Recessive mutations in a common pathway block thymocyte apoptosis induced by multiple signals.

The glucocorticoid receptor (GR) is a ligand-regulated transcription factor that controls genes necessary to initiate glucocorticoid-induced thymocyte apoptosis. We have performed a genetic analysis of thymocyte cell death by isolating and characterizing a panel of GR+ dexamethasone-resistant mutants of the murine WEHI7.2 thymocyte cell line. These apoptosis-defective (Apt-) mutants were used to identify previously unknown early steps in the apoptotic pathway. The Apt- mutants contain nonglucocorticoid receptor, recessive mutations in genes that represent multiple complementation groups. These mutations block apoptosis induced by dexamethasone, gamma irradiation, and c-AMP treatment before the point where Bcl-2 exerts its protective effect. We propose that different signals share a common apoptotic pathway, and that the induction of apoptosis involves multiple precommitment steps that can be blocked by recessive mutations.

Transcriptional transactivation functions localized to the glucocorticoid receptor N terminus are necessary for steroid induction of lymphocyte apoptosis.

Genetic studies have suggested that transcriptional regulation of specific target genes (by either induction or repression) is the molecular basis of glucocorticoid-mediated lymphocyte apoptosis. To examine the role of transcriptional regulation more directly, we developed a complementation assay utilizing stable transfection of wild-type (wt) and mutant (nti) glucocorticoid receptor (GR) cDNA constructs into a GR-deficient S49 murine cell line (7r). Our data confirm that the level of functional GR is rate limiting for S49 apoptosis and moreover that the GR amino terminus (N terminus), which as been deleted from the nti GR, is absolutely required for complementation in this system. Surprisingly, we found that at physiological levels of receptor, expression of the nti GR in cells containing wt GR results in enhanced dexamethasone sensitivity rather than a dominant negative phenotype. One interpretation of these data is that DNA binding by wt-nti heterodimers may be functionally similar to that of wt-wt homodimers, indicating that GRE occupancy by at least one transactivation domain may be sufficient to induce the hormonal response. To determine whether acidic activating sequences such as those localized to the GR N terminus are important in the induction of lymphocyte apoptosis, we tested the activity of a chimeric receptor in which we replaced the entire GR N terminus with sequences from the herpes simplex virus VP16 protein. Our results demonstrate that 7r cells expressing VP-GR fusions are indeed steroid sensitive, strongly supporting the idea that S49 apoptosis is dependent on transcriptional regulation of specific genes which respond to acidic activating domains, implying that induction, rather than repression, may be the critical initiating event.

Evidence that glucocorticoid- and cyclic AMP-induced apoptotic pathways in lymphocytes share distal events.

WEHI7.2 murine lymphocytes undergo apoptotic death when exposed to glucocorticoids or elevated levels of intracellular cyclic AMP (cAMP), and these pathways are initiated by the glucocorticoid receptor (GR) and protein kinase A, respectively. We report the isolation and characterization of a novel WEHI7.2 variant cell line, WR256, which was selected in a single step for growth in the presence of dexamethasone and arose at a frequency of approximately 10(-10). The defect was not GR-related, as WR256 expressed functional GR and underwent GR-dependent events associated with apoptosis, such as hormone-dependent gene transcription and inhibition of cell proliferation. Moreover, the glucocorticoid-resistant phenotype was stable in culture and did not revert after treatment with 5-azacytidine or upon stable expression of GR cDNA. In addition, WR256 did not exhibit the diminished mitochondrial activity commonly associated with apoptosis. Interestingly, WR256 was also found to be resistant to 8-bromo-cAMP and forskolin despite having normal levels of protein kinase A activity and the ability to induce cAMP-dependent transcription. We examined the steady-state transcript levels of bcl-2, a gene whose protein product acts dominantly to inhibit thymocyte apoptosis, to determine whether elevated bcl-2 expression could account for the resistant phenotype. Our data showed that bcl-2 RNA levels were similar in the two cell lines and not altered by either dexamethasone or 8-bromo-cAMP treatment. These results suggest that WR256 exhibits a "deathless" phenotype and has a unique defect in a step of the apoptotic cascade that may be common to the glucocorticoid- and cAMP-mediated cell death pathways.

nti glucocorticoid receptor transcripts lack sequences encoding the amino-terminal transcriptional modulatory domain.

Glucocorticoid induction of cell death (apoptosis) in mouse lymphoma S49 cells has long been studied as a molecular genetic model of steroid hormone action. To better understand the transcriptional control of glucocorticoid-induced S49 cell death, we isolated and characterized glucocorticoid receptor (GR) cDNA from two steroid-resistant nti S49 mutant cell lines (S49.55R and S49.143R) and the wild-type parental line (S49.A2). Our data reveal that nti GR transcripts encode intact steroid- and DNA-binding domains but lack 404 amino-terminal residues as a result of aberrant RNA splicing between exons 1 and 3. Results from transient cotransfection experiments into CV1 cells using nti receptor expression plasmids and a glucocorticoid-responsive reporter gene demonstrated that the truncated nti receptor exhibits a reduced transcriptional regulatory activity. Gene fusions containing portions of both the wild-type and the nti GR-coding sequences were constructed and used to functionally map the nti receptor mutation. We found that the loss of the modulatory domain alone is sufficient to cause the observed defect in nti transcriptional transactivation. These results support the proposal that glucocorticoid-induced S49 cell death requires GR sequences which have previously been shown to be required for transcriptional regulation, suggesting that steroid-regulated apoptosis is controlled at the level of gene expression.

Characterization of Apt- cell lines exhibiting cross-resistance to glucocorticoid- and Fas-mediated apoptosis.

Apoptosis induction by staurosporine, ceramide, and Fas stimulation was investigated in the mouse thymoma cell line W7.2 and a panel of dexamethasone (dex)-resistant W7.2 mutant cell lines, Apt3.8, Apt4.8 and Apt5.8, and a Bcl-2 transfected W7.2 cell line (Wbcl2). While W7. 2 cells were found to be sensitive to these apoptosis inducers, the Apt- mutants and Wbcl2 cells were shown to be resistant to some or all of the treatments. Specifically, all three Apt- mutants and Wbcl2 cells were found to be resistant to ceramide and Fas-mediated apoptosis, whereas, Apt4.8 and Apt5.8 were sensitive to staurosporine-induced apoptosis under conditions in which Apt3.8 and Wbcl2 cells were resistant. Measurements of caspase activity and cytochrome c release in cytosolic extracts of dex and staurosporine-treated cells indicated that the recessive Apt- mutations effect steps upstream of mitochondrial dysfunction. Steady-state RNA levels of apoptosis-associated gene transcripts showed that the observed differential resistance of the Apt- cell lines could not be explained by altered expression of numerous Bcl-2 or Fas related genes. Transient transfection of human Fas gene coding sequences into the Apt- mutants and Wbcl2 cells did not induce apoptosis, even though these same cell lines were sensitive to ectopic expression of the FADD and caspase 8 genes. Taken together, these data provide genetic evidence for the existence of shared components in the dex- and Fas-mediated apoptotic pathways in W7.2 cells.

Isolation and characterization of transcripts induced by androgen withdrawal and apoptotic cell death in the rat ventral prostate.

A variety of stimuli have been identified which initiate transcription-dependent programmed cell death (apoptosis) in specific target cells. Since the withdrawal of androgens induces regression and apoptosis in rat ventral prostate (RVP) epithelial cells, and it is known that the androgen receptor is a transcriptional regulator, we used subtraction cDNA cloning to isolate differentially expressed transcripts from the RVP of androgen ablated rats. In addition to sulfated glycoprotein-2 and glutathione S-transferase (GST), which had been previously described, several other transcripts were found to be elevated 3- to 8-fold in the regressing RVP. DNA sequencing revealed that two of these cDNA clones encode matrix carboxyglutamic acid and gamma-actin, respectively. A third cDNA contained novel sequence information and was named RVP.1. The RVP.1 transcript is expressed at very low levels in the RVP and epididymis of normal adult rats (less than 0.01% of the total mRNA) and is undetectable in other tissues, such as kidney, liver, and muscle. RVP.1 encodes a putative 280-amino acid protein, which shares no significant homology with previously described protein functional domains. We examined the expression of these transcripts in serum-starved NIH 3T3 cells to determine whether any of them are elevated in cells that are growth arrested. It was found that only GST mRNA levels are increased under these conditions. These data may suggest that induction of some genes, such as RVP.1, could be associated with apoptosis, whereas other transcripts, such as GST, may be up-regulated in response to altered rates of cellular metabolism.

Transcriptional control of steroid-regulated apoptosis in murine thymoma cells.

Early studies in murine T cell lines indicated that transcriptional transactivation functions encoded in the glucocorticoid receptor (GR) N-terminal domain are required for glucocorticoid-mediated apoptosis. However, more recent studies in human T cell lines have suggested that the N-terminal domain is not necessary for steroid-regulated apoptosis and that GR-mediated transrepression may be the more critical mechanism. To better understand the contribution of the GR N-terminal transactivation domain in mediating murine thymocyte apoptosis, we stably transfected GR, GR variants, and the androgen receptor (AR) into receptor-negative S49 murine thymoma cells. GR expression levels were shown to be rate-limiting for initiating the apoptotic pathway, and a positive correlation between steroid sensitivity and GR-mediated induction of an integrated mouse mammary tumor virus (MMTV) LTR reporter gene was observed. Analysis of GR chimeric receptors containing the potent VP16 and E1A viral transactivation domains in place of the GR N terminus revealed that even low level expression of these receptors resulted in both enhanced steroid sensitivity and MMTV induction, thus supporting a role for transactivation in apoptosis. In contrast, we found that AR can initiate apoptosis in S49 cells after treatment with 5 alpha-dihydrotestosterone, despite its relative inability to induce high level expression of MMTV. To investigate this further, we examined the steroid-regulated expression of an endogenous thymocyte-specific gene called GIG18. We found that GIG18 was rapidly induced to comparable levels by both AR and GR, demonstrating that AR can indeed function as a transcriptional activator in S49 cells and, moreover, that GIG18 induction may be a marker of early apoptotic events in steroid-treated cells. Taken together, these results support our conclusion that transcriptional transactivation is a necessary signaling component of S49 cell apoptosis, although an additional role for GR-mediated transrepression cannot be excluded.

Functional characterizations of the androgen receptor confirm that the molecular basis of androgen action is transcriptional regulation.

In an effort to understand the molecular basis of androgen action in the prostate, we isolated androgen receptor (AR) cDNA from rat ventral prostate cells and analyzed the transcriptional regulatory activity of the encoded protein in a cotransfection assay. We found that AR is capable of inducing chloramphenicol acetyltransferase activity more than 20-fold using the mouse mammary tumor virus LTR as a source of androgen response elements. This induction was observed in both monkey CV1 cells and human HeLa cells, neither of which contains endogenous functional AR, and was entirely dependent on added androgens. Deletion mapping studies showed that carboxy-terminal deletions of approximately 250 amino acids convert AR into a constitutive activator of transcription. In addition, a chimeric receptor protein containing the amino-terminus and DNA-binding domains of AR fused to the previously defined ligand domain of the glucocorticoid receptor was found to be fully functional based on dexamethasone-induced chloramphenicol acetyltransferase activity. Our results support the prediction that androgens modulate rates of transcriptional initiation, suggesting that posttranscriptional effects of androgens are secondary responses. Moreover, these data reveal that, like other steroid receptors, AR contains a number of distinct regulatory regions important for normal activity. The isolation and characterization of fully functional AR sequences will facilitate the use of molecular genetics to study complex androgen responses in target tissues such as the prostate.

Stable expression of the calbindin-D28K complementary DNA interferes with the apoptotic pathway in lymphocytes.

The WEHI7.2 thymoma cell line undergoes apoptotic cell death when exposed to glucocorticoids and agents that increase intracellular cAMP. Several lines of evidence indicate that calcium may play an important role in events culminating in lymphocyte apoptosis. In these studies, calbindin-D28K was stably overexpressed in WEHI7.2 cells to determine if increasing the Ca(2+)-binding capacity of the cell interferes with the apoptotic pathway. Indeed, stable expression of calbindin-D28K decreased the apoptotic effects of dexamethasone and forskolin, and the level of resistance to these agents correlated with the relative amount of calbindin expressed in each line. Overexpression of calbindin also increased cell survival in the presence of the calcium ionophore A23187. The stably expressed calcium-binding protein appeared to exert its protective effect subsequent to transcriptional activation, since glucocorticoid- and cAMP-induced gene expression were not affected. These data support the proposal that calcium fluxes are involved in apoptosis and suggest that high level expression of proteins that buffer calcium fluxes can effectively suppress death in apoptosis-susceptible cells.

Transcriptional analyses of steroid-regulated gene networks.

It has been proposed that cell-specific responses to steroid action are the result of coordinate expression of steroid gene networks. Using three different cell systems, we have performed transcriptional analyses to determine if the observed hormone-induced alterations in gene expression are consistent with a limited number of potential target genes in any one cell type. Our results indicate that greater than 95% of the transcripts in dexamethasone-treated rat hepatoma (HTC), or mouse lymphoma (WEH17) cells, are similar to the mRNAs in untreated cells based on subtraction hybridization. In addition, we find that although the castration-induced expression of androgen-regulated transcripts in the rat ventral prostate (RVP) is significantly different between normal and castrated rats (19%), the majority of these mRNAs are accounted for by the over abundance of sulfated glycoprotein-2 sequences. Specifically, analysis of an RVP subtracted cDNA library revealed that sulfated glycoprotein-2 mRNA masked the presence of less abundant differentially expressed sequences, confirming that the actual size of the RVP androgen gene network is small. We conclude that steroid-mediated changes in transcription accurately reflect the expression of a few cell-specific target genes, and thus support the model of steroid gene networks. The potential to characterize key elements which determine both the time course and magnitude of cell-specific hormone responses is discussed.

Quantitative differences in androgen and glucocorticoid receptor DNA binding properties contribute to receptor-selective transcriptional regulation.

Androgen receptor (AR) and glucocorticoid receptor (GR) belong to the same subfamily of steroid/nuclear receptors and have been shown to bind qualitatively to the same hormone response element (HRE) DNA sequences. Despite this similarity in target gene recognition, AR and GR have differential affects on the transcriptional regulation of genes containing both simple and complex HRE control regions. Using HREs from the mouse mammary tumor virus (MMTV), tyrosine aminotransferase (TAT), prostatein (C3) or sex-limited protein (SLP) genes, linked to the thymidine kinase promoter, we found receptor-selective differences in the ability of rat AR and rat GR to induce transcription of these various reporter genes. Since AR and GR have a 20% amino acid sequence difference in their DNA binding domains (DBDs), which could result in altered DNA binding affinities, we measured the ability of purified AR and GR DBDs to bind selectively and with high affinity to these HRE sequences in vitro. Gel shift mobility assays showed that the GR DBD had a higher affinity for a consensus HRE than did the AR DBD, and quantitative DNase I footprinting revealed that AR and GR DBDs bound to the MMTV, TAT, C3 and SLP HREs with different affinities. It was found that AR had a dissociation constant (Kd) that was 2-3 times higher than GR on the TAT, C3 and SLP HREs and that the Kd of AR for the C3 and SLP HREs differed by an order of magnitude (43 nM and 460 nM, respectively). Taken together, these data suggest that amino acid differences in the AR and GR DBDs contribute to altered receptor-DNA interactions, however it is likely that non-receptor factors are involved in further modulating receptor-selective DNA binding and transactivation functions.

Crosstalk during Ca2+-, cAMP-, and glucocorticoid-induced gene expression in lymphocytes.

In the WEHI7.2 thymoma cell line, cAMP, glucocorticoids, or increases in cytosolic Ca2+ concentration lead to cell death by apoptosis. In the present study, we examined the effects of these compounds on cAMP response element (CRE)-mediated gene expression. Thapsigargin and A23187 were employed to increase cytosolic Ca2+ levels and induce apoptosis. Both compounds enhanced transcription from a CRE preceding apoptotic death. Moreover, the transcriptional response to the combination of forskolin and either thapsigargin or A23187 was synergistic mirroring the effect on cell death. Importantly, dexamethasone treatment, which causes an efflux of Ca2+ from the ER, induced transcription from a CRE alone or in synergy with forskolin. The increase in CRE-controlled gene expression correlated with a decrease in cell viability. Following treatment with forskolin, thapsigargin, or dexamethasone, the CRE binding protein (CREB) was phosphorylated at levels correlating with the level of induced gene expression. These data suggest that transcriptional crosstalk between independent signaling pathways occurs in lymphocytes, and CREB may play a central role in the mediation of CRE-dependent transcription by these diverse set of apoptotic agents.

Isolation of differentially expressed sequence tags from steroid-responsive cells using mRNA differential display.

Transcriptional control of steroid-regulated gene networks by nuclear receptor proteins results in the coordinate expression of a limited number of target genes. Although much is known about the structure and function of steroid receptors, relatively few cell-specific steroid-regulated genes have been isolated and characterized. In this paper we describe results using mRNA differential display reverse transcriptase PCR (DDPCR) to identify and isolate short cDNA sequence tags from thymocyte and prostate cells under various hormone conditions. Using this technique we have isolated several differentially expressed sequence tags (DESTs) from the mouse thymocyte cell line WEHI 7.2. Two of these DESTs, GIG10 and GIG18, are rapidly induced by dexamethasone within 2 h of treatment. GIG10 is a novel sequence and GIG18 is the mouse homologue of a human expressed sequence tag isolated from activated B lymphocytes. We also used DDPCR to isolate DESTs from androgen-modulated rat ventral prostate tissue, one of which we characterized and found to correspond to the 3' end of prostatic spermine binding protein mRNA, a known androgen-regulated gene. Modifications of the original DDPCR protocol, which we found can potentially decrease the frequency of isolating false-positive DESTs, are described and the merits of DDPCR, relative to other differential cDNA cloning strategies, are discussed.

Regulated expression of microinjected DNA in adult Aedes aegypti mosquitoes.

We have developed a novel molecular genetic approach to investigating gene regulation in adult mosquitoes called whole body transfection (WBT). This DNA microinjection method allows for both constitutive and regulated expression of plasmid vectors in the fat body and midgut of adult mosquitoes within 24 h of injection. Using a luciferase reporter gene containing the Aedes aegypti heat shock protein 70 (Hsp70) promoter, we optimized the WBT protocol at various times post-injection and used these parameters to measure the expression of a vitellogenin-luciferase reporter gene in response to blood meal feeding. These studies showed that a 843 bp fragment of the Ae. aegypti vitellogenin-C (VgC) promoter caused a greater than 200-fold induction of luciferase activity in a strict tissue-specific manner, and only in response to feeding. Functional mapping of the VgC promoter by WBT identified essential upstream regulatory elements in the region spanning -780 to -182 bp from the transcriptional start site. We also constructed a lipopolysaccharide-regulated expression vector using a 1096 bp genomic fragment of the Ae. aegypti cecropin B (CecB) promoter. Our data show that four days after WBT injection, the CecB-luciferase reporter gene could be induced more than 100-fold in the fat body following lipopolysaccharide injection. Moreover, we found that lipopolysaccharide-induction of the CecB reporter gene occurred up to 28 days post-WBT injection. These data suggest that WBT could provide a novel strategy to express recombinant proteins and RNAi constructs in adult mosquitoes using conventional microinjection methods.

Molecular genetics of corticosteroid action.

The recent isolation and characterization of steroid receptor coding sequences has revolutionized the field of steroid hormone action. These studies have revealed that steroid receptors are members of a much larger nuclear receptor "super family." The ligand and DNA binding domains have been shown to be molecular components that functionally interact to transform the steroid-receptor complex into a highly specific gene regulator that induces or represses the expression of cell-specific target genes. Molecular genetic approaches have been used to study structure-function relationships of several steroid receptor proteins, the most extensive analysis has been that of the glucocorticoid receptor. Several breakthroughs in the study of steroid hormone action include the construction of novel chimeric steroid receptor proteins, functional expression of steroid receptors in yeast, and the development of sensitive cloning techniques designed to isolate low abundance, hormonally regulated transcripts.

The structure and function of steroid receptor proteins.

This review has highlighted several topics in the study of steroid hormone action. The unanswered questions regarding the mechanism of ligand-controlled LRF activity, the extent of evolutionary conservation and specificity of DNA binding, and the validity of various models of transcriptional regulation mediated through gene networks point to the future direction of research in this field. Steroid hormones are used extensively in clinical treatments, especially glucocorticoids. Our laboratory is attempting to determine which gene networks are responsible for some of these clinical phenotypes. Figure 5 points out that the study of glucocorticoid action holds a unique position because it spans both the basic sciences and the field of applied molecular biology. Now that we have a fundamental knowledge of the necessary elements required for steroid-dependent regulation of gene expression, we can better investigate the clinical responses to steroid therapy (which include devastating side effects) by isolating and characterizing the important target gene(s). In this author's opinion, future directions in the study of steroid responsiveness will have to include a systematic approach toward deciphering a variety of these LRF-regulated gene networks in experimentally feasible systems. Hopefully, work in this area may be revealing and perhaps beneficial to ongoing clinical studies. In addition, the study of mechanisms of transcriptional induction and repression, using the model system of LRFs, could be applicable to many gene regulatory systems which are controlled by such processes as development and differentiation.

Adenomatous polyposis coli, protein kinases, protein tyrosine phosphatase: the effect of sulindac.

A putative explanation of the effect of sulindac on adenomatous colon and duodenal polyps from clinical observations and related in vitro experiments is presented. In cells with mutant APC genes, persistent high prostaglandin content of polyps leads to desensitization, downregulation of adenylate cyclase, uncoupling of cAMP synthesis from prostaglandin, and inactivation of protein kinase A (PKA). It is suggested that in normal cells, (APC) protein binds to catenins and microtubules to maintain structure and contribute to cell-cell communication, adherence, and the dephosphorylated state, a necessary condition for such functions. Cells with mutant APC product become isolated, deprived of communication and adhesion to other epithelial cells, overphosphorylated, and without corrective capability. The latter is largely due to downregulation of cAMP synthesis and protein kinase A activity secondary to high prostaglandin. Three main biochemical defects ensue: (1) the restrictive influence of PKA catalyzed phosphorylation of Raf-1 kinase and resultant effects on the MAP kinase cascade and transcription is lost, (2) the transcription of immediate early genes, including cyclooxygenase is stimulated, and (3) the stimulation of protein tyrosine phosphatase (PTPase) by PKA is in abeyance. These putative abnormalities are reversed by inhibition of cyclooxygenase-1 by sulindac. cAMP synthesis and PKA activity return to normal. PKA catalyzed phosphorylations block Raf-1 kinase at the confluence of the Ras and protein kinase C pathways. The MAP kinase cascade is inhibited as is transcription of immediate early genes. At the same time PKA stimulates PTPase, which dephosphorylates the cytoskeleton and restores cell-cell communication, adherence, and structure. The transformed phenotype is circumvented by adjustment of the phosphorylation state and mutant cells rejoin the epithelial community. The redox state of cytoplasm in mutant cells may be shifted toward reduction.

The length and location of CAG trinucleotide repeats in the androgen receptor N-terminal domain affect transactivation function.

Some transcription factors contain stretches of polyglutamine encoded by repeats of the trinucleotide CAG. Expansion of the CAG repeat in the androgen receptor (AR) has been correlated with the incidence and severity of X-linked spinal and bulbar muscular atrophy (Kennedy's disease). In order to understand the relationship of this mutation to AR function, we constructed ARs that varied in the position and size of the polyglutamine tract, and assayed for the abilities of these mutant receptors to bind androgen and to activate transcription of several different AR-responsive reporter genes. Elimination of the tract in both human and rat AR resulted in elevated transcriptional activation activity, strongly suggesting that the presence of the polyglutamine tract is inhibitory to transactivation. Progressive expansion of the CAG repeat in human AR caused a linear decrease of transactivation function. Importantly, expansion of the tract did not completely eliminate AR activity. We postulate that this residual AR activity may be sufficient for development of male primary and secondary sex characteristics, but may fall below a threshold level of activity necessary for normal maintenance of motor neuron function. This functional abnormality may be representative of other genetic diseases that are associated with CAG expansion mutations in open reading frames, such as spinocerebellar ataxia type I and Huntington's disease.

Delineation of two distinct type 1 activation functions in the androgen receptor amino-terminal domain.

Based on the finding that some transcription factors contain multiple transcriptional regulatory activities, we constructed a panel of rat androgen receptor (AR) mutants containing small internal deletions and point mutations within the amino-terminal region of the receptor. Trans-activation assays in CV-1 cells using AR-responsive reporter genes were performed and led to the identification of two noncontiguous trans-activation regions in the AR amino terminus. One of these regions, termed activator function 1a (AF-1a) is a highly-conserved 14-amino acid segment that is predicted to form a beta-turn followed by an acidic amphipathic alpha-helix. Point mutagenesis within AF-1a revealed that two adjacent hydrophobic residues were required for full AR trans-activation function, as arginine substitutions resulted in a 60% reduction in transcriptional activity. A second amino-terminal region was also identified and has been designated AF-1b. Deletion of the 65-amino acid AF-1b segment, which contains numerous glutamate and aspartate residues, caused a 55% decrease in trans-activation function. An AF-1a/AF-1b double mutant retains less than 10% trans-activation function compared with wild-type AR, suggesting that AF-1a and AF-1b may each contribute separately to maximal AR activity. To determine whether AF-1a and AF-1b play a role in AR-mediated trans-repression of AP-1 function, we tested single and double AF-1a/AF-1b mutants in a transient trans-repression assay. Our results showed that neither AF-1a nor AF-1b was required for AP-1 trans-repression, demonstrating that AR-mediated trans-repression and trans-activation are discrete functions.

Characterization of a panel of rat ventral prostate epithelial cell lines immortalized in the presence or absence of androgens.

We have transfected rat ventral prostate (RVP) epithelial cells with a plasmid containing the SV40 large T-antigen in an attempt to establish a panel of cell lines that will be useful in molecular genetic studies of prostate cell function. Since the distribution of cell types in the RVP is dramatically affected by androgen withdrawal and replacement, cells isolated from normal, castrated, or castrated rats that were given daily injections of testosterone were used in these experiments. Cell lines were established in media that were supplemented or depleted of androgens to accommodate the possible requirements of different prostate cell types. Numerous cell lines were isolated which retain characteristics of RVP epithelial cells and five of these cell lines were studied in detail. All five cell lines express the SV40 large T-antigen, supporting the role of this viral protein in immortalization. The RVP cell lines were shown to contain high levels of functional glucocorticoid receptors, but very low levels of androgen binding activity even though androgen receptor RNA could be detected. It was determined that the decreased androgen receptor activity in the RVP cells was apparently due to low receptor expression based on the results of transient transfection assays using androgen receptor cDNA. Taken together, the biochemical, cytological, and morphological characterizations of the RVP cell lines suggest that they may all have been derived from basal prostate epithelial cells despite the initial differences in androgen status of the animal and the level of androgens in the culture media.