Selective Up-regulation of Cytokine-induced RANTES Gene Expression in Lung Epithelial Cells by Overexpression of Ikappa BR*

(Received for publication, May 23, 1997)

Prabir Ray Dagger , Liyan Yang , Dong-Hong Zhang , Samir K. Ghosh and Anuradha Ray

From the Department of Internal Medicine, Pulmonary and Critical Care Section, Yale University School of Medicine, New Haven, Connecticut 06520

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES


ABSTRACT

We previously reported the cloning of a cDNA for Ikappa BR (for Ikappa B-related) from human lung alveolar epithelial cells. Ikappa BR is related to the Ikappa B proteins that function as regulators of the NF-kappa B family of transcription factors. Here, we investigated the consequence of Ikappa BR overexpression on the expression of NF-kappa B-regulated chemokine genes in lung alveolar epithelial cells. Chemokines play an important role in many inflammatory diseases such as asthma and AIDS. Overexpression of Ikappa BR in the lung cells resulted in a rapid 50-100-fold greater production of the RANTES (regulated upon activation, normal T expressed and presumably secreted) protein upon cytokine-induction compared with control cells. Ikappa BR overexpression, however, did not enhance interleukin-8 or MIP-1alpha gene expression, despite the fact that the expression of all three chemokine genes are regulated by NF-kappa B. The up-regulation of RANTES gene expression resulting from overexpression of Ikappa BR correlated with increased amounts of a unique RANTES-kappa B binding activity and decreased binding of p50 homodimers. Previous studies have shown that p50 homodimers function as repressors of certain kappa B sites. Our studies suggest that Ikappa BR can aid activation of select NF-kappa B-regulated genes by sequestering p50 homodimers.


INTRODUCTION

We previously described the cloning of a cDNA for Ikappa BR (for Ikappa B-related) from human lung alveolar epithelial cells (1). Ikappa BR belongs to the Ikappa B family of proteins that function as cytoplasmic retention proteins for the Rel-NF-kappa B transcription factors and serve to regulate their functions (2, 3). Several members of the Ikappa B family have now been identified that, in vertebrates, include Ikappa Balpha , Ikappa Bbeta , Ikappa Bgamma , Ikappa BR, Bcl-3, p105, and p100 (reviewed in Refs. 2 and 3). So far, five members of the NF-kappa B family have been described that are c-Rel, NF-kappa B1 (p50), NF-kappa B2 (p52), RelA (p65), and RelB (reviewed in Refs. 4-6). Most members of the NF-kappa B family can form homo- or heterodimers (except for RelB, which only forms heterodimers with p50 or p52) that bind slightly different kappa B motifs (2-6). The existence of multiple homo- and heterodimeric forms of NF-kappa B-Rel proteins in a given cell type requires tight regulation of their activity that appears to be achieved via differential interactions with different Ikappa B proteins. For example, both Ikappa Balpha and Ikappa Bbeta inhibit the DNA binding activity of p50-p65 heterodimers but not that of the p50 homodimer (2, 3). Bcl-3, on the other hand, interacts with (p50)2 or (p52)2 and has been reported to behave as a transactivator (2, 3). Because gene knockout studies indicate that the different NF-kappa B-Rel proteins are not functionally redundant (2-6), it may be speculated that the Ikappa B proteins, which regulate their functions, also play distinct roles in the cell.

NF-kappa B proteins control the expression of multiple genes involved in inflammatory processes such as those encoding pro-inflammatory cytokines and chemokines (4-6). Chemokines are low molecular weight proteins secreted in response to inflammatory cytokines and play a critical role in leukocyte trafficking. Recently, the C-C chemokines RANTES, MIP1alpha , and MIP1beta were found to suppress HIV-11 infection (7, 8). The suppressive activity of MIP1alpha , MIP1beta , and RANTES for HIV-1 infection combined with the identification of CCR5 (the cell surface receptor for these chemokines) as a coreceptor for HIV-1 entry (9-13) has led to the proposal that these chemokines may have therapeutic benefits in blocking or delaying virus infection.

RANTES, originally isolated as a cDNA from CD8+ T cells (14), also plays an important role in the chemotaxis of cells such as eosinophils (15, 16), mast cells (17, 18), and CD45 RO+ memory T cells (19), which predominate in allergic inflammation. In humans, an up-regulation of RANTES message was observed in the airways of asthmatics (20-22) and in a local endobronchial allergen challenge model, a significant correlation between RANTES concentration and eosinophil number was observed at the challenge site (23). In a murine model of endotoxemia, significant levels of RANTES mRNA and protein were detected in lung homogenates of mice following intraperitoneal administration of endotoxin and RANTES mRNA was detected as early as 1-2 h post endotoxin stimulation in the lung (24). Furthermore, the RANTES protein was immunolocalized to the alveolar epithelium in this setting and was implicated in macrophage recruitment in the lungs (24). In other studies, the cytokine TNFalpha was shown to induce RANTES mRNA at 16 h post-stimulation in lung epithelial cells (25). Although lung-derived RANTES has been implicated in the recruitment of eosinophils in the lungs of asthmatics, little is known at the molecular level about mechanisms that control RANTES gene expression in lung cells. Clearly, an understanding of such mechanisms could be useful in the design of drugs to combat asthma on the one hand and for developing strategies for suppressing HIV-1 infection via overproduction of RANTES on the other.

Here we show that overexpression of Ikappa BR can selectively up-regulate cytokine-induced expression of the RANTES gene in lung epithelial cells. Furthermore, this up-regulation of RANTES gene expression is associated with increased binding of a unique NF-kappa B complex to the RANTES kappa B region and decreased binding of p50 homodimers.


EXPERIMENTAL PROCEDURES

Generation of Stable Transfectants

The oligonucleotide GACTACAAGGACGACGATGACAAA encoding the FLAG octapeptide epitope (DYKDDDDK; IBI/Kodak) was inserted immediately downstream of the codon for amino acid 479 of Ikappa BR using polymerase chain reaction techniques. The FLAG epitope-tagged Ikappa BR cDNA was subcloned into pcDNA3 (Invitrogen) for expression under the control of the cytomegalovirus promoter in eukaryotic cells and for in vitro transcription with T7 polymerase. The cloning was confirmed by coupled in vitro transcription-translation reactions using T7 polymerase and the TNT rabbit reticulocyte system (Promega). The in vitro translated product was immunoprecipitated with anti-FLAG monoclonal Ab (M2; IBI/Kodak) and analyzed by SDS-PAGE and autoradiography. This plasmid and the insert-free vector pcDNA3 were subsequently used to generate the stable transfectants A549/Ikappa BR and A549/vector, respectively. Briefly, A549 cells (ATCC) were maintained in Dulbecco's modified Eagle's medium/Ham's F-12 medium (Life Technologies, Inc.) supplemented with 10% fetal bovine serum (Life Technologies, Inc.). Cells were transfected using the calcium-phosphate coprecipitation procedure (26), and transfected cells were selected by using 500 µg/ml of active G418 (Life Technologies, Inc.) in culture medium 48 h after transfection. G418-resistant clones were picked after 2 weeks, and pooled clones were used for all analyses.

Transient Transfection Assays

For transient transfection assays, cells were transfected by the the calcium-phosphate coprecipitation procedure (26). The wt RANTES promoter-reporter (luciferase) plasmid contained promoter sequences between -897 (StuI) and +54 (KpnI) (derived from a -961/+54 construct obtained from A. M. Krensky and co-workers (27)), and the mutant -897/+54 plasmid was constructed by swapping a fragment (-181/+54) containing mutations in the A and B NF-kappa B sites (28) with the corresponding wt fragment. 16 h after transfection, cells were washed, suspended in serum-free medium, and treated with recombinant hIL-1alpha (5 ng/ml) or hTNFalpha (50 ng/ml) and harvested 6 h later for assaying beta -galactosidase and luciferase activity. Luciferase assays were performed using the Luciferase Assay System of Promega (Wisconsin), and the luciferase activity was measured in the LB 9501 luminometer of Berthold, Inc. (Germany). beta -Galactosidase assays were performed using chlorophenyl beta -D-galactoside as substrate.

Northern Blot Analysis and ELISAs

For Northern blot analyses, cells were either left untreated or treated with recombinant hIL-1alpha (5 ng/ml; R & D Systems) or recombinant hTNFalpha (50 ng/ml; R & D Systems) for the indicated times in serum-free medium. The culture supernatants were collected and clarified by centrifugation at 12,000 × g for 10 min, and the supernatants were stored at -70 °C until further use for protein estimation by ELISA. Total RNA was prepared from the cell pellets by treatment with Trizol (Life Technologies, Inc.) according to the instructions of the manufacturer. Total RNA (15 µg) from each sample was fractionated on a formaldehyde agarose gel, transferred to nylon membrane, and cross-linked to the membrane by UV light (Stratalinker; Stratagene). Prehybridization of the membranes was performed with QuikHyb (Stratagene) at 50 °C for 2 h. Fragments derived from the RANTES gene, the IL-8 gene, the Ikappa BR gene and glyceraldehyde 3-phosphate dehydrogenase gene were labeled with [alpha -32P]dCTP using a Random Primed DNA labeling kit (Boehringer Mannheim) and used as probes to detect expression of the corresponding mRNAs. Hybridizations with individual probes were carried out with ~3 × 106 cpm/ml of hybridization buffer (QuikHyb). The blots were washed twice for 15 min at room temperature in 2 × SSC/0.1% SDS and once for 15 min at 42 °C in 0.2 × SSC/0.1% SDS. The RANTES probe was a 410-base pair EcoRI/HindIII fragment of the RANTES cDNA (14), the IL-8 probe was a 250-base pair cDNA fragment (29), and the MIP1alpha probe was an EcoRI fragment of the MIP1alpha cDNA (30).

Preparation of Cell Extracts and EMSAs

For the preparation of nuclear extracts, cells were harvested and suspended in ice-cold phosphate-buffered saline. The cells were collected by centrifugation and suspended in ice-cold buffer A (10 mM Hepes, pH 7.9, 10 mM KCl, 0.1 mM EDTA, 1 mM dithiothreitol, and a mixture of protease inhibitors (Boehringer Mannheim); 100 µl per 2 × 107 cells). After incubation of on ice for 10 min, the mixture was diluted with an equal volume of buffer A containing 0.4% Nonidet P-40 and immediately centrifuged at 800 × g for 1 min at 4 °C. The pelleted nuclei were washed in buffer A-Nonidet P-40 and suspended in 50 µl of buffer B (20 mM Hepes, pH 7.9, 420 mM NaCl, 1 mM EDTA, 1 mM dithiothreitol, 25% glycerol, and a mixture of protease inhibitors). The nuclei were incubated with shaking for 15 min at 4 °C and centrifuged at 14,000 × g at 4 °C. The supernatants were aliquoted and quickly frozen on dry ice and stored at -70 °C until further use. The experiments were repeated with different batches of nuclear extracts to ensure reproducibility of data. Binding reactions and gel electrophoresis (using 6% native polyacrylamide gels) were performed as described previously (1).

Immunoprecipitation and Western Blotting

Cells in 6-cm plates were washed and starved for 30 min in serum-free Dulbecco's modified Eagle's medium/Ham's F-12 medium without methionine or cysteine. Cells were labeled in 2 ml of the same medium with Express Label (NEN Life Science Products) containing [35S]methionine and cysteine at 100 µCi/ml for 3 h at 37 °C. Cells were washed, and 35S-labeled nuclear and cytoplasmic extracts were prepared. Equal amounts of counts from nuclear and cytoplasmic fractions were diluted 10-fold in buffer containing 50 mM Tris-HCl, pH 7.5, 150 mM NaCl, 10% glycerol, 0.1% Triton X-100, 0.5 mM EDTA, and a mixture of protease inhibitors (Boehringer Mannheim). The extracts were then precleared by incubation with fixed Staphylococcus aureus cells (Zysorbin; Zymed) for 2 h at 4 °C. The mixtures were centrifuged, and immunoprecipitations were performed with the supernatants using anti-FLAG Ab M2 coupled Sepharose (IBI/Kodak) or with Sepharose coupled control IgG1 by overnight incubation at 4 °C. The beads were washed four times in the same buffer, suspended in 2 × SDS-PAGE sample buffer and analyzed by electrophoresis on 4-20% gradient gels (Bio-Rad). In the sequential immunoprecipitation-Western blot analyses, unlabeled nuclear and cytoplasmic extracts were subjected to immunoprecipitations with the anti-FLAG antibody, and the immunoprecipitates were separated by SDS-PAGE and transferred to polyvinylidene difluoride membrane. The membrane was probed with different anti-NF-kappa B antibodies, and antibody interactions were detected by chemiluminiscence with horseradish peroxidase-conjugated secondary antibody and ECL reagent (Amersham Corp.).


RESULTS AND DISCUSSION

To address the effect of Ikappa BR on NF-kappa B-mediated chemokine gene regulation in lung epithelial cells, we established A549 clones stably expressing epitope-tagged Ikappa BR, named A549/Ikappa BR. Ikappa BR was epitope-tagged to distinguish the protein expressed from the expression vector from other endogenous Ikappa B proteins. A pool of stable transfectants were incubated with IL-1alpha or TNFalpha for various lengths of time and analyzed for expression of different chemokine mRNAs by Northern blotting techniques. In control A549/vector cells, TNFalpha induced a very low level of RANTES mRNA expression at 24 h post-stimulation, and the level of induction with IL-1alpha was barely detectable even after 24 h (Fig. 1). In contrast, in A549/Ikappa BR cells, both TNFalpha and IL-1alpha caused an up-regulation of RANTES gene expression as early as 2 h post-stimulation, which continued to increase even at 24 h after stimulation. We then tested whether Ikappa BR overexpression specifically up-regulated RANTES gene expression or the expression of other NF-kappa B-regulated genes such as IL-8 (31-35) and MIP-1alpha (macrophage inflammatory protein-1alpha ) (36, 37) as well. As illustrated in Fig. 1A, IL-8 gene expression induced by either IL-1alpha or TNFalpha was partly inhibited in A549/Ikappa BR cells. We also studied the effect of Ikappa BR overexpression on the expression of MIP1alpha , whose induced expression is barely detectable in A549 cells. Overexpression of Ikappa BR failed to up-regulate IL-1alpha - or TNFalpha -induced MIP1alpha expression in these cells (data not shown). We tested the culture supernatants for the presence of RANTES and IL-8 proteins. As shown in Fig. 1B, the protein data were in good agreement with the Northern analyses. At 6 h post-stimulation with IL-1alpha or TNFalpha , A549/Ikappa BR cells produced 50- and 100-fold more RANTES than the control cells. The results of these experiments showed that Ikappa BR preferentially up-regulated RANTES gene expression in A549 cells.


Fig. 1. Up-regulation of RANTES gene expression in A549 lung epithelial cells overexpressing Ikappa BR. A, A549 cells were stably transfected with pcDNA3 empty vector (containing the cytomegalovirus promoter; Invitrogen; A549/vector) or with the same vector containing a cDNA encoding Ikappa BR tagged with a FLAG epitope at its COOH terminus (A549/Ikappa BR). Cells were either left untreated or treated with recombinant hIL-1alpha (5 ng/ml; R & D Systems) or recombinant hTNFalpha (50 ng/ml; R & D Systems) for the indicated times. Total RNA was isolated from each sample and analyzed by Northern blotting techniques as described under "Experimental Procedures." The probes used are indicated on the left. Hybridization was performed using QuikHyb (Stratagene), and the same blot was stripped of hybridized probe and reused for all the hybridizations. B and C, A549/vector or A549/Ikappa BR cells were either left untreated or treated with recombinant IL-1alpha or TNFalpha as in A for 6 or 24 h. Cell culture supernatants were analyzed for the presence of RANTES (B) or IL-8 protein (C) by ELISA (RANTES, Amersham Corp., sensitivity > 2.5 pg/ml; IL-8, R & D Biosystems, sensitivity > 6 pg/ml). The data in each case are representative of three independent experiments.
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To determine whether the Ikappa BR-mediated up-regulation of cytokine-induced RANTES mRNA expression was associated with activation of the RANTES promoter, A549/vector and A549/Ikappa BR cells were transiently transfected with a reporter gene (luciferase) construct containing ~900 nucleotides from the 5'-flanking region immediately upstream of the transcription start site of the RANTES gene (27, 28). The 5'-flanking region of the RANTES gene contains two NF-kappa B-binding sites in tandem, termed A and B (see Fig. 3 and Refs. 27 and 28). In A549/vector cells, the RANTES promoter was activated by IL-1alpha or TNFalpha between 1.5-2-fold (Fig. 2). In contrast, in A549/Ikappa BR cells, IL-1alpha and TNFalpha activated the RANTES promoter between 7-8- and 8-10-fold, respectively (Fig. 2). Mutations in the A and B sites in the context of the 900-base pair promoter abolished reporter gene activity in both cell types. The difference between the level of RANTES mRNA expression and the fold induction of the RANTES promoter in cytokine-induced A549/Ikappa BR cells can be attributed to the stability of RANTES mRNA. RANTES mRNA lacks the destabilizing AUUUA sequence in its 3'-untranslated region (14). This probably explains why RANTES mRNA induced by TNFalpha or IFN-gamma was reduced by only 30% after incubation for 4 h in the presence of actinomycin D (25). IL-8, on the other hand has a half-life of less than 1 h in epithelial cells (38). Because mRNA destabilization appears to play an insignificant role in the regulation of RANTES production, it stands to reason that an up-regulation of RANTES promoter activity by IL-1 or TNF in A549/Ikappa BR cells would cause a significant difference in steady-state levels of RANTES mRNA and protein levels between the Ikappa BR-overexpressing cells and the control cells.


Fig. 3. Augmented binding of an NF-kappa B-Rel complex to the RANTES NF-kappa B region with nuclear extracts from A549/Ikappa BR cells. A549/vector or A549/Ikappa BR cells were either left untreated or treated with hIL-1alpha or hTNFalpha and collected at the indicated times for the preparation of nuclear extracts. Nuclear extracts (4 µg) were incubated with 20,000 cpm of a 32P-labeled oligonucleotide containing the RANTES kappa B region containing two kappa B-binding sequences A and B in tandem (28). Nuclear extracts prepared from cells stimulated with hTNFalpha for 2 h were used to assess DNA binding activity by EMSAs in the presence or the absence of the indicated oligonucleotides (at 100-fold molar excess) or antibodies (1-2 µg/20-µl reaction volume). The anti-p50 Ab used in lane 8 was the anti-NLS Ab (114x; Santa Cruz Biotech.). All of these antibodies, including the anti-FLAG Ab M2 (47), have been previously used by us and other investigators in EMSAs. The major DNA-protein complexes (I, II, and III) are indicated on the right. The open arrow indicates a nonspecific complex. The oligonucleotides containing the wt RANTES kappa B sites (underlined) or mutated A and B sites are shown. Different preparations of nuclear extracts yielded essentially identical data with some differences in the intensity of the nonspecific band. The binding reactions were analyzed by electrophoresis on 6% native polyacrylamide gels (1).
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Fig. 2. Increased activation of the RANTES promoter by IL-1alpha and TNFalpha in A549/Ikappa BR cells compared with A549/vector cells. Cells were transiently transfected with a RANTES promoter-reporter construct that included ~900 nucleotides of the region immediately upstream of the transcription start site and the complete 5'-untranslated region excluding the translational start site (27, 28). Cells in 60-mm Petri dishes were transfected by the calcium phosphate coprecipitation method with 1.5 µg of the reporter plasmid together with 1 µg of RSVbeta gal (a vector for constitutive expression of beta -galactosidase for monitoring transfection efficiency) and carrier plasmid adding up to a total of 10 µg of DNA. 16 h after transfection, cells were washed, treated with recombinant hIL-1alpha (5 ng/ml) or hTNFalpha (50 ng/ml), and harvested 6 h later for assaying beta -galactosidase and luciferase activity. The data are representative of three independent experiments with deviations of not more than 10% between experiments.
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We next examined the possibility that the Ikappa BR-mediated up-regulation of RANTES promoter activity was associated with altered binding of protein(s) to the RANTES kappa B region. Toward this end, EMSAs were performed with nuclear fractions of cytokine-induced A549/Ikappa BR cells and A549/vector cells and a radiolabeled 32-base pair double stranded oligonucleotide containing the two RANTES NF-kappa B sites as the probe. Although IL-1alpha and TNFalpha caused induction of NF-kappa B DNA binding activity in both cell types, the DNA-protein complexes formed with the activated proteins were not identical with nuclear extracts prepared from the two cell types (Fig. 3). As illustrated in Fig. 3, the binding intensity of complex I was equivalent in the two cell types. The intensity of complex II was 2-3-fold greater with nuclear extracts of A549/vector cells compared with that observed with A549/Ikappa BR nuclear extracts. However, the intensity of complex III was at least 10-15-fold (as judged by densitometric scanning) greater with nuclear extracts of A549/Ikappa BR cells compared with that observed with extracts of control cells (Fig. 3, lower panel). Two additional minor complexes migrating more slowly than complex I were also obtained with extracts of both cell types. All of these complexes were specific because an excess of the same unlabeled oligonucleotide efficiently competed for formation of the complexes, whereas an oligonucleotide containing mutations in the kappa B sites failed to compete (Fig. 3, lanes 6 and 7, respectively). Because different members of the NF-kappa B-Rel family could potentially interact with the kappa B motifs, we used specific antibodies to determine the composition of the different polypeptide complexes. Formation of complex I was affected with both anti-p50 and anti-p65 antibodies, suggesting that it contained the classic p50-p65 heterodimer (lanes 8 and 9). Complex II and complex III formation were both affected only by the anti-p50 antibody (lane 8). The complex migrating immediately after (slower than) complex I was affected only by the anti-p65 antibody (lane 9). This complex may contain a p65 homodimer. None of the complexes were inhibited/supershifted by the antibodies against c-Rel, p52, and RelB (lanes 10-12). Also, Ikappa BR itself did not appear to be present in any of the complexes because a monoclonal antibody against the FLAG epitope (Ab M2; IBI/Kodak) had no effect on the complexes (lane 13).

The ability of the anti-p50 antibody to affect both complex II and complex III formation and the selective augmentation of complex III formation with the A549/Ikappa BR nuclear extracts prompted us to further analyze the nature of both II and III. Toward this end, we first tested whether recombinant p50 (Promega) could bind to the RANTES kappa B region. The recombinant p50 was derived from a full-length cDNA encoding 453 amino acids (39) that was identical to the human p50 cDNA described previously (40). As shown in Fig. 4A, p50 homodimers bound to the RANTES kappa B region. As expected, the (p50)2-DNA complex could be supershifted with the anti-p50 antibody but not with the anti-p65 (used as control) antibody (Fig. 4A). Also, in accordance with previous findings (31, 34), recombinant p50 did not interact with the IL-8 kappa B site (Fig. 4A). Interestingly, the (p50)2-RANTES kappa B complex comigrated with complex II (compare lanes 1, 4, and 5 in Fig. 4A).


Fig. 4. The Ikappa BR-augmented DNA binding activity is not (p50)2 but may be a heterodimer containing p50. EMSAs were carried out with either recombinant p50 (rp50; Promega) or nuclear extracts (n.e.) of A549/Ikappa BR cells. A, 32P-labeled RANTES oligonucleotide was incubated with rp50 in the presence (lanes 2 and 3) or the absence of the anti-NLS anti-p50 Ab or an anti-p65 Ab (372x; Santa Cruz Biotech., used as a control). The samples were analyzed in parallel with binding reactions carried out with nuclear extracts from control and A549/Ikappa BR cells and the RANTES probe (lanes 4 and 5, respectively). The binding of rp50 to the IL-8 kappa B site was also examined in the same experiment. B, the ability of the anti-NLS Ab and the anti-NH2-terminal anti-p50 Ab (1191x; Santa Cruz Biotech.) to supershift/inhibit binding of rp50 or A549/Ikappa BR nuclear proteins to the RANTES probe was investigated. C, nuclear extracts of A549/Ikappa BR cells were incubated with the wt RANTES probe with or without (lane 1) a 100-fold molar excess of oligonucleotides containing a wt (lane 2) or a mutated (lane 3) IL-8 kappa B site. D, binding reactions were performed with A549/Ikappa BR nuclear extracts and the wt (lane 1) or mutant RANTES probes containing either a mutant A site and a wt B site (mAwtB; lane 2) or a wt A site and a mutant B site (wtAmB; lane 3). Binding reactions were analyzed by electrophoresis on 6% native polyacrylamide gels (1).
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Because both complexes II and III could not contain (p50)2 and the data in Fig. 4A suggested that complex II contained (p50)2, we further investigated the composition of the faster migrating complex III with two different anti-p50 antibodies. Although the first antibody (114x; Santa Cruz Biotech) recognizes sequences mapping within the nuclear localization signal (NLS) region of p50, the second antiserum (1191x; Santa Cruz Biotech) was raised against the NH2-terminal of p50. Both antibodies supershifted the RANTES DNA-(p50)2 complex (Fig. 4B). However, the anti-NLS antibody but not the anti-NH2-terminal antibody supershifted complex III (Fig. 4B). The latter antibody did not inhibit complex I (p50-p65) formation either (Fig. 4B). This was consistent with previous reports showing weaker effects of some p50-specific antisera on p50 heterodimers than on p50 homodimers (32, 41). These results demonstrated that complex III did not consist of p50 homodimers.

Because our Northern analyses and ELISAs showed that Ikappa BR overexpression actually slightly inhibited IL-8 gene expression, we tested the ability of the IL-8 kappa B site to compete in the EMSA. At a 100-fold molar excess, the wt IL-8 kappa B sequence did compete for formation of complex III, albeit incompletely (Fig. 4C, lane 4). The binding of the p50-p65 heterodimer (complex I) was only partially competed for by the wt IL-8 kappa B sequence (Fig. 4C, lane 4). This was in accordance with previous reports showing the preferential binding of p65-c-rel heterodimers rather than p50-p65 heterodimers to the IL-8 kappa B site (31, 34, 35), and as shown previously (31, 34), the binding of the p50 homodimers (complex II) was not competed out by the wt IL-8 kappa B sequence. The formation of complex III with the RANTES probe could not be competed out with 200-fold excess of oligonucleotides containing consensus binding sequences for a few additional families of transcription factors, C/EBP, Oct, CREB/ATF, AP-1, and AP-2 (data not shown). Also, the mobility of complex III is far lower than what might be expected of an NF-kappa B-HMG-I(Y) dimeric complex (42). Taken together, it appears that complex I is a heterodimer of p50-p65 and complex II contains p50 homodimers. Complex III may contain a homodimer of a p50-related protein or more likely a heterodimer containing p50 and an as yet unidentified Rel protein, a splice variant of a Rel protein, or a non-Rel protein. It is unlikely that this complex contains any of the known splice variants of p65 (p65Delta , p65Delta 2, or p65Delta 3), all of which are larger in size than p50. A TNFalpha -inducible complex of similar mobility (faster than p50 homodimers) and with reactivity only to anti-p50 antiserum but not to any other Rel-specific antisera was previously detected in primary murine embryonal fibroblasts (41).

Because the RANTES kappa B site contains two NF-kappa B sites (A and B) (27, 28), we also examined the involvement of the individual sites for formation of the different complexes using two mutant probes. One of these mutants contained a mutant A site and a wt B site (mAwtB), whereas the other contained a wt A site and a mutant B site (wtAmB). As shown in Fig. 4D, both probes formed complex I, although the binding to wtAmB was slightly better. Also, whereas the intensity of complex III appeared to be the same with either probe, it was less than that obtained with the complete wt probe (Fig. 4D, compare lanes 2 and 3 with lane 1). Complex II containing (p50)2, however, was only formed with the mAwtB probe (lane 2), whereas the p65 homodimeric complex was formed only with the wtAmB probe (lane 3). Thus, both A and B sites need to be intact for stabilization of complex III. Collectively, the EMSAs showed that overexpression of Ikappa BR decreases formation of complex II but augments formation of complex III.

To determine whether the observed decrease in binding of (p50)2 to the RANTES probe with nuclear extracts prepared from A549/Ikappa BR cells stemmed from the ability of Ikappa BR to interact with p50 in vivo, we investigated the subcellular distribution of Ikappa BR in A549 cells. Untreated A549/Ikappa BR cells expressing FLAG epitope-tagged Ikappa BR protein were metabolically labeled with [35S]methionine, and the cell lysates were fractionated into cytoplasmic and nuclear fractions. The fractions were subjected to immunoprecipitation with the anti-FLAG monoclonal Ab M2 (IBI/Kodak). Two specific bands were detected on the SDS gel resulting from immunoprecipitations of the cytoplasmic fraction. The identity of the upper band was confirmed to be Ikappa BR in several Western blot experiments using a polyclonal antisereum against Ikappa BR (1). No specific bands were immunoprecipitated from the nuclear fraction of the A549/Ikappa BR cells. These results showed that Ikappa BR predominantly resides in the cytoplasm. To determine the identity of the coimmunoprecipitated band from the cytoplasmic fraction, we performed sequential immunoprecipitation-Western blot experiments. In these experiments, cytoplasmic extracts of untreated A549/Ikappa BR cells were immunoprecipitated with M2. The immunoprecipitate was divided into three parts and subjected to Western blot analysis with antibodies against three different NF-kappa B-Rel proteins. The results of this experiment suggested that Ikappa BR preferentially interacts with p50 (Fig. 5B). Use of a different anti-p50 antibody that works well in Western blot analysis (BioMol) also gave identical results (data not shown). A similar immunoprecipitation-Western blot experiment was also simultaneously carried out with untransfected A549 cells using a rabbit anti-Ikappa BR antibody (1). The results were essentially similar except that less p50 was immunoprecipitated from untransfected A549 cells (data not shown). This was what we expected because the endogenous Ikappa BR is not expressed in sufficient amounts to sequester all (p50)2, which is probably why, as all of our data suggest, these cells make much less RANTES than the Ikappa BR-overexpressing cells.


Fig. 5. Ikappa BR predominantly resides in the cellular cytoplasm and associates with a p50-p50-related protein. A, A549/Ikappa BR cells were metabolically labeled with Express Label (NEN Life Science Products) as described under "Experimental Procedures." Cells were lysed, and cytoplasmic and nuclear extracts (c.e. and n.e., respectively) were prepared. The extracts were precleared and then immunoprecipitated with control mouse IgG1 coupled (lane 1) or anti-FLAG Ab M2 coupled Sepaharose (IBI/Kodak; lane 2). Immunoprecipitates were extensively washed and directly analyzed by SDS-PAGE. B, cytoplasmic extracts prepared from unlabeled A549/Ikappa BR cells were immunoprecipitated with M2, and the immunoprecipitates were boiled in 2 × SDS-PAGE sample buffer. The supernatant was divided into three equal parts, subjected to SDS-PAGE, and analyzed by immunoblotting with antibodies against p50 (114x), p65 (372x), and c-Rel (70x) (all purchased from Santa Cruz Biotech.).
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In our previous report we demonstrated that recombinant Ikappa BR inhibits the DNA binding activity of (p50)2 in EMSAs (1). Our present data suggest that in intact cells Ikappa BR preferentially interacts with p50. Earlier studies have shown that among the various NF-kappa B-Rel dimers, (p50)2 possesses the highest affinity for the NF-kappa B site present in the Igkappa enhancer (43). This probably explains why complex III can only be detected in Ikappa BR-overexpressing cells; by sequestering (p50)2, Ikappa BR causes a shift in the stoichiometry of complex III to complex II from ~1:2 in control cells to ~10:1 in Ikappa BR-overexpressing cells (see Figs. 3 and 4A). In control cells, occupancy of the B site in the RANTES NF-kappa B region by (p50)2 can be expected to exert a negative regulatory influence on RANTES gene expression because (p50)2 has been shown to act as a dominant repressor of transcription from certain kappa B sites (44-46). By permitting increased binding of complex III, Ikappa BR allows the RANTES gene to override the competitive repressor activity of coexisting (p50)2. This model is particularly attractive in intact cells where the various NF-kappa B dimers are in competition to bind limiting amounts of target DNA unlike in EMSAs where a large excess of the probe is present. A similar mechanism, involving a switch from inhibitory p50 homodimers to p50-p65 activators, was proposed in the induction of IL-2 gene expression in activated CD4+ T cells (46). In addition to less competition from inhibitory (p50)2, synergy between complex III and complex I can also be envisaged as a component in the up-regulation of RANTES gene expression in A549/Ikappa BR cells. In our previous studies we showed that Ikappa BR added in vitro to nuclear extracts inhibited the DNA binding activity of p50-p65 heterodimers in EMSAs. In these studies, nuclear extracts prepared from control cells and Ikappa BR-overproducing cells displayed similar binding of the p50-p65 heterodimer to the RANTES kappa B region. The difference in the two results can be best explained by the fact that the p50-p65 heterodimer in vivo is normally sequestered by Ikappa Balpha and Ikappa Bbeta via the p65 subunit of the complex and therefore unavailable for interaction with excess Ikappa BR in A549/Ikappa BR cells.

Although Ikappa BR overexpression resulted in an up-regulation of RANTES gene expression, it did not stimulate IL-8 gene expression, which is also regulated by NF-kappa B. It is important to note in this regard that the p50 homodimer does not bind the IL-8 kappa B site as this study and previous studies show (31, 34), and therefore the IL-8 promoter should not be subjected to repression by this dimer. Furthermore, the expression of the IL-8 gene has been shown to require not only the NF-kappa B site in the promoter but also the adjacent C/EBP site. It is likely that the synergism between the C/EBP site-binding protein C/EBPbeta (NF-IL6) and the p65-c-Rel heterodimer, which is the major IL-8 kappa B binding activity (31, 34), is greater than that between C/EBPbeta and the proteins constituting complex III, and therefore the increased availability of the latter does not up-regulate IL-8 gene expression.

The NF-kappa B region of the RANTES promoter is important for its induction in activated T lymphocytes (28). Our experiments indicate that this region is also critical for RANTES promoter activation in lung alveolar epithelial cells. However, T cells express the RANTES gene only around 3-5 days after activation (28) in contrast to detectable expression in lung epithelial cells ~20-24 h after stimulation that can be shifted to as early as 2 h post-stimulation by overexpression of Ikappa BR. It appears that an up-regulation of RANTES gene expression in lung epithelial cells involves the formation of a unique NF-kappa B-Rel complex (complex III) with the RANTES kappa B site. Our data suggest that overexpression of Ikappa BR sequesters (p50)2, which may facilitate the binding of the unique complex to the RANTES kappa B region. This complex was not detected in EMSAs with nuclear extracts of activated T cells (28). Therefore, the expression of the RANTES gene might follow different kinetics through the involvement of different DNA-binding proteins. In inflammatory disease conditions such as asthma and endotoxemia, where an up-regulation of RANTES gene expression has been reported in lung epithelial cells (20-22, 24), the expression of Ikappa BR and formation of complex III need to be investigated in the disease processes. The present system will allow us to further characterize complex III, which might provide a tool for the specific modulation of RANTES gene expression in different diseases.


FOOTNOTES

*   This work was supported by National Institutes of Health Grants HL 52014 (to P. R.) and AI 31137 (to A. R.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Dagger    To whom correspondence should be addressed: Dept. of Internal Medicine, Pulmonary and Critical Care Section, Yale University School of Medicine, 333 Cedar St., New Haven, CT 06520. Tel.: 203-785-3620; Fax: 203-785-3826; E-mail: Prabir.Ray{at}qm.yale.edu.
1   The abbreviations used are: HIV-1, human immunodeficiency virus, type I; Ab, antibody; PAGE, polyacrylamide gel electrophoresis; wt, wild type; IL, interleukin; hIL, human IL; TNF, tumor necrosis factor; hTNF, human TNF; ELISA, enzyme-linked immunosorbent assay; EMSA, electrophoretic mobility shift assay; NLS, nuclear localization signal.

ACKNOWLEDGEMENTS

We thank A. M. Krensky for the kind gift of the RANTES reporter plasmids, J. A. Elias and N. H. Ruddle for critically reading the manuscript, and Z. Zhou for assistance with ELISAs.


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