Differentiation of myeloid cell lines correlates with a selective expression of RIZ protein

BACKGROUND

The retinoblastoma-interacting zinc-finger gene RIZ is expressed in two forms (RIZ1 and RIZ2) that differ for the presence near the N-terminus of RIZ1 of a conserved domain, defined PR (PRDI-BF1-RIZ homology), homologous to a similar domain present in other proteins recognized as tumor suppressor gene products. The RIZ1 form is usually absent or expressed at low levels in tumor cells, whereas RIZ2 is frequently expressed. We investigated a possible involvement of RIZ1 in differentiation control using a myeloid cell maturation model that is easily modulated by retinoids and other agents.

MATERIALS AND METHODS

HL60 or NB4 cell lines or patients' leukemic promyelocytes were treated with all- trans -retinoic acid or other agents to induce differentiation. RIZ gene expression was determined with reverse transcriptase polymerase chain reaction (RT-PCR) and RNase protection assay. Immunocytochemistry was performed to assess variation of the intracellular distribution of RIZ protein on all- trans-retinoic acid treatment. Forced expression of RIZ1 protein was obtained with a recombinant adenovirus containing RIZ1 cDNA.

RESULTS

Treatment with retinoic acid induced a selective expression of RIZ1 in HL60 cell line. Retinoic acid effect was maximal at 7 days and correlated to the granulocytic differentiation of cells. A similar effect was obtained in retinoic acid-sensitive NB4 cell line or in patients' leukemic promyelocytes, but not in the retinoic acid-resistant cell line NB4.007/6 or in the U937 cell line. Selective expression of RIZ1 was also induced by 12-O-tetradecanoyl-phorbol-13-acetate in the U937 and HL60 cell lines and by 1,25-dihydroxyvitamin D(3) only in HL60 cells. In HL60 cells, RIZ1 was also induced by activation of a retinoid alpha receptor-independent maturation pathway based on retinoid X receptor agonist and protein kinase A synergism. In addition, retinoic acid produced a redistribution of the antigen within the nucleus in these cells. Forced expression of RIZ1 protein induced growth arrest and death of HL60 cells.

CONCLUSIONS

The correlation between the selective expression of RIZ1 induced by retinoic acid, 12-O-tetradecanoyl-phorbol-13-acetate, or 1,25-dihydroxyvitamin D(3) and differentiation suggested that RIZ protein was involved in myeloid cell differentiation induced by these agents.

Estradiol induces functional inactivation of p53 by intracellular redistribution

Estrogen treatment of MCF-7 cells grown in serum-free medium induced a modification of the intracellular distribution of p53 protein. Western blot analysis and immunofluorescence staining showed that p53 was localized in the nucleus of untreated cell and that after 48 h of hormone treatment, it was mostly localized in the cytoplasm. This effect was blocked by the antiestrogen ICI182,780. Intracellular redistribution of p53 was correlated to a reduced expression of the WAF1/CIP1 gene product and to the presence of degradation fragments of p53 in the cytosol. Estradiol treatment prevented the growth inhibition induced by oligonucleotide transfection, simulating DNA damage. This observation indicated that the wild-type p53 gene product present in the MCF-7 cell could be inactivated by estradiol through nuclear exclusion to permit the cyclin-dependent phosphorylation events leading to the G1-S transition. In addition, the estradiol-induced inactivation of p53 could be involved in the tumorigenesis of estrogen-dependent neoplasm.

The retinoblastoma-interacting zinc-finger protein RIZ is a downstream effector of estrogen action

Co-immunoprecipitation experiments in cell extract from cultured cells or target tissues indicated that estrogen receptor was complexed with the retinoblastoma binding protein RIZ in a ligand-dependent manner. Mapping of interaction sites indicated that in both proteins the same regions and motifs responsible for the interaction of transcriptional co-activator and nuclear receptors were involved. In cultured cells, estradiol induced a redistribution of RIZ protein within the nucleus and in the cytoplasm. A similar effect was produced in vivo, in prepuberal rat endometrium, by administration of a physiological dose of estradiol. Therefore, RIZ protein could be a specific effector of estrogen action downstream of the hormone-receptor interaction, presumably involved in proliferation control.

Identification of a DNA binding protein cooperating with estrogen receptor as RIZ (retinoblastoma interacting zinc finger protein)

Double-stranded DNA fragments were selected from a random pool by repeated cycles of estrogen receptor-specific immunoprecipitation in the presence of a nuclear extract and PCR amplification (cyclic amplification and selection of target, CAST, for multiple elements). Fragments were cloned and sequence analysis indicated the 5-nucleotide word TTGGC was the most recurrent sequence unrelated to the known estrogen responsive element. Screening a HeLa cell expression library with a probe designed with multiple repeats of this sequence resulted in the identification of a 1700-aa protein showing a complete homology with the product of the human retinoblastoma-interacting zinc-finger gene RIZ. In transfection experiments, RIZ protein was able to bestow estrogen inducibility to a promoter containing an incomplete estrogen responsive element and a TTGGC motif. RIZ protein present in MCF-7 cell nuclear extract retarded the TTGGC-containing probe in an EMSA. Estrogen receptor was co-immunoprecipitated from MCF-7 cell extract by antibodies to RIZ protein and vice versa, thus indicating an existing interaction between these two proteins.

Interaction of vault particles with estrogen receptor in the MCF-7 breast cancer cell

A 104-kD protein was coimmunoprecipitated with the estrogen receptor from the flowtrough of a phosphocellulose chromatography of MCF-7 cell nuclear extract. mAbs to this protein identified several cDNA clones coding for the human 104-kD major vault protein. Vaults are large ribonucleoprotein particles of unknown function present in all eukaryotic cells. They have a complex morphology, including several small molecules of RNA, but a single protein species, the major vault protein, accounts for >70% of their mass. Their shape is reminiscent of the nucleopore central plug, but no proteins of known function have been described to interact with them. Western blot analysis of vaults purified on sucrose gradient showed the presence of estrogen receptor co-migrating with the vault peak. The AER317 antibody to estrogen receptor coimmunoprecipitated the major vault protein and the vault RNA also in the 20,000 g supernatant fraction. Reconstitution experiments of estrogen receptor fragments with the major vault protein mapped the site of the interaction between amino acids 241 and 280 of human estrogen receptor, where the nuclear localization signal sequences are located. Estradiol treatment of cells increased the amount of major vault protein present in the nuclear extract and coimmunoprecipitated with estrogen receptor, whereas the anti-estrogen ICI182,780 had no effect. The hormone-dependent interaction of vaults with estrogen receptor was reproducible in vitro and was prevented by sodium molybdate. Antibodies to progesterone and glucocorticoid receptors were able to coimmunoprecipitate the major vault protein. The association of nuclear receptors with vaults could be related to their intracellular traffic.

A novel p53 mutant in human breast cancer revealed by multiple SSCP analysis

DNA from tumor tissue and peripheral blood lymphocytes of primary breast cancer patients was screened for the presence of p53 mutations. In DNA from one tumor we found that the histidine codon 193 (CAT) was somatically converted to arginine (CGT). This amino acid residue is highly conserved in many species, thus suggesting that such mutation plays an important role in the loss of wt-p53 function.

Characterization and epitope mapping of a new panel of monoclonal antibodies to estradiol receptor

A new panel of monoclonal antibodies to the calf uterus estrogen receptor was prepared. Thirteen antibodies were characterized for their isotype and for the affinity for the antigen. These antibodies recognize the human receptor and can be used in Western blot analysis. The location of the epitopes was mapped on the antigen structure using synthetic fragments of estrogen receptor, and it was possible to group the antibodies in five groups. Many antibodies were useful for the purification of estrogen receptor from tissue extracts by immunoaffinity chromatography. The reciprocal inhibition of the antibodies for the antigen binding was measured with an immunoadsorption assay. This was maximal and symmetrical for antibody pairs within the same group, but was incomplete and, in some instances, asymmetrical between pairs of antibodies from different groups. One antibody was able to inhibit the estrogen receptor-DNA interaction, whereas two others were unable to recognize the receptor-DNA complexes. This new panel of antibodies is a useful addition to the existing tools for studying structure and function of the estrogen receptor.

17 beta-hydroxysteroid dehydrogenase gene expression in human breast cancer cells: regulation of expression by a progestin

The expression of the 17 beta-hydroxysteroid dehydrogenase (17-HSD) gene in a series of human breast cancer cell lines was studied by Northern blot hybridization with a cDNA probe and by a time-resolved immunofluorometric assay using polyclonal antibodies against the enzyme protein. The 17-HSD enzyme protein concentration was measured in the 800 x g cell extract. A high concentration was measured in the BT-20 cell line, corresponding to one-fourth of the average concentration in placental tissue. Western blot analysis indicated that the antigen corresponded to a single Mr 35,000 band. In 2 other cell lines (MDA-MB-361 and T-47D), the 17-HSD protein concentration was much lower, but still measurable, whereas in the remaining 5 cell lines (HBL-100, MCF-7, MDA-MB-231, MDA-MB-468, and ZR-75-1) it was below the detection limit of the assay. Treatment of the cells for 5 days with the synthetic progestin, ORG2058, resulted in an increase of the 17-HSD protein concentration only in the T-47D cell line. By Northern blot analysis, a low level of 2.3-kilobase mRNA transcripts was detected in all 8 cell lines. In addition, a 1.3-kilobase 17-HSD mRNA was present in the samples from the 3 cell lines containing measurable amounts of 17-HSD protein in the cell extract, and the band intensities were proportional to the amount of protein measured with the immunofluorometric assay. Only in the T-47D cell line did progestin treatment correspond to an increased amount of the 17-HSD 1.3-kilobase mRNA. These results suggest that the 1.3-kilobase mRNA for 17-HSD is the form most closely associated with protein expression and is also the only form responding to the progestin induction of the 17-HSD gene.

Comparison of estrogen receptors in hormone-dependent and hormone-independent Grunder strain mouse mammary tumors

Hormone-dependent (HD) Grunder strain mouse mammary carcinomas contain a 65-kDa estrogen receptor (ER) with minor amounts of 50- and 35-kDa components which apparently still contain the intact hormone-binding (COOH-terminal) domain. When the HD tumors lose their hormonal dependence during serial transplantation, the hormone-independent (HI) transplants show an increase in 50- and 35-kDa components relative to 65-kDa ER. In HI transplants of three of five tumor lines studied (TSl 85, 86, and 106), the 65-kDa receptor was entirely replaced by 50- and 35-kDa receptors, whereas in the two other lines (TSl 101 and 104) there usually were about equal amounts of 65- and 50-kDa ERs. No difference was found between ERs of HD and HI tumors in affinity for estradiol, steroid specificity, or immunoreactivity for the monoclonal antibody JS34/32. Estrogen stimulation of HI tumors did not increase the concentration of progesterone receptor in the tumor tissue, indicating that ER in these tumors was not functional in enhancing progesterone receptor. Incubation of 65-kDa ER with HI tumor cytosol or combined homogenization of HD and HI tumor tissue did not cause degradation of 65-kDa ER. alpha-Chymotrypsin-like protease activity generally was lower in HI than in HD tumor cytosols, indicating that the lower molecular size of ER in HI tumors cannot be attributed to the increased level of this protease activity.

Proteolytic activity of the purified hormone-binding subunit in the estrogen receptor

The hormone-binding subunit of the calf uterus estradiol receptor was purified as a hormone-free molecule. Immunoaffinity chromatography with a specific monoclonal antibody was used as the final step. The purified subunit was specifically labeled by radioactive diisopropyl fluorophosphate. The diisopropyl fluorophosphate-labeled amino acid was serine. The purified receptor was able to release the fluorogenic or chromogenic group from synthetic peptides containing phenylalanine at the carboxyl terminus. This occurred only in the presence of estradiol and was hampered by aprotinin and diisopropyl fluorophosphate. Estradiol-dependent hydrolytic activity was also found in the eluate from gel slices after SDS/PAGE of purified receptor. This activity comigrated with the renaturable estradiol-binding activity. The estradiol antagonists 4-hydroxytamoxifen and ICI 164,384 as well as other steroid hormones were unable to activate this hydrolytic activity.

In vitro binding of the purified hormone-binding subunit of the estrogen receptor to oligonucleotides containing natural or modified sequences of an estrogen-responsive element

Estrogen receptor (ER) was purified from calf uterus by immunoaffinity chromatography in the absence of the ligand. The purified ER consists of a mixture of monomer and homodimer forms of 67-kDa hormone-binding subunit (no 90-kDa heat shock protein is present). The purified ER was incubated with a 32P-labeled 61-basepair oligonucleotide containing the sequence of the estrogen response element (ERE) of the Xenopus laevis A2 vitellogenin gene. DNA mobility shift assays showed formation of specific complexes of the ERE containing oligonucleotide with ER, formation which did not require and was not affected by estradiol or antiestrogenic molecules. Both the monomer and the dimer were equally able to interact with the ERE-containing oligonucleotide. Sucrose gradient experiments showed that only the ER monomer is able to interact with an oligonucleotide in which a single mutation destroyed the dyad symmetry of ERE. Multiple symmetric mutations which did not alter the dyad symmetry of ERE nevertheless totally destroyed the ability of the oligonucleotide to form complexes with either the monomeric or dimeric form of ER. These results suggest that ER is able to bind to ERE independently of the presence of estradiol or other proteins and, therefore, that estradiol does not act by modulating the ability of ER to bind to ERE on DNA.

An aprotinin binding site localized in the hormone binding domain of the estrogen receptor from calf uterus

It has been proposed that the estrogen receptor bears proteolytic activity responsible for its own transformation. This activity was inhibited by aprotinin. Incubation of transformed ER with aprotinin modified the proteolytic digestion of the hormone binding subunit by proteinase K. The smallest hormone-binding fragment of the ER, obtained by tryptic digestion, was still able to bind to aprotinin. These results suggest that aprotinin interacts with ER and the hormone-binding domain of ER is endowed with a specific aprotinin-binding site.

Estrogen receptors in cultured rabbit articular chondrocytes: influence of age

Primary cultures of pubertal and prepubertal rabbit articular cartilage cells were performed. Total homogenates or cell extracts were used to determine the specific binding of 17 beta-estradiol. A comparative study was undertaken with tissue minces homogenized without enzymatic treatment. Scatchard analysis of cell or tissue extracts revealed the presence of a high-affinity receptor with Kd values of 0.55 +/- 0.16 nM and 0.12 +/- 0.03 nM in prepubertal and pubertal rabbit chondrocytes respectively. A significant difference in the affinity of estrogen receptor for its ligand as a function of age was observed. In contrast there was no significant difference in the number of binding sites expressed as fmol per mg DNA between the two age groups. The ligand binding specificity was as expected for an estrogen receptor and the sedimentation coefficient was 3.2 S when analyzed by ultracentrifugation on sucrose density gradient in presence of 0.4 M KCl and 8.1 S in low salt conditions. The binding sites, labeled with [125I]estradiol, were specifically immunoprecipitated by a monoclonal antibody to the estrogen receptor (JS34/32).

Different int-1 region DNA rearrangements within different zones of a single mouse mammary tumor

Fragments were taken from separate parts of hormone-dependent (HD) primary GR mouse mammary tumors and serially transplanted in estrone plus progesterone treated or hormonally untreated castrated mice. The transplants were examined with respect to int-1 DNA rearrangement, proviral integrations of the murine mammary tumor virus (MMTV), and estrogen and progesterone receptor content. One of the fragments (b) taken from the primary tumor of line TSI 96 produced transplants that showed int-1 rearrangement in one allele and also MMTV proviral integrations not at the int-1 gene, whereas transplants from another fragment (a) only had the normal germ-line int-1 arrangement and no extra MMTV provirus. These respective genotypes were retained when the tumors became hormonally independent during further transplantations. The results indicate that int-1 rearrangement was not present in the originally transformed cell but occurred in a HD cell during growth of the tumor. Furthermore they indicate that loss of hormonal dependence in GR mammary tumors is due to a mutational event, unrelated to int-1 rearrangement.

Interaction of two nonhistone proteins with the estradiol response element of the avian vitellogenin gene modulates the binding of estradiol-receptor complex

The DNA sequence corresponding to the estradiol response element has been synthesized and tested in vitro for the binding of specific proteins. Gel retardation experiments combined with dimethyl sulfate protection experiments revealed that this region binds two nonhistone proteins (NHPs). One of them, NHP-1, has a molecular weight of 70,000 and binds specifically to the dyad symmetry sequence GGTCAGCGTGACC. The NHP-1 can be separated from the estradiol receptor chromatographically; it does not bind estradiol and does not cross-react with an antibody directed against the estradiol receptor. A series of synthetic "mutant" oligonucleotides were tested in a protein-DNA binding competition assay. Deletion of the GCG in the center of the dyad symmetry sequence suppressed the binding of NHP-1 by 90%, and the conversion of any GC pair to an AT pair decreased the affinity of the binding site for NHP-1. Methylation of the two CpGs on both strands of the dyad symmetry sequence decreased the affinity of the binding site for NHP-1 by 60%, whereas hemimethylation of the same structure did not inhibit the binding of NHP-1. NHP-1 and NHP-2, the NHP binding to the DNA next to the dyad symmetry sequence, bind exclusively to double-stranded DNA. NHP-2 has a molecular weight of 60,000. NHP-1 and NHP-2 are neither tissue nor species specific. In vitro reconstitution experiments show that NHP-1 and NHP-2 increase the binding efficiency of the estradiol-receptor complex to the estradiol response element.

Estradiol-dependent trans-acting factor binds preferentially to a dyad-symmetry structure within the third intron of the avian vitellogenin gene

The secondary activation of the avian vitellogenin II gene in isolated liver nuclei by cytoplasmatic liver extracts of estradiol-treated chicks is accompanied by the binding of a protein from the extract to the structural part of the cloned gene. Both the DNA-binding and gene-stimulatory activities, which cochromatograph on heparin-Sepharose, are apparently present only in the cytoplasmatic liver extracts of estradiol-treated roosters and in the oviduct extracts of egg-laying hens. DNA-binding competition assays combined with exonuclease III footprinting showed that the factor binds to the imperfect dyad-symmetry structure 5'GTCTTGTTCCAAAC3' within the third intron of the gene. The factor is sequence specific and binds equally well to both single-and double-stranded DNA with an estimated dissociation constant of 3.5 X 10(-10) M.

Subunit composition of the molybdate-stabilized "8-9 S" nontransformed estradiol receptor purified from calf uterus

The structure of the calf uterus nontransformed molybdate-stabilized estradiol receptor (ER) has been investigated using affinity labeling with tamoxifen aziridine and several monoclonal antibodies directed either against the steroid binding protein (Mr approximately 65,000) or against the heat shock protein of Mr approximately 90,000 (hsp 90). The purification was performed using affinity chromatography and a DEAE-Sephacel column. The [3H] estradiol-ER complex was obtained as a well-defined radioactive peak, the specific activity varying between 1,600 and 3,400 pmol/mg of protein. The purified ER sediments in glycerol gradients at 9.4 S +/- 0.2 (n = 5) and at 8.1 S +/- 0.2 (n = 15) in a 0.15 M KCl containing gradient ("8-9 S" ER). From a measured Stokes radius of 7.4 +/- 0.2 nm (n = 12), an Mr of approximately 300,000 has been calculated. Studies of the purified 8-9 S ER by glycerol gradient centrifugation and by "twin antibody" assay with the JS34/32 anti-ER monoclonal antibody suggest the presence of two binding subunits in the nontransformed molecular complex. Results of immunological analysis with polyclonal and several monoclonal antibodies against hsp 90 suggest the association of two molecules of this protein to the two steroid binding subunits. In high salt medium (0.4 M KCl), the purified ER sediments at 5.2 +/- 0.3 (n = 8), has a Stokes radius of 5.7 nm +/- 0.1 (n = 2) and the Mr is approximately 129,000, values expected for a homodimer consisting of two hormone-binding subunits (Mr approximately 65,000), a result confirmed by glycerol gradient centrifugation experiments, using the monoclonal antibody JS34/32. The relationship between the nontransformed 8-9 S ER and the transformed 5 S-ER forms are discussed, the simplest possibility being the release of the already formed homodimeric ER from 8-9 S ER during transformation.

Immunocytochemical demonstration of estrogen receptors by monoclonal antibodies in human breast cancer: correlation with estrogen receptor assay by dextran-coated charcoal method

Immunocytochemical demonstration of estrogen receptors in 115 human breast cancer specimens was performed using mouse monoclonal antibodies against estrogen receptor and avidin-biotin as the displaying system. The antibody indicated a highly heterogeneous endowment of neoplastic cells with estrogen receptor at both nuclear and cytoplasmic levels. The percentage of labeled cells within each tumor specimen was recorded to compare this immunocytochemical assay with the biochemical assay of estrogen receptors by the dextran-coated charcoal method. A significant correlation was observed between these two assays. The present results show that estrogen receptors can be confidently demonstrated at the single cell level, thus providing additional information to quantitative biochemical assays. Their prognostic and therapeutic predictive powers may be usefully integrated, particularly in view of the heterogeneous distribution of receptors among cancer cells.

Hormonal regulation of mouse mammary tumor growth

In view of reports that human breast cancer cells secrete growth factors that can replace estradiol in sustaining tumor growth [1], we have investigated whether hormone independent (HI) GR mouse mammary tumors can sustain growth of estrogen-depleted hormone dependent (HD) tumors. HD GR mammary tumor TSl 106 was grafted subcutaneously in the right flank of estrone plus progesterone treated castrated (020 X GR)F1 mice. After 2 weeks the estrone treatment was stopped and the mice received 50, 100 or 150 mg HI GR mammary tumor TSl 104 in the left flank. However, the regression of the HD tumor due to estrone depletion was not prevented or retarded by the HI grafts. In other experiments we investigated integrations of mouse mammary tumor virus (MMTV) proviral DNA in the DNA of GR mammary tumors. We could demonstrate the presence of two cell populations in tumor TSl 96, both HD but differing in MMTV DNA integration events. Our data indicate that exogenous integrations of MMTV proviruses can take place in mouse mammary tumor DNA without loss of hormone dependency of the tumors. Like in GR/Mtv-2+ mice, mammary tumor transplants differing in MMTV proviral integrations are also observed in 020/Mtv-2+ mice.

Association of the heat shock protein hsp90 with steroid hormone receptors and tyrosine kinase oncogene products

Monospecific, polyclonal rabbit antibody raised against the 90-kd non-hormone binding component of molybdate-stabilized steroid hormone receptor specifically recognises the 90-kd molecular weight heat shock protein (hsp 90) in mink cell extracts. Partial proteolytic digestion experiments indicate that this protein is identical to the 90-kd phosphoprotein found in a highly stable complex with the protein products of at least three members of the tyrosine kinase family of oncogenes (src, fes, fgr).

Interaction between estrogen receptor and subcellular structures of target cells: nuclear localization of unoccupied receptor and its modification induced by estradiol

Experimental conditions affecting the partitioning of the estrogen receptor were studied. Homogenization of rat uteri at 25 degrees C resulted in a particulate partitioning of the estrogen receptor. The use of frozen tissue (-70 degrees C) or pre-exposure of the tissue to 0 degrees C prior to 25 degrees C homogenization, homogenization at 0 degrees C and tissue dilution all induced soluble partitioning of the receptor. The estrogen receptor found in the particulate fraction was mostly associated with the nuclei, even in the absence of hormone. The interaction between estradiol and the estrogen receptor induced modification in the receptor's charge and size that promoted its cold-insensitive association with the nuclei of target cells. These modifications were studied in a cell-free in vitro system and were reversibly blocked by molybdate. Similar changes occurred in vivo when estradiol interacted with the receptor in the nuclei of target cells.

In vitro secondary activation (memory effect) of avian vitellogenin II gene in isolated liver nuclei

The vitellogenin II gene is specifically reactivated in vitro (secondary stimulation, memory effect) in purified liver nuclei that had ceased to express the gene in vivo a month after the roosters had received a single injection of estradiol (primary stimulation). The in vitro reactivation depends on the addition to the nuclei of nuclear and cytoplasmic extracts from estradiol-stimulated livers, polyamines (0.1-1.0 mM), and calmodulin (0.1 mM). Under identical incubation conditions the vitellogenin gene could not be reactivated in oviduct, embryonic, and immature chicken liver nuclei. Two other genes, those for ovalbumin and lysozyme, which are regulated by estradiol in the oviduct, could not be activated in the liver nuclei. The correct initiation of vitellogenin gene transcription in the liver nuclei was tested by primer extension studies. Addition of the antiestrogen tamoxifen (0.1 microM) to the system decreased vitellogenin mRNA synthesis by about 45% without affecting total RNA synthesis. Addition of quercetin (0.1 mM) and trans-flupenthixol (0.2 mM), inhibitors of nuclear protein kinase II and calmodulin-dependent kinase, respectively, inhibited the synthesis of vitellogenin mRNA by about 55% without affecting total RNA synthesis. The inhibitory effects of the antiestrogen and the kinase inhibitors were not additive, suggesting that both classes of inhibitor act on the same target or related targets. Depleting the estradiol receptors from the cell and nuclear extracts by means of estradiol-receptor antibodies covalently bound to Matrex beads reduced the stimulation of the vitellogenin gene by 40%. We conclude that in addition to the estradiol receptor and phosphorylation of nuclear protein(s) there are additional factors responsible for the in vitro secondary activation of the avian vitellogenin II gene.

Particulate nature of the unoccupied uterine estrogen receptor

Homogenization of rat uteri at 25 degrees C resulted in a particulate partitioning of the estrogen receptor. Homogenization at 0 degrees C, the use of frozen tissue, or the pre-exposure of the tissue to 0 degrees C prior to 25 degrees C homogenization induced soluble partitioning of the estrogen receptor. Binding of a radiolabeled monoclonal antibody indicated that, in absence of estradiol, the estrogen receptor is particulate and is associated with the nuclei-enriched fraction of the target cell. The presence of receptor in the soluble fraction thus appears to be an artifact of homogenization. The unoccupied receptor, loosely associated with the particulate fraction (cold-sensitive) represents the "native" form of receptor which, upon arrival of the hormone, becomes tightly associated (cold-insensitive). The transition from the cold-sensitive to the cold-insensitive status is accompanied by a modification of the electrical charge of the receptor.

Interaction of estrogen receptor of calf uterus with a monoclonal antibody: probing of various molecular forms

A monoclonal antibody to estrogen receptor (JS34/32) is able to recognize, in the calf uterine cytosol, a protein (approximately 65 000 daltons) giving a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Two molecules of this antibody are able to simultaneously interact with the native 8S form of the receptor present in the calf uterine cytosol ("twin antibody" assay). This indicates the presence of two antigenic determinants on the "low-salt" 8S form of the receptor. This form of the receptor shows an increase in Mr from 345 000 to 665 000 after interaction with the soluble antibody. Dissociating agents that induce the dissociation of the 8S form to smaller forms also induce the dissociation of the two antigenic determinants. The 4S "high-salt" form of the estrogen receptor has one determinant per molecule, appearing to be the smallest form of the receptor not containing repetitive structures associated with the steroid binding site. The nuclear receptor also shows the presence of more than one antigenic determinant on its molecule.

Binding of monoclonal antibodies to the nuclear estrogen receptor in intact nuclei

A monoclonal antibody to calf uterus cytoplasmic estrogen receptor shows a specifically displaceable and saturable binding to intact nuclei of mouse uterus after estradiol stimulation. The binding is complete after 3 hr at 0 degree C. The binding of the antibody correlates with the exchangeable estradiol binding activity of the nuclei over a 4-hr time course following in vivo injection of 17 beta-estradiol.

Monoclonal antibodies against estrogen receptor: interaction with different molecular forms and functions of the receptor

Hybridoma cells have been produced by fusing SP2/O-Ag14 mouse myeloma cells with spleen cells from a mouse immunized with a purified preparation of estrogen receptor from calf uterus. The antibodies, all of the immunoglobulin G (IgG) class, interact with different forms of calf receptor as well as with rat and human receptors. The equilibrium dissociation constant of the antibody-receptor complex was measured in solid phase and in solution. With immobilized antibodies the Kd is 0.06 nM whereas in solution it is 0.5 nM. Only one antigenic determinant is present per molecule of receptor with the antibodies tested. The antibodies JS34/32 are able to form only a 1:1 complex with the 8S form of the receptor, whereas a 2:1 receptor-IgG complex is formed at low antibody concentration with the high-salt or nuclear form of receptor. The antibodies JS34/32 and JS28/32 prevent neither the nuclear uptake of the receptor nor the extraction of the translocated receptor from the nuclei.

Formation and identification of cytoskeletal components from liver cytosolic precursors

Liver cytosol forms a macroscopic fibrillary network in the presence of low concentrations of MgCl2. This process represents the generation of 3- to 11-nm filaments from soluble precursors, involving selectively at least 12 major polypeptides. Similar polypeptides are enriched in the detergent-insoluble fraction from hepatocytes, suggesting that they may be important constituents of the native cytoskeleton. AcA 34 gel-permeation chromatography resolves the cytosol into three independently "polymerizing" peaks: A, B, and C. The formation of filaments follows biphasic kinetics in peaks B and C, whereas peak A lacks the slow phase. Filament formation in all three systems is inhibited by 1-15 mM inorganic phosphate, 10 mM NaF, or 10 mM sodium molybdate. The polymerization of peak C only is inhibited by 0.2-2 mM ATP. CaCl2 (1-100 microM) has no apparent regulatory effect. Two-dimensional polypeptide analysis and peptide mapping show that actin is a major component of peak C, while peaks A and B contain prominent polypeptides that may be related to intermediate filament subunits. In addition, all three systems contain two or three high molecular weight (greater than 170,000) polypeptides that may participate in modulating and extending the filament network. The filaments from peaks A and B are soluble in 8 M urea and reform on removal of the urea in the presence of 5 mM MgCl2. The polypeptide composition remains constant through three such cycles.

Effect of sodium molybdate on cytosolic estrogen receptor

Estrogen binding activity of crude calf uterus cytosol is rapidly destroyed in heating. The time course of inactivation at 37 degrees C shows a biphasic pattern; sodium molybdate (5-10 mM) completely blocks one of the components in the estradiol-free cytosol, while it has little effect on cytosolic receptor complexed with estradiol. Partially purified native 8S receptor loses its heat sensitivity, and, as a consequence, the molybdate effect disappears. By sucrose gradient analysis of crude cytosol it is evident that molybdate does not affect the sedimentation properties of the estradiol receptor at low temperature. However, at increasing temperatures, molybdate prevents the disappearance of the receptor peak in the crude cytosol or the formation of large, KCl-resistant, aggregates in the presence of estradiol. The partially purified native 8S receptor does not aggregate on heating; addition to it of receptor-depleted cytosol results in the recovery of heat inactivation and aggregate formation, and this is prevented by molybdate. Molybdate has no protective effect on any other inactivating agent which does not act through aggregation of receptors. A crude cytosolic preparation of the receptor which is unable to form heat-dependent aggregates does not display the fast heat inactivating component.

Estradiol receptor of calf uterus: interactions with heparin-agarose and purification

Heparin attached covalently to agarose beads binds the "native" form of the estradiol receptor with very high affinity. Chondroitin sulfate does not bind to the receptor. When the receptor is complexed with hormone, the affinity is at least 10 times higher. Only the "native" and not the "nuclear" or the "derived" (i.e., after activation by a calcium-dependent enzyme) forms of the estradiol receptor interact with heparin. The "native" estradiol-receptor complex is purified to homogeneity after chromatography on columns of heparin-agarose, Sephadex G-200, and DEAE-cellulose, followed by two more Sephadex G-200 columns. The purified molecule is a single polypeptide of molecular weight 69,000 by polyacrylamide gel electrophoresis in sodium dodecyl sulphate. The sedimentation coefficient on sucrose gradients is 4.3 S, the Stokes radius from gel filtration is 36.5 A, and the isoelectric point is 6.4. The purified [3H]estradiol-receptor complex exchanges the radioactive hormone with estradiol or other estrogenic steroids, but not with testosterone, 5alpha-dihydrotestosterone, or progesterone.