A transcription factor with AP3-like binding specificity mediates gene regulation after an allergic triggering with IgE and Ag in mouse mast cells.

Mast cells are an important source of a number of lymphokines and chemokines primarily those released after challenge with the allergic trigger IgE and Ag. However, the mechanisms of lymphokine and chemokine gene activation in this cell type, as opposed to the mechanisms of activation in T cells, are poorly understood. As a model system, we addressed this issue in mast cells by using the recently cloned chemokine MARC gene, which belongs to the RANTES/sis gene family. After allergic stimulation, MARC induction is pronounced and mast cell specific. Northern blot analysis, in combination with two inhibitors, actinomycin D and cycloheximide, resulted in the formation of our initial hypothesis, which was that both transcriptional and post-transcriptional regulation are involved after stimulation through the Fc epsilon R. We performed a detailed promoter analysis of the cloned MARC gene by using transient assays of transfected reporter gene constructs. Thereby, two potential promoter regions were identified as being crucial for transcriptional stimulation. Additional fine mapping of the proximal element and subsequent electrophoretic mobility shift assays, combined with competitions of known transcription factor binding sites, identified one of the transcription factors in stimulated mast cells as an AP3 or AP3-like binding activity.

Immunoglobulin E plus antigen challenge induces a novel intercrine/chemokine in mouse mast cells.

In an attempt to characterize genes participating in the allergic late phase reaction, we have isolated a novel intercrine/chemokine (called MARC) from a cDNA library of the stimulated mouse mast cell line, CPII. As measured by Northern blotting, it is strongly upregulated at the mRNA level after the physiological challenge of the cells with immunoglobulin (Ig)E plus antigen. Unstimulated cells completely lack significant, stable expression, as do a number of other, different cell lines (uninduced and induced) and mouse tissues. In contrast to the Northern blot analysis, a polymerase chain reaction (PCR) analysis, performed on CPII cells and on Percoll gradient purified mouse peritoneal mast cells, revealed a basal level of transcription in the uninduced stage. After 2 h of IgE plus antigen challenge, a quantitative reverse transcriptase-PCR, using a spiked in MIMIC, showed a level of transcripts more than 100-fold higher in the CPII cells and 5-20-fold higher in purified mouse peritoneal cavity mast cells. This rapid induction after the Fc epsilon RI challenge, the identification of the gene as a member of the chemokine family, and its upregulated expression in peritoneal mast cells, all suggest an involvement in certain acute and chronic pathological mast cell-driven diseases.

A novel transiently expressed, integral membrane protein linked to cell activation. Molecular cloning via the rapid degradation signal AUUUA.

A novel cDNA clone termed E16 which codes for an integral membrane protein of 241 amino acids with six transmembrane domains was isolated from peripheral blood lymphocytes. The cDNA clone is 4000 base pairs in length and exhibits an unusually long 3'-untranslated region of about 3000 nucleotides. Its expression at the mRNA level is closely linked to cellular activation and division. In all myeloid and lymphoid cells, as well as in primary lymphocytes from peripheral blood, E16 transcripts are rapidly induced and rapidly degraded after stimulation. This pattern of expression is unusual for an integral membrane protein and resembles more closely the kinetic seen for protooncogenes and lymphokines in the T cell system. Its isolation was made possible by a novel approach especially designed to selectively clone cDNAs which exhibit such an expression kinetic. It is based on a combination of the differential screening of a subtracted cDNA library and the subsequent hybridization of the resulting phages to a short oligonucleotide (5'-TAAATAAA-TAAATA-3'). This oligonucleotide is complementary to a trimer of the rapid degradation signal (AUUUA) which is present as a single or reiterated motif in the 3'-untranslated region of many short-lived transcripts.

A new superfamily of lymphoid and melanoma cell proteins with extensive homology to Schistosoma mansoni antigen Sm23.

A novel cDNA clone termed R2 was isolated by subtractive hybridization of a cDNA library of phytohemagglutinin (PHA)/phorbol myristate acetate-stimulated Jurkat cells and by rescreening a cDNA library of PHA-stimulated peripheral blood lymphocytes. It hybridizes to a single mRNA species of about 2.2 kb, which is inducible in lymphoid cells and codes for a protein of 267 amino acids which contains four potential transmembrane domains. A computer-aided comparison showed strong homology to four other membrane proteins, the pan B cell marker CD37, the pan leukocyte marker CD53, the melanoma antigen ME491 and, surprisingly, the Schistosoma mansoni antigen Sm23. The four human proteins share a number of additional similarities in their overall structure. These include identical spacing of the transmembrane domains, similar hydrophobicity plots, possible N-linked glycosylation sites of similar number and position as well as similar distribution of the cysteine residues. The majority of these characteristics are still conserved in the evolutionary most distant member of this family, the Schistosoma mansoni antigen Sm23. Here we introduce this new protein superfamily and characterize the inducible, lymphoid-specific member R2.