Mechanism of Regulatory Target Selection by the SOX High-Mobility-Group Domain Proteins as Revealed by Comparison of SOX1/2/3 and SOX9

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Molecular and Cellular Biology, January 1999, p. 107-120, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Mechanism of Regulatory Target Selection by the SOX High-Mobility-Group Domain Proteins as Revealed by Comparison of SOX1/2/3 and SOX9

Yusuke Kamachi,¹ Kathryn S. E. Cheah,² and Hisato Kondoh¹^,^*

Institute for Molecular and Cellular Biology, Osaka University, Osaka 565-0871, Japan,¹ and Department of Biochemistry, The University of Hong Kong, Hong Kong, China²

Received 17 July 1998/Returned for modification 29 September 1998/Accepted 14 October 1998

	ABSTRACT

Top Abstract Introduction Materials and methods Results Discussion References

SOX proteins bind similar DNA motifs through their high-mobility-group (HMG) domains, but their action is highly specificwith respect to target genes and cell type. We investigated themechanism of target selection by comparing SOX1/2/3, which activate $delta$ -crystallin minimal enhancer DC5, with SOX9, which activatesCol2a1 minimal enhancer COL2C2. These enhancers depend on boththe SOX binding site and the binding site of a putative partnerfactor. The DC5 site was equally bound and bent by the HMG domainsof SOX1/2 and SOX9. The activation domains of these SOX proteinsmapped at the distal portions of the C-terminal domains were notcell specific and were independent of the partner factor. Chimericproteins produced between SOX1 and SOX9 showed that to activatethe DC5 enhancer, the C-terminal domain must be that of SOX1,although the HMG domains were replaceable. The SOX2-VP16 fusionprotein, in which the activation domain of SOX2 was replaced bythat of VP16, activated the DC5 enhancer still in a partner factor-dependentmanner. The results argue that the proximal portion of the C-terminaldomain of SOX1/2 specifically interacts with the partner factor,and this interaction determines the specificity of the SOX1/2action. Essentially the same results were obtained in the converseexperiments in which COL2C2 activation by SOX9 was analyzed, exceptthat specificity of SOX9-partner factor interaction also involvedthe SOX9 HMG domain. The highly selective SOX-partner factor interactionspresumably stabilize the DNA binding of the SOX proteins and providethe mechanism for regulatory targetselection.

	INTRODUCTION

Top Abstract Introduction Materials and methods Results Discussion References

An important question of transcriptional regulation is how transcription factors select their correct target genes withinthe genome. DNA-binding specificity of individual protein factorsmust be one of the major determinants of target gene selection.A family of closely related transcription factors often have highlysimilar DNA-binding properties, most often recognizing only ~6-bpDNA sequences, with allowance of considerable degeneracy. Nevertheless,these transcription factors activate or repress each specificset of target genes via these binding motifs and exert quite differentbiological effects even within a protein family. The Sox genefamily investigated in this work is a good example of such a family.The problem is the mechanism which enables each SOX protein toselect the correct subset of binding sites to achieve its properin vivofunction.

Sox genes have been identified on the basis of their homology to the high-mobility-group (HMG) box of the mammalian testis-determininggene Sry (17; for a review, see reference 36). They comprisea large gene family of more than 20 members in mammals and arefound in all investigated species of the animal kingdom (10,49). SOX proteins are grouped into subfamilies based on theamino acid sequence of the HMG domain (49). Within each subfamily,the amino acid sequence of the HMG domain is $>=$ 90% identical andsequence similarity extends outside this domain. Although thehomology exhibited within the HMG domain is ~60% between distantlyrelated subfamilies, DNA-binding characteristics of the variousSRY and SOX family proteins tested so far appear very similarto each other. They recognize essentially the same sets of sequenceswith very similar affinities (11, 19, 24, 26) and inducesharp bends at similar angles (7, 12, 31).

Sox genes are found to be expressed in a wide variety of tissues during development. Neural tissues express high levels ofmany Sox genes, e.g., Sox1, Sox2, Sox3, Sox6, Sox9, and Sox11(6, 8, 18, 34, 37, 39, 42, 45). Sox2 is alsoexpressed in the lens and gut epithelium in chicken embryos (24,25, 45), and in teratocarcinoma and embryonic stem cells (50).Sox9 is expressed in prechondrogenic and chondrogenic tissues(34, 47, 48, 51) and in the genital ridge (9, 27),sites which are consistent with the skeletal malformations andsex reversal found in campomelic dysplasia patients with mutationsin the gene. Sox11 is widely expressed throughout embryos at earlystages, but its expression becomes restricted in tissues, e.g.,central and peripheral nervous systems, at later stages (18,45).

In these Sox-expressing tissues, the products of the Sox genes are each expected to have a unique biological function andto regulate different sets of genes. A limited number of authentictarget genes of SOX proteins have been identified, but SOX proteinsactivate the genes in all known cases. An important observationis that activation of a particular gene by a SOX protein occursonly in a subset of cells or tissues among those expressing theSOXprotein.

Best-characterized examples of SOX target genes are the lens-specific chicken $delta$ 1-crystallin and mouse $gamma$ -crystallin genes,regulated by three highly related SOX proteins, SOX1, -2, and-3 (collectively called SOX1/2/3) (24, 25, 35). Lens-specificactivity of the intronic enhancer of the chicken $delta$ 1-crystallingene (20) is dependent on the 30-bp-long DC5 fragment, whichby itself has a lens-specific enhancer activity (22). It hasbeen demonstrated that SOX1/2/3 (Fig. 1A) bind to the 5' halfof the DC5 sequence (Fig. 1B), and binding of one of these SOXproteins is essential for the DC5 enhancer (24, 25). It isimportant that in activation of the DC5 enhancer, SOX1/2/3 requirethe putative partner factor $delta$ EF3, which interacts with the 3'-halfof the DC5 sequence and is present in lens cells but absent infibroblasts (22, 24, 25). Mutations of the DC5 sequencethat inhibit binding of either SOX1/2/3 (e.g., M4) or $delta$ EF3 (e.g.,M7) abolish the enhancer activity (22, 24) (Fig. 1B). It hasbeen demonstrated that overexpression of SOX2 increases the enhanceractivity of the wild-type DC5 (DC5-WT) in lens cells, but thisdoes not occur when the $delta$ EF3 site is mutated to M7 sequence (24).It has also been demonstrated that lens-specific $gamma$ -crystallinpromoters have an essential SOX1/2/3 binding site (24, 35).Importance of SOX1/2/3 in crystallin gene expression is confirmedby the fact that Sox1-deficient mice lack expression of all membersof $gamma$ -crystallin genes in the stage when only SOX1 is normallyexpressed in the lens (35).

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FIG. 1. Comparison of SOX1/2/3, SOX9, and SOX11 with respect to protein structure and activation of the DC5 enhancer. (A) Schematic presentation of chicken SOX proteins used in this study. Percentages of amino acid identity with SOX1 in the HMG domain are given. (B) Sequences of the DC5 fragments used in this study. In the DC5 mutant sequences (22), altered bases are shaded. The SOX binding site and the putative $delta$ EF3 site are indicated at the top. Lowercase letters indicate bases introduced to generate BglII and BamHI restriction sites. (C) (a) Scheme of the cotransfection assay. The luciferase reporter plasmid contains octamerized DC5 fragment positioned upstream of $delta$ 1-crystallin minimal promoter ( $delta$ -Cry pro; $-$ 51 to +57). The cDNAs of Sox genes were expressed by the CMV enhancer-promoter. (b) Comparison of effects of SOX1, SOX9, and SOX11 on the DC5 enhancer. Lens cells were transfected with the luciferase reporter plasmid and with various amounts of effector vectors (0, 0.2, 1, and 5 ng) encoding one of the SOX proteins. Luciferase activity generated by the reporter in the absence of exogenous SOX was taken as 1. (D) Expression of FLAG-tagged SOX proteins in lens cells. Lens cells were transfected with pCMV/SV-Flag1 plasmids encoding no protein ( $-$ ) or the indicated SOX proteins. Whole-cell lysates were subjected to Western blot analysis using anti-FLAG antibody. Calculated molecular masses of FLAG-SOX proteins are as follows: FLAG-SOX1, 39.2 kDa; FLAG-SOX2, 35.8 kDa; and FLAG-SOX9, 56.4 kDa. The sizes of molecular mass markers are indicated on the left.

Other established targets of regulation by SOX are the human (COL2A1) and mouse (Col2a1) genes encoding type II collagen,the major extracellular matrix component of cartilage (2, 31).Expression of Sox9 parallels that of Col2a1 during chondrogenesis,and abnormal regulation of COL2A1 expression is presumed to bea cause of the skeletal abnormalities associated with campomelicdysplasia (34, 51). Chondrocyte-specific expression of Col2a1/COL2A1is regulated by conserved sequences in the first intron (2,30, 32). SOX9 is shown to bind to at least two sites, COL2C1and COL2C2, of the 309-bp human COL2A1 enhancer (2). Mutationsof these SOX9 binding sequences abolish chondrocyte-specific activityof the human COL2A1 enhancer in transgenic mice (2). In thecase of mouse Col2a1, the conserved 18-bp enhancer has been demonstratedto be the minimal enhancer in chondrosarcoma cells (32); the18-bp sequence is identical to human COL2C2. Analogous to theDC5 enhancer, the COL2C2 activity is dependent on both the SOXbinding site and a site for another enhancer binding factor (31,32). SOX9 has been shown to activate the COL2C2-containing enhancerfragments in transfected cells of various origins (31). Ectopicexpression of SOX9 also transactivates reporter constructs containingCOL2C1 and COL2C2 in transgenic mice (2).

In this report, we investigated the mechanism by which SOX proteins selectively activate particular enhancers, taking advantageof two established natural target sequences, $delta$ 1-crystallin DC5for SOX1/2/3 and Col2a1/COL2A1 COL2C2 for SOX9. The data indicatethat enhancer activation by SOX proteins requires DNA-bindingpartner factors which specifically interact with each subclassof SOX proteins. This cooperation likely occurs not at the stepof transactivation but presumably at the step of establishinghigh-affinity DNA binding. Through the specific interaction withthe partners, a specific SOX protein is selectively employed bya particular SOXsite.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and methods Results Discussion References

Chicken Sox cDNAs. cDNAs of Sox9 and Sox11 used in this study were obtained from cDNA libraries of chicken embryonic (14-day-old) brain. DNAdatabase accession numbers are AB012236 for Sox9 and AB012237for Sox11. Chicken Sox2 (24) and chicken Sox1 and Sox3 (25)cDNAs have been describedelsewhere.

Plasmid construction. To express Sox cDNAs in cultured cells, we inserted cDNA fragments into cytomegalovirus (CMV) enhancer-promoter-driven expressionvectors pCMV/SV1, pCMV/SV2, and/or pCMV/SV-Flag1. pCMV/SV1 wasconstructed by inserting the simian virus 40 replication origininto pCMVX (22). pCMV/SV2 is the same as pCMV/SV1 except thatit has the cloning sites of pcDNAI (Invitrogen). pCMV/SV-Flag1was constructed by replacing the cloning site of pCMV/SV2 withthe Met-FLAG sequence and the cloning sites of pCITE-3(Novagen).

Plasmid constructs of SOX1 C-terminal deletions were made by digestion of SmaI ( $Delta$ C323, $Delta$ C216, and $Delta$ C192) or ScaI ( $Delta$ C132) andby inserting the fragments into pCMV/SV2(EcoStop), in which theEcoRI-NotI fragment was replaced by a sequence containing three-framestop codons. The internal deletion $Delta$ 132-247 construct was madeby removing ScaI-PstI fragment. In the SOX1 $Delta$ N45 mutant, the AvaIIsite was preceded by Kozak sequence and a methionine codon. Thedeletions are indicated by the amino acids that have beendeleted.

Constructs coding for SOX1-SOX9 chimeric proteins were made by exchanging cDNA fragments corresponding to the N-terminal,HMG, and/or C-terminal domains of the proteins, using XmnI andBbsI sites which are located at the N- and C-terminal ends, respectively,of the HMG domain. As the natural Sox9 sequence does not containthe BbsI site, we generated the junctional BbsI site by PCR usingBbsI-tagged primers. BbsI site-bearing Sox9 cDNA coded for SOX9(+BbsI)with alteration of the amino acid sequence (underlined in thesequence below) at the junction of the HMG and C-terminal domains,but this alteration did not affect the activation potential asSOX9 in cotransfection experiments (data not shown). Amino acidsequences at the junctions of the N-terminal, HMG, and C-terminaldomains are as follows: SOX1, KAGQ/DRVK-----PRRKTK/TLLKK; SOX9,SKNK/PHVK-----PRRRKS/VKNGQ; SOX9(+BbsI), SKNK/PHVK-----PRRKTK/T/VKNGQ;SOX9-1-9, SKNK/PHVK-----PRRKTK/T/VKNGQ; and SOX1-9-1, KAGQ/DRVK-----PRRKTK/TLLKK.

The expression vector for GAL4 fusions was made by inserting the HindIII-EcoRI fragment encoding the DNA-binding domain (GAL4DBD;amino acids [aa] 1 to 147) from pSGVP (40) into pCMV/SV2, resultingin pCMV/SV2-GAL4DBD. The fragments encoding the C-terminal domainsof SOX proteins were inserted downstream of the GAL4sequence.

Luciferase reporter plasmids containing the octamerized DC5 and COL2C2 derivatives were constructed as described by Kamachiand Kondoh (22). To make the luciferase reporter for the GAL4fusion assay, a fragment containing a tetramerized GAL4 site wasinserted upstream of the $delta$ 1-crystallin minimal promoter of p $delta$ 51LucII.

For in vitro protein synthesis, portions of Sox cDNAs indicated in Fig. 2 were inserted into a pCITE-3 vector (Novagen) sothat SOX proteins were made as S-Tag (Novagen)fusions.

Cell culture and transfection analysis. Cultures of lens cells and fibroblasts were prepared from 14-day-old chicken embryos as described by Hayashi et al. (20).We have recently found that a patched form of lens epithelia givesa higher activity of the DC5 enhancer than dissociated lens cells,and it was used in the experiment represented in Fig. 5. The cultureswere prepared as follows. Lenses were disrupted with forceps andincubated in Hanks' saline containing 0.1% collagenase for 30min at 37°C. The epithelial cell clumps derived from one lensequivalent were plated in a 35-mm-diameter dish coated with typeI collagen (Iwaki Glass) and cultured in Dulbecco's modified Eaglemedium supplemented with 10% fetal calf serum (FCS). Two dayslater, the medium was replaced with Ham's F12 medium with 10%FCS, and cells were cultured for another 24 h before transfection.10T1/2 cells were cultured in Dulbecco's modified Eagle mediumcontaining 10% FCS and seeded at 5 × 10⁴ cells per 35-mm-diameter dish 1 day beforetransfection.

Cells cultured in a 35-mm-diameter dish were transfected with 1.5 µg of plasmid DNA by a calcium phosphate precipitation method(5). Cotransfection was performed with plasmid DNA containing1.3 µg of luciferase reporter, 0.1 µg (total) of Sox expressionvector-empty vector mixture, and 0.1 µg of $beta$ -galactosidase referencereporter (pSV- $beta$ -Galactosidase [Promega] or pMiwZ [44]). In thetransfections shown in Fig. 5, DNA containing 1.4 µg of luciferasereporter and 0.1 µg of pSV- $beta$ -Galactosidase was transfected. Luciferaseactivity was measured 48 h after transfection as described byKamachi and Kondoh (22) and normalized to $beta$ -galactosidase activity,determined by using 4-methylumbelliferyl- $beta$ -D-galactopyranoside(13). Transfections were carried out at least three times, andthe averages are shown with the standarddeviations.

Western blotting. Lens cells cultured in a 90-mm-diameter dish were transfected with 10 µg of plasmid DNA encoding FLAG-tagged SOX proteins,and whole-cell lysates were prepared in 100 µl of sodium dodecylsulfate-polyacrylamide gel electrophoresis sample buffer; 15 µlof the lysates was loaded onto a sodium dodecyl sulfate-10% polyacrylamidegel and transferred to Immobilon-P polyvinylidene difluoride membrane(Millipore) with 10 mM 3-(cyclohexylamino)-1-propanesulfonic acid(pH 11.0) and 10% methanol. FLAG-SOX proteins were detected withanti-FLAG M5 antibody (IBIKodak).

Protein preparation and gel mobility shift assay. For in vitro protein synthesis, a transcription/translation coupled reticulocyte lysate system (TNT; Promega) was used withpCITE-3 containing Sox cDNAs. Synthesized S-Tag fusion proteinswere estimated by S-Tag rapid assay (Novagen), and 0.7 to 0.9µl of the lysate containing 2 ng of fusion proteins was used inbinding assays. Gel mobility shift assays were carried out underthe conditions described by Kamachi and Kondoh (22).

Circular permutation assay. The DC5 fragment was cloned between the BamHI and BglII sites of the circular permutation vector pBend2 (28). Circularlypermuted DNA fragments were excised with one of the restrictionenzymes indicated in Fig. 2B and labeled by using either Klenowenzyme and [ $alpha$ -³²P]dCTP or T4 polynucleotide kinase and [ $gamma$ -³²P]ATP. Gel mobility shift assays were performed as described byKamachi and Kondoh (22). Bending angles were estimated accordingto the method of Ferrari et al. (12).

	RESULTS

Top Abstract Introduction Materials and methods Results Discussion References

$delta$ 1-crystallin DC5 enhancer is activated by SOX1/2/3 but not by SOX9 or SOX11. We have previously shown that overexpression of SOX1/2/3 activates the DC5 enhancer in lens cells but not in fibroblasts (24,25). Since SOX9 and SOX11 resemble SOX1/2/3 only in the HMGdomain (Fig. 1A), we inquired whether such distantly related SOXproteins could equally activate the DC5 enhancer. Lens cells weretransfected with a luciferase reporter gene carrying the DC5 enhancerand with various amounts of effector vectors expressing eitherSOX9 or SOX11 (Fig. 1Ca). In these experiments, a 25-fold rangeof effector vectors (0.2 to 5 ng) was used to compensate for possibledifference of expression levels of SOX proteins (Fig. 1Cb). Incontrast to SOX1 or SOX2/3 (reference 25; see also Fig. 3A),neither SOX9 nor SOX11 was capable of activating the DC5 enhanceractivity in lens cells (Fig. 1Cb) or in fibroblasts (data notshown). The same SOX9 construct activated the COL2C2 enhancer(see Fig. 7) in lens cells (data not shown), indicating expressionof functional SOX9 in transfected lens cells. When analogous expressionvectors coding for FLAG-tagged SOX proteins were transfected tolens cells, synthesis of these proteins was demonstrated by Westernblotting (Fig. 1D for SOX1, -2, and -9; data for SOX11 in a separateexperiment not shown) and by nuclear accumulation of the proteinsby immunofluorescence (data not shown). These results confirmedthat all exogenous SOX proteins were expressed in the transfectedlens cells, but only SOX1/2/3 were capable of activating the DC5enhancer.

DNA-binding and DNA-bending properties are indistinguishable among the HMG domains of different SOX proteins. To examine the molecular basis of selective activation of the DC5 enhancer by SOX1/2/3, we analyzed which parts of the moleculesare involved in the selectivity by comparing SOX1/2/3 with SOX9and SOX11. SOX1 and SOX2 were analyzed among the former mainlybecause of their high activation potentials (25), while SOX9was chosen as the counterpart of SOX1/2/3 for comparison becauseits natural target gene isknown.

We first compared the HMG domains of SOX1/2/3 and SOX9 with respect to DNA binding and bending. The identity of amino acidsequence of the HMG domain is ca. 60% between SOX1/2/3 and SOX9(Fig. 1A). Approximately 200-aa-long polypeptides containing theHMG domain of SOX1, -2, or -9 were produced as fusion proteinswith S-Tag by an in vitro coupled transcription-translation system(Fig. 2A). All of these HMG domain fusion proteins formed a complexwith the DC5 sequence placed in pBend2 (Fig. 2B and C). The complexeswere sensitive to competition by the WT DC5 sequence and $gamma$ F-crystallinpromoter sequence but not to competition by the mutated DC5 sequences,M3, M4, and M5, in which the SOX binding sequence was altered(data not shown) equally to the full-length SOX2 as reported previously(24). These results indicated that HMG domains of SOX1, SOX2,and SOX9 are indistinguishable from each other in DNA bindingto the regulatory sites of $delta$ 1- and $gamma$ F-crystallin genes.

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FIG. 2. Comparison of DNA binding and DNA bending by SOX proteins. (A) Schematic presentation of the S-Tag fusion proteins synthesized in vitro by coupled transcription/translation (TNT system). S-Tag sequence at the N terminus is hatched. (B) pBend2-DC5 contained the DC5 fragment (black bar) in the middle of the duplicated multi-restriction site sequences. pBend2-DC5 DNA was cleaved at the restriction sites indicated on the map and used as probes in the circular permutation analysis. (C) Circular permutation analysis of DNA bending induced by SOX1, -2, and -9. Gel mobility shift experiments were done with S-Tag-SOX proteins (2 ng) and the permuted probes A to G. (D) The relative mobilities of the protein-DNA complexes were plotted against the flexure displacement of the probes (12).

The same pBend2-DC5 DNA was used to compare the abilities of the HMG domains to induce DNA bending at the binding site bya circular permutation assay. The circularly permuted DNA fragmentsbound by the S-Tag-SOX fusion proteins were subjected to a gelmobility shift assay (Fig. 2C). The angle of the protein-inducedbend in a DNA fragment by all three proteins was estimated at66° (Fig. 2D).

Thus, SOX1/2/3 and SOX9 are indistinguishable in binding to and bending at the DC5 sequence (data not shown for SOX3). Therefore,the interaction of the HMG domain with the DC5 DNA is not involvedin the mechanism to discriminate SOX1/2/3 from SOX9 and otherSOX proteins in activation of the DC5enhancer.

The C-terminal domain of SOX1/2 is involved not only in transactivation but in selective action to DC5. It is important to know which domain of the SOX proteins is involved in selective activation of the DC5 enhancer in lens cells.We conceptually divided the SOX proteins into three domains, theN-terminal, HMG, and C-terminal domains (Fig. 1A). To determinedomains required for DC5 activation, we analyzed SOX1 mutantswith deletions of the C-terminal and N-terminal domains. We introduceda set of successive C-terminal truncations in SOX1 and testedtheir effects on the ability to activate the DC5 enhancer in acotransfection assay. As shown in Fig. 3A, removal of 51 aa fromthe C terminus of SOX1 ( $Delta$ C323) significantly reduced the abilityto stimulate the DC5 enhancer activity. Transactivation activitywas totally lost upon extended truncation to position 192. Thus,the HMG domain of SOX1 alone is not sufficient but the associationof the C-terminal domain is essential for activation of the DC5enhancer. An internal deletion of aa 132 to 247 also resultedin a loss of activation, indicating that at least two subdomains,aa 132 to 247 and aa 323 to 373, of the C-terminal domain arerequired for activation of the DC5 enhancer by SOX1. In contrast,the N-terminal domain of SOX1 was dispensable for activation ofDC5 (Fig. 3A). Essentially the same result was obtained with SOX2,consistent with the amino acid sequence conservation between SOX1and SOX2 (23, 25).

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FIG. 3. Requirement of the SOX1 C-terminal domain for activation of the DC5 enhancer. (A) Transcriptional activity of SOX1, its deletion mutants, and SOX2. Schematic structures of the SOX proteins are shown on the left. Symbols are as in Fig. 1A. Cotransfection assays were done as described for Fig. 1C. (B) Activity of the SOX1-SOX9 chimeric proteins in activation of the DC5 enhancer. Schematic structures of chimeric proteins made by combinations of the domains derived from SOX1 and SOX9 are shown on the left. The chimeric proteins are designated by the origin of N-terminal, HMG, and C-terminal domains. For instance, SOX1-1-9 had the N-terminal and HMG domains of SOX1 and the C-terminal domain of SOX9. SOX1 portions are indicated by shaded boxes, and SOX9 portions are indicated by open boxes. SOX $Delta$ N(9)-9-1 protein lacked the N-terminal 96 aa of SOX9 and instead had Met-FLAG tag sequence indicated by the black box. Cotransfection assays were done as for Fig. 1C. (C) C-terminal domains of the SOX proteins have transactivation potential. (a) The luciferase reporter plasmid contained tetramerized GAL4 binding sites in the upstream of $delta$ 1-crystallin minimal promoter ( $delta$ -Cry pro). C-terminal domains of SOX proteins (×) were fused in frame to GAL4DBD. (b) Various amounts of effector plasmids expressing GAL4-SOX fusion proteins were transfected into lens cells and 10T1/2 cells together with the luciferase reporter plasmid and compared with GAL4DBD and GAL4-VP16. Luciferase activity generated by the reporter in the absence of GAL4 fusion proteins was taken as 1.

To determine which domains establish the functional specificity of SOX proteins at the DC5 enhancer, we produced cDNA encodingchimeric proteins in which the N-terminal, HMG, and C-terminaldomains of SOX1 and SOX9 were interchanged in various combinations(Fig. 3B). Synthesis and DNA-binding activities of these chimericproteins were confirmed in COS-7 cells transfected with the expressionvectors (data not shown). The chimeric proteins were tested forthe ability to stimulate the DC5 enhancer by cotransfection assays(Fig. 3B). Since the chimeric protein SOX1-1-9 (SOX1 N-terminaldomain, SOX1 HMG domain plus SOX9 C-terminal domain) failed tostimulate enhancer activity, the C-terminal domain of SOX1 isessential for the specific transactivation. On the other hand,the chimeric protein SOX1-9-1 showed even higher transactivationthan SOX1, confirming the requirement of SOX1 C-terminal domainin activation of DC5 in lens cells. This finding also indicatesthat the HMG domain is interchangeable between SOX1 and SOX9 andis not significantly involved in discrimination of SOX1 over SOX9in transactivation of the DC5 enhancer. In this regard, it wasrather surprising that the chimeric protein SOX9-9-1 showed fairlymodest transactivation in spite of having the SOX1 C-terminaldomain. However, removal of the N-terminal portion of the protein[SOX $Delta$ N(9)-9-1] resulted in transactivation comparable to thatfor SOX1, suggesting that the N-terminal domain of SOX9 has aninhibitory effect on activation of the DC5 enhancer by the SOX1C-terminal domain in lens cells. In a gel mobility shift assay,SOX9-9-1 and SOX $Delta$ N(9)-9-1 bound to the DC5 probe indistinguishably.On the other hand, removal of the N-terminal domain from SOX9did not cause activation of DC5 by SOX9 (data not shown). Fromthese results, we concluded that the C-terminal domain of SOXis determinative in specific activation of the DC5enhancer.

We inquired whether the C-terminal domains of SOX1/2/3 have transactivation potential when isolated from the HMG domains andfused to GAL4DBD (Fig. 3C). Lens cells were transfected with theGAL4DBD fusion constructs and a luciferase reporter plasmid carryingGAL4-binding sites (Fig. 3Ca). While GAL4DBD alone caused no increaseof luciferase activity, GAL4-SOX1 and GAL4-SOX2 stimulated luciferaseexpression 20- to 40-fold (Fig. 3Cb). It was also observed thatthese GAL4DBD-SOX fusion proteins similarly activated the luciferasereporter in chicken fibroblasts (data not shown) and 10T1/2 cells(Fig. 3Cb). These results indicate that the C-terminal domainsof SOX1 and SOX2 when isolated all display transactivation potentialwithout dependence on the cell type. The same conclusion has beenreached in studies using the mouse SOX1 C-terminal domain (L.Pevny and R. Lovell-Badge, unpublished result cited in reference25). Südbeck et al. (43) and Ng et al. (34) recently reportedthat human and mouse SOX9 have a potent transactivation domainin their C termini. The failure of SOX9 to stimulate the DC5 enhancercannot be accounted for by models assuming cell-type-dependentactivity of the activation domain of SOX9, since exogenous SOX9activated the COL2C2 enhancer in lens cells as described above.Furthermore, GAL4-SOX9 fusion protein carrying the C-terminaldomain of chicken SOX9 and GAL4DBD activated expression of theGAL4-dependent reporter gene in lens cells (Fig. 3C) and fibroblasts(data not shown), in sharp contrast to the failure of intact SOX9to activate DC5 in either cells. The level of stimulation by GAL4-SOX9was even higher than those by GAL4-SOX1/2 and was comparable tothat by GAL4-VP16, in which GAL4DBD was fused to an acidic activationdomain of the herpes simplex virus protein VP16 (40). Thus,the activation domain of SOX9 does not function at the DC5 enhancerwhen linked to the intrinsic SOX9 HMG domain, in spite of bindingof the SOX9 HMG domain to the DC5 sequence in in vitro experiments(Fig. 2).

The above results indicate that the C-terminal domain of SOX1/2 was essential and unable to be replaced with that of SOX9for selective activation of the DC5 enhancer, while C-terminaldomains of SOX1/2 and SOX9 exhibited nonspecific transactivationpotential when tested as GAL4DBD fusions. This finding impliesthat a portion of the C-terminal domain, one not involved in transactivationby itself, may play a role in selective action of SOXproteins.

The VP16 activation domain joined to the SOX HMG domain does not overcome the requirement of the partner factor $delta$ EF3 in activation of the DC5 enhancer. Previously, we reported that activation of the DC5 enhancer by SOX2 requires the integrity of a sequence neighboring the SOXbinding site which is assigned to the $delta$ EF3 binding site (24).For instance, mutation M7 of the putative $delta$ EF3 site (Fig. 1B)totally inactivated the DC5 enhancer activity, although it didnot affect SOX2 binding to DC5 in vitro (24). The requirementfor $delta$ EF3 was also investigated for SOX1, SOX3, and the chimericSOX1-9-1. It was demonstrated that activation of the DC5 enhancerby these SOX proteins was lost by mutation M7 of the $delta$ EF3 sitesimilarly to mutation M4 in the SOX binding site (Fig. 4B; datanot shown for SOX3 and SOX1-9-1). This result confirmed that allSOX proteins capable of activation of DC5 depend on binding ofthe partner factor $delta$ EF3 at the nearby site.

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FIG. 4. Fusion proteins of SOX HMG domains bearing the VP16 activation domain still require the partner factor for transactivation. (A) Schematic structures of SOX-VP16 fusion proteins. C-terminal domains of SOX2 and SOX9 carrying the transactivation potential were replaced with the VP16 activation domain. (B to E) Luciferase reporter plasmids were the same as in Fig. 1 and carried the WT, M4 (loss of SOX binding), or M7 (loss of $delta$ EF3 binding) form of the DC5 enhancer. Luciferase reporter plasmids were cotransfected with various amounts of effector vectors (0, 0.2, 1, and 5 ng) expressing either SOX1 (B), SOX2(4-183)-VP16 (C and D), SOX2(4-120)-VP16 (D), or SOX9(1-264)-VP16 (E) into lens cells. Luciferase activity generated by the reporter containing DC5-WT in the absence of exogenous SOX proteins was taken as 1 in each experiment. Luciferase expression of the reporters carrying the M4 or M7 mutation was ~15-fold lower than that of the DC5-WT-carrying reporter. This finding indicates that in lens cells, the transfected reporter is already activated by endogenous SOX1/2/3. Therefore, the overall activation level of DC5 enhancer by SOX1/2/3 in lens cells is estimated to be 30- to 100-fold, and that by SOX2(4-183)-VP16 is ~300-fold.

The above results indicated that in the absence of a proper partner factor bound at a nearby site of the enhancer, the transactivationdomains of SOX do not stimulate transcription when they are linkedto the SOX HMG domain, which binds to the DC5 sequence in in vitroexperiments. These results were in contrast to the case of theGAL4DBD-SOX1/2 C-terminal domain fusion protein which was independentof the partner factor (Fig. 3C). To test whether properties ofthe activation domains of SOX have unique characteristics to accountfor this behavior, we examined the performance of the typicalacidic activation domain of VP16 when it is linked to SOX proteins(Fig. 4A). We first made a fusion protein in which the VP16 activationdomain was fused to a truncated SOX2 protein [SOX2(4-183)] thathad lost its own activation potential (25) (Fig. 3A shows comparabledata for SOX1). This SOX2(4-183)-VP16 fusion protein stronglystimulated the DC5 enhancer activity when expressed in lens cells(Fig. 4C); this activation was dependent on the SOX binding siteas expected (Fig. 4C; compare WT with M4). It was remarkable thatwhen the DC5-M7 mutant lacking the partner $delta$ EF3 site was used,SOX2(4-183)-VP16 was totally inactive in inducing an enhanceractivity in lens cells (Fig. 4C). In fibroblasts which lacks $delta$ EF3activity, overexpressed SOX2(4-183)-VP16 did not stimulate transcriptioneven through DC5-WT (data not shown). These results show thatSOX2(4-183)-VP16 cannot activate transcription by itself and isstill dependent on cooperation with $delta$ EF3 to stimulate the DC5enhancer. The SOX9(1-264)-VP16 fusion, in which the VP16 activationdomain was linked to the truncated SOX9, did not stimulate theactivity of the DC5 enhancer even in lens cells, just as withthe intact SOX9 protein (Fig. 4E). These results indicate thatthe requirement for $delta$ EF3 for SOX1/2/3 activation of the DC5 enhanceris not overcome by replacement of the SOX activation domain withthe strong VP16 activation domain. Thus, the mechanism renderingtransactivation by SOX1/2/3 dependent on cooperation by the partnerfactor $delta$ EF3 is not associated with the activation domain per sebut is attributed to some other characteristic of the SOX proteins,possibly the direct protein-protein interactions with $delta$ EF3 atthe closely positioned DNA-bindingsites.

Where in the SOX2 protein is the interaction interface with $delta$ EF3 located? Since SOX2(4-183)-VP16 efficiently activated theDC5 enhancer, the interaction surface must be between aa 4 and183. We made another SOX2-VP16 fusion, in which SOX2(4-120) wasfused to the VP16 activation domain, and compared it with SOX2(4-183)-VP16.In contrast to SOX2(4-183)-VP16, SOX2(4-120)-VP16 activated theDC5 enhancer only three- to fourfold (Fig. 4D), indicating thatthe domain from aa 121 to 183 is important for SOX1/2/3- $delta$ EF3 interaction.It is to be noted, however, that SOX2(4-120)-VP16 still activatedDC5, albeit ineffectively, and this activation was lost with DC5-M7,indicating dependence on $delta$ EF3. Thus, the region from aa 4 to 120including the HMG domain seems to provide a minor interface for $delta$ EF3interaction.

The DC5 enhancer activity depends on orientation and spacing of the SOX and $delta$ EF3 binding sites. As described above, SOX1/2/3 require cooperation with $delta$ EF3 to activate the DC5 enhancer. If a direct protein interaction betweenthe two factors is involved, orientation and spacing between theirbinding sites should have a critical effect on the cooperation.We thus examined the effect of altering their relative positionsby using mutated forms of the DC5 enhancer. In the SR mutation,the SOX binding site ATTGTT has been altered to AACAAT, producingCATTGTTG sequence in reverse orientation; the I4a mutation hasa 4-bp spacer inserted between the SOX and $delta$ EF3 binding sites(Fig. 5A). In gel mobility shift assays, it was confirmed thatDC5-SR and DC5-I4a sequences were bound by SOX2 protein to thesame extent as DC5-WT (data not shown). As shown in Fig. 5B, bothmutations eliminated the DC5 enhancer activity in lens cells.Exogenous expression of SOX2 did not induce any enhancer activityof DC5-SR or DC5-I4a (data not shown). The data strongly supportthe model that direct protein interaction between SOX1/2/3 and $delta$ EF3 is required for SOX1/2/3 to activate DC5.

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FIG. 5. Effects of altering orientation and spacing between the SOX and $delta$ EF3 sites in the DC5 enhancer. (A) The SOX binding site was mutated in DC5-M4 and reversed in orientation in DC5-SR. A 4-bp spacer was added between the SOX and $delta$ EF3 sites in DC5-I4a. Altered bases are shaded. The binding sites for SOX and $delta$ EF3 are shown at the top. (B) Octamerized DC5 fragments were placed upstream of the $delta$ 1-crystallin minimal promoter ( $-$ 51 to +57) in both normal (N) and reverse (R) orientations relative to the direction of transcription. Activity of the mutated DC5 enhancers in panel A was assessed by transfecting luciferase reporter plasmids into patched cultures of lens cells and fibroblasts. Luciferase expression by reporter plasmids was normalized to that of the enhancerless plasmid p $delta$ 51LucII ( $-$ ).

Activation of the Col2a1 enhancer by SOX9 also requires specific cooperation with another enhancer-binding factor. Bell et al. (2) and Lefebvre et al. (31) identified COL2A1/Col2a1 as a target gene of SOX9 during chondrogenesis. Thehuman 309-bp COL2A1 enhancer has two SOX9 binding sequences, COL2C1and COL2C2 (Fig. 6A), both of which are essential for its enhancerfunction in transgenic mice (2). The COL2C2 sequence, the 18-bpminimal enhancer of Col2a1, is perfectly conserved among human,mouse, and rat cells. In addition, Lefebvre et al. (31) showedthat the mouse 48-bp Col2a1 enhancer containing the COL2C2 sequenceis activated by SOX9 but not by SOX4 or SOX5. In this study, activationof the COL2C2 enhancer by SOX9 was dependent not only on the bindingsite of SOX itself but also on a nearby sequence which is likelyto be the binding site of another protein factor. This providedus with an opportunity to compare the mechanism of selective actionof SOX9 on the Col2a1 enhancer with that of SOX1/2/3 on the DC5enhancer. We first tested the specificity of SOX9 in activationof the minimal enhancer COL2C2. As shown in Fig. 7A and B, eightcopies of the COL2C2 sequence placed upstream of the $delta$ -crystallinpromoter were strongly activated by SOX9 in 10T1/2 cells but onlymarginally by SOX1 and SOX2 and not at all by SOX11. This resultindicated that the determinant of SOX specificity resides in the18-bp sequence of COL2C2.

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FIG. 6. Binding of SOX proteins to the Col2a1 enhancer. (A) WT and mutant sequences of the COL2C2 enhancer. To designate COL2C2 mutations, we followed the nucleotide numbering of Lefebvre et al. (32). The C2M(9-14) mutation is the same as C2M in reference 2, which abolishes SOX binding. In C2M(SC), the SOX site was converted to the SOX consensus sequence. In the mutant sequences, altered bases are shaded. Lowercase letters indicate the base sequences added to generate BglII and BamHI restriction sites. (B) Comparison of binding of SOX1, SOX2, and SOX9 to COL2C2 sequences. Gel mobility shift assays were performed with either unprogrammed TNT lysate ( $-$ ) or S-Tag-SOX proteins (Fig. 2), using the indicated probes. SOX9 bound to the COL2C2 WT and M(1-4) sequences more efficiently than did SOX1 or SOX2. Alteration to C2M(SC) resulted in binding of SOX1 and SOX2 comparable to that of SOX9.

To determine which domain of SOX9 is required for activation of the COL2C2 enhancer, we tested various SOX derivatives, includingSOX9 deletion mutants and SOX1-SOX9 chimeric proteins, for theability to activate COL2C2 in cotransfection assays (Fig. 7B).SOX9 $Delta$ C265 failed to activate the COL2C2 enhancer, confirming theprevious notion that SOX9 requires the C-terminal activation domainfor transactivation (34, 43). The chimeric proteins SOX9-9-1and SOX1-9-1 were defective in activation of COL2C2, which indicatesthat activation of COL2C2 requires the SOX9 C-terminal domain.This is similar to the case of activation of DC5, where the SOX1C-terminal domain was essential. However, in addition to the C-terminaldomain, the HMG domain of SOX9 was also required for activationof COL2C2, since SOX9-1-9 and SOX1-1-9 were inefficient, indicatingthat the HMG domain could not be substituted by that of SOX1.Among SOX1-SOX9 chimeric proteins, only SOX1-9-9 was as activeas SOX9, confirming that both the HMG and C-terminal domains ofSOX9 are essential to fully activate COL2C2.

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FIG. 7. Specific activation of the COL2C2 enhancer by SOX9. (A) The luciferase reporter plasmid contained an octamerized COL2C2 fragment placed upstream of the $delta$ 1-crystallin minimal promoter. (B) Regulation of the COL2C2 enhancer by various SOX protein derivatives. 10T1/2 cells were transfected with the luciferase reporter plasmid and various amounts of SOX expression plasmid (0, 1, 5, and 10 ng). Luciferase activity generated by the reporter in the absence of exogenous SOX was taken as 1. (C) The luciferase reporter plasmid containing either COL2C2 WT or COL2C2 M(SC) was cotransfected as for panel B. (D) Various amounts of effector vectors (0, 1, 5, and 10 ng) bearing genes encoding either SOX9 (a) or SOX9(1-264)-VP16 (Fig. 4A) (b) were cotransfected into 10T1/2 cells with luciferase reporter plasmids carrying COL2C2 WT (

), C2M(1-4) ( $bullet$ ), or C2M(9-14) ( $black-triangle$ ). Luciferase activity generated by the reporter containing COL2C2 WT in the absence of exogenous SOX proteins was taken as 1. The VP16 activation domain could not overcome the requirement of the partner factor for SOX9 to activate the COL2C2 enhancer.

To dissect the molecular events involved in selective utilization of SOX9 in activation of the COL2C2 enhancer, we comparedthe binding affinities of SOX proteins to the COL2C2 sequences.Interestingly, SOX9 bound to the wild-type COL2C2 probe more efficientlythan SOX1 and SOX2 (Fig. 6B, lane 2 to 4), while the three proteinsbound to the DC5 sequence with similar affinities (Fig. 2C anddata notshown).

Differential binding to and requirement of the SOX9 HMG domain in activation of COL2C2 prompted us to examine to what extentthe higher affinity of SOX9 to COL2C2 sequence contributes tospecific activation by SOX9. To this end, we changed the SOX9binding sequence ATTCAT in COL2C2 to the SOX consensus ATTGTT(SC mutation), creating COL2C2M(SC) (Fig. 6A). It was confirmedin a gel mobility shift assay that SOX1, -2, and -9 bound to theCOL2C2 M(SC) probe with almost the same affinity (Fig. 6B, lane10 to 12). In transactivation assays using transfected 10T1/2cells, SOX9 activated the COL2C2 M(SC) enhancer to levels comparableto those of the COL2C2 WT enhancer (Fig. 7C). The SC mutationaugmented activation by SOX1 and by SOX9-1-9 only slightly (Fig.7C), indicating that differential binding of COL2C2 plays onlya minor role in the selective activity ofSOX9.

Because of the presence of the neighboring binding motif influencing COL2C2 enhancer activity (31), we focused on the interactionswith this site. Earlier findings and our results described abovesuggest that interaction between SOX9 and the partner factor iscrucial for activation of the COL2C2 enhancer as observed in regulationof the DC5 enhancer by SOX1/2/3. To analyze the nature of theinteraction of SOX9 with the partner factor, we tested the abilityof the SOX9(1-264)-VP16 fusion protein (Fig. 4A) to activate transcriptionthrough the WT or two mutant forms of COL2C2: COL2C2 M(9-14),in which the SOX9 binding site is mutated in a way to abolishSOX9 binding (2), and COL2C2 M(1-4), in which the putativebinding site of the partner factor is ablated without affectingSOX binding (Fig. 6B, lane 6 to 8). Similar mutations have beenshown to abolish enhancer activity in chondrocytes (32). Weconfirmed that exogenous SOX9 could not transactivate expressionvia mutant sequence COL2C2 M(9-14) or COL2C2 M(1-4) in 10T1/2cells (Fig. 7Da). Similarly, neither of the mutant forms of theCOL2C2 enhancer was activated by SOX9(1-264)-VP16 (Fig. 7Db),which indicates that activation by SOX9(1-264)-VP16 is also dependenton interaction with the partnerfactor.

	DISCUSSION

Top Abstract Introduction Materials and methods Results Discussion References

Although the binding sequences of all known SOX proteins are barely distinguishable from each other, each SOX protein regulatesa distinct set of target genes. How are specific SOX proteinsused in regulation of particular genes? Further, regulation ofa target gene by SOX protein does not always occur but is celldependent. For instance, SOX1, SOX2, and SOX3 activate expressionof crystallin genes only in lens cells, although expression ofSox1, -2, and -3 genes is not confined to the lens but is alsofound in other tissues, e.g., the central nervous system. Whatis the mechanism of this cell dependence? To address these relatedquestions, we investigated regulation of the two established SOXtarget enhancers, the $delta$ 1-crystallin DC5 enhancer activated bySOX1/2/3 and the Col2a1 COL2C2 enhancer activated by SOX9. Animportant clue to the answers was that these enhancers carry notonly the binding site of SOX proteins but also an essential elementnext to it which is considered a putative binding site for a partnerfactor. The questions concern the nature of the interaction ofthe SOX and the partner factor in activation of anenhancer.

We analyzed the contribution of individual domains of SOX proteins in the selective activation of the DC5 and COL2C2 enhancers.It was first shown that the process of binding of the individualHMG domains to the DC5 enhancer does not discriminate betweenthe SOX proteins and thus plays no role in this selective action.The chimeric proteins were made in various combinations of thedomains derived from SOX1 and SOX9. It was demonstrated that activationof the DC5 enhancer required the SOX1 C-terminal domain, but theHMG domain could be replaced by that of SOX9. By contrast, activationof the COL2C2 enhancer required the SOX9 HMG domain in additionto the SOX9 C-terminal domain. The differential binding affinitiesof the SOX HMG domains to the COL2C2 element do not account forthis specific requirement, and a unique property of the SOX9 HMGdomain other than that of DNA binding is essential for activationof the COL2C2 enhancer. These and other data argue that the SOXproteins interact with the partner factor by using an interfaceinvolving the proximal half of the C-terminal domain and the HMGdomain. The interaction with the partner factor stabilizes bindingof SOX proteins to the target site and renders the transactivationpotential associated with the C-terminal domain effective. Theportions of the interface which are employed in specific interactionwith the partner factor are dependent on the particular SOX-partnercombination. The rationales for this model are discussedbelow.

DNA binding by HMG domains of the SOX proteins. When tested for binding to the DC5 sequence, SOX9 was indistinguishable from SOX1/2/3 in binding affinity and DNA bending.The observed bending angle of 66° is slightly different from thosepreviously reported for SRY (76°) (12, 38), SOX5 (74°) (7),and SOX9 (57°) (31), but these differences are likely ascribedto the difference in the binding sequence used, which is knownto affect the degree of bending (38). Consistent with the similarproperties of DNA binding and bending, a domain swap experimentindicated that the HMG domain of SOX1 can be replaced by thatof SOX9 in activation of the DC5 enhancer. These findings argueagainst the model that selective DNA binding by individual HMGdomains is the major mechanism of the target selection by SOXproteins.

In contrast to the case of the DC5 enhancer, COL2C2 has a SOX binding sequence fairly different from the SOX consensus, andit was bound by SOX9 more strongly than SOX1 and SOX2. This isthe first clear observation that each SOX protein may have a sequencepreference in DNA recognition. Even in this case, however, thesequence preference cannot be the major determinant of the specificityof SOX action. The COL2C2 M(SC) enhancer was bound equally wellby SOX9 and SOX1 HMG domains, yet it was not effectively activatedby SOX1 or SOX9-1-9. Therefore, it is a property of the SOX9 HMGdomain other than DNA binding that is required. As will be discussed,this requirement concerns the interaction with the partnerfactor.

Transcriptional activation by the activity of the C-terminal domains requires DNA-binding partner factors. C-terminal domains of SOX proteins bear the transactivation potential, which is demonstrated by the fusion of these domainswith GAL4DBD. However, this activation potential is cryptic inthe native protein without cooperation of the specific partnerfactor which is available only in the proper context of the enhancersequence and in the proper celltypes.

Mutational analysis of SOX1 (Fig. 3A) and SOX2 (25) revealed that the distal part of the C-terminal domain is required fortransactivation of the DC5 enhancer. The transactivation potentialof C-terminal domains of SOX1/2/3 and SOX9 displayed by fusionwith GAL4DBD was not cell dependent (Fig. 3C) and does not accountfor the cell-specific activities of SOXproteins.

An important observation was made in assays using the artificial SOX proteins in which the C-truncated SOX2 and SOX9 werefused to the strong activation domain VP16. These SOX-VP16 fusionproteins showed the same specificity of transactivation as nativeSOX2 and SOX9, still being dependent on interaction with the partnerfactor to activate the DC5 and COL2C2 enhancers, respectively.Thus, activation domains of VP16, SOX1/2, and SOX9 all functionednon-cell specifically when bound to DNA through GAL4DBD, but thesame activation domains were cell and enhancer specific when boundto DNA through the SOX HMG domain. These different outcomes betweenHMG domain-mediated and GAL4-mediated DNA bindings probably liein their affinity to DNA. GAL4DBD binds DNA as a dimer at a highaffinity (K_d = 2 × 10¹¹ M) (3), whereas SOX or SRY binds as a monomer at moderateaffinities, e.g., K_ds of 2 × 10⁹ M for SOX5 (7) and 10⁸ to 3 × 10⁹ M for SRY (16, 38), (but 3 × 10¹¹ M for SOX4 [46]). The K_d of SOX1 was estimated at ~3 × 10⁹ M in our preliminary experiment (23). Presumably SOX, whenit binds DNA by its HMG domain, is not stable enough to initiatetransactivation and requires a binding partner to achieve stablebinding to the regulatory target site. Kjærulff et al. (29)reported a similar observation for the yeast HMG protein Ste11;they suggested that Ste11 does not bind to the Ste11 sites ofM-specific genes by itself in P cells but instead binds to thesites through interaction with Mat1-Mc and acquires the capacityto activate transcription in Mcells.

It is highly possible that SOX1/2/3 directly interact with $delta$ EF3 upon binding to the DC5 enhancer and make a complex. Thisview is supported by the finding that displacement of the $delta$ EF3binding site by 4 bp away from the original position or flippingthe SOX binding site while maintaining the same distance fromthe $delta$ EF3 site resulted in total loss of enhancer activity (Fig.5).

Under ordinary conditions of gel mobility shift assay using lens nuclear extract, a $delta$ EF3-DC5 complex has not been detected,but a lens-specific $delta$ EF3 footprint on the genomic DC5 sequencehas been demonstrated by in vivo footprinting using isolated nuclei(41). Molecular cloning of $delta$ EF3 which is under way will clarifythe nature of interaction between SOX1/2/3 and $delta$ EF3.

The interface of interaction between the SOX proteins and their partner factors. The interaction between SOX1/2/3 and $delta$ EF3 must involve the HMG-proximal portion of the C-terminal domain (Fig. 8A). This ismost clearly demonstrated by the result that SOX2(4-183), whichby itself was defective in activating the DC5 enhancer, stronglyactivated the same enhancer by fusion of the VP16 activation domain(Fig. 4C); this activation was totally dependent on the $delta$ EF3 bindingsite and occurred only in lens cells (i.e., dependent on $delta$ EF3).The same analysis further indicated that the HMG domain of SOX2is also involved in the interaction with $delta$ EF3. Although the SOX(4-120)-VP16fusion protein activated DC5 enhancer only marginally, this activatingeffect was still dependent on $delta$ EF3 (Fig. 4D). Corresponding domainsof SOX9 showed no such interaction with $delta$ EF3 (Fig. 4E). Thus,the HMG domain and the proximal portion of the C-terminal domainof SOX1/2/3 form the interface between $delta$ EF3 and the SOX proteins.However, since SOX1-9-1 strongly activated the DC5 enhancer ina $delta$ EF3-dependent manner (data not shown), it appears that theC-terminal domain of SOX1/2/3 provides the major and determinativeportion of the interface.

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FIG. 8. Model of SOX-partner factor interactions essential for activation of a specific target gene by a SOX protein. (A) Functional domains of SOX proteins. Major transactivation potential is mapped to the distal portion of the C-terminal domain for both SOX2 (25) and SOX9 (34, 43). The interface region possibly interacting with the partner factors is indicated by broken lines. (B) Model for selection of a target site by SOX1/2/3 and SOX9. In the absence of the partner factor, binding of the SOX proteins to the SOX site occurs with low affinity (K_d of 3 × 10⁹ M for SOX1 binding to DC5) and is not stable enough to exert a significant effect in an in vivo situation. Only when the partner factor lies next to the SOX site do SOX proteins more stably bind to their sites (e.g., K_d of 10¹¹ M, assuming affinity analogous to that for the GAL4DBD-GAL4 binding site) and elicit transactivation.

Participation of the HMG domain in interfacing between a SOX protein and the partner factor is more clearly demonstrated inthe case of SOX9. SOX9(1-264)-VP16 efficiently activated COL2C2(Fig. 7D), indicating that the region from aa 1 to 264 spanningthe HMG domain and the proximal portion of the C-terminal domainwas sufficient for interaction with the partner factor. However,SOX1-SOX9 chimeric proteins must have the SOX9 HMG domain andthe SOX9 C-terminal domain to activate the COL2C2 enhancer (Fig.7B). The HMG domain of SOX9 could not be replaced by that of SOX1even when the SOX site of COL2C2 was changed to COL2C2M(SC) sequence,which is bound efficiently by the SOX1 HMG domain (Fig. 7C).

Thus, although the proximal portion of the C-terminal domain and the HMG domain of a SOX protein may generally form the interfaceto the partner factors (Fig. 8A), which portion of the interfaceprovides the major interaction sites seems to depend greatly onthe nature of the partner factor of the particular enhancer tobe activated by the SOX protein, as indicated by the differencebetween SOX1/2 and SOX9. This notion has been further corroboratedby a recent report on the analysis of the fibroblast growth factor4 enhancer (1). Activity of this enhancer in embryonal carcinomacells is dependent on synergistic interaction of SOX2 and Oct-3,which bind nearby sites (50), and this synergism relies on directinteractions between the SOX2 HMG domain and Oct-3 POU domain(1).

Consideration of analogous cases. LEF-1 is one of the best-characterized members of the TCF/SOX family. It has been shown that LEF-1 cannot activate transcriptionon its own but that it must act in concert with factors that bindto other nearby sites in the T-cell receptor alpha-chain enhancer.In contrast to the C-terminal activation domains of SOX, the context-dependenttransactivation domain of LEF-1, when linked to GAL4DBD, is stilldependent on the enhancer context and does not activate promotersbearing only GAL4 DNA-binding sites (4, 15). In this respect,SOX and LEF-1 proteins are very different, although they havemany properties in common. Considering, however, that the DNA-bindingaffinity of LEF-1 (K_d = 10⁹ M [14]) is comparable to that of SOX proteins, protein interactionbetween LEF-1 and other enhancer binding factors may be crucialto form a stable complex on the enhancer to activatetranscription.

Other transcription factor families might select their target genes in a manner similar to that of SOX proteins. For example,the homeodomain is similar to the HMG domain in that it bindsto DNA as a monomer with dissociation constants of 10⁸ to 10⁹ M and in that homeodomains have only a 6-bp consensus bindingsite (21). Moreover, it is shown that some of the HOX proteinscooperatively bind DNA with the partner PBX/EXD proteins, whichis suggested to be important for HOX proteins to carry out theirin vivo functions (33). Thus, the model proposed here for SOXproteins provides a paradigm of a general mechanism of targetgeneselection.

The mechanism of specific action of the SOX proteins. We have investigated the mechanism by which a given SOX protein activates a limited set of genes in a cell-specific manner.What is the mechanism behind the regulation of $delta$ 1-crystallin andCol2a1 genes through their SOX-dependent enhancers? SOX2 expressionis activated in the lens area of lateral head ectoderm by inductionby the retina primordium and continues to be expressed togetherwith SOX1 and SOX3 in the lens cells (24, 25), but this inductionalone does not explain the lens-specific expression of $delta$ -crystallin,since SOX1, SOX2, and SOX3 are expressed in the central nervoussystem and several other tissues as well (6, 25, 37, 39,42, 45). It is likely that the tissue distribution of thepartner factor $delta$ EF3 is highly restricted. In fact, we could notdetect the activity of $delta$ EF3, which activates the DC5 enhancerin cooperation with SOX2, in cells other than the lens (24).It is likely that the unique combination of SOX1/2/3 and $delta$ EF3is present only in the lens cells, and this is the basis of lens-specificactivation of the $delta$ -crystallinenhancer.

By contrast, it has been shown that high Sox9 expression closely parallels Col2a1 expression (34, 51). Lefebvre et al.(31) and we have indeed observed activation of COL2C2 enhancerby exogenous SOX9 in a variety of cell types (data not shown),indicating that the SOX9 partner factor is widely distributed.Because of this, activation of the Col2a1 gene appears primarilydependent on the expression of SOX9, and the specific interactionof SOX9 and its partner factor may be primarily employed in precludingthe action of an inappropriate class of SOX protein from Col2a1activation. In fact, ectopic expression of SOX9 in transgenicmice activated expression of the endogenous Col2a1 gene and COL2A1enhancer-bearing reporter gene in the majority of the ectopicSOX9 sites (2). However, there is a difference in expressionbetween Sox9 and Col2a1. For example, the genital ridge expressesSox9 at fairly high levels but no Col2a1 transcript is detectable(9, 27, 34, 51), implying that the SOX9 partner factoremployed in activation of COL2C2 is lacking. Consistent with thisnotion is the observation that in the above-mentioned transgenicmice with ectopic SOX9 expression, transactivation of the COL2A1enhancer reporter gene did not occur in some sites of ectopicSOX9 expression (2).

The model of target site selection by the SOX HMG domain proteins derived from the present study is summarized in Fig. 8.(i) In an in vivo situation, the HMG domain of SOX is not sufficientto form a stable protein-DNA complex at a SOX site by itself.(ii) SOX proteins require binding partner factors unique to eachSOX or SOX subfamily in order to achieve stable complex formationwith the target DNA, which leads to transcriptional activation.(iii) The HMG domain and proximal portion of the C-terminal domainof the SOX proteins provide the interface with partner factors.(iv) The portions of the interface used in selection of the authenticpartner factor vary depending on the combination of the SOX anditspartner.

	ACKNOWLEDGMENTS

We are grateful to S. Adhya for his gift of the pBend2vector.

This work was supported by grants from the Ministry of Education, Science and Culture of Japan and Science and TechnologyAgency of Japan to Y.K. and H.K.

	FOOTNOTES

^* Corresponding author. Mailing address: Institute for Molecular and Cellular Biology, Osaka University, Yamadaoka 1-3, Suitashi,Osaka 565-0871, Japan. Phone: 81-6-879-7963. Fax: 81-6-877-1738.E-mail: j61056{at}center.osaka-u.ac.jp.

REFERENCES

Top
Abstract
Introduction
Materials and methods
Results
Discussion
References

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5. Chen, C., and H. Okayama. 1987. High-efficiency transformation of mammalian cells by plasmid DNA. Mol. Cell. Biol. 7:2745-2752[Abstract/Free Full Text].

6. Collignon, J., S. Sockanathan, A. Hacker, M. Cohen-Tannoudji, D. Norris, S. Rastan, M. Stevanovic, P. N. Goodfellow, and R. Lovell-Badge. 1996. A comparison of the properties of Sox-3 with Sry and two related genes, Sox-1 and Sox-2. Development 122:509-520[Abstract].

7. Connor, F., P. D. Cary, C. M. Read, N. S. Preston, P. C. Driscoll, P. Denny, C. Crane-Robinson, and A. Ashworth. 1994. DNA binding and bending properties of the post-meiotically expressed Sry-related protein Sox-5. Nucleic Acids Res. 22:3339-3346[Abstract/Free Full Text].

8. Connor, F., E. Wright, P. Denny, P. Koopman, and A. Ashworth. 1995. The Sry-related HMG box-containing Sox6 is expressed in the adult testis and developing nervous system of the mouse. Nucleic Acids Res. 23:3365-3372[Abstract/Free Full Text].

9. da Silva, S. M., A. Hacker, V. Harley, P. Goodfellow, A. Swain, and R. Lovell-Badge. 1996. Sox9 expression during gonadal development implies a conserved role for the gene in testis differentiation in mammals and birds. Nat. Genet. 14:62-68[Medline].

10. Denny, P., S. Swift, N. Brand, N. Dabhade, P. Barton, and A. Ashworth. 1992. A conserved family of genes related to the testis determining gene, SRY. Nucleic Acids Res. 20:2887[Free Full Text].

11. Denny, P., S. Swift, F. Connor, and A. Ashworth. 1992. An SRY-related gene expressed during spermatogenesis in the mouse encodes a sequence-specific DNA-binding protein. EMBO J. 11:3705-3712[Medline].

12. Ferrari, S., V. R. Harley, A. Pontiggia, P. N. Goodfellow, R. Lovell-Badge, and M. E. Bianchi. 1992. SRY, like HMG1, recognizes sharp angles in DNA. EMBO J. 11:4497-4506[Medline].

13. Fiering, S. N., M. Roederer, G. P. Nolan, D. R. Micklem, D. R. Parks, and L. A. Herzenberg. 1991. Improved FACS-Gal: flow cytometric analysis and sorting of viable eukaryotic cells expressing reporter gene constructs. Cytometry 12:291-301[Medline].

14. Giese, K., A. Amsterdam, and R. Grosschedl. 1991. DNA-binding properties of the HMG domain of the lymphoid-specific transcriptional regulator LEF-1. Genes Dev. 5:2567-2578[Abstract/Free Full Text].

15. Giese, K., and R. Grosschedl. 1993. LEF-1 contains an activation domain that stimulates transcription only in a specific context of factor-binding sites. EMBO J. 12:4667-4676[Medline].

16. Giese, K., J. Pagel, and R. Grosschedl. 1994. Distinct DNA-binding properties of the high mobility group domain of murine and human SRY sex-determining factors. Proc. Natl. Acad. Sci. USA 91:3368-3372[Abstract/Free Full Text].

17. Gubbay, J., J. Collignon, P. Koopman, B. Capel, A. Economou, A. Münsterberg, N. Vivian, P. Goodfellow, and R. Lovell-Badge. 1990. A gene mapping to the sex-determining region of the mouse Y chromosome is a member of a novel family of embryonically expressed genes. Nature 346:245-250[Medline].

18. Hargrave, M., E. Wright, J. Kun, J. Emery, L. Cooper, and P. Koopman. 1997. Expression of the Sox11 gene in mouse embryos suggests roles in neuronal maturation and epithelio-mesenchymal induction. Dev. Dyn. 210:79-86[Medline].

19. Harley, V. R., R. Lovell-Badge, and P. N. Goodfellow. 1994. Definition of a consensus DNA binding site for SRY. Nucleic Acids Res. 22:1500-1501[Free Full Text].

20. Hayashi, S., K. Goto, T. S. Okada, and H. Kondoh. 1987. Lens-specific enhancer in the third intron regulates expression of the chicken $delta$ 1-crystallin gene. Genes Dev. 1:818-828[Abstract/Free Full Text].

21. Hayashi, S., and M. P. Scott. 1990. What determines the specificity of action of Drosophila homeodomain proteins? Cell 63:883-894[Medline].

22. Kamachi, Y., and H. Kondoh. 1993. Overlapping positive and negative regulatory elements determine lens-specific activity of the $delta$ 1-crystallin enhancer. Mol. Cell. Biol. 13:5206-5215[Abstract/Free Full Text].

23. Kamachi, Y., and H. Kondoh. Unpublished data.

24. Kamachi, Y., S. Sockanathan, Q. Liu, M. Breitman, R. Lovell-Badge, and H. Kondoh. 1995. Involvement of SOX proteins in lens-specific activation of crystallin genes. EMBO J. 14:3510-3519[Medline].

25. Kamachi, Y., M. Uchikawa, J. Collignon, R. Lovell-Badge, and H. Kondoh. 1998. Involvement of Sox1, 2 and 3 in the early and subsequent molecular events of lens induction. Development 125:2521-2532[Abstract].

26. Kanai, Y., M. Kanai-Azuma, T. Noce, T. C. Saido, T. Shiroishi, Y. Hayashi, and K. Yazaki. 1996. Identification of two Sox17 messenger RNA isoforms, with and without the high mobility group box region, and their differential expression in mouse spermatogenesis. J. Cell Biol. 133:1-15[Free Full Text].

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32. Lefebvre, V., G. Zhou, K. Mukhopadhyay, C. N. Smith, Z. Zhang, H. Eberspaecher, X. Zhou, S. Sinha, S. N. Maity, and B. de Crombrugghe. 1996. An 18-base-pair sequence in the mouse pro $alpha$ 1(II) collagen gene is sufficient for expression in cartilage and binds nuclear proteins that are selectively expressed in chondrocytes. Mol. Cell. Biol. 16:4512-4523[Abstract].

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1.	Ambrosetti, D.-C., C. Basilico, and L. Dailey. 1997. Synergistic activation of the fibroblast growth factor 4 enhancer by Sox2 and Oct-3 depends on protein-protein interactions facilitated by a specific spatial arrangement of factor binding sites. Mol. Cell. Biol. 17:6321-6329[Abstract].
2.	Bell, D. M., K. K. H. Leung, S. C. Wheatley, L. J. Ng, S. Zhou, K. W. Ling, M. H. Sham, P. Koopman, P. P. L. Tam, and K. S. E. Cheah. 1997. SOX9 directly regulates the type-II collagen gene. Nat. Genet. 16:174-178[Medline].
3.	Carey, M., H. Kakidani, J. Leatherwood, F. Mostashari, and M. Ptashne. 1989. An amino-terminal fragment of GAL4 binds DNA as a dimer. J. Mol. Biol. 209:423-432[Medline].
4.	Carlsson, P., M. L. Waterman, and K. A. Jones. 1993. The hLEF-1/TCF-1 $alpha$ HMG protein contains a context-dependent transcriptional activation domain that induces the TCR $alpha$ enhancer in T cells. Genes Dev. 7:2418-2430[Abstract/Free Full Text].
5.	Chen, C., and H. Okayama. 1987. High-efficiency transformation of mammalian cells by plasmid DNA. Mol. Cell. Biol. 7:2745-2752[Abstract/Free Full Text].
6.	Collignon, J., S. Sockanathan, A. Hacker, M. Cohen-Tannoudji, D. Norris, S. Rastan, M. Stevanovic, P. N. Goodfellow, and R. Lovell-Badge. 1996. A comparison of the properties of Sox-3 with Sry and two related genes, Sox-1 and Sox-2. Development 122:509-520[Abstract].
7.	Connor, F., P. D. Cary, C. M. Read, N. S. Preston, P. C. Driscoll, P. Denny, C. Crane-Robinson, and A. Ashworth. 1994. DNA binding and bending properties of the post-meiotically expressed Sry-related protein Sox-5. Nucleic Acids Res. 22:3339-3346[Abstract/Free Full Text].
8.	Connor, F., E. Wright, P. Denny, P. Koopman, and A. Ashworth. 1995. The Sry-related HMG box-containing Sox6 is expressed in the adult testis and developing nervous system of the mouse. Nucleic Acids Res. 23:3365-3372[Abstract/Free Full Text].
9.	da Silva, S. M., A. Hacker, V. Harley, P. Goodfellow, A. Swain, and R. Lovell-Badge. 1996. Sox9 expression during gonadal development implies a conserved role for the gene in testis differentiation in mammals and birds. Nat. Genet. 14:62-68[Medline].
10.	Denny, P., S. Swift, N. Brand, N. Dabhade, P. Barton, and A. Ashworth. 1992. A conserved family of genes related to the testis determining gene, SRY. Nucleic Acids Res. 20:2887[Free Full Text].
11.	Denny, P., S. Swift, F. Connor, and A. Ashworth. 1992. An SRY-related gene expressed during spermatogenesis in the mouse encodes a sequence-specific DNA-binding protein. EMBO J. 11:3705-3712[Medline].
12.	Ferrari, S., V. R. Harley, A. Pontiggia, P. N. Goodfellow, R. Lovell-Badge, and M. E. Bianchi. 1992. SRY, like HMG1, recognizes sharp angles in DNA. EMBO J. 11:4497-4506[Medline].
13.	Fiering, S. N., M. Roederer, G. P. Nolan, D. R. Micklem, D. R. Parks, and L. A. Herzenberg. 1991. Improved FACS-Gal: flow cytometric analysis and sorting of viable eukaryotic cells expressing reporter gene constructs. Cytometry 12:291-301[Medline].
14.	Giese, K., A. Amsterdam, and R. Grosschedl. 1991. DNA-binding properties of the HMG domain of the lymphoid-specific transcriptional regulator LEF-1. Genes Dev. 5:2567-2578[Abstract/Free Full Text].
15.	Giese, K., and R. Grosschedl. 1993. LEF-1 contains an activation domain that stimulates transcription only in a specific context of factor-binding sites. EMBO J. 12:4667-4676[Medline].
16.	Giese, K., J. Pagel, and R. Grosschedl. 1994. Distinct DNA-binding properties of the high mobility group domain of murine and human SRY sex-determining factors. Proc. Natl. Acad. Sci. USA 91:3368-3372[Abstract/Free Full Text].
17.	Gubbay, J., J. Collignon, P. Koopman, B. Capel, A. Economou, A. Münsterberg, N. Vivian, P. Goodfellow, and R. Lovell-Badge. 1990. A gene mapping to the sex-determining region of the mouse Y chromosome is a member of a novel family of embryonically expressed genes. Nature 346:245-250[Medline].
18.	Hargrave, M., E. Wright, J. Kun, J. Emery, L. Cooper, and P. Koopman. 1997. Expression of the Sox11 gene in mouse embryos suggests roles in neuronal maturation and epithelio-mesenchymal induction. Dev. Dyn. 210:79-86[Medline].
19.	Harley, V. R., R. Lovell-Badge, and P. N. Goodfellow. 1994. Definition of a consensus DNA binding site for SRY. Nucleic Acids Res. 22:1500-1501[Free Full Text].
20.	Hayashi, S., K. Goto, T. S. Okada, and H. Kondoh. 1987. Lens-specific enhancer in the third intron regulates expression of the chicken $delta$ 1-crystallin gene. Genes Dev. 1:818-828[Abstract/Free Full Text].
21.	Hayashi, S., and M. P. Scott. 1990. What determines the specificity of action of Drosophila homeodomain proteins? Cell 63:883-894[Medline].
22.	Kamachi, Y., and H. Kondoh. 1993. Overlapping positive and negative regulatory elements determine lens-specific activity of the $delta$ 1-crystallin enhancer. Mol. Cell. Biol. 13:5206-5215[Abstract/Free Full Text].
23.	Kamachi, Y., and H. Kondoh. Unpublished data.
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