and separated populations of B and T cells from both organs. Although the antiserum only lysed 10 to 20 percent of thymocytes, these cells could be used to remove all reactivity against lymph node and spleen cells. Depletion of the T cells in a lymph node suspension by Thy-1.2 treatment did not affect the percentage of lysis of residual cells. Attempts to remove possible contaminating antibodies by absorption with either donor thymus or EL4 cells were unsuccessful because these tissues removed all antibody activity. Neither did partial absorption with separated B and T cells affect the relative activity against these cells. The strain distribution of Ly-4.2 was similar to that reported in the literature, and backcross tests indicated that there was probably no linkage with theH-2 locus.