A Bidirectional Regulation between the TR2/TR4 Orphan Receptors (TR2/TR4) and the Ciliary Neurotrophic Factor (CNTF) Signaling Pathway*

Win-Jing YoungDagger §, Yi-Fen LeeDagger §, Susan M. Smithparallel , and Chawnshang Chang§**

From the § George Whipple Laboratory for Cancer Research, Departments of Pathology, Urology, and Biochemistry, University of Rochester Medical Center, Rochester, New York 14642 and the parallel  Department of Nutritional Sciences, University of Wisconsin, Madison, Wisconsin 53792

    ABSTRACT
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Previously, we reported that the nuclear orphan receptor TR4 could induce transcriptional activity via the 5th intron of the ciliary neurotrophic factor (CNTF) alpha  receptor gene (CNTFR-I5). Here we show CNTF could increase TR4 expression and enhance the DNA-binding capacity of TR4. Interestingly, the expression of TR2, a close family member of TR4, could also be induced by CNTF. In return, TR2 induced CNTFRalpha transcriptional activity through binding to a direct repeat response element of AGGTCA within CNTFR-I5. The possibility of this mutual influence between TR2 and the CNTF signaling was further strengthened by in situ hybridization. Similar expression patterns of TR2 and CNTFRalpha were observed in most of the developing neural structures such as the ganglia, neural epithelia, spinal cord, and the periventricular areas of brain. Together, our data suggest that an interaction between TR2/TR4 and the CNTF signaling pathway may occur, supporting the hypothesis that TR2/TR4 may play important roles in neurogenesis.

    INTRODUCTION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The testicular receptor 2 (TR2)1 and testicular receptor 4 (TR4) orphan receptors belong to the same subfamily within the superfamily of steroid/thyroid hormone receptors (1, 2). They are termed "orphan receptor" because no ligands have been identified. As are other steroid receptors, TR2 and TR4 are transcriptional factors that trigger regulation of their target genes by binding to the hormone-response elements, thus leading to the activation of gene transcription (3). The hormone response elements for TR2 and TR4 consist of the AGGTCA direct repeat with a 1-6-base pair spacing (DR1-DR6). The affinity of TR2 for these DRs follows the order: DR1 > DR2 > DR5, DR4, DR6 > DR3 (4); a similar tendency was observed for TR4.2 The finding of identical P and D boxes in the DNA-binding domains for TR2 and TR4 reasonably explains such a similar DNA-binding preference and implies that the function of these two receptors may overlap in certain biological processes. Indeed, similar actions of TR2 and TR4 were observed in the retinoic acid (RA) signal transduction pathway and in the Simian virus 40 promoter recognition2 (4-6).

Earlier studies of TR2 function focused on its role in the reproductive organs where TR2 cDNAs were initially identified. Several TR2 isoforms, TR2-5, -7, -9, and -11, with different truncations in the C-terminal region, were isolated from testis and prostate cDNA libraries (7). High TR2 mRNA levels were detected in mouse embryos beginning at embryonic day 9 (E/9) and in adult testis (8). Overexpression of TR2 causes aggressive fighting behavior observed in both male and female transgenic mice,3 suggesting TR2 may make important contributions to nervous system development. High abundance of TR4 messages found in many brain regions, such as the hippocampus and cerebellum (2), and within the active proliferating zone of the developing nervous system in embryos (9), has suggested that TR4 participates in neurogenesis.

Signal transduction of the ciliary neurotrophic factor (CNTF) requires binding to its receptor CNTFRalpha (10), which then sequentially associates with two structurally related beta  signal-transducing receptor components, gp130 and the leukemia inhibitory factor receptor beta  (LIFRbeta ) (11, 12). This association is then followed by signal transduction (11). Whereas gp130 and LIFRbeta are ubiquitously distributed, CNTFRalpha expression is restricted to CNTF-responding cells of the nervous system (13). Interestingly, CNTFRalpha does not merely act as a receptor; a soluble form of CNTFRalpha can potentially interact with LIFRbeta following its release from the membrane (14). Mice with null mutation in CNTFRalpha gene died shortly after birth and exhibited profound deficits in all motor neuron populations examined (15), suggesting that CNTFRalpha is essential for the developing nervous system.

The regulation of the CNTFRalpha gene expression remains unclear. A previous report published by Valenzuela et al. (16) showed that the fifth intron of the CNTF alpha  receptor gene (CNTFR-I5) contains six copies of AGGTCA-like sequences, which are preferentially bound by RA receptors, retinoid X receptors, and many orphan receptors (3, 4). These AGGTCA-like sequences accumulated in a 176-base pair small intron, including a direct repeat of the AGGTCA sequence with one base pair spacing (DR1) and one consensus NBRE sequence (17). The sequences of both DR1 and NBRE response elements are conserved among many species (9). When CNTFR-I5 was present in a reporter gene construct, it could enhance the transcriptional activity in the presence of TR4, suggesting that TR4 may be involved in the regulation of CNTFRalpha gene expression (9). We further hypothesized that TR2 and/or TR4 may be regulated by CNTF. Thus, a two-way interaction could result with CNTF to regulating TR2/TR4 expression and also TR2/TR4 to regulating CNTFRalpha expression.

CNTF is a neurocytokine that promotes the survival and differentiation of a variety of neuron cell types, including motor, sensory, sympathetic, parasympathetic, cerebellar, and hippocampal neurons (18); it also inhibits apoptotic cell death of cultured oligodendrocytes (19). Exogenous CNTF effectively blunts the progression of motoneuropathy (20, 21). Clinical trials of the CNTF application have been launched to treat patients with amyotrophic lateral sclerosis (ALS), a degenerative human motoneuropathy (22). Whereas CNTF may have important clinical significance, the mechanism of CNTF in neuron protection is not fully understood.

In the present study, we used P19 cells as a model system because these cells can be induced into the neuronal differentiation pathway in the presence of inducers, such as CNTF and RA (23, 24), and at a high cell density. Interestingly, the pattern of responsiveness to inducers appeared to be specifically influenced by cell-cell interactions: astrocytes showed greatly enhanced differentiation in three-dimensional aggregating cell cultures, whereas in monolayer cell cultures a predominantly mitogenic response has been observed (24). As our preliminary data indicated, P19 cells endogenously express TR2, TR4, and CNTFRalpha (23). Therefore, we can test the effect of CNTF on the expression of TR2 and TR4 during neuronal differentiation. Here, our results show that CNTF treatment increased the population of TR2 and TR4 in P19 cells, and the DNA-binding ability of TR2/TR4 was enhanced. Such an increase may result in the induction of the enhancer activity of CNTFR-I5 and contribute to the expression of the CNTFRalpha gene. In addition, the distribution pattern of TR2 in the developing neural tissues correlated well with the pattern of CNTFRalpha reported by Ip et al. (13), supporting the physiological significance of our finding.

    MATERIALS AND METHODS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Cell Culture Procedures-- Differentiation of P19 cells was carried out as described previously (24) with minor modification. Briefly, cells in exponential growth were treated with trypsin-EDTA to remove them from the surface of Petri dishes and then plated at a density of 105 cells/ml into bacteria grade Petri dishes where they aggregated spontaneously and suspended. Cell aggregates were grown in alpha -MEM medium (Life Technologies, Inc.) supplemented with 10% charcoal-treated fetal calf serum and were allowed to sit for 3 days before treatment. The medium was replaced every 3 days. To induce neuron differentiation, rat CNTF (Boehringer Mannheim or American Research Products) at 20 ng/ml was added to the medium for 4 days. The aggregates were then plated into tissue culture dishes and examined morphologically 3 days later.

Immunofluorescence Assays-- Aggregates were plated directly onto coverslips for staining in situ. After fixation in acetone for 5 min at -20 °C, the cells were incubated with the primary monoclonal antibodies at a dilution of 1:80 for anti-neurofilament 200 (Sigma) or at a concentration of 10 µg/ml for glial fibrillar protein (GFAP) (PharMingen). This was followed by treatment with biotinylated secondary antibodies at 10 µg/ml (Vectastain Elite ABC universal kit; Vector Laboratories, Inc.) and then with fluorescein avidin (Vector Laboratories, Inc.). Cells were examined with an Olympic Photomicroscope equipped with epifluorescence optics. Photographs were taken by Kodak DCS System (Eastman Kodak Co.).

Cloning of the Mouse TR2 cDNAs-- A positive mouse clone, named mTR2-1, which covers the nucleotide positions 832-1557, was isolated from an adult mouse testis lambda gt 11 cDNA library using the 1.7-kb EcoRI DNA fragment of hTR2-11 as a probe (7). The N and C termini were cloned by using RT-PCR (Perkin-Elmer) and 3'-RACE kits (CLONTECH), respectively. Reaction conditions followed the manufacturer protocols, and the total RNA purified from the adult mouse testis was used as a template. Oligonucleotides TR2-3 and TR2-8 were used to amplify the N terminus of the mTR2 cDNA. For 3'-RACE, the first strand of cDNA was synthesized from the testis RNA template with the C1(dt) primer in a reverse transcription reaction. A PCR reaction was then performed to amplify the C terminus of mTR2 cDNA using primers C1 (part of C1(dt) primer) and C2. The PCR products were cloned into pT7 Blue vector (Novagen) and sequenced using a Sequenase kit (U. S. Biochemical). The primers used are shown as followings: C1(dt), 5'-AAGGATCCGTCGACATCGATTTTTTTTTTTTTTTTT-3'; C1, 5'-AAGGATCCGTCGACATCGAT-3'; C2, 5'-TCCAGACTGCTGTTCTTATC-3'; TR2-3, 5'-TTTTGCAAGAGTGTCAAAT-3'; TR2-8, 5'-ATGGCAACCATAGAA-3'.

RNase Protection Assay-- Total RNAs of P19 cells were purified by a standard CsCl centrifugation method, followed by extraction with phenol and chloroform. Riboprobes were labeled with [32P]UTP and in vitro transcribed (Ambion, Austin, TX) from plasmids containing a partial N-terminal fragment of mTR2 (nucleotides 154-234) or of mTR4 (nucleotides 1-250) (9). In each reaction, total RNAs (30 µg) were simultaneously hybridized with the antisense mTR2, mTR4, and beta -actin riboprobes, using the HybSpeed RNase protection kit (Ambion). Procedures followed the protocols suggested by the manufacturer (Ambion). The protected bands were visualized and the intensity of each band was quantified by using PhosphorImager (Molecular Dynamics) with ImageQuant program.

Nuclear Extract Preparation-- Nuclear extracts were prepared following the mini-extract procedures as described previously (25). Briefly, cells were collected and lyzed by pushing through a 25-gauge needle 10 times. The nuclear pellet was collected by centrifugation and homogenized using a glass homogenizer. The supernatant containing the nuclear proteins was then dialyzed for 2 h against buffer D (20 mM HEPES-KOH, 100 mM KCl, 0.2 mM EDTA, 20% glycerol, pH 7.9). Protein concentration was determined by the Bradford method with a Protein Assay kit (Bio-Rad). A precise amount of extract to be used in the gel shift assay was further normalized to the protein amount binding to the Oct-1 probe (5'-CTAGACCCCCTCATTATCATATTAACCA-3'), assuming the formation of the Oct-1-specific complex remains constant during differentiation (25).

Coupled in Vitro Transcription and Translation-- Plasmids pSPU-TK-TR2 (5) and pCMX-TR4 (9) containing the full length of human TR2 cDNA and of TR4 cDNA, respectively, were in vitro transcribed and translated using the TNT system (Promega).

Electrophoretic Mobility Shift Assay-- EMSA was performed as described previously (25) with minor modification. Briefly, the reaction was performed by incubating the gamma -32P-end-labeled human CNTFR-DR1 probe (5'-GCCCTGACCTCTGACCTCTC-3') (2 × 105 cpm/0.2 ng) with the Oct-1 normalized P19 cell nuclear extracts or 2 µl of in vitro translated protein. For antibody supershift assay, 1 µl of the monoclonal antibodies specific for TR2 or TR4 (9) were incubated with the reactions for 15 min at 25 °C prior to loading on a 5% native gel. After electrophoresis, the gel was dried and exposed overnight to a Kodak X-AR film.

Scatchard Analysis-- The protein-DNA binding assay was performed as described previously (4). Briefly, 2 µl of in vitro translated TR2 protein was incubated with various concentrations of the gamma -32P-end-labeled CNTFR-DR1 probe. Protein-DNA complexes were resolved on a 5% nondenaturing polyacrylamide gel at 4 °C. After exposing to an x-ray film, the respective bands of the free probe and the protein-DNA complex were excised and counted directly in a scintillation counter (Beckman). The radioactivity ratio between the specific protein-DNA complex and the free DNA probe (bound/free) with respect to the radioactivity of specific DNA-protein complex (bound, nM) was plotted. The dissociation constant (Kd) and Bmax values were generated from the Ebda program (Biosoft).

Transfection and CAT Assays-- Reporter plasmids, containing the CNTFR-I5 inserted into the pCAT-promoter vector (Promega), were as described previously (9). Chinese hamster ovary cells (CHO) were cultured and transfected by the calcium phosphate co-precipitation procedure as described previously (4). To normalize the transfection efficiency, the beta -galactosidase plasmid, pCMVbeta (CLONTECH), was co-transfected. Results were plotted as mean ± S.D. of at least three independent experiments of CAT expression normalized to the beta -galactosidase activity.

Northern Blot Hybridization-- RNA samples (30 µg) were electrophoresed and transferred onto a nylon membrane (Amersham Pharmacia Biotech). The probe was labeled with [alpha -32P]dCTP using a random hexamer labeling kit (Amersham Pharmacia Biotech). The blot was hybridized with the mTR2N (nucleotide 1-282) probe. After stringent washing in 0.1× SSC solution at 55 °C for 15 min, the blot was exposed to an x-ray film (Kodak).

In Situ Hybridization-- Embryos from C57BL/J (Harlan Sprague-Dawley) were collected from E/9 to E/16. Section preparation and in situ hybridization were performed as described previously (4). The riboprobe transcribed from mTR2N was [35S]UTP-radiolabeled using an in vitro transcription kit with T7 or T3 RNA polymerase (Ambion). The specific activity of riboprobes must be no lower than 1-2 × 109 cpm/µg. Both the sense and antisense riboprobes were included in each batch of experiments. After stringent washes, slides were dipped into Kodak NTB2 emulsion, exposed for 6 weeks, and photographed under the light field microscope.

    RESULTS
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

CNTF Stimulates Differentiation of P19 Cells-- To study the potential role of TR2 and TR4 in cells that follow a neuronal differentiation pathway, we first confirmed that P19 cells grown in a high cell density of an aggregation culture could be induced into differentiation following CNTF treatment. Differentiation of P19 cells into the glia cells and neuron cells were indicated by the presence of the GFAP and neurofilament (NF-L), respectively. As shown in Fig. 1, P19 cell aggregates without treatment contained undifferentiated embryonal carcinoma cells that resembled extraembryonic endoderm, and neither GFAP- nor NF-L- containing filaments were observed (Fig. 1A and B). In contrast, approximately 10-15% of the CNTF-treated P19 cell aggregates developed processes and appeared to establish contacts with other cells. In addition to this morphological change, GFAP, the biochemical indicators for the glia cells, appeared in many CNTF-treated cells, and a minor population showed NF-L immunoreactivity (Fig. 1C and D).


View larger version (115K):
[in this window]
[in a new window]
 
Fig. 1.   Immunofluorescence staining for GFAP and NF-L. P19 cells were aggregated for 4 days and then plated onto tissue culture dishes for 3 more days with the medium only (A and B) or the medium containing rCNTF at 20 ng/ml (C and D). P19 cell aggregates were stained with anti-GFAP monoclonal antibody mixture (A and C) or anti-NF-L monoclonal antibody (B and D). The cells expressing GFAP and NF-L are indicated by an arrow and arrowhead, respectively.

Increased TR2 and TR4 Expression Correlates with Early Neuronal Differentiation of P19 Cells as Induced by CNTF-- The expression of TR2 and TR4 in P19 cell aggregates was examined during the course of CNTF treatment. As shown in Fig. 2, both TR2 and TR4 mRNA levels were increased 10-fold in P19 cell aggregates after 2 days of CNTF incubation but then declined as differentiation progressed. The basal expression level of TR2 mRNA is low such that multiple exposures are required for visualization of the TR2 band in the P19 RNA sample without the CNTF treatment (t = 0).


View larger version (35K):
[in this window]
[in a new window]
 
Fig. 2.   Induction of the TR2 and TR4 transcripts during CNTF-induced neuron differentiation. A, P19 cell aggregates were treated with CNTF (20 ng/ml) from 0 h to 3 days as indicated. Total RNA samples (30 µg/reaction) were simultaneously hybridized with various 32P-radiolabeled riboprobes. Following hybridization, samples were digested with RNase H/T1 and loaded onto a urea-denaturing polyacrylamide gel. The expected sizes of protected bands for mTR2, mTR4, and beta -actin are 81-, 250-, and 125-base pairs, respectively. The resulting autoradiograms were visualized by a PhosphorImager. Positions of each band are indicated at right. The sizes of RNA marker in nucleotides (lane M) are indicated at left. B, quantitative analysis of mRNA levels of mTR2 and mTR4 in response to CNTF treatment. All these data were quantified by the ImageQuant program (Molecular Dynamic). The individual level in the untreated control is counted as 1. The results from three independent experiments are expressed as mean ± S.D.

CNTF Enhances TR4 Protein Binding to CNTFR-DR1-- As DNA-binding is essential for TR2 and TR4 to carry out their transcriptional activity, we developed an EMSA to examine the DNA-binding activity of TR4, using the CNTFR-DR1 as a probe. Crude nuclear extracts were isolated from the CNTF-treated P19 cell aggregates, and the endogenous TR4 protein was separated from other DR1-binding proteins by the TR4-specific monoclonal antibody, which supershifts the TR4 protein-DNA complex (Fig. 3). RA-treated aggregated P19 cells served as a positive control. As shown in Fig. 3A, the amount of TR4-CNTFR-DR1 complex (solid arrow) was low in undifferentiated P19 cells (lane 5) and was increased 80-fold upon CNTF treatment (lane 6). Interestingly, CNTF treatment resulted in TR4 being the predominate DR1-binding factor (>50%) in P19 cells (Fig. 3C). However, when the TR4 protein levels were examined by a Western blotting analysis (Fig. 3B), only a 6-fold increase was observed in the CNTF-treated nuclear extract. The discrepancy between the TR4 DNA-binding capacity and the immunoreactivity implies that posttranslational modification may be involved in activating TR4 for DNA-binding. Another possibility could be the suppression of other DR1-binding proteins by CNTF treatment, or the discrepancy observed is just a coupling efficiency difference. Consistent with the idea that RA has a broad effect on protein expression, we showed that the TR4 protein level was dramatically increased by the RA treatment (Fig. 3B); however, the expression of other DR1 binding proteins were proportionally increased by RA as well (Fig. 3A). Thus, TR4 represents 25% of all populations binding to CNTFR-DR1 (Fig. 3C). These data suggest that the activity of TR4 may dominate over other DR1-binding proteins in response to CNTF and could potentially play a major role in mediating the CNTF action.


View larger version (19K):
[in this window]
[in a new window]
 
Fig. 3.   Enhanced binding capacity of TR4 toward the CNTFR-DR1 by CNTF or RA treatment. A, autoradiogram showing TR4 and other DR1-binding protein populations in aggregated P19 cells. EMSA was performed using the radiolabeled CNTFR-DR1 oligonucleotides with nuclear extracts (3 µg) isolated from the P19 cell aggregates treated with medium only (lanes 1 and 5) or with rCNTF at 10 ng/ml (lanes 2 and 6) or with RA at 5 × 10-7 M (lanes 3, 4, 7, and 8) for the indicated time. Addition of the TR4-15 monoclonal antibody (Ab) produced a TR4-DNA supershift band (solid arrow) in lanes 5-8 and 10, and separated TR4 from the rest of the DR1-binding proteins (open arrow). The in vitro translated human TR4 protein (TNT-hTR4) served as a position control (lanes 9 and 10). B, Western blot showing the effects of CNTF or RA on the TR4 protein expression. The origin of protein samples in lanes 1-6 is the same as those used in lanes 5-10 of Fig. 3A. Positive control used was the in vitro expressed TNT-hTR4 (67 kDa in size); 1 µl (lane 5) and 10 µl (lane 6). The TR4 size in P19 cells is 65 kDa. C, comparison of the relative level of TR4 among all the DR1-binding proteins in CNTF-treated or RA-treated P19 cell aggregates. The radioactivity of TR4 supershift band is expressed as a percentage relative to the total radioactivity bound by DR1-binding proteins in the individual lane. The results from three independent EMSA experiments are expressed as mean ± S.D.

TR2 Binds to CNTFR-DR1 with High Affinity-- EMSA was performed with in vitro translated TR2 using the 32P-labeled CNTFR-DR1 oligonucleotide as a probe. As shown in Fig. 4A, a specific DNA-protein complex was formed in the presence of both probe and TR2 (lane 3, solid arrow) but was absent in the reaction containing the probe only and in the mock-translated control (lane 2). This TR2-CNTFR-DR1 complex could be abolished by a 10- or 100-fold molar excess of unlabeled CNTFR-DR1 oligonucleotide (lanes 4 and 5), but remained intact in the presence of a 100-fold molar excess of mutant CNTFR-DR1 oligonucleotide (lane 6). Moreover, this retarded complex could be fully supershifted in the presence of the anti-TR2 monoclonal antibody (lane 8, open arrow). As a negative control, an unrelated monoclonal antibody with the same subtype (IgM) showed no effect on the retarded complex (lane 7). Together, these data indicate that CNTFR-DR1 is a specific binding site for TR2.


View larger version (17K):
[in this window]
[in a new window]
 
Fig. 4.   Binding of the in vitro expressed TR2 to the CNTFR-DR1 with high affinity. A, analysis of the DNA binding and antigenic properties of in vitro expressed TR2 protein by EMSA. TR2 protein was synthesized in a reticulocyte lysate. The CNTFR-DR1 oligonucleotides were 32P-end-labeled and used as a probe. As negative controls, the binding reaction contained either no lysate (lane 1) or lysate without TR2 (lane 2). Binding reaction mixtures incubated with the probe and the in vitro expressed TR2 (lanes 3-8) in the presence of a 10-fold (lane 4) or 100-fold (lane 5) molar excess of unlabeled CNTFR-DR1, or a 100-fold molar excess of mutated CNTFR-DR1 (lane 6). Supershift of the TR2 protein-DNA complex was induced in the presence of the TR2 monoclonal antibody G204.218 (lane 8) but was not induced by unrelated monoclonal antibody (lane 7). The positions of the TR2 proteinDNA complex and the supershift band are indicated by the solid and hollow arrows, respectively. B, the binding profile of in vitro expressed TR2 to CNTFR-DR1 was resolved by EMSA. In binding reactions, a constant amount of TR2 was incubated with varying concentrations of the labeled CNTFR-DR1 probe, as indicated. When the probe amount was limited, only the TR2 protein-DNA complex was seen (lanes 2, 3, and 4), indicating strong affinity of TR2 over the CNTFR-DR1 probe.

To determine the binding affinity of TR2 and CNTFR-DR1, we performed the Scatchard analysis by EMSA. The typical EMSA pattern of protein-DNA complex formed between increasing amounts of the CNTFR-DR1 probe (0.0039-1 ng) and fixed amounts of TR2 was shown in Fig. 4B. The radioactivity of the specific complex (bound) and unbound (free) probe was quantified for the subsequent Scatchard plot analysis. The results are consistent with a single binding population for the specific DNA-protein complex with a dissociation constant (Kd) of 0.039 nM and a Bmax of 0.3 nM. This binding affinity is about 2-fold higher than that of TR4 (9) and about 30-90-fold higher than the Kd range for other steroid receptors and their response elements (26). At very low probe concentrations, the specific protein-DNA complex was still visible but not the free probe (Fig. 4B, lanes 2-4). This is consistent with the calculated dissociation constant.

The Enhancer Activity of CNTFR-I5 Was Induced by TR2 in a Dosage-responsive Manner-- We examined whether TR2, like TR4, could activate transcriptional activity through CNTFR-I5. Various CAT reporter plasmids, containing CNTFR-I5 in different orientations and positions relative to the CAT gene (Fig. 5B), were co-transfected with TR2 expression plasmids into CHO cells. It showed that TR2 could induce CAT activity from 8-30-fold (Fig. 5C). In contrast, induction did not occur when either the antisense TR2 or backbone plasmids were transfected. Different orientations or positions of CNTFR-I5 did not appear to significantly affect TR2-mediated transcriptional activity. These results suggest that TR2 may contribute to the CNTFRalpha gene expression through the CNTFR-I5 enhancer.


View larger version (34K):
[in this window]
[in a new window]
 
Fig. 5.   Induction of an intronic enhancer activity from human CNTFR-I5 by TR2. A, the genomic position of the 5th intron of the CNTFRalpha gene is located in the region encoding a fibronectin-like domain (16). A DR1 (solid box) and four copies of AGGTCA-like sequence (hollow box) were found within the CNTFR-I5 as indicated. B, construction of three CNTFR-I5-containing enhancer reporter plasmids. Names assigned to each construct are as indicated. Vector pCAT-promoter, containing the Simian virus 40 promoter linked to the CAT gene is as shown. Arrows indicate the orientation of the CNTFR-I5 fragments and the sites at which they were inserted into the pCAT-promoter vector. C, the dosage effect of TR2 on the CNTFR-I5 enhancer activity using a CAT reporter assay. Various reporter constructs with or without expression vector were transfected into CHO cells. The reporter constructs for transfection were either pCATp (lanes 1 and 2), CNTFR-I5-CATe5+ (lanes 3-7), CNTFR-I5-CATe5- (lanes 8-12), CNTFR-I5-CATe3+ (lanes 13-17). Expression plasmids co-transfected include: sense TR2 expression plasmid, 0.5 µg (lanes 4, 9, and 14), or 3 µg (lanes 5, 10, and 15); and antisense TR2 expression plasmid, 0.5 µg (lanes 6, 11, and 16), or 3 µg (lanes 7, 12, and 17). Chloramphenicol conversion rates were calculated from PhosphorImager quantifiable intensities. Fold induction was normalized relative to the CAT activity produced by the control plasmid pCATp without co-transfection with TR2 expression plasmid. The results from at least three independent experiments are expressed as mean ± S.D.

Cloning the mTR2 cDNAs-- The full-length and partial mTR2 cDNA fragments were cloned for studying the distribution of TR2 mRNA. DNA sequence analysis revealed that the full-length mTR2 consists of an open reading frame (590 amino acids) which is highly homologous to human TR2-11 (1). Sequence comparison between mTR2 and mTR4 (Fig. 6A) showed that the N terminus is the most divergent (30% homology), whereas the DNA-binding domain remains conserved (75% homology). Thus, we chose the N-terminal domain of mTR2 as a probe and tested its specificity by Northern blot hybridization. As shown in Fig. 6B, the mTR2N probe hybridized two bands in adult mouse testis with the sizes of 2.4 and 2.9-kb (lane 1, Fig. 6B). These transcripts were clearly distinct from those encoding mTR4, which are 7.8-kb (major band) and 2.8 kb (minor band) (9). No TR2 signal was detected in kidney (Fig. 6, lane 2). These data suggest that the mTR2N probe is specific for TR2.


View larger version (81K):
[in this window]
[in a new window]
 


View larger version (45K):
[in this window]
[in a new window]
 
Fig. 6.   Sequencing and specificity analyses of the mTR2 cDNA fragments. A, alignment of the nucleotide and the deduced amino acid sequences of mTR2 and mTR4. These sequences are numbered on the left. The mTR4 residues that are identical to the mTR2s are shown by hyphens (-). Gaps were introduced to obtain an optimal match. The missing residues are shown by asterisks (*). The putative DNA-binding domain is boxed, the stop codon is indicated as stop, and the polyadenylation signal is underlined. The region covered by the mTR2-1 clone is bracketed. The position and orientation of oligonucleotides used in the present study are as indicated (for details, see "Materials and Methods"). The nucleotide sequences of mTR2 and mTR4 have been deposited into GenBankTM as accession numbers U30482 and U32939, respectively. B, total RNAs (30 µg) isolated from adult mouse testis (lane 1) and kidney (lane 2) were hybridized with the 32P-labeled mTR2N probe. After washing, x-ray film was exposed in the presence of the blot for 2 days. The positions of 28 S and 18 S are marked on the left, and the sizes of two hybridized bands are indicated on the right of the autoradiogram.

Expression of TR2 in the Developing Central and Peripheral Nervous System-- To determine the tissue distribution of TR2 mRNA in mouse embryos, we performed in situ hybridization. Our results showed that TR2 transcripts were most prominent in developing neural structures (Fig. 7). During E/11-E/16, the TR2 signals were progressively restricted to the periventricular zones of developing brain vesicles, where many cells are in the mitotic cycle (Fig. 7, A and B) (27). Strong TR2 signals were found within the developing spinal motor neurons (Fig. 7A) and within the brain areas, such as cerebella (Fig. 7B), neocortex, striatum, and olfactory bulb (Fig. 7E). No signal was ever detected with the sense riboprobe (data not shown). Prominent TR2 expression was also detected in the peripheral neural tissues; ganglia with strong TR2 signal include the sympathetic (Fig. 7C, s), parasympathetic (Fig. 7D, X), and sensory ganglia, e.g. the dorsal root (Fig. 7, B and C, drg) and trigeminal ganglia (Fig. 7D, V). In addition, TR2 transcripts were abundant in targets of sensory innervation, such as the developing neural epithelia of the inner ear, nasal cavity, tongue, and retina (Fig. 7, A, D, and F). TR2's localized expression is consistent with its potential participation in neurogenesis, especially during the events of early neuron proliferation or differentiation.


View larger version (105K):
[in this window]
[in a new window]
 
Fig. 7.   Analysis of the TR2 expression during mouse embryogenesis by in situ hybridization. Sagittal sections of embryos (E/11-E/16) were hybridized with the [35S]UTP-radiolabeled antisense mTR2N riboprobe and were photographed under a light-field illuminated microscope. Tissues and organs with strong hybridization signals (dark areas) were labeled. A-B, low magnification of autoradiographs show the expression patterns of TR2. C-F, high magnification shows the neural structures with strong TR2 hybridization signals. The embryonic stages and the regions noted are indicated at the top of each photograph. Abbreviations used are: cb, cerebellar primordium; di, diencephalon; drg, dorsal root ganglia; e, otic epithelium; ht, hypothalamus; hv, otic vesicle; l, lens; m, motor neuron; mo, dorsal part of medulla oblongata; nc, neocortex; ob, olfactory bulb; oe, olfactory epithelium; r, retina; rm, rhombomeres; s, sympathetic ganglia; sr, striatum; t, gustatory epithelium; tel, telencephalon; V, trigeminal ganglion; and X, vagal ganglion. The size bars represent 1 mm for panel B and represent 200 nm for panels A and C-F.

    DISCUSSION
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

The Effects of CNTF on P19 Cell Differentiation and on the Expression of TR2 and TR4-- Previous studies have shown that CNTF has a potent effect on the survival and differentiation of P19 cells (23). According to Gupta et al. (23), around 10-15% of P19 cells with CNTF treatment developed neurites. These process-bearing cells expressed the neuronal markers HNK-1 and neurofilament as well as the carbohydrate marker of neuronal differentiation. In addition, we observed CNTF-treated P19 cells developed into glia cells that grew neurites and expressed the GFAP marker. However, the neuronal marker NF-L appeared in a population that is morphologically different from the cells expressing GFAP. Recently, Bonni et al. (27) reported that CNTF triggers the differentiation of the cortical precursors into astrocytes, indicating the gliogenetic effect of CNTF on P19 cells is similar to that on the cerebral cortical precursors in certain ways. Thus, P19 cells could be a suitable model for our study.

The mechanism by which CNTF induces gene transcription has been well studied (27, 28). Activation of the CNTF receptors stimulates JAK-kinases to phosphorylate STAT1 and STAT3, which belong to the family of signal transducers and activators of transcription (STAT). Phosphorylated STAT proteins then translocate to the nucleus and bind to the CNTF-response element (TTCCNNNAA or TTCCNNNNAA), leading to the activation of genes containing this DNA-element within their promoter, for example the tis11 and SOD1 (29, 30). In reporter gene assays, two copies of the CNTF response element are sufficient to confer rapid CNTF responsiveness and result in an 8.5-fold induction of transcription (28). Interestingly, we found four putative CNTF response elements in the human TR2 promoter (2.7 kb in size) (31). The study of the human TR2 promoter in relation to CNTF treatment with STAT1 cotransfection is under way. These findings reasonably explain the inducibility of TR2 upon CNTF treatment. Although the TR4 promoter has not been characterized completely, we predict it may contain a similar response element given the rapid mRNA and protein induction of TR4 following CNTF exposure (Figs. 2 and 3).

To the authors' knowledge, steroid receptors induced by CNTF treatment have not been previously reported. Our finding that induction of TR2 and TR4 by CNTF treatment establishes the first evidence for steroid receptors cross-talk to the CNTF signaling pathway.

CNTF Promotes the DNA-binding Capacity of TR4-- Our data show that the amount of TR4 protein binding to the CNTFR-DR1 increases dramatically after CNTF treatment (Fig. 3). Possible explanations are that the TR4 expression level was increased, or the DNA-binding affinity of TR4 toward CNTFR-DR1 was increased, or both. Our data showed discrepancy between the TR4 DNA binding capacity and TR4 immunoreactivity, suggesting that protein modification such as phosphorylation, may be involved in the activation of TR4. An alternative explanation is that such a discrepancy could be because of a coupling efficiency difference. Correspondingly, TR2 has been shown to be activated via the cAMP-mediated phosphorylation induced by the neurotransmitter dopamine (32). The effects of CNTF upon TR2/TR4 signaling may provide clues to the mechanism of CNTF actions in neuron protection. Whether the CNTF pathway could cross-talk to the dopamine pathway mediated by TR2/TR4 is an intriguing question to ask.

Comparison of the Expression Patterns for TR2, TR4, and CNTFRalpha during Embryogenesis-- Whereas the overall expression patterns of TR2 and TR4 are very similar during development, the specificity of each probe has been confirmed by Northern blot analysis. Both TR2 and TR4 were strongly expressed in the actively proliferating cell populations of brain and of many peripheral organs. Such a wide but cell type-specific expression pattern leads to the hypothesis that both TR2 and TR4 may be involved in a stage-specific instead of a tissue-specific process. As the TR2 probe was derived from the N terminus, which is conserved in all the TR2 isoforms identified (7), this expression pattern may be caused by more than one TR2 isoform.

Certain developing tissues express only TR2 and not TR4, such as the developing rhombomeres, retina, lens, and branchial arches at E/11 (Fig. 7A) as well as the vagal ganglia at E/15 (Fig. 7D). Interestingly, strong TR2 signals were found in the junction of each rhombomere and branchial arch, suggesting a contribution to boundary segmentation or reinforcement of these repeating units. Reciprocal expression kinetics were observed between TR2 and TR4, implying TR2 is more important in the early developmental stage, whereas TR4 works during the late development and the maintenance of the nervous system.

Recently, different chromosomal locations have been mapped for human TR2 and TR4 to 12q22 and 3p24.3 (31), respectively. This rules out the possibility that TR2 and TR4 are isoforms transcribed from the same gene. Instead, their overlapping distribution patterns reflect functional conservation through evolution.

The TR2 expression overlaps profoundly with the expression of the CNTFRalpha gene (13) within the developing nervous system and many nonneural tissues. These three gene transcripts are co-expressed in large amounts within 1) the periventricular brain regions; 2) the motor neuron-containing tissues such as the striatum, ventral spinal cord, and muscle; and 3) the ganglia of sensory, sympathetic, and parasympathetic origins. The co-localization of these transcripts suggests that interaction between TR2 and CNTFRalpha could be physiologically relevant.

TR2 Induces the Intronic Enhancer Activity of CNTFR-I5-- Although the contribution of CNTFR-I5 to the CNTFRalpha gene expression remains unknown, we demonstrated that CNTFR-I5 could function as an enhancer in the presence of TR2/TR4 in a reporter gene assay. In fact, other DR1 binding proteins, such as RAR and RXR, and the AGGTCA half-site binder, such as TR3, could also induce the CNTFR-I5 enhancer activity in the same reporter assay.4 The possibility for these steroid receptors to regulate CNTFRalpha gene expression therefore may depend on the availability of these factors.

Upon binding to a DR1 sequence, TR2 could either induce gene transcription through CNTFR-I5 or repress the RA-induced transcriptional activation through a similar DR1 response element present in the CRBPII promoter (4). The mechanism for such a discrepancy is still unclear, but evidence suggests the gene context could be critical in determining the consequence of protein binding (33). Thus, CNTFR-I5 could be a natural target for TR2 and TR4. The ligand searches for TR2 and TR4 based on the CNTFR-I5-containing reporters are now under way.

In summary, our data suggest that a two-way interaction of TR2/TR4 and the CNTF signaling pathways may occur, which supports the hypothesis that TR2/TR4 may have important roles in neurogenesis.

    ACKNOWLEDGEMENTS

We thank Dr. Ritsuro Ideta for helping to clone and sequence the mTR2 cDNAs. We also thank Dr. Jay E. Reeder for excellent professional instruction in fluorescence microscopic photography and image printing.

    FOOTNOTES

* This work was supported in part by Grants CA71570 and DK47258 from the National Institutes of Health.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.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U30482 (mTR2) and U32939 (mTR4).

Dagger These authors contributed equally to this paper.

Supported by Grant T32 CA09363D from the NCI, National Institutes of Health.

** To whom correspondence should be addressed: University of Rochester Medical Center, 601 Elmwood Ave., Box 626, Rochester, NY 14642. Tel.: 716-273-4500; Fax: 716-756-4133; E-mail: chang{at}pathology.rochester.edu.

The abbreviations used are: TR2, TR2 orphan receptor; mTR2, mouse TR2; TR4, TR4 orphan receptor; mTR4, mouse TR4; CNTF, ciliary neurotrophic factor; CNTFR-I5, 5th intron of the CNTF alpha receptor gene; DR1, direct repeat with one base pair spacing; E/9, embryonic day 9; RT-PCR, reverse transcription-polymerase chain reaction; EMSA, electrophoretic mobility shift assay; CAT, chloramphenicol acetyltransferase; RA, retinoic acid; NBRE, TR3/NGFI-B/nur77 response element; LIFRbeta , leukemia inhibitory factor receptor beta ; kb, kilobase(s); RACE, rapid amplification of cDNA ends; GFAP, glial fibrillar protein.

2 Lee, Y.-F., Young, W.-J., Burbach, J. P., and Chang, C. (1998) J. Biol. Chem. 273, in press.

3 W.-J. Young, and C. Chang, manuscript in preparation.

4 Mu, X.-M., Young, W.-J., Liu, Y.-X., Uemura, H., and Chang, C. (1998) Endocrine, in press.

    REFERENCES
Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

  1. Chang, C., and Kokontis, J. (1988) Biochem. Biophys. Res. Commun. 155, 971-977[Medline] [Order article via Infotrieve]
  2. Chang, C., Da Silva, S. L., Ideta, R., Lee, Y., Yeh, S., and Burbach, J. P. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 6040-6044[Abstract]
  3. Beato, M. (1989) Cell 56, 335-344[Medline] [Order article via Infotrieve]
  4. Lin, T.-M., Young, W.-J., and Chang, C. (1995) J. Biol. Chem. 270, 30121-30128[Abstract/Free Full Text]
  5. Lee, H.-J., and Chang, C. (1995) J. Biol. Chem. 270, 5434-5440[Abstract/Free Full Text]
  6. Lee, H.-J., Lee, Y., Burbach, J. P., and Chang, C. (1995) J. Biol. Chem. 270, 30129-30133[Abstract/Free Full Text]
  7. Chang, C., Kokontis, J., Acakpo-Satchivi, L., Liao, S., Takeda, H., and Chang, Y. (1989) Biochem. Biophys. Res. Commun. 165, 735-741[Medline] [Order article via Infotrieve]
  8. Lee, C., Copeland, N. G., Gilbert, D. J., Jenkins, N. A., and Wei, L. N. (1995) Genomics 30, 46-52[CrossRef][Medline] [Order article via Infotrieve]
  9. Young, W.-J., Smith, S. M., and Chang, C. (1997) J. Biol. Chem. 272, 3109-3116[Abstract/Free Full Text]
  10. Davis, S., Aldrich, T. H., Valenzuela, D. M., Wong, V., Furth, M. E., Squinto, S. P., and Yancopoulos, G. D. (1991) Science 253, 59-63[Medline] [Order article via Infotrieve]
  11. Davis, S., Aldrich, T. H., Stahl, N., Pan, L., Taga, T., Kishimoto, T., Ip, N. Y., and Yancopoulos, G. D. (1993) Science 260, 1805-1808[Medline] [Order article via Infotrieve]
  12. Ip, N. Y., Nye, S. H., Boulton, T. G., Davis, S., Taga, T., Li, Y., Birren, S. J., Yasukawa, K., Kishimoto, T., Anderson, D. J., Stahl, N., and Yancopoulos, G. D. (1992) Cell 69, 1121-1132[Medline] [Order article via Infotrieve]
  13. Ip, N. Y., McClain, J., Barrezueta, N. X., Aldrich, T. H., Pan, L., Li, Y., Wiegand, S. J., Friedman, B., Davis, S., and Yancopoulos, G. D. (1993) Neuron 10, 89-102[Medline] [Order article via Infotrieve]
  14. Davis, S., Aldrich, T. H., Ip, N. Y., Stahl, N., Scherer, S., Farruggella, T., DiStefano, P. S., Curtis, R., Panayotatos, N., Gascan, H., Chevalier, S. N., and Yancopoulos, G. D. (1993) Science 259, 1736-1739[Medline] [Order article via Infotrieve]
  15. DeChiara, T. M., Vejsada, R., Poueymirou, W. T., Acheson, A., Suri, C., Conover, J. C., Friedman, B., McClain, J., Pan, L., Stahl, N., Ip, N., Kato, A., and Yancopoulos, G. D. (1995) Cell 83, 313-322[Medline] [Order article via Infotrieve]
  16. Valenzuela, D. M., Rojas, E., Le Beau, M. M., Espinosa, R., Brannan, C. I., McClain, J., Masiakowski, P., Ip, N. Y., Copeland, N. G., Jenkins, N. A., and Yancopoulos, G. D. (1995) Genomics 25, 157-163[CrossRef][Medline] [Order article via Infotrieve]
  17. Wilson, T. E., Fahrner, T. J., Johnston, M., and Milbrant, J. (1991) Science 252, 1296-1300[Medline] [Order article via Infotrieve]
  18. Sendtner, M., Carroll, P., Holtmann, B., Hughes, R. A., and Thoenen, H. (1994) J. Neurobiol. 25, 1437-1453
  19. Louis, J.-C., Magal, E., Takayama, S., and Varon, S. (1993) Science 259, 689-692[Medline] [Order article via Infotrieve]
  20. Forger, N. G., Wong, V., and Breedlove, S. M. (1995) J. Neurobiol. 28, 354-362[Medline] [Order article via Infotrieve]
  21. Sendtner, M., Schmalbruch, H., Stockli, K. A., Carroll, P., Kreutzberg, G. W., and Thoenen, H. (1992) Nature 358, 502-504[CrossRef][Medline] [Order article via Infotrieve]
  22. ALS CNTF Treatment Study (ACTS) Phase I-II Study Group. (1995) Clin. Neuropharmacol. 18, 515-532[Medline] [Order article via Infotrieve]
  23. Gupta, S. K., Haggarty, A. J., Carbonetto, S., Riopelle, R. J., Richardson, P. M., and Dunn, R. J. (1993) Eur. J. Neurosci. 5, 977-985[Medline] [Order article via Infotrieve]
  24. Jones-Villeneuve, E. M. V., McBurney, M. W., Rogers, K. A., and Kalnins, V. I. (1982) J. Cell Biol. 94, 253-262[Abstract]
  25. Jonk, L. J., de Jonge, M. E., Pals, C. E., Wissink, S., Vervaart, J. M., Schoorlemmer, J., and Kruijer, W. (1994) Mech. Dev. 47, 81-97[CrossRef][Medline] [Order article via Infotrieve]
  26. Schrader, M., Becker-Andre, M., and Carlberg, C. (1994) J. Biol. Chem. 269, 6444-6449[Abstract/Free Full Text]
  27. Bonni, A., Sun, Y., Nadal-Vicens, M., Bhatt, A., Frank, D. A., Rozovsky, I., Stahl, N., Yancopoulos, G. D., and Greenberg, M. E. (1997) Science 278, 477-483[Abstract/Free Full Text]
  28. Bonni, A., Frank, D. A., Schindler, C., and Greenberg, M. E. (1993) Science 262, 1575-1579[Medline] [Order article via Infotrieve]
  29. DuBois, R. N., McLane, M. W., Ryder, K., Lau, L. F., and Nathans, D. (1990) J. Biol. Chem. 265, 19185-19191[Abstract/Free Full Text]
  30. Rosen, D. R. (1993) Nature 362, 59-62[CrossRef][Medline] [Order article via Infotrieve]
  31. Lin, D., Wu, S., and Chang, C. (1998) Endocrine 8, 123-134[Medline] [Order article via Infotrieve]
  32. Lydon, J. P., Power, R. F., and Conneely, O. M. (1992) Gene Expr. 2, 273-283[Medline] [Order article via Infotrieve]
  33. Cooney, A. J., Tsai, S. Y., O'Malley, B. W., and Tsai, M. J. (1992) Mol. Cell. Biol. 12, 4153-4163[Abstract]


Copyright © 1998 by The American Society for Biochemistry and Molecular Biology, Inc.