Establishment of an antigen-specific B cell clone by somatic hybridization

Splenic B cells of A/J mice immunized with 2,4,6-trinitrophenyl (TNP)-lipopolysaccharide were fused with 2.52M, a mutant of a B cell line, in the presence of polyethylene glycol and dimethyl sulfoxide. TP67.21, a subclone of a resulting hybridoma, expresses IAk, IEk, IgM, B220, P50, and receptors for C3 fragment of complement, the Fc portion of IgG, and interleukin 2 receptor on the cell membrane; it also possesses receptor molecules for TNP on its surface, derived from TNP-reactive B cells of A/J mice primed with TNP-lipopolysaccharide used for somatic hybridization, by a rosette-forming assay with TNP-sheep erythrocytes. In contrast, parental 2.52M lacks IAk and IEk on the cell membrane and does not bind to TNP-sheep erythrocytes under the same conditions. Thus, it is likely that TP67.21 is an antigen-specific B cell clone directed against TNP. The antigen binding of cells was markedly inhibited by the specific free hapten or anti-IgM antibodies. Interestingly, TP67.21 was induced to generate a significant amount of anti-TNP antibody when treated with TNP conjugates including T cell-independent and -dependent antigens, such as TNP-lipopolysaccharide, TNP-bovine serum albumin, TNP-ovalbumin, and TNP-keyhole limpet hemocyanine in the absence of T cell help, as well as polyclonal activators; this was followed by a marked decrease in the expression of B cell surface markers on the cell membrane. This suggests that the cross-linkage of receptor molecules on TP67.21 by antigen may directly provide a differentiative signal for maturation to a lineage of B cells, and consequently results in the generation of antigen-specific antibodies without T cell involvement.     

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.     

Production of interleukin 3 and gamma-interferon by an antigen-specific mouse suppressor T cell clone

An interleukin 2 (IL 2)-dependent, keyhole limpet hemocyanin (KLH)-specific, mouse suppressor T cell clone, 3D10, was found to produce interleukin 3 (IL 3) and gamma-interferon (IFN-gamma) in response to T cell mitogens Con A and PHA. Different from KLH-specific suppressor factor (TsF) that was spontaneously released into the medium when cultured in IL 2-containing conditioned medium, the production of IL 3 and IFN-gamma was induced by mitogenic stimuli. IL 3, IFN-gamma, and TsF were separable by gel filtration through a Sephadex G-100 column, being recovered in fractions of m.w. 25,000 to 30,000, 45,000 to 50,000 and 60,000 to 70,000, respectively. On the other hand, minimum size of IL 3 and IFN-gamma were shown to be about 25,000 and 20,000, respectively, by determining the lymphokine activities contained in the extracts from slices of SDS gels. These results indicate that IFN-gamma was present as a homodimer or hetero-complex with another carrier protein(s), whereas IL 3 was present as a monomeric form. A highly positive correlation (a correlation coefficient r = 0.96) between the titers of IL 3 and IFN-gamma produced by seven subclones derived from 3D10 was obtained, suggesting that IL 3 and IFN-gamma are induced by a process with a common mechanism. 3D10 also produced IL 3 and IFN-gamma when cultured with its specific antigen, KLH, in the presence of antigen-presenting cells. When Con A-stimulated 3D10 cells were labeled with L-[35S]methionine, we found that at least three proteins, with m.w. of 35,000, 25,000, and 20,000, were specifically released into medium by the stimulation. The latter two may be IL 3 and IFN-gamma described above, respectively, because of the similarities in m.w.     

Activation and function of an autoreactive T cell clone with dual immunoregulatory activity

Previously it was demonstrated that the human autoreactive CD4+ T cell clone MTC-4 is bifunctional, having the capacity to augment differentiation of autologous B cells into Ig-secreting cells in the absence of PWM and the capacity to suppress such differentiation in the presence of PWM. In the present study it was shown that these two functions of MTC-4 are mediated by distinctly different mechanisms. In the presence of autologous class II MHC Ag, MTC-4 releases one or more non-MHC-restricted soluble factors which stimulate B cell differentiation. The helper factors are different from IL-2, and act on both resting (small) and activated (large) B cells. The suppressor function of MTC-4 cells is elicited when MTC-4 cells are co-cultured with autologous non-T cells preincubated with PWM for 4 h, but not with non-T cells preincubated with PWM for 24 h; thus, activated autologous non-T cells have a transient capacity to induce MTC-4 suppressor function. Induction of MTC-4 suppressor activity is not associated with increased proliferation of MTC-4 and is mediated by low numbers of these cells. Unlike helper function, MTC-4 suppression of Ig synthesis can occur late in B cell cultures, and MTC-4 suppresses Ig production by autologous B cells, but not by allogeneic B cells. Finally, in co-cultures with activated autologous non-T cells and allogeneic B cells, MTC-4 can simultaneously produce helper factors that augment Ig synthesis by allogeneic B cells and suppress Ig synthesis by autologous B cells. In summary, exposure of MTC-4 to autologous non-T cells causes release of non-MHC-restricted factors which augment Ig production by both resting and activated autologous B cells, whereas exposure of MTC-4 to recently activated B cells causes MTC-4 to express the additional function of directly suppressing Ig production by differentiated autologous B cells. Thus autoreactive T cells may be uniquely suited to regulate Ig production.     

Functional studies on the role of I-A molecules expressed by the antigen-specific T suppressor cell clone HF1

The antigen-specific T suppressor (Ts) cell clone HF1 (Thy-1.2+, I-Ak+, I-Ek+) was isolated from a CBA/J mouse tolerized to low doses of bovine serum albumin (BSA), and a subclone was adapted to grow in the absence of antigen-presenting cells. The functional role of the I-Ak molecules endogenously expressed by HF1 Ts cells was analyzed by using anti-I-Ak monoclonal antibodies (mAb) in attempts to block the antigen-induced proliferation of these cells. Among a panel of anti-I-Ak mAb tested, only the H118-49 mAb directed against the private determinant Ia.m1 blocked BSA-induced proliferation. The data presented here suggest a selective regulatory role of membrane-bound I-Ak molecules in the antigen-induced signal transmission.     

Direct involvement of surface IA/E molecules during B cell maturation using an antigen-specific B cell clone

TP67.14 is a subclone of a resulting B cell hybridoma established by somatic hybridization between splenic B cells of A/J mice immunized with TNP-LPS and 2.52 M, a HAT medium-sensitive mutant of a B cell line; it expresses IgM, B220, IAk, and IEk on the cell membrane and also possesses a receptor molecule for TNP on its surface derived from TNP-reactive B cells of A/J mice used for cell fusion. As shown previously, TP67.14 could be induced to generate a significant amount of anti-TNP antibodies when treated with TNP-conjugated protein such as TNP-BSA and TNP-keyhole limpet hemocyanin without T cell help as well as LPS. Our study was undertaken to investigate direct involvement of surface MHC class II molecules on B cells during B cell maturation by analysis with this Ag-specific B cell clone. The data demonstrate that mAb against IAk and IEk molecules, but not IAd and H-2k, markedly inhibited the differentiative effects of LPS on TP67.14. In contrast, both antibodies specifically augmented the secretion of anti-TNP antibodies by TP67.14 treated with TNP-BSA, although these antibodies alone failed to induce the generation of anti-TNP antibodies. Interestingly, TP67.14 significantly differentiated into anti-TNP antibody secreting cells when incubated with TNP-conjugated monoclonal anti-IAk or anti-IEk antibodies alone; this differentiative effect was much greater than that of TNP-conjugated anti-IAd mAb or purified mouse IgG under the same conditions. Our result suggests that surface IA/E molecules on B cells may be directly involved in a transductional signal for B cell maturation mediated by the cross-linkage of receptor molecules on B cells with Ag.     

T cell regulation of antibody responses: an I-A-specific, autoreactive T cell collaborates with antigen-specific helper T cells to promote IgG responses

In earlier studies we showed that hapten-specific inducer T cell clones specifically induce B cells from immunized donors to secrete IgM antibodies. However, IgG responses were not observed, suggesting that an additional signal(s) was required. In this report, we show that an autoreactive T cell clone produces a factor(s) that collaborates with antigen-specific inducer T cells to promote specific IgG responses. This factor is not restricted by antigen or MHC determinants and promotes IgG production both in vivo and in vitro. These findings suggest that autoreactive cells may play an important role in the regulation of isotype expression.     

Functional role of self IA molecules in polyclonal B cell activation using an autoreactive B cell clone derived from (NZB X NZW) F1 mice.

The mechanism of polyclonal B cell activation in autoimmune diseases was investigated by using an autoreactive B cell clone established by somatic hybridization with B cells derived from NZB X NZW (B/W) F1 mice. Briefly, splenic B cells from B/W F1 mice were fused with M12.4.1, a mutant of a B cell line, in the presence of polyethylene glycol and DMSO. NW47.7, a subclone of a resulting hybridoma, expresses B cell surface antigens on the cell membrane, namely IAd, IgM, B220, the receptors for the C3 fragment of complement (C3R), and the Fc portion of IgG (Fc gamma R). It also possesses a receptor molecule for mouse red blood cells treated with bromelain (Br-MRBC) on its surface, by rosette-forming assay with Br-MRBC. In contrast, parental M12.4.1 does not express IAd and IgM on the cell membrane, and does not bind to Br-MRBC under the same conditions. Thus, it is likely that NW47.7 may be an autoreactive B cell clone specific for Br-MRBC. Interestingly, NW47.7 was induced to generate a significant number of IgM-secreting cells when treated with Br-MRBC and rIL-5. Furthermore, mAb against IAd molecules, but not IAk and KdDd, markedly inhibited the differentiative effect of polyclonal activators such as LPS and rIL-5. Also, when MHC identical irradiated B cells were added to the culture of NW47.7 as a stimulator, the induction of IgM-producing cells was greatly augmented, but this augmenting effect was lost by interfering with direct contact of NW47.7 cells with stimulator B cells using a semipermeable membrane, as well as by the addition of mAb against IAd molecules. In addition, irradiated NW47.7, but not M12.4.1, by itself could enhance the secretion of IgM by NW47.7 as a stimulator, but this enhancing effect markedly decreased in the presence of anti-IAd mAb. The present results suggest that surface IA molecules on B cells are involved during the differentiative response to polyclonal activators, and may directly provide a differentiative signal for maturation of B cells into IgM-secreting cells.     

Immunoregulatory activities of autoreactive T cells: an I-A-specific T cell clone mediates both help and suppression of antibody responses

We have derived a Ly-1+, 2-3- T cell clone that is specific for autologous I-A on activated but not on resting cells. After activation, this clone produces factors that induce purified (B + adherent) cells to secrete antibody in response to sheep red blood cells and type 2 T-independent antigens. Regulation of plaque-forming cell responses by this clone is dose dependent: low numbers enhance the plaque-forming cell response, whereas high numbers suppress the response. The inhibition observed with high doses is associated with cytolysis of I-A+ cells, and this can be blocked by the addition of anti-I-A antibodies. The physiologic significance of this novel cell type in regulating immune responses is discussed.     

A human alloreactive inducer T cell clone that selectively activates antigen-specific suppressor T cells

We showed previously that T cells with the phenotype Leu-3+,8+ are required for the induction of antigen-specific Leu-2+ suppressor cells. Furthermore, when mixed lymphocyte reactions are carried out in the presence of 1 microgram/ml cyclosporin A (CsA), such cultures lead preferentially to the activation of alloantigen-specific suppressor-inducer Leu-3+,8+ cells. In an attempt to generate a clone of T cells with such specific suppressor-inducer properties, we activated Leu-3+,8+ T cells with allogeneic (HLA-DR4+) lymphocytes in the presence of CsA. Clone SP-21, derived by propagating such activated T cells with conditioned medium containing IL 2, is a noncytotoxic, nonsuppressor clone that specifically proliferates to allogeneic cells bearing HLA-DR4 antigen. When cultured with fresh autologous Leu-2+ cells in the absence of HLA-DR4+ cells, clone SP-21 selectively activates Leu-2+ suppressor cells, which inhibit the response of fresh Leu-3+ cells to DR4+ stimulator cells. On the other hand, clone SP-21 fails to induce cytolytic T cells or to help B cell differentiation. These results demonstrate that a T cell clone with a remarkably narrow functional repertoire nonetheless contains and transmits all of the signals necessary for the activation of antigen-specific suppressor cells.     

Differential inhibition of human antigen-specific T cell clone proliferative responses by distinct monoclonal anti-HLA-DR antibodies

The inhibition of diphtheria toxoid and varidase-specific T cell clones from a single DR 6/7 donor by eight distinct monoclonal anti-HLA-DR antibodies was tested in proliferative assays. These moAb were selected because they had been previously defined for their ability: 1) to react with Ia molecules; 2) to recognize similar or different epitopes; 3) to share or not share idiotypic specificities. Our results show a distinct inhibition pattern for each clone tested. Furthermore, the various moAb could be classified into three groups according to their inhibitory effect on T cell proliferation. These data suggest: a) an epitopic restriction by class II antigens of antigen-specific human T cell clone proliferation; and b) the recognition of functional epitopes on the human Ia-like antigens by some but not all moAb studied.     

Activation of B cells by autoreactive T cells: cloned autoreactive T cells activate B cells by two distinct pathways

Although the existence of autoreactive T cells has been widely reported, the functional capacities of these populations have been less well defined. Studies were therefore carried out to characterize the relationship of autoreactive T cells to antigen-specific major histocompatibility complex (MHC)-restricted T cells in their ability to act as helper cells for the induction of immunoglobulin synthesis by B cells. A number of autoreactive T cell lines and clones were isolated from antigen-primed spleen and lymph node cell populations. Autoreactive T cells were found to proliferate in response to direct recognition of syngeneic I-A or I-E subregion-encoded antigens in the absence of any apparent foreign antigen. It was shown that cloned autoreactive T cells were capable of activating B cell responses through two distinct pathways. After appropriate stimulation by syngeneic cells, autoreactive T cells polyclonally activated primed or unprimed B cells to synthesize IgM antibodies. These activated T cells functioned in these responses through an MHC-unrestricted pathway in which polyclonal responses were induced in both syngeneic and allogeneic B cells. These cloned autoreactive T cells were also able to activate IgG responses by primed B cells through a different activation pathway. In contrast to the polyclonal activation of IgM responses, the induction of IgG antibodies by the same cloned T cells required primed B cells and stimulation with the priming antigen. The activation of B cells to produce IgG was strongly MHC restricted and required the direct recognition by the autoreactive T cells of self MHC determinants expressed on the B cell surface, with no bystander activation of allogeneic B cells. These results indicate that cloned autoreactive T cells resemble antigen-specific MHC-restricted T cells in their ability to function as T helper cells through distinct MHC-restricted and MHC-unrestricted pathways.     

Tumor modulation of autoreactivity: decreased macrophage and autoreactive T cell interactions

The autologous mixed lymphocyte reaction (AMLR) is an in vitro measure of autoreactivity, a key mechanism in immune homeostasis. In this system, macrophages (M phi) act as accessory cells to autoreactive L3T4+ T cells by presenting self-Ia and releasing soluble modulators. During tumor growth, changes occur in M phi and T cells. Tumor-bearing host (TBH) M phi have a reduced ability to act as accessory cells. In fact, TBH M phi suppressed autoreactivity by 60-70%. The decrease in TBH M phi or T-cell abilities was not due to differences in cell numbers or incubation time. Because tumor growth causes increased prostaglandin E2 (PGE2) production by M phi, indomethacin was used to assess the contribution of prostaglandins. Normal and TBH T-cell reactivity increased nearly 50% when stimulated by normal host M phi, while normal and TBH T-cell reactivity increased nearly 100% when stimulated by TBH M phi. Thus increased prostaglandin production is partly responsible for the increased TBH suppressor M phi activity and in the normal host, suppressor M phi may be responsible for maintaining immune regulation. To assess the direct role of prostaglandins in T-cell hyporesponsiveness, PGE2 was titrated into the cultures. PGE2 suppressed normal and TBH T-cell responsiveness in a dose-dependent manner. Normal host T cells were suppressed to a greater extent than TBH T cells by PGE2 (66% versus 42% suppression, respectively). Reduced Ia expression and active suppressor mechanisms are not the only mechanisms mediating hypoautoreactivity during tumor growth. TBH autoreactive L3T4+ T cells were less responsive to self-Ia; they were only 60-80% as reactive as their normal counterparts. To address whether the helper T (TH)-cell defect involved cytokines, T cells were treated with interleukin (IL)-1, IL-2, and IL-4. In all cases, the TBH T-cell response to the factors was decreased (only 60-75% as reactive as normal T cells). Because TBH M phi-mediated suppression can override the addition of IL-1, IL-2, and IL-4, indomethacin was also added with the exogenous interleukins. This coaddition significantly enhanced normal host autoreactivity above control levels while TBH autoreactivity (the combination of TBH T cells and TBH M phi) only returned to normal host unstimulated levels. Tumor growth modulates the immune response at least by (i) decreasing the accessory cell abilities of TBH M phi through decreased Ia expression and increased production of suppressive molecules such as prostaglandins; and (ii) decreasing the responsiveness to immune enhancing factors by TH cells.     

Spontaneous autoreactive memory B cell formation driven by a high frequency of autoreactive CD4+ T cells

Although somatically mutated autoantibodies are characteristic of many autoimmune diseases, the processes that can lead to their development remain poorly understood. We have examined the formation of autoreactive memory B cells in PevHA mice, which express the influenza virus PR8 hemagglutinin (HA) as a transgenic membrane bound neo-self-Ag. Using a virus immunization strategy, we show that PR8 HA-specific memory B cell formation can occur in PevHA mice, even though a major subset of PR8 HA-specific B cells is negatively selected from the primary repertoire. Moreover, PR8 HA-specific memory B cells develop spontaneously in TS1 x PevHA mice, which coexpress a transgenic PR8 HA-specific TCR and contain a high frequency of HA-specific CD4(+) T cells. Notably, autoreactive memory B cell formation occurred in TS1 x PevHA mice even though approximately half of the HA-specific CD4(+) T cells were CD25(+)Foxp3(+) cells that could significantly attenuate, but did not completely abolish HA-specific autoantibody production in an adoptive transfer setting. The findings provide evidence that a high frequency of autoreactive CD4(+) T cells can be sufficient to promote autoreactive memory B cell formation in the absence of signals provided by overt immunization or infection and despite the presence of abundant autoantigen-specific CD4(+)CD25(+)Foxp3(+) regulatory T cells.     

An antigen-specific DTH-initiating cell clone. Functional, phenotypical, and partial molecular characterization

The elicitation of delayed-type hypersensitivity (DTH) reactions in mice is due to the sequential action of two different Ag-specific Thy-1+ cells. An early-acting DTH-initiating cell in the lymphoid organs produces a circulating, Ag-specific factor that is functionally analogous to IgE antibody and initiates DTH by sensitizing the local tissue for release of the vasoactive amine serotonin. In picryl chloride (PC1) or oxazolone (OX) contact sensitivity, this DTH-initiating factor is called PC1-F and OX-F respectively, and is Ag-specific, but MHC-unrestricted. The phenotype of polyclonal DTH-initiating cells was recently shown to be unusual for an Ag-specific cell. The phenotype was: Thy-1+, Lyt-1+ (CD5), triple negative (CD4-, CD8-, and CD3-), B220+ (Ly-5, CD45RA), positive for IL-3 receptors, but not IL-2 receptors, and positive for antibodies that react with a putative constant or framework portion of DTH-initiating factors such as anti-PC1-F antibodies and 14-30 mAb. We report here the generation of an Ag-specific DTH-initiating cell clone from nude mice that were immunized and boosted by contact sensitization with OX. By flow microfluorometry analysis, this clone has a similar unique surface phenotype, and by in vivo assay has the same functional abilities, as polyclonal DTH-initiating cells. The clone produces Ag-specific OX-F that acts in an Ag-specific manner to initiate DTH. Moreover, specific cDNA probes and Northern blot analysis of the clone demonstrated that the Ag-specific DTH-initiating cells are Thy-1+, CD3-, and IL-3R+. Thus, DTH initiation is due to an Ag-specific lymphoid cell, that produces an Ag-specific factor, and that has a unique surface phenotype for Ag-specific cells; namely, Thy-1+, CD5+, sIg-, CD4-, CD8-, CD3-, CD45RA+, IL-2R-, and IL-3R+.     

Intrahepatic, nucleocapsid antigen-specific T cells in chronic active hepatitis B

Hepatitis B core antigen (HBcAg)-specific T cell lines were established from hepatic lymphomononuclear cells derived from five patients with chronic active hepatitis B. No hepatitis B virus envelope antigen-specific cell lines were established. Proliferation in response to recombinant and native HBcAg, but not to native hepatitis B surface antigen containing the pre-S(2) region, confirmed the specificity of the five T cell lines. All cell lines represented mixed populations of CD4+ and CD8+ T cells. The CD4+ subset provided antigen-specific help to autologous B cells with respect to anti-HBc production and to CD8+ cells with regard to HBcAg-induced proliferation and suppressor activity. The CD8+ subset contained suppressor cells that selectively inhibited the proliferative response of autologous HBcAg-specific CD4+ cells without inhibiting CD4+ cells of unrelated specificity (tetanus toxoid). Moreover, the CD8+ cells were also capable of suppressing HBcAg-stimulated antibody to HBcAg production without showing inhibition of total immunoglobulin production stimulated by pokeweed mitogen. The cytotoxic potential of the T cell lines was established in a lectin-dependent cytotoxicity system; natural killer cytotoxicity was completely absent. Our data suggest that the lesional T cells present at the site of hepatocellular injury in chronic active hepatitis B are primarily HBcAg-specific lymphocytes of the helper and suppressor/cytotoxic phenotypes and that both are functionally competent.     

Induction of antigen-specific regulatory T cells following overexpression of a Notch ligand by human B lymphocytes

In mice, activation of the Notch pathway in T cells by antigen-presenting cells overexpressing Notch ligands favors differentiation of regulatory T lymphocytes responsible for antigen-specific tolerance. To determine whether this mechanism operates in human T cells, we used Epstein-Barr virus-positive lymphoblastoid cell lines (EBV-LCL) as our (viral) antigen-presenting cells and overexpressed the Notch ligand Jagged-1 (EBV-LCL J1) by adenoviral transduction. The EBV-LCL J1s were cocultured with autologous T cells, and the proliferative and cytotoxic responses to EBV antigens were measured. Transduction had no effect on EBV-LCL expression of major histocompatibility complex (MHC) antigens or of costimulatory molecules CD80, CD86, and CD40. However, we observed a 35% inhibition of proliferation and a >65% reduction in cytotoxic-T-cell activity, and interleukin 10 production was increased ninefold. These EBV-LCL J1-stimulated T lymphocytes act as antigen-specific regulatory cells, since their addition to fresh autologous T cells cultured with autologous nontransduced EBV-LCL cells significantly inhibited both proliferation and cytotoxic effector function. Within the inhibitory population, CD4(+)CD25(+) and CD8(+)CD25(-) T cells had the greatest activity. This inhibition appears to be antigen-specific, since responses to Candida and cytomegalovirus antigens were unaffected. Hence, transgenic expression of Jagged-1 by antigen-presenting cells can induce antigen-specific regulatory T cells in humans and modify immune responses to viral antigens.     

乙型肝炎病毒X蛋白对细胞凋亡的影响存在剂量依赖性

乙型肝炎病毒(HBV)X蛋白(HBx)与HBV相关肝细胞肝癌(HCC)的发生和发展密切相关.深入研究HBx在HCC形成中的作用将为探索HBV致癌机制提供重要依据.HBx是多功能蛋白,其对细胞凋亡的影响至今仍存在分歧.许多研究表明,HBx既有促进细胞凋亡又有抑制细胞凋亡的功能,但原因不清楚.本研究中,将表达HBx的质粒短...