Evidence indicating proximity in the nucleosome between the histone H4 N termini and the globular domain of histone H1.

Proteolysis of rat liver chromatin by the Arg-C peptidase, clostripain, is characterized by a progressive fragmentation of the N-terminal segments of the four core histones H2A, H2B, H3 and H4, until a well-defined limit digest is reached. This work addresses the case of histone H4. Two intermediate proteolytic sites are identified for this histone, i.e. Arg3 and Arg17, before the limit digest is achieved through cleavage of the polypeptide chain after Arg19. The accessibility of these intermediate sites depends strongly on the presence or absence of histone H1. When H1 is absent, both intermediate sites of histone H4 are similarly accessible, whereas one of them, Arg3, becomes totally inaccessible in the presence of histone H1. Di- and trinucleosomes were used with the aim of avoiding any interference with superstructural effects which can occur with longer polynucleosomes in the presence of H1. We also investigated the accessibility of the Arg sites of H1 that are located primarily in the central globular domain of this histone. In free histone H1, all the centrally located Arg sites are accessible to clostripain. In contrast, in the chromatin-bound state none of these sites is accessible. Besides the arginyl sites in the central globular domain of H1, two Arg residues are observed with the most abundant H1d variant in rat chromatin, one in the N-terminal region and the other in the C-terminal region. The restricted number of proteolytic fragments observed with chromatin-bound H1 is accounted for by the cleavage of H1 after these Arg residues located on the outside of the globular domain. Our results suggest that mutual steric effects are at play between histones H1 and H4 and indicate that the N termini of both histones H4 in the nucleosome lie in close proximity to the globular domain of H1. Based on these observations and taking into account the known structural features of the nucleosome, we propose a model for positioning the N-terminal segments of both histones H4 at the periphery of the nucleoprotein structure. In this model both H4 segments are located within the expanded DNA minor grooves, at periods +/- 1, symmetrically disposed relatively to the nucleosome dyad axis. This arrangement brings the amino ends of both H4 molecules in close contact with the H1 globular domain thus accounting for the observed inaccessibility of the Arg3 site of H4 in the presence of H1.

Human mineralocorticoid receptor interacts with actin under mineralocorticoid ligand modulation.

The human mineralocorticoid receptor of the steroid receptor family contains a modular structure with domain E which is considered to be a hormone binding domain. Recombinant protein approaches enabled us to clearly determine that this domain is also able to interact with F-actin (Kd about 2 microM) and G-actin. Moreover, it was revealed that this mineralocorticoid receptor domain/actin interaction was modulated by specific mineralocorticoid ligands. Agonist (aldosterone) steroid binding almost totally (91%) abolished the interaction with F-actin, while antagonist (progesterone) binding allowed more than 30% of this binding. Steroid modulation of the interaction between domain E and actin indicated that this actin binding is specific and could be essential for cellular mineralocorticoid receptor activity.

Putative steroid binding domain of the human mineralocorticoid receptor, expressed in E. coli in the presence of heat shock proteins shows typical native receptor characteristics.

Domain E, considered as the putative hormone binding domain (HBD) of the human mineralocorticoid receptor (hMR) was expressed in Escherichia coli as a fusion protein with either maltose binding protein (MBP) or glutathione S-transferase (GST). These bacterially-produced MR constructs had no steroid binding activity per se. In fact, heat shock protein association (hsp) is required for high affinity ligand-binding of the MR. After incubation of purified MBP- or GST-HBD with rabbit reticulocyte lysate, known to be rich in heat shock proteins, we obtained saturable binding of [3H]aldosterone. The Kd value for aldosterone was 0.3 nM and the Bmax = 32 pmol/mg. Hormone binding specificity was assessed by competition studies with various steroid ligands. Sucrose gradient assays performed with [3H]aldosterone-MBP-HBD revealed complex sedimenting at 8.3S and 4.9S with [3H]progesterone-MBP-HBD. Western-blot analysis of the sedimentation peak showed the concomitant presence of MBP-HBD by a monoclonal anti-MBP antibody, and hsp90 by a monoclonal anti-hsp antibody. Moreover, following incubation with the anti-rabbit hsp90 monoclonal antibody the sedimenting gradient showed a 10.4S sedimenting complex. These analyses demonstrated that the [3H]aldosterone-MBP-HBD complex is at least associated with hsp90 in reticulocyte lysate and that the HBD of hMR is sufficient to bind hsp90. Deletions of a relatively short amino- (729-766) or carboxy-terminal (940-984) region of the HBD fragment eliminated all steroid-binding properties. Overall, these results indicate that the integrity of domain E is necessary and sufficient to bind steroid ligands, agonists or antagonists, with characteristics similar to the entire native MR.

Cysteines 849 and 942 of human mineralocorticoid receptor are crucial for steroid binding.

To assess the role of each of the four cysteine residues in the hormone binding domain (HBD) of the human mineralocorticoid receptor (hMR), we have separately substituted C808, C849, C910, and C942 into serine. These mutations were created in the G595-K984 hMR receptor fragment which encompasses the DNA binding domain, the hinge region, and the hormone binding domain. Each mutant was further analyzed by steroid binding assays and transactivation assays using wild-type and mutant proteins expressed in vitro in the reticulocyte lysate. While the C910S mutant exhibited similar wild-type G595-K984 receptor binding properties for aldosterone, the C808S mutant affinity was 3.5-fold higher. In contrast, the C849S mutant showed a drastic drop in affinity for aldosterone and the mutant C942S was unable to bind the steroid. Affinities for the antagonist progesterone were also determined. C808S, C849S, and C910S were found to bind progesterone better than aldosterone (about a 2-fold increase in their affinities). Mutant C942S failed to bind any steroid tested (aldosterone, progesterone, cortisol, and the synthetic antagonist RU26752). No change in the specificity toward various agonists and antagonists could be observed with the mutants when compared to the wild-type G595-K984. When transactivation assays were performed, the properties of mutants C808S and C910S were similar to those of the wild-type G595-K984, while mutant C849S showed reduced sensitivity and C942S was devoid of any transcriptional activity. Our data indicate that C849 and C942 are critical for the ligand binding process of hMR. Moreover, C942 might be involved in a direct contact with the 20-keto group of the steroid.

Quantitative analysis of corticosteroids in adrenal cell cultures by capillary column gas chromatography combined with mass spectrometry.

A quantitative method using glass capillary column gas-liquid chromatography (GLC) has been established for the analysis of corticosteroids in small biological samples such as a few milliliters of medium from steroidogenic cultured cells. The steroid extract is separated in three main thin-layer chromatographic fractions. The steroids assayed in these fractions are: less polar fraction (C21O2) steroids), 20 alpha-dihydroprogesterone, pregnenolone and 20 alpha-dihydro-pregnenolone; intermediate fraction (C21O3 steroids), deoxycorticosterone, 11-oxo- and several hydroxy-20 alpha-dihydroprogesterones; corticosteroid fraction (C21O4 steroids), corticosterone and 18-hydroxydeoxycorticosterone. The method has been assessed by characterizing the steroid structures and checking the purity of GLC effluents through direct coupling of the capillary column to the electron-impact or chemical-ionization source of a computerized mass spectrometer. Applications to the quantitative evaluation of the endocrinological status of newborn rat adrenocortical cell cultures under various conditions of development, hormonal stimulation or specific inhibition by drugs are described.

Isolation from thyroid cells or purified plasma membranes with associated actin microfilaments. Proteins bound to actin.

Plasma membranes of thyroid cells were purified from hog thyroid glands following two procedures. Their homogeneity was tested by electron microscopy and by measurements of the activity of membrane-bound enzyme markers. According to the procedure used the membrane fractions obtained present some differences in their morphological features as well as in the repartition of the activities of the membrane-bound enzyme markers. However, whatever the composition of the membrane fraction examined (membrane vesicles, single membrane sheets with junctional complexes), decoration with heavy meromyosin clearly shows the presence of actin filaments attached to these fragments. Analysis of proteins by polyacrylamide gel electrophoresis indicates the presence of about twelve major components with actin. Treatment of membranes with Triton X-100 results in an insoluble core which contains all the actin and most of the major proteins. The selective extraction of these components by buffers differing in their ionic strength, pH, or the presence or absence of ATP X Mg has been used to characterize some of the proteins associated to actin; among them are filamin, myosin, alpha-actinin, tropomyosin.

A chromatin core particle obtained by selective cleavage of histones by clostripain.

Rat liver chromatin core particles digested with clostripain yield a structurally well-defined nucleoprotein particle with an octameric core made up of fragmented histone species (designated H'2A, H'2B, H'3 and H'4, respectively) after selective loss of a sequence segment located in the N-terminal region of each core histone. Sequential Edman degradation and carboxypeptidase digestion unambiguously establish that histones H2A, H2B, H3 and H4 are selectively cleaved at the carboxyl side of Arg 11, Lys 20, Arg 26 and Arg 19 respectively and that the C-terminal sequences remain unaffected. Despite the loss of the highly basic N-terminal regions, including approximately 17% of the total amino acids, the characteristic structural organization of the nucleosome core particle appears to be fully retained in the proteolyzed core particle, as judged by physicochemical and biochemical evidence. Binding of spermidine to native and proteolyzed core particles shows that DNA accessibility differs markedly in both structures. As expected the proteolyzed particle, which has lost all the in vivo acetylation sites, is not enzymatically acetylated, in contrast to the native particle. However, proteolyzed histones act as substrates of the acetyltransferase in the absence of DNA, as a consequence of the occurrence of potential acetylation sites in the core histones thus rendered accessible. The possible role of the histone N-terminal regions on chromatin structure and function is discussed in the light of the present observations with the new core particle obtained by clostripain proteolysis.