Estradiol dependent anchoring of the goat uterine estrogen receptor activation factor (E-RAF) at the endoplasmic reticulum by a 55 kDa anchor protein (ap55)

The primary intracellular site of localization of the estrogen receptor activation factor (E-RAF) is shown here to be the endoplasmic reticulum where the protein remains anchored through an estrogen dependent mechanism. The retention of E-RAF by the endoplasmic reticulum is facilitated by two proteins: (1) a 55 kDa anchor protein (ap55) which is an integral membrane protein of the endoplasmic reticulum. ap55 is a high affinity estrogen binding protein. A conformational change induced by estrogen binding is thought to favor the anchoring process. (2) The anchoring of E-RAF by ap55 is mediated by yet another protein. This is the 66 kDa transport protein (tp66) which recognizes ap55 on the one hand and E-RAF on the other. The presence of estradiol that saturates the hormone binding sites on ap55 appears to favor the anchoring of tp66-E-RAF complex to ap55. This interaction appears to be weakened by levels of estradiol below 7 nM concentration leading to the dissociation of the tp66-E-RAF complex from ap55. The tp66-E-RAF complex moves towards the nucleus.     

Cholesterol inhibits the nuclear entry of estrogen receptor activation factor (E-RAF) and its dimerization with the nonactivated estrogen receptor (naER) in goat uterus

An alternative form of estrogen receptor isolated from goat uterus, the nonactivated estrogen receptor (naER), has no DNA-binding function, although it is closely similar to the classical estrogen receptor (ER) in its hormone binding affinity and specificity. The naER dimerizes with a DNA binding protein, estrogen receptor activation factor (E-RAF). The heterodimer binds to the DNA. Assays carried out during the purification of E-RAF showed that an endogenous inhibitor that is heat stable and dialyzable bound to the E-RAF and prevented the formation of the heterodimer. The inhibitor has been isolated and purified. GC-MS analysis identifies this molecule to be cholesterol. Circular dichroism measurement has shown that the high-affinity binding of cholesterol to E-RAF results in subtle changes in the secondary and the tertiary structure of the protein. The E-RAF with altered conformation fails to dimerize with the naER. Instead of facilitating E-RAF entry into the nucleus, dimerization with the naER prevents it. Similarly, cholesterol binding blocks the nuclear entry of the protein, showing that E-RAF with altered conformation is incapable of interaction with the nuclear pore complex/membrane proteins. The naER-E-RAF heterodimer remains at the nuclear periphery, incapable of further transport. These results indicate the possibility that the dimerization between naER and the E-RAF takes place only within the nuclear compartment. The observation that cholesterol binding prevents nuclear entry of the E-RAF reflects the similarity of E-RAF with the sterol regulatory element (SRE) binding protein that enters the nucleus and binds to SRE only when the intracellular level of cholesterol remains low.     

Proteins which mediate the nuclear entry of goat uterine non activated estrogen receptor (naER) following naER internalization from the plasma membrane

The nuclear transport of the internalised naER is influenced by a 58 kDa protein, p58, that appears to recognize the nuclear localization signals on the naER. At the nuclear pore complex the naER-p58 complex binds to a 62 kDa protein, p62; p58 recognizes p62 in this interaction. It is further observed that p62 gets 'docked' at a 66 kDa nuclear pore complex protein, npcp66. The nuclear entry of naER is an ATP-dependent process. An ATP-dependent biphasic nuclear entry of naER, has been observed. It is possible that the docking of p58-naER complex at the nuclear pore complex and the eventual nuclear entry of naER following its dissociation from the p58 are influenced by two different ranges in the concentration of ATP. In this process, it appears that, the nuclear entry requires an additional quantum of energy, provided by the hydrolysed ATP, in contrast to the energy requirement associated with, the nuclear 'docking' event.     

Interdependence between a 55 kDa protein (p55) and a 12 kDa protein (p12) in facilitating the nuclear entry of goat uterine estrogen receptor under cell-free conditions

A 55 kDa nuclear localization signal binding protein (p55) is involved in the transport of the goat uterine estrogen receptor from the cytoplasm to the nuclear pore complex (NPC). p55 forms a complex with a 12 kDa protein (p12) which in turn becomes 'docked' at the NPC. The present study reports on the purification and functional characterization of p12. Both p55 and p12 are Mg2+-dependent ATPases. The protein-protein interactions that take place between these two molecules at the NPC cause an enhancement in the net ATPase activity associated with the protein complex. Presumably, this enhanced ATPase function helps in the final nuclear entry of the estrogen receptor; p55 remains associated with p12 at the nuclear entry site under these conditions.     

A nuclear transforming factor that converts the goat uterine nonactivated estrogen receptor to nuclear estrogen receptor II

A 62-kDa nuclear protein that transforms the goat uterine nonactivated estrogen receptor (naER) to nuclear estrogen receptor II (nER II) has been isolated and purified. This is being identified as the naER-transforming factor (naER-TF). The transformation is achieved through deglycosylation of the naER. It is observed that the naER-TF action on the naER introduces significant changes in the structural and functional features of the naER. The capacity of the naER to bind estradiol increases 8- to 10-fold, while its hormone binding affinity reduces to a considerable extent following its exposure to naER TF. There is a critical ratio in the concentration of the two proteins, the TF and the naER, that would ensure an optimum transformation process. The transformed naER is incapable of dimerization with the estrogen receptor activation factor (E-RAF).     

Nuclear estrogen receptor II (nER-II) is involved in the estrogen-dependent ribonucleoprotein transport in the goat uterus I. Localization of nER-II in snRNP.

Exposure of goat uterine nuclei to estradiol in vitro results in an immediate exit of ribonucleoproteins (RNP) from the nuclei to the medium. This RNP exit appears to be mediated by an estrogen receptor localized in small nuclear ribonucleoproteins containing U1 and U2 snRNA. Available evidence indicates that the estrogen receptor involved is not the ERalpha, but an alternative form, which is also a 66 kDa protein. This is the nuclear estrogen receptor II (nER-II) that has no DNA-binding capacity. The transport is estrogen-specific since non-estrogenic steroids do not stimulate the transport of the RNP where the receptor is localized.     

Import and export of nuclear proteins: Focus on the nucleocytoplasmic movements of two different species of mammalian estrogen receptor

There is a wealth of information regarding the import and export of nuclear proteins in general. Nevertheless, the available data that deals with the nucleocytoplasmic movement of steroid hormone receptors remains highly limited. Some research findings reported during the past five years have succeeded in identifying proteins related to the movement of estrogen receptor from the cytoplasm to the nucleus. What is striking in these findings is the facilitatory role of estradiol in the transport process. A similar conclusion has been drawn from the studies on the plasma membrane-to nucleus movement of the alternative form of estrogen receptor, the non-activated estrogen receptor (naER). The internalization of naER from the plasma membrane takes place only in the presence of estradiol. While the gene regulatory functions of ER appear to get terminated following its ubiquitinization within the nucleus, the naER, through its deglycosylated form, the nuclear estrogen receptor II (nER II) continues to remain functional even beyond its existence within the nucleus. Recent studies have indicated the possibility that the estrogen receptor that regulates the nucleo cytoplasmic transport of m RNP is the nERII. This appears to be the result of the interaction between nERII and three proteins belonging to a group of small nuclear ribonucleo proteins (snRNP). The interaction of nERII with two of this protein appears to activate the inherent Mg²⁺ ATPase activity of the complex, which leads to the exit of the RNP through the nuclear pore complex.     

MS-KIF18A, a kinesin, is associated with estrogen receptor

The study of MS-KIF18A kinesin protein is focused on its cellular distribution and association with a cargo protein. Indirect immunofluorescence (IF) analyzed the intracellular distribution of endogenous MS-KIF18A and the transfected enhanced green fluorescence protein (eGFP)-MS-KIF18A in osteogenic cells. In both cases, the proteins were localized at the plasma membrane, cytosol, and nucleus. Bioinformatics analysis suggested interactions between MS-KIF18A and estrogen receptor (ERalpha) which were further elucidated by immunoprecipitation (IP). We identified interaction between endogenous MS-KIF18A with 66 and 46 kDa isoforms of ERalpha in MBA-15 cells. Moreover, MS-KIF18A and 66 kDa ERalpha complex has been demonstrated between ectopically expressed proteins in COS-7 cells. We have shown that anti-MS-KIF18A antibody immunoprecipitated the ERalpha and pERK in cells challenged with 17beta-estrogen (17beta-E2). The hormone activation induced mitogen-activated protein kinases (MAPK) pathway and increased p-ERK. The activation was interfered when cells were pre-treated with either ICI-182,780 or MAPK inhibitor PD98059 prior the challenge with 17beta-E2 that resulted in a decrease in association between MS-KIF18A and p-ERK1/2. The obtained results suggest a role for the proteins in a non-genomic response of MBA-15 cells challenged with 17beta-E2. This study presents a novel interaction between MS-KIF18A and ER that may have important physiological and pharmacological implications for estrogen action in various cells.     

Computational and biochemical identification of a nuclear pore complex binding site on the nuclear transport carrier NTF2

Nuclear transport carriers interact with proteins of the nuclear pore complex (NPC) to transport their cargo across the nuclear envelope. One such carrier is nuclear transport factor 2 (NTF2), whose import cargo is the small GTPase Ran. A domain highly homologous to the small NTF2 protein (14kDa) is also found in a number of additional proteins, which together make up the NTF2 domain containing superfamily of proteins. Using structural, computational and biochemical analysis we have identified a functional site that is present throughout this superfamily, and our results indicate that this site functions as an NPC binding site in NTF2. Previously we showed that a D23A mutant of NTF2 exhibits increased affinity for the NPC. The mechanism of this mutation, however, was unknown as this region of NTF2 had not been implicated in binding to NPC proteins. Here we show that the D23A mutation in NTF2 does not result in gross structural changes affecting other known NPC binding sites. Instead, the D23 residue is located in an evolutionarily important region in the NTF2 domain containing superfamily, that in NTF2, is involved in binding to the NPC.     

Binding of estrogen and progesterone-BSA conjugates to glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and the effects of the free steroids on GAPDH enzyme activity: physiological implications

In this study rat brain solubilized plasmalemma-microsomal fractions (B-P3) or cytosolic fractions were applied to P-3-BSA (progesterone linked to BSA at C-3 position) and E-6-BSA (17beta-estradiol linked to BSA at C-6 position) affinity columns. It is interesting that a 37 kDa protein was retained by both columns which was identified as glyceraldehyde-3-phosphate dehydrogenase (GAPDH) by N-terminal sequencing. The 37 kDa protein (GAPDH) was not retained by either a control BSA conjugated affinity column or a corticosterone-BSA affinity column. E-6-BSA bound to GAPDH with higher binding affinity than P-3-BSA or T-3-BSA (testosterone linked to BSA at C-3 position) affinity columns. In addition, the binding of 17beta-E-6-BSA to GAPDH was impeded by free estrogen (17beta-estradiol) completely. Binding studies of E-6-BSA and P-3-BSA to commercial GAPDH from rabbit skeletal muscle using radiolabeled ligand binding assays revealed that P-3-BSA had 10x lower GAPDH binding affinity than E-6-BSA. Next, the effects of estrogen and progesterone on GAPDH activity were studied. Rapid and significant increases in V(max) and changes in K(m) were observed by the addition of 10 nM estradiol, whereas 100 nM progesterone decreased only V(max) significantly. Testosterone, corticosterone, 17alpha-estradiol, and diethylstilbestrol did not affect the enzyme activity. The results indicate that GAPDH is a target site for 17beta-estradiol and progesterone and suggest possible roles in the regulation of cellular metabolism and synaptic remodeling in which GAPDH has been reported to be involved.     

Characterisation of nuclear pore complex oxalate binding protein from human kidney

Both rat and human kidney nuclei exhibited time and pH dependent oxalate or histone-oxalate uptake which was inhibited by anion transport inhibitor, 4,4-dithiocyanostilbene-2,2-disulphonic acid. Sodium chloride had no effect. Nuclear membrane had oxalate binding at pH 7.4. Extraction of nuclear membrane by Triton–high salt mixture showed maximal oxalate binding activity with nuclear pore complex while nuclear lamin had no oxalate binding. The rat and human kidney nuclear pore complex showed oxalate binding of 144 and 220 pmoles/mg protein respectively. Subsequent purification of the protein on diethyl amino ethyl–Sephadex A 50 column and Sephadex G-200 column yielded 4-fold purification. The protein revealed a molecular weight of 205 kDa on SDS-PAGE. The protein was found to be saturable at 2 M oxalate and had a Kd of 2.98 pM and a Bmax of 197 pmoles. Antibody for 205 kD was separated from primary biliary cirrhosis serum containing auto antibody against 205 kDa using affinity column chromatography. The oxalate binding activity as well as the nuclear uptake of oxalate or histone-oxalate were inhibited by its antibody.     

Nuclear estrogen receptor II (nER-II) is involved in the estrogen-dependent ribonucleoprotein transport in the goat uterus: II. Isolation and characterization of three small nuclear ribonucleoprotein proteins which bind to nER-II.

Three proteins of a goat uterine small nuclear ribonucleoprotein (snRNP) fraction, which bind to nuclear estrogen receptor-II (nER-II) have been isolated and purified. These are the p32, p55, and p60 of which p32 is the major nER-II binding protein. Indirect evidence reveals that p32 binds to the nuclear export signal (NES) on the nER-II. nER-II is a snRNA binding protein while p32 does not bind to the RNA. nER-II along with p32 and p55 form an effective Mg(++)ATPase complex, the activation of which appears to be the immediate reason behind the RNP exit from the nuclei following estradiol exposure. The three nER-II binding proteins bind to the nuclear pore complex; nER-II does not possess this property.     

Progesterone abbreviates the nuclear retention of estrogen receptor in the rat oviduct and counteracts estrogen action on egg transport

Progesterone has synergistic or antagonistic effects on several estrogenic actions. The effects of progesterone on estrogen-induced accelerated ovum transport and on the dynamics of estrogen receptors in the rat oviduct were examined. The involvement of the progesterone receptors in these phenomena was assessed. On Day 1 of pregnancy, rats were treated with estradiol, estradiol plus progesterone, or either one plus the progesterone receptor-blocking agent RU486. Control animals received the oil vehicle alone. The number of eggs remaining in the oviduct was assessed 24 h after treatment. Cytoplasmic and nuclear estrogen receptor levels in the oviduct, as well as plasma concentrations of estradiol and progesterone, were measured at various intervals--up to 11 h and 24 h after treatment, respectively. Accelerated oviductal egg transport induced by estrogen was blocked by the concomitant administration of progesterone. This effect of progesterone was not associated with changes in estrogen circulating levels and was preceded by a reduction in the total amount of estrogen receptors and by a shortened retention of estrogen receptors in the nucleus. The effects of progesterone on egg transport and on the levels of estrogen receptors were reversed by blocking the progesterone receptor with RU486, suggesting that both effects were receptor-mediated. These findings demonstrate that progesterone antagonizes the effect of estrogen on oviductal egg transport in the rat, and suggest that this antagonism is mediated by a reduction both in the amount of estrogen receptors and in their retention time in the nucleus.     

Protein-protein interactions that precede the nuclear entry of goat uterine estrogen receptor under cell-free conditions

Mechanisms associated with a regulated nuclear entry of the goat uterine estrogen receptor (gER), under the influence of estradiol, have been examined using a cell-free system. The gER transport into the nucleus is mediated by a 55-kDa cytosolic protein, p55. Experimental evidence has been provided to demonstrate that p55 binds to the nuclear localization signals (NLS) on the gER. Under hormone-free conditions, a 28-kDa protein, p28, binds to the NLS and prevents the p55 interaction with the NLS. This inhibition is reversed by a 73-kDa protein, p73. It appears that p73 associates with the hormone binding domain (HBD) of the gER under hormone-free conditions. Estradiol binding to the HBD facilitates p73 interaction with p28. This leads to the dissociation of p28 from the NLS, which, in turn, facilitates the binding of p55 to the NLS on the gER. Both p28 and p55 cross-react with monoclonal antibodies against hsp-25 and hsp-70, indicating a possibility that p28 and p55 belong to a superfamily of molecular chaperones. J. Cell. Biochem. 78:650-665, 2000.     

Identification and characterization of nuclear location signal-binding proteins in nuclear envelopes

A radioiodinated, photoactivable synthetic nonapeptide corresponding to the nuclear location signal (NLS) of SV40 large T antigen has been used in photolabelling reactions with purified mouse liver nuclei, nuclear envelopes and other cellular fractions, to identify specific NLS-binding proteins which may be involved in selective transport of karyophilic proteins. SDS-polyacrylamide gel analysis of photolabelled products demonstrates that a 60 kDa nuclear protein and four nuclear envelope proteins (67, 60, 53 and 47 kDa) bind specifically to the native NLS and not to a mutant NLS or unrelated sequences. This binding shows saturation kinetics, with highest affinity of the NLS for the 60 and 67 kDa proteins. The nuclear 60 kDa NLS-binding protein is identical to the nuclear envelope 60 kDa NLS-binding protein by two-dimensional gel analysis of labelled proteins. Biochemical fractionation of labelled nuclear envelopes suggests that the 53 and 47 kDa proteins are peripheral membrane proteins whereas the 67 and 60 kDa proteins can be localized to the pore complex. The NLS also binds to solubilized 67, 60, 53 and 47 kDa proteins but with decreased affinity. Our results suggest that one of the early steps in selective nuclear transport of proteins may be the recognition of the NLS by the 60 kDa and/or 67 kDa binding proteins present in the nuclear pore complex.