The effects of HPFH mutations in the human gamma-globin promoter on binding of ubiquitous and erythroid specific nuclear factors.

Genetic evidence indicates that single point mutations in the gamma-globin promoter may be the cause of high expression of the mutated gene in the adult period (Hereditary Persistence of Fetal Hemoglobin, HPFH). Here we show that one of these mutations characterized by a T----C substitution at position -175 in a conserved octamer (ATGCAAAT) sequence, abolishes the ability of a ubiquitous octamer binding nuclear protein to bind a gamma-globin promoter fragment containing the mutated sequence; however, the ability of two erythroid specific proteins to bind the same fragment is increased three to five fold. DMS interference and binding experiments with mutated fragments indicate that the ubiquitous protein recognizes the octamer sequence, while the erythroid specific proteins B2, B3 recognize flanking nucleotides. Competition experiments indicate that protein B2 corresponds to an erythroid-specific protein known to bind to a consensus GATAG sequence present at several locations in alpha, beta and gamma-globin genes. Although the distal CCAAT box region of the gamma-globin gene shows a related sequence, an oligonucleotide including this sequence does not show any ability to bind the above mentioned erythroid protein; instead, it binds a different erythroid specific protein, in addition to a ubiquitous protein. The -117 G----A mutation also known to cause HPFH, and mapping two nucleotides upstream from the CCAAT box, greatly decreases the binding of the erythroid-specific, but not that of the ubiquitous protein, to the CCAAT box region fragment.     

Direct interactions of Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 ORF50/Rta protein with the cellular protein octamer-1 and DNA are critical for specifying transactivation of a delayed-early promoter and stimulating viral reactivation

The Kaposi's sarcoma-associated herpesvirus (KSHV) delayed-early K-bZIP promoter contains an ORF50/Rta binding site whose sequence is conserved with the ORF57 promoter. Mutation of the site in the full-length K-bZIP promoter reduced Rta-mediated transactivation by greater than 80%. The K-bZIP element contains an octamer (Oct) binding site that overlaps the Rta site and is well conserved with Oct elements found in the immediate-early promoters of herpes simplex virus type 1(HSV-1). The cellular protein Oct-1, but not Oct-2, binds to the K-bZIP element in a sequence-specific fashion in vitro and in vivo and stimulates Rta binding to the promoter DNA. The coexpression of Oct-1 enhances Rta-mediated transactivation of the wild type but not the mutant K-bZIP promoter, and Oct-1 and Rta proteins bind to each other directly in vitro. Mutations of Rta within an amino acid sequence conserved with HSV-1 virion protein 16 eliminate Rta's interactions with Oct-1 and K-bZIP promoter DNA but not RBP-Jk. The binding of Rta to both Oct-1 and DNA contributes to the transactivation of the K-bZIP promoter and viral reactivation, and Rta mutants deficient for both interactions are completely debilitated. Our data suggest that the Rta/Oct-1 interaction is essential for optimal KSHV reactivation. Transfections of mouse embryo fibroblasts and an endothelial cell line suggest cell-specific differences in the requirement for Oct-1 or RBP-Jk in Rta-mediated transactivation of the K-bZIP promoter. We propose a model in which Rta transactivation of the promoter is specified by the combination of DNA binding and interactions with several cellular DNA binding proteins including Oct-1.     

A common RNA recognition motif identified within a defined U1 RNA binding domain of the 70K U1 snRNP protein

We have defined the RNA binding domain of the 70K protein component of the U1 small nuclear ribonucleoprotein to a region of 111 amino acids. This domain encompasses an octamer sequence that has been observed in other proteins associated with RNA, but has not previously been shown to bind directly to a specific RNA sequence. Within the U1 RNA binding domain, an 80 amino acid consensus sequence that is conserved in many presumed RNA binding proteins was discerned. This sequence pattern appears to represent an RNA recognition motif (RRM) characteristic of a distinct family of proteins. By site-directed mutagenesis, we determined that the 70K protein consists of 437 amino acids (52 kd), and found that its aberrant electrophoretic migration is due to a carboxy-terminal charged domain structurally similar to two Drosophila proteins (su(wa) and tra) that may regulate alternative pre-messenger RNA splicing.     

Unexpected flexibility in an evolutionarily conserved protein-RNA interaction: genetic analysis of the Sm binding site

Human autoantibodies of the Sm specificity recognize a conserved set of proteins found in the U class small nuclear ribonucleoproteins (U snRNPs), key trans-acting factors involved in the splicing of mRNA precursors. The Sm protein binding site in U snRNAs is unusual because of its single-stranded nature and its simple sequence motif (AU5-6GPu). Here we use genetics to probe this specific protein-RNA interaction by saturation mutagenesis of the Sm binding site of the Saccharomyces cerevisiae U5 snRNA. The assay system used to analyze these mutations takes advantage of a conditionally expressed U5 gene which does not support growth under non-permissive conditions; U5 genes containing Sm site mutations were tested for their ability to complement this lethal phenotype. Our results indicate that the Sm binding site is remarkably tolerant to mutation despite its high degree of conservation, suggesting that relatively few or redundant specific contacts can determine recognition of single-stranded RNA by protein. A complementary biochemical analysis of these mutants demonstrates that integrity of the Sm site is necessary for snRNP stability in vivo and in vitro.