Nucleic Acids Research, 2000, Vol. 28, No. 2 411-415
© 2000 Oxford University Press
Members of the SRY family regulate the human LINE retrotransposons
Unité des Rétrovirus Endogènes et Eléments Rétroï des des Eucaryotes Supérieurs, UMR1573 CNRS, Institut Gustave Roussy, 39 rue Camille Desmoulins, 94805 Villejuif Cedex, France
Received October 20, 1999; Revised and Accepted November 22, 1999.
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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LINEs are endogenous mobile genetic elements which have dispersed and accumulated in the genomes of most higher eukaryotes via germline transposition, with up to 100 000 copies for the human LINE-1 (L1H) sequences. Although severely repressed in most normal tissues, L1H is still functional, with evidence for both germline and somatic—essentially in tumors—transpositions. Yet, no transcription factor that could regulate their transcription and be responsible for their transposition has hitherto been described. Here we show that factors belonging to the family of the testis-determining factor gene SRY (the SOX family) can modulate L1H promoter activity over a 10-fold range in a transient transfection assay using a luciferase reporter gene. These effects depend on two functional SRY binding sites which can be identified within the L1H promoter via mobility shift assays. Induction of endogenous L1Hs upon ectopic expression of the SOX11 transcription factor is further demonstrated, thus strengthening the physiological relevance of these new—and highly dispersed—target sites for the otherwise unclassical transcription factors of the SRY family.
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INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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LINEs are highly reiterated transposable elements (100 000 copies in the human genome), responsible for several genetic diseases through insertional mutagenesis (reviewed in 1). Their transposition requires synthesis of a full-length genomic RNA (gRNA) followed by its reverse transcription and integration by LINE-encoded proteins. Human LINE-1 (L1H) transcription is driven by an internal promoter located within the first 670 bp of the element (2,3). It is severely repressed in most somatic, differentiated cells, but induction can be observed in embryonal carcinoma cells and testicular germline tumors (4–6). DNA methylation (7,8) and RNA polymerase III (9,10) have been tentatively identified as playing a role in L1H promoter activity, but no transcription factor that could regulate transcription of endogenous L1Hs has been described. We show here that the L1H promoter contains two functional binding sites for transcription factors of the SRY family (11,12), namely the SOX factors (reviewed in 13). SRY, the prototype of the SOX family members, is involved in sex determination (11,12). It is expressed in the urogenital ridge of the embryo and, in the adult, in the testis, hypothalamus and midbrain (reviewed in 13). Although less extensively studied, other SOX factors also appear to be expressed according to restricted and specific patterns, mainly during development and, in some cases, in the adult (13). SOX factors all share a conserved domain of about 80 amino acids, the High Mobility Group (HMG) box (14)—also found in the HMG1 and HMG2 proteins (15). This HMG box is involved in DNA binding and a consensus sequence for SOX binding sites has been derived as A/TA/TCAAA/T (16 and references therein). The two binding sites that we presently identify in the L1H promoter are functional sites, which are required for some of the SOX members to transactivate a luciferase reporter gene driven by the L1H promoter. Ectopic overexpression of one member of the SRY family, SOX11, is further shown to result in a 10-fold transactivation of the endogenous L1Hs in human cells.
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MATERIALS AND METHODS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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Cell culture and transfection
RD and 293 cells (from the European Collection of Cell Cultures) and NTera2/D1 (from the ATCC) were grown in DMEM—in MEM for 293 cells—supplemented with 4.5 g/l glucose, 10% fetal calf serum and antibiotics, at 37°C in 6% CO2. Transfections of dispersed cells were carried out with Lipofectamine Plus Reagent (Gibco BRL) or Geneporter (Boehringer Mannheim) according to manufacturers’ instructions. Cells were harvested 2 days post-transfection for transient transfection assays. Luciferase activity was measured with a luciferase assay kit (Promega) and ß-galactosidase activity with CPRG (Boehringer Mannheim) as a ß-galactosidase substrate, using the same cell extract. For stable transfections, cells were cotransfected with the pJ3
SOX11 vector, or control vector, and the pSVTKneoß plasmid, conferring G418 resistance, at a 19:1 molar ratio, and G418R cell clones were isolated using 1 mg/ml G418 (Gibco BRL).
Plasmids
L1luc reporter gene and mutated L1Amluc, L1Bmluc and L1AmBmluc derivatives (1). The L1H promoter was excised from pL1.2A plasmid [which contains L1.2A L1H element (17) with no flanking cellular DNA, subcloned in pGEM5Zf+] as a BstXII (position 902 in L1H) Klenow-treated SacII (in pGEM5Zf+ polylinker) fragment and subcloned in pKS– (Stratagene) opened by XbaI Klenow-treated and SacII. L1H promoter was then excised as a SacI–BamHI fragment (both sites in PKS-polylinker) and inserted into pGL3 Basic Vector (Promega) opened by SacI and BglII [both sites in the polylinker, upstream of the luciferase open reading frame (ORF)]. Mutations in the A and B sites were introduced by PCR with oligonucleotide primers carrying the modified sequences. L1H sequences for all the luciferase vectors were verified by DNA sequencing. (2) SOX expression vectors: the SOX3 sequence was excised from plasmid X2-1 H33 (which contains a SOX3 genomic fragment cloned at the HindIII site of pKS+; gift from P. Hextall, Cambridge, UK) as a HindIII (~440 bp upstream of the SOX3 ORF first AUG codon) Klenow-treated fragment. SOX11 ORF was excised from the pJ3SOX11 expression vector (gift from P. Berta, UPR1142, France) as a HindIII (located in the polylinker of pJ3 and 3' to SOX11 ORF) Klenow-treated fragment. SOX fragments (or no fragment for the CMV-none control expression vector) were cloned into the pCMVß vector (Clontech) opened by NotI (which removes the ß-galactosidase ORF) and Klenow-treated. CMV–SRY was a gift from M. Fellous (Pasteur Institute, France).
Northern blot analysis
Cytosolic RNA was extracted using 107–4 x 107 cells, which were first rinsed twice with isotonic phosphate-buffered (pH 7.5) saline (PBS), and then harvested, after trysin/EDTA treatment, by soft pipetting in PBS. After centrifugation, the cells were lysed by a 10-min incubation on ice in 1 ml of EBC buffer (0.5% Nonidet P-40, 10 mM Tris–HCl pH 7.9, NaCl 140 mM) supplemented with 30 mM ß-mercaptoethanol, 5 mM ribosyl-orthovanadate complexes, 2 mM MgCl2 and brief vortexing. Supernatants recovered after a 10-min centrifugation at 13 000 r.p.m. were supplemented with 7 ml guanidium-thiocyanate and further processed by the guanidium/cesium chloride procedure (18). RNAs were separated by electrophoresis and blotted onto HybondN+ filters (Amersham) according to the manufacturer’s instructions.
L1H single-stranded DNA probes were synthesised by submitting 100 ng of pL1luc plasmid linearised with SacI (site just 5' to the L1H 1–906 promoter sequence) to 20 cycles of PCR using the GLprimer2 (Promega) oligonucleotide (located 65 bp 3' to the L1H promoter) and [
-32P]dCTP. Labelled DNA was purified by elution through a Sephadex G50 column. Control experiments disclosed that this single-strand DNA probe, but not the complementary one (generated as above after linearisation of pL1luc and PCR amplification with the Promega RVprimer3 oligonucleotide), specifically hybridised to L1H gRNA from NTera2/D1 cells.
Electrophoretic mobility shift assay
The indicated DNA probes were synthesised by PCR with linearised pL1luc or its mutated derivatives as templates and adequate oligonucleotide primers. Procedures to obtain Escherichia coli cytoplasmic cell extracts were as follows: lysis of the washed bacterial cells in 50 mM sodium phosphate buffer pH 7.4, 50 mM NaCl, 10 µg/ml RNase A, 1 mg/ml lyzozyme, 1 mM PMSF, 0.2% Tween, brief sonication, centrifugation at 13 000 r.p.m. for 15 min and harvesting of the supernatant. pT7-hSRYbox88 bacterial cells contains an IPTG-inducible plasmid encoding the 88 amino acid long HMG box of the human SRY factor (19). In our hand, this peptide was produced in too weak amounts to be detected upon SDS–PAGE electrophoresis and Coomassie blue staining of the bacterial cell extract. Protein–DNA binding reactions were performed in 30 µl, containing 100 mM KCl, 20% glycerol, 20 mM HEPES pH 7.9, 1 mM DTT, 1 mM EDTA, 1 mM PMSF, 1 µg salmon sperm DNA, 6 µg E.coli cytoplasmic cell extracts and ~100 000 c.p.m. of the 32P-labelled DNA probes.
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RESULTS |
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Using a computer search program (TFSEARCH version 1.3), we identified two potential binding sites for SOX transcription factors within the first 670 nt of the L1H sequence (9,17): one between nucleotides 472 and 477 (site A) and another between nucleotides 572 and 577 (site B), both with the sequence AACAAA (Fig. 1A). Electrophoretic mobility shift experiments (Fig. 1B) confirmed that these A and B sites can specifically interact with the DNA binding domain of SRY—the prototype of the SOX family members (11,12). Indeed, cytoplasmic extracts from E.coli cells expressing the SRY HMG box domain (hSRYbox88) (19), but not cytoplasmic extracts from control cells, alter the mobility of DNA probes encompassing the A or B sites. Moreover, mutations introduced into the A (Am) or B (Bm) sites abolished the observed SRY-dependent mobility shift (Fig. 1B).
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These observations led us to examine whether L1H promoter-driven transcription is modulated by SOX factors. A luciferase reporter gene (L1luc) was therefore constructed by inserting the first 906 nt of L1H [corresponding to the promoter-containing 5' UTR of the L1.2A clone (2,17), Fig. 1A] into a commercially available luciferase vector (Fig. 2A and Materials and Methods). The effects of various SOX proteins on L1H promoter activity was then analysed by transient co-transfection of cultured cells with the L1luc reporter together with different SOX expression vectors and a ß-galactosidase expressing gene (pCMVß, see legend to Fig. 2) to normalise for transfection efficiency. Cells from the human RD cell line—derived from a human embryo rhabdomyosarcoma—were used as recipients because they display a very low basal level of endogenous L1H gRNA (T.Tchénio, unpublished). As illustrated in Figure 2B, the SOX11 factor (20,21) transactivates the L1luc reporter gene up to a maximum of 9-fold (at 200 ng DNA), followed by a small decrease at higher DNA concentrations. The SOX3 factor (22,23) also transactivates L1luc, but only to a limited extent. Conversely, the human SRY factor reduces L1luc expression by ~2-fold, under conditions where no effect of SRY on a control luciferase reporter gene driven by the minimal SV40 promoter (pGL3promoter vector; Promega) was observed (data not shown). This antagonistic effect of SRY on L1H promoter is also manifested by the observed reduction of the SOX11-mediated L1luc transactivation in the presence of SRY, not observed with SOX3 (Fig. 2C). These results are in agreement with the absence of an activation domain in the human SRY factor, and with the reported inhibitory effects of SRY on a recombinant thymidine kinase promoter flanked by SRY binding sites (24). Finally, to demonstrate the role of the A and B sites in the SOX-mediated regulation of L1H promoter activity, the Am and/or Bm mutations (Fig. 1A) were introduced into the L1luc vector. The data in Figure 2D show that both sites are required for full transactivation by the SOX11 protein and that mutation of both sites completely abolishes the SOX11 stimulatory effect.
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To analyse whether ectopic expression of SOX proteins can modulate the level of endogenous L1H gRNA, a transient transfection assay was performed, using the easily transfectable human kidney-derived 293 cells. Endogenous L1H RNAs were then analysed by northern blot, upon hybridisation with an antisense L1H single-stranded DNA probe (Materials and Methods). NTera2/D1 embryonal carcinoma cells—one of the only few human cell lines in which high level expression of a discrete 6 kb L1H gRNA can be detected by northern blot analysis (6)—as well as murine NIH 3T3 cells (devoid of L1H genetic elements) were used as controls (Fig. 3A). Although endogenous L1H transcripts are not highly expressed in the 293 cell line, transient transfection of the cells with the CMV-SOX11, but not the CMV-SRY, vector resulted in an increase in the accumulation level of the 6 kb L1H-hybridising transcript (2–3-fold, Fig. 3A and data not shown). To further confirm these results, stably transfected SOX-expressing cells were established. A vector expressing SOX11 under the control of the SV40 early promoter (pJ3
SOX11 vector) was introduced by transfection into RD cells together with a vector for the selectable neomycin gene. G418-resistant clones were then isolated, and those expressing stably integrated SOX11 vectors (about one-third of the transfected clones) were characterised by Southern and northern blot analyses (data not shown). As illustrated for independent clones by the northern blot shown in Figure 3B, L1H gRNAs—as detected using the antisense L1H probe—were induced in the SOX11 expressing cells, ~10-fold as compared to control transfected cells. A heterogenous population of L1H-hybridising transcripts of larger size, most probably originating from inefficient transcription termination of endogenous L1Hs (25), was also induced upon SOX11 expression, resulting in the observed smear of high molecular weight RNAs. No antisense transcripts were detected in these clones using, under identical experimental conditions, a sense L1H single-stranded DNA probe (data not shown), thus indicating that the transcripts observed above do originate from L1Hs.
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DISCUSSION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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The present results therefore show that the human L1H promoter not only contains SRY binding sites, sensu stricto, but that these sites are indeed ‘functional’, being responsible for the efficient transactivation of the L1H promoter by a SOX family member. Although one would expect the rather degenerate consensus SOX binding sequence (i.e. A/TA/TCAAA/T) to be frequently encountered, and despite the limited sequence specificity for SOX binding (26), functional SOX sites have been identified in only a limited number of genes (including the Müllerian Inhibiting Substance, the FGF4, the collagen II and the TCR
genes; reviewed in 13). It has been suggested that the much more stringent conditions required for a SOX ‘effect’ versus ‘binding’ is due in part to a recognition sequence that extends beyond the consensus sequence and/or the ability of SOX to make protein–protein contacts with other DNA binding proteins (13,16). In fact, it has been proposed that the mode of action of the SRY factor and related proteins is to organise the local chromatin structure—in part via their ability to bend DNA in a sequence-dependent manner—and assemble other DNA-bound factors into biologically active, sterically defined multiprotein complexes (27,28). In the case of L1H, no conspicuous binding site for other known transcription factors has yet been identified in the promoter sequence, except those previously characterised for the YY1 protein (29,30). Being ubiquitously expressed, it is very unlikely that YY1 accounts for the restricted pattern of L1H expression as observed in vivo, but it remains plausible that it cooperates with SOX factors to assemble the transcription machinery at the L1H promoter, all the more as YY1 is itself an ‘architectural’ factor which can promote DNA binding to the nuclear matrix (31). Whatever the underlying mechanisms for the SOX-mediated transactivation, a noteworthy consequence of the present investigation is that the high copy number of full-length L1H transposable elements results de facto in the dispersion of thousands of functional SOX binding sites in the genome. Targeting of SOX factors to these sites may therefore result not only in the activation of the LINE elements themselves, but also in that of nearby genes, possibly via SOX-mediated ‘architectural’ effects. This would constitute an unexpected and important additional consequence of transposon mobility on genome structure and gene regulation. Finally, an important issue will be to determine whether SOX factors, such as SOX11, are expressed in vivo in the human germ cell lineage, that could activate L1H elements. In fact, several SOX family members are likely to be expressed in these cells, as suggested by the demonstrated expression of various SOX factors in germline-derived tumours (32 and references therein). Such germline-expressed SOX factors would be serious candidates as essential determinants of L1H activity in vivo under both normal and pathological conditions. |
ACKNOWLEDGEMENTS |
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We thank P. Berta for plasmid pJ3
SOX11, M. Fellous for the CMV-SRY expression vector, P. Hextall for plasmid X2-1 H33 and the pT7-hSRYbox88 containing bacterial strain, and H. H. Kazazian for the cloned L12.A element. P. Berta is also acknowledged for helpful suggestions, S. Cristescu and C. Lavialle for critical reading of the manuscript.
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FOOTNOTES |
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* To whom correspondence should be addressed. Tel: +33 1 42 11 49 70; Fax: +33 1 42 11 53 42; Email: heidmann@igr.fr
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