Generation of a conditional disruption of the Tsc2 gene

Tuberous sclerosis complex (TSC) is an autosomal dominant disorder caused by mutations in the TSC1 or TSC2 gene. Patients afflicted with TSC develop tumors in various organ systems, but cerebral pathology is particularly severe. Conventional gene disruption of the Tsc1 or Tsc2 gene in mice cause limited central nervous system pathology. Homozygous deletion of either gene causes midgestation lethality. To circumvent the homozygous lethality of the conventional Tsc2 knockout we have generated a conditional allele of the Tsc2 gene by homologous recombination in mouse ES cells. The homozygous Tsc2(flox/flox) mice are identical to wildtype in many organs typically affected by TSC, especially the brain. Using this Tsc2(flox) allele we have generated a null allele using Cre recombination. This allele will be useful in investigating TSC pathology with appropriate cell and organ specific Cre-transgenic mice.     

T cell tolerance by clonal elimination in the thymus

The monoclonal antibody KJ23a reacts with T cell receptors utilizing the V beta segment V beta 17a. T cells bearing V beta 17a+ receptors react with very high frequency with the MHC class II protein, IE. In this paper we show that T cells expressing V beta 17a are selectively eliminated from the peripheral T cell and mature thymocyte pool of mice expressing IE, but are present in expected numbers in the immature thymocyte population of such animals. These results show that in normal animals tolerance to self-MHC is due to clonal elimination rather than suppression. In addition, they indicate that tolerance induction may occur in the thymus at the time immature thymocytes are selected to move into the mature thymocyte pool.     

T cell differentiation in the thymus

T lymphocytes arise in the thymus and seed to peripheral lymphoid organs as fully functional cells at the time of exit. In humans, the thymus begins to function very early in ontogeny and releases large numbers of T cells before the time of birth. However, the vast majority of developing thymocytes (>95%) die within the thymus as a result of stringent selection processes. Positive selection imposes self-MHC-restriction on thymocytes and dictates the MHC-restricted repertoire of post-thymic T cells. Negative selection results in deletion of autoreactive cells. Both types of selection depend on cell to cell contracts and on the presence of appropriate growth factors which are still largely undetermined. Cell to cell contacts occur between developing thymocytes and cells of the thymic microenvironment (accessory cells), and are mediated by several receptor/ligand interactions which subserve the function of establishing and stabilizing these contacts. Besides MHC-TCR interactions, adhesion molecules are important for thymocyte maturation, selection and activation, and for the export and peripheral homing of mature T cells produced in the thymus. Here we describe a novel integrin involved in thymocyte-thymic epithelial cell interactions.     

Nef-mediated disruption of HLA-A2 transport to the cell surface in T cells

Human immunodeficiency virus type 1 (HIV-1) Nef is a key pathogenic factor necessary for the development of AIDS. One important function of Nef is to reduce cell surface levels of major histocompatibility complex class I (MHC-I) molecules, thereby protecting HIV-infected cells from recognition by cytotoxic T lymphocytes. The mechanism of MHC-I downmodulation by Nef has not been clearly elucidated, and its reported effect on MHC-I steady-state levels ranges widely, from 2-fold in HeLa cells to 200-fold in HIV-infected primary T cells. Here, we directly compared downmodulation of HLA-A2 in HIV-infected HeLa cells to that in T cells. We found that similar amounts of Nef protein resulted in a much more dramatic downmodulation of HLA-A2 in T cells than in HeLa cells. A comparison of Nef's effects on HLA-A2 endocytosis, recycling, and transport rates indicated that the most prominent effect of Nef on HLA-A2 in T cells was to inhibit transport to the cell surface. The phosphatidylinositol 3-kinase inhibitor, LY294002, previously reported to inhibit Nef-mediated MHC-I downmodulation in astrocytic cells, did not directly affect Nef's ability to block transport of MHC-I to the cell surface in T cells.     

Ontogeny of T cell receptors in the chicken thymus

A panel of murine mAb against chicken TCR and associated molecules was used to study the ontogeny of T cells. The intrathymic maturation of the TCR-gamma delta, (TCR-1) and TCR-alpha beta (TCR-2) sublineages was the focus of these studies employing immunoperoxidase staining of tissue sections and immunofluorescence analysis of cell suspensions. The first CD3+ cells appeared in the thymus on embryonic day 9 (E9) when the CD3 Ag was restricted to the cytoplasm. In tissue sections, both TCR-1+ and TCR-2+ cells were observed on E12, whereas only the TCR-1 cells were identifiable by surface immunofluorescence. On the next day, when a discrete thymic medullary region was first recognizable, the TCR-1 cells were present in both cortex and medulla. Two days later (E15), TCR-1 cells were found in the spleen. Surface TCR-2+ cells did not appear until E14, began to migrate in to the medulla on E17, and appeared in the spleen on E19. The first TCR-1 cells thus move quickly through this maturational pathway, whereas TCR-2 cells undergo a prolonged developmental period in the cortex. While most TCR-1+ cells were CD4-CD8-, a minor subpopulation (5 to 15%) were CD4-CD8+, and less than 1% were CD4+CD8+. In contrast, immature TCR-2+ thymocytes in the cortex were predominantly CD4+CD8+, whereas cells expressing a higher density of the CD3/TCR-2 complex were either CD4+CD8- or CD4-CD8+ and were localized in the thymic medulla. In the medulla of the mature thymus, the TCR-1+ cells preferentially occupy the cortico-medullary junction and form small aggregates around vessels. TCR-2+ cells were less frequent in these areas of TCR-1 accumulation. The thymic ontogeny and, by implication, the selection of the receptor repertoire thus differs substantially for these two TCR isotypes.     

Separable roles of UFO during floral development revealed by conditional restoration of gene function

The UNUSUAL FLORAL ORGANS (UFO) gene is required for several aspects of floral development in Arabidopsis including specification of organ identity in the second and third whorls and the proper pattern of primordium initiation in the inner three whorls. UFO is expressed in a dynamic pattern during the early phases of flower development. Here we dissect the role of UFO by ubiquitously expressing it in ufo loss-of-function flowers at different developmental stages and for various durations using an ethanol-inducible expression system. The previously known functions of UFO could be separated and related to its expression at specific stages of development. We show that a 24- to 48-hour period of UFO expression from floral stage 2, before any floral organs are visible, is sufficient to restore normal petal and stamen development. The earliest requirement for UFO is during stage 2, when the endogenous UFO gene is transiently expressed in the centre of the wild-type flower and is required to specify the initiation patterns of petal, stamen and carpel primordia. Petal and stamen identity is determined during stages 2 or 3, when UFO is normally expressed in the presumptive second and third whorl. Although endogenous UFO expression is absent from the stamen whorl from stage 4 onwards, stamen identity can be restored by UFO activation up to stage 6. We also observed floral phenotypes not observed in loss-of-function or constitutive gain-of-function backgrounds, revealing additional roles of UFO in outgrowth of petal primordia.     

Recognition of adenovirus E1A gene products on immortalized cell surfaces by cytotoxic T lymphocytes.

The experiments described in this report were designed to examine whether target cells transfected with the adenovirus E1A gene and exhibiting increased susceptibility to lysis by natural killer cells and activated macrophages (J. L. Cook, T. A. Walker, A. M. Lewis, Jr., H. E. Ruley, F. L. Graham, and S. H. Pilder, Proc. Natl. Acad. Sci. USA 83:6965-6969, 1986) also express E1A proteins on their surfaces. MT1A, 12S, and 13S are strain Fischer baby rat kidney (BRK) cell lines immortalized by transfection with plasmids containing only the E1A gene of nononcogenic adenovirus. All of these cell lines were effective in stimulating the generation of cytotoxic T lymphocytes (CTL) in vitro, provided that the cultures were supplemented with an exogenous source of lymphokine and that the responding lymphocytes were from syngeneic Fischer rats previously immunized with a cell line containing the intact E1A gene. HrA2, a Fischer BRK cell line immortalized by transfection with a plasmid containing only exon 1 of the E1A gene, did not generate, nor was it lysed by, E1A-specific CTL. The cytolytic activity of E1A-specific CTL was blocked by antiserum from Fischer rats immunized with purified E1A proteins synthesized in Escherichia coli, supporting the conclusion that an epitope on E1A proteins encoded by the intact E1A gene constitutes part of the CTL target structure on adenovirus-transformed cells. These data suggest that in addition to their functions within host cells, E1A gene products are important immunogenic determinants on the surfaces of adenovirus-transformed cells.     

SIT and TRIM determine T cell fate in the thymus

Thymic selection is a tightly regulated developmental process essential for establishing central tolerance. The intensity of TCR-mediated signaling is a key factor for determining cell fate in the thymus. It is widely accepted that low-intensity signals result in positive selection, whereas high-intensity signals induce negative selection. Transmembrane adaptor proteins have been demonstrated to be important regulators of T cell activation. However, little is known about their role during T cell development. Herein, we show that SIT (SHP2 Src homology domain containing tyrosine phosphatase 2-interacting transmembrane adaptor protein) and TRIM (TCR-interacting molecule), two structurally related transmembrane adaptors, cooperatively regulate TCR signaling potential, thereby influencing the outcome of thymic selection. Indeed, loss of both SIT and TRIM resulted in the up-regulation of CD5, CD69, and TCRbeta, strong MAPK activation, and, consequently, enhanced positive selection. Moreover, by crossing SIT/TRIM double-deficient mice onto transgenic mice bearing TCRs with different avidity/affinity, we found profound alterations in T cell development. Indeed, in female HY TCR transgenic mice, positive selection was completely converted into negative selection resulting in small thymi devoided of double-positive thymocytes. More strikingly, in a nonselecting background, SIT/TRIM double-deficient single-positive T cells developed, were functional, and populated the periphery. In summary, we demonstrated that SIT and TRIM regulate cell fate of developing thymocytes, thus identifying them as essential regulators of central tolerance.     

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

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

Regulation of NK cell activity by prostaglandin E2: the role of T cells

The influence of T cells on the production of prostaglandins (PGE2) and on PGE2-mediated regulation of natural killer (NK) activity was studied. Supernatants from peripheral blood mononuclear cells (PBMC) and from PBMC depleted of T cells ((PBMC)-T), both of which had been incubated in plastic petri dishes overnight, contained similar amounts of PGE2, as detected by radioimmunoassay and by their potential to inhibit NK activity of peripheral blood mononuclear cells in a 51Cr release assay with K 562 cells as the target population. However, the NK activity of PBMC was inhibited significantly more strongly (P less than 0.005) by PGE2-containing supernatants than was the NK activity of (PBMC)-T. In further assays, in which synthetic PGE2 in concentrations of 10(-4) and 10(-5)M was added, a significant inhibition of NK activity was observed in PBMC populations (P less than 0.05), but not in (PBMC)-T. Thus, T cells did not seem to be involved in the control of PGE2 production, but their presence was necessary for PGE2-mediated inhibition of NK activity.     

An analysis of T cell responsiveness in Indian kala-azar

The inability of most untreated patients with Kala-azar to control their visceral infections with Leishmania donovani has been attributed to a defective cell-mediated immune response to leishmanial antigens. We examined the in vitro response of T cells, including Leu-2+-depleted T cell populations, to determine whether unresponsiveness could be reversed. These studies on patients with visceral leishmaniasis in Bihar, north India, support previous observations regarding T cell unresponsiveness in patients with active disease: it is profound, it is specific, and it is reversible after successful chemotherapy. However, these studies also indicate that the specific unresponsiveness cannot be reversed by depletion of "suppressor" Leu-2+ T lymphocytes, nor by the addition of exogenously supplied human IL 2 to the cultures. One interpretation of these results is that in active cases of Kala-azar, there is an absence of Leishmania-specific T cells in the periphery. The possibility that reactive cells can be found in situ cannot be excluded. The observation that 13 of 25 family members of active cases were able respond to L. donovani in vitro or by skin testing suggests that the frequency of infection within an endemic area in Bihar is very high, and that assays for T cell responsiveness are far better epidemiologic tools for the detection of asymptomatic infection than is ELISA. Identification of such an exposed, Kala-azar-resistant population will be required to study host factors which influence the development of disease in infected individuals.     

Prostaglandin E2 inhibits the activation of cloned T cell hybridomas

To minimize complicating interactions inherent in heterogeneous cell populations, we used a panel of cloned murine autoreactive (E8.A1) and antigen-specific (HEL.C10, HEL.B14) T cell hybridomas to examine the effect of prostaglandin E2 (PGE2) on T cell activation. These T cells secrete interleukin 2 (IL 2) when co-cultured with a cloned population of I region-matched stimulator cells (TA3), or with mitogenic signals in the absence of TA3 stimulator cells. Physiologic concentrations of PGE2 inhibited the induction of IL 2 secretion by the T cell hybridomas tested, when they were activated either by TA3 cells or by mitogenic signals. IL 2 production was inhibited in a dose-dependent manner by concentrations of PGE2 between 10(-7) and 10(-11) M, with 50% inhibition occurring at 10(-10) M. Pretreatment of the T hybridoma cells with 10(-7) M PGE2 for 1 hr before culture also resulted in marked inhibition of IL 2 secretion. Similar pretreatment of the TA3 cells did not affect their ability to activate the T cell hybridomas. PGE2 at 10(-8) M induced a 30-fold increase in cAMP levels within 25 min of addition to culture of the E8.A1 T cell hybridoma, but caused no significant elevation of cAMP levels in TA3 cells. The direct addition of dibutyryl cAMP (dcAMP) to cultures of E8.A1 cells resulted in marked inhibition of IL 2 secretion when stimulated by TA3 or by mitogenic signals, with an average of 80% inhibition occurring at 10(-4) M dcAMP. PGE2 and dcAMP also inhibited the growth of E8.A1 cells. Initially, cell growth was virtually halted, but began to recover between 24 and 48 hr after the addition of either PGE2 or dcAMP. Neither PGE2 nor dcAMP inhibited the division of TA3 cells. High affinity binding sites for PGE2 were detected in the E8.A1 T cell hybridomas with an apparent Kd of 7.6 X 10(-10) M, which is consistent with the functional data. No specific binding was detected in the TA3 stimulator cells. These findings suggest that the immunosuppressive effects of PGE2 are localized to the T cell, are receptor regulated, and may be mediated by the associated increase of cAMP levels in the T cell hybridomas.     

Functional competency of T cell antigen receptors in human thymus

The T cell antigen receptor is likely to play a role in both positive and negative selection in the thymus. Three populations of thymocytes can be distinguished by the level of expression of the CD3-alpha/beta-chain heterodimer of the T cell antigen receptor (CD3/Ti alpha/beta) complex. Cells which fail to express these receptors or express low levels of receptors are contained in a population of thymocytes which express low levels of the CD5 antigen and are predominantly CD4+/CD8+. Thus, these cells appear to be relatively immature phenotypically. In contrast, the cells which express high levels of CD3/Ti alpha/beta co-express high levels of CD5 and are predominantly contained in the more mature single positive cells which express either CD4 or CD8. With the calcium-sensitive dye, Indo-1, and immunofluorescence, we demonstrated that, despite the relative phenotypic immaturity of cells which express low levels of CD3/Ti alpha/beta, these antigen receptors are able to mediate transmembrane signaling when stimulated with CD3 monoclonal antibodies. Although increases in calcium were observed in these CD3/Ti alpha/beta-low expressing cells in response to anti-CD3, no proliferative response was observed, even in the presence of phorbol myristate acetate. Proliferative responses were observed in the more mature cells which express high levels of CD3/Ti alpha/beta. These results suggest that, rather than a defect in the functional capability of the antigen receptor complex to mediate transmembrane signaling events, cellular responses to signals generated by the antigen receptor may differ at various stages of thymocyte development.