Isolation and genomic analysis of the rat polymeric immunoglobulin receptor gene terminal domain and transcriptional control region

The polymeric immunoglobulin receptor: bridging innate and adaptive immune responses at mucosal surfaces

Secretory antibodies of the immunoglobulin A (IgA) class form the first line of antigen-specific immune protection against inhaled, ingested, and sexually transmitted pathogens and antigens at mucosal surfaces. Epithelial transcytosis of polymeric IgA (pIgA) is mediated by the polymeric immunoglobulin receptor (pIgR). At the apical surface, the extracellular ligand-binding region of pIgR, known as secretory component (SC), is cleaved and released in free form or as a component of secretory IgA (SIgA). SC has innate anti-microbial properties, and it protects SIgA from proteolytic degradation. Expression of pIgR is regulated by microbial products through Toll-like receptor signaling and by host factors such as cytokines and hormones. Recent studies of the structure of the extracellular ligand-binding domain of pIgR have revealed mechanisms by which it binds pIgA and other ligands. During transcytosis, pIgA has been shown to neutralize pathogens and antigens within intracellular vesicular compartments. The recent identification of disease-associated polymorphisms in human pIgR near the cleavage site may help to unravel the mystery of how pIgR is cleaved to SC. The identification of novel functions for SC and SIgA has expanded our view of the immunobiology of pIgR, a key component of the mucosal immune system that bridges innate and adaptive immune defense.

Upstream stimulatory factor but not c-Myc enhances transcription of the human polymeric immunoglobulin receptor gene

Secretory antibodies protect mucosal surfaces from ingested, inhaled and sexually transmitted pathogens. The polymeric immunoglobulin receptor (pIgR) transports antibodies across mucosal epithelia into external secretions. We and others have identified a region of the human polymeric immunoglobulin receptor gene (locus PIGR) that is sufficient for basal transcriptional activity. An E-Box motif, which binds transcription factors of the basic helix-loop-helix/leucine zipper (bHLH/zip) family, was identified as a major regulatory element in the PIGR gene promoter. Transient transfection of PIGR promoter reporter plasmids in intestinal epithelial cell (IEC) lines suggested that the transcription factors upstream stimulatory factor (USF) and c-Myc may exert opposing effects on PIGR promoter activity. Mutations within and flanking the E-Box that favored USF binding enhanced promoter activity, while mutations that favored c-Myc binding reduced promoter activity. Ectopic expression of USF1 or USF2 enhanced PIGR promoter activity, while exogenous c-Myc did not. Electrophoretic mobility shift assays (EMSA) demonstrated that USF1 and USF2 bound to the E-Box motif as homo- and heterodimers. Chromatin immunoprecipitation (ChIP) demonstrated that USF proteins bind the PIGR promoter in vivo, which is enriched in acetylated histones. E-Box motifs are commonly observed in promoters of genes that are highly expressed in the human colon. Genes that are down-regulated in colorectal cancer, including PIGR, frequently have non-canonical E-Boxes, while genes that are up-regulated in colorectal cancer generally have canonical E-Boxes. The results of our experiments may shed light on the mechanisms of dysregulated expression of pIgR in inflammatory bowel disease and colorectal cancer, diseases associated with aberrant expression of c-Myc.

Transcriptional regulation of the human polymeric Ig receptor gene: analysis of basal promoter elements

Secretory Igs provide the first line of adaptive immune defense against ingested, inhaled, and sexually transmitted pathogens at mucosal surfaces. The polymeric Ig receptor regulates transport of dimeric IgA and pentameric IgM into external secretions. The level of expression of polymeric Ig receptor is controlled to a large extent by transcription of the PIGR gene in mucosal epithelial cells. Here we present a detailed analysis of the promoter of the PIGR gene by transient transfection of luciferase reporter plasmids into cultured cell lines. Comparisons of the human and mouse PIGR promoters in human and mouse intestinal and liver cell lines demonstrated that the human PIGR promoter was 4- to 5-fold more active than the mouse PIGR promoter in all cell types, and that both the human and mouse PIGR promoters were more active in intestinal than in liver cell lines. Targeted deletions of 22-bp segments of the human PIGR promoter revealed that the region from nt -63 to -84 is crucial for basal transcription, and that two upstream regions can act as positive or negative regulators. Point mutations within the region from nt -63 to -84 demonstrated that an E box motif, which binds the basic helix-loop-helix protein upstream stimulatory factor, is required for PIGR promoter activity. Two additional regulatory motifs were identified in the proximal promoter region: a binding site for AP2, and an inverted repeat motif that binds an unidentified protein. These findings suggest that cooperative binding of multiple transcription factors regulates basal activity of the human PIGR promoter.

Multiple transcription factors in 5'-flanking region of human polymeric Ig receptor control its basal expression

The polymeric Ig receptor (pIgR) is a critical component of the mucosal immune system and is expressed in largest amounts in the small intestine. In this study, we describe the initial characterization of the core promoter region of this gene. Expression of chimeric promoter-reporter constructs was supported in Caco-2 and HT-29 cells, and DNase I footprint analysis revealed a large protein complex within the core promoter region. Site-directed mutagenesis experiments determined that elements within this region serve to either augment or repress basal activity of the human pIgR promoter. Band shift assays of overlapping oligonucleotides within the core promoter identified eight distinct complexes; the abundance of most complexes was enhanced in post-confluent cells. In summary, we report the characterization of the human pIgR promoter and the essential role that eight different nuclear complexes have in controlling basal expression of this gene in Caco-2 cells.

A novel NF-kappa B/Rel site in intron 1 cooperates with proximal promoter elements to mediate TNF-alpha-induced transcription of the human polymeric Ig receptor

Secretory Abs constitute the first line of specific immune defense at mucosal surfaces. Such Abs are generated by the active transport of polymeric Ig (pIg) across secretory epithelia mediated by the pIgR, also known as transmembrane secretory component (SC). The proinflammatory cytokine TNF-alpha is a key mediator of host responses to infections, and it can stimulate protein synthesis-dependent transcriptional up-regulation of pIgR/SC in the HT-29 intestinal adenocarcinoma cell line. By reporter gene assay we identified a novel TNF-alpha-responsive region located within a 748-bp fragment in intron 1 of the human pIgR/SC gene which depended on an NF-kappaB/Rel site for full responsiveness. EMSAs demonstrated preferential binding of the NF-kappaB/Rel family member p65 (RelA) to this DNA element after TNF-alpha stimulation, with weaker and more delayed binding of p50. Furthermore, the TNF-alpha-responsive region in intron 1 required cooperation with DNA elements located in the proximal promoter region of the gene. Mutational analysis demonstrated that an IFN-stimulated response element near the transcriptional start site in exon 1 was involved in the TNF-alpha responsiveness. Thus, DNA elements located >4 kb apart were found to cooperate in TNF-alpha-induced pIgR/SC up-regulation. The intronic TNF-alpha-responsive enhancer overlapped with a recently identified IL-4-responsive enhancer. Several intronic DNA elements found to be functionally important in the human gene are highly conserved between the human and mouse pIgR/SC genes, suggesting the presence of a conserved cytokine-responsive enhancer region.

Tissue-specific androgen responses in primary cultures of lacrimal epithelial cells studied by adenoviral gene transfer

The lacrimal gland secretes most of the water and many proteins present in tear fluid. The composition of the tear fluid is affected dramatically by androgens, an observation which has been linked to the fact that more than 90% of the patients with Sjögren syndrome are female. Although the presence of androgen receptors in the lacrimal gland has been established, the molecular biology of the protective effects of androgens remains largely unknown. Here, we report the use of primary cultures of the lacrimal gland which express endogenous proteins under androgen control, as a more homologous test system for tissue-specific transcription studies. Infection with recombinant adenoviral vectors was the most efficient method to introduce foreign gene constructs in these cultures. A thus introduced mouse mammary tumor virus promoter was inducible with androgens and this effect was independent of the sexual genotype of the infected cells. By use of two recombinant adenoviral vectors containing genomic fragments of the SC gene, which is androgen responsive in the lacrimal gland, we could demonstrate the functionality of the sc promoter as well as its androgen regulation in this culture system.

Mechanism of IL-4-mediated up-regulation of the polymeric Ig receptor: role of STAT6 in cell type-specific delayed transcriptional response

The polymeric IgR (pIgR) mediates transport of dimeric IgA and pentameric IgM across mucosal epithelia, thereby generating secretory Abs. Its expression is up-regulated at the transcriptional level by IL-4 in HT-29 cells. In this study, we demonstrate that IL-4 mediates up-regulation of human pIgR through a 554-bp IL-4-responsive enhancer in intron 1. Mutation of a binding site for STAT-6 within this region abolished IL-4-induced enhancement, while an adjacent putative C/EBP site was dispensable. IL-4 treatment induced binding of STAT6 to the intronic STAT6 site, but cooperation with nearby upstream and downstream DNA elements was required for IL-4 responsiveness. Furthermore, IL-4-mediated increased transcription of the pIgR-derived enhancer, like the endogenous pIgR gene, required de novo protein synthesis. Interestingly, a conditionally active form of STAT6 sufficed to activate a pIgR-derived enhancer in HT-29 cells, but not in Cos-1 cells, suggesting a requirement for cell type-specific factors. Thus, STAT6 activation mediates a delayed transcriptional enhancement of pIgR by induction of a de novo synthesized protein that cooperates with STAT6 itself bound to its cognate DNA element in intron 1. This mechanism may represent a general strategy for how pleiotropic cytokines elicit cell type-specific transcriptional responses.

The first exon of the human sc gene contains an androgen responsive unit and an interferon regulatory factor element

Secretory component (SC) plays a key role in the transport of IgA and IgM to the lumina of many glands. The gene is constitutively expressed, but can be modulated by hormonal and immunological stimuli. Recently, the promoter and the first exon of the human sc gene have been cloned. The first exon contains a putative androgen/glucocorticoid response element (ARE/GRE) and an Interferon Regulatory Factor Element (IRF-E). Here we show that the ARE/GRE can bind the DNA-binding domain (DBD) of both the androgen (AR) and glucocorticoid receptor (GR) with a preference for the AR-DBD. In transient transfection experiments, this element confers higher responsiveness to androgens than to glucocorticoids. The IRF-E can function as an IRF-2, but surprisingly not as an IRF-I responsive element. We postulate that these two regulatory elements play a key role in the complex regulation of the sc gene in vivo.

Transcriptional control of the murine polymeric IgA receptor promoter by glucocorticoids

Glucocorticoids have been implicated as an important regulator of intestinal epithelial cell ontogeny. The polymeric IgA receptor (pIgR) is expressed in the intestinal epithelial layer and is regulated by several mediators, including glucocorticoids. The mechanism of how corticosteroids alter the transcriptional regulation of pIgR expression has not been defined. In this study, we demonstrated that glucocorticoids upregulate steady-state pIgR mRNA levels in the proximal intestine of suckling rats and in the IEC-6 intestinal cell line. We performed functional analysis of the 5'-flanking region in the presence of glucocorticoids and its receptor using the intestinal cell line Caco-2. We screened 4.7 kb of the upstream region of the murine gene and identified the most potent steroid response element to reside between nt -215 and -163 relative to the start of transcription. Substitution mutation analysis of this region identified the location of the putative steroid response element to be between nt -195 and -176. In vitro DNase I footprint analysis using the recombinant glucocorticoid receptor DNA binding domain confirmed a single area of protection that spans the nt identified by mutagenesis analysis. Electrophoretic mobility shift assays of the putative element confirmed the binding of both recombinant and cell synthesized glucocorticoid receptor in a specific manner. In summary, we report the identification and characterization of the glucocorticoid-DNA response element located in the immediate 5'-upstream region of the murine pIgR gene.

Cutting Edge: Coordinate Regulation of IFN Regulatory Factor-1 and the Polymeric Ig Receptor by Proinflammatory Cytokines

The polymeric IgR (pIgR) mediates transcytosis of IgA across epithelial barriers of mucous membranes and exocrine glands. Synthesis of pIgR is up-regulated by the proinflammatory cytokines TNF-α, IFN-γ, and IL-1 in HT-29 human colon carcinoma cells. We previously reported that IFN-γ and TNF-α induce production of the transcription factor IFN regulatory factor-1 (IRF-1) in HT-29 cells and that IRF-1 binds to an element in exon 1 of the PIGR gene. We now report that levels of IRF-1 and pIgR mRNA are coordinately regulated in HT-29 cells by TNF-α, IFN-γ, and IL-1β. Furthermore, we demonstrate that in vivo expression of pIgR mRNA is greatly depressed in the intestine and liver of IRF-1-deficient mice. Our findings indicate a major role for the IRF-1 transcription factor in regulation of the PIGR gene and suggest a model for regulation of important genes in the mucosal immune system by proinflammatory cytokines.

Characterization of the 5'-flanking region of the murine polymeric IgA receptor gene

The regulatory elements that control basal and activated transcriptional expression of the polymeric IgA receptor gene (pIgR) have not been defined. In this study, we performed functional analysis of the murine pIgR 5'-upstream region. Transient transfection studies identified the gene's minimal promoter to reside within 110 nucleotides upstream from the start of transcription. Substitution mutations of this region identified both a putative activator (-78 to -70) and a repressor (-66 to -52) element. DNase I footprint analysis confirmed an area of protection that spans from nucleotides -85 to -62. Mobility shift assays of the putative region confirmed binding of upstream stimulatory factor 1 (USF1) to an E box element at positions -75 and -70, representing the putative enhancer. Overexpression studies using various forms of USF suggest that both USF1 and USF2 enhance activity of the pIgR minimal promoter. We report the identification and characterization of the murine pIgR minimal promoter, as well as the critical role of USF in enhancing its basal level of transcription in Caco-2 cells.

Mapping of mouse polymeric immunoglobulin receptor (PIgR) gene using simple sequence length polymorphism markers

We found a repetition of CA dinucleotides on the second intron of mouse polymeric immunoglobulin receptor (PIgR) gene. This repetition is genetically polymorphic among mouse strains and was used as a simple sequence length polymorphism marker to map the PIgR gene. Alleles of this and other SSLP markers were determined with PCR for progenies from a back cross between C57BL/6J mice and F1 heterozygotes of AKR/J and C57BL/6J. This mapping located the pIgR gene between D1Mit200 and D1Mit218 of the mouse chromosome 1.

A composite DNA element in the promoter of the polymeric immunoglobulin receptor regulates its constitutive expression

The polymeric immunoglobulin receptor (pIgR), which is constitutively expressed on the basolateral surface of secretory epithelial cells, mediates external translocation of polymeric IgA and pentameric IgM (collectively called pIg) to exocrine secretions. A high level of synthesis must be maintained because the receptor is continuously cleaved to release bound secretory component (SC) in secretory IgA and secretory IgM, as well as free SC from unoccupied receptor. We have isolated the promoter of the pIgR gene and identified a short activating region that is required for the expression of pIgR promoter-driven reporter genes. This region contained an E-box and an inverted repeat sequence (IRS). Gel electrophoresis mobility shift assays with nuclear extracts from different pIgR-expressing epithelial cell lines demonstrated proteins that bind independently to both the E-box and the IRS sequence of the pIgR promoter. In addition, a DNA probe that contained both the E-box and the IRS gave rise to a larger complex that could not be competed by either element on its own. Binding was confirmed by DNase I footprinting of the E-box and IRS sequences with nuclear extracts, and by dimethyl sulfide footprinting in living HT-29 epithelial cells. Finally, a mutation in the pIgR promoter that inhibited protein binding to the E-box and the formation of the larger complex, abolished activated transcription from the reporter gene.

Primary rat lacrimal cells undergo acinar-like morphogenesis on reconstituted basement membrane and express secretory component under androgen stimulation

Single cells or small cell clusters, isolated from the rat lacrimal gland, were incubated on reconstituted basement membrane (matrigel) in a well-defined serum-free medium. During the first days of culture, cells reassociated and reorganized in structures resembling acini. These multicellular structures, maintained in culture for 2 weeks, consisted of well-polarized cuboidal cells surrounding a central lumen and exhibiting apically located microvilli. Myoepithelial cells were observed at the periphery of the acinar structures. Both in the native lacrimal and in the cultured aggregates, epithelial cells displayed strong immunoreactivity for cytokeratin 8, while myoepithelial cells were immunoreactive for vimentin and alpha-smooth muscle isoactin. These data indicate that the cultured aggregates closely mimic the in vivo architecture of lacrimal glands both by morphology and immunohistochemistry. We further demonstrated the presence of an intact androgen receptor and the ability of the cultured aggregates to respond to androgens with increased secretion of the secretory component. Comparable androgen responses were observed in lacrimal gland cultures of 5-week-old male and female rats. In conclusion, we report a morphologically and functionally differentiated culture system of primary rat lacrimal cells, in which androgen-regulated gene expression was observed. This culture model provides a unique experimental paradigm for studying the effects of hormones, cytokines, and growth factors on the morphogenesis, growth, and functional differentiation of lacrimal glands.

Genomic cloning and structural analysis of the murine polymeric receptor (pIgR) gene and promoter region

The role of the polymeric receptor (pIgR) is to transport polymeric IgA across various mucosal epithelial layers. Although several mammalian pIgR cDNAs, including mouse, have been cloned, genomic structure has only been partially analyzed in the human, and neither its 5'-upstream region nor its transcriptional start site is known. We report the isolation and characterization of the murine pIgR gene that spans 32 kb and contains 11 exons. The general organization of the murine gene, including its intron/exon boundaries was similar to its human homolog; however, the second intron was 7.2 kb in the mouse vs. only 0.8 kb in humans. Primer extension and 5'-RACE independently identified the identical transcriptional initiation site. Sequence analysis of 350 base pairs in the 5'-flanking region revealed several motifs, including a TATA box, and putative interferon-gamma, HNF-3beta and AP1 sites. In summary, we have isolated the murine pIgR gene and described its structure and organization.

Transcriptional regulation of the human polymeric immunoglobulin receptor gene by interferon-gamma

IgA is transported into external secretions by the polymeric Ig receptor (pIgR). Interferon-gamma (IFN-gamma), a major regulator of pIgR expression, has been shown to increase pIgR mRNA levels in HT-29 human colon carcinoma cells. To determine the molecular mechanisms of pIgR regulation, genomic DNA containing the 5'-flanking region of the human pIgR gene was isolated and a single start site of transcription in human intestinal epithelial cells was identified. Using chimeric reporter plasmids containing flanking regions of the pIgR gene, a segment of the pIgR promoter which is necessary and sufficient for induction of transcription by IFN-gamma in HT-29 cells was identified. Significantly, the pIgR promoter contains three motifs homologous to the interferon-stimulated response element (ISRE), two in the 5'-flanking region and one in exon 1 of the pIgR gene. The upstream ISREs bind nuclear protein(s) which are constitutively expressed by HT-29 cells, while the exon 1 ISRE binds interferon regulatory factor-1 (IRF-1), following stimulation with IFN-gamma. Furthermore, induction of the IRF-1 promoter by IFN-gamma correlates with induction of the pIgR promoter by IFN-gamma. It has previously been demonstrated that induction of pIgR mRNA by IFN-gamma, requires de novo protein synthesis. It is now shown that IRF-1 is not detected in nuclear extracts from HT-29 cells stimulated with IFN-gamma in the presence of cycloheximide, suggesting that de novo synthesis of IRF-1 is required for induction of pIgR transcription by IFN-gamma.