Transgene-encoded human CD2 acts in a dominant negative fashion to modify thymocyte selection signals in mice

CD2 is a cell surface glycoprotein present on all T cells which has been shown to function as an adhesion and signaling molecule. Expressed early in T cell development, human CD2 (HCD2) has been suggested to play a role during thymopoiesis. However, the relevance of CD2 in T cell development has been called into question recently, as neither disruption of the CD2 gene nor anti-CD2 antibody treatment of fetal thymic organ cultures in mouse were shown to have any discernible consequences. We have expressed HCD2 at high levels in transgenic mice and found a profound effect of the transgene on thymocyte differentiation. Transgenic thymuses are considerably reduced in cell number as a consequence of increased apoptosis of double-positive (DP) thymocytes in the cortex. The remaining DP cells have up-regulated levels of T cell receptor (TCR) and are resistant to apoptosis mediated by administration of antigen. These effects are dependent on the cytoplasmic domain of HCD2, as mice expressing comparable levels of a tailless HCD2 transgene have a normal phenotype. The HCD2 cytoplasmic domain contains several regions of identity with mouse CD2 and can interact effciently with mouse intracellular signaling machinery. These results suggest there is considerable cross-talk between CD2 and TCR on developing thymocytes with consequences for the stimulation threshold of mature T cells.     

Induction of thymocyte positive selection does not convey immediate resistance to negative selection

The acquisition of functional competence represents a critical phase during intrathymic development of T cells. Thymocytes reaching this stage represent cells which have been positively selected on the basis of major histocompatibility complex reactivity, but which have also been purged of potentially autoreactive T-cell receptor specificities by negative selection. While the developmental window in which thymocytes are subjected to positive selection is now well defined, the precise developmental timing of negative selection, in relation to positive selection events, is less clear. Moreover, the underlying mechanism allowing single-positive thymocytes to respond to T-cell receptor ligation by activation rather than death, remains controversial. Here we have analysed the developmental timing of negative selection in relation to positive selection, using measurement of thymocyte susceptibility to dendritic cell presentation of the superantigen staphylococcal enterotoxin B (SEB). We show that thymocytes which have received initial positive selection signals, namely CD4+ CD8+ CD69+ thymocytes, like their CD4+ CD8+ CD69minus sign precursors, are susceptible to negative selection, indicating that induction of positive selection does not convey immediate resistance to negative selection. In contrast, newly generated CD4+ CD8minus sign CD69+ cells are not only resistant to deletion by SEB, but respond to SEB-mediated T-cell receptor-ligation by activation, indicating that the acquisition of functional competence occurs at the newly generated CD4+ CD8minus sign CD69+ stage. Finally, by using direct retroviral infection of primary CD4+ CD8+ thymocytes, we also show that Notch-1 activation in CD4+ CD8+ thymocytes does not correlate with, nor convey resistance to superantigen-mediated negative selection. Thus, our data suggest that although Notch-1 has been implicated in resistance to thymocyte apoptosis, the acquisition of resistance to negative selection occurs independently of Notch-1 signalling.     

Bi-directional signaling by Semaphorin 1a during central synapse formation in Drosophila

Semaphorins have been intensively studied for their role in dendritic and axonal pathfinding, but less is known about their potential role in synapse formation. In the adult giant fiber (GF) system of fruit flies (Drosophila melanogaster), we show that transmembrane Semaphorin 1a (Sema-1a) is involved in synapse formation in addition to its role in guidance during pathfinding. Cell-autonomous rescue experiments showed that Sema-1a is involved in assembly of a central synapse and that it is required both pre- and postsynaptically. We also found that pre- but not postsynaptic gain-of-function Sema-1a was able to disrupt the GF-motor neuron synapse and that the phenotype depended on a proline-rich intracellular domain that contains a putative Enabled binding site. We suggest that transmembrane Sema-1a is part of a bi-directional signaling system that leads to the formation of the GF synapse and possibly acts as both a ligand and a receptor.     

Activity-dependent switch from synapse formation to synapse elimination during development of neuromuscular junctions

The embryonic development of neuromuscular junctions consists of two successive epochs, an early period marked by exuberant synapse formation and a later period marked by synapse elimination. In the frog muscles we have studied, myogenesis is protracted and overlaps the periods of synapse formation and elimination. Thus, the formative and regressive events of synaptic development do not occur in synchrony across different fibers in the muscle. We propose that local activity orchestrates a shift from synaptogenesis to synapse elimination at the level of single muscle fibers. We also present evidence that perisynaptic Schwann cells and the expression of ion channels in the sarcolemma play important roles in the development of neuromuscular junctions. Questions for future study are outlined.     

Correlation of a dynamic model for immunological synapse formation with effector functions: two pathways to synapse formation

During antigen recognition by T cells different receptors and ligands form a pattern in the intercellular junction called the immunological synapse, which might be involved in T-cell activation. Recently, a synapse assembly model has been proposed, which enables the calculation of the propensity for synapse assembly driven by membrane-constrained protein binding interactions. We bring together model predictions of mature synapse assembly with data on the dependence of T-cell responses on T-cell receptor (TCR)-MHC-peptide (pMHC) binding kinetics. Predictions of mature synapse assembly, based on TCR-pMHC binding kinetics, correlate well with observed cytokine responses by T cells bearing the relevant TCR but not with cytotoxic T lymphocyte-mediated killing. We discuss the suggested different role for the synapse in pre- and post-nuclear activation events in T cells. The view of immunological synapse assembly given here emphasizes the importance of both the on and off rates for the TCR-pMHC interaction and in this context recent data on a positive role for analogs of self-peptides in synapse assembly is considered.     

免疫突触形成过程中T细胞受体的重定向运动:涡旋驱动模型

目的：建立T细胞受体（TCR）在免疫突触形成过程中作重定向（reorientation）运动的机制模型.方法：基于经典流体力学环境中的双分子反应传能原理,提出了T细胞受体的涡旋驱动模型,利用免疫突触内耦合的受体或配体分子作为涡源驱动T细胞受体分子的募集.结果：模型计算的结果表明,在强度及作用频率同时具备一定范围的涡旋连续驱动下,TCR重定向运动速度可达到实验测定的范围（0.04～0.1 μm/s）.结论：本模型证明突触内受体/配体对耦合时通过将其结合自由能转化为细胞内外流体涡旋运动的机械能可能直接提供了TCR重定向运动的驱动力.     

Ontogeny of a novel CD4+CD8-CD3- thymocyte subpopulation: a comparison with CD4- CD8+ CD3- thymocytes

We have studied the ontogeny of a novel thymocyte subset, CD4+CD8-CD3-. Three-colour flow cytometric analysis demonstrated that these cells constituted approximately 1% of the total thymocyte content in adult CBA mice, and were not present in lymph nodes. They were mainly blastic, cortisone-sensitive, and localized in the outer thymic cortex. During foetal life they were first observed at day 15 and reached a maximum (6%) at day 17, beyond which they decreased to the adult level. This kinetic profile was similar to that of the CD4-CD8+CD3- subpopulation, except that the CD4+CD8-CD3- cells appeared slightly earlier and their percentage was lower. Both these populations appeared after the CD4-CD8-CD3- cells but before the CD4+CD8+CD3- cells. Similar observations were made during thymic reconstitution following dexamethasone treatment. In this case, both CD4+CD8-CD3- and CD4-CD8+CD3- thymocytes disappeared 48 h after the treatment. While their absolute number increased up to 14 days post-treatment, their percentage was maximal at day 7 post-treatment and returned to normal values by day 10 post-treatment. These results argue strongly that not only the CD4-CD8+CD3- population but also the CD4+CD8-CD3- population can be considered an intermediate precursor in CBA thymuses.     

T cell killing does not require the formation of a stable mature immunological synapse

A notable feature of T lymphocyte recognition on other cell surfaces is the formation of a stable mature immunological synapse. Here we use a single-molecule labeling method to directly measure the number of ligands a cytotoxic T cell engages and track the consequences of that interaction by three-dimensional video microscopy. Like helper T cells, cytotoxic T cells were able to detect even a single foreign antigen but required about ten complexes of peptide-major histocompatibility complex (pMHC) to achieve full calcium increase and to form a mature synapse. Thus, cytotoxic T cells and helper T cells are more uniform in their antigen sensitivities than previously thought. Furthermore, only three pMHC complexes were required for killing, showing that stable synapse formation and complete signaling are not required for cytotoxicity.     

Over-expression of human CD44s in murine 3T3 cells: selection against during primary tumorigenesis and selection for during micrometastasis

Human CD44 standard isoform (hCD44s) cDNA regulated by a high-expressing promoter was transfected into Balb/c 3T3 cells and the tumorigenic and metastatic capacities of the transfectants were investigated in nude mice at the subcutaneous site. One of three transfectants was tumorigenic. hCD44s expression was lost in the cells of large primary tumors using this tumorigenic clone. These tumors were extremely aggressive giving overt metastases and micrometastases to several sites including mesentery, stomach, liver, diaphragm, pancreas and lung. Micrometastatic cells re-expressed hCD44s, consistent with its importance for early steps in the metastatic cascade. hCD44s was not expressed in overt metastases; most probably the expression was lost during the outgrowth of micrometastases into overt metastatic tumors. Thus hCD44s expression in murine 3T3 cells does induce tumorigenicity in select cases, is not compatible with aggressive outgrowth of primary or secondary tumors, and is advantageous for early steps in metastatic spread. These results suggest that CD44s is an example of a novel type of metastasis molecule that is disadvantageous for tumor growth and is only transiently advantageous during metastatic spreading of tumor cells to distant organs.     

CD8 is needed for positive selection but differentially required for negative selection of T cells during thymic ontogeny

During thymic development, immature thymocytes expressing major histocompatibility complex (MHC) class I-restricted T cell receptors (TcR) differentiate into CD8⁺ T cells with cytolytic functions. To evaluate the role of CD8 in positive and negative selection during thymic ontogeny, mice rendered CD8-null by gene targeting were bred with three lines of transgenic mice expressing unique MHC class I-restricted TcR. In all three instances CD8 was required for positive selection of MHC class I-restricted transgenic T cells. The efficiency of positive selection decreased in accordance with a reduced level of CD8 expression on thymocytes. Surprisingly, there was a differential requirement for CD8 expression in negative selection of MHC class I-restricted thymocytes, depending on the antigen specificity of TcR. These observations show that CD8 is essential for positive selection but is differentially required for negative selection of MHC class I-restricted T cells. Thus thymic selection, at least for negative selection, can occur in the absence of the CD8 accessory molecule.     

Peptidergic contribution to posttetanic potentiation at a central synapse of aplysia

Posttetanic potentiation (PTP)-like phenomena appear to be mediated by a variety of mechanisms. Although neuropeptides are located in a large number of neurons and many neuropeptides, like PTP, can enhance synaptic transmission, there is a paucity of studies indicating that peptides may actually participate in PTP. Here, we utilize a single central synapse in the feeding circuit of Aplysia to investigate a possible peptidergic contribution to PTP in the CNS. The cholinergic command-like interneuron, cerebral-buccal interneuron 2 (CBI-2), contains two neuropeptides, feeding circuit activating peptide (FCAP) and cerebral peptide 2 (CP2). Previous studies showed that tetanic prestimulation or repeated stimulation of CBI-2, as well as perfusion of FCAP and CP2, increase the size of the cholinergic excitatory postsynaptic potentials (EPSPs) that CBI-2 evokes in the motoneurons B61/62 and shorten the latency to initiate B61/62 firing in response to CBI-2 stimulation. We used temperature-dependent suppression of peptide release and occlusion experiments to examine the possible contribution of FCAP and CP2 to PTP at the CBI-2 to B61/62 synapse. When peptide release was suppressed, perfusion of exogenous peptides increased the size of posttetanic EPSPs. In contrast, when peptide release was not suppressed, exogenous peptides did not enhance the size of posttetanic EPSPs, thus indicating occlusion. Temperature manipulation and occlusion experiments also indicated that peptides extend PTP duration. This peptide-dependent prolongation of PTP has functional consequences in that it extends the duration of time during which the latency to initiate B61/62 firing in response to CBI-2 stimulation is shortened.     

Altered functional responsiveness of thymocyte subsets from CD3delta- deficient mice to TCR-CD3 engagement

CD3delta-deficient (delta degrees) mice are defective in alphabeta T cell development. Here we explore the capacity of TCR-CD3 signaling complexes expressed on delta degrees thymocytes to mediate the following functional outcomes in response to antibody cross-linking: (i) the transition from the CD4-CD8- to CD4+CD8+ stage, (ii) the transition from the CD4+CD8+ to CD4+CD8- or CD4-CD8+ stages and (iii) the induction of apoptosis. We provide evidence that CD3deltaepsilon complexes are dispensable for mediating the anti-CD3-mediated CD4-CD8- to CD4+CD8+ transition. On the other hand, CD3delta is critical at the CD4+CD8+ stage. We demonstrate that CD4+CD8+ thymocytes from delta degrees mice, unlike delta degrees CD4-CD8- thymocytes and wild-type CD4+CD8+ thymocytes, require prolonged or consecutive stimuli to elicit functional responses. Depending on the nature of the secondary stimulus, delta degrees thymocytes can be induced to undergo apoptosis or preferential maturation to the CD4-CD8+ stage. Taken together these results indicate that the signaling capacity of the TCR-CD3 complex is noticeably altered in the absence of CD3delta. The essential role of CD3delta at the CD4+CD8+ stage of development correlates with the onset of TCRalpha rearrangement, consistent with a critical structural and/or functional relationship between CD3delta and TCRalpha.      

Double-negative thymocyte subsets in CD3′ chain-deficient mice: Absence of HSA+CD44−CD25− cells

Double-negative (DN) thymocyte subsets were examined in mice deficient in the CD3′ chain (ζ −/−). The HSA ⁺CD44⁻CD25⁻ subset was found to be missing, and DN thymocytes seemed to differentiate directly from HSA⁺CD25⁺CD44⁻cells to double-positive (DP) cells. When fetal thymic ontogeny was examined, we found a marked difference between ζ −/− embryos and heterozygous littermates from embryonic day 17.5, in terms of CD25, CD4 and CD8 expression, and thymus size. The ζ −/− thymocytes failed to down-regulate CD25 and to expand exponentially. The cell cycle status of adult thymocyte subsets indicated that although the HSA ⁺CD25⁻CD44⁻ subset was missing, the CD25⁺ DN population contained normal numbers of cycling cells, and the CD25⁺ DP cells (which were not detectable in normal mice) contained 5–10% cells in G2/M + S. Taken together these data suggest that the CD3′ chain might have a specific role in the control of proliferation of DN thymocytes during T cell development. Our data clearly show that one can dissociate the signal for a CD25⁺ DN cell to differentiate (which occurs in the absence of CD3′), from a signal to proliferate and from loss of cell surface CD25.     

Selective expression of CD45 isoforms and of maturation antigens during human thymocyte differentiation: observations and hypothesis

Selective expression of high and low molecular weight isoforms of CD45 (T200) occurs coincident with activation of mature T lymphocytes. Expression of CD45 p180 and CDw29 defines antigen-experienced memory T cells in the periphery, and expression of CD45R (CD45 p205/220) defines naive T cells. Upon activation, CD45R+ T cells lose CD45R and acquire CD45 p180 and high density CDw29. In this review we discuss the expression of CD45 isoforms, CDw29, pgp-1 and CD1 on human thymocytes and develop the hypothesis that expression of CD45R marks the generative thymic lineage while expression of CD45 p180 marks those cells destined for intrathymic death. This hypothesis is supported by evidence from phenotypic, molecular and functional analysis of thymocyte subsets. We propose that expression of high molecular weight isoforms of CD45 is essential for growth and differentiation of immature T cells and that inappropriate rearrangement or specificity of TCR activates a transition from expression of CD45R to that of CD45 p180 and intrathymic death.     

The Wiskott-Aldrich syndrome protein acts downstream of CD2 and the CD2AP and PSTPIP1 adaptors to promote formation of the immunological synapse

The Wiskott-Aldrich syndrome protein (WASp) couples actin cytoskeletal rearrangement to T cell activation, but the mechanisms involved are unknown. Here, we show that antigen-induced formation of T cell:APC conjugates and synapses is abrogated in WASp-deficient T cells and that CD2 engagement evokes interactions between the proline-rich region required for WASp translocation to the synapse and the PSTPIP1 adaptor SH3 domain and between the PSTPIp1 coiled-coil domain and both CD2 and another CD2-binding adaptor, CD2AP. The induced colocalization of these proteins at the synapse is disrupted by expression of coiled-coil domain-deleted PSTPIP1. These data, together with the impairment in CD2-induced actin polymerization observed in WASp-deficient cells, suggest that PSTPIP1 acts downstream of CD2/CD2AP to link CD2 engagement to the WASp-evoked actin polymerization required for synapse formation and T cell activation.     

Corrigendum: CD3{zeta} and {eta} chains are produced by alternative splicing from a common gene

Concerning the above article, the authors found that the Clone 10-3 had a deletion of approximately 1.4 kb inlength withinintron 8, which resulted in the misestimation of the lengthof intron 8. The correct distance between exon 8 (exon 8) andexon 8 (exon 9) should be 5.4 kb instead of 4 kb (in line theright coloumn of page 1117).     

ERM-dependent movement of CD43 defines a novel protein complex distal to the immunological synapse.

The large mucin CD43 is actively excluded from T cell/APC interaction sites, concentrating in a membrane domain distal to the site of TCR engagement. The cytoplasmic region of CD43 was necessary and sufficient for this antipodal movement. ERM cytoskeletal adaptor proteins colocalized with CD43 in this domain. An ERM dominant-negative mutant blocked the distal accumulation of CD43 and another known ERM binding protein, Rho-GDI. Inhibition of ERM function decreased the production of IL-2 and IFNgamma, without affecting PKC(theta) focusing or CD69 upregulation. These results indicate that ERM proteins organize a complex distal to the T cell/APC interaction site and provide evidence that full T cell activation may involve removal of inhibitory proteins from the immunological synapse.