RNA-Seq mapping and detection of gene fusions with a suffix array algorithm.

High-throughput RNA sequencing enables quantification of transcripts (both known and novel), exon/exon junctions and fusions of exons from different genes. Discovery of gene fusions-particularly those expressed with low abundance- is a challenge with short- and medium-length sequencing reads. To address this challenge, we implemented an RNA-Seq mapping pipeline within the LifeScope software. We introduced new features including filter and junction mapping, annotation-aided pairing rescue and accurate mapping quality values. We combined this pipeline with a Suffix Array Spliced Read (SASR) aligner to detect chimeric transcripts. Performing paired-end RNA-Seq of the breast cancer cell line MCF-7 using the SOLiD system, we called 40 gene fusions among over 120,000 splicing junctions. We validated 36 of these 40 fusions with TaqMan assays, of which 25 were expressed in MCF-7 but not the Human Brain Reference. An intra-chromosomal gene fusion involving the estrogen receptor alpha gene ESR1, and another involving the RPS6KB1 (Ribosomal protein S6 kinase beta-1) were recurrently expressed in a number of breast tumor cell lines and a clinical tumor sample.

Contrived Materials and a Data Set for the Evaluation of Liquid Biopsy Tests: A Blood Profiling Atlas in Cancer (BLOODPAC) Community Study.

The Blood Profiling Atlas in Cancer (BLOODPAC) Consortium is a collaborative effort involving stakeholders from the public, industry, academia, and regulatory agencies focused on developing shared best practices on liquid biopsy. This report describes the results from the JFDI (Just Freaking Do It) study, a BLOODPAC initiative to develop standards on the use of contrived materials mimicking cell-free circulating tumor DNA, to comparatively evaluate clinical laboratory testing procedures. Nine independent laboratories tested the concordance, sensitivity, and specificity of commercially available contrived materials with known variant-allele frequencies (VAFs) ranging from 0.1% to 5.0%. Each participating laboratory utilized its own proprietary evaluation procedures. The results demonstrated high levels of concordance and sensitivity at VAFs of >0.1%, but reduced concordance and sensitivity at a VAF of 0.1%; these findings were similar to those from previous studies, suggesting that commercially available contrived materials can support the evaluation of testing procedures across multiple technologies. Such materials may enable more objective comparisons of results on materials formulated in-house at each center in multicenter trials. A unique goal of the collaborative effort was to develop a data resource, the BLOODPAC Data Commons, now available to the liquid-biopsy community for further study. This resource can be used to support independent evaluations of results, data extension through data integration and new studies, and retrospective evaluation of data collection.

Prediction of the tissue-specificity of selective estrogen receptor modulators by using a single biochemical method.

Here, we demonstrate that a single biochemical assay is able to predict the tissue-selective pharmacology of an array of selective estrogen receptor modulators (SERMs). We describe an approach to classify estrogen receptor (ER) modulators based on dynamics of the receptor-ligand complex as probed with hydrogen/deuterium exchange (HDX) mass spectrometry. Differential HDX mapping coupled with cluster and discriminate analysis effectively predicted tissue-selective function in most, but not all, cases tested. We demonstrate that analysis of dynamics of the receptor-ligand complex facilitates binning of ER modulators into distinct groups based on structural dynamics. Importantly, we were able to differentiate small structural changes within ER ligands of the same chemotype. In addition, HDX revealed differentially stabilized regions within the ligand-binding pocket that may contribute to the different pharmacology phenotypes of the compounds independent of helix 12 positioning. In summary, HDX provides a sensitive and rapid approach to classify modulators of the estrogen receptor that correlates with their pharmacological profile.

Identification and characterization of noncalcemic, tissue-selective, nonsecosteroidal vitamin D receptor modulators.

Vitamin D receptor (VDR) ligands are therapeutic agents for the treatment of psoriasis, osteoporosis, and secondary hyperparathyroidism. VDR ligands also show immense potential as therapeutic agents for autoimmune diseases and cancers of skin, prostate, colon, and breast as well as leukemia. However, the major side effect of VDR ligands that limits their expanded use and clinical development is hypercalcemia that develops as a result of the action of these compounds mainly on intestine. In order to discover VDR ligands with less hypercalcemia liability, we sought to identify tissue-selective VDR modulators (VDRMs) that act as agonists in some cell types and lack activity in others. Here, we describe LY2108491 and LY2109866 as nonsecosteroidal VDRMs that function as potent agonists in keratinocytes, osteoblasts, and peripheral blood mononuclear cells but show poor activity in intestinal cells. Finally, these nonsecosteroidal VDRMs were less calcemic in vivo, and LY2108491 exhibited more than 270-fold improved therapeutic index over the naturally occurring VDR ligand 1,25-dihydroxyvitamin D3 [1,25-(OH)2D3] in an in vivo preclinical surrogate model of psoriasis.

Regulation of carbohydrate metabolism by the farnesoid X receptor.

The farnesoid X receptor (FXR; NR1H4) is a nuclear hormone receptor that functions as the bile acid receptor. In addition to the critical role FXR plays in bile acid metabolism and transport, it regulates a variety of genes important in lipoprotein metabolism. We demonstrate that FXR also plays a role in carbohydrate metabolism via regulation of phosphoenolpyruvate carboxykinase (PEPCK) gene expression. Treatment of either H4IIE or MH1C1 rat hepatoma cell lines as well as primary rat or human hepatocytes with FXR agonists led to stimulation of PEPCK mRNA expression to levels comparable to those obtained with glucocorticoid receptor agonists. We examined the physiological significance of FXR agonist-induced enhancement of PEPCK expression in primary rat hepatocytes. In addition to inducing PEPCK expression in primary hepatocytes, FXR agonists stimulated glucose output to levels comparable to those observed with a glucocorticoid receptor agonist. Consistent with these observations, treatment of C57BL6 mice with GW4064 significantly increased hepatic PEPCK expression. Activation of FXR initiated a cascade involving induction of peroxisome proliferator-activated receptor alpha and TRB3 expression that is consistent with stimulation of PEPCK gene expression via interference with a pathway that may involve Akt-dependent phosphorylation of Forkhead/winged helix transcription factor (FOXO1). The FXR-peroxisome proliferator-activated receptor alpha-TRB3 pathway was conserved in rat hepatoma cell lines, mice, as well as primary human hepatocytes. Thus, in addition to its role in the regulation of lipid metabolism, FXR regulates carbohydrate metabolism.

Ser-884 adjacent to the LXXLL motif of coactivator TRBP defines selectivity for ERs and TRs.

Ligand-dependent interaction of nuclear receptors and coactivators is a critical step in nuclear receptor-mediated transcriptional regulation. TR-binding protein (TRBP) interacts with nuclear receptors through a single LXXLL motif. Evidence suggested that the sequences flanking the LXXLL motif in a number of coactivators determine receptor selectivity. We performed mutagenesis studies at residues adjacent to the TRBP LXXLL motif and identified S884 of TRBP at the -3 position of the LXXLL motif as a key residue for receptor selectivity. Analysis of in vitro and in vivo receptor interactions with TRBP suggested that S884 allowed selective interactions for ERbeta, TR, and RXR vs. ERalpha. Transient transfection studies further confirmed that the LXXLL-binding affinity correlates with TRBP transcriptional activity. Consistent with the structural modeling, an E380G substitution within ERalpha altered the binding to TRBP mutants, demonstrating the direct contact between TRBP S884 and ERalpha E380, which is a residue that distinguishes receptor subclasses. Furthermore, S884 can be phosphorylated by MAPK in vitro, an event that significantly altered the binding of TRBP to ER and suggests a potential mechanism for regulatory interaction. As the differential recruitment of TRBP to ERalpha and ERbeta may rely on S884, our finding provides insight into estrogen signaling and may lead to the development of therapeutic receptor-selective peptide antagonists.

Target specificity of selective estrogen receptor modulators within human endometrial cancer cells.

Selective estrogen receptor modulators (SERMs) are estrogen receptor (ER) ligands that function as antagonists in some tissues, but have either partial or full agonist activity in others. SERMs often display variable partial agonist activity in uterine tissues and this activity can be displayed in uterine cell lines such as the human Ishikawa endometrial adenocarcinoma cell line. In this study, we compared the effects of several ER ligands including some SERMs on alkaline phosphatase (AP) activity and the expression of an ER target gene, the progesterone receptor (PR), in Ishikawa cells. As expected, estradiol (E2) was a potent and efficacious activator of both AP activity and PR mRNA expression. 4-Hydroxytamoxifen (4OHT) stimulated AP activity to a level 47% of that of E2 (100nM), while CP 336156 (lasofoxifene) increased AP activity 18%. A benzothiophene, such as LY 117018, a raloxifene analog, stimulated AP even less with values approximately 11% of E2-stimulated levels. A pure antiestrogen, ICI 182,780 did not stimulate AP activity. Interestingly, when we examined the ability of these compounds to increase the expression of the ER target gene, PR, a different rank order of efficacy was detected. After E2, CP 336156 was the most efficacious in increasing PR mRNA with a maximal stimulation of 20% of E2 levels, while 4OHT stimulated only 17%. LY 117018 increased PR mRNA expression 8% while ICI 182,780 did not increase PR mRNA expression at all. These data illustrate the target specificity that a SERM is able to display within a single cell type independent of "tissue specificity" and differential levels of expression of various cofactors. While 4OHT is 160% more active than CP 336156 in terms of inducing AP activity in the Ishikawa cells, CP 336156 has equivalent activity as 4OHT when one examines the ability of these SERMs to induce PR mRNA expression. Since the stimulation of Ishikawa cells by ER ligands is often used to assess the potential in vivo uterotrophic activity, these data indicate that examination of several endpoints in these cells may be necessary in order to fully characterize the activity of SERMs.

A 15-ketosterol is a liver X receptor ligand that suppresses sterol-responsive element binding protein-2 activity.

Hypercholesterolemia is a major risk factor for coronary artery disease. Oxysterols are known to inhibit cholesterol biosynthesis and have been explored as potential antihypercholesterolemic agents. The ability of 3beta-hydroxy-5alpha-cholest-8(14)-en-15-one (15-ketosterol) to lower non-HDL cholesterol has been demonstrated in rodent and primate models, but the mechanisms of action remain poorly understood. Here we show in a coactivator recruitment assay and cotransfection assays that the 15-ketosterol is a partial agonist for liver X receptor-alpha and -beta (LXRalpha and LXRbeta). The binding affinity for the LXRs was comparable to those of native oxysterols. In a macrophage cell line of human origin, the 15-ketosterol elevated ATP binding cassette transporter ABCA1 mRNA in a concentration-dependent fashion with a potency similar to those of other oxysterols. We further found that in human embryonic kidney HEK 293 cells, the 15-ketosterol suppressed sterol-responsive element binding protein processing activity and thus inhibited mRNA expression of 3-hydroxy-3-methylglutaryl-coenzyme A reductase, LDL receptor, and PCSK9. Our data thus provide a molecular basis for the hypocholesterolemic activity of the 15-ketosterol and further suggest its potential antiatherosclerotic benefit as an LXR agonist.

Regulation of pyruvate dehydrogenase kinase expression by the farnesoid X receptor.

The pyruvate dehydrogenase complex (PDC) functions as an important junction in intermediary metabolism by influencing the utilization of fat versus carbohydrate as a source of fuel. Activation of PDC is achieved by phosphatases, whereas, inactivation is catalyzed by pyruvate dehydrogenase kinases (PDKs). The expression of PDK4 is highly regulated by the glucocorticoid and peroxisome proliferator-activated receptors. We demonstrate that the farnesoid X receptor (FXR; NR1H4), which regulates a variety of genes involved in lipoprotein metabolism, also regulates the expression of PDK4. Treatment of rat hepatoma cells as well as human primary hepatocytes with FXR agonists stimulates the expression of PDK4 to levels comparable to those obtained with glucocorticoids. In addition, treatment of mice with an FXR agonist significantly increased hepatic PDK4 expression, while concomitantly decreasing plasma triglyceride levels. Thus, activation of FXR may suppress glycolysis and enhance oxidation of fatty acids via inactivation of the PDC by increasing PDK4 expression.

Reconstitution of functional nuclear receptor proteins using high pressure refolding.

Members of the nuclear receptor superfamily are ligand dependent transcription factors and many of the receptors are difficult to produce in their functional form. Here, we describe a method for obtaining functional nuclear receptor ligand binding domain proteins from bacterial expressed inclusion bodies by high hydrostatic pressure induced refolding. High pressure refolding successfully reconstituted activity from several insoluble nuclear receptor proteins and represents a valuable tool for both functional and structural investigation of proteins or fragments thereof that might otherwise remain insoluble.

Coactivation of the human vitamin D receptor by the peroxisome proliferator-activated receptor gamma coactivator-1 alpha.

The vitamin D receptor (VDR) belongs to the superfamily of steroid/thyroid hormone receptors that is activated by 1alpha,25-dihydroxyvitamin D(3). Traditional targets for 1alpha,25-dihydroxyvitamin D(3) action include tissues involved in the maintenance of calcium homeostasis and bone development and remodeling. Peroxisome proliferator-activated receptor gamma coactivator-1alpha (PGC-1alpha), a transcriptional coactivator that plays a role in mitochondrial biogenesis and energy metabolism, is predominantly expressed in kidney, heart, liver, and skeletal muscle. Because VDR and PGC-1alpha display an overlapping pattern of expression, we investigated the possibility that PGC-1alpha could serve as a coactivator for VDR. Transient cotransfection assays demonstrate that PGC-1alpha augments ligand-dependent VDR transcription when either full-length VDR or Gal4 DNA binding domain-VDR-ligand binding domain chimeras were analyzed. Furthermore, mammalian two-hybrid assays, coimmunoprecipitation analyses, and biochemical coactivator recruitment assays demonstrate a ligand-dependent interaction between the two proteins both in cells and in vitro. The coactivation potential of PGC-1alpha requires an intact AF-2 domain of VDR and the LXXLL motif in PGC-1alpha. Taken together, these results indicate that PGC-1alpha serves as a coactivator for VDR.

Potent inhibitors of LXXLL-based protein-protein interactions.

Protein-protein interactions between estrogen receptors, ERalpha and ERbeta, and their coactivators (CoAs) are an attractive target for drug intervention. This interaction is mediated by a small pentapeptide motif (LXXLL), termed the NR box. Based on this motif, a variety of cyclic and linear peptides were synthesized in order to gain a better understanding of the association of CoA proteins with the ER isoforms. Utilizing a time-resolved florescence-based coactivator interaction assay, we determined the abilities of these peptides to inhibit this interaction. Using molecular modeling and CD spectroscopy, we have examined the structural basis of their bioactivities with both hormone receptor isoforms. Either homocysteine or penicillamine was utilized as a substitute for cysteine in the disulfide-bridged peptides, while tertiary leucine and neopentyl glycine were used as the surrogates for the NR box leucines. The most potent disufide-bridged peptide (K(i)= 70 pM, with ERalpha) incorporates neopentyl glycine in the NR box, while the most active peptide in this series with ERbeta (K(i)=350 pM) incorporates tertiary leucine. Surprisingly, several linear peptides containing a single cysteine residue showed activities with low nanomolar K(i) values. Collectively, our results suggest a synthetic approach for designing potent and selective peptidomimetics for ERalpha and ERbeta interactions with CoA proteins effecting estrogen action.

Ligand-dependent coactivation of the human bile acid receptor FXR by the peroxisome proliferator-activated receptor gamma coactivator-1alpha.

Peroxisome proliferator-activated receptor gamma coactivator-1alpha (PGC-1alpha) has been shown to play an important role in energy metabolism by coordinating transcriptional programs involved in mitochondrial biogenesis, adaptive thermogenesis, gluconeogenesis, and fatty acid oxidation. PGC-1alpha also plays a crucial role in cholesterol metabolism by serving as a coactivator of the liver X receptor-alpha and inducing the expression of cholesterol 7-alpha-hydroxylase. Here, we demonstrate that PGC-1alpha also functions as an effective coactivator of farnesoid X receptor (FXR), the bile acid receptor. Transient cotransfection assays demonstrate that PGC-1alpha enhances ligand-mediated FXR transcription when either full-length FXR or Gal4 DNA binding domain-FXR-ligand binding domain chimeras were analyzed. Mammalian two-hybrid analyses, glutathione S-transferase affinity chromatography and biochemical coactivator recruitment assays demonstrate ligand-dependent interaction between the two proteins both in vivo and in vitro. PGC-1alpha-mediated coactivation of FXR was highly ligand-dependent and absolutely required an intact activation function-2 (AF-2) domain of FXR and the LXXLL motif in PGC-1alpha. The integrity of the charge clamp was required, further illustrating the role of the ligand binding domain of FXR in PGC-1alpha recognition. Together, these results indicate that PGC-1alpha functions as a potent coactivator for FXR and further implicates its role in the regulation of genes that are involved in bile acid and lipid metabolism.

Effects of selective estrogen receptor modulators (SERMs) on coactivator nuclear receptor (NR) box binding to estrogen receptors.

Coactivators are required for activation of target genes by nuclear receptors. A well-studied class of coactivators, the p160 proteins, use short nuclear receptor interaction domains (NR boxes) to bind to the activated ligand-binding domain of a nuclear receptor. To investigate how selective estrogen receptor modulators (SERMs) affect NR box recruitment, we compared the recruitment of p160 NR box peptides to the estrogen receptor (ER)alpha and ER beta in the presence of 17beta-estradiol (E2), 4-OH tamoxifen (4-OH Tam), LY 117018 (a raloxifene analog), and ICI 182780 (ICI, an ER antagonist). Our coactivator interaction assay utilizes time-resolved fluorescence technology to assess the binding of the 10 NR boxes derived from the three known p160 coactivators (SRC-1, -2, -3) to the ER subtypes in the presence of each ligand. The SERMs we studied did not increase NR box binding to either ER alpha or ER beta, but instead were potent antagonists decreasing estradiol-dependent NR box binding. We also demonstrated inverse agonism for all of the SERMs tested as they dose-dependently decreased hormone-independent NR box binding to ER beta. Therefore, the SERMs studied behave as antagonists of ER alpha and ER beta NR box binding and do not increase coactivator NR box binding to either ER subtype. In addition, we examined the preference of E2-bound ER alpha and ER beta for various naturally occurring NR boxes including the 10 SRC boxes as well as the motifs from PGC-1, TRBP, TRAP220, and CBP. Interestingly, a clear preferential pattern of interaction was noted that was receptor specific.

Pharmacology of nuclear receptor-coregulator recognition.

The nuclear receptor (NR) superfamily comprises approximately 50 members that are responsible for regulating a number of physiologic processes in humans, including metabolism, homeostasis, and reproduction. Included in the superfamily are the receptors for steroids, lipophilic vitamins, bile acids, retinoids, and various fatty acids. NRs exert their action as transcription factors that directly bind to the promoters of target genes and regulate their rate of transcription. To modulate transcription, however, NRs must recruit a number of accessory coregulators known as corepressors and coactivators. These coregulators harbor a variety of activities, such as the ability to modify chromatin structure, interact with basal transcriptional machinery, and modify RNA splicing. Recent studies have revealed that the pharmacological characteristics of various NR ligands are regulated by their ability to modulate the coregulator interaction profile of an NR.

T0901317 is a dual LXR/FXR agonist.

We characterize the ability of the liver X receptor (LXRalpha [NR1H3] and LXRbeta [NR1H2]) agonist, T0901317, to activate the farnesoid X receptor (FXR [NR4H4]). Although T0901317 is a much more potent activator of LXR than FXR, this ligand actually activates FXR more potently than a natural bile acid FXR ligand, chenodeoxycholic acid. Thus, the FXR activity of T0901317 must be considered when utilizing this agonist as a pharmacological tool to investigate LXR function.

Liver X receptor and retinoic X receptor mediated ABCA1 regulation and cholesterol efflux in macrophage cells-messenger RNA measured by branched DNA technology.

ABCA1 is an ATP binding cassette transporter that plays an essential role in cholesterol and phospholipid efflux and HDL biogenesis. ABCA1 expression in macrophage cells is subject to regulation by cAMP, cholesterol loading, and ligands of the nuclear receptors liver X receptor (LXR) and retinoid X receptor (RXR). We report here the development of a rapid and high volume branched DNA (bDNA) method to measure ABCA1 mRNA. By using the bDNA method, we show that both LXR and RXR ligands effectively regulate ABCA1 expression in three macrophage cell types: mouse RAW264.7 cell line, mouse peritoneal macrophage cells, and human macrophage THP-1 cells and their regulation is additive. Furthermore, by using a radiolabeled cholesterol efflux assay, we show that both LXR and RXR ligands are sufficient to mediate cholesterol efflux in macrophage cells and their efficacy correlates with ABCA1 regulation. These studies strengthen further the notion that LXR and RXR mediate ABCA1 expression and cholesterol efflux in macrophage cells as a permissive heterodimer and development of small molecule ligands of these nuclear receptors may represent a promising approach to modulating cholesterol efflux and plasma HDL cholesterol level in humans.

A chemical switch regulates fibrate specificity for peroxisome proliferator-activated receptor alpha (PPARalpha ) versus liver X receptor.

Fenofibrate is clinically successful in treating hypertriglyceridemia and mixed hyperlipidemia presumably through peroxisome proliferator-activated receptor alpha (PPARalpha)-dependent induction of genes that control fatty acid beta-oxidation. Lipid homeostasis and cholesterol metabolism also are regulated by the nuclear oxysterol receptors, liver X receptors alpha and beta (LXRalpha and LXRbeta). Here we show that fenofibrate ester, but not fenofibric acid, functions as an LXR antagonist by directly binding to LXRs. Likewise, ester forms, but not carboxylic acid forms, of other members of the fibrate class of molecules antagonize the LXRs. The fibrate esters display greater affinity for LXRs than the corresponding fibric acids have for PPARalpha. Thus, these two nuclear receptors display a degree of conservation in their recognition of ligands; yet, the acid/ester moiety acts as a chemical switch that determines PPARalpha versus LXR specificity. Consistent with its LXR antagonistic activity, fenofibrate potently represses LXR agonist-induced transcription of hepatic lipogenic genes. Surprisingly, fenofibrate does not repress LXR-induced transcription of various ATP-binding cassette transporters either in liver or in macrophages, suggesting that fenofibrate manifests variable biocharacter in the context of differing gene promoters. These findings provide not only an unexpected mechanism by which fenofibrate inhibits lipogenesis but also the basis for examination of the pharmacology of an LXR ligand in humans.

Helix-stabilized cyclic peptides as selective inhibitors of steroid receptor-coactivator interactions.

The interaction between nuclear receptors and coactivators provides an arena for testing whether protein-protein interactions may be inhibited by small molecule drug candidates. We provide evidence that a short cyclic peptide, containing a copy of the LXXLL nuclear receptor box pentapeptide, binds tightly and selectively to estrogen receptor alpha. Furthermore, as shown by x-ray analysis, the disulfide-bridged nonapeptide, nonhelical in aqueous solutions, is able to adopt a quasihelical conformer while binding to the groove created by ligand attachment to estrogen receptor alpha. An i, i+3 linked analog, H-Lys-cyclo(d-Cys-Ile-Leu-Cys)-Arg-Leu-Leu-Gln-NH2 (peptidomimetic estrogen receptor modulator 1), binds with a Ki of 25 nM, significantly better than an i, i+4 bridged cyclic amide, as predicted by molecular modeling design criteria. The induction of helical character, effective binding, and receptor selectivity exhibited by this peptide analog provide strong support for this strategy. The stabilization of minimalist surface motifs may prove useful for the control of other macromolecular assemblies, especially when an amphiphilic helix is crucial for the strong binding interaction between two proteins.

Alternative splicing within the ligand binding domain of the human constitutive androstane receptor.

The human constitutive androstane receptor (hCAR; NR1I3) is a member of the nuclear receptor superfamily. The activity of hCAR is regulated by a variety of xenobiotics including clotrimazole and acetaminophen metabolites. hCAR, in turn, regulates a number of genes responsible for xenobiotic metabolism and transport including several cytochrome P450s (CYP 2B5, 2C9, and 3A4) and the multidrug resistance-associated protein 2 (MRP2, ABCC2). Thus, hCAR is believed to be a mediator of drug-drug interactions. We identified two novel hCAR splice variants: hCAR2 encodes a receptor in which alternative splice acceptor sites are utilized resulting in a 4 amino acid insert between exons 6 and 7, and a 5 amino acid insert between 7 and 8, and hCAR3 encodes a receptor with exon 7 completely deleted resulting in a 39 amino acid deletion. Both hCAR2 and hCAR3 mRNAs are expressed in a pattern similar to the initially described MB67 (hCAR1) with some key distinctions. Although the levels of expression vary depending on the tissue examined, hCAR2 and hCAR3 contribute 6-8% of total hCAR mRNA in liver. Analysis of the activity of these variants indicates that both hCAR2 and hCAR3 lose the ability to heterodimerize with RXR and lack transactivation activity in cotransfection experiments where either full-length receptor or GAL4 DNA-binding domain/CAR ligand binding domain chimeras were utilized. Although the role of hCAR2 and hCAR3 is currently unclear, these additional splice variants may provide for increased diversity in terms of responsiveness to xenobiotics.