Estradiol-17β receptors in the immature rat ovary

Estradiol binding components in the cytosol and nuclear fractions of the ovary from immature rats (22–28 days old) were characterized by $\text{in vitro}$ methods. Several of the biochemical characteristics of the estradiol binding components in the ovarian tissue were compared with the estradiol receptor from the uterus. The results suggest that the ovarian estradiol binding components are similar to the specific high affinity estradiol receptors in the uterus. In the cytosol of intact rat ovary a significant fraction of the total binding sites was found to be occupied, presumably by the endogenous estrogen. Following hypophysectomy there was a significant increase in the available cytosol binding sites. Evidence for translocation of cytosol receptor-estrogen (RE) complex to the nucleus was obtained for the ovary. The sedimentation properties of the RE complex of the ovary and the uterus are similar. The ovarian cytosol RE complex sediments at 7-8S in glycerol gradients at low ionic strength and at 4S in sucrose gradients at high ionic strength. Following extraction with 0.4 M KCl the ovarain nuclear RE complex sediments at 5S in sucrose gradients which is identical to that of the uterine nuclear receptor.     

High affinity estrogen binding by rabbit liver

Macromolecular binding components for [3H]estradiol-17beta are present to cytosol prepared from rabbit liver. When cytosol from sexually mature male liver was incubated with [3H]estradiol and analyzed for binding on low ionic strength sucrose gradients, two peaks of binding activity were detected. One peak had a sedimentation coefficient of 4--5 S and the other had a sedimentation coefficient of 8--9 S. The two components differed from each other regarding steroid specificity and various physiocochemical parameters. [3H]estradiol binding to the 4--5 S component was not inhibited by estrogens, 5alpha-dihydrotestosterone, progesterone or cortisol. Binding to this component did not appear to be saturable and label was rapidly stripped from it by charcoal. Estradiol binding to the 8--9 S component was estrogen specific, saturable and of high affinity. The specific binder dissociates on high ionic strength sucrose gradients and sediments as a 4--5 S moiety. The specific binding protein has a Kd of 3.05 . 10(-10) M and a dissociation half-time of 33 h and there are 35.2 fmol of binding sites/mg cytosol protein. Estrogen binders are also present in liver cytosol from sexually mature female and sexually immature male rabbits. During prolonged incubation of [3H]estradiol with mature male liver cytosol at 0--5 degrees C polar metabolites of estradiol are produced.     

Reduced high affinity 5 -dihydrotestosterone receptor capacity in the ventral prostate of the aging rat

Cytoplasmic extracts of ventral prostates obtained from young (50–90 day old) rats 24 hours post orchidectomy contained high affinity binding activity for 5α-dihydrotestosterone which migrated with a sedimentation coefficient of 10–11S on linear sucrose gradients. By contrast, when cytoplasmic extracts were prepared from ventral prostates of aging rats (10–14 months old), 80 percent of the animals evidenced a complete absence of 10–11S binding activity. A single extract prepared from the ventral prostates of the remaining aging animals in the 10–14 month age category had a level of 10–11S binding activity that was about 20 to 25 percent of the value routinely obtained for identical preparations from young animals. Cytoplasmic extracts prepared from the ventral prostate of animals older than 14 months were always found to be devoid of 10–11S binding activity.     

Characterization of 7–8S progestin binding protein in human prostate using vertical tube rotor

The specific binding of the synthetic progestin, 17α-methyl [³H]promegestone (R5020), to the cytosol of human benign hyperplastic prostate has been studied in sucrose density gradients using a vertical tube rotor. The eytosol of human prostate was shown to contain substantial amounts of a 7–8S macromolecule with a high affinity (K_d = 0.5–1 nM) for R5020 which is saturated at low concentrations (10 nM). The conventional technique of sucrose density gradient analysis in a swinging bucket rotor was not suitable for reproducible optimal analysis of a 7–8S high affinity complex. The use of the salt, Na₂MoO₄, had a stabilizing effect on the complex. Comparison of saturation analysis assays using dextran charcoal assay and vertical tube rotor assay showed that the charcoal assay can give an over-estimation of the 7–8S saturable binding. Progestational steroids competed with R5020 for binding to 7–8S, whereas androgenic steroids, with the exception of 19-nor-testosterone, did not compete.Incubation of cytosol at elevated temperatures in the presence of DNA-cellulose resulted in the binding of the hormone-protein complex to DNA-cellulose. High ionic strength buffer was required to extract the complex which sedimented at 4.5S in sucrose gradients prepared in 0.4 M KCl. Based on the data presented, progestin binding in human prostate is clearly similar in physical chemical properties to progesterone receptors in “classical” target tissues. However, rapid sucrose gradient analysis with a vertical tube rotor is preferred over conventional techniques to evaluate progestin receptor binding in human prostate.     

High affinity estrogen binding by rabbit liver

Macromolecular binding components for [³H]estradiol-17β are present to cytosol prepared from rabbit liver. When cytosol from sexually mature male liver was incubated with [³H]estradiol and analyzed for binding on low ionic strength sucrose gradients, two peaks of binding activity were detected. One peak had a sedimentation coefficient of 4–5 S and the other had a sedimentation coefficient of 8–9 S. The two components differed from each other regarding steroid specicity and various physiocochemical parameters. [³H]-estradiol binding to the 4–5 S component was not inhibited by estrogens, 5α-dihydrotestosterone, progesterone or cortisol. Binding to this component did not appera to be saturable and lavel was rapidly stripped from it by cahrcoal. Estradiol bindng to the 8–9 S component was estrogen specific, saturable and of high affinity. The specific binder dissociates on high ionic strength sucrose gradients and sediments as a 4–5 S moiety. The specific binding protein has a K_d of 3.05 · 10⁻¹⁰ M and a dissociation half-time of 33 h and there are 35.2 fmol of binding sites/mg cytosol protein. Estrogen binders are also present in liver cytosol from sexually mature female and sexually immature male rabbits. During prolonged incbuation of [³H]estradiol with mature male liver cytosol at 0–5°C polar metabolites of estradiol are produced.     

Characteristics of androgen binding in rat adrenal tissue using [3H]methyltrienolone (R1881) as tracer

A high level of binding of [3H]methyltrienolone (R1881 = 17beta-hydroxy-17alpha-methyl-estra-4, 9, 11-trien-3-one) was found in cytosol prepared from adrenals of castrated male rats. Binding of [3H]R1881 was of high affinity (DK = 6.2 nM) and highly specific for androgens. The [3H]R1881 complex migrates at 7-9S on sucrose gradients in low ionic strength buffer and at 4-5S in buffer containing 0.4M KC1. All binding studies have been performed in parallel with rat ventral prostate and adrenal cytosol. The present data suggest the presence of an androgen binding component in rat adrenal tissue.     

Estrogen receptors in the adrenal cortex of the possum (Trichosurus vulpecula)

1. Specific [3H]estradiol binding activity with characteristics of estrogen receptors was found in the cytosols and nuclear extracts of the adrenal cortex proper and special zone of the brushtail possum (Trichosurus vulpecula). 2. The specific estradiol receptor had a sedimentation coefficient on sucrose gradients of approximately 9S and a molecular weight on gel filtration of more than 200,000. The adrenal cortex cytosol binds [3H]estradiol with high affinity (Ka 5.5 X 10(9) M-1), and limited capacity (Bmax 62.7 fmol/mg cytosol prot). In competition experiments with different steroids the receptor showed a high affinity for four estrogens and a very low affinity to androgens, progesterone and cortisol. 3. There was no difference in the affinity and maximum binding capacity of the cytosols from cortex proper in male and female animals, but the binding capacity of the special zone of females was half that of cortex proper. Estradiol receptors were found in the kidney, liver, lung, testis and muscle but only in the adrenal and prostate was the binding capacity relatively high compared with the uterus. 4. The specific binding capacity of [3H]estradiol to cytosols of adrenal cortex at different stages of the estrus cycle and pregnancy was unrelated to that of the uterus. In the adrenal the receptor concentration was lowest at estrus, when uterine concentration was high, while in late pregnancy the binding of adrenal cortex and uterus cytosols was almost the same. 5. The possible physiological significance of the presence of a specific estrogen receptor in male and female possums is discussed.     

Intracellular receptors for 5alpha-dihydrostestosterone in the epididymis of adult rats. Comparison with the androgenic receptors in the ventral prostate and the androgen binding protein (ABP) in the testicular and epididymal fluid

Epididymal cytosol fractions of adult short-time castrated rats contained at least two different androgen protein complexes by experiments $\text{in vivo}$ (Complex I and II).Complex I is probably located intracellularly in the epididymal cells. It was specific for 5α-dihydrotestosterone (DHT) and appeared to be very similar to the cytoplasmic DHT-receptor complexes in rat ventral prostate. By ultracentrifugation on sucrose gradients, it sedimented as heavy aggregates 8–10 S complexes and 3–4 S complexes, which dissociated into 3–4 S complexes at high ionic strength. Complex I was eluted in the void volume from columns of Sephadex G-200.Complex II was also specific for DHT and showed physical properties similar to those of the androgen binding protein (ABP) in the testicular fluid. It was eluted between immunoglobulin G (IgG) (53 Å) and albumin (36 Å) by gel filtration on Sephadex G-200. The sedimentation coefficient was 4.5–5 S (mean 4.6 S_W, 20) at both high and low ionic strength.Complex I and the cytosol receptors for DHT in the rat ventral prostate were both destroyed by heating at 50° C for 30 min, addition of 1 mM p-chloro-mercuri-phenyl-sulphonate (PCMPS) and charcoal absorption (1 mg/mg protein) overnight, whereas complex II was not influenced by similar treatment.Hemi-castration for 4 weeks caused complex II to disappear completely from the castrated side, confirming the intraluminal localization of this complex. Complex I was not influenced by such treatment, indicating that this protein is located within the epididymal cells. The similarity between complex I and the cytoplasmic DHT-receptor complexes in the ventral prostate also suggests that complex I represents the cytoplasmic receptors for DHT in the epididymis.     

Effects of estradiol on prostate epithelial cells in the castrated rat.

There is evidence that estrogens can modulate the activity of prostate epithelial cells. To determine whether estradiol can have a direct influence on rat prostate, this study examined the effects of estradiol-17beta (E(2)) administered alone or in combination with dihydrotestosterone (DHT) to castrated rats for 3 weeks on prostate binding protein (PBP) C1 mRNA expression and androgen receptor (AR) localization. PBP C1 mRNA levels were measured by semi-quantitative in situ hybridization using a (35)S-labeled cDNA probe. In intact animals, strong hybridization signal could be observed in prostate sections after 12 hr of exposure to Kodak X-Omat films. In castrated rats, no PBP C1 mRNA could be detected even with longer exposure times, an effect that was prevented by administration of DHT. E(2) administered alone induced a detectable hybridization signal, and the concomitant administration of E(2) and DHT induced an increase in PBP C1 mRNA that significantly exceeded that obtained in animals that received only DHT. In prostate epithelial cells of intact animals, AR immunostaining was restricted to the nucleus. In castrated animals the alveoli were decreased in size and the epithelial cells were atrophied. AR staining was weak and was detected in both cytoplasm and nucleus. DHT administration completely obviated the effect of castration on epithelial cell histology and on AR immunostaining distribution and intensity. Interestingly, E(2) administration alone induced moderate hypertrophy of epithelial cells compared to the histological appearance of cells in untreated castrated rats. Moreover, in E(2)-treated animals the nuclear staining was much stronger than that detected in untreated castrated rats, whereas the cytoplasmic staining was not modified by the treatment. In animals that received both DHT and E(2), the staining was similar to that seen in DHT-treated rats. These results suggest that E(2) can influence the activity of rat prostate epithelial cells by mechanisms that remain to be fully clarified.     

Localization,metabolism, and binding of estrogens in the male rat

Estrogen assimilation by male Wistar rats was examined in these studies in several accessory sex organs (seminal vesicles and anterior, dorsal, lateral, and ventral prostates) as well as in a variety of nonaccessory sex organs. When [³H]estradiol was injected into intact 3- to 4-month-old rats in a pulse dose, no selective accumulation of radioactivity recovered as estradiol was found in the accessory sex glands when compared to other organs. This was due at least in part to the metabolism of estradiol to estrone and to the relatively low concentration of high affinity estrophilic molecules in the accessory sex organs. The order for the rate of formation of estrone from estradiol in tissues obtained from intact animals was ventral prostate > lateral and dorsal prostate > anterior prostate and seminal vesicles. Steroid specificity studies for cytosol estradiol binding by the ventral prostate and seminal vesicles revealed that estrophilic molecules exist in these organs. Based on Scatchard plot analyses in 24-h castrates, the number of available estradiol binding sites was too low in the ventral prostate to quantify accurately, but the seminal vesicles contained distinctly more estrophilic activity than the ventral prostate. The affinity for the seminal vesicle cytosol estradiol-estrophile binding exceeded that quantified for the seminal vesicle dihydrotestosterone-androphile reaction while the number of estradiol binding sites was less than that quantified for dihydrotestosterone. In relation to the accessory sex organs of other species, the rat seminal vesicles have a relatively small amount of cytosol estrophile. The findings that the seminal vesicles catabolize less estradiol and contain significantly more estrophilic activity than the ventral prostate is consistent with and offers insight into the noted estrogenic sensitivity of the seminal vesicles and lack thereof in the rat ventral prostate. With aging of the rat from 3–4 months to 22–26 months, the affinity of the seminal vesicle estradiol-estrophile interaction was unchanged but the number of binding sites increased significantly.     

Estrogen Receptor Characterization Following Selective Sedimentation Separation of Estrogen-Binding Components In Immature Rat Uterine Cytosol

Abstract

Characterization of a specific estrogen receptor (ER) in fetal and early postnatal rat uterine cytosol is complicated by the presence of other high-affinity estrogen-binding components, such as alpha-fetoprotein (AFP). In an attempt to circumvent their influence, we have employed the selective sedimentation of unlabeled cytosol through sucrose gradients, followed by the analysis of [³H]estradiol binding to a pool of fractions comprising the ER region, as well as to individual gradient fractions. As the amount of AFP present in 21-day-old rats is sufficiently low to permit ER characterization by conventional methodology, we have validated the selective sedimentation method by comparing its results with those obtained conventionally. Though conventional gradient analysis revealed only one estrogen-binding component, saturation and binding inhibition analyses indicated the presence of multiple components, identified as AFP and the ER. These conclusions were supported by results from labeling individual gradient fractions obtained following selective sedimentation of unlabeled cytosol. Further, when unlabeled 7–9 S gradient fractions were pooled and assayed by saturation and binding inhibition analyses, only one binding component, with ER characteristics, was revealed. These results validate selective sedimentation as an effective method for separating multi-component estrogen-binding systems and suggest its applicability to similar systems.     

Binding sites of iron transferrin on rat reticulocytes. Inhibition by specific antibodies

Rat ventral prostate contains an acidic protein which can bind spermine selectively. The relative binding affinities of various aliphatic amines for the protein are, in decreasing order, spermine greater than thermine greater than greater than putrecine greater than 1,10-diaminodecane, cadaverine and 1,12-diaminododecane. The binding protein has an isoelectric point at pH 4.3 and a sedimentation coefficient of 3 S. Its molecular weight is approx. 30 000. Histones and nuclear chromatin preparations of the prostate can interact with the binding protein. The spermine-binding activity of the purified prostate protein can be inactivated by treatment with intestinal alkaline phosphatases. The phosphatase treated preparation can then be reactivated by beef heart protein kinase in the presence of cyclic AMP and ATP. The spermine-binding activity of the prostate cytosol protein fraction decreases after castration, but increases very rapidly after the castrated rats are injected with 5alpha-dihydrotestosterone. This finding raises the possibility that, in the postate, certain androgen actions may be dependent on the androgen-induced increase in the acidic protein binding of polyamines and their translocation to a functional cellular site such as nuclear chromatin. In the prostate cytosol, spermine also binds to 4-S tRNAs and to a unique RNA which has a sedimentation coefficient of 1.5 S.     

Interaction of medroxyprogesterone acetate with cytosol androgen receptors in the rat hypothalamus and pituitary

The binding of medroxyprogesterone acetate (MPA) with cytosol androgen receptors from rat pituitary and hypothalamus was studied. The pituitary and hypothalamic cytosol androgen receptors from adult castrated female rats were in vitro labeled using 3H natural (testosterone (T) and 5 alpha-dihydrotestosterone (DHT] and [3H]synthetic (methyltrienolone) androgens as radioligands. The [3H]androgen-receptor complexes sedimented with a coefficient of 8S in linear sucrose gradients. When incubated with an excess of radioinert MPA, specific binding was abolished indicating interaction of MPA with androgen receptors. Furthermore specific [3H]MPA-androgen cytosol receptor complexes could be identified in these neuroendocrine tissues when a post-gradient receptor labeling technique was used in the absence or presence of radioinert MPA, DHT, and triamcinolone acetonide. A study of binding kinetics disclosed that the equilibrium dissociation constant and saturation binding capacity for the MPA binder, were similar to those exhibited by DHT binding to androgen receptors in both studied tissues under identical experimental conditions. The overall results were interpreted as demonstrating that MPA interacts with cytosol steroid receptors other than those of progesterone in the rat hypothalamus and anterior pituitary. The data are consistent with MPA binding to androgen receptors.     

Selective polyamine-binding proteins spermine binding by an androgen-sensitive phosphoprotein

Rat ventral prostate contains an acidic protein which can bind spermine selectively. The relative binding affinities of various aliphatic amines for the protein are, in decreasing order, spermine > thermine >> spermidine > putrecine > 1,10-diaminodecane, cadaverine and 1,12-diaminododecane. The binding protein has an isoelectric point at pH 4.3 and a sedimentation coefficient of 3 S. Its molecular weight is approx. 30 000. Histones and nuclear chromatin preparations of the prostate can interact with the binding protein.The spermine-binding activity of the purified prostate protein can be inactivated by treatment with intestinal alkaline phosphatases. The phosphatase-treated preparation can then be reactivated by beef heart protein kinase in the presence of cyclic AMP and ATP.The spermine-binding activity of the prostate cytosol protein fraction decreases after castraction, but increases very rapidly after the castrated rats are injected with 5α-dihydrotesterone. This finding raises the possibility that, in the prostate, certain androgen actions may be dependent on the androgen-induced increase in the acidic protein binding of polyamines and their translocation to a functional cellular site such as nuclear chromatin.In the prostate cytosol, spermine also binds to 4-S tRNAs and to a unique RNA which has a sedimentation coefficient of 1.5 S.     

Immunological demonstration of alpha-fetoprotein in uterine cytosol from immature rats

An immunological demonstration of alpha-fetoprotein (AFP) in uterine cytosol from immature rats is reported. The identity between serum AFP and the estrogen binding 4.5 S macromolecular complex of uterine cytosol was demonstrated by the use of a specific immunoadsorbent to AFP. Analysis of the sedimentation profile in glycerol gradients of uterine cytosol incubated with tritiated estrone or estradiol suggests that the total estrogen binding capacity of the 4.5 S complex is provided by AFP. Changes of AFP content in rat uterus with the age of the animals suggest that this protein is probably present in the cytosol as a serum contaminant.     

Comparison of formation, activation, and nuclear translocation of receptor . estradiol (R . E2) complex at 0 degrees C and 37 degrees C in intact uterine cells.

The present study was undertaken to establish whether molecular events leading to binding, transformation-activation, and nuclear translocation of cytoplasmic uterine estrogen receptor described for cell-free systems also occur in intact uterine cells. Cell suspensions were incubated at 0 degrees C or 37 degrees C with estradiol (E2) and specific binding to intracellular receptors was measured. The data demonstrate that saturation of specific estrogen binding sites occurs within 60 min at 37 degrees C and within 22 h at 0 degrees C, with a total of approximately 24,000 to 30,000 receptor sites per cell. At equilibrium, the total number and subcellular distribution of receptor . estradiol (R . E2) complexes formed in cells incubated at 0 degrees C or 37 degrees C were identical. Scatchard analysis of the equilibrium binding data yielded the same association constants for cytoplasmic and nuclear R . E2 formed in intact cells incubated at either temperature. Sucrose density gradient analysis of nuclear and cytoplasmic R . E2 formed in intact cells at 0 degrees C or 37 degrees C showed that at both temperatures, the nuclear R . E2 had a 5 S sedimentation coefficient; at both temperatures, a 5 S cytosol R . E2 was detected; only in the 0 degrees C incubation, an additional 4 S cytosol R . E2 was found. These results suggest that the molecular interactions regulating the dynamics of estrogen binding in the intact cell are similar at both physiological and low temperatures.     

DNA and ribonucleotide binding characteristics of two forms of the androgen receptor from rat prostates

Androgen receptors (sedimentation value approximately 4S and Stokes radius 2.8 nm) present in the cytoplasmic fraction obtained from prostates of castrated rats bind to DNA-Sepharose and double stranded DNA. A receptor fragment (sedimentation value approximately 3S and Stokes radius 2.3 nm) obtained from rat prostates in the course of a purification procedure showed greatly diminished binding affinity for both DNA-Sepharose and soluble DNA. In contrast, both the 4S cytosol receptor and the 3S receptor form interacted with equal affinity with prostate RNA or poly(UG). These observations provide evidence that for DNA binding a different or additional part of the receptor molecule is required than for RNA and polyribonucleotide binding.     

Specific binding of oestradiol to guinea-pig prostate cytosol and nuclear fractions

A high affinity (Kd approximately 0.15 nM), saturable oestradiol binding site, which is specific for natural and synthetic oestrogens has been identified in guinea-pig prostate cytosol fractions. The binding site is protein in nature (heat- and protease-sensitive) and has a sedimentation coefficient of approx. 8S on glycerol gradients. A high affinity (Kd approximately 0.16 nM), saturable oestradiol binding site was also identified in salt-extracted (0.5 M KC1) nuclear fractions. The optimum incubation conditions for measuring the cytosolic and nuclear oestradiol binding sites were determined to be 20 h at 4 degrees C. Saturation analysis studies revealed that following oestrogen treatment of intact animals, approx. 80% of the specific oestradiol binding sites in prostatic cytosol fractions were transferred into the nucleus. The presence of a specific oestradiol binding protein with characteristics of an oestrogen receptor in the guinea-pig prostate, is consistent with oestrogen having biological activity in this tissue. In view of the abundance of stroma in the prostate of this species, and the consistent finding that the stroma of male accessory sex tissues is oestrogen sensitive, the guinea-pig may be an appropriate experimental animal for further investigating the role of oestrogen in the growth and development of the prostate.     

Characterization of estrogen binding in the developing rat testis. Ontogeny of the testicular cytoplasmic estrogen receptor.

The properties and physical characteristics of a steroid binding component present in the immature (7 to 35 day) rat were investigated and found to be different from those of the 17 beta-estradiol receptor in the mature rat testis. These properties include a binding capacity of 483 fmol estradiol/mg protein, a Ka at equilibrium of 4.23 x 10(7)M-1, and broad steroid specificity as shown by interaction with several steroids; no binding was observed with diethylstilbestrol. The component, found in blood and several tissues including the testis, migrated as a 4.6S peak on sucrose gradients. This 4.6S component, which interacted with an anti-alphafetoprotein antiserum, decreased with age and was not detectable in the testis after day 21 or in the serum after day 25. These data suggest that this component is alphafetoprotein. Ontogenic appearance of the testicular cytoplasmic 17 beta-estradiol receptor in the developing rat was further elucidated. Sucrose gradient sedimentation analysis of cytosols revealed an 8S binding component that was first detectable at 23 days. Specific binding (fmol [3H]-estradiol/testis) was relatively low in neonates, rose to 59 fmol during the third week, and increased dramatically to 333 fmol at 7 weeks; binding rose only gradually after maturity. The receptor was tissue specific and steroid specificity studies demonstrated that only diethylstilbestrol and other estrogens were effective in competing with 17 beta-estradiol for binding sites. The Ka at equilibrium was determined as 3 x 10(10)M-1 and the binding sites were saturable in an in vitro system. The receptor did not interact with anti-alphafetoprotein antiserum as indicated by sucrose gradient studies. These data demonstrate the developmental appearance of the testicular cytoplasmic estradiol receptor in the immature rat.     

RNase A effects on sedimentation and DNA binding properties of dexamethasone-receptor complexes from HeLa cell cytosol

Dexamethasone-receptor complexes from HeLa cell cytosol sediment at 7.4S in low salt sucrose gradients, and at 3.8S in high salt gradients. If cytosol is heated at 25 degrees C, receptor complexes sediment at 6.9S in low salt, and at 3.6S in high salt gradients. RNase A treatment at 25 degrees C, instead, results in receptor complexes which sediment in low salt gradients as two major forms at 6.5 and 4.8S. Receptor complexes from RNase A-treated cytosols sediment as their counterparts from untreated cytosols in high salt gradients. Although the shift in sedimentation properties of receptor complexes at 2 degrees C is induced by RNase A, and not by other low molecular weight basic proteins or RNase T1, the effect can be also obtained by inactive RNase A. The catalytically active enzyme, however, is required to observe 6.5 and 4.8S complexes after cytosol incubations at 25 degrees C. Placental ribonuclease inhibitor prevents the appearance of RNase A-induced receptor forms at 25 degrees C, but not at 2 degrees C. Moreover, this inhibitor can prevent the 7.4 to 6.9S shift in sedimentation coefficient of receptor complexes caused by cytosol heating. Dexamethasone-receptor complexes from HeLa cell cytosol show low levels of binding to DNA-cellulose, and heating at 25 degrees C is required to observe a six-fold increase in DNA binding levels. RNase A treatment of cytosols at 2 degrees C does not result in significant enhancement in receptor complex binding to DNA. If RNase A treatment is carried out at 25 degrees C, however, DNA binding levels of receptor complexes increased by 25% over the values observed with control heated cytosol. This effect cannot be observed if RNase T1 substitutes for RNase A. Placental ribonuclease inhibitor can prevent the temperature-dependent increase in DNA binding properties of dexamethasone-receptor complexes either in the presence or absence of exogenous RNase A. These findings indicate that exogenous RNases can perturb the structure of dexamethasone-receptor complexes without being involved in the transformation process.