Identification and characterization of a beta-globin promoter-binding factor from murine erythroleukemia cells.

We have identified a DNA-binding activity with specificity for the beta DRE, an evolutionarily conserved transcriptional regulatory element in mammalian adult beta-globin promoters. This binding activity, which we term beta DRf, for beta-globin direct repeat factor, was detected in fractionated nuclear extracts from the murine erythroleukemia cell line and has been partially purified from undifferentiated cells. beta DRf makes symmetric contacts on the two copies of its recognition sequence on both strands and introduces a bend into the DNA helix upon binding. While the factor displays a low binding affinity for the beta DRE in isolation, it binds to the intact beta-globin promoter and DNA fragments containing multiple beta DRE-binding sites with high affinity. A correlation between beta DRf binding affinity and transcriptional activity of beta DRE mutant promoters suggests that this factor stimulates transcription of the beta-globin promoter in vivo.

A directly repeated sequence in the beta-globin promoter regulates transcription in murine erythroleukemia cells.

We have identified a previously undetected cis-acting element in the mouse beta-major globin promoter region that is necessary for maximal transcription levels of the gene in the inducible preerythroid murine erythroleukemia (MEL) cell line. This element, termed the beta-globin direct-repeat element (beta DRE), consists of a directly repeated 10-base-pair sequence, 5'-AGGGCAG(G)AGC-3', that lies just upstream from the TATA box of the promoter. The beta DRE motif is highly conserved in all adult mammalian beta-globin promoter sequences known. Mutation of either single repeat alone caused less than a twofold decrease in transcript levels. However, simultaneous mutation of both repeated regions resulted in a ninefold decrease in accumulated transcripts when the gene was transiently transfected into MEL cells. Attachment of the beta DRE to a heterologous promoter had little effect on levels of accumulated transcripts initiated from the promoter in undifferentiated MEL cells but resulted in a threefold increase in transcript levels in induced (differentiated) MEL cells. Similarly, a comparison of the relative effects of mutations in the beta DRE in uninduced and induced MEL cells indicated that the element was more active in induced cells. The increase in beta DRE activity upon MEL cell differentiation and the more pronounced effects of mutations in both repeats of the beta DRE have implications for the mechanism of action of the element in regulating beta-globin transcription and for mutational studies of other repetitive or redundant transcription elements.

Expression of cell-associated and secreted forms of herpes simplex virus type 1 glycoprotein gB in mammalian cells.

The gene for glycoprotein gB1 of herpes simplex virus type 1 strain Patton was expressed in stable Chinese hamster ovary cell lines. Expression vectors containing the dihydrofolate reductase (dhfr) cDNA plus the complete gB1 gene or a truncated gene lacking the 194 carboxyl-terminal amino acids of gB1 were transfected into CHO DHFR-deficient cells. Radioimmunoprecipitation demonstrated that the complete gB1 protein expressed in CHO cell lines was cell associated, whereas the truncated protein was secreted from the cells due to deletion of the transmembrane and C-terminal domains of gB1. Cells expressing the truncated gB1 protein were subjected to stepwise methotrexate selection, and a cell line was isolated in which the gB1 gene copy number had been amplified 10-fold and the level of expression of gB1 had increased over 60-fold. The truncated gB1 protein was purified from medium conditioned by the amplified cell line. N-terminal amino acid sequence analysis of this purified protein identified the signal peptide cleavage site and predicted the cleavage of a 30-amino-acid signal sequence from the primary protein. The immunogenicity of the truncated gB1 protein was also tested in mice, and high levels of antibody and protection from virus challenge were observed.

Structure and expression of the herpes simplex virus type 2 glycoprotein gB gene.

The gene for glycoprotein gB2 of herpes simplex virus type 2 strain 333 was cloned, sequenced, and expressed in mammalian cells. The gB2 protein had an overall nucleotide and amino acid sequence homology of 86% with the cognate gB1 protein. However, of the 125 amino acid substitutions or deletions, only 12.5% were conservative replacements. These differences were clustered within an NH2-terminal region, a central region, and a COOH-terminal region, resulting in domains of near identity broken by small regions of marked divergence. Regions of greatest homology included a 90-amino-acid stretch starting at residue 484 and 39 amino acids spanning residues 835 to 873, which cover a rate-of-entry locus mapped to Ala-552 and a syn locus mapped to Arg-857, respectively, in gB1 by Bzik et al. (D. J. Bzik, B. A. Fox, N. A. DeLuca, and S. Person, Virology 133:301-314, 1984). Pellett et al. (P. E. Pellett, K. G. Kousoulas, L. Pereira, and B. Roizman, J. Virol. 53:243-253, 1985) mapped the mutations in three monoclonal antibody-resistant gB1 mutants between amino acids 273 and 443. These epitopes are included in a region of 98 residues identical between gB1 and gB2. The identity of this protein was verified by placing a truncated gene lacking the 303 carboxyl-terminal amino acids of gB2 into mammalian COS and CHO cells. Expression was demonstrated by immunofluorescence and radioimmunoprecipitation. This protein will be purified from the stable CHO cell lines and compared with gB1 for immunogenicity and protective efficacy in animal challenge models.

Characterization of corticotropin receptors in human adrenocortical cells.

[125I-Tyr23,Phe2,Nle4]ACTH-(1-38) ([125I]ACTH analog), which is equipotent with ACTH, was used to characterize ACTH receptors in human adrenocortical cells. Adrenals were obtained from brain-dead patients at the time of renal harvest with permission. Binding of [125I]ACTH analog to human adrenocortical cells was highly specific, rapid, reversible, and saturable. Analysis of the inhibition of binding of [125I]ACTH analog by ACTH was compatible with a single class of binding sites with an apparent dissociation constant (Kd) of 1.6 nM and a mean binding capacity of 3560 sites/cell. Concentration-response curves for cAMP and cortisol production were shifted to the left of the binding curve, with ACTH concentrations required for half-maximal stimulation being 20- and 720-fold less, respectively, than those for binding. Extracellular calcium was essential for binding and stimulation of cAMP production. These results indicate that human adrenocortical cells contain a single class of ACTH receptors which are highly similar in affinity, capacity, and calcium requirement to those of rat adrenocortical cells, but differ from the rat receptors in the concentration of ACTH needed for cAMP generation.

A fluorescence study of the binding of poly(1,N6-ethenoadenylic acid) to Escherichia coli initiation factor 3.

The binding of initiation Factor 3 (IF3) to poly (1,N6-ethenoadenylic acid) [poly(epsilon A)] was investigated by fluorescence spectroscopy. At low salt concentrations, IF3 evokes an increase in the fluorescence intensity of poly(epsilon A) due to the unstacking of the nucleotide bases. The poly(epsilon A) fluorescence enhancement titrates to an endpoint of 13 +/- 2 nucleotide residues per IF3. The maximum poly(epsilon A) fluorescence enhancement, at lattice saturation, decreases with increasing salt concentration. Even though IF3 does not produce a large fluorescence increase between 75 and 200 mM NaCl concentration, the protein still binds to poly(epsilon A) at these salt concentrations as measured by sedimentation partition chromatography; the value of Kobs for the IF3-poly(epsilon A) interaction is comparable to that of other synthetic polynucleotides. The binding of IF3 to poly(A) at 150 and 200 mM NaCl induces an increase in nucleotide base-base separation as determined by CD, yet IF3-induced disruption of base stacking of poly(epsilon A) at these same salt concentrations is not detected by fluorescence. It is likely that IF3 binds primarily to the phosphate backbone of poly(epsilon A) at low salt concentrations, producing an increase in the fluorescence intensity. But, at higher salt concentrations, the aromatic amino acids intercalate between the nucleotide bases quenching the poly(epsilon A) fluorescence.