Significance
Extant vertebrates include jawless and jawed species. Jawless vertebrates, such as lamprey and hagfish, do not possess paired fins, whereas jawed vertebrates have two pairs of appendages. Although paired appendages are important in performing complex movements, including swimming, burrowing, and flying, their evolutionary origin remains elusive. In this study, we compare jawless and jawed vertebrate embryos and identify fundamental differences in the expression and regulation of a gene that is essential for the pectoral fin and girdle formation. Our data suggest that modification of the expression and regulation of this gene is coincident with the origin of paired appendages.
Keywords: paired fins, evolution, development, Tbx5 enhancer
Abstract
The diversification of paired appendages has been a major factor in the evolutionary radiation of vertebrates. Despite its importance, an understanding of the origin of paired appendages has remained elusive. To address this problem, we focused on T-box transcription factor 5 (Tbx5), a gene indispensable for pectoral appendage initiation and development. Comparison of gene expression in jawless and jawed vertebrates reveals that the Tbx5 expression in jawed vertebrates is derived in having an expression domain that extends caudal to the heart and gills. Chromatin profiling, phylogenetic footprinting, and functional assays enabled the identification of a Tbx5 fin enhancer associated with this apomorphic pattern of expression. Comparative functional analysis of reporter constructs reveals that this enhancer activity is evolutionarily conserved among jawed vertebrates and is able to rescue the finless phenotype of tbx5a mutant zebrafish. Taking paleontological evidence of early vertebrates into account, our results suggest that the gain of apomorphic patterns of Tbx5 expression and regulation likely contributed to the morphological transition from a finless to finned condition at the base of the vertebrate lineage.
Paired appendages are one of the fundamental novelties of vertebrates. Having emerged in Paleozoic taxa, they have been associated with major patterns of phylogenetic, ecological, and functional diversification ever since. An understanding of the origin of paired appendages is a problem that links multiple approaches—from paleontology to genomics (1–7). The main challenge to progress in the field derives from understanding the similarities and differences between taxa with and without paired fins: How did the mechanisms that pattern paired appendages arise from taxa that lack them altogether?
Whereas jawed vertebrates have two sets of paired fins—pectoral and pelvic—their outgroups, jawless vertebrates, have a range of conditions. Extant jawless fish such as the lamprey and hagfish do not have any paired appendages. The fossil record, however, reveals extinct jawless fish that have pectoral appendages but lack pelvic ones (8). The phylogenetic distribution of extant and extinct species supports the notion that pectoral fins arose before the pelvics (7–12). Therefore, an understanding of pectoral fin development looms large in analyses of the origin of paired appendages.
Tbx5, and its homolog in jawless fish, Tbx4/5, have emerged as attractive candidates to explore the origin of pectoral fins. Phylogenetic analysis reveals that Tbx4/5 of an ancestral jawless vertebrate split into two functional paralogs in species with paired appendages, Tbx4 and Tbx5. These paralogs are involved in the initiation of the pectoral and pelvic appendages, respectively (6, 13–17). Of particular interest is Tbx5 because of its role in pectoral fin development (16–22). The expression pattern of Tbx5 has been studied in multiple chordate species, including amphioxus Tbx4/5. However, data on the expression of Tbx4/5 is sparse in jawless vertebrates (13–16, 18, 23, 24), and detailed comparative expression analysis in taxa with and without paired appendages is lacking. Moreover, whereas it has been hypothesized that cis-regulatory changes of Tbx5 have played an important role in pectoral fin evolution, an understanding of Tbx5 regulation is limited to amniotes and, therefore, lacking in more basal outgroups (15, 24–28).
Here, we performed embryological and genomic analyses of Tbx5 and Tbx4/5 in vertebrates lacking paired fins as well as diverse finned and limbed vertebrates. First, we assessed lamprey Tbx4/5 expression and compared it with that of vertebrates with paired appendages. Subsequently, we explored Tbx5 enhancer activity through a combination of phylogenetic footprinting, functional genomics, and transgenic reporters in zebrafish. Our data reveal phylogenetic patterns of Tbx5 expression and regulation that provide a window into the origin of mechanisms that pattern paired appendages.
Results
To compare Tbx5 expression in jawless and jawed vertebrates, we cloned sea lamprey Tbx4/5, skate Tbx5, and zebrafish tbx5a and performed whole-mount in situ hybridization. The phylogenetic relationship of sea lamprey Tbx4/5 and skate Tbx5 was confirmed by using the maximum-likelihood method (Fig. S1). In skate and zebrafish embryos, Tbx5 was expressed in the dorsal portion of the eye, heart, and LPM (lateral plate mesoderm) of the pectoral fin field (Fig. 1 A and C). In embryos of skate and zebrafish, expression in the heart and pectoral fin formed a continuous domain as in tetrapods (Fig. 1 A and C) (16, 18, 23). In sea lamprey, Tbx4/5 expression was found in the heart (Fig. 1E and Fig. S2) (24) but, lacking molecular markers, it is difficult to compare the posterior border of expression with jawed vertebrates. To delineate the posterior limit of the heart field, we isolated Flt (fms-like tyrosine kinase/vascular endothelial growth factor receptor) and observed its expression (Fig. 1 B, D, and F and Figs. S1 and S2). Flt is a marker of angioblasts and prefigures the formation of blood vessels. Flt4 and Flt1/4 genes marked anterior and posterior cardinal veins (acv and pcv), which extended in both rostral and caudal directions in the embryos. These two veins were confluent and continued vertically toward the common cardinal vein (ccv, also known as ductus Cuvieri), posterior to the gills. The vein ran further ventrally, bifurcated the hepatocardiac vein, and reached to the posterior extremity of the heart (Fig. 1 B, D, F, and G and Fig. S2). This circulatory pattern, and its topological relationships with surrounding structures, is conserved in vertebrates (5, 29). When the patterns of Tbx5 and Flt4 expression were compared by using these morphological landmarks, we found that the Tbx5 domain included the dorsal part of eye, heart, ccv, and LPM posterior to this vein in jawed vertebrates. In contrast, the Tbx4/5 domain resides exclusively in the heart in sea lamprey with no posterior extension (Fig. 1 and Figs. S2 and S3). Because Tbx5 expression posterior to the heart and gills is limited to jawed vertebrates and Tbx5 is essential for pectoral fin/limb development (16–22), these results imply that the expansion of Tbx5 expression in the LPM posterior to the heart might be associated with the evolution of pectoral fins.
The regulation of Tbx5 in limbs has been explored in mouse, revealing one forelimb enhancer in the second intron (Tbx5 intron2) and its regulation by Hox genes (15, 25, 30). To assess the phylogenetic diversity of Tbx5 regulation by this enhancer, we first analyzed the evolutionary conservation of Tbx5 intron2 activity. By comparing vertebrate genomic sequences adjacent to the Tbx5 locus, we found that Tbx5 intron2 was conserved in mammals, but not in other vertebrates (Fig. S4 A–C). Because enhancers can retain function without displaying sequence similarity (31), the regulatory potential of Tbx5 intron2 from skate, gar, and zebrafish was tested in transgenic zebrafish. Several independent stable lines were established in zebrafish, but none could recapitulate the endogenous expression pattern of Tbx5 (five lines with skate sequence, three lines with gar sequence, and seven lines with zebrafish sequence) (Fig. S4 D–I). Enhancers can change their position in the genome (32, 33), and if zebrafish retains a Tbx5 intron2-like enhancer somewhere else in the genome along with the similar trans environment to mouse, transgenic zebrafish carrying mouse Tbx5 intron2 could express GFP in the pectoral fin. To test this possibility, we assayed mouse Tbx5 intron2 activity in transgenic zebrafish. Six stable lines were established, but conspicuous GFP signal was never detected in the pectoral fin (Fig. S4 J and K). Altogether, these results do not support the notion that Tbx5 intron2 and its regulation are evolutionarily conserved.
Next, we assayed for Tbx5 fin-specific enhancers. We used recently published ATAC-seq (Assay for Transposase-Accessible Chromatin) data from whole zebrafish embryos at 24 h after fertilization (hpf) to assess open chromatin regions as sites of putative enhancers (34). In addition, we inspected predicted CTCF (CCCTC-binding factor) sites in the open chromatin regions (35). Because these sites are involved in the formation of chromatin loops, we prioritized open chromatin regions without CTCF sites. Using these criteria, more than 30 open chromatin regions were detected within a 120-kb genome sequence between tbx3a and pax8, two flanking genes of tbx5a in the zebrafish genome (Fig. 2A and Fig. S5). Subsequently, we assessed sequence conservation of diverse vertebrate species to reveal CNSs (conserved noncoding sequences) around the Tbx5 locus (Fig. 2B and Fig. S5). This approach revealed more than 30 CNSs. The intersection of these two criteria (open chromatin regions and CNSs) winnowed the pool to 10 candidate enhancer regions to assay by using functional tests in transgenic reporter constructs. The gar genome was used to engineer these constructs because it is more similar to the tetrapod genome than zebrafish one, being basal to the teleost-specific whole genome duplication (34, 36). Gar DNA fragments were integrated into the GFP reporter vector and injected into zebrafish eggs to establish stable transgenic lines (Fig. S6). With these lines, we identified CNS12, a 3,108-bp sequence located downstream of the Tbx5 coding region, as a fin enhancer. CNS12 drove GFP expression in the dorsal part of eye and pectoral fin (Figs. 2 and 3, three independent transgenic stable lines), in a spatial pattern identical to that of Tbx5 ortholog in jawed vertebrates. Importantly, GFP signals in the LPM driven by the enhancer reside posterior to the heart and gills in the same apomorphic pattern detected in jawed vertebrates (Figs. 1 and 3 and Figs. S3 and S7) (16, 18, 23).
Phylogenetic footprinting revealed a highly conserved domain within CNS12, an ∼200-bp sequence, which was named CNS12sh (CNS12 short) (Fig. 2). To test the evolutionary conservation of CNS12 activity, we isolated orthologous sequences of CNS12sh from gar, zebrafish, and mouse, and assayed their activity in transgenic zebrafish. Analysis of stable lines revealed that all three CNS12sh drove GFP expression in the pectoral fin bud (four lines with gar sequence, two lines with zebrafish sequence, and nine lines with mouse sequence) (Fig. 4). GFP expression in the dorsal part of eye was not detected in these lines. We also cloned a DNA fragment from the Japanese lamprey genome, which was aligned to CNS12 of jawed vertebrates in mVISTA analyses (Fig. 2B and Fig. S8), and tested its activity in transgenic zebrafish. Four transgenic stable lines were established, but GFP expression was undetectable in the pectoral fin (Fig. 4). These results indicate that the function of CNS12 is conserved only among jawed vertebrates.
If Tbx5 regulation by CNS12 is associated with pectoral fin initiation, then CNS12 driving Tbx5 expression posterior to the heart and gills should be sufficient to induce pectoral fin development (28). To test this possibility, we used a zebrafish tbx5a mutant, heartstrings (hst), that has an aberrant heart and does not develop a pectoral fin (Fig. 5 A–D) (19). The hst mutation is a premature stop codon in tbx5a exon8, and tbx5a is weakly expressed in the LPM of hst embryos until 32 hpf, but undetectable thereafter (19). We performed injections of a vector carrying two copies of gar CNS12sh and the zebrafish tbx5a coding sequence into hst embryos and assayed development through 3 dpf (Fig. S9). The injected homozygous hst embryos were screened for heart morphology and genotyped by the sequence of tbx5a exon8. Although the heart morphology of hst was not rescued, a number of injected homozygous embryos revealed pectoral fin buds in the region where fin buds appear in the wild-type (n = 22/163) (Fig. 5 E and F). When we injected a control vector, which contains the zebrafish tbx5a coding sequence but lacks the cis-regulatory element (Fig. S9), the injected hst embryos did not develop a pectoral fin (n = 0/52) (Fig. 5 G and H). fgf8a and fgf10a, markers for apical ectodermal ridge and fin mesenchyme, respectively, were expressed in the rescued fin buds in a manner similar to the wild-type (Fig. 5 I, J, L, and M) (37). We further detected col2a1a expression at the base of the rescued fin, indicating that aspects of pectoral girdle development were also restored by the expression construct (Fig. 5 K and N). To test phylogenetic conservation of CNS12sh function, we engineered a construct with two copies of mouse CNS12sh and the zebrafish tbx5a coding sequence, and injected it into hst mutant. We found fin buds in a subset of the injected hst embryos (n = 16/175). In these rescue experiments, fin buds appeared variable in size and laterality, likely due to the mosaicism of injected embryos (Fig. 5 and Fig. S9, seven bilateral and 15 unilateral rescued fins in gar CNS12sh and five bilateral and 11 unilateral rescued fins in mouse CNS12sh). These results indicate that CNS12 driving tbx5a is able to partially rescue the phenotype of hst that lacks a pectoral fin and girdle (Fig. 5 and Fig. S9). Moreover, this ability is conserved between fish and mouse.
Discussion
Epigenetic, comparative, and functional genomic analyses led to the identification of a Tbx5 fin enhancer, CNS12, in the noncoding region downstream of Tbx5 locus (Figs. 2 and 3). This enhancer drove reporter gene expression in the LPM posterior to the heart, where vertebrates with pectoral appendages exhibit an apomorphic pattern of Tbx5 expression (Figs. 1–3). Importantly, sequence conservation of CNS12 was detected among jawed vertebrates, while remaining undetectable adjacent to the Japanese lamprey Tbx4/5 locus (Fig. 2B and Fig. S8). Indeed, we confirmed the evolutionary conservation of CNS12 activity only among jawed vertebrates (Figs. 2, 4, and 5). Comparative genomic analyses of the noncoding sequence downstream of jawed vertebrate Tbx5 and Japanese lamprey Tbx4/5 repeatedly aligned the same sequence of the Japanese lamprey genome with CNS12, but this lamprey sequence did not show any activity in pectoral fins of transgenic zebrafish (Fig. 4).
In this context, Tbx4/5 expression in amphioxus (Branchiostoma floridae BfTbx4/5 and Branchiostoma lanceolatum BlTbx4/5) becomes phylogenetically relevant. BfTbx4/5 expression was originally described in the caudoventral part of the amphioxus body and was compared with Tbx5 expression in the heart and LPM of jawed vertebrates (14, 15). However, reexamination of these patterns revealed that BlTbx4/5 is expressed in the pharyngeal and posterior mesoderm together with cardiac genes. This broad expression, and its association with cardiac markers, suggests that amphioxus Tbx4/5 is involved in the development of a noncentralized heart (38). Consistent with this observation, marker genes for vertebrate head and trunk mesoderm are expressed in overlapping domains in amphioxus dorsal mesoderm indicating that, in contrast to vertebrates, the mesodermal components of amphioxus are not differentiated along the craniocaudal axis (39). Together with our comparative assays, these findings support the hypothesis that expansion of Tbx5 expression in the LPM of the prospective pectoral domain is an apomorphic feature of jawed vertebrates and is not directly comparable to Tbx4/5 expression of amphioxus.
Given the function of Tbx5 and its regulatory element in pectoral fin development (16–22, 28) (Fig. 5), the gain of a Tbx5 expression domain controlled by CNS12 was likely an important step in the acquisition of vertebrate paired appendages. Analysis of Paleozoic osteostracans, armored jawless fish from the Silurian and Devonian, may reveal phylogenetic nodes at which this developmental mechanism arose. Osteostracans have head shields containing a canal for a lateral head vein, which passes along the lateral side of the semicircular canals, and another for a marginal vein, that runs ventrolaterally to the lateral head vein (Fig. S10). Ventromedial to the canals, an ossified pericardial capsule lies posterior to the gill region in osteostracans. Based on the topographic relationships of this capsule and the canals, the common cardinal vein is inferred to reside in the caudal part of the head shield in osteostracans (Fig. S10) (12, 40, 41). Importantly, osteostracans have a pectoral girdle, and portions of the fin skeleton, lying caudally to the heart, gills, and the inferred position of the ccv, a condition much like jawed vertebrates (7–12, 40, 42–45). These observations support the hypothesis that Tbx5 expression and regulation caudal to the heart and gills, characteristic of jawed vertebrates, may have had its origins in Paleozoic jawless taxa.
Materials and Methods
Embryos, Cloning, and in Situ Hybridization.
The protocol for animal experiments was approved by the University of Chicago Institutional Animal Care and Use Committee. Sea lamprey embryos were sampled in the Bronner laboratory at the California Institute of Technology and staged as described (46). Skate embryos were purchased from the Marine Biological Laboratory and staged as described (47). Zebrafish embryos (strain *AB) were obtained from natural mating and staged as described (48). Sea lamprey, skate, and zebrafish embryos were fixed in MEMFA (MOPS, EGTA, magnesium sulfate salts, and formaldehyde) fixative. Total RNAs of these animals were extracted from whole embryos with TRIzol Reagent (Life Technologies) and then used to synthesize cDNAs with SuperScript III system (Thermo Fisher Scientific). DNA fragments were amplified by GoTaq (Promega) and cloned into pCRII-TOPO vector (Invitrogen). RNA probes were synthesized by using SP6 or T7 RNA polymerase (Promega). The accession numbers of cloned genes and all primer sequences used in this study were listed in Tables S1 and S2. In situ hybridization was performed as described (49), with modification of the hybridization solution (5× SSC, pH 4.5, and 50 μg/mL heparin, instead of salt solution and dextran sulfate). The initial stage showing Flt4 (Flt1/4) expression in the common cardinal vein of sea lamprey, skate, and zebrafish embryos was used for the comparison. Embryos were postfixed in MEMFA fixative, washed in TE buffer, and photographed on a Leica M205FA microscope.
Table S1.
Table S2.
Gene/position | Forward | Reverse |
Primers for cloning | ||
P. marinus Tbx4/5 | TAYAARTTYGCNGAYAAYAA | CCYTTNGCRAANGGRTTRTTYTC |
AARTTYGCNGAYAAYAARTGG | RAANCCYTTNGCRAANGGRTT | |
CGCGGCTGGTACTTGTGCATCGAG | ||
GCGAGTCGGGGTGCACGTAGAG | ||
Primers for probe synthesis | ||
L. erinacea Tbx5 | GGGGAGGTTGTACGTTCACCCAGAT | GGGCTGGTGAGAAACTGAGGTCTGA |
L. erinacea Flt4 | CGGGACTTCTGGACAATCTCACCGA | TACTCCACGATCACCATCAGCGGAC |
Danio rerio tbx5a (AF179407) | CGGTAGACATCGTACAGGCCTCTCC | ACGGCTTCTTATAGGGGTGTTCTCCTG |
D. rerio flt4 (NM_130945) | TGCAATGTCAAGCGAGTGAACCCAG | CAATCTGGATGCCGGGGTATGGAGA |
D. rerio tpma (NM_131105) | CGCCTTGGACAGAGCAGAGCAG | AGTGCGATGGAGAAAAGCGGCA |
D. rerio fgf8a (NM_131281) | TCCTTCACCTCTTTGCGTTT | CACATCCTGTGCTTCGCTTA |
D. rerio fgf10a (NM_182870) | ACCAACTCCTCATCGTCTGC | CAATGTCCGATTCCTCTCGT |
D. rerio col2a1a (NM_131292) | GGTGATCGTGGTGAGATTGGTGCAC | CCTCTGTGTCCCTTCTGGCCTCTTT |
P. marinus Tbx4/5 | AARTTYGCNGAYAAYAARTGG | CCYTTNGCRAANGGRTTRTTYTC |
P. marinus Flt1/4 | GACGAGCGAGGATGAAGGGGAGTAC | CCACACCATTATCGGCCAGCAGAAC |
(ENSPMAT00000007382) | ||
Primers for L. japonicum Tbx4/5 genome sequence | ||
Tbx4/5 Gap1 | CGTGTCGCCTTCCTCCGCAGA | TGGATGCGTGGGTGATTTCGTGGAT |
Tbx4/5 Gap2 | CGCCTCCTCCGCTCTCCTTATCTGA | ACCACGGGAAGAGAGAAAGAGACGC |
Tbx4/5 Gap3 | TGCGGTCTGTGAACATCGTCACTGG | AACATCTCCTAGCCACCGTGCTTGC |
Tbx4/5 Gap4 | TGTGGGAGGAGAAATCGGAGGACCC | TGCGGTAATTTCCAGAACTGCGGCT |
Tbx4/5 Gap5 | GCAACTCACGACTACCCCACTTGCA | GTGGTGACCGTGAGCAGGAATCGAG |
Tbx4/5 Gap6 | GCAACTCACGACTACCCCACTTGCA | GTGGTGACCGTGAGCAGGAATCGAG |
Tbx4/5 Gap7 | GAGGGAGGGAGAGAGAGAGGGACAA | CGTCACCGGTGTTGGCGGT |
Tbx4/5 Gap8 | CTGCTGCCCATCACATCACCCGC | GTGTAGGTGGTCGCGGGCACTTAAG |
Tbx4/5 Gap9 | CCGTGACCTTTTACATCGTGCACCCAA | CAACCGGGCAATGACACGATTCAGC |
Tbx4/5 Gap10 | GTGCTCCTCCTGAACATCGCCCATT | ACCTAGTTGCTGTACTGCCGTGCTG |
Primers for genomic DNA fragment | ||
Mouse Tbx5 intron2 | CTCCCAGCAAGTCTCCATCATCCCC | AACTTCAGCCACAGTTCACGTTCATGA |
Mouse CNS12sh | CCTCATCATCATTAGTCATGCTCGCT | GCTGCTTCTGGAGACACTGGTC |
Gar Tbx5 intron2 | TCTCCATCACCACAGACAACATACACTCA | CCTCCCTGCCTTGGTTATAATCATCTCTGT |
Gar Tbx5 intron5 | CGCGCGATTGAGGGTTAGAGTTGAA | AGCGTCTGTTAAGTGATTTCAGATGGCAA |
Gar CNS11 | AGTCGGCAGAGTCAGCTTCCATAGG | GTGCTCACTACGCCTTCCATTTCGG |
Gar CNS12 | GGCTGCTGTCTTAAATACCTTTCTTGGGC | TGACGGGTGCTATTTGTCCTTTGCC |
Gar CNS12sh | AAATCATCATTAGTCGTGGCTCATCGTG | GCCTATCTTGATGTTAGTTTGACCCCTG |
Gar CNS23 | TCTACAGGCACACACAACCCCTCTG | CTGGACTCTGGACTCTGGACTGTGG |
Gar CNS26 | CAGGGATGGAAGGCTTCAAACACTCA | AGGAATTAAACCCAGGGCCCCAGAG |
Gar CNS27 | AGGTTACCAGCTACAGTTGTCACACAGATG | GGCGAGTTCATCCAGTTACACTCAGAAGG |
Gar CNS58 | AGGCATCGATTCCTTCTCCGTGACG | ATGTGGACTGCAGGGGTTGTGATGG |
Gar CNS59 | GGGGAGGCTGTGTGGAAAACTGAGT | CTTGTAGCACTGGGGCTCTGGGTTC |
Gar CNS63 | TATAGCGCTCAGTCACGTGGCCTT | TGCAAATCAACACTCAACGGTACAAGATGT |
Zebrafish tbx5a intron2 | GTAACGTCAACTAGTGCCTCGATGGT | CTTTTTAAAGAAGCATGCAGACAGAGAGTGAG |
Zebrafish CNS12sh | GTGACCTTCTCGCTGTAAGATGATTGT | ACACATCTTGATTTCATTAACATCTCTTCCTTCT |
Zebrafish CNS65 | TGTTCCAGGGTCACAATAATGATGCTTTTAAGA | CATGAAGGTTGCTCTGTGTTCTGCATGA |
SkateTbx5 intron2 | CCAACAAACCACATTCCCCACAGCA | TCCCGCTTTCGTAATGATCATCTCTGTCC |
Lamprey DNA fragment | TCGATGCGTTCCTCAAAAGTGGCAC | AGGATTAGGGCAGAGGGAGAGGGTG |
Primers for tbx5a mutant genotype | ||
Zebrafish tbx5a exon8 | AGTATTCCTGTGAGAACGGCGTTTCC | |
Zebrafish tbx5a intron8 | AGGTATCAGTGTGTGGTTTAGAGGCACA |
Phylogenetic Analysis.
Amino acid sequences were collected from the Ensembl (uswest.ensembl.org/index.html), GenBank (www.ncbi.nlm.nih.gov/), and SkateBase (skatebase.org), and then aligned by ClustalW (www.clustal.org/) without gaps. The construction of phylogenetic trees was performed by the maximum-likelihood method the JTT+I+Γ4 model in PhyML (50).
Genomic Analysis.
ATAC-seq data and CTCF sites were reported (34, 35). Open chromatin regions with peak intensity more than 10 (arbitrary units) and without overlapping CTCF sites were regarded as primary candidates for potential enhancers. Genomic sequences of animals used in this study were gathered from Ensembl (www.ensembl.org//uswest.ensembl.org/index.html?redirectsrc=//www.ensembl.org%2Findex.html), University of California, Santa Cruz Genome Browser (genome.ucsc.edu), SkateBase (skatebase.org), Elephant Shark Genome Project (esharkgenome.imcb.a-star.edu.sg), and Japanese Lamprey Genome Project (jlampreygenome.imcb.a-star.edu.sg). Genomic DNA of Japanese lamprey was obtained from the Sugahara laboratory at the Hyogo College of Medicine. The genome assembly gaps adjacent to Japanese lamprey Tbx4/5 locus were cloned and sequenced. The accession number of lamprey genome sequence is listed in Table S2. The comparison of genomic sequences was performed by mVISTA LAGAN program (genome.lbl.gov/vista/mvista/submit.shtml) with the following parameters: 50 bps calc window, 100 bps min cons Width, and 70% cons Identity. We defined CNSs as regions conserved between more than two vertebrate species. Of these regions, CNSs with conservation among more than five species including gar and/or elephant shark were preferentially assessed.
Vector Construction.
Mouse genomic DNA (Swiss–Webster albino mice) was purchased from Promega. Gar, zebrafish, and skate genome DNA were extracted with phenol-chloroform-isoamyl alcohol and chloroform solutions. The DNA fragment of a putative enhancer was amplified by Platinum Taq DNA Polymerase High Fidelity, cloned into pCR8/GW/TOPO vector, and then relocated to pXIG-cfos-EGFP by using LR Clonase II Plus (Life Technologies). The sequence of a putative enhancer was inserted into 5′ of EGFP, and checked by restriction enzyme digestion and sequencing.
Zebrafish Injection.
Zebrafish fertilized eggs (strain *AB) were obtained from natural mating. Male and female heterozygous tbx5a mutant zebrafish were mated to obtain homozygous tbx5a mutant eggs. For transgenic analyses, 25 ng/μL pXIG-cfos-EGFP vector was injected into one- or two-cell stage embryos with 35 ng/μL transposase RNA, 0.2 M KCl, and phenol red. Injected eggs were raised for 3 mo and then outcrossed to *AB fish (34). Zebrafish with GFP expression in any tissue were screened for establishing transgenic stable lines. For the rescue experiment, 25 ng/μL pXIG-cfos-tbx5a vector with two copies of CNS12sh was injected into one-cell stage hst embryos with 50 ng/μL transposase RNA and phenol red. pXIG-cfos-tbx5a vector without the enhancer was used as a control. Genomic DNA was extracted from wild-type, heterozygous, and homozygous hst embryos at 72 hpf, and PCR was performed with zebrafish tbx5a exon8 and intron8 primers (Table S2). PCR products were sequenced to identify homozygous tbx5a mutants. Embryos were photographed on a Leica M205FA microscope.
Acknowledgments
We thank John Westlund for illustrations; Andrew Gehrke, Darcy Ross, Gokhan Dalgin, Igor Schneider, Joyce Pieretti, Julie Szymaszek, Justin Lemberg, Tetsuya Nakamura, Philippe Janvier, and Robert K. Ho for helpful discussions and critical reading of the manuscript; Marianne Bronner and Stephen Green for sea lamprey sampling; Peter Currie, Alysha Heimberg, Catherine Boisvert, and Steve McLeod for elephant shark embryos; Fumiaki Sugahara for Japanese lamprey materials; and José Luis Gómez-Skarmeta for ATAC-seq data. tbx5a mutant zebrafish was kindly provided by Deborah Garrity and Rasha Alnefie, and we are grateful to Marc Ekker, Gary Hatch, Koichi Kawakami, Gembu Abe, and Robert K. Ho for vectors. This work was supported by The Brinson Foundation and the University of Chicago Biological Sciences Division.
Footnotes
The authors declare no conflict of interest.
Data deposition: The sequence reported in this paper has been deposited in the DNA Data Bank of Japan (DDBJ) database (accession nos. LC121589–LC121592).
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1609997113/-/DCSupplemental.
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