Selective localization of radiolabeled immune lymphocytes into syngeneic tumors.

Newly formed long-lived small lymphocytes (LLSL) generated during the immunization of mice to tumor specific transplantation antigens (TSTA) of syngeneic MCA-induced sarcomas were labeled. We then studied the localization of these labeled cells into tumor implants. "Crisis-cross" experiments were performed in which MCA sarcomas with individually distinct TSTA were studied in parallel. A selective localization of LLSL into tumors to which the lymphocytes were immune was found when small tumor pieces were implanted into immune mice whose LLSL had been labeled. Selective localization was also detected upon adoptive transfer of immune LLSL to tumor-bearing mice, but only when these mice had, before transfer, received a sublethal dose of whole body irradiation.     

Production of T cell differentiation factor in syngeneic lymphocyte macrophage culture for cytotoxic T lymphocyte generation

This study demonstrated that T cell differentiation factor (TCDF) was produced in syngeneic lymphocyte-macrophage cultures. Conditioned medium containing TCDF and interleukin 2 (IL 2) induced the differentiation of leukoagglutinin (LA)-activated cytotoxic T lymphocyte precursors (CTLp) into cytotoxic T lymphocyte (CTL) effectors. The production of TCDF and IL 2 peaked at day 4 to 5 in cultures containing normal spleen cells, syngeneic peritoneal macrophages, and indomethacin. Macrophages and T cells with Thy-1+, L3T4+, and Lyt-2- phenotype were needed for TCDF production. There was no requirement for xenogeneic serum in the culture medium; thus, TCDF could be produced in a syngeneic system. Recognition of self Ia molecules appeared to be essential for TCDF production, which was completely abolished by the addition of monoclonal anti-Ia antibody. In our experiments, removal of IL 2 from conditioned medium containing TCDF abolished its ability to generate LA-activated CTL. However, the cytotoxic response could be restored by the addition of a small amount (5 U/ml) of purified human recombinant IL 2 (HRIL 2), which alone was unable to generate LA-activated CTL at this dose. The generation of LA-activated CTL by high dose HRIL 2 (greater than 50 U/ml) was likely due to the endogenous production of TCDF. The bulk of TCDF could be separated from IL 2 by gel filtration in a Sephadex G-100 column. The peak of TCDF activity was concentrated at a m.w. of 16K dalton, and there was very little IL 2 activity in these fractions. When added alone to the LA-activated lymphocyte cultures, these active fractions were unable to induce CTL; supplementation of exogenous IL 2 was needed to restore the cytotoxic responses. Our findings indicate that both IL 2 and TCDF, which are needed in CTL generation. are produced in syngeneic cultures in the absence of antigenic or mitogenic stimulation.     

Functional analysis of mononuclear cells infiltrating into tumors. III. Soluble factors involved in the regulation of T lymphocyte infiltration into tumors

We have analyzed the mechanisms controlling the accumulation of T lymphocytes in tumor tissues. Spleen cells, left or right popliteal lymph node cells, and tumor-infiltrating cells were obtained from tumor-inoculated rats and were cultured for 24 h. Culture supernatants were obtained and assessed for lymphocyte migration factor (LMF) activity with the use of a modified Boyden chamber. We found that tumor-infiltrating cells derived from T-9-sensitized rats produced LMF. Two waves of LMF production were observed. The first wave of LMF production was detected between 6 and 12 h (LMF-a) and the second wave of LMF production was detected between 4 and 6 days (LMF-4d and -6d) after tumor inoculation. The tumor-infiltrating cells consisted of heterogenous cell populations. We found that only tumor-infiltrating neutrophils of T-9-sensitized rats produced LMF-a. Five peaks of LMF (A through E) were detected upon fractionation of LMF-a using Mono Q anion exchange column chromatography. Peak D exhibited the strongest activity. The action of peak D was chemotactic, but not chemokinetic. The m.w. of peak D was 33,000 and 70,000. Only W3/25 (+) (helper/inducer) T cells were found to be sensitive to peak D. The production of LMF-a by purified tumor-infiltrating neutrophils in vitro is in agreement with the histologic observation that the infiltration of neutrophils precedes the appearance of W3/25 (+) T cells in tumor tissues of T-9-sensitized rats. It is thus likely that peak D of LMF-a is responsible for the infiltration of T lymphocytes into tumor tissues.     

Fibroblastic reticular cells guide T lymphocyte entry into and migration within the splenic T cell zone

Although a great deal is known about T cell entry into lymph nodes, much less is understood about how T lymphocytes access the splenic white pulp (WP). We show in this study that, as recently described for lymph nodes, fibroblastic reticular cells (FRCs) form a network in the T cell zone (periarteriolar lymphoid sheath, PALS) of the WP on which T lymphocytes migrate. This network connects the PALS to the marginal zone (MZ), which is the initial site of lymphocyte entry from the blood. T cells do not enter the WP at random locations but instead traffic to that site using the FRC-rich MZ bridging channels (MZBCs). These data reveal that FRCs form a substrate for T cells in the spleen, guiding these lymphocytes from their site of entry in the MZ into the PALS, within which they continue to move on the same network.     

Suppressor T cells regulate the cytolytic T lymphocyte response to syngeneic tumors induced by murine sarcoma virus (MSV) in the mouse.

Studies were designed to analyze the immune activities of spleen cells from mice previously injected with murine sarcoma virus (MSV) and undergoing the processes of MSV tumor growth and rejection. Fractionation of MSV-primed spleen cells according to cell size by velocity sedimentation at unit gravity showed that MSV-specific cytolytic T lymphocytes (CTL) generated in vivo underwent an apparent transition in size from large to small cells as the tumor regressed. The majority of CTL precursors, however, were invariably recovered among small to medium-sized MSV-immune cells, as revealed to CTL generation in vitro in secondary mixed leukocyte-tumor cell cultures (MLTC). Evidence was obtained for the existence in MSV-immune spleens of two suppressor cell populations capable of inhibiting CTL generation in vitro: one population probably consisted of macrophages and could be removed by treatment with carbonyl iron; the second population was comprised of T cells and inhibited the differentiation of tumor-immune CTL precursors in a selective manner. These results provide a preliminary overview of the mechanisms regulating the generation, differentiation, and activity of tumor-specific CTL in a syngeneic model system.     

Abnormal migration of T lymphocyte clones

Several in vitro T cell clones were markedly deficient in their ability to home to peripheral lymphoid tissue. This was found for an alloreactive noncytolytic clone, a soluble antigen- (KLH)specific line, and cytotoxic clones specific for allogeneic cells and for Abelson virus-induced lymphoma cells. This abnormal circulation pattern was probably caused by the lack of the receptors of the lymphocytes for high endothelial venules (HEV), as implied by the lack of binding of these T cells to HEV in frozen sections of mouse lymph node and Peyer's patches. The loss of surface receptors that are necessary for normal lymphocyte migration may thereby alter the in vivo function of adoptively transferred T cells.     

The cytolytic T lymphocyte response to trinitrophenyl-modified syngeneic cells. I. Evidence for antigen-specific helper T cells.

Mice were primed subcutaneously with trinitrophenyl (TNP)-modified syngeneic spleen cells. Seven days later, spleen cells from these in vivo primed mice, or spleen cells from naive mice, were co-cultured with TNP-modified syngeneic cells. Spleen cells from the in vivo primed mice demonstrated augmented cytolytic T lymphocyte (CTL) activity. The spleens of these in vivo primed mice contained a population of radioresistant, antigen-specific, helper T cells. Specifically, spleen cells from these mice, after x-irradiation, were able to augment the in vitro CTL response of normal spleen cells to TNP-modified syngeneic cells.     

The cytolytic T lymphocyte response to trinitrophenyl-modified syngeneic cells. II. Evidence for antigen-specific suppressor T cells.

The subcutaneous administration of trinitrophenyl (TNP)-coupled syngeneic cells 7 days before co-culture with TNP-coupled syngeneic stimulator cells results in increased cytolytic activity. This augmented cytotoxic response has been shown to be dependent, at least partially, on radioresistant "helper" T cells. In this paper we have demonstrated that TNBS-generated suppressor T cells that are capable of suppressing contact sensitivity can specifically suppress the augmented response seen after subcutaneous priming. The i.v. administration of TNP-coupled cells results in priming of the recipient; however, if cells from these animals are transferred to a second recipient, there is evidence of suppressor activity. Thus, the cytotoxic T lymphocyte response is controlled by the same type of complex interactions previously demonstrated for humoral and delayed-type hypersensitivity responses.     

Differential activation of cytotoxic and suppressor T cells against syngeneic tumors in the mouse.

The cytotoxic T cell against a methylcholanthrene-induced sarcoma, S1509a, was induced in syngeneic mice by deliberate immunization with mitomycin C (MMC)-treated live tumor cells. The soluble tumor antigen (STA) extracted from the same tumor by 3 M KCl was, however, unable to induce the cytotoxic T cell upon immunization, although it was able to activate predominantly the suppressor T cell that then specifically suppressed the effect of the cytotoxic T cell against the homologous tumor. The suppressor T cell generated by STA had the same characteristics as those found in tumor-bearing animals: 1) The suppressor T cell has a very strict specificity against individual tumors; 2) The cell expresses cell surface determinants controlled by genes in the I-J subregion of the mouse H-2 complex. The activity of the cytotoxic T cell was completely inhibited by live tumor cells but not by STA, whereas that of the suppressor T cell was neutralized by STA. The results that cytotoxic and suppressor T cells are activated under different conditions, and that the antigenic determinants recognizable by these two cell types are not the same. The soluble extract contains only the determinants recognizable by the suppressor T cell, and the cytotoxic T cell can be activated only by the determinants associated with self antigen present on the surface of live tumor cells.     

Cellular interaction between cytotoxic and suppressor T cells against syngeneic tumors in the mouse.

Splenic T cells from animals bearing growing syngeneic tumors specifically inhibited the effector process of tumor cell lysis by the cytotoxic T cell which had been activated in vitro by mitomycin C treated homologous tumor. The suppression was strictly specific for the individual tumor by which suppressor cells were generated, whereas in some cases cytotoxic T cells generated by two closely related sarcomas showed a certain degree of crossreactivity. This suggests that suppressor and cytotoxic T cells recognize different antigenic moieties on tumor cells; one unique to the individual tumor and the other shared by related tumor cell lines.The suppressor T cell from tumor bearing animals possessed Ia antigen controlled by a gene in I-J subregion of H-2 major histocompatibility complex. Cytotoxic T cells generated by some but not all syngeneic tumors were also killed by anti-Ia and complement; however, the Ia antigen on such cytotoxic T cells was found to be controlled by a locus in I-A subregion. In general, the cytotoxic T cells generated by newly established tumor cell lines had Ia antigen, whereas some old cell lines, which were capable of growing across the H-2 barrier, activated the Ia negative cytotoxic T cell. These results collectively indicate that the immunological resistance against tumors is dependent on the balance of activations of the cytotoxic and suppressor T cells with different specificities and phenotypic expressions.     

The differentiation of T lymphocytes. Density characterisation of thymic and peripheral T cells responding in syngeneic and allogenic mixed lymphocyte reactions.

Equilibrium density separation on continuous albumin gradients was used to separate and characterise the T cells responding by proliferation to both syngeneic and allogeneic stimulating cells in the one-way mixed leucocyte reactions (MLR). In CBA mouse spleen both light and dense T cells were capable of responding in an allogeneic MLR. No T cells responding to stimulation be syngeneic B lymphocytes could be isolated from adult or 7-day CBA mouse spleen. In adult CBA mouse thymus, cells responding to allogeneic stimuli were enriched in the light density region, along with the low theta subpopulation. Self-reactive cells, responding with proliferation when cultured with syngeneic adult CBA splenic lymphocytes, and found in adult and 4-day CBA mouse thymus, were also enriched in the light density zones. However, in adult thymus syngeneic MLR reactivity was also found in the dense zones, and the density distribution profiles of total syngeneic MLR responding cells revealed a series of peaks extending over the whole density range. It was suggested that these syngeneic MLR responders undergo a complete maturation process, including progressive density increases, within the thymus gland. Such a sterile differentiation pathway could be a censorship process, leading to death of self-reactive cells within the thymus.     

Antibody blockade of lysis by T lymphocyte effectors generated against syngeneic SV40 transformed cells.

Antibody blockade of cell-mediated lysis was used to probe the cell surface structures recognized by T lymphocytes generated to syngeneic SV40 virus-transformed mouse cells. Alloantisera to H-2 antigens were highly effective in inhibiting lysis. Anti-H2 antibody blockade of lysis was haplotype specific even on transformed F1 target cells. Inhibition occurred only when antibody was bound to the target cell. Antibody binding to the effector did not inhibit lysis. Inhibition required that antibody be bound to the H-2 molecule itself; antibody to molecules associated with H-2, such as beta2-microglobulin, had no effect. Attempts to block lysis by using antisera to known virus-coded molecules were uniformly unsuccessful. These results are discussed in light of current controversy concerning the nature of the SV40 virus-specific transplantation antigen.     

Requirements for T lymphocyte migration in explanted lymph nodes

Although the requirements for T lymphocyte homing to lymph nodes (LNs) are well studied, much less is known about the requirements for T lymphocyte locomotion within LNs. Imaging of murine T lymphocyte migration in explanted LNs using two-photon laser-scanning fluorescence microscopy provides an opportunity to systematically study these requirements. We have developed a closed system for imaging an intact LN with controlled temperature, oxygenation, and perfusion rate. Naive T lymphocyte locomotion in the deep paracortex of the LN required a perfusion rate of >13 microm/s and a partial pressure of O(2) (pO(2)) of >7.4%. Naive T lymphocyte locomotion in the subcapsular region was 38% slower and had higher turning angles and arrest coefficients than naive T lymphocytes in the deep paracortex. T lymphocyte activation decreased the requirement for pO(2), but also decreased the speed of locomotion in the deep paracortex. Although CCR7(-/-) naive T cells displayed a small reduction in locomotion, systemic treatment with pertussis toxin reduced naive T lymphocyte speed by 59%, indicating a contribution of Galpha(i)-mediated signaling, but involvement of other G protein-coupled receptors besides CCR7. Receptor knockouts or pharmacological inhibition in the adenosine, PG/lipoxygenase, lysophosphatidylcholine, and sphingosine-1-phosphate pathways did not individually alter naive T cell migration. These data implicate pO(2), tissue architecture, and G-protein coupled receptor signaling in regulation of naive T lymphocyte migration in explanted LNs.     

Kinetic study of antitumor lymphocyte cytotoxicity in rats bearing progressive or regressive syngeneic colonic tumors

In order to perform a kinetic study of the antitumor lymphocyte-mediated cytotoxicity in syngeneic BDIX rats bearing progressive (TRb) or regressive (TSb) colonic tumors, the 51Cr release assay was adapted to this experimental model. Two groups of 72 rats were inoculated with TRb or TSb cells. Results failed to show any clear and univocal evolution of lymphocyte cytotoxicities against TRb or TSb cells. On the other hand these cytotoxicities were roughly at the same level than natural cytotoxicity (normal rats), and were always higher against TSb than TRb cells.     

A role for CCR9 in T lymphocyte development and migration

CCR9 mediates chemotaxis in response to CCL25/thymus-expressed chemokine and is selectively expressed on T cells in the thymus and small intestine. To investigate the role of CCR9 in T cell development, the CCR9 gene was disrupted by homologous recombination. B cell development, thymic alphabeta-T cell development, and thymocyte selection appeared unimpaired in adult CCR9-deficient (CCR9(-/-)) mice. However, competitive transplantation experiments revealed that bone marrow from CCR9(-/-) mice was less efficient at repopulating the thymus of lethally irradiated Rag-1(-/-) mice than bone marrow from littermate CCR9(+/+) mice. CCR9(-/-) mice had increased numbers of peripheral gammadelta-T cells but reduced numbers of gammadeltaTCR(+) and CD8alphabeta(+)alphabetaTCR(+) intraepithelial lymphocytes in the small intestine. Thus, CCR9 plays an important, although not indispensable, role in regulating the development and/or migration of both alphabeta(-) and gammadelta(-) T lymphocytes.