Molecular dissection of subunit interfaces in the acetylcholine receptor: identification of residues that determine curare selectivity.

The acetylcholine receptor from vertebrate skeletal muscle is a transmembrane channel that binds nerve-released acetylcholine to elicit rapid transport of small cations. Composed of two alpha subunits and one beta, one gamma, and one delta subunit, the receptor is a cooperative protein containing two sites that bind agonists, curariform antagonists, and snake alpha-toxins. Until recently the two binding sites were thought to reside entirely within each of the two alpha subunits, but affinity labeling and expression studies have demonstrated contributions by the gamma and delta subunits. Affinity labeling and mutagenesis studies have identified residues of the alpha subunit that contribute to the binding site, but the corresponding gamma- and delta-subunit residues remain unknown. By making gamma-delta chimeras and following the nearly 100-fold difference in curare affinity for the two binding sites, the present work identified residues of the gamma and delta subunits likely to be near the binding site. Two sets of binding determinants were identified in homologous positions of the gamma and delta subunits. The determinants lie on either side of a disulfide loop found within the major extracellular domain of the subunits. This loop is common to all acetylcholine, gamma-aminobutyrate, and glycine receptor subunits.     

Mapping of DNase I-hypersensitive sites in the upstream DNA of human embryonic epsilon-globin gene in K562 leukemia cells.

We have mapped the DNase I-hypersensitive sites around the epsilon-globin and c-myc genes in two human leukemia cell lines K562 and HL60. In K562 cells in which the epsilon-globin gene is transcribed, six DNase I-hypersensitive sites are found in 6 kilobases (kb) of upstream flanking DNA; in HL60 cells in which the c-myc gene is expressed, two DNase I-hypersensitive sites are observed in 2 kb of upstream DNA. Neither the inactive epsilon-globin gene in HL60 cells nor the inactive c-myc gene in K562 cells displays such upstream DNase I-hypersensitive sites. Our results are consistent with previous studies that have shown DNase I-hypersensitive sites within 1 kb of the 5' end of other expressed genes. In addition, we have found sites displaying even more DNase I sensitivity further upstream of expressed epsilon-globin and c-myc genes. Among the six DNase I-hypersensitive sites of the expressed epsilon-globin gene in K562 cells, the most sensitive site is located about 6 kb upstream of the epsilon-globin gene. When correlated with the DNA sequence upstream of the epsilon-globin gene, this site was found to correspond to a region that contains a stretch of 28 consecutive Ts, three enhancer core-like sequences, and a stretch of consecutive (C-A)15(T-A)6 alternating purine and pyrimidine bases. These findings suggest the possibility that an enhancer element for epsilon-globin gene expression resides within this DNase I-hypersensitive site.     

The prolactin gene hypersensitive sites are present early in development and are not induced by estrogen administration

We have previously shown that two DNase I-hypersensitive sites are present upstream of the PRL gene in pituitary tumors of Fischer 344 rats. In this paper we present a method for examining hypersensitive sites in nontumorous pituitaries where PRL-producing lactotrophs comprise a small percentage of the total cell population. Using this method we are able to show that DNase I-hypersensitive sites in the PRL gene chromatin remain present even when estrogen is withdrawn from animals and PRL synthesis is markedly decreased. Furthermore, the hypersensitive sites appear before sexual development in female rats, and estrogen administration does not affect the appearance of the sites.     

Human fetal to adult hemoglobin switching: changes in chromatin structure of the beta-globin gene locus.

We have investigated the chromatin structure of the chromosomal DNA regions containing the human G gamma-, A gamma-, delta-, and beta-globin structural genes in both fetal and adult erythropoietic tissues and in two human erythroleukemia cells lines before and after induction. Our results indicate that DNase I introduces specific cuts into the beta-globin gene cluster in erythroid cells but not in leukocytes. The predominant sites are located at the 5' sides of the G gamma-, A gamma-, delta-, and beta-globin genes, within 200 base pairs of the respective cap sites. Examination of fetal liver cells has revealed the presence of hypersensitive sites at the 5' side of all four genes, whereas analysis of adult bone marrow has revealed the characteristic sites near the delta- and beta-globin genes but no hypersensitive sites at the 5' termini of the G gamma- or A gamma-globin genes. The presence of delta and beta hypersensitive sites in fetal cells suggests that the increment in expression of the delta and beta genes during development most likely involves the modulation of another pathway to gene expression. Using isolated nuclei from HEL and K562 cells, we have found that the G gamma, A gamma, delta, and beta genes are preferentially sensitive [relative to the pro-alpha2(I) collagen gene] to mild digestion with DNase I, whereas these genes are as resistant as collagen genes in cells that do not express globin. These findings are discussed within the context of chromatin structural correlates of hemoglobin switching.     

Photoaffinity labeling of Torpedo acetylcholine receptor at multiple sites.

The acetylcholine receptor from Torpedo californica electroplax was labeled with the photoaffinity reagent bis(3-azidopyridinium)decane perchlorate. All four receptor subunits (alpha, beta, gamma, and delta) were specifically labeled. In the presence of cholinergic agonists the gamma-, beta-, and delta-subunit labeling was decreased significantly, whereas labeling of the alpha subunit was minimally affected. Full occupancy of the two high-affinity sites involving the alpha subunits in the vicinity of alpha-Cys-192-Cys-193 by covalent reaction with bromoacetylcholine also caused a large decrease of gamma-subunit labeling by the photoaffinity reagent and lesser but significant decreases in beta- and delta-subunit labeling. No decrease in labeling of the alpha subunit was seen. Labeling of the alpha subunit could, however, be inhibited by high concentrations of the agonist carbamoylcholine. We conclude that the binding sites of high-affinity reside at interfaces of the alpha subunit and other subunits and that the alpha subunit also contributes to formation of a low-affinity site(s) for cholinergic compounds.     

Gamma delta beta-thalassemia due to a de novo mutation deleting the 5'' beta-globin gene activation-region hypersensitive sites.

gamma delta beta-Thalassemia is a rare disorder of hemoglobin biosynthesis, characterized molecularly by partial or complete deletions of the beta-globin gene complex of 100 kilobases (kb) or greater. Common to all mutants described has been the deletion of the most-5' sequences of the beta-globin complex. We have used the techniques of pulsed-field gel electrophoresis and polymerase chain reaction to study a patient with a clinical gamma delta beta-thalassemia phenotype. This subject developed a de novo deletion on a maternally inherited beta-globin gene chromosome involving approximately 30 kb of sequences 5' to the epsilon gene; the deletion extends from -9.5 kb to -39 kb 5' of epsilon and includes three of the four DNase I hypersensitive sites (at -10.9 kb, -14.7 kb, and -18 kb 5' of epsilon). The remaining sequences of the beta-globin complex, including the DNase I hypersensitive sites at -6.1 kb and all structural genes in cis to the deletion are physically intact, but presumably nonfunctional, as evidenced by the presence of a beta S-globin gene that is not expressed as a sickle hemoglobin. Deletion of DNase I hypersensitive sites on a previously functional beta-globin gene complex confirms the significance of these sites in regulating globin gene expression.     

Molecular analysis of the human beta-globin locus activation region.

Recently, DNA sequences containing four erythroid-specific DNase I hypersensitive sites within 20 kilobases 5' of the human epsilon-globin gene have been identified as an important cis-acting regulatory element, the locus activation region (LAR). Subfragments of the LAR, containing either all or only the two 5' or two 3' hypersensitive sites were linked to the human beta-globin gene and analyzed for their effect on globin gene expression in stably transformed mouse erythroleukemia (MEL) cells. Constructs containing all four of the hypersensitive sites increase beta-globin mRNA levels 8- to 13-fold, while constructs with only the 5' or 3' sites increase globin expression to a lesser extent. No effect was seen when the constructs were assayed in 3T3 fibroblasts. All of the LAR derivatives form hypersensitive sites at the corresponding sequence position in MEL cells prior to and after induction of MEL cell differentiation. However, in 3T3 fibroblasts only the hypersensitive site corresponding to the previously described erythroid-specific -10.9 site was formed.