scholarly journals Two distinct types of helper T cells involved in the secondary antibody response: independent and synergistic effects of Ia- and Ia+ helper T cells.

1978 ◽  
Vol 147 (2) ◽  
pp. 446-458 ◽  
Author(s):  
T Tada ◽  
T Takemori ◽  
K Okumura ◽  
M Nonaka ◽  
T Tokuhisa
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cell Response ◽  
Helper T Cells ◽  
Helper T Cell ◽  
Ia Antigen ◽  
Nylon Wool ◽  
B Cell Response

We have described here two distinct types of carrier-specific helper T cells which act independently and synergistically to augment the B-cell response to a hapten. They are separable by passage through a nylon wool column. The first type of helper T cell, which we designate as Th1, is nylon nonadherent, and can help the response of hapten-primed B cells only if the haptenic and carrier determinants are present on a single molecule (cognate interaction). The second type of helper T cell, Th2, adheres to the nylon wool column, and can help the B-cell response to a hapten coupled to a heterologous carrier upon stimulation with unconjugated relevant carrier (polyclonal interaction). The addition of a small number of Th2 to the mixture of Th1 and B cells significantly augmented the net response to the hapten carrier conjugate. Both Th1 and Th2 cells belong to the Lyt-1+,2-,3- subclass. Th1 has no detectable Ia antigen, whereas Th2 is killed by certain anti-Ia antisera and complement. The Ia antigen detected on Th2 was found to be controlled by a locus in the I-J subregion. The results clearly established the fact that there are two distinct pathways in the T- and B-cell collaboration, which involves two different subsets of carrier-specific helper T cells.

scholarly journals The role of H-2-linked genes in helper T-cell function. I. In vitro expression in B cells of immune response genes controlling helper T-cell activity

1977 ◽  
Vol 146 (6) ◽  
pp. 1748-1764 ◽  
Author(s):  
JW Kappler ◽  
P Marrack
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cross Reaction ◽  
Helper T Cells ◽  
Helper T Cell ◽  
Low Responder ◽  
The Cross

The ability of murine helper T cells primed to the antigen, sheep erythrocytes (SRBC) to cross-react with burro erythrocytes (BRBC) in the in vitro anti-trinitrophenol (TNP) response to TNP-RBC was shown to be under genetic control. Although non-H-2 genes were shown to influence the absolute level of helper activity assayed after SRBC priming, the extent of cross-reaction of SRBC-primed helpers with BRBC was shown to be controlled by an H-2-1inked Ir gene(s). H-2 haplotypes were identified which determined high, intermediate, or low response to the cross- reacting determinants and the gene(s) controlling the cross-reaction tentatively mapped to the K through I-E end of the H-2 complex. Helpers primed in F(1) mice of high x intermediate or high x low responder parents were tested for cross-reaction using B cells and macrophages (Mφ) of parental haplotypes. In each case the extent of cross-reaction was predicted by the H-2 haplotype of the B cells and Mφ, establishing the expression of the Ir gene(s) in B cells and/or Mφ a t least, but not ruling out its expression in T cells as well. The low cross-reaction seen when T cells from F(1) mice of high × low responder parents were tested on low responder B cells and Mφ was not increased by the presence of high responder Mφ, indicating the Ir gene(s) is expressed in the B cell a t least although it may be expressed in Mφ as well. These and our previously reported experiments are consistent with the hypothesis that helper T cells recognize antigen bound to the surface of B cells and Mφ in association with the product(s) of Ir gene(s) expressed on the B cell and Mφ.

scholarly journals The role of H-2-linked genes in helper T cell function. VII. Expression of I region and immune response genes by B cells in bystander help assays.

1980 ◽  
Vol 152 (5) ◽  
pp. 1274-1288 ◽  
Author(s):  
P Marrack ◽  
J W Kappler
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cell Function ◽  
High Responder ◽  
Helper T Cells ◽  
Spleen Cells ◽  
Region Gene ◽  
Immunoglobulin Receptor

The mode of action by bystander helper T cells was investigated by priming (responder X nonresponder) (B6A)F1 T cells with poly-L-(Tyr, Glu)-poly-D,L-Ala--poly-L-Lys [(TG)-A--L] and titrating the ability of these cells to stimulate an anti-sheep red blood cell (SRBC) response of parental B cells and macrophages in the presence of (TG)-A--L. Under limiting T cell conditions, and in the presence of (TG)-A--L, (TG)-A--L-responsive T cells were able to drive anti-SRBC responses of high-responder C57BL/10.SgSn (B10) B cells and macrophages (M0), but not of low-responder (B10.A) B cells and M0. Surprisingly, the (TG)-A--L-driven anti-SRBC response of B10.A B cells was not restored by addition of high-responder acessory cells, in the form of (B6A)F1 peritoneal or irradiated T cell-depleted spleen cells, or in the form of B10 nonirradiated T cell-depleted spleen cells. These results suggested that (TG)-A--L-specific Ir genes expressed by B cells controlled the ability of these cells to be induced to respond to SRBC by (TG)-A--L-responding T cells, implying that direct contact between the SRBC-binding B cell precursor and the (TG)-A--L-responsive helper T cells was required. Analogous results were obtained for keyhold limpet hemocyanin (KLH)-driven bystander help using KLH-primed F1 T cells restricted to interact with cells on only one of the parental haplotypes by maturing them in parental bone marrow chimeras. It was hypothesized that bystander help was mediated by nonspecific uptake of antigen [(TG)-A--L or KLH] by SRBC-specific b cells and subsequent display of the antigen on the B cell surface in association with Ir of I-region gene products, in a fashion similar to the M0, where it was then recognized by helper T cells. Such an explanation was supported by the observation that high concentrations of antigen were required to elicit bystander help. This hypothesis raises the possibility of B cell processing of antigen bound to its immunoglobulin receptor and subsequent presentation of antigen to helper T cells.

Cultured Human B Cell APCs Expanded Using Il-4 and CD40 Ligand Preferentially Promote a Type 2 T Cell Response to Alloimmune Stimulation.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 2668-2668
Author(s):  
Abdul Tawab ◽  
Yoshiyuki Takahashi ◽  
Childs Richard ◽  
Kurlander J. Roger
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cell Response ◽  
Cd40 Ligand ◽  
T Cell Response ◽  
Ifn Γ

Abstract In vitro stimulation of human peripheral blood B cells with recombinant IL-4 and CD40 ligand (CD40L) markedly increases their expression of MHC and costimulatory molecules, thus enhancing antigenic peptide presentation to T cells. Because these cells proliferate extensively in vitro (unlike monocytes or dendritic cells), they represent a promising and convenient reagent for the generation and maintenance of antigen-specific T cells for use in a variety of experimental or therapeutic settings. However, the impact of this type of B cell APC on cytokine production by responder T cells has hitherto not been examined. To address this issue, we stimulated normal human T cells with either allogeneic B cells (generated in vitro) or with MNCs obtained from the same donor. After 7 days, T cells were washed and re-challenged with the same APCs. The resulting alloreactive cytokine response was measured using quantitative ELISPOT methods and expressed as the frequencies of IFN-γ, IL-4, and IL-5 producing cells per thousand responder cells added. B cell- and MNC-primed cell lines both produced vigorous lymphokine responses, but B cell-stimulated T cells consistently produced more IL-5 spots (mean of 265 vs. 98/1000 responders, p<0.002) and fewer IFN-γ spots (163 vs 386/1000 cells, p<0.005) than MNC-stimulated cells. Further, the ratio of IFN-γ to IL-5 spots was almost ten-fold lower in B cell-stimulated cultures compared to MNC-induced cultures (0.67 vs. 5.2, p<0.001). ELISPOT studies assessing the ratio of IFN-γ to IL-4 spots and ELISA assays comparing IFN-γ and IL-5 levels from culture supernatants demonstrated the same pattern of marked type 2 skewing by B cells. This pattern was unaffected by the presence of anti-IL-4 antibody suggesting type 2 skewing was not mediated by IL-4. Cytokine skewing produced by B cells or MNC could be partially reversed by swapping MNC and B cells during re-stimulation on day 7, but this plasticity was markedly reduced after 3 (weekly) cycles of B cell or MNC re-stimulation in vitro. Type 2 skewing by B cells was enhanced when monocytes were removed from responder T cell populations by either depleting CD14+ positive cells or by positive selection of T cells prior to stimulation. In contrast, type 2 polarization could be prevented using recombinant IL-12. Not all cells of B-cell origin share the same propensity to type 2 skewing observed with IL-4/CD40L-stimulated B cells; under identical conditions, EBV-transformed B cells stimulated alloimmune T cells to produce a strong type 1 cytokine response comparable to that produced by MNCs. In summary, IL-4/CD40L-stimulated B cells strongly promote a type 2 T cell response during primary alloimmune challenge; this skewing can become fixed after repeated B cell stimulation. Investigators using these cells as APC should be aware of this potential phenomenon, particularly during primary T cell responses. It is also important to consider the factors described above that may exacerbate or ameliorate this effect.

scholarly journals The histocompatibility restrictions on macrophage T-helper cell interaction determine the histocompatibility restrictions on T-helper cell B-cell interaction.

1978 ◽  
Vol 148 (5) ◽  
pp. 1171-1185 ◽  
Author(s):  
U Yamashita ◽  
E M Shevach
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cell Interaction ◽  
T Helper Cell ◽  
Helper T Cells ◽  
T Helper ◽  
Ia Antigens ◽  
Nominal Antigen

To study the histocompatibility restriction between macrophages and helper T cells, carrier primed guinea pig T cells were positively selected in vitro with antigenpulsed macrophages for 7 days and the selected T cells were then mixed with hapten-primed B cells and stimulated with antigen in a modified Mishell-Dutton system. Helper T cells could only be selected with syngeneic, but not allogeneic, antigen-pulsed macrophages and would then collaborate only with syngeneic, but not allogeneic, hapten-primed spleen cells. When F1 T cells were selected with antigen-pulsed parental macrophages they would only collaborate with B cells of the same parental strain as the macrophages used in the selection culture. These results are strongly in support of the view that the primed T cell is activated by carrier determinants of the nominal antigen in association with Ia antigens on macrophages and the helper T cell, in turn, activates B cells which bear the same Ia antigens and determinants of the nominal antigen bound to immunoglobulin receptors on their surface. In addition, in experiments with antigens the response to which is controlled by I-linked genes, we demonstrated that primed (responder X nonresponder)F1 T cells would only collaborate with B cells of the responder parent. The defect appeared to be at the level of the B cell in that the addition to the cultures of antigen-presenting cells of the responder type did not restore the ability of F1 T cells to collaborate with non-responder B cells.

Rapid T Cell Response to Vaccination Can Occur without Antibody Response in Children Post HSCT.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 2235-2235
Author(s):  
W. Nicholas Haining ◽  
J. Evans ◽  
N. Seth ◽  
G. Callaway ◽  
K. Wucherpfennig ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cell Response ◽  
Influenza A ◽  
T Cell Response ◽  
T Cell Memory ◽  
Cell Immunity ◽  
Before And After ◽  
B Cell Response

Abstract Vaccination is widely used to improve pathogen-specific immunity in patients post HSCT, but it is not known whether patients can mount an effective T cell response to vaccine antigens (vAg). Moreover the relationship between T and B cell response to vAg has not been studied. We hypothesized that a sufficiently sensitive assay of T cell response to vAg would allow vaccination to be used as a tool to measure immune recovery post HSCT and improve vaccine design. We therefore: (1) developed a flow-cytometry-based approach to quantify and characterize T cells specific for vAg; (2) validated it by measuring T cell immunity to influenza A in normal donors; and (3) characterized the T and B cell response to influenza vaccination in pediatric HSCT patients. PBMC were labeled with CFSE and stimulated in vitro with whole influenza Ag. Ag-specific T cells were sensitively detected by their proliferation (loss of CFSE fluorescence) and simultaneous expression of the activation marker HLA-DR. Proliferating/active T cells could be readily detected after stimulation with influenza A Ag in healthy adult (n=4) and pediatric (n=19) donors but were absent in control conditions. Both CD4+ and CD8+ T cell proliferation was detected in all donors but one, and in children as young as 6mo. Staining with MHC I- and MHC II-tetramers confirmed that the proliferating/active population contained T cells specific for immunodominant CD8+ and CD4+ epitopes, demonstrating that vAg were processed and presented to epitope-specific T cells. To characterize the phenotype of influenza-specific T cell memory, we separated memory and naive CD4+ cells prior to antigen-stimulation. Antigen-experienced (CD45RA−/CCR7−) but not naive (CD45RA+/CCR7+) T cells proliferated to vAg confirming that the assay detected pre-existing influenza-A-specific T cell memory. We next assessed Influenza-A-specific T cell immunity before and after influenza vaccination in five pediatric HSCT recipients (mean age 10.6y, range 5–15y; mean time from transplant 13m, range 3–21m). Prior to vaccination the CD4 proliferation to influenza-A was a mean of 3.3% (range 0.04–11%). Following vaccination CD4 proliferation increased significantly in all patients (mean 19.0%, range 6.9%–31.8%, p=0.02). This increase was specific as proliferation to control Ag was unchanged. Influenza-A CD8+ proliferation also increased in 3 of 5 patients but was not statistically significant for the group consistent with the limited efficacy of soluble vAg in inducing CD8+ T cell response. All patients had detectable influenza-A-specific IgG levels prior to vaccination but despite a T cell response to vaccination in all patients, none had a significant increase in IgG level following vaccination. Only one patient had an IgM response; this patient also had the highest influenza-A-specific CD4 proliferation before and after immunization suggesting that there may be a threshold of T cell response required for a B cell response. Using a novel assay we demonstrate that a T cell response to vaccination can occur without an accompanying B cell response. This assay provides a more sensitive measure of immunity to vaccination and allows vaccine response to be used as a benchmark of strategies to accelerate post-HSCT T cell reconstitution.

scholarly journals T-independent and T-dependent steps in the murine B cell response to antiimmunoglobulin.

1987 ◽  
Vol 166 (2) ◽  
pp. 506-519 ◽  
Author(s):  
M L Birkeland ◽  
L Simpson ◽  
P C Isakson ◽  
E Pure
Keyword(s):  
T Cells ◽  
Dendritic Cells ◽  
T Cell ◽  
B Cells ◽  
B Cell ◽  
Cell Response ◽  
Buoyant Density ◽  
S Phase ◽  
And Function ◽  
Further Development

Sepharose-anti-Ig and purified populations of small, high-density B cells have been used to study the formation and function of B lymphoblasts. Sepharose-anti-Ig converts small, Ia-poor B cells with a high-buoyant density to large, Ia-rich, B blasts with a low-buoyant density. We find that this response proceeds efficiently in the absence of IL-4 (BSF-1) as well as most T cells, macrophages, and dendritic cells. Further development of the blasts requires an additional stimulus, such as LPS or the conditioned medium of stimulated EL-4 thymoma cells. Within 6 h, blasts begin to enter S phase and within 24 h most divide. At later times (48-72 h) most of the blasts are actively secreting IgM. Recombinant IL-1, -2, -3, and -4 have little or no effect on the B blasts, and a neutralizing mAb to IL-4 does not block the response to EL-4 Sn. We conclude that Sepharose-anti-Ig induces B cell blastogenesis in a T-independent fashion and that these blasts represent a highly enriched population of cells that respond to distinct, T cell-derived lymphokines.

scholarly journals Cellular and genetic control of antibody responses. V. Helper T-cell recognition of H-2 determinants on accessory cells but not B cells.

1979 ◽  
Vol 149 (5) ◽  
pp. 1208-1226 ◽  
Author(s):  
A Singer ◽  
K S Hathcock ◽  
R J Hodes
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
Helper T Cells ◽  
Cell Recognition ◽  
Helper T Cell ◽  
T Cell Recognition ◽  
Accessory Cells

Requirements for helper T-cell recognition of H-2 determinants expressed on adherent accessory cells and on B cells was individually assessed in the anti-hapten PFC responses to TNP-KLH. Complicating allogeneic effects were minimized or avoided by the use of helper T cells from normal F1 hybrids, parent leads to F1 chimeras, and F1 leads to parent chimeras. The results of both in vitro and in vivo experiments demonstrated that: (a) helper T cells are not required to recognize the identical H-2 determinants on both accessory cells and B cells; (b) helper T cells are required to recognize K or I-A region-encoded determinants expressed on accessory cells; (c) no requirement was observed in vitro or in vivo for helper T-cell recognition of B-cell-expressed H-2 determinants; and (d) no requirement was observed for H-2 homology between accessory cells and B cells. The absence of required helper T-cell recognition of the identical H-2 determinants on both accessory cells and B cells was demonstrated in two ways: (a) naive of KLH-primed (A x B)F1 hybrid helper T cells collaborated equally well with B cells from either parentA or parentB in the presence of accessory cells from either parent; (b) A leads to (A x B)F1 chimeric spleen cells depleted of accessory cells collaborated equally well with accessory cells from either parentA or parentB, even though the B cells only expressed the H-2 determinants of parentA. A requirement for helper T-cell recognition of K or I-A region-encoded H-2 determinants on accessory cells was also demonstrated in two ways: (a) (A x B)F1 leads to parentA chimeric spleen cells depleted of accessory cells collaborated with accessory cells from parentA but not parentB; and (b) (A x B)F1 leads to parentA chimeric helper T cells collaborated with normal F1 B cells only in the presence of parental or recombinant accessory cells that expressed the K or I-A region-encoded determinants of parentA. Although restricted in their ability to recognize H-2 determinants on accessory cells, it was demonstrated both in vitro and in vivo that (A x B)F1 leads to parentA chimeric helper T cells were able to collaborate with B cells from either parentA or parentB. In vitro in the presence of accessory cells from parentA, (A x B)F1 leads to parentA chimeric helper T cells collaborated equally well with B cells from either parent. In addition, the inability of (A x B)F1 leads to parentA chimeric helper T cells to collaborate with (B + accessory) cells from parentB was successfully reversed by the addition of parentA SAC as added accessory cells. In vivo, upon the addition of parentA accessory cells, (A x B)F1 leads to parentA chimeric helper T cells collaborated with parentB B cells in short-term adoptive transfer experiments.

scholarly journals The role of H-2 linked genes in helper T-cell function. IV. Importance of T-cell genotype and host environment in I-region and Ir gene expression.

1978 ◽  
Vol 148 (6) ◽  
pp. 1510-1522 ◽  
Author(s):  
J W Kappler ◽  
P Marrack
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cells ◽  
Cell Function ◽  
High Responder ◽  
Helper T Cells ◽  
Helper T Cell ◽  
Region Gene ◽  
Host Environment ◽  
Low Responder

We have studied the properties of helper T cells specific for sheep erythrocytes (SRBC), keyhole limpet hemocyanin (KLH), or poly-L-(Tyr,Glu)-poly-DL-Ala-poly-L-Lys [(T,G)-A--L]. These T cells differentiated and were primed in vivo in irradiation chimeras constructed of various combinations of F1 and parental bone marrow donors and irradiated recipients. Primed T cells were then tested for helper activity in the in vitro response of B cells and macrophages (Mphi) of parental or F1 origin to the hapten trinitrophenol coupled to the priming antigen. When testing either SRBC or KLH-specific T cells of parental H-2 type which had differentiated in F1 hosts, we found that they cooperated equally well with B cells and Mphi of either parental H-2 type. On the other hand, when testing F1 T cells which had differentiated in parental hosts, we found that they cooperated well only with B cells and Mphi which had the K-IA region type of the parental host. In similar experiments we found that (T,G)-A--L-specific T cells of low responder H-2 type which had differentiated in (high responder X low responder) F1 hosts induced high responses in high responder B cells and Mphi (T,G)-A--L-specific F1 T cells which differentiated in high responder but not those which differentiated in low responder hosts induced high responses in high responder B cells and Mphi. Low responder B cells and Mphi yielded low responses in all cases regardless of the source of (T,G)-A--L-specific T cells with what they were tested. Our results support the conclusion that I-region and Ir genes function via their expression in B cells and Mphi and in the host environment during helper T-cell differentiation, but not, at least under the conditions of these experiments, via their expression in the helper T cell itself. These findings place constraints upon models which attempt to explain the apparent dual recognition of antigen and I-region gene products by helper T cells.

scholarly journals IMMUNOLOGICAL MEMORY IN MICE

1972 ◽  
Vol 135 (2) ◽  
pp. 165-184 ◽  
Author(s):  
G. F. Mitchell ◽  
Eva L. Chan ◽  
Marion S. Noble ◽  
I. L. Weissman ◽  
R. I. Mishell ◽  
...  
Keyword(s):  
T Cells ◽  
T Cell ◽  
B Cell ◽  
Cell Population ◽  
Cell Response ◽  
Cell Activity ◽  
Cell Lineage ◽  
Cell Types ◽  
Spleen Cells ◽  
B Cell Response

Using anti-allotype sera and AKR anti θC3H sera, a requirement for two cell types has been demonstrated in the adoptive secondary response of mice to heterologous erythrocytes. The cell types have been designated B cells [precursors of plaque-forming cells (PFC)] and T cells (thymus-influenced cells, not providing precursors of detectable PFC). The in vivo indirect PFC response of spleen cells from primed mice is markedly reduced by in vitro treatment of the cells with a mixture of anti-θ serum and guinea pig serum (Anti θ + GPS). This B cell response is fully restored to control levels by thymus cells from normal mice which do not themselves provide precursors of indirect PFC. Thus memory is carried by the B cell lineage but the expression of this memory is dependent on the presence of a cell population which is sensitive to Anti θ + GPS and which is replaced functionally by unprimed T cells. When assayed for T cell activity, thoracic duct cells from specifically primed mice are better than cells from nonspecifically primed mice in restoring the B cell response of spleen cells from immunized mice. Moreover, the T cell activity of a reconstitutive cell population from primed mice is reduced by incubation with Anti θ + GPS. We conclude that memory to heterologous erythrocyte antigens is carried by the T cell lineage as well as the B cell lineage even though unprimed T cells are sufficient for expression of B cell memory.

Helper T cell activation for the human B cell response to trinitrophenylated polyacrylamide beads: involvement of the T4 antigen

1984 ◽  
Vol 14 (5) ◽  
pp. 426-430 ◽  
Author(s):  
Jean-François Delfraissy ◽  
Aimé Vazquez ◽  
Christine Wallon ◽  
Rose-Marie Desmottes ◽  
Pierre Galanaud
Keyword(s):  
T Cell ◽  
B Cell ◽  
T Cell Activation ◽  
Cell Response ◽  
Cell Activation ◽  
Helper T Cell ◽  
Human B Cell ◽  
B Cell Response
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