Defining cytolytic T lymphocyte recognition of chemically modified self. I. Response to trinitrophenyl-H-2Kk

We used purified class I antigen incorporated into liposomes to examine the response of secondary cytolytic T lymphocytes (CTL) to chemically modified self. By generating the secondary response in the presence of T cell helper factor, the level of CTL response was limited by CTL recognition of added antigen rather than by helper cell generation of lymphokines. We found a strong secondary response against chemically modified self when spleen cells from trinitrophenyl (TNP)-primed C3H/HeJ mice were stimulated with a) TNP-modified liposomes containing H-2Kk, b) liposomes containing H-2Kk purified from TNP-modified RDM-4 (H-2k) cells, or c) liposomes containing the limited trypsin proteolysis product of H-2Kk that had been directly modified with TNP. In contrast, we were not able to generate a significant CTL response with unmodified H-2Kk incorporated into vesicles along with TNP-modified membrane components lacking H-2Kk. These results suggest that TNP-modified H-2Kk is a major antigenic site recognized by CTL from C3H/HeJ mice after priming against TNP-modified self.     

Entry into S phase is inhibited in two immortal cell lines fused to senescent human diploid cells.

Senescent human diploid cells (HDC) were fused to T98G human glioblastoma cells and to RK13 rabbit kidney cells, and DNA synthesis was analyzed in the heterodikaryons. T98G and RK13 cells are “partially transformed” cell lines that have some characteristics of normal cells, yet are transformed to immortality, i.e., they do not senesce. Previous experiments have shown that “fully transformed” HeLa and SV80 cells induce DNA synthesis in senescent HDC nuclei, whereas normal young HDC do not. Our experiments show that T98G and RK13 cells do not induce DNA synthesis in senescent HDC nuclei. These results demonstrate that the ability to induce DNA synthesis in senescent HDC is not correlated with immortality per se. Our results show further that a T98G cell in S phase at the time of fusion to a senescent HDC will continue to make DNA. However, a T98G cell in G1 phase at the time of fusion is prevented from initiating DNA synthesis. RK13 cells behave similarly to T98G. These results are consistent with the hypothesis that the molecular basis for the senescent phenotype involves a block that prevents cells in G1 phase from entering S phase. Thus, we conclude that the senescent phenotype can be dominant in heterokaryons composed of senescent HDC fused with certain immortal cell lines. To explain the different results obtained with various immortal cell lines, we present a model that suggests that T98G and RK13 cells are immortal because they have lost a normal regulatory factor, whereas HeLa and SV80 are immortal because they have gained a dominant transformation factor.     

H2Kk can influence whether cytotoxic T lymphocytes recognize trinitrophenyl in association with H2Dk unique or H-2Kk and H-2Dk shared self determinants

The present study investigates the effect of trinitrophenyl- (TNP) modified H-2Kk (TNP-Kk) antigens on the generation of anti-TNP-Dk restricted cytotoxic T lymphocyte (CTL) responses. C3H.OH mice were primed to TNP-self by skin-painting with trinitrochlorobenzene, and spleen cells from these primed mice were subsequently stimulated in vitro with TNP-self. The effector cells generated exhibited appreciable lysis of TNP-modified C3H.OH blast target cells. Cold target inhibition studies demonstrated the generation of two effector cell populations: one that recognizes TNP in association with unique Dk self determinants, and one that recognizes TNP in association with self determinants shared between TNP-Kk and TNP-Dk. This was in contrast to primed C3H/He spleen cells, which did not generate CTL that recognized TNP in association with unique Dk self determinants. When spleen cells from (C3H/He x C3H.OH)F1 mice primed to TNP were stimulated in vitro with TNP-C3H.OH cells, unique Dk self determinants were recognized in association with TNP. However, in vitro stimulation of the same F1 responding cells with TNP-C3H/He or TNP-F1 cells failed to elicit CTL that utilized these Dk-unique self determinants. The findings of this study demonstrate that unique or shared H-2Dk determinants can be differentially utilized by CTL populations, depending on the H-2 alleles expressed by the stimulator cells.     

Association of TNP2 Gene Polymorphisms of the bta-miR-154 Target Site with the Semen Quality Traits of Chinese Holstein Bulls

Transition protein 2 (TNP2) participates in removing nucleohistones and the initial condensation of spermatid nucleus during spermiogenesis. This study investigated the relationship between the variants of the bovine TNP2 gene and the semen quality traits of Chinese Holstein bulls. We detected three single nucleotide polymorphisms (SNPs) of the TNP2 gene in 392 Chinese Holstein bulls, namely, g.269 G>A (exon 1), g.480 C>T (intron 1), and g.1536 C>T (3′-UTR). Association analysis showed that the semen quality traits of the Chinese Holstein bulls was significantly affected by the three SNPs. The bulls with the haplotypic combinations H6H4, H6H6, and H6H8 had higher initial semen motility than those with the H7H8 and H8H4 haplotypic combinations (P<0.05). SNPs in the microRNA (miRNA) binding region of the TNP2 gene 3′-UTR may have contributed to the phenotypic differences. The phenotypic differences are caused by the altered expression of the miRNAs and their targets. Bioinformatics analysis predicted that the g.1536 C>T site in the TNP2 3′-UTR is located in the bta-miR-154 binding region. The quantitative real-time polymerase chain reaction results showed that the TNP2 mRNA relative expression in bulls with the CT and CC genotypes was significantly higher than those with the TT genotype (P<0.05) in the g.1536 C>T site. The luciferase assay also indicated that bta-miR-154 directly targets TNP2 in a murine Leydig cell tumor cell line. The SNP g.1536 C>T in the TNP2 3′-UTR, which altered the binding of TNP2 with bta-miR-154, was found to be associated with the semen quality traits of Chinese Holstein bulls.     

CELL SIZE DIFFERENTIATION IN THE BLOOM-FORMING DINOFLAGELLATE GYMNODINIUM CF. NAGASAKIENSE1

Two subpopulations differing essentially by their mean cell size were observed regularly in cultures and natural samples of the naked dinoflagellate Gymnodinium cf. nagasakiense Takayama et Adachi (currently known as Gyrodinium aureolum Hulburt), a species which frequently forms red tides in North European seas. “Large” cells represented the typical forms; they were morphologically similar to cells of the closely related Japanese species G. nagasakiense, which did not form any subpopulation of reduced size. “Small” and “large” cells of G. cf. nagasakiense had the same DNA content, but the nucleus of the former appeared to be much more condensed during interphase. Each cell type was able to divide and had its own growth dynamics; therefore, any intermediary between pure populations of “small” and of “large” cells were observed in culture. The “large” form generated a “small” cell by an atypical budding-like division, whereas the “small” form gave back a “large” form, once it ceased to divide, by simple enlargement of its cell body. Factory inducing cell size differentiation are yet unclear. Neither nitrogen nor phosphorus starvation induced a significant increase in the relative proportion of “small” and budding cells. Although cell size differentiation is associated with the formation of gametes in a variety of dinoflagellates, we demonstrated that “small” cells of G. cf. nagasakiense are able to divide asexually, in contrast to gametes of most other species. The high proliferative power of “small” cells as compared with normal cells suggests that they could play a significant role during red tides of G. cf. nagasakiense; in contrast, cells of the Japanese species G. Nagasakiense could sustain high growth rates with larger cell size because this species generally blooms in waters much warmer than those found in northern Europe.     

Purification and characterization of TNP-specific immunoregulatory molecules produced by T cells sensitized by picrylchloride (PC1F)

T cell-derived TNP-specific factors associated with immunoregulatory activity were obtained by culture of T cells obtained from mice sensitized by skin-painting with picrylchloride. Culture medium was absorbed to TNP-Sepharose and TNP binding proteins were prepared by elution with TNP. The hapten affinity-purified proteins were characterized by size and charge and were found to be acidic 70,000 m.w. polypeptides that occur as monomers or oligomers. Oligomeric proteins interact with factors produced by mice injected with trinitrobenzenesulfonic acid to form factors that suppress specifically the ability of TNP-sensitized T cells to transfer contact sensitivity to TNP. Monomeric (no more than 70,000 m.w.) molecules do not form suppressor factors but can transfer contact sensitivity to TNP. Moreover, reduction and alkylation of oligomeric molecules inactivates their suppressor activity but causes them to be able to transfer contact sensitivity. The results suggest that T cell-derived antigen-specific molecules may have different effector functions dependent on their oligomeric state.     

Establishment of a tumor-specific immunotherapy model utilizing TNP-reactive helper T cell activity and its application to the autochthonous tumor system

Preinduction of potent hapten-reactive helper T cell activity and subsequent immunization with hapten-coupled syngeneic tumor cells result in enhanced induction of tumor-specific immunity through T-T cell collaboration between anti-hapten helper T cells and tumor-specific effector T cells. On the basis of this augmenting mechanism, a tumor-specific immunotherapy protocol was established in which a growing tumor regresses by utilizing a potent trinitrophenyl (TNP)-helper T cell activity. C3H/He mice were allowed to generate the amplified (more potent) TNP-helper T cell activity by skin painting with trinitrochlorobenzene (TNCB) after pretreatment with cyclophosphamide. Five weeks later, the mice were inoculated intradermally with syngeneic transplantable X5563 tumor cells. When TNCB was injected into X5563 tumor mass, an appreciable number of growing tumors, in the only group of C3H/He mice in which the amplified TNP-helper T cell activity had been generated were observed to regress (regressor mice). These regressor mice were shown to have acquired tumor-specific T cell-mediated immunity. Such immunity was more potent than that acquired in mice whose tumor was simply removed by surgical resection. These results indicate that in situ TNP haptenation of the tumor cells in TNP-primed mice can induce the enhanced tumor-specific immunity leading to the regression of a growing tumor. Most importantly, the present study further investigates the applicability of this TNP immunotherapy protocol to an autochthonous tumor system. The results demonstrate that an appreciable percent of growing methylcholanthrene-induced autochthonous tumors regressed by the above TNP immunotherapy protocol. Thus, the present model provides an effective maneuver for tumor-specific immunotherapy in syngeneic transplantable as well as autochthonous tumor systems.     

Influence of sex hormones on Coxsackie B-3 virus infection in Balb/c mice

Background and “spontaneous” proliferation are terms often used for the proliferative activity normally exhibited by peripheral blood mononuclear cells (MNC) in vitro. In this report, we show that Interleukin-2 (IL-2) added to unfractionated MNC but not to isolated T or non-T cells significantly increased their proliferative activity. The cells responding to IL-2 stimulation from MNC were OKT3 positive lymphocytes. In addition, treatment of MNC with either a monoclonal anti-HLA-DR antibody (in the absence of C′) or Cyclosporin-A strongly suppressed the “background” whereas treatment of MNC with the 3A1 monoclonal anti-human T cell antibody did not modify “spontaneous” proliferation of these cells. IL-2 could not restore or increase the proliferative activity of MNC exposed to the anti-HLA-DR antibody or Cyclosporin-A while the T cell growth factor significantly enhanced proliferation of MNC cultured in the presence of the OKT4 antibody. Taken together these results strongly suggest that IL-2 responding T cells from MNC become sensitive to IL-2 by interacting with HLA-DR antigens on B lymphocytes and/or monocytes contained in MNC (resting T cells are Dr^?). By a similar mechanism we have previously shown that T cells acquire responsiveness to IL-2 in the autologous mixed lymphocyte reaction (AMLR). Since all the cells that participate in AMLR are present in MNC, we postulate that a “mini” AMLR taking place within MNC may explain the “spontaneous” proliferation of peripheral blood mononuclear cells.     

IL 2 restores memory B cell activation by antigen-specific T cell clone variants

It has recently been demonstrated that there are at least two separate pathways by which a single keyhole limpet hemocyanin (KLH) reactive T cell clone can induce B cell differentiation. With the use of the high-dose antigen-driven system (10 micrograms/ml trinitrophenyl (TNP)-KLH), a KLH-specific T cell clone was able to induce a primary anti-TNP response in unprimed B cells. In the presence of aliquots of the same T cell clone, a low-dose of antigen (5 X 10(-2) micrograms/ml TNP-KLH) induced an immunoglobulin (Ig)G response in primed B cells. It has also been demonstrated that there are variant subclones of such KLH-specific helper T cell clones that are unable to provide antigen-specific help in the presence of low-dose antigen but maintain the high-dose antigen-driven helper response. This study was undertaken to investigate whether interleukin 2 (IL 2) had some activity in the low-dose, antigen-driven response induced by the T cell clone. With the use of a variant T cell clone (which lost low-dose, antigen-driven helper activity), it was demonstrated that IL 2 was capable of reconstituting the low-dose, antigen-driven helper activity. To investigate whether accessory cells were required in this system, we removed the adherent cell population from the primed spleen cells added to culture. Interestingly, removal of the G10-adherent cells eliminated the low-dose, antigen-driven response induced by IL 2. Additionally by add-back experiments, we were able to demonstrate that the necessary adherent cell population did not require major histocompatibility complex (MHC) restriction for reconstitution of the IL 2-dependent, low-dose, antigen-driven response. Furthermore, 1% concanavalin A (Con A) supernatant (Sn), but not interleukin 1 (IL 1), could replace this adherent cell function. These data suggest that in this system, IL 2 bypasses the MHC-restricted interaction between T cells and antigen-charged adherent cells; B cells can present antigen to cloned helper T cells efficiently for primary responses but need an added factor(s) to induce IgG production; and adherent cells are essential for IgG production in primed B cells, possibly through the release of soluble factor(s) included in Con A Sn.     

Membrane defects in the tolerant B cell. II. Mechanism of capping failure and reversal by antigen exposure.

The demonstration that TNP-binding B lymphocytes from animals whose B cells have been rendered tolerant to TNP by trinitrobenzene sulfonic acid cannot undergo antigen-induced capping of their TNP receptors for at least a year despite recovery of immune responsiveness has led to a search for the mechanism of the capping failure. Microtubule-dependent membrane “locking” analogous to that induced by concanavalin A appears to afflict the tolerant B cells, in that capping TNP receptors is restored after exposure to 10^?4M colchicine or overnight incubation at 4 °C. Assignment of the defect to the cytoskeleton rather than the receptors themselves is also supported by the observations that enzymatic stripping and regrowth of receptors does not unlock the cell and that non-Ig membrane molecules recognized by antilymphocyte serum also cannot be capped on the tolerant cells. Cells which have remained locked for 4 days to 8 months after a single tolerogen exposure become unlocked 4 days after immunogen is given. Four days after immunogen, tolerogen fails to lock the membranes of TNP-binding cells. These results suggest that tolerogen contact interferes in a much broader range of functions in the TNP-binding cell than those which affect the immune response. Among these effects is a remarkably stable “locked” configuration of the cytoskeleton which is independent of immune responsiveness or receptor turnover, but which can be reversed by exposure to immunogen whether or not an immune response ensues.     

Helper cells in the autologous mixed lymphocyte reaction. I. Generation of cytotoxic T cells recognizing modified self H-2

The autologous mixed lymphocyte reaction (AMLR) in mice measures the proliferative response of T cells to determinants on syngeneic non-T spleen cells. Normally, cytotoxic T lymphocytes (CTL) are not generated in this reaction. However, the addition of trinitrophenyl-modified mitomycin C-treated syngeneic T cells (TNP-Tm) to the AMLR results in the generation of TNP-specific CTL but does not alter the proliferative response. Significant cytotoxic activity is not detectable against TNP in association with Ia unless TNP is present on cells bearing those determinants. Thus, if unselected spleen cells are TNP-modified and used as stimulators in the AMLR, the proliferative response is enhanced and CTL are generated that recognize TNP in association with K, D, and I region-encoded determinants. The CTL generated in the AMLR are H-2 restricted and dependent on the presence of adherent cells in the sensitization cultures. The experiments presented here suggest that the AMLR can provide the help necessary for generating cytotoxic T cells in vitro.     

Dysfunction of thymocytes of C3H/HeJ mice in blastogenic response to anti-thymocyte serum in vitro and its repair with lipopolysaccharide induced mediator.

In vitro mitogenic responses of thymocytes to rabbit anti-mouse thymocyte serum (ATS) have been compared in several mouse strains. The response of thymocytes of C3H/HeJ mice is about one-third of those of thymocytes of C3H/He, ATL or ATH strains. Phenol-extracted bacterial lipopolysaccharide (LPS) does not induce mitogenic response in cultured C3H/HeJ spleen cells, but the spleen cells of all other strains used are capable of responding to LPS. The low response of C3H/HeJ thymocytes to ATS is restored by adding “endotoxin soup” prepared from spleen cell cultures of LPS-responder mice in the presence of LPS. Neither soup prepared from C3H/HeJ spleen cell cultures without the addition of LPS nor soup prepared from cell cultures with LPS show such restoration of the response of C3H/HeJ thymocytes to ATS. The molecular size of the active factor in “endotoxin soup” was estimated on a Sepharose CL-4B column and determined to be about 20,000 daltons. The activity of “endotoxin soup” is destroyed by heating at 70 C for 30 min or 80 C for 10 min and diminished by digestion with trypsin. The mechanisms of restoration of low response of C3H/HeJ thymocytes to ATS by “endotoxin soup” are discussed.     

RADIOSENSITIVITY,RNA, AND PROTEIN METABOLISM OF “LEAKY” AND ARRESTED CELLS IN SUNFLOWER ROOT MERISTEMS (HELIANTHUS ANNUUS)

Two cell populations in sunflower root meristems are described. Most cells stop in G1 after being cultured in sucrose-deficient medium, but “leaky” cells continue through DNA synthesis and stop in G2. A comparison of “leaky” and arrested cells is reported on the basis of radiosensitivity, and cytological and biochemical responses to metabolic inhibitors. “Leaky” cells are randomly distributed throughout primary meristematic tissues. They are not inhibited from initiating DNA synthesis by exposure to doses of γ-irradiation ranging from 300–7200 R; arrested cells, depending upon the dose, are inhibited partially or completely. “Leaky” cells do, however, show a dose-dependent mitotic delay in G2, which is the same as arrested cells. Treatment with puromycin and actidione does not inhibit “leaky” cells from initiating DNA synthesis but does inhibit them from mitosis. Arrested cells are inhibited from advancing to S and M by both inhibitors. Also, puromycin and actidione cause a decrease in protein and RNA synthesis, demonstrating a possible protein dependent RNA synthesis necessary for cell cycle progression. Actinomycin D (10 μg/ml) inhibits neither “leaky” nor arrested cells from entering S and M. At 30 μg/ml, however, arrested cells are partially inhibited. “Leaky” cell metabolism is unique in preparation for and initiation of DNA synthesis but similar to that of the remaining cells of the meristem in terms of requirements for progression through the rest of the mitotic cycle.     

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.     

Characterization of oligosaccharides of highly purified glycoprotein gC of herpes simplex virus type 1 (HSV-1)

The envelope membrane glycoprotein gC of HSV-1 was purified from Triton X-100 extracts of virus-infected BHK-21 or HEp-2 cells by a single step immuno-affinity column using monoclonal anti-gC antibody. The analysis of the purified [³H]G1cN labeled glycoprotein gC (by gel filtration on Bio-Gel P4) before and after digestion with endo-β-N-acetylglucosaminidase (endo D) indicated that gC contains Asn-linked “complex type” oligosaccharides. No “high mannose” type oligosaccharides were detected. Fractionation of radio-labeled glycopeptides of gC on a column of concanavalin A-sepharose suggested that glycopeptides have “diantennary” and “triantennary” and/or “tetra antennary” structures. Tunicamycin inhibited the incorporation of [¹⁴C]GalN or [³H]GlcN into gC in HSV-1 infected BHK-21 or HEp-2 cells. Gel filtration analysis of [³H]GlcN labeled gC following β-elimination reaction failed to indicate O-glycosidically linked oligosaccharides.     

Chromosomes of the caryophyllidean tapeworm Glaridacris laruei

The chromosomes of the monozoic tapeworm Glaridacris laruei, from 4 locations in New York State, were studied in leucobasic fuchsin stained squashes of testes and vitelline cells. The diploid chromosome number is 16. Metaphase figures from vitelline cells consist of 3 pairs of metacentrics (“V's”), 4 pairs of acrocentrics (“rods”), and 1 pair of submetacentrics (“J's”). The complement is characterized by a pair of metacentrics 9 μm long, representing 11.5% of the total chromosome length. The shortest are acrocentrics, 2–4 μm long. Meiosis was observed only in spermatogenesis, which proceeds as usual with normal sperm formed after 2 meiotic divisions. Colchicine pretreatment did not facilitate analysis of chromosomes. The scarcity of cell division in 2 populations of G. laruei suggests a possible mitotic rhythm or temperature effect on cell division. Similarities were observed between the the complements of G. laruei and Hunterella nodulosa (2n = 14). A theoretical idiogram, constructed from that of G. laruei, closely resembles H. nodulosa, indicating that there may be a close cytological relationship between these phenotypically different caryophyllids. An idiogram and photographs of chromosomes supplement the paper.     

Antigen-specific T-cell factor in cell cooperation and genetic control of the immune response.

Cell interactions between thymus-derived (T) and bone marrow-derived (B) lymphocytes in the antibody response appear to involve soluble T-cell mediators known as 'factors.' This paper describes the properties of a T-cell factor that has specificity for the inducing antigen, a synthetic polypeptide (T, G)-A--L, and is able to replace T cells in the thymus-dependent antibody response to (T, G)-A--L. Besides antigen specificity, the main features of the molecule are that it is nonimmunoglobulin; it has a molecular weight of about 50,000; and it is a product of the I-A subregion of the H-2 complex (the mouse major histocompatibility complex). These properties suggest that the factor is closely related to the T-cell receptor, which may, by inference, also be a product of the H-2 complex. The factor cooperates well with allogeneic B cells. It can also be absorbed by bone marrow cells and B cells. Studies on the genetic control of the immune response to (T, G)-A--L using the T-cell factor indicate that two immune response genes in the H-2 complex are involved in genetic control, one expressed in T cells and the other in B cells. This two gene hypothesis has been confirmed by showing that an F1 between two low responders to (T, G)-A--L can be a high responder.     

Suppressor T cells induced by soluble immune complexes can adoptively transfer inhibition of cytophilic antibody receptors on macrophages.

Immune complexes (soluble antigens of L1210 and antibody to L1210) when given to allogeneic C3H mice generated suppressor cells that inhibited receptors for cytophilic antibody on macrophages. Thymocytes or nylon-nonadherent splenic T cells (4 × 10⁷) from immune-complex-treated mice transferred this suppressive activity when injected into normal syngeneic mice. Maximal suppression of macrophages occurred 4 to 6 days after transfer. In contrast, even 5 × 10⁷ nylon-adherent, non-T spleen cells from immune-complex-treated (“suppressed”) mice failed to induce macrophage suppression in the syngeneic recipients. When T-cell-depleted “B” mice were used as recipients, neither thymocytes nor splenic T cells from suppressed mice were able to transfer suppressive activity. However, the admixture of 2 × 10⁷ normal syngeneic thymocytes with 4 × 10⁷ thymocytes from suppressed mice restored the latter's ability to elicit suppression of macrophages in T-cell-deprived recipients. Peritoneal monocytes from recipients of suppressor thymocytes (to L1210) could not attach cytophilic antibody to L1210 but could attach cytophilic antibody to EL-4 and sheep erythrocytes. Thus, suppressor T cells induced by immune complexes can transfer immunologically specific macrophage suppression (inhibition of cytophilic antibody receptors) to syngeneic recipients. The suppressor cells required the cooperation of normal T cells, suggesting either recruitment of suppressor cells from, or a helper effect by, the normal T cells, in order to produce their effect.     

trans activation of nerve growth factor in transgenic mice containing the human T-cell lymphotropic virus type I tax gene.

Three lines of transgenic mice containing the human T-cell lymphotropic virus type I (HTLV-I) tax gene develop neurofibromas composed of perineural fibroblasts (S. H. Hinrichs, M. Nerenberg, R. K. Reynolds, G. Khoury, and G. Jay, Science 237:1340-1343, 1987; M. Nerenberg, S. H. Hinrichs, R. K. Reynolds, G. Khoury, and G. Jay, Science 237:1324-1327, 1987). Tumors and tumor cell lines derived from these mice produce neurite outgrowth from PC-12 cells and nerve growth factor (NGF), as determined by RNA (Northern) blot analysis and enzyme-linked immunosorbent assays. In vitro cotransfection studies demonstrate that Tax is able to trans activate the NGF promoter in NIH 3T3 fibroblast cells. The major cis-acting tax-responsive element in the NGF promoter (AGGGTGTGACGA) has 92% homology with a tax-responsive element contained within the 21-bp repeats of the HTLV-I long terminal repeat. The receptor for NGF is also expressed in the transgenic tumor cells, suggesting that Tax may activate an autocrine mechanism through the upregulation of NGF.     

Tolerance to Mls-disparate cells induces suppressor T cells that act at the helper level to prevent in vivo generation of cytolytic lymphocytes to hapten-altered self

We have been examining the mechanisms that control in vivo development and down regulation of cytolytic T lymphocytes (CTL) to trinitrophenyl (TNP)-altered self antigens. In vivo generation of hapten-specific CTL requires an auxiliary antigenic stimulus, which can be provided by H-2 compatible but Mls-disparate cells. These experiments were designed to study the effect of tolerization with such Mls-disparate cells on CTL development. C3H/HeN (H-2k, Mlsc ) mice sensitized in the footpads with C3H-TNP spleen cells plus CBA/J (H-2k, Mlsd ) spleen cells develop CTL in the draining lymph nodes that will lyse 51Cr-labeled TNP-modified C3H targets. However, we have found that if C3H/HeN mice are given tolerizing doses of CBA/J spleen cells 5 to 7 days before sensitization, a splenic suppressor T cell (Ts) appears. This Ts will suppress CTL development in its tolerant host, and can be transferred adoptively to function in naive mice. Ts and its precursor are cyclophosphamide insensitive and therefore different from the naturally existing suppressor cell present in mice. When triggered by cells with Mlsd , the Ts produces a factor (TsF) that hinders helper factors from functioning in an in vitro CTL assay. Furthermore, TsF acts to prevent utilization of IL 2 by an IL 2-dependent cell line. Thus, evidence has been provided that the in vivo generation of CTL toward hapten-altered self can be down regulated at the level of helper signals by a Ts. The latter is inducible by the Mls-disparate cells that are needed at a different site to trigger the helper factors in this CTL system.