A role for the vegetally expressed Xenopus gene Mix.1 in endoderm formation and in the restriction of mesoderm to the marginal zone.

We have studied the role of the activin immediate-early response gene Mix.1 in mesoderm and endoderm formation. In early gastrulae, Mix.1 is expressed throughout the vegetal hemisphere, including marginal-zone cells expressing the trunk mesodermal marker Xbra. During gastrulation, the expression domains of Xbra and Mix.1 become progressively exclusive as a result of the establishment of a negative regulatory loop between these two genes. This mutual repression is important for the specification of the embryonic body plan as ectopic expression of Mix.1 in the Xbra domain suppresses mesoderm differentiation. The same effect was obtained by overexpressing VP16Mix.1, a fusion protein comprising the strong activator domain of viral VP16 and the homeodomain of Mix.1, suggesting that Mix.1 acts as a transcriptional activator. Mix.1 also has a role in endoderm formation. It cooperates with the dorsal vegetal homeobox gene Siamois to activate the endodermal markers edd, Xlhbox8 and cerberus in animal caps. Conversely, vegetal overexpression of enRMix.1, an antimorphic Mix.1 mutant, leads to a loss of endoderm differentiation. Finally, by targeting enRMix.1 expression to the anterior endoderm, we could test the role of this tissue during embryogenesis and show that it is required for head formation.

A novel Xenopus mix-like gene milk involved in the control of the endomesodermal fates.

Here we describe a novel Xenopus homeobox gene, milk, related by sequence homology and expression pattern to the vegetally expressed Mix.1. As is the case with Mix.1, milk is an immediate early response gene to the mesoderm inducer activin. milk is expressed at the early gastrula stage in the vegetal cells, fated to form endoderm, and in the marginal zone fated to form mesoderm. During gastrulation, expression of milk becomes progressively reduced in the involuting mesodermal cells but is retained in the endoderm, suggesting that it may play a key role in the definition of the endo-mesodermal boundary in the embryo. Overexpression of milk in the marginal zone blocks mesodermal cell involution, represses the expression of several mesodermal genes such as Xbra, goosecoid, Xvent-1 or Xpo and increases the expression of the endodermal gene, endodermin. In the dorsal marginal zone, overexpression of milk leads to a severe late phenotype including the absence of axial structures. Ectopic expression of milk in the animal hemisphere or in ectodermal explants induces a strong expression of endodermin. Taken together, we propose that milk plays a role in the correct patterning of the embryo by repressing mesoderm formation and promoting endoderm identity.

Defect in rearrangement of the most 5' TCR-J alpha following targeted deletion of T early alpha (TEA): implications for TCR alpha locus accessibility.

To address the role of the TEA germline transcription, which initiates upstream of the TCR-J alpha S, in the regulation of TCR-J alpha locus accessibility, we created a mouse in which this region has been removed by homologous recombination. Normal development of T alpha beta cells and the expression of other TCR alpha germline transcripts in TEA-/- mice ruled out an exclusive role for TEA in the overall accessibility of the J alpha cluster. However, the rearrangement of the most 5' J alpha (J alpha 61 to J alpha 53) was severely impaired, indicating that TEA may control the DNA accessibility of a particular J alpha window. Moreover, the relative usage of every J alpha segment was affected. These results are consistent with TEA acting as a "rearrangement-focusing" element, targeting the primary waves of V alpha-J alpha recombination to the most 5' J alpha S in an ongoing TCR-J alpha rearrangement model.

Sequences affecting the V(D)J recombinational activity of the IgH intronic enhancer in a transgenic substrate.

The immunoglobulin heavy chain intronic transcriptional enhancer (E mu) is part of a complex cis-regulatory DNA region which has notably been shown to modulate V(D)J rearrangements of associated variable gene segments. We have used recombination substrates comprised of the E mu enhancer together with various lengths of additional downstream mu sequences to assess the individual contribution of those sequences to the V(D)J recombinational regulatory activity. Surprisingly, in the absence of large amounts of mu sequences, substrate rearrangements were not detected in Southern blot analyses of the lymphoid tissues from independent transgenic mice, but were readily detectable following transfection into cultured pre-B cells. A short mu segment which includes matrix association regions (MARs) was not sufficient to restore high levels of rearrangements within the reporter transgenes. However, additional experiments demonstrated that the mu sequences are dispensable for V(D)J recombination in transgenic thymuses, implying a suppressive effect exerted by the vector sequences left in the transgenic insert, when they are attached near the E mu regulatory region. This suppression of V(D)J recombination, which correlates with an hypermethylation of the transgenes, is discussed in view of previously reported transgenic and gene targeting experiments.

Thy-1 supports adhesion of mouse thymocytes to thymic epithelial cells through a Ca2(+)-independent mechanism.

The aim of this study was to explore whether Thy-1, like other members of the Ig-like superfamily (e.g., CD2 and neural cell adhesion molecule), participates in cell-cell adhesion. This was investigated by measuring the binding of Thy-1+ probe cells (thymocytes or AKR1 T lymphoma cells) to Thy-1- cloned mouse thymic epithelial (MTE) cells using a quantitative cell adhesion assay. The results were as follows: (a) the thymo-epithelial cell interaction was found to be inhibitable (by 25-40%) by soluble Thy-1 molecules purified from phosphatidylinositol-specific phospholipase C-treated mouse thymocytes as well as by Fab' fragments of a Thy-1-specific mAb; (b) the binding of the Thy-1- AKR1 (Thy-1-d) mutant to MTE cells was found to be reduced (by 50%) as compared with that of the wild type T lymphoma; (c) the Thy-1-mediated adhesion pathway did not require Ca2+ and promoted the initial thymo-epithelial binding measured at 4 degrees C. These data provide the first direct evidence of an adhesive function of Thy-1 and suggest that this molecule, in addition to its T cell triggering properties, might play a role during the early T cell maturation by promoting thymocyte adhesion to thymic stroma.

The major parasite surface antigen associated with human resistance to schistosomiasis is a 37-kD glyceraldehyde-3P-dehydrogenase.

Schistosomiasis, due to Schistosoma mansoni, is a major health problem in many subtropical countries, and major efforts are being made to define a vaccine. In this regard, we have reported that sera from subjects with low susceptibility to infection by S. mansoni react with a major larval surface antigen (P-37), having an apparent molecular mass of 37 kD, against which sera of susceptible individuals show little reactivity. We have now cloned the cDNA for this antigen by screening a schistosome cDNA expression library with antibodies against the purified protein. The selected cDNAs encode a protein that is specifically identified by immune human sera containing antibodies against P-37, while sera exhibiting low or no reactivity toward P-37 fail to recognize the recombinant protein. The cloned cDNAs hybridize with a 1.2-kb RNA that is the transcript of a single copy gene. This RNA directs the synthesis of a 36.5-kD polypeptide that is precipitated by sera from the most resistant subjects. The amino acid sequence of the encoded polypeptide shows homology with the glycolytic enzyme Glyceraldehyde-3P-dehydrogenase (72.5% of positional identity with human Glyceraldehyde-3P-dehydrogenase). Antibodies against the recombinant protein identified P-37 on the larva. These findings, together with other reports, indicate that a number of conserved proteins may be major targets of host-protective immunity against S. mansoni. The hypothesis is discussed that genetic restriction of the immune response to these antigens may occur in heterogeneous human populations because of the limited number of T cell epitopes carried by these host-like proteins. Such genetic effects might allow parasite transmission through nonresponder (susceptible) individuals. This hypothesis and the protective properties of P-37 can now be tested using the recombinant protein and synthetic peptides derived from selected regions of the polypeptide chain.

Human resistance to Schistosoma mansoni is associated with IgG reactivity to a 37-kDa larval surface antigen.

The aim of this work was to determine whether human resistance to Schistosoma mansoni was associated with increased antibody reactivity to certain larval surface Ag. To this end, young residents of a hyperendemic area were selected for their low or high susceptibility to reinfection after parasitologic cure, and the reactivity of their sera to individual larval surface Ag was determined at different times before and after treatment. The data showed that six Ag: 202, 165, 90 to 92, 85, 72, and 37 kDa are the principal targets on the larva of IgG in the sera of resistant subjects. The comparative study, by immunoblotting and ELISA on purified Ag, of the sera from high and low susceptibility subjects indicates that IgG reactivity toward the 37-kDa Ag may be associated with resistance. This work and ongoing vaccination trials carried out in mice suggest that the 37-kDa Ag may have vaccinating potentials.

Analysis of the expression of cloned HLA class I genes in mouse transfected L cells by quantitative flow cytometry.

By using a calibrated cell sorter and monoclonal antibodies conjugated to fluorochromes, a quantitative analysis of the levels of expression of HLA class I molecules at the surface of cloned murine L cells transfected with purified A3, B7, or CW3 genes was performed and compared with radioimmunoassay data. We selected clones of heterogeneous levels of HLA class I expression, which were shown to remain constant over a period of 4 mo in absence of HAT selection and not to be correlated to the DNA copy number of the corresponding integrated gene.

The association between murine beta 2-microglobulin and HLA class I heavy chains results in serologically detectable conformational changes of both chains.

HLA-A3-, HLA-B7-, and HLA-CW3-transfected L cells, maintained in medium supplemented with murine serum so as to ensure that the human heavy chains were associated with murine beta 2-microglobulin, were subjected to a systematic serologic analysis for an evaluation of the structural consequences of such an heterologous association. The hybrid molecules exhibited alterations of their serologic reactivities that suggest the occurrence of structural modifications of both light and heavy chains. Thus, reactivity of HLA-A3-, HLA-B7-, and HLA-Cw3-transfected L cells with a monoclonal antibody (B1.1G6) directed at a human beta 2-microglobulin specific antigenic determinant was observed; this implies structural modifications of murine beta 2-microglobulin after its association with HLA class I heavy chains. Conversely, a profound reduction of the reactivity of the same transfectants with a monoclonal antibody (W6/32) directed at a monomorphic heavy chain related epitope was observed. The W6/32 reactivity was restored after replacement of the murine by the human light chain, indicating that the conformation adopted by the HLA class I heavy chain depends on the origin of the beta 2-microglobulin associated. Therefore it appears that the complex interactions that develop between the extracellular domains (including the one formed by the light chain) markedly influence the overall structure and the antigenic properties of HLA class I molecules.

HLA class I genes: from structure to expression, serology and function.

HLA class I genes have been isolated from phage and cosmid libraries and assayed by transfection into murine L cells. The transfection step proved to be very important because of the large number of genes (and pseudogenes) in this family. All functional genes characterized so far in this way are "classical" class I genes, i.e. members of the HLA-A, -B or -C families. Three of these have been sequenced (HLA-A3, -Aw24; HLA-Cw3) in addition to the pHLA 12.4 pseudogene. Sequence comparisons indicate, in particular, extreme conservation of the 3' non-coding region between allelic HLA-A locus genes; the general organization of all these genes (8 exons) is very similar. Restriction mapping around the functional genes has been performed to investigate the degree of conservation (e.g. between HLA-A3 regions from 2 different individuals) and examine allelism at the DNA level (e.g. between HLA-A3 and HLA-Aw24 regions). Exon shuffling experiments followed by serological analysis of the expressed product indicate that, as expected, specificities are determined by the first two domains of the molecule. However, further constructs show that as soon as a single exon is exchanged most specific reactivities disappear. CTL analysis of murine cells expressing HLA molecules has run into many difficulties but still holds promise for the study of structure-function relationships in this system.

Delineation of three subsets of class I human T antigens (HTA) on Molt-4 cells: serologic and regulatory relationship to HLA class I antigens.

Three subsets of class I human T antigens (HTA) were serologically identified on the surface of the Molt-4 T lymphoma cell line. The HTA 1 subset is defined by NAI/34, D47, or 10H3.9 cross-reactive m.Ab. and by BL6 m.Ab. The HTA 2 and HTA 3 subsets are defined by M241 and 4A7.6 m.Ab., respectively. We obtained no evidence of any additional HTA subset. The different HTA antigens share only few epitopes with human leukocyte antigens (HLA-A, -B, and -C). Interestingly, these epitopes all belong to the same cluster defined on HLA class I molecules, but differ from one HTA subset to another. These results would therefore suggest that HTA and HLA class I antigens display a limited structural homology, but have a conserved epitopic area whose detailed structure differs for each HTA subset. Furthermore, the cell surface expression of each HTA class I molecule type is differently enhanced by natural interferon (IFN)-alpha or -gamma. This result additionally supports the serologic delineation of HTA subsets, and suggests that the corresponding genes in Molt-4 cells, are subjected to distinct regulations.

Altered structure of HLA class I heavy chains associated with mouse beta-2 microglobulin.

The serological reactivities of HLA-A3, -B7, and -CW3 heavy chains associated with either mouse, bovine, or human beta-2-microglobulin (beta 2m) and expressed on the surface of transfected mouse fibroblasts were analyzed. All reactivities associated with one cluster (defined by monoclonal antibody W6/32) of antigenic determinants expressed by these HLA class I molecules were lost, or profoundly reduced, after each heavy chain associated with mouse beta 2-m. Expression by the transfected fibroblasts of the HLA-A3, -B7, and -CW3 heavy chains in association with human beta 2m restores these reactivities. Since most of the amino acid differences between mouse and human beta 2m probably correspond to externally oriented hydrophilic residues, these results suggest that critical interactions in the three-dimensional structure of HLA class I molecules occur between the light chain and the first two external domains of the class I heavy chains, to which some of the altered reactivities have been mapped.

Expression of an HLA-Bw6-related specificity by the HLA-Cw3 molecule.

Radioimmunoassay of HLA-transformed mouse L cells expressing A3, A24, B7, or Cw3 HLA class I molecules with a set of monomorphic monoclonal antibodies distinguishes between A3-A24 and B7-Cw3 patterns of reactivity. Analyses with Bw6-specific monoclonal antibodies and a human alloantiserum demonstrate the expression by the HLA-Cw3 molecules of a Bw6 public specificity related to but not identical with that expressed by the HLA-B7 molecules. Exon-shuffling experiments and inhibition studies of monoclonal antibody cell-surface fixation indicate that similar parts of B7 and Cw3 molecules account for their serological cross-reactivity.

Transformation of LMTK- cells with purified HLA class I gene. VI. Serological characterization of HLA-B7 and AW24 molecules.

Serological characterization of HLA-B7 and HLA-AW24 class I molecules following transfection of murine LMTK- cells with purified HLA class I genes was performed using human alloantisera. Induction by murine alpha interferon of the expression of class I molecules was required to obtain unambiguous identification of these molecules which appear serologically identical to the HLA-B7 and HLA-AW24 molecules expressed at the surface of human peripheral blood lymphocytes of 20 unrelated individuals. Analysis of the transformed cells with 8 different anti-HLA class I monoclonal antibodies results in the definition of 3 separate clusters of antigenic determinants shared by all HLA class I molecules. These studies further suggest the existence of locus-specific serological reactivities associated either with the HLA-A or with the HLA-B and C gene products.

Transformation of LMTK- cells with purified class I genes. V. Antibody-induced structural modification of HLA class I molecules results in potentiation of the fixation of a second monoclonal antibody.

A potentiation phenomenon was observed with HLA-A3 and CW3 transformed murine L cells between anti-HLA class I B10.6 (potentiated) and B10.8 (potentiating) monoclonal antibodies (m.Ab.). Further studies of this phenomenon with these transformed L cells indicated that: 1) no significant specific binding of B10.6 m.Ab. to HLA-A3 and CW3 transformed L cells could be demonstrated by conventional radioimmunoassay or cytofluorometric study in the absence of B10.8 m.Ab.; 2) potentiation of the fixation of B10.6 m.Ab. was induced by other anti-HLA class I m.Ab., which all reacted with the same cluster of antigenic determinants; 3) potentiation reflects an increased specific fixation of B10.6 m.Ab. to HLA class I molecules implicating its combining site; 4) potentiation was mediated by B10.8 Fab fragments. These results indicate that potentiation of the fixation of B10.6 m.Ab. to the HLA-A3 and CW3 molecules expressed by the transformed L cells reflects conformational changes of these molecules after interaction with B10.8 m.Ab.

Absence of cell surface fixation of a monoclonal antibody detectable by conventional immunoassays does not exclude expression of and interaction with the corresponding antigenic determinant.

No specific binding of anti-HLA class I B.10.6 monoclonal antibody (mAb) could be demonstrated by cell surface radioimmunoassay and cytofluorographic studies at the surface of murine transformed L cells expressing HLA-A3 or Cw3 molecules. However, specific interaction of this antibody with these molecules at the surface of these transformed cells was indirectly established, since it inhibited specifically the binding to the same HLA class I molecules of other anti-HLA class I mAb. Therefore, the absence of detectable binding of mAb, in conventional immunoassays, does not exclude expression by these cells of the corresponding antigenic determinant.

Transformation of murine LMTK- cells with purified HLA class I genes. I. Modification of conformation of murine beta 2-microglobulin upon its association with HLA heavy chains.

Murine LMTK- cells were unexpectedly found to cross-react with a murine anti-human beta 2-microglobulin (beta 2-m)monoclonal antibody (m.Ab) after transformation with cosmid clones containing different purified HLA class I genes. The same cross-reactivity was observed with CTP 34 B4 (murine x human) somatic hybrid cells, which express class I molecules constituted of human HLA heavy chains and murine beta 2-m. Inhibition studies of the complement-dependent cytolysis mediated by the cross-reacting m.Ab indicated that isolated murine beta 2-m does not express the cross-reacting determinant, suggesting that its expression by the transformed cells reflects conformational modification of murine beta 2-m upon its association with HLA heavy chains. These results illustrate one of the possible post-translational mechanisms through which the antigenicity of a polypeptide chain can be modified. They might provide a serologic marker of the third domain of HLA class I heavy chains. Finally, because quantitative differences of reactivity with the anti-human beta 2-m m.Ab were observed, depending on the HLA class I genes used for transformation, these results individualize two families of HLA class I heavy chains responsible for different conformational modifications of murine beta 2-m.

Transformation of LMTK- cells with purified HLA class I genes. II. Serologic characterization of HLA-A3 and CW3 molecules.

The expression of two different HLA class I genes was observed after transformation of LMTK- cells. The corresponding class I molecules reacted differentially with monomorphic monoclonal antibodies (m.Ab). Absorption and elution studies of the human alloantibodies reacting with the transformed cells and cellular radioimmunoassay of these cells with polymorphic m.Ab resulted in the identification of HLA-A3 and CW3 molecules. These transformed cells were used to immunize C3H mice and induce the production of xenogeneic antisera, which, following absorption, showed polymorphic reactivity with human cells, suggesting that some of these sera could be used as typing reagents.