Mouse thymic epithelial cell lines interact with and select a CD3lowCD4+CD8+ thymocyte subset through an LFA-1-dependent adhesion--de-adhesion mechanism

Differentiation of bone-marrow-derived precursor cells into mature mouse T lymphocytes occurs in the thymus and involves sequential interactions with MHC-positive hemopoietic and epithelial stromal cells. To study the in vitro molecular mechanisms at play during the lympho-epithelial cell adhesion, we derived thymic stromal cell lines which were shown to possess cytokeratin filaments and tight junctions. These mouse thymic epithelial (MTE) cell lines did not express the classical hemopoietic stromal cell surface markers (i.e. LFA-1, Mac-1, and CD45) but expressed ICAM-1, NCAM, J11d, CD44, and MHC molecules. A quantitative cell adhesion assay was used to evaluate the interaction of various lymphoid cell subsets with MTE cells. Two cell interaction patterns could be defined: first, a rapid adhesion of a fraction of CD4+CD8+ and of a few CD4-CD8- immature thymocytes to MTE cells was observed at 4 degrees C. The CD8 molecule was shown to be partially involved in this initial contact. The strength of adhesion between MTE cells and distinct thymocyte subsets was evaluated and found to be maximal with neonatal thymocytes. Second, a temperature-dependent adhesion step characterized by a rapid and active stabilization of the interaction of MTE cells with 20% of CD4+CD8+CD3low thymocytes was seen, followed by a more progressive de-adhesion step. This active process of engagement was highly LFA-1-dependent, involved the CD4 and CD8 molecules, and required protein kinase C activation and cytoskeletal integrity. The results are consistent with the involvement of LFA-1 in a transient and regulated cell adhesion under the control of the TCR-CD3 complex that progressively appears on maturing cells. This phenomenon might contribute to the selection of a subset of immature thymocytes by epithelial cells occurring during the process of maturation of these cells.     

Determination of the lifetime and force dependence of interactions of single bonds between surface-attached CD2 and CD48 adhesion molecules

We studied single molecular interactions between surface-attached rat CD2, a T-lymphocyte adhesion receptor, and CD48, a CD2 ligand found on antigen-presenting cells. Spherical particles were coated with decreasing densities of CD48–CD4 chimeric molecules then driven along CD2-derivatized glass surfaces under a low hydrodynamic shear rate. Particles exhibited multiple arrests of varying duration. By analyzing the dependence of arrest frequency and duration on the surface density of CD48 sites, it was concluded that (i) arrests were generated by single molecular bonds and (ii) the initial bond dissociation rate was about 7.8 s⁻¹. The force exerted on bonds was increased from about 11 to 22 pN; the detachment rate exhibited a twofold increase. These results agree with and extend studies on the CD2–CD48 interaction by surface plasmon resonance technology, which yielded an affinity constant of ≈10⁴ M⁻¹ and a dissociation rate of ≥6 s⁻¹. It is concluded that the flow chamber technology can be an useful complement to atomic force microscopy for studying interactions between isolated biomolecules, with a resolution of about 20 ms and sensitivity of a few piconewtons. Further, this technology might be extended to actual cells.     

Idiotypic analysis of monoclonal antibodies to poly(Glu60Ala30Tyr10).

Fifteen hybridoma anti-poly(Glu60Ala30Tyr10) (anti-GAT) antibodies were analyzed for the presence of a common set of idiotypic specificities associated with murine anti-GAT antibodies, termed CGAT idiotype, which are present on the anti-GAT antibodies of all mouse strains. Thirteen of these monoclonal anti-GAT antibodies expressed a major fraction of CGAT idiotypic specificities. However, the remaining fraction of CGAT idiotypic specificities were not detected in individual or pooled hybridoma anti-GAT antibodies. Anti-idiotypic antisera made against each of the 15 hybridoma anti-GAT antibodies preferentially bound homologous ligand and showed minimal binding activity to specifically purified serum anti-GAT antibodies. Furthermore, the diversity of the hybridoma anti-GAT antibodies was demonstrated by the presence of individual idiotypic specificities on each of the hybridoma anti-GAT antibodies. However, relatedness among some of the hybridoma antibodies was also apparent since idiotypic analysis revealed that some hybridoma anti-GAT antibodies shared cross-reactive idiotypic specificities not associated with CGAT idiotype. The genetic mechanisms which could account for the generation of such antibody diversity are discussed.     

In vivo effects of anti-Ia alloantisera. I. Elimination of specific suppression by in vivo administration of antisera specific for I-J controlled determinants

The in vivo effects of intravenous administration of alloantisera directed to I-J subregion coded determinants were investigated. In confirmation and extension of our previous results, anti-I-Jk [B10.A(3R) anti-B10.A(5R)] and anti-I-Js ([B10.A(3R) X B10.S(9R)]F1 anti-B10.HTT) antisera, when administered in 1 to 10 microliter amounts at the time of immunization, led to twofold increases in the IgM and IgG plaque-forming cells (PFC) responses to suboptimal doses of sheep erythrocytes in A/J (I-Jk) and SJL (I-Js) mice, respectively. To assess whether this immunopotentiation was due to a decrease in specific suppression, experiments were carried out using the polypeptide antigens random linear terpolymer of L-glutamic acid60, L-alanine30, and L-tyrosine10 (GAT) and random linear copolymer of L-glutamic acid50-L-tyrosine50 (GT), since administration of GAT to the nonresponder strain SJL, or GT to the nonresponder strain CBA fails to induce a primary PFC response and stimulates specific suppressor T cells able to prevent PFC responses to subsequent challenge with the immunogens GAT-methylated bovine serum albumin (MBSA) or GT-MBSA, respectively. The current study demonstrates that CBA (I-Jk) mice given 100 microgram GT in Maalox-pertussis adjuvant on day 0, and 10 microliter anti-I-Jk antiserum i.v. on days 0, 1, and 2, develop a significant primary specific PFC response on day 7. A similar responsiveness to 10 microgram GAT is found in SJL mice treated with 10 microliter anti-I-Js antiserum for 3 days. This same active anti-I-Js antiserum does not permit CBA mice to respond to GT, demonstrating the specificity of the anti-I-J effect. These data suggest that anti-I-J antiserum treatment at the time of antigen administration reduces suppressor responses to GAT or GT, permitting primary PFC responses. To directly demonstrate such an effect on suppressor activity, SJL or CBA mice treated, respectively, with GAT or GT to induce suppressor cells active on GAT-MBSA or GT-MBSA responses after adoptive transfer to normal syngeneic recipients were also given anti-I-J antisera (10 microliter/day) for 3 days, at which time their spleen cells were tested for suppressive activity upon transfer. Cells from such treated mice failed to show detectable suppressive activity upon transfer to syngeneic recipients challenged with GAT-MBSA or GT-MBSA, confirming the hypothesis of an in vivo effect of anti-I-J antiserum on suppressor activity.     

Molecular Heterogeneity of I-Ab Molecules: Analysis of I-Ab Subsets with Monoclonal Antibodies

In the mouse there are two Ia molecules, A and E, which are encoded by two alpha genes and two beta genes. However, previous studies from this laboratory suggested the existence of multiple forms of Ia molecules. In this report, we have investigated the molecular heterogeneity of A^b molecules by isolating and analyzing subpopulations of Ia molecules. By using monoclonal antibody affinity columns, we have isolated four distinct subpopulations of A^b molecules. These subpopulations representing a significant fraction of the total A molecules were negative for determinants recognized by one or more anti-A^b monoclonal antibodies. Possible mechanisms of the origin of these molecules are discussed.     

The I-J subregion codes for determinants on suppressor factor(s) which limit the contact sensitivity response to picryl chloride

The cell-mediated immune reactivity (CMI) of mice to contact chemicals such as picryl chloride (PCI) is influenced by thymus-derived suppressor T lymphocytes (1,2). The development of these suppressor T lymphocytes is stimulated by the intravenous administration of 2,4,6-trinitrobenzene sulfonic acid (TNBS). Zembala and Asherson have further demonstrated that a specific suppressor factor(s) can be detected in the supernates of cultured suppressor T cells. This factor suppresses the transfer of contact sensitivity (CS) to PCl (1,2). In experiments reported elsewhere (3), we have shown that the PCl suppressor supernates of Zembala and Asherson can also suppress the development of contact sensitivity to PCl. The immunochemical analysis of suppressor factor (SF) operative in the CS response to PCl has revealed many similar properties (3) to other suppressive moieties functioning to limit the plaque-forming cell (PFC) response to dinitrophenylated-keyhole limpet hemocyanin (DNP-KLH) as well as the strict antigen specificity of each respective suppressive factor, suggested that there might be a common origin of these substances. Indeed, in each case these respective factors were found to bear determinants controlled by the H-2 gene complex (4,5). Recently, in selected systems, the I-J subregion has been found to code for the Ia determinants present on suppressor cells (6) and suppressor factors (4,5). In accord with these findings, we report that antigen-specific SF which limit the CS response to PCl bear I-J determinants, implying that analogous suppressive regulatory mechanisms in CMI as well as antibody responses may be determined by genes of one subregion of the H-2 complex.     

Human CalDAG-GEFI gene (RASGRP2) mutation affects platelet function and causes severe bleeding

The nature of an inherited platelet disorder was investigated in three siblings affected by severe bleeding. Using whole-exome sequencing, we identified the culprit mutation (cG742T) in the RAS guanyl-releasing protein-2 (RASGRP2) gene coding for calcium- and DAG-regulated guanine exchange factor-1 (CalDAG-GEFI). Platelets from individuals carrying the mutation present a reduced ability to activate Rap1 and to perform proper αIIbβ3 integrin inside-out signaling. Expression of CalDAG-GEFI mutant in HEK293T cells abolished Rap1 activation upon stimulation. Nevertheless, the PKC- and ADP-dependent pathways allow residual platelet activation in the absence of functional CalDAG-GEFI. The mutation impairs the platelet’s ability to form thrombi under flow and spread normally as a consequence of reduced Rac1 GTP-binding. Functional deficiencies were confined to platelets and megakaryocytes with no leukocyte alteration. This contrasts with the phenotype seen in type III leukocyte adhesion deficiency caused by the absence of kindlin-3. Heterozygous did not suffer from bleeding and have normal platelet aggregation; however, their platelets mimicked homozygous ones by failing to undergo normal adhesion under flow and spreading. Rescue experiments on cultured patient megakaryocytes corrected the functional deficiency after transfection with wild-type RASGRP2. Remarkably, the presence of a single normal allele is sufficient to prevent bleeding, making CalDAG-GEFI a novel and potentially safe therapeutic target to prevent thrombosis.Inherited platelet disorders are rare diseases that give rise to bleeding when platelets fail to fulfill their hemostatic function upon vessel injury. Clinical manifestations include mainly mucocutaneous bleeding, menometrorrhagia and excessive bleeding after surgical intervention or trauma. The study of these diseases allows a better understanding of normal platelet biochemistry and physiology. These inherited disorders include abnormalities of platelet receptors, granules, or signal transduction (Nurden and Nurden, 2011). Signal transduction dysfunction is thought to be the most common cause of platelet inherited disorders; however, only a few have been successfully genotyped.Here, we have identified and characterized the first mutation of RASGRP2 (RAS guanyl-releasing protein-2) in a family suffering severe bleeding. RASGRP2 codes for a major signaling molecule in platelets, calcium-and-DAG-regulated guanine exchange factor-1 (CalDAG-GEFI). It is a guanine nucleotide exchange factor (GEF) that is critical for Ras-like GTPase activation whose target is mainly Rap1 in platelets (Crittenden et al., 2004; Bergmeier et al., 2007; Cifuni et al., 2008; Stefanini et al., 2009). Rap1 is one of the most predominant small GTPases in platelets and constitutes a key signaling element that governs platelet activation by directly regulating integrin-mediated aggregation and granule secretion (Chrzanowska-Wodnicka et al., 2005; Zhang et al., 2011). Mice lacking CalDAG-GEFI not only have major defects in platelet function, with a reduced ability to form thrombi upon vascular injury, but they also have impaired neutrophil functions (Crittenden et al., 2004; Bergmeier et al., 2007; Carbo et al., 2010). To date, no pathological mutation in RASGRP2 has been reported in man and knowledge about the phenotype linked to human CalDAG-GEFI deficiency is lacking.     

The mouse T-lymphocyte-activating molecule THAM is associated to ECTO-aminopeptidase activity

In the mouse there are three non-CD3/T-cell receptor T cell-activating molecules, Thy-1, Ly-6 antigens, and the CD28 homologue. Using a mitogenic rat monoclonal antibody, we identified a novel thymocyte-activating molecule (THAM). Here we review the main characteristics of this heterodimeric glycoprotein with respect to its expression on lymphoid and non-lymphoid cells, and its biochemical and T-cell-activating properties. THAM shares a number of structural features with surface peptidases of epithelial cell brush borders, and is in fact associated with a neutral aminopeptidase activity. The biologic significance of this observation is discussed in the context of recent data on the involvement of several ecto-enzymes in T-cell activation and differentiation.     

Cross-reactions of anti-I-Ek monoclonal antibodies with subsets of I-Ab molecules

Monoclonal antibodies H9-15.4 and H39-459 were derived from an A.TH anti-A.TL immunization. Antibodies H9-15.4 and H39-459 were found to be directed against the I-Ek molecule with positive reactions against B10.A (AkEk) and B10.S(9R) (AsEk) but not B10.A(4R) (AkEb). The monoclonal antibodies were also found to react with the b and q haplotypes, which do not express an I-E molecule. Sequential precipitation analysis showed that in the b haplotype, H9-15.4 and H39-459 react with the I-Ab molecule. These results showed that H9-15.4 and H39-459 recognize determinants shared by I-Ek and I-Ab molecules, suggesting that I-A and I-E molecules may have a common evolutionary origin, possibly through gene duplication. Sequential immunoprecipitation analysis of I-Ab molecules precipitated by H9-15.4 and H39-459 also suggested that these monoclonal antibodies recognize subsets of I-Ab molecules. Pretreatment with the 17-227 monoclonal anti-I-Ab antibody (Ia.15) had no effect on I-Ab molecules precipitated by H9-15.4 and H39-459. Also, pretreatment with H9-15.4 and H39-459 had no effect on I-Ab molecules immunoprecipitated by 17-227. Also H9-15.4 and H39-459 only partially cleared Ia molecules immunoprecipitated by each other. These results suggest that 17-227, H9-15.4, and H39-459 detect a minimum of four subsets of I-Ab molecules. To account for these observations, it is proposed that during evolution of the mouse H-2 complex, in addition to gene duplication of ancestral gene(s) to yield the genes encoding E alpha A alpha, A beta, and E beta polypeptide chains, further gene duplication occurred, forming multiple copies of genes encoding each Ia polypeptide chain.