The mouse DNA binding protein Rc for the kappa B motif of transcription and for the V(D)J recombination signal sequences contains composite DNA-protein interaction domains and belongs to a new family of large transcriptional proteins.

Rc is a DNA binding protein with dual specificities for the V(D)J recombination signal sequences and for the B motif of the immunoglobulin kappa chain gene enhancer. The largest Rc transcript present in lymphoid cells/tissues is approximately 9 kb. Molecular cloning and sequence determination for 8822 bp of mouse Rc cDNA revealed an open reading frame of 2282 amino acids and long 5'- and 3'-untranslated regions. The derived amino acid sequence contains multiple DNA and protein interaction domains. Composite ZAS structures with tandem zinc fingers, an acidic motif, and a Ser/Thr-rich segment are located near the N-terminal and the C-terminal regions. The middle region of Rc contains a lone zinc finger, an acidic motif, a Ser-rich region, a nucleus localization signal, and GTPase motifs. Cloning and characterization of a mouse Rc gene show that the Rc cDNA corresponds to seven exons located in a genomic region spanning 70 kb. Exon 2 is exceptionally large, with 5487 bp. cDNA cloning and Northern blot analyses revealed multiple Rc transcripts, probably generated by alternative splicings. Sequence comparisons show that Rc belongs to a ZAS protein family that is involved in gene transcription and/or DNA recombination. The major histocompatibility complex class I gene enhancer binding proteins MBP1 and MBP2 are other representatives of this ZAS protein family.

The V(D)J recombination signal sequence and kappa B binding protein Rc binds DNA as dimers and forms multimeric structures with its DNA ligands.

The murine DNA binding protein Rc binds to the heptamer motif of the V(D)J recombination signal sequences and to the kappa B motif of the immunoglobulin enhancer. Bacterial fusion proteins for Rc and DNA ligands of Rc form multiple protein-DNA complexes in electrophoretic mobility shift assays (EMSA). Large complexes formation is favored by an increased Rc concentration. In order to determine the architecture of these complexes, the apparent molecular weights of the protein-DNA complexes were first determined by their gel mobilities. The data suggest that Rc binds to its DNA ligands as dimers, tetramers, and multiples of tetramers. The inference that Rc binds DNA as dimers was substantiated by the formation of chimeric complexes when two electrophoretically distinguishable Rc proteins were employed in EMSA. Methylation interference experiments show that there are no contiguous protein binding sites evident in the DNA of the larger complexes. Apparently, multimerization occurs via protein-protein interactions. Such interaction was demonstrated by the formation of Rc dimers and tetramers in a chemical crosslinking experiment. Significantly, the multimerization of DNA-bound Rc could be involved in bringing the variable region gene segments together for the somatic V(D)J recombination.

Derepression of HPRT locus on inactive X chromosome of human lymphoblastoid cell line.

Human XX lymphoblastoid cells with a deletion in the HPRT locus on the active X were exposed to HPRT clone pHPT32. HPRT+ isolates GPT3 and GPT5 lacked pHPT32 DNA, suggesting that their HPRT+ phenotype resulted from expression of a cellular gene. GPT3 mutated to thioguanine resistance at least 100 times more frequently than cells in which the expressed HPRT locus was on the active X. Most GPT3-derived HPRT- had lost one entire X chromosome, indicating that the HPRT+ phenotype of GPT3 resulted from derepression of the HPRT locus on its inactive X. Virtually unchanged G6PD and PGK activities and the presence of a late-replicating X in GPT3 suggest that derepression of the inactive X was not general. Eleven of the GPT3-derived mutants had a tiny centric remnant that may result from a frequently operative mechanism of X chromosome loss. The detection of partial or complete loss of an X by direct selection presents unusual opportunities for genotoxicity detection with human cells.

Mutations that impair a posttranscriptional step in expression of HLA-A and -B antigens.

Mutations can interfere with posttranscriptional expression of the HLA-A and -B genes. B-lymphoblastoid cells that contain one copy of the major histocompatibility complex (MHC) were subjected to mutagenesis and immunoselection for MHC antigen-loss mutants. Some mutations partially reduced surface expression of HLA-A and eliminated HLA-B expression concurrently, although the HLA-A and -B genes were present and transcribed. Antigen expression was fully restored in hybrids of these mutants with other B-lymphoblastoid cells. Therefore, normal cell surface expression of the HLA-A and -B antigens on B lymphoblasts requires (i) execution of at least one trans-active step in the production of the antigens after transcription of the HLA-A and -B genes or (ii) association of the class I antigens with other molecules. DNA analysis of one mutant suggests the possibility that a locus required for the normal expression of the HLA-A and -B antigens is located between the MHC complement genes and the HLA-DP alpha II locus.