Background
Persistent regurgitation of gastroduodenal contents into the lower esophagus causes mucosal injury manifested as reflux esophagitis (RE) [
1,
2]. As a complication of chronic RE, a Barrett's esophagus (BE) can develop [
3,
4]. BE is defined as an acquired condition in which the stratified squamous epithelium of the lower esophagus is replaced by specialized intestinal epithelium [
5]. It is the sole commonly recognized risk factor for the development of esophageal adenocarcinoma (EAC) [
6,
7] and has an increasing incidence in the Western world [
8]. While the importance of acid and bile exposure in the development of BE is well established [
1,
5,
9,
10], only a small percentage of BE patients will ultimately develop EAC. It remains largely unclear which factors control the rate of neoplastic progression in BE [
11]. A growing body of evidence suggests that the intrinsic adaptive response to the toxic bile acids from the gastroduodenal contents is unable to prevent injury to the esophageal lining, thus suggesting a role for bile-induced signalling in the progression of BE [
12].
An important step in understanding the adaptive defence mechanism against toxic substances has been the identification and characterization of the nuclear pregnane × receptor (PXR) [
13‐
16]. PXR belongs to the nuclear receptor subfamily of ligand-activated transcription factors that play a key role in the regulation of biliary transport systems and enzymes that confer a protective role against toxic bile acids [
12]. This group of nuclear receptors includes the constitutive androstrane receptor and the vitamin D receptor [
17,
18]. In humans, PXR is most abundantly found in the liver, the small intestine and the colon [
13,
15,
16,
19]. It is activated by a structurally diverse array of xenobiotics and endogenous compounds, including bile acids and steroid hormones [
13,
17,
18]. Variability at the PXR genetic locus is therefore thought to be associated with pathophysiological changes in steroid, cholesterol or bile acid levels [
14]. Polymorphisms in the PXR gene are associated with diseases such as inflammatory bowel disease and primary sclerosing cholangitis [
20,
21]. As these chronic inflammatory diseases are associated with aberrant bile acid metabolism, there may also be a link between PXR and BE.
The specific aim of this study was to explore the expression and distribution of PXR in BE and adenocarcinoma patients and analyse possible associations in the PXR gene with esophageal disease. We show that PXR expresses in tissue of BE and adenocarcinoma patients, and that it translocates to the nucleus in esophageal adenocarcinoma cells upon bile acid stimulation. In addition, a link between PXR polymorphisms and esophageal disease was found.
Methods
Human specimens
For immunohistochemistry, multiple biopsies of adenocarcinoma tissue (n = 19), columnar epithelium from BE patients without dysplsia (n = 28) and squamous epithelium from RE patients (n = 8) were taken at the same distance from the z-line. As healthy controls we included subjects that had no gastroesophageal reflux disease (GERD) symptoms or endoscopically detected aberrations of the esophagus (n = 3). The number of biopsies taken was approximately four per patient, and varied between one and eight biopsies. For each patient, all biopsy specimens were embedded in one single block of paraffin and were therefore stained and analyzed in one slide. Histologic diagnosis was made by two experienced gastrointestinal pathologists (HD and HV). All patients had specialized intestinal metaplasia and were graded according to the most severe stage found. Cases on which agreement could not be reached or that were indefinite for dysplasia were excluded from this study.
Table
1 gives patient characteristics of the population used for analysis of PXR mRNA levels. mRNA levels were determined in a total of 119 esophageal samples, counting biopsies from 11 adenocarcinoma patients, duplicate biopsies of both the squamous and the columnar epithelium from BE patients (n = 21), squamous epithelium of RE patients (n = 7), and squamous epithelium of healthy controls (n = 5) without GERD symptoms or endoscopically detected aberrations of the esophagus. All BE patients had histologically confirmed intestinal metaplasia without high-grade dysplasia.
Table 1
Patient characteristics for PXR mRNA analysis
Age, y (range)* | 43 (21-60) | 61 (34-78) | 62 (42-73) |
Male, (%)* | 71 | 71 | 82 |
Type of epithelium | Sq | Sq, CE | tumor |
Characteristics of the group included in this study for genotyping are shown in Table
2. The total of 683 genetically unrelated Caucasians included 249 BE patients, 233 RE patients and 201 controls without any history of GERD symptoms, who all visited the endoscopy unit of the Erasmus MC-University Medical Center Rotterdam or the IJsselland Hospital in Capelle aan den IJssel between November 2002 and February 2005 [
22]. This study was approved by the institutional ethics review committees, and all patients gave informed consent before participating in the study.
Table 2
Patient characteristics per group for genotyping
Age, y (range) | 57 (18-90) | 54 (19-88) | 61 (33-95) |
Male, (%) | 57 | 54 | 69 |
Length of BE segment, cm (SD) | NA | 0 | 4.23 (2.39) |
Cell lines
The human adenocarcinoma cell line OE19 and human squamous epithelial cell line HET1A were obtained from the ATCC. OE19 cells were grown in RPMI 1640 supplemented with 10% fetal calf serum (FCS), 2 mmol/l glutamine, 100 units/ml penicilline and streptomycin. HET1A cells were cultured in serum-free BRFF-EPM2 medium supplemented with 100 units/ml penicilline and streptomycin. Cells were maintained routinely at 37°C in 5% CO2 humidified atmosphere. After a period of at least 24 h to allow cells to adhere they were stimulated with 10 μM of rifampicine, 50 μM lithocholic acid (LCA), or 50 or 100 μM taurolithocholic acid (TLCA) for 24 h.
Real-Time PCR mRNA quantification from human esophagus samples
Total RNA was extracted from tissue biopsies using TriReagent (Sigma, St Louis, MO) and purified using an RNeasy micro column kit (Qiagen, Hilden, CA). One-fortieth of a 1 μg cDNA synthesis reaction (iScript cDNA Synthesis Kit; Bio-Rad) was used in a 25 μl Real Time-PCR using SYBR GreenER (Invitrogen, Carlsbad, CA). The following primers were used for PXR gene amplification: 5'- ATGGCAGTGTCTGGAACTAC-3' and 5'- CAGTTGACACAGCTCGAAAG-3'. Duplicate samples were run three times in independent PCR runs and the average level of PXR was normalized to GAPDH using the ΔCt method [
23].
Immunohistochemistry
Formalin fixed, paraffin embedded, five μm sections were mouned on glass slides. After deparaffinization in xylene and dehydration in alcohol, endogenous peroxidase was inactivated by incubation with 1% hydrogen peroxidase in methanol for 20 min. Microwave pretreatment in glycin-HCl/EDTA buffer (50 mM Glycin, 10 mM EDTA, pH 3.5) was performed for 10 min. After treatment with 10% normal human plasma/10% goat serum to block non-specific antibody binding, sections were incubated overnight at 4°C with a rabbit anti-human PXR antibody (diluted 1:200, clone poly6169; Biolegend; San Diego, USA), followed by a biotin-labeled mouse anti-rabbit IgG (diluted 1:200; Dako, Glostrup, Danmark), and streptavidin-horseradish peroxidase (diluted 1:300, Dako) and visualized with diaminobenzidine. Nonspecific background controls were done by omitting the primary antibody and an isotype control was included. Samples of the terminal ileum served as a positive control. Sections were evaluated at a 200- and 400-fold magnification using light microscopy (Axioskop 20, Zeiss) by two independent observers (AW and KZ). At least 100 cells were counted in representative areas of longitudinally sectioned crypts in BE cases or high power fields in adenocarcinoma cases. For quantification only cases with nuclear protein expression were considered PXR positive, with cases evaluated as positive for PXR when more than 2% of counted cells showed nuclear positivity of PXR protein.
Confocal microscopy
Cells were cultured on coverslips washed with phosphate buffered saline (PBS) and fixed with 2% paraformaldehyde for 10 min. After washing, cells were permeabilized with 0.2% Triton ×100 for 20 min and then blocked with 5% goat serum and 5% normal human plasma in PBS with 5% BSA. Cells were incubated with mouse IgG or anti-hPXR antibody (1:200; Biolegend, San Diego, USA) at 4°C overnight and then probed with 1:200 dilution of goat anti-rabbit Alexafluor 594 (Invitrogen; Oregon, USA). Hoechst 33342 was used to stain nuclei. Coverslips were mounted onto glass slides with gelvatol and visualized under a Zeiss LSM 410 laser-scanning confocal microscope (Zeiss, Oberkochen, Germany).
Genotyping
Genomic DNA was extracted from 5 ml of whole blood by a wizard genomic DNA purification kit (Promega, Madison, USA). We analyzed polymorphisms -25385C/T, 7635A/G, and 8055C/T as these should be informative for eight PXR polymorphisms and were observed by Zhang
et al [
14] to have an effect on PXR function in humans. Assay validation setup was performed by K-Biosciences (Herts, UK) before performing a double blind analysis of PXR SNPs with a competitive allele-specific PCR system using primers designed in flanking region of the SNP located at -25385; TGGTCATTTTTTGGCAATCCCAGGTT[C/T]TCTTTTCTAC CTGTTTGCTCAATCG at 7635; AGGAGCCATCCTCCCTCTTCCTCTC[A/G]CCCCCAA CTTCTGGATTATGGGATG and at 8055; GCTTGCTGAGAAGCTGCCCCTCCAT[C/T]CT GTTACCATCCACAGGTGGCTTCC of the PXR gene NR1I2.
Statistical analyses
The study was powered (80%) to allow detection of a 10% difference in genotype distribution of the PXR polymorphisms between the groups by performing Chi-square analysis. Odds ratio (OR) and 95% confidence interval (95% CI) were calculated by risk estimate analysis. All statistical analyses were conducted using SPSS v11.0 (SPSS, Chicago, IL) and two-sided significance was taken as P < 0.05.
Discussion
The precise pathophysiological mechanisms causing BE is still unclear, but the combination of gastric acid and bile acids from the gastroduodenal reflux is commonly acknowledged as the key factor in the development of BE [
26]. At low pH, bile acids are thought to cause esophageal mucosal injury, which has been substantiated both
in vitro and in animal model systems [
27‐
29].
The NR1I family of orphan nuclear receptors are known to prevent toxic accumulations of xenobiotics within cells by regulating a broad range of cellular transporters [
17,
30,
31]. The nuclear receptor PXR is a member of this family and functions in the enterohepatic organs as a detoxifier and regulator of bile acid homeostasis [
12‐
16]. It can bind a variety of bile acids [
32,
33] and subsequently regulate the expression of a multitude proteins that transport bile acids across cell membranes [
34‐
36]. These include the multidrug resistance (MDR)1 gene [
37,
38], which encodes the efflux protein P-glycoprotein that removes xenobiotics from cells [
39]. Other bile acid transporters that are induced by PXR include the multidrug resistance associated protein (MRP)2 and 3 [
40‐
42] and the organic anion transporting polypeptide (OATP)1 and 2 [
42‐
44]. From studies in mice it was concluded that the function of PXR is of particular importance when bile acid concentrations reach pathophysiologic levels [
33,
45].
PXR expression is known in healthy liver and intestinal tract, but in cancer it has yet to be explored. Therefore, in this study we investigated the expression and significance of PXR in esophageal pathology. We did not detect PXR in normal squamous epithelium or in the squamous epithelium of RE patients. PXR did however express at both mRNA and protein level in columnar epithelium, and was significantly lower in adjacent squamous esophageal epithelium of the same patient. In samples from adenocarcinoma patients PXR was clearly observed the nucleus. PXR mRNA levels between BE and EAC do not differ, but nuclear PXR protein expression does increase in EAC. Perhaps, this is an effect of difference posttranscriptional modifications between the stages. It could also indicate a translocation from the cytoplasm to the nucleus occuring during progression from BE to EAC, as our studies showed translocation from cytoplasm to the nuclei of adenocarcinoma cells in vitro after stimulation with rifampicine or litholic acid. These processes and their significance to PXR function need to be further explored, and a first step in this could be Western blot analysis on subcellular fractions of BE and EAC cells.
Previous studies have suggested that PXR expression in cancer cells can interfere with the metabolism and responsiveness to chemotherapeutics, such as irinotecon and tamoxifen [
46,
47]. They suggest this drug resistance involves the metabolizing enzyme CYP3A4, one of the key target genes of PXR [
15]. These effects on the metabolism of anticancer agents are especially important considering that PXR ligands include endogenous steroids and bile acids, as well as numerous environmental chemicals and dietary constituents. It has yet to be investigated whether higher levels of PXR in the esophagus also affects responsiveness to chemotherapy.
Given the relatively low rare allele frequency for SNP 8055C/T, our population size may have been insufficient to detect a statistically significant association. Validation of our findings will require a well-characterized population from a multicenter study. Recent studies associate PXR polymorphisms with other pathogenic conditions of the gastrointestinal tract, such as inflammatory bowel disease [
20] and primary sclerosing cholangitis [
21]. Since associations with the two PXR SNPs in this study are in line with previous findings in IBD [
20], this draws attention on a possible link of the functional effect of these SNPs with chronic inflammation. It is well known that inflammation, through the activation of NF-κB pathway leads to a decrease of CAR, PXR and RXR-alpha expression and the expression of their target genes. In addition, it has recently been shown that the mutual repression between PXR and NF-κB signalling pathways provides a molecular mechanism linking xenobiotic metabolism and inflammation [
48].
Although it cannot be ruled out that the observed link between BE and PXR levels is not the cause but only the consequence of the metaplasia from squamous to intestinal-type mucosa, the link with PXR-activity associated SNPs suggest a active role of PXR in BE pathophysiology. Further research should focus on the biologic function of PXR in BE and EAC, especially because PXR protein expression was observed in only few nuclei in Barrett's epithelium whereas EAC tissue was abundant with PXR positive nuclei. Here, we chose LCA to study nuclear translocation as it is the endogenous ligand with the highest binding affinity for PXR. As supraphysiological levels of LCA were used to stimulate esophageal cells, further research will be required using extensive stimulation assays that mimick the
in vivo situation by long-term repetitive stimulations with a mix of bile acids in physiologic concentrations as recently performed [
49]. For a complex disease such as BE, development and validation of representative animal models will be of great value to investigate whether PXR plays a protective role in the development of BE or if it has a detrimental effect on neoplastic progression.
Conclusions
In summary, PXR which is normally not present in the squamous esophageal epithelium, is expressed highly in the columnar esophageal epithelium of BE patients and tumor tissue of EAC patients. At a protein level, this expression appears to be more nuclear in EAC than in BE. Upon stimulation with lithocholic acid, PXR translocates to the nuclei of OE19 adenocarcinoma cells. Together with the observed association of a PXR-activity associated SNPs and BE, this data implies that PXR may have a function in predicting progression and treatment of esophageal disease, though further studies are warranted to support this hypothesis.
Declaration of competing interest
The authors declare that they have no competing interests.
Authors' contributions
AW carried out the cell and immunohistochemical studies, participated in all analysis and drafted the manuscript. VM participated in design and acquisition of molecular genetic studies. AC participated in the cell and immunohistochemical studies and contributed to interpretation of data. LM made substantial contributions to acquisition, analysis and interpretation of genetic studies. RP carried out the molecular genetic studies and performed the statistical analysis. HD acted as expert pathologist in analysing and interpreting analysis. PS conceived of the study, and participated in its design and coordination. JK conceived of the study, and participated in its design and coordination. LL participated in study design and coordination and made substantial contributions to interpretation of data and drafting and revising the manuscript. EK participated in study design and made substantial contributions to interpretation of data and was involved in drafting the manuscript and revising it critically for important intellectual content. All authors read and approved the final manuscript