Abstract
Development and regeneration are orchestrated by gene regulatory networks that operate in part through transcriptional enhancers. Although many enhancers are pleiotropic and are active in multiple tissues, little is known about whether enhancer pleiotropy is due to 1) site pleiotropy, in which individual transcription factor binding sites (TFBS) are required for activity in multiple tissues, or 2) multiple distinct sites that regulate expression in different tissues. Here, we investigated the pleiotropy of an intronic enhancer of the stickleback Bone morphogenetic protein 6 (Bmp6) gene. This enhancer was previously shown to regulate evolved changes in tooth number and tooth regeneration, and is highly pleiotropic, with robust activity in both fins and teeth throughout embryonic, larval, and adult life. We tested the hypothesis that the pleiotropy of this enhancer is due to site pleiotropy of an evolutionarily conserved predicted Foxc1 TFBS. Transgenic analysis and site-directed mutagenesis experiments both deleting and scrambling this predicted Foxc1 TFBS revealed that the binding site is required for enhancer activity in both teeth and fins throughout embryonic, larval, and adult development. Collectively these data support a model where the pleiotropy of this Bmp6 enhancer is due to site pleiotropy and this putative binding site is required for enhancer activity in multiple anatomical sites from the embryo to the adult.
Introduction
Eukaryotic gene expression is governed by enhancers, non-coding cis-regulatory elements that positively regulate transcription. Enhancers bind transcription factors that promote cell-type-specific gene expression programs throughout development and drive transcription in response to stimuli (Levine et al., 2014). Decades of genetic studies have revealed that most human disease phenotypes (Farh et al., 2015; Maurano et al., 2012), and much of natural phenotypic variation in animals are associated with sequence changes in non-coding DNA (Rebeiz & Tsiantis, 2017). These findings suggest that enhancers play a critical role in both evolution and disease, thereby motivating further study of basic enhancer biology.
Many enhancers are known to function in multiple distinct tissues, suggesting that these elements are pleiotropic. A study on chromatin from a subset of human tissues found that at least 1% of identified cis-regulatory elements were active in at least two spatially distinct domains (Singh & Yi, 2021). In vivo studies in fish and mice have additionally identified enhancer sequences that drive gene expression in more than one tissue type (Cleves et al., 2018; Erickson et al., 2015; Jackman & Stock, 2006; Jumlongras et al., 2012; Stepaniak et al., 2021). Two different described mechanisms of enhancer pleiotropy are (1) tightly clustered, but different, transcription factor binding sites (TFBS) that drive expression in different tissues and (2) site pleiotropy, where a single TFBS drives expression in multiple tissues (Preger-Ben Noon et al., 2018). These two mechanisms of enhancer pleiotropy have different implications for evolution; site pleiotropy would constrain evolution to preserve the integrity of critical regulatory sequences, as a single mutation in the TFBS could have a significant impact on gene expression in multiple tissues (Boffelli et al., 2004; Fish et al., 2017; Infante et al., 2015; Sabarís et al., 2019). In contrast, tightly clustered TFBS could allow for more modular evolution of gene expression in different tissues or at different developmental stages.
Threespine stickleback fish (Gasterosteus aculeatus) are a powerful system to study enhancer biology, as abundant natural variation throughout their adaptive radiation occurs largely due to non-coding variation, pointing to the importance of enhancers in phenotypic evolution (Jones et al., 2012). For example, changes in tooth number have evolved repeatedly in sticklebacks, with derived freshwater populations having increases in tooth number and tooth regeneration rates relative to ancestral marine populations (Cleves et al., 2014; Ellis et al., 2015). Quantitative trait loci mapping revealed a large effect locus that contains the gene Bone Morphogenetic Protein 6 (Bmp6), which is dynamically expressed in both epithelial and mesenchymal cells within developing teeth (Cleves et al., 2014). Further high-resolution genetic mapping of this large effect locus linked the evolved phenotypic effects to an enhancer in the fourth intron of Bmp6 (Cleves et al., 2018). This intronic enhancer is highly pleiotropic and drives expression in all developing and regenerating teeth, as well as the distal edges of the pectoral, median, and caudal fins (Cleves et al., 2018). Comparing the marine and freshwater versions of this intronic enhancer in doubly transgenic lines revealed evolved spatial shifts in enhancer activity in both tooth epithelium and mesenchyme, consistent with an evolved change in enhancer activity driving phenotypic evolution of tooth number (Stepaniak et al., 2021). In addition, although both enhancers drive strong expression in the distal edges of embryonic fins, only the freshwater enhancer was detected in fin ray joints in pectoral and caudal fins (Stepaniak et al., 2021). However, whether the enhancer utilizes common inputs for tooth and fin activity, and which sites are required for this activity are unknown.
Previous studies have found that fish teeth and mammalian hair share many aspects of early development: both are derived from placodes (Pispa & Thesleff, 2003), continuously regenerate in adults, are regulated by BMP signaling during replacement (Jia et al., 2013; Vainio et al., 1993; Wang et al., 2012), and express similar batteries of genes during regeneration (Square et al., 2021). In mice, BMP signaling has been proposed as a major regulator of maintaining stem cell quiescence. Conditional ablation of the Bmpr1a gene in skin epithelium activated the stem cell niche, causing quiescent hair follicle stem cells to proliferate (Kandyba et al., 2013; Kobielak et al., 2007). Further, Foxc1 regulates Bmp6 expression in regenerating hair. Foxc1 binds to a regulatory region adjacent to Bmp6 in mice and inhibits hair regeneration, as conditional knockout of Foxc1 in skin results in accelerated hair regeneration (Wang et al., 2016). Moreover, Foxc1 was proposed to be a candidate regulator of the Bmp6 intron 4 enhancer, as a putative Foxc1 TFBS was identified within this enhancer (Cleves et al., 2018). Given that this enhancer is expressed in regenerating teeth, has been linked to evolved changes in tooth regeneration, and the similarities between hair and tooth regeneration, a parsimonious model is that BMP signaling negatively regulates mammalian hair and fish tooth regeneration using homologous gene regulatory networks. Here we test the hypotheses that (1) a predicted Foxc1 TFBS is required for Bmp6 enhancer activity in developing and regenerating teeth and (2) this predicted Foxc1 TFBS has site pleiotropy and is required for enhancer activity in teeth and fins.
Methods
Animal husbandry
All animal work was approved by UC Berkeley IACUC protocol AUP-2015–01-7117. Sticklebacks were raised as previously described (Cleves et al., 2014; Square et al., 2021). All experiments used lab-reared marine (Rabbit Slough, Alaska) sticklebacks.
Generation of transgenic GFP enhancer stickleback lines
Tol2 plasmid transgenesis was performed using pT2HE plasmid backbone as previously described (Erickson et al., 2016; O’brown et al., 2015). To generate GFP reporter constructs, PCR-based site-directed mutagenesis was done on plasmids containing the ∼1300 bp Paxton benthic (PAXB) high-tooth-associated intron four enhancer allele (Cleves et al., 2018; Stepaniak et al., 2021). Primers for site-directed mutagenesis were designed using the Quickchange tool and PCR was carried out according to Erickson et al. (Erickson et al., 2015) https://www.agilent.com/store/primerDesignProgram.jsp. Primer sequences used for the deleted were CTAATTACCCCGACGAGGTCGGGTGGGGAG and CTCCCCACCCGACCTCGTCGGGGTAATTAG and for the scrambled CCCCACCCGACCTTTTGAATACCGTCGGGGTAATTA and TAATTACCCCGACGGTATTCAAAAGGTCGGGTGGGG. Transposase messenger RNA was synthesized as described previously (Kawakami & Shima, 1999). Stickleback embryos at the one-cell stage were microinjected as described (Erickson et al., 2016). Two stable transgenic lines were generated with each of the intact, scrambled, and deleted reporter constructs.
Imaging fluorescent transgenic sticklebacks
Transgenic GFP reporter lines were imaged using a Leica M165FC stereoscope with a DFC340 FX camera. Transgenic embryos were imaged live. Transgenic juvenile and adult fish were fixed in 4% paraformaldehyde for 4 hours for 9-19 mm standard length (SL) or overnight (>20mm SL). Teeth were imaged using Montage z-stack projections on a Leica M165FC dissecting microscope with a GFP2 filter.
Bioinformatics
The following genome assemblies were used to compare Bmp6 sequences: stickleback Gasterosteus aculeatus, “Gac”: Broad/gasAcu, medaka Oryzias latipes, “Ola”: NIG/UT MEDAKA1/oryLat2, zebrafish Danio rerio, “Dre”: GRCz10/danRer10, gar Lepisosteus oculatus “Loc”: LepOcu1 (GCA_000242695.1). A ∼25 kb window centered on stickleback Bmp6 was aligned to orthologous sequences from these three other species using mVISTA and LAGAN at https://genome.lbl.gov/vista/index.shtml (Frazer et al., 2004) using default visualization parameters of 100 bp windows showing minimum y-axis of 50% and 70% sequence identity to color windows as conserved. The entire fourth intron sequence from all four species was aligned as above, and the first 5.5 kb of the ∼6.5 kb intron shown in Figure 2C. Sequences orthologous to the minimally sufficient ∼500 bp Bmp6 intron 4 enhancer (Cleves et al., 2018) were aligned using Clustal Omega at https://www.ebi.ac.uk/Tools/msa/clustalo/ (Sievers et al., 2011) and default parameters. The resulting text alignment was opened in MS Word and conserved bases in all four species highlighted manually.
In situ hybridizations on sections
Sample preparation, sectioning, in situ hybridization, and riboprobe synthesis were carried out as previously described (Square et al., 2021). Riboprobes were designed as described previously (Ellis et al., 2016) against Foxc1a and Foxc1b. Riboprobe template plasmids were created by PCR cloning gene fragments from genomic DNA using primers to Foxc1a: 5’-GCCGctcgagGGGACAGGTCTAGCCACTTG-3’; 5’-GCCGtctagaACGGCGATA-TACACGTTCCT-’3 and Foxc1b: 5’-GCCGctcgagCCTGCCCGACTATTGCATCA-3’; 5’-GCCGactagtAGACGGCAC-TTTATTAAACAAACA-3’.
Results
Previous research mapped evolved increases in tooth number in freshwater sticklebacks to an enhancer located in the fourth intron of Bmp6 (Cleves et al., 2014, 2018). This enhancer drives robust expression in all developing pharyngeal and oral teeth, as well as in the distal margins of the pectoral and median fins (Fig. 1A,B) (Cleves et al., 2018; Stepaniak et al., 2021). The sequence of this intronic enhancer is evolutionarily conserved in teleosts, with clear homology detectable in medaka and zebrafish, as well as to gar, an outgroup to teleosts (Fig. 1C,D). Comparison of enhancer sequences within fish and outgroups suggests different levels of constraint within this enhancer, possibly representing functionally required TFBSs. Of those regions with 100% sequence conservation across the aforementioned fish species, one includes a nine base pair motif TTTGTTTAC that perfectly matches the binding site consensus previously reported for human FOXC1 (Fig. 1D, Fig. S1) (Berry et al., 2008).
Teleosts underwent a whole genome duplication (Amores et al., 1998), resulting in pairs of co-orthologs of many teleost genes relative to outgroups. In sticklebacks, both Foxc1a and Foxc1b have been maintained. Expression of both Foxc1 genes was detected in developing adult teeth, with Foxc1a largely restricted to the dental mesenchyme (Fig. 1E), and Foxc1b distributed throughout the inner and outer dental epithelium (Fig. 1F). Thus, Foxc1 gene expression overlaps with activity of the Bmp6 intronic enhancer in teeth (Stepaniak et al., 2021).
To test the hypothesis that the predicted Foxc1 TFBS is required for enhancer activity, we introduced mutations in a Bmp6 reporter construct previously described (Cleves et al., 2018; Stepaniak et al., 2021). The unaltered construct drove GFP expression in several tissues including the pectoral and median fins, and oral and pharyngeal teeth. Site directed mutagenesis was used to make two mutant enhancer variants: (1) a scrambled enhancer, where two thymidine nucleotides in the predicted Foxc1 TFBS were mutated to adenine, and (2) a deleted enhancer, where the entire nine base pair Foxc1 predicted TFBS was deleted (Fig. 2A). We generated two stable transgenic lines each for three different enhancer transgenes: intact wild-type, scrambled, and deleted (Fig. 2A). For all three genotypes, we imaged transgenic larvae, juveniles, and adults to test for possible effects on enhancer activity in different tissues. All scrambled and deleted transgenes dramatically reduced GFP expression in the pectoral and median fins of the developing embryo (Fig. 2B).
While the stable transgenic reporter lines containing the intact binding site drove robust expression in every detectable tooth in the pharyngeal and oral jaw, neither the scrambled nor deleted reporter lines drove detectable GFP expression in pharyngeal teeth (Fig. 3). As a control, GFP lens expression driven by the hsp70l promoter (Erickson et al., 2015) was comparably bright in the intact, scrambled, and deleted transgenic lines (Fig. 3A). Within developing primary oral and pharyngeal teeth, transgene GFP expression was observed in the dental epithelium and mesenchyme for the intact enhancer, but in neither epithelium nor mesenchyme for the scrambled or deleted enhancer in pharyngeal teeth (Fig. 3). GFP expression was also seen in the epithelium and mesenchyme of adult teeth for the intact enhancer. Faint GFP expression was detected in some oral teeth in the premaxilla at adult stages for the scrambled enhancer (Fig 3C). Overall, adult tooth expression was largely abolished in the scrambled and deleted enhancer reporter lines, suggesting that the predicted Foxc1 TFBS is required for enhancer activity in replacement as well as primary teeth (Fig. 3).
Additionally, we found that the predicted Foxc1 TFBS is required for enhancer function in fins at all developmental time points examined, including in the intersegmental joints of the juvenile and adult pectoral and caudal fins. All fin domains were nearly abolished in both the scrambled and deleted reporter lines at all developmental stages (Fig. 4). GFP expression was detected in rare intersegmental joints of the pectoral fins in juveniles for the scrambled enhancer, and in the base of the pectoral fin rays for both the scrambled and deleted construct (Fig. 4A). Some GFP expression persisted in the caudal peduncle for the deleted enhancer (Fig. 4B). In general, all sites of fin expression, like tooth expression, were severely reduced in both the scrambled and deleted enhancer lines relative to the intact enhancer lines. These data support a crucial role for this single putative Foxc1 binding site in positively regulating both tooth and fin expression across development from embryos to adults.
Discussion
A short, conserved, pleiotropic binding site is required for enhancer activity in teeth and fins
Here we show a predicted Foxc1 TFBS is required for Bmp6 intron four enhancer activity in teeth and fins at all stages examined of stickleback development. Altering the predicted Foxc1 TFBS by scrambling two nucleotides or deleting nine nucleotides via site-directed mutagenesis severely downregulated enhancer activity in both teeth and fins, suggesting that this predicted TFBS is critical for enhancer function in multiple expression domains. This site pleiotropy is reminiscent of a previously described enhancer 5’ to the stickleback Bmp6 gene, where a conserved predicted SMAD3 binding site is required for enhancer activity in teeth and fins (Erickson et al., 2015). While both marine and freshwater intron four Bmp6 enhancers drive strong expression in the distal edges of embryonic fins, only the freshwater enhancer was detected in intersegmental joints in pectoral and caudal fins (Stepaniak et al., 2021). The intact enhancer tested here was the freshwater allele and drove robust fin ray joints as previously reported. Both early distal fin fold and later fin joint expression domains driven by the intact enhancer were largely absent in the scrambled and deleted Foxc1 TFBS reporter lines.
Enhancers have displayed both site pleiotropy and tightly linked binding sites driving expression in different tissues at different developmental stages. A study investigating the shavenbaby enhancers in Drosophila found that while one enhancer used the same TFBS to regulate embryonic and pupal expression (site pleiotropy), another enhancer required distinct tightly linked binding sites for expression in different tissues (Preger-Ben Noon et al., 2018). While we hypothesize that this predicted TFBS studied here is bound by Foxc1, it may serve as a binding site for other Fox or non-Fox transcription factors with similar binding site affinity. It is possible that in generating scrambled or deleted TFBSs, one or more new TFBS were generated. However, it would be unlikely that both deleted and scrambled nucleotides would create the same TFBS, given the different primary sequence of these two mutations. Once stickleback Foxc1 antibodies are available, biochemical experiments could test whether stickleback Foxc1a and/or Foxc1b binds this predicted TFBS. Genetic experiments, crossing this enhancer into Foxc1a and Foxc1b single and double mutants could directly test whether either or both of these duplicate Foxc1 genes regulate this pleiotropic enhancer.
Roles for Foxc1 in BMP regulation
Previous studies have revealed Foxc1 as a molecular switch for regulating regeneration in mouse hair follicles. As a transcription factor, Foxc1 activates BMP signaling in self-renewing hair follicle stem cells (HFSCs) (Wang et al., 2016). The conditional knockout of Foxc1 in mouse results in reduced quiescence in HFSCs and an increase in hair regeneration rates. RNA sequencing (RNA-Seq) and quantitative polymerase chain reaction (qPCR) revealed that genes associated with quiescence of HFSCs, like Bmp6, were down-regulated. The direct regulation of Bmp6 by Foxc1 was supported by chromatin immunoprecipitation PCR (Wang et al., 2016). Here we suggest Foxc1 regulates the BMP pathway for tooth, and possibly fin, development and regeneration through this TFBS in Bmp6. Future experiments analyzing the phenotypic effects of Foxc1a and Foxc1b single and double mutants could shed light on the role that these stickleback Foxc1 co-orthologs play in maintaining quiescence and organ development and regeneration through the BMP pathway.
Foxc1 in organogenesis and chromatin remodeling
Previous studies of enhancer evolution have suggested that enhancers are born as “proto-enhancers” with an initial low-information content but containing a TFBS that serves as a nucleation point around which other TFBSs then evolve (Emera et al., 2016). The winged-helix structure of the forkhead DNA-binding domain, which is highly conserved across all members of the Fox family, resembles the structure of the linker histone H1, a key modulator of chromatin structure. Because of its structure and chromatin binding interactions, FoxA proteins have been proposed to act as pioneer transcription factors, opening compacted chromatin to allow the binding of other transcription factors (Cirillo et al., 2002; Lee et al., 2005). Foxd3 has been shown to act as a pioneer factor by re-arranging the chromatin landscape and opening cis-regulatory elements to maintain multipotency in the early neural crest lineage (Lukoseviciute et al., 2018). Together, these studies suggest Fox family transcription factors promote chromatin accessibility within promoter and enhancer regions.
The loss of Foxc1 co-orthologs (foxc1a and foxc1b) in zebrafish results in severe reductions of upper facial cartilages as well as missing trabecular cartilage of the neurocranium. The zebrafish foxc1a−/− mutants died by 7 dpf, and displayed facial cartilage defects and foxc1b−/− mutants displayed a truncation in the symplectic cartilage (Xu et al., 2018). In double homozygous foxc1a; foxc1b mutants, severe reductions of upper facial cartilages occurred, suggesting that Foxc1a and Foxc1b act redundantly in upper facial cartilage development (Xu et al., 2018). In zebrafish embryos doubly homozygous foxc1a and foxc1b mutations, the cartilaginous skeleton did not form properly, likely because many of the regulatory sequences in cartilage regulatory genes were not accessible (Xu et al., 2021). These results support a model in which zebrafish Foxc1 proteins serve as pioneer transcription factors to open chromatin, making it accessible for other transcription factors to bind and regulate genomic regions responsible for cartilage development. It is possible that stickleback Foxc1 proteins may serve similar roles by opening chromatin regions specific to tooth and fin enhancers so other transcription factors can regulate development or regeneration. Future experiments analyzing the genetic effects of Foxc1a and Foxc1b single and double null-mutants could elucidate the role of the Foxc1 co-orthologs in sticklebacks, and test whether they serve as pioneer transcription factors to promote chromatin accessibility.
Supplemental Figure
Funding
This work was supported by the National Institutes of Health (DE021475 and DE027871).
Acknowledgements
We thank Mark Stepaniak and Josh Tworig for assistance and advice on developing and injecting transgenic constructs, and Sophie Archambeault, Naama Weksler, and Hernan Garcia for suggestions on the manuscript.