A transcript map of a 2-Mb BAC contig in the proximal portion of the mouse X chromosome and regional mapping of the scurfy mutation.

A physical clone contig has been constructed, spanning 2 Mb on the proximal mouse X chromosome containing the mouse scurfy (sf) and tattered (Td) mutations. Extensive transcript mapping in this interval has identified 37 potential transcription units, including a number of novel genes, and 4 pseudogenes. These genes have been ordered by STS content and restriction mapping. Comparison of the transcript map to the corresponding region in human Xp11.23-p11.22 shows extensive homology, with complete conservation of gene order for loci in common between the two maps. Further, using a novel method to identify simple sequence length polymorphisms, we have developed a number of genetic markers, which has enabled the region containing the sf mutation to be narrowed to <300 kb. This contig has already allowed the cloning of the Td gene using a candidate gene approach and now serves as a starting point for the cloning of the sf mutation.

Ox40-ligand has a critical costimulatory role in dendritic cell:T cell interactions.

The tumor necrosis factor family molecule Ox40-ligand (Ox40L) has been identified as a potential costimulatory molecule and also has been implicated in T cell homing and B cell activation. To ascertain the essential functions of Ox40L, we generated and characterized Ox40L-deficient mice. Mice lacking Ox40L exhibit an impaired contact hypersensitivity response, a dendritic cell-dependent T cell-mediated response, due to defects in T cell priming and cytokine production. In contrast, Ox40L-deficient mice do not have defects in T cell homing or humoral immune responses. In vitro, Ox40L-deficient dendritic cells are defective in costimulating T cell cytokine production. Thus, Ox40L has a critical costimulatory function in vitro and in vivo for dendritic cell:T cell interactions.

Molecular characterization of murine and human OX40/OX40 ligand systems: identification of a human OX40 ligand as the HTLV-1-regulated protein gp34.

A ligand was cloned for murine OX40, a member of the TNF receptor family, using a T cell lymphoma cDNA library. The ligand (muOX40L) is a type II membrane protein with significant identity to human gp34 (gp34), a protein whose expression on HTLV-1-infected human leukemic T cells is regulated by the tax gene. The predicted structures of muOX40L and gp34 are similar to, but more compact than, those of other ligands of the TNF family. Mapping of the muOX40L gene revealed tight linkage to gld, the FasL gene, on chromosome 1. gp34 maps to a homologous region in the human genome, 1q25. cDNAs for human OX40 receptor were cloned by cross-hybridization with muOX40, and gp34 was found to bind the expressed human receptor. Lymphoid expression of muOX40L was detected on activated T cells, with higher levels found on CD4+ rather than CD8+ cells. The cell-bound recombinant ligands are biologically active, co-stimulating T cell proliferation and cytokine production. Strong induction of IL-4 secretion by muOX40L suggests that this ligand may play a role in regulating immune responses. In addition, the HTLV-1 regulation of gp34 suggests a possible connection between virally induced pathogenesis and the OX40 system.

The mouse Fas-ligand gene is mutated in gld mice and is part of a TNF family gene cluster.

The gene for the mouse Fas ligand was cloned and its chromosomal position determined. Fasl was tightly linked to gld (no crossovers in 567 meiotic events) on mouse chromosome 1 and closely linked with a novel member of the same TNF family of ligands, the Ox40 ligand (Ox40l, 1 crossover in 567 meiotic events). Southern blot analysis did not reveal any difference between the Fasl gene from gld and wild-type mice and levels of Fasl mRNA transcripts were similar in PMA and ionomycin induced wild-type and coisogenic gld T cells. Sequence analysis of the gld gene indicated a single amino acid change (Phe Leu) in the COOH terminal portion of this type II transmembrane protein, and COS cells transfected with Fasl cDNA from gld mice failed to induce apoptosis of Fas-expressing target cells. Thus, the data demonstrate that the gld phenotype is the result of a point mutation in the Fasl gene and that Fasl is part of a complex of ligands structurally related to TNF mapping within a small region of mouse chromosome 1.

Induction of B cell costimulatory function by recombinant murine CD40 ligand.

T cell-dependent regulation of B cell growth and differentiation involves an interaction between CD40, a B cell surface molecule, and the CD40 ligand (CD40L) which is expressed on activated CD4+ T cells. In the current study, we show that recombinant membrane-bound murine CD40L induces B cells to express costimulatory function for the proliferation of CD4+ T cells. CD40L- or lipopolysaccharide (LPS)-activated, but not control-cultured B cells were strong costimulators of anti-CD3 or alloantigen-dependent T cell responses. The molecular interactions responsible for the increased costimulatory functions were examined by analyzing the activated B cells for changes in the expression of two costimulatory molecules, B7 and heat-stable antigen (HSA), as well as by the use of antagonists of B7 and HSA (CTLA4.Fc and 20C9, respectively). The expression of both B7 and HSA was enhanced on B cells activated with LPS. As observed in previous studies, the costimulatory activity of the LPS-activated B cells was dependent on both B7 and HSA and was completely inhibited in the presence of a combination of CTLA4.Fc and 20C9. In contrast, activation of B cells with CD40L induced the expression of B7 but did not enhance the expression of HSA. In addition the costimulatory activity of the CD40L-activated B cells was partially, but not completely, inhibited by the combination of CTLA4.Fc and 20C9. These results demonstrate that CD40L regulates costimulatory function of B cells in part by inducing the expression of B7 and suggest that CD40L-activated B cells express an additional costimulatory activity that is not associated with LPS-activated B cells.

Molecular cloning and characterization of a novel receptor protein tyrosine kinase from human placenta.

Using a polymerase chain reaction-based approach we have isolated and characterized a cDNA (HPK-6) from human placental RNA encoding a novel receptor protein tyrosine kinase. This receptor tyrosine kinase has a unique extracellular domain, with an immunoglobulin-like domain at the amino terminus followed by three EGF-like cysteine repeats and three fibronectin type III repeats, giving the HPK-6 gene extracellular domain a novel combination of structural motifs. A comparison of the HPK-6 sequence with other receptor tyrosine kinases shows that the HPK-6 gene is the human homolog of the murine tek gene and very closely related to the recently described receptor tyrosine kinase tie. The HPK-6 gene is expressed predominantly in placenta and lung, with a lower level in umbilical vein endothelial cells, brain and kidney. The HPK-6 cDNA, when transfected into COS-7 cells, encodes a 140-kDa protein with in vitro kinase activity.

Simian virus 40-specific polypeptides in AD2+ ND1- and Ad2+ ND4-infected cells.

A comparison of the proteins synthesized in human cells at late times after infection with adenovirus (Ad2) and with the adeno-simian virus 40 (SV40) hybrid viruses revealed polypeptides of 30,000 and 92,000 molecular weight specific for the hybrid viruses Ad2+ND1 and Ad2+ND4, respectively. Cell-free translation of SV40-specific mRNA, prepared from these cells by hybridization of total cytoplasmic RNA to SV40 DNA, showed that the mRNA's specifying these two polypeptides were at least partially encoded by the SV40 portion of the hybrid viruses. Cell-free translation of SV40-specific mRNA prepared from monkey cells infected with SV40 produced polypeptides of 40,000, 43,000, 48,500, and 92,000 molecular weight. The SV40 and Ad2+ND4 92,000-molecular-weight polypeptides made in vitro were very similar in electrophoretic mobility in sodium dodecyl sulfate-polyacrylamide gels to the polypeptide precipitated by Tegtmeyer (1974) with SV40 anti-T serum.

Location and identification of the genes for adenovirus type 2 early polypeptides.

Virus-specific RNA was prepared from cells early after adenovirus type 2 infection and fractionated by hybridization to specific fragments of viral DNA. The viral mRNA was used to program cell-free protein synthesis, and the products were analyzed by electrophoresis. The genes for the early polypeptides of apparent molecular weight 44,000, 15,000, 72,000, 15,500, 19,000, and 11,000 daltons were located, respectively, between positions 0-4.1, 4.1-16.7, 58.5-70.7, 75.9-83.4, 89.7-98.6, and 89.7-98.6 of the conventional adenovirus DNA map. The polypeptide of molecular weight 72,000 daltons was shown to be the single-stranded DNA-binding protein described by others. RNAs from three different adeno-transformed cell lines each program the synthesis in vitro of predominantly the 15K polypeptide, as well as variable amounts of the polypeptide of molecular weight 44,000 daltons. The genes for these two polypeptides are located in the portion of DNA known to be required for transformation of rodent cells by adenovirus.

Mapping of late adenovirus genes by cell-free translation of RNA selected by hybridization to specific DNA fragments.

Cytoplasmic RNA, isolated from cells late after infection by adenovirus type 2 and fractionated by hybridization to specific fragments of adenovirus DNA produced by cleavage with the endonuclease R-EcoRI, was used as template for protein synthesis in cell-free mammalian extracts. Each of the R-EcoRI fragments of DNA selects RNA that encodes specific subsets of the viral polypeptides. From the known order of the R-EcoRI fragments, the following partial map is deduced: (III, IIIa, IVa2, V, P-VII, IX), (II, P-VI), 100K, IV-where the relative order of the components enclosed in parentheses has not yet been determined.

Processing of adenovirus 2-induced proteins.

Analysis of (35)S-methionine-labeled extracts of adenovirus 2-infected KB cells revealed 22 virus-induced polypeptide components. Most proteins of the virion were easily detected in extracts of whole cells labeled for short periods between 15 and 30 h after infection; however, several virion components were conspicuously absent. Radioactivity appeared in two of these virion components during a chase in nonradioactive medium, and this appearance was paralleled by a decrease in the radioactivity associated with two nonvirion adenovirus-induced proteins, results which imply precursor-product relationships for these components. Comparison of one of the chasable adenovirus-induced components (designated P-VII; mass of 20,000 daltons) and the major core protein (VII; mass of 18,500 daltons) of the virion showed that they have four common methionine-containing tryptic peptides; P-VII has an additional methionine residue which is not found in the major core protein. We propose that at least two of the adenovirus 2 virion components are derived by the cleavage of higher molecular weight precursor polypeptides.