Androphilic proteins in cytosols of human benign prostatic hypertrophy.

To examine the properties of androphilic proteins in human benign prostatic hypertrophy, the binding capacity and affinity of the proteins were determined after acetone-treatment, ammonium sulfate precipitation and chromatographies of DEAE and Sephadex G-200. Androphilic proteins in the extract of acetone-dried cytosol from the hypertrophic human prostate was precipitated at 30-50% saturation of ammonium sulfate. The binding of this fraction to dihydrotestosterone and testosterone was high affinity, but the binidng to estradiol-17 beta was the one of non-specific. Androphilic proteins in the 30-50% fraction were eluted from DEAE-cellulose column by buffer containing 0.05 M KCL. On Sephadex G-200 chromatography of 30-50% fraction, the androphilic proteins were observed in three peaks; one was eluted in the void volume and other two were eluted at the sites of IgG and albumin. The amount and ratio of proteins eluted in the void volume and the site of IgG from Sephadex G-200 column were variable in individual tissue samples. The chromatographic behavior of the 30-50% fraction in Sephadex G-200 was not changed significantly by introducing 0.4 M KCl in the system. Polyacrylamide gel electrophoresis was applied for further separation of the proteins.     

Inhibition by various steroids on dihydrotestosterone binding to androphilic protein in human benign prostatic hypertrophy.

The effect of various steroidal compounds on the binding of the androphilic protein to dihydrotestosterone in the cytosol of tissues of human benign prostatic hypertrophy was examined. Androgens, as well as estrogens and gestagens showed an inhibitory effect on the binding. Non-steroidal anti-androgens were revealed to be weak inhibitors on the binding. Two androphilic proteins were observed in Sephadex G-200 chromatography in fractions eluted at the void volume and in fractions appearing at the site of IgG, and the rate of inhibition on the binding of both fractions by various steroids was compared. The rate of inhibition by various compounds was generally higher in the IgG fraction than in the void volume fraction. When the ligand and inhibitors were incubated with the cytosol prior to fractionation by Sephadex chromatography, rate of inhibition was lower than that obtained when the ligand and inhibitors were reacted with fractions after chromatography. Implications of the difference observed in these two experiments are not clear at this moment. The results obtained by the protamine precipitation experiment were almost the same as those by the experiment using the extract of the unfractionated acetone-dried cytosol, therefore, the protamine procedure does not seem to precipitate the tissue specific androphilic protein specifically.     

Studies on the nuclear binding of steroid hormone-receptor complex; characteristics of binding of nuclei from fetal rat liver to 3H-dexamethasone-liver cytoplasmic receptor complex

Binding of 3H-dexamethasone (Dex)-rat liver cytoplasmic receptor complex to nuclei from fetal rat livers in vitro exhibited a high-affinity and saturable nature (Kd=1.5 X 10- M, maximal binding sites=470 fmole/mg DNA), and the binding was inhibited competitively by prior injection of Dex in vivo. While binding of 3H-Dex-receptor complex to nuclei from adult rat liver was in low affinity and unsaturable, and injection of Dex prior to the sacrifice of animals did not influence the nuclear binding to 3H-Dex-receptor complex in vitro. Differential salt-extraction with KCl solution of the nuclear bound 3H-Dex receptor complex revealed the presence of salt-extractable and residual forms of bound receptors. The amount of the fraction extracted with 0.3 M KCl reached its maximum at 10 min after the start of incubation, while the 1.0 M KCl-extractable and residual fractions reached their maximum plateaus after 30 min of the incubation. Scatchard analysis revealed that the binding of the receptor complex to the 0.3M and 1.0M KCl fractions was saturable, while the residual fraction did not show any tendency of saturation under the experimental conditions employed in the present study. The results obtained in this work were compared to those which have been reported by other investigators.     

Receptor recycling: liberation of glucocorticoid receptors from liver nuclei in vitro

Dynamics of the steroid receptors seems to be the consequence of receptor recycling. In the present study, as a clue to elucidate the mechanism of receptor recycling, factors which affect the rate of liberation of nuclear bound 3H-glucocorticoids were examined in vitro. Among the factors examined, NAD, NADPH, cAMP and p-nitrophenyl phosphate accelerated the liberation of radioactivity from nuclei in a temperature-dependent manner when added to the incubation mixture. The presence of a large amount of unlabeled dexamethasone (Dex) did not modify the rate of liberation. From these results, it was concluded that the metabolism of ligand bound to the receptor is not a necessary step in the liberation of receptor from nuclei. These agents did not influence the binding process of 3H-Dex-receptor complex to DNA-cellulose. Therefore the stimulation of receptor release does not seem to be mediated by reducing the binding affinity between nuclei and receptor complexes. The liberated radioactivity was eluted on a Sephadex G-100 column in the void volume and in macromolecule-unbound fractions. In both fractions, the majority of the radioactivity comigrated with authentic glucocorticoids on thin-layer chromatography.     

The nuclear matrix is the site of glucocorticoid receptor complex action in the nucleus

Binding of highly purified glucocorticoid receptor complexes to nuclear matrix was evaluated. Extraction of purified nuclei with 2M potassium chloride and brief deoxyribonuclease digestion leaves a matrix structure containing 1% of nuclear DNA and 6-12% of nuclear proteins. The nuclear matrix retained two binding sites for receptor complexes, a high affinity, low capacity site and a low affinity, high capacity site. These sites have affinities and capacities consistent with those reported for binding of these complexes to intact nuclei. More extensive deoxyribonuclease treatment of the matrix resulted in a marked reduction of high affinity complex binding. Furthermore, the DNA binding form of the receptor complex but not the unactivated receptor complex bound to DNA fibers anchored to nuclear matrix as visualized by 18 nm gold particle receptor complexes. The data suggest that the nuclear matrix is the major site for coordinating glucocorticoid hormone action in the nucleus.     

Binding to R 1881 (methyltrienolone) of proteins from human benign prostatic hypertrophy

Cytosol of human benign prostatic hypertrophy bound to R 1881 in a high affinity manner. Most of the protein which bound to R 1881 was recovered in the precipitate of a 0-30% saturation of ammonium sulfate, and was eluted in the void volume on a Sephadex G-200 column. The binding of cytosol to R 1881 was more inhibited by progestins than by dihydrotestosterone and estradiol-17 beta. The binder therefore seemed to be different from dihydrotestosterone-binding protein. The R 1881-binding component extracted from the nuclei by 0.4M KCl bound also to dihydrotestosterone in a high affinity manner. Cytosol prelabeled with R 1881 was bound to the nuclei in a nonsaturable process, and the extraction pattern of R 1881 by 0.4M KCl from the nuclei was almost identical to that in the case of dihydrotestosterone as the ligand. These results suggested that a part of the cytosolic protein which bound to R 1881 entered the nuclei where it bound to nuclear such components as dihydrotestosterone-binding protein.     

Recombinant, truncated CD4 molecule (rT4) binds IgG

CD4 is a cell surface glycoprotein that identifies the subset of human T lymphocytes that induces sIg+ B lymphocytes to differentiate and secrete Ig after intimate T-B cell contact. In the course of studying a recombinant, truncated form of CD4 (rT4) we noticed that goat antibodies of apparently irrelevant specificities bound to immobilized rT4. To directly study whether rT4 interacts with Ig molecules, purified human IgG was added to rT4-coated wells and a dose-dependent interaction between IgG and rT4 was observed by ELISA. Purified myeloma IgG proteins bound to immobilized rT4 with the same avidity as polyclonal IgG that suggests that rT4-IgG binding was not due to the presence of anti-rT4 antibodies in the IgG fraction. IgG from 6 sera bound to rT4 in concentration dependent manner similar to purified IgG. Immobilized rT4 specifically bound IgG, and not IgM, IgA, IgD, or beta 2-microglobulin. The specific interaction of rT4 and IgG was also observed when IgG or IgM were immobilized, demonstrating that IgG binding was not a unique property of immobilized rT4. As with low affinity receptors for IgG, rT4 bound heat aggregated IgG with increased avidity. Neither anti-CD4 mAb nor dextran sulfate inhibited rT4-IgG binding. rT4 bound Fc but not F(ab)2 fragments. Each of the purified IgG subclasses; IgG1, 2, 3, and 4 bound to rT4 with similar avidity. Taken together, these data suggest that rT4 specifically interacts with a public structure on IgG Fc.     

Binding of progesterone receptor by nuclear preparations of rabbit and guinea pig uterus.

Guinea pig and rabbit uterine nuclei bound [3H] progesterone in vitro only in the presence of cytosol from estrogen-stimulated uteri. Nuclei from unstimulated and estrogen-stimulated uteri bound progesterone equally well. Nuclei of nontarget tissues also bound progesterone, but to a lesser extent. The rate of nuclear bindins increased with temperature from 0-30 degrees. At 25 degrees nuclear binding remained stable for at least 3 h, but at temperatures of 30 degrees and greater, nuclear binding decreased rapidly after 15 min. Activation of the progesterone-cytoplasmic receptor complex (the change in the complex that enables it to bind quickly to nuclei at 0 degrees) took place slowly at temperatures from 0-5 degrees and rapidly at 10-25 degrees. Activation was facilitated by dilution of the cytosol. Some activation occurred in diluted cytosol in the absence of added progesterone. The cytoplasmic progesterone receptor had a sedimentation coefficient of 7 S when concentrated cytosol (20 mg of protein/ml) was incubated with progesterone at 0 degrees in 5 mM phosphate buffer. Diluting the cytosol and increasing the temperature to 20 degrees caused the sedimentation coefficient to decrease to 5.5 S. Gel filtration of guinea pig uterine cytosol on Sephadex G-100, in the absence of progesterone, yielded a progesterone-binding fraction in the void volume, with a sedimentation coefficient of 5.5 S. The complex of progesterone with the material in the void volume was taken up by nuclei at 0 degrees more rapidly than the complex of progesterone and crude cytosol. The nuclear uptake of progesterone was decreased in phosphate buffer of concentrations greater than 80 mM. Under conditions that favor the nuclear binding of progesterone, the sedimentation coefficient of the cytoplasmic progesterone receptor was 5.5 S. This may be the form of the preceptor which is taken up by nuclei. In decreasing order of effectiveness, unlabeled progesterone, 5 alpha-pregnane-3,20-dione, corticosterone 20 alpha-hydroxy-4-pregnen-3-one, testosterone, estradiol-17 beta, and cortisol competed with [3H] progesterone for binding to nuclei.     

Uptake of oestradiol by the rabbit hypothalamus. Specificity of binding by nuclei in vitro

The binding of [6,7-(3)H]oestradiol-17beta to subcellular fractions of the hypothalamus and the cerebellum of the rabbit was studied in vitro. Uptake of steroid was higher in hypothalamic nuclei than in cerebellar nuclei. Lower binding was observed in other fractions of both tissues. After dialysis of the fractions, hypothalamic nuclei retained a high percentage of oestradiol whereas cerebellar nuclei lost most of the bound steroid. Supernatant fractions of both tissues retained a significant proportion of label after dialysis and after gel filtration on Sephadex G-200. No specific binding was observed in these fractions when subjected to sucrose-density-gradient centrifugation. Purification of nuclei followed by incubation with labelled oestradiol in the absence of the supernatant fraction resulted in loss of binding of steroid by hypothalamic nuclei. Incubation of the purified hypothalamic nuclei with supernatant fraction maintained the binding specificity of hormone retention.     

Specific cytosol binding of diethylstilbestrol in rat skeletal muscle

Rat skeletal muscle cytosol proteins bound ³H-diethylstilbestrol (³H-DES). More than 90% of this binding was high capacity and low affinity. Serum albumin accounted for roughly 50–60% of the binding, as evidenced by its precipitation with anti-rat albumin IgG. About half of the binding was distinguishable from albumin and other serum proteins by its precipitation in 40% saturated ammonium sulfate. This material sedimented at 4–5S in high-salt sucrose gradients, and resolved into two components (8S and 4–5S) in low-salt. Following incubation at 23–27°C for one hour, 2% of the bound ³H-DES in whole cytosol (approximately 2 fmole/mg cytosol protein) was retained by DNA-cellulose, and was eluted with 0.6 M KCl. This small fraction of the total binding was inhibited by estrogens and DES analogues: estradiol-17β, DES, dienestrol, and hexestrol were strong inhibitors; isodienestrol, dimethylstilbestrol, estradiol-17α, estrone, tamoxifen, MER-25, CI-628, and nafoxidine were weak inhibitors; dihydrotestosterone, testosterone, and prednisone did not compete. These observations indicate that specific estrogen-binding sites exist in rat skeletal muscle.     

Interaction of glucocorticoid receptor-steroid complexes with acceptor sites.

The binding of the "activated" receptor-glucocorticoid complexes of cultured rat hepatoma cells to nuclei, chromatin, and DNA has been studied under cell-free conditions. A critical factor in determining the shape of the binding curve is shown to be an inhibitory material which is present in crude cytosol and which can be removed without destroying the receptor-steroid complex. These and other results argue that the apparent saturation observed in earlier experiments may have been due to the inhibitors. Thus, the actual number of acceptor sites in hepatoma tissue culture cell nuclei is much larger than previously estimated and their affinity for the complex is lower. Nuclear binding experiments indicate that the inhibitory material interacts with the receptor-steroid complex. The inhibitors appear to be macromolecular; but their effects cannot be mimicked by albumin or hemoglobin. The acceptor capacity at low ionic strength for binding receptor-glucocorticoid complexes increases when proceeding from nuclei to DNA. An analysis of the kinetics of association and dissociation and of the relative binding behavior of nuclei and DNA argues that the affinity of complex for nuclei is much greater than for DNA. DNA-associated histones reduce the amount of complex that binds to DNA. These and perhaps other chromosomal proteins may be responsible for the ordering of acceptor capacity. Evidence is presented that the difference in affinities of nuclear and DNA acceptors could also be due to chromosomal proteins. In nuclei, these proteins may thus both reduce the amount of complex binding by rendering regions of DNA less accessible and increase the binding affinity of some, or all, of those DNA binding sites which remain exposed.     

Binding and endocytosis of heparin by human endothelial cells in culture

Binding of heparin and low molecular weight heparin fragments (CY 222, Mr range 1500-8000) to human vascular endothelial cells was studied. Primary culture of human umbilical vein endothelial cells and either 125I or 3H-labeled heparin or [125I]CY 222 were used. Slow, saturable and specific binding was found. No other tested glycosaminoglycan, excepting a highly sulfated heparan fraction, was able to compete for heparin binding. Two groups of binding sites for [3H]heparin could be distinguished: one with high affinity (Kd = 0.12 microM) and another with lower affinity (Kd = 1.37 microM) and a relative large capacity of binding (1.16 X 10(7) molecules/cell) was calculated. The Kd for unlabeled heparin, as calculated from competition experiments, was 0.23 microM. Much lower affinity was calculated for unlabeled low molecular weight heparin fragments CY 222 (Kd = 4.3 microM) from competition experiments with [125I]CY 222. The binding reversibility was only partial for unfractionated heparin. Even by chasing with unlabeled compound, a fraction of 25-30% was not dissociable from endothelial cells. This fraction was much lower if incubation was carried out at 4 degrees C. The addition of basic proteins (histones) to the incubation medium greatly enhanced the undissociable binding at 37 degrees C, but not at 4 degrees C. The undissociable fraction of heparin was not available to degradation by purified microbial heparinase. These results suggest that a fraction of bound heparin is internalized by the vascular endothelium.     

Structural studies of Fc receptors. III. Isolation and molecular weight analysis of the component chain of Fc gamma receptor of macrophage

Surface receptors of guinea pig peritoneal macrophages specific for the Fc region of IgG (Fc gamma receptor) were isolated and identified as a surface-radioiodinated component with a molecular weight of 44,000 that bound in an Fc-specific manner to IgG2 of guinea pig immunoglobulin immobilized in any of the following three different ways: IgG2 antibody in insoluble immune complex, IgG2 antibody bound to antigen-coupled Sepharose, and IgG2 covalently coupled to Sepharose. In order to obtain the Fc gamma receptor retaining the binding activity, the Fc-binding component was isolated by IgG2 affinity chromatography in which mild acidic buffer (pH 5.0-4.0) was chosen to elute the component bound to the affinity column. Forty-five to sixty-two percent of the eluted radioactivity was shown to rebind to the IgG2-affinity column. The bound fraction showed a single radioactive peak of 44,000 daltons in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The Fc-binding component isolated by the affinity chromatography behaved similarly in gel filtration in the presence of a detergent, as did the detergent-solubilized Fc gamma receptor before isolation by affinity chromatography. These results suggested that the Fc gamma receptor was isolated in a native form. Furthermore, it was confirmed that the isolated Fc gamma receptor is distinct from actin or the actin-like protein (DNase I-binding protein) which had been reported to bind to IgG-affinity column.     

Differences in the binding of 3-methylcholanthrene and phenobarbital to rat liver cytosolic and nuclear protein fractions

The inducers of cytochrome P-450c and P-450b, 3-methylcholanthrene and phenobarbital, respectively, have been studied in their interaction with subcellular fractions from rat liver. 3-Methylcholanthrene bound to both nuclear and cytoplasmic components as demonstrated by DNA-cellulose chromatography. The binding of 3-methylcholanthrene to cytosolic proteins, on DNA-cellulose, was approximately 27 fmol/mg of applied protein, whereas the binding to nuclear proteins was 250–570 fmol/mg applied protein. Phenobarbital did not bind to proteins of rat serum, rat liver cytosol, or rat liver nuclei which could bind to DNA-cellulose. Further examination of the potential interaction of phenobarbital to rat liver cytosolic proteins was carried out using either DEAE A-50 Sephadex chromatography, charcoal dextran analysis, or sucrose density gradients. No binding of phenobarbital to rat liver cytosolic proteins was observed under these experimental conditions. In contrast, the binding of 3-methylcholanthrene to cytosolic proteins showed four peaks of radioactivity after DEAE A-50 Sephadex chromatography, two peaks by sucrose density gradient analysis, and specific binding (0.13 pmol/mg protein) was observed using the charcoal dextran technique. One of the peaks on sucrose gradients was labile in the presence of salt. The uptake and intranuclear distribution of 3-methylcholanthrene and phenobarbital were markedly different after incubation with whole nuclei: 64% of the available 3-methylcholanthrene but only 3% of the available phenobarbital radioactivity became associated with nuclei. Of this radioactivity, the highest specific activity of the 3-methylcholanthrene radioactivity was associated with the 2 m KCl-resistant nuclear pellet and the highest specific activity of the phenobarbital radioactivity was associated with the nuclear fraction soluble in the absence of salt. These results are interpreted in regard to the induction of cytochrome P-450c.     

Action of heparin on protein fractions of isolated nuclei and on their DNA content

Summary Isolated nuclei of rat hepatocytes were incubated with 0.05% sodium heparinate for 2 to 10 min. Alterations in the nuclei were controlled biochemically, determining the amounts of DNA and histones, and by cytophotometric methods determining the amounts of total and nonhistone proteins and DNA. Under the selected experimental conditions 95% of histones are bound already after 5-min incubation with heparin; nonhistone proteins of cell nuclei remain unchanged. The blockade of histones is followed by DNA diffusion into the incubation medium. Experiments with nuclear staining with alcian blue proved the specificity of heparin binding with histones and showed that heparin-histone complex remains in the nuclei, and its histones lose their extractability with 0.25 n HCl.     

Action of heparin on protein fractions of isolated nuclei and on their DNA content.

Isolated nuclei of rat hepatocytes were incubated with 0.05% sodium heparinate for 2 to 10 min. Alterations in the nuclei were controlled biochemically, determining the amounts of DNA and histones, and by cytophotometric methods determining the amounts of total and nonhistone proteins and DNA. Under the selected experimental conditions 95% of histones are bound already after 5-min incubation with heparin; nonhistone proteins of cell nuclei remain unchanged. The blockade of histones is followed by DNA diffusion into the incubation medium. Experiments with nuclear staining with alcian blue proved the specificity of heparin binding with histones and showed that heparin-histone complex remains in the nuclei, and its histones lose their extractability with 0.25 n HCl.     

Characterization of high affinity and low affinity dexamethasone binding sites on male rat liver nuclear envelopes

Steroids must traverse the nuclear envelope before exerting their action at the chromatin. However, few studies have been done to elucidate the mechanism by which steroids traverse this membrane barrier. As first steps towards investigating the mechanism, we have characterized the binding sites for dexamethasone on male rat liver nuclear envelopes. The nuclear envelopes, prepared in the presence of dithiothreitol, were isolated from purified nuclei after treatment with DNase 1 at high pH. Binding of dexamethasone to the nuclear envelopes was measured after 16 h of incubation at 0-4 degrees C. At pH 7.4, only a single high capacity, low affinity binding site for dexamethasone was identified. However, at pH 8.6, two sites were identified; a low capacity, high affinity site and a high capacity, low affinity site. Adrenalectomy of the animal before preparation of the membranes caused loss of the high affinity site and reduction in the number of the lower affinity sites. Acute dexamethasone treatment of adrenalectomized rats resulted in the reappearance of the high affinity site but long term treatment with dexamethasone was required for complete restoration of the high affinity sites and reappearance of any of the low affinity sites. The steroid specificity of these nuclear envelope binding sites was different from that of the cytosolic glucocorticoid receptor, generally showing broader specificity. However, triamcinolone acetonide, which is a potent competitor for binding to the glucocorticoid receptor, did not complete effectively. The binding sites were sensitive to protease treatment and salt extraction studies revealed that the dexamethasone binding sites do not represent proteins non-specifically bound to the nuclear envelope. The affinity and the hormone responsiveness of the high affinity site are similar to those of the nuclear glucocorticoid receptor. Therefore, the nuclear envelope may be a site of action of glucocorticoids.     

Z protein: Isolation and characterization of multiple forms in rat liver cytosol

The Z protein fraction of rat liver cytosol contains one or more proteins which have been associated with organic anion transport, fatty acid metabolism, and aminoazodye binding. To study the possible identity of these proteins and investigate their function, Z was purified using ammonium sulfate fractionation, gel filtration, and preparative isoelectric focusing. Three protein fractions were obtained (pI 5.2, 6.0, 7.3) which reacted specifically with anti-Z IgG. These three fractions were homogenous as determined by several electrophoretic systems. Monospecific antibody prepared against two of the proteins cross-reacted specifically with all three. Each fraction bound BSP with different affinity; acidic Z bound the least BSP. The molecular weight of each fraction was 12,500 as determined by SDS-gel electrophoresis. Amino acid analyses of the three Z protein bands were virtually identical. Heterogeneity in Z probably results from interaction of the protein with ampholytes or exogenous ligands.     

Anti-DNA activity of IgG F(ab')2 from normal human serum.

The components of normal human serum (NHS) which bound DNA in a standard assay for anti-DNA antibody were characterized. IgG was the major detectable protein isolated from NHS by affinity chromatography on DNA-cellulose. A second adsorption of the whole serum IgG with DNA-cellulose did not remove additional gamma-globulin indicating that only a very small fraction of the IgG was capable of binding DNA. This binding activity was largely restricted to denatured DNA. IgG (Fab')2 bound DNA as well as the intact molecules demonstrating the antibody-like nature of the IgG binding. These results suggest that IgG antibody to denatured DNA is a normal component of human serum.     

Mechanism of resistance to lysis by the alternative complement pathway in Trypanosoma cruzi trypomastigotes: effect of specific monoclonal antibody

Trypanosoma cruzi G strain epimastigotes were lysed by normal human serum (NHS) through activation of the alternative complement pathway (ACP), whereas metacyclic trypomastigotes were resistant to lysis. Epimastigotes and metacyclics with equivalent amounts of C3b deposited on their surface bound factor B with similar affinities. In contrast, factor H bound with higher affinity to metacyclics than to epimastigotes. Both T. cruzi forms with bound C3b were extensively (60 to 80%) lysed after formation of surface C3-convertase and the addition of a C3-C9 complement source. In the presence of factors H and I, or incubation with NHS with EDTA, the percentage of lysis of metacyclics decreased faster than that of epimastigotes with increasing incubation times. These data suggest, as a possible mechanism of resistance to lysis in metacyclic trypomastigotes, the higher binding affinity of factor H to C3b and the inactivation of the latter by serum regulatory proteins. Metacyclics were lysed by NHS, through ACP, in the presence of human immune serum to T. cruzi or anti-T. cruzi monoclonal antibody, but not with the Fab fragment of the latter, which recognizes a 90,000 m.w. antigen from T. cruzi metacyclics. Protection of parasite-bound C3b from serum control proteins was observed when parasites were incubated, before C3 deposition, with the lytic monoclonal antibody but not with its Fab fragment or a nonrelated IgG control. When C3b was deposited on metacyclics before antibody binding, C3b inactivation occurred. In the lysis of metacyclics, through ACP activation, binding of antibody apparently creates new acceptor sites which prevent the activity of serum regulatory proteins.