Conditional mutagenesis by oligonucleotide-mediated integration of loxP sites in zebrafish

Many eukaryotic genes play essential roles in multiple biological processes in several different tissues. Conditional mutants are needed to analyze genes with such pleiotropic functions. In vertebrates, conditional gene inactivation has only been feasible in the mouse, leaving other model systems to rely on surrogate experimental approaches such as overexpression of dominant negative proteins and antisense-based tools. Here, we have developed a simple and straightforward method to integrate loxP sequences at specific sites in the zebrafish genome using the CRISPR/Cas9 technology and oligonucleotide templates for homology directed repair. We engineered conditional (floxed) mutants of tbx20 and fleer, and demonstrate excision of exons flanked by loxP sites using tamoxifen-inducible CreERT2 recombinase. To demonstrate broad applicability of our method, we also integrated loxP sites into two additional genes, aldh1a2 and tcf21. The ease of this approach will further expand the use of zebrafish to study various aspects of vertebrate biology, especially post-embryonic processes such as regeneration.


Introduction
Model system genetics is undergoing a major shift from forward to reverse genetics, driven by a combination of two key factors.The first is the increasing robustness of genomic and proteomic tools, which enable rapid identification of candidate genes with potential roles in biological processes of interest.The second factor is the proliferation of precise, efficient, and easy to use genome editing tools, from zinc finger nucleases to TALE-guided nucleases and CRISPR/ Cas9 (reviewed in [1]).CRISPR/Cas9 in particular has made introduction of mutations into genomes of various organisms very straightforward and cost-effective.
Zebrafish first rose to prominence as a vertebrate model system that made development and organogenesis amenable to forward genetic analyses [2,3].Over the past twenty years, use of the zebrafish has expanded to include biological processes which occur much later in ontogenesis.Examples of such biological processes include regeneration [4], various aspects of behavior from habituation [5] to sleep-wake cycle [6], and carcinogenesis [7].
Genetic analyses of post-embryonic processes in zebrafish have had to rely on overexpression of dominant negatives, knockdown using morpholino oligonucleotides, modulation using small molecules, and similar approaches.The inability to generate true conditional mutants has led scientists to try alternatives, such as mutant rescue using floxed Bacterial Artificial Chromosomes [8], random gene trapping using conditional vectors [9][10][11], or targeted integration of a Cre-inducible gene trap cassette [12].Only recently has generation of the first floxed zebrafish mutant been reported [13].In contrast, mouse geneticists have been refining conditional mutagenesis since the introduction of the term "floxed" in 1994 [14].
We have recently developed a method for integration of epitope-coding sequences into the zebrafish genome using oligonucleotide-directed repair of CRISPR/Cas9-induced double strand breaks [15].High germline transmission rates suggested that sequential integration of two loxP sites might be feasible.Single-stranded oligonucleotide templates have been successfully used to integrate loxP sites, either sequentially or two at a time, into the mouse genome [16][17][18][19].However, since only non-palindromic mlox sites have so far been successfully integrated into the zebrafish genome using oligonucleotide templates [20,21], we were concerned that the palindromic nature of the loxP site may interfere with homology-directed repair in zebrafish embryos.
To test the feasibility of oligonucleotide-mediated integration of loxP sites, we selected four genes which play essential roles in development and may also be required for regeneration: tbx20, fleer, aldh1a2 and tcf21.tbx20 is required for heart development in mouse and zebrafish, but is also required for mouse cardiac homeostasis [22][23][24][25][26]. tbx20 is upregulated during zebrafish heart regeneration, and overexpression of Tbx20 improves the regenerative capacity of the mouse heart [27,28].fleer is essential for ciliogenesis, and zebrafish embryos lacking fleer display pleiotropic phenotypes including laterality defects, kidney cysts, and failure to inflate brain ventricles [29].While it is not known if cilia are required for regeneration, their roles in mechanosensing as well as shh signal transduction suggest that they may be needed for regeneration to occur.aldh1a2 mutants display pleiotropic phenotypes in neural, heart, and pectoral fin development [30,31].Upregulation of aldh1a2 mRNA is the signature of endocardial and epicardial activation after cardiac injury [32].Finally, tcf21 mutants display defects in morphogenesis of branchial arch-derived structures [15,33].tcf21 is also constitutively expressed in the epicardium and epicardial-derived cells of adult zebrafish, and tcf21 expressing cells are required for cardiac regeneration [34].
Here we found that single stranded oligonucleotide templates can efficiently direct integration of loxP sites into CRISPR/Cas9-induced double strand breaks in the zebrafish genome.We performed sequential integration of two loxP sites to generate a conditional (floxed) allele of tbx20.We have used this conditional allele to demonstrate that early expression tbx20 is essential for zebrafish heart development.Using fleer as a model, we demonstrate that Crerevertible Gene Breaking Transposon (GBT) mutants can be readily converted into fully conditional alleles by the addition of a single loxP site.Using aldh1a2, we demonstrate that prior to -or in parallel with-generation of a floxed allele, the target exon can be readily removed to test if the deletion produces a phenotype.Finally, using tcf21 as a model for small genes, we demonstrate that a loxP site can be integrated into the 5' untranslated region without significantly impairing gene function.

Efficient oligonucleotide-mediated integration of loxP sites into the zebrafish genome
Conditional loss-of-function mutagenesis requires two loxP sites flanking an exon (or several exons) of a gene.We have recently developed a methodology for oligonucleotide-mediated integration of epitope-coding sequences into the zebrafish genome [15].The relatively high efficiency of our method prompted us to speculate that conditional mutagenesis could be achieved by sequential integration of loxP sites.However, since oligonucleotide-mediated integration of wild type loxP sites into the zebrafish genome has not yet been demonstrated, we first needed to test if it was at all feasible.We selected tbx20 for our initial experiments (Fig 1) and chose to flox its second exon because it encodes the first few amino acids of the Tbox DNA binding domain, and because removal of the second exon would put exons 3-7 out of reading frame.Two highly active sgRNAs, tbx20 sgRNA9 and tbx20 sgRNA10 (Fig 1a and  1b), flanking the second exon, were identified by loss of a restriction enzyme site and/or T7 endonuclease assay (assessment of tbx20sgRNA9 activity is shown in S1 Fig).
To integrate a loxP site into intron 2 of tbx20, we designed an oligonucleotide template for homology directed repair of the double strand break induced by tbx20 sgRNA10.(Fig 1c).Since we have frequently observed small indels at the homology arm junction in past experiments, we decided to flank the loxP sequence with three nucleotides of "spacer" sequence.We injected tbx20 sgRNA10 along with nCas9n mRNA into embryos at the one cell stage, followed by injection of the HDR oligonucleotide with 21 nucleotide-long homology arms as previously described [15].Indels were readily detected using the T7 endonuclease assay, and integration of the loxP site was detected by PCR in pooled injected embryos.Siblings of tested embryos were raised, incrossed, and screened for germline transmission of integration of the loxP site by nested PCR.One out of twelve incrosses produced embryos positive by both 5' and 3' nested PCR.Notably, nested PCR for the 3' end worked poorly, with only one of three batches of embryos appearing barely positive (Fig 1d top vs bottom panels).Poor amplification with loxP-specific primers turned out to be a recurring issue.Several different loxP primers were designed over the course of this work; for some loci, several loxP-specific primers were tested on injected embryos.Nevertheless, sequencing of the 5' and 3' PCR fragments indicated integration of the full-length loxP site, with a 10-nucleotide partial target site duplication at the 5' end of the HDR oligonucleotide template.Integration of the loxP site was further confirmed by performing a short flanking PCR on individual embryos and sequencing the larger PCR fragment.Siblings were raised to adulthood and 16 were genotyped by tail clip.We identified four adults heterozygous for a loxP site (Fig 1e, red arrows, sequenced in Fig 1f).Two additional fish had a single band corresponding to a loxP-containing allele, but no wild type band (yellow arrows).Since both parents were mutagenized, we interpreted this as the presence of a deletion removing at least one of the primer binding sites on the homologous chromosome.
In parallel, we performed experiments to integrate a loxP site into the first intron of tbx20.Sequence analysis revealed the presence of a polymorphic poly-T stretch a few nucleotides downstream of tbx20 sgRNA9 target site, with wild type AB fish having either 9 or 10 thymidines.The shorter stretch (9 thymidines) seemed more prevalent among the fish we were injecting.In this experiment, we tested an HDR oligonucleotide template with asymmetriclength homology arms, antisense to the PAM-containing strand [35].We designed a 120 nt- Representative image of the 5' nested PCR reaction used to screen pools of F1 embryos.L, 100 bp DNA ladder (ThermoFisher Scientific).1-13, PCR on pools of embryos from 5 different F1 in-crosses (pools from the same F0 pair are grouped, loxP-positive cross is underlined in red).C1 control DNA from embryos injected with tbx20 sgRNA9 and tbx20sg9-loxP HDR oligonucleotide.C2, control DNA from embryos injected with tbx20 sgRNA10 and tbx20sg10-loxP HDR oligonucleotide.e. PCR genotyping of tail clips of adult F1 fish from the F0 in-cross underlined in red in d.Red arrows indicate fish heterozygous for the loxP-containing allele.Yellow arrows indicate fish which likely contain one loxP-containing allele, but presumably lack the wild type allele due to a deletion inherited from the other parent.f.Sequence of the recovered tpl135 allele containing integration of the full-length loxP site with 10-nucleotide partial target site duplication at the 5' of the HDR oligonucleotide.g, h.Experimental design for integration of loxP site into intron 1 of tbx20.g.The single stranded oligonucleotide used for homology-directed repair was antisense to the PAMcontaining strand and had loxP site flanked by 3-nucleotide spacer sequences, 62-nucleotide 5' homology arm and 18-nucleotide 3' homology arm.h.Sequence of the recovered tpl136 allele containing perfect integration of the loxP site.https://doi.org/10.1371/journal.pgen.1007754.g001long oligonucleotide template for HDR (Fig 1g), and injected it into 1-cell zebrafish embryos along with nCas9n mRNA and tbx20sgRNA9 RNA.Integration of the loxP site was detected in pools as well as in individual injected embryos as described in Materials and Methods.Siblings of tested embryos were raised to adulthood and screened for germline transmission of a loxP site by nested PCR as described in Materials and Methods.One out of three incrosses gave embryos that were positive for the loxP site both at the 5' and 3'end by nested PCR.Integration of the loxP site was confirmed by sequencing individual embryos.Siblings of genotyped embryos were raised to adulthood and 16 fish were genotyped for presence of the loxP site by short flanking PCR.Three fish were found to be heterozygous for the loxP-containing allele, leading to establishment of the tbx20 tpl136 loxP integration line (Fig 1h).

Generation of a conditional allele by sequential integration of loxP sites
To engineer a floxed allele, we incrossed F1 fish heterozygous for the intron 2 loxP site and injected the embryos with tbx20 sgRNA9 and nCas9n mRNA, followed by injection of the HDR template oligonucleotide targeting intron 1 (Fig 2a).Injected embryos were raised to adulthood and genotyped for the presence of the intron 2 loxP site.Among 61 adults, 28 were heterozygous and 14 were homozygous for the loxP site (Fig 2b).All 42 were outcrossed and screened by nested PCR for integration of the loxP site into intron 1 (Fig 2c).Nine were positive by 5' end PCR (3' with regard to the HDR oligonucleotide), and 12 were positive by both 5' and 3' end PCRs.In many cases the 3' end nested PCR fragment was larger than would be predicted, sometimes by a few hundred bases.For six germline transmitters (candidate founders), we extracted DNA from individual embryos and performed flanking PCR to assess germline mosaicism and to confirm complete loxP site integration (S2 Fig) .The larger PCR bands observed in two candidate founders yielded poor quality sequences, and these founders were not followed up further.Sequencing the larger PCR bands from the four other founders revealed a high prevalence of insertions and deletions, most remarkably centered around the oligo-T stretch immediately 3' to loxP integration (corresponding to the 5' end of the HDR oligonucleotide).Subsequent re-sequencing of the locus revealed that the chromosome containing the loxP site in intron 2 had the longer 10-nucleotide oligo-T, while our HDR template oligonucleotide contained 9. Nonetheless, one of the candidate founders (NP#39) had transmitted integration of a full-length loxP site, albeit with an insertion of an additional 62 nucleotides immediately 3' to it (Fig 2d).Siblings of genotyped embryos from founder NP#39 were raised to adulthood.

Validation of the conditional (floxed) allele of tbx20
Eight adult fish that were raised from an outcross of candidate founder NP#39 were tail clipped and screened by flanking PCR (Fig 2e).In four of the fish, a larger PCR band corresponding to a floxed allele was observed (red arrows in Fig 2e).Two of the four purified PCR bands were sequenced directly and found to contain identical full-size loxP integrations with a partial target site duplication.For further confirmation, these fragments were cloned into pJet PCR cloning vector and sequenced, and the resulting floxed allele was designated tbx20 tpl145 (Fig 2d).
We then proceeded to incross these "F1" fish heterozygous for tbx20 tpl145 and to inject some of the embryos with Cre mRNA as described previously [36].All uninjected embryos were phenotypically normal (n = 52).This observation, together with the fact that tbx20 deficiency leads to severe cardiac defects [22,25,26], enabled us to conclude that the integration of two loxP sites does not significantly impair tbx20 expression.Among embryos injected with Cre mRNA, approximately 25% displayed severe cardiac defects at 3 dpf in two independent experiments.We genotyped three embryos with severe cardiac defects and five siblings .In contrast, phenotypically wild type embryos were either homozygous wild type or heterozygous for the (excised) floxed allele.Some Cre-injected embryos were raised to adulthood and genotyped.Adult fish heterozygous for the deletion were incrossed, and one quarter of embryos were found to display severe heart defects indistinguishable from that seen in Cre-injected embryos of the previous generation (Fig 2j).
We next tested if Cre-mediated deletion of the second exon of tbx20 can be achieved in a temporally-regulated manner.We crossed fish heterozygous for the floxed tbx20 tpl145 allele to fish expressing the tamoxifen-inducible CreERT2 under the control of the ubiquitin promoter [37].Obtained embryos were selected for GFP fluorescence (the marker of Tg(ubb:CreERT2)), incubated in 4-hydroxytamoxifen for 24 hours between 2 dpf and 3 dpf, and individual embryos were genotyped.Deletion of exon 2 of tbx20 was readily observed in embryos incubated with 4-hydroxytamoxifen, but not in control embryos (Fig 2h and 2i).As expected, all embryos were phenotypically normal because all had a wild type allele of tbx20.Together, these experiments led us to conclude that we have successfully engineered a fully conditional (floxed) allele of tbx20.
Many experimental approaches in genomics, proteomics and metabolomics require a large amount of starting tissue.Due to their small size, hundreds to thousands of zebrafish embryos or larvae may be needed for each experiment.Genotyping such large numbers of embryos is impractical, leaving two approaches: morpholino knockdown or germline replacement [38,39].We hypothesized that if embryos obtained from incross of parents homozygous for the floxed allele were injected with Cre mRNA, we would be able to obtain clutches of all-mutant embryos.To test this hypothesis, we genotyped adults obtained from tbx20 tpl145 incross and identified homozygotes.Homozygous fish were incrossed, and embryos were injected with Cre mRNA at 1-cell stage.As expected, Cre-injected embryos displayed full tbx20 mutant phenotype, while non-injected embryos were all phenotypically wild type (S3 Fig).Thus, large clutches of all-mutant embryos, along with wild type controls, could be generated using this approach.

Temporally-regulated loss of tbx20 function
In zebrafish, tbx20 is expressed in bilateral cardiac precursors prior to their migration and coalescence.Expression appears to persist through larval development, and is upregulated in response to injury in adult hearts [22,[25][26][27]40].In mouse, cardiomyocyte-specific deletion of Tbx20 in adults leads to lethal cardiomyopathy and arrhythmia, indicating that TBX20 is required not only for cardiac development, but also for homeostasis [24].To test when it is required for heart development in zebrafish, we sought to induce ubiquitous loss of tbx20 function at different time points.While performing the experiments described in the paragraph above, we noted that the ubb:CreERT2 line is multi-copy, e.g.carries multiple unlinked integrations of the transgene.We established two lines, sub-designated ubb:CreERT2.C and ubb:CreERT2.F which were single-copy genetically (50% of progeny positive for the cardiac incubated with 5μM 4-HT for 24 hours.j.Adults raised from Cre-injected tbx20 tpl145/+ embryos were incrossed, resulting in approximately 1/4 of embryos ( 36 GFP (myl7:eGFP) transgenesis marker [37]), and crossed them a tbx20 tpl122 partial deletion mutant obtained during epitope tagging experiments to be described elsewhere (Burg et al.,unpublished,and S4 Fig).We then crossed ubb:CreERT2.C, tbx20 tpl122 double heterozygotes to tbx20 tpl145 floxed homozygotes, and exposed embryos to 4-OHT at different time points.We found that exposure to 0.5 μM 4-OHT at 6 hpf reliably induced a full tbx20 loss-of-function phenotype.In contrast, only a small subset of embryos exposed to 4-HT at 10 hpf displayed a milder cardiac phenotype, while all embryos exposed at 14 or 24 hpf were phenotypically normal.In order to eliminate the possibility that 4-HT was less effective at 10 hpf compared to 6 hpf, we performed qPCR to assess the completeness of Cre recombination at the DNA level.We found that excision was 99% complete in embryos exposed to 4-HT at 6 hpf, and 94% complete in embryos exposed at 10 hpf (S1 Table ).Thus, 4-HT is somewhat less efficient at inducing ubb:CreERT2-mediated recombination at 6 hpf compare to 10 hpf.Consequently, absence of phenotype in embryos exposed at 10 hpf may not be due to timing loss of Tbx20 function, but instead due to slightly lower efficiency of recombination.
To explore the possibility that 4-HT is taken up less well by older embryos, we next compared the toxicity of 4-HT at 6 vs 10 hpf (S2 Table ).We treated pools of embryos from the same clutch with 4-HT ranging in concentration from 5 μM to 60 μM and found that embryos treated with 25 μM 4-HT at 6 hpf had a 73% survival rate, while embryos given the same dose given at 10 hpf had a 100% survival rate.Survival rate at higher doses dropped off significantly faster in embryos treated at 6 hpf compared to 10 hpf; however, even the 10 hpf embryos displayed toxicity effects at doses above 25 μM.
We then repeated our loss-of-function experiment by exposing 10 hpf embryos to 20 μM 4-HT, and 6 hpf embryos to either 5 μM or 0.  ), using two different single-copy ubb:CreERT2 drivers.We found the Cre-mediated loss of function was at least 95% efficient in embryos exposed to 20 μM 4-HT at 10 hpf, but the embryos displayed very mild, if any, cardiac abnormalities.Exposure to very low doses of 4-HT at 6 hpf induced nearcomplete excision of the second exon when ubb:CreERT2.C driver was used.In contrast, excision was significantly less efficient with ubb:CreERT2.F driver.However, we observed that 90%-efficient excision of the second exon was sufficient to induce a severe cardiac defect (Fig 2l and 2m, S1 Table ).
We also performed a semi-quantitative test for the time lag of CreERT2-mediated recombination after exposure to 4-HT.Pools of 20 embryos exposed to 5 μM 4-HT at 6 hpf and 10 hpf were collected 30 minutes, 1 hr, 2 hrs and 4 hours after exposure.The excision band was readily detectable after 2 hours in 6 hpf treated embryos, and 1 hour after 4-HT exposure in 10 hpf embryos (S5 Fig) , indicating that a significant subset of cells may have lost tbx20 function by then.Increased intensity of the excision band at 4 hours after exposure indicates that recombination is likely not complete yet at 2 hours after addition of 4-HT.

Conversion of Cre-revertible Gene Breaking Transposon allele to a floxed conditional allele
Gene Breaking Transposons (GBTs) have been used to generate a large collection of gene trap mutants in zebrafish [36, 41] [42, 43] In a typical scenario, a GBT integrates into an intron of a gene and terminates the expression of the mutated gene, leading to complete loss of function.In most widely used GBT's, the gene trap cassette is flanked by direct loxP sites.Expression of Cre recombinase leads to very efficient excision of the gene trap cassette, reverting the mutant phenotype and leaving a single loxP site flanked by terminal repeats of the Tol2 transposon.Thus, the addition of a single loxP site should convert such reverted gene traps to fully conditional (floxed) alleles.
In the fleer tpl19 mutants selected for these experiments, the gene breaking transposon was integrated into the first intron of fleer, eliminating expression of downstream exons [36] (Fig 3b).We first injected embryos with Cre mRNA and established a reverted line fleer tpl19R (Fig 3c ), which was homozygous viable.To engineer a conditional allele, we reviewed the exons of fleer for reading frame phase and the presence of conserved protein domains.Exons 2, 3, and 4 all begin and end in the same reading frame, and mRNAs lacking one or more of them may be translated into functional protein.Furthermore, the first 12 exons all begin and end in either phase 0 or phase 1 (Fig 3a).We therefore decided to attempt to generate a deletion removing all three N-terminal tetratricopeptide repeats (likely important for protein-protein interactions) of fleer by engineering a loxP site into intron 7 (Fig 3c and 3d).We sequenced the seventh intron from fish homozygous for the reverted gene trap, designed sgRNAs targeting it and identified flr sgRNA3 as being sufficiently active by Surveyor assay as described in (15).To integrate a loxP site, we designed a 110-base HDR template oligonucleotide with asymmetric homology arms, antisense to the PAM.Embryos were injected with flr sgRNA3, nCas9n mRNA, followed by injection of the HDR template oligonucleotide.Fish were raised to adulthood and screened for germline transmission of the loxP site by nested PCR.After screening 14 F0 fish, we identified one that transmitted a perfect integration of the loxP site.Siblings were raised to adulthood, and one out of twenty-one adult F1 fish was positive for the loxP integration (sequenced in Fig 3e) and was assigned allele name flr tpl141 .
We then proceeded to test the conditionality of this allele by incrossing flr tpl141 F2 heterozygous fish and injecting embryos with Cre mRNA (Fig 3f).Twenty-five percent of the progeny were expected to be homozygous for the floxed allele, and approximately one quarter of the injected embryos displayed a phenotype consistent with previously published flr m477 chemical mutant, as well as flr tpl19 gene trap mutant [29,36].Embryos were first genotyped using primers spanning the intron 7 loxP site, which amplified the WT allele as well as any non-excised flr tpl141 .The same embryos were also genotyped for the loxP site in intron 1, and amplicons were detected in embryos carrying flr tpl141 .Finally, embryos were genotyped by PCR across both loxP sites, with the excision product being readily detected in all flr tpl141 -positive embryos embryos injected with Cre mRNA (Fig 3f, bottom panel).In this last experiment, any nonexcised floxed allele was undetectable due to large amplicon size.All genotyped embryos with the fleer mutant phenotype were homozygous for flr tpl141 , while all heterozygous and WT siblings were phenotypically wild-type.

aldh1a2 is the only retinal dehydrogenase highly expressed in regenerating zebrafish hearts
Pharmacological perturbation of retinoic acid (RA) signaling leads to severe defects in regeneration across various model systems and tissues (reviewed in [44]).Conditional mutants capable of inactivating RA signaling in specific cell types are needed to better understand the requirement of RA signaling for regeneration.Zebrafish have at least three genes coding for retinal dehydrogenases: aldh1a2, aldh1a3 and aldh8a1.Upregulation of aldh1a2 expression serves as the hallmark of endocardial and epicardial activation, making it an attractive target for conditional mutagenesis.In order to test which retinal dehydrogenases are likely to make an important contribution to retinoic acid production during regeneration, we analyzed RNA sequencing data from zebrafish hearts at 1, 3 and 5 days after cryoinjury and confirmed that aldh1a2 is highly expressed and upregulated in response to cryoinjury [45].In contrast, ald-ha8a1 was expressed at a much lower level, and expression of aldh1a3 was undetectable (S6 Fig) .The observation that other RA-synthesizing enzymes are poorly, if at all, expressed in the regenerating heart suggests that loss of aldh1a2 function is likely to lead to severe reduction in RA signaling in the regenerating heart.This hypothesis cannot currently be directly tested, as aldh1a2 mutants display pleiotropic embryonic phenotypes and do not survive [30,31].

Deletion of exon 8 of aldh1a2 results in a null mutant
For aldh1a2, we decided to target exon 8 because it encodes a part of the highly conserved alcohol dehydrogenase domain (Fig 4).In addition, it begins and ends in different phases of the reading frame.With exon 8 deleted, in-frame transcripts can be generated by either skipping exons 5-7 or by skipping exon 9.Both of these scenarios would remove additional parts of the dehydrogenase domain with highly conserved amino acids.We sequenced the region flanking exon 8 from four wild type TLF fish (two males and two females), and designed four sgRNAs (S7 Fig) .We tested their activity by direct sequencing of PCR fragments generated on pools of injected embryos [46] and found that aldh1a2 sgRNA1 and aldh1a2 sgRNA4 were highly active, while aldh1a2 sgRNA2 and aldh1a2 sgRNA3 produced very few indels.
To test if deletion of the eighth exon would lead to loss of function phenotypes comparable to those of previously published aldh1a2 mutants, we co-injected both aldh1a2 sgRNA1 and aldh1a2 sgRNA4 along with nCas9n mRNA, and observed the appearance of a PCR band corresponding to the expected deletion product.Injected embryos were raised to adulthood, and two incrosses of F0 fish were performed.In pools of embryos from both incrosses, a PCR band corresponding to the expected deletion size was readily observed (S7 Fig) We crossed the F1 fish heterozygous for aldh1a2 tpl137 allele to the F1 fish heterozygous for the aldh1a2 tpl138 allele.Approximately 25 percent of 3 dpf embryos lacked pectoral fins and had moderate to severe pericardial edema.In addition, the majority of embryos displaying these phenotypes also displayed curved tail consistent uncoordinated leftright somitogenesis as previously reported [47] (Fig 4d).The absence of pectoral fin buds at 30 hpf was confirmed by in situ hybridization using a probe against tbx18.Since both tcf21 and aldh1a2 are expressed in the branchial arches and both mutants display a defect in the development of branchial arch-derived structures, we also performed in situ hybridization using a probe against tcf21.We found that while tcf21 expression in the posterior branchial arches is absent in aldh1a2 mutants, expression of tcf21 in the first and second branchial arches of aldh1a2 mutants persists (Fig 4f).We therefore concluded that aldh1a2 is not required for tcf21 expression in the first and second branchial arches.Linkage of these phenotypes to aldh1a2 exon 8 deletion was confirmed by 3-primer genotyping PCR (S8 Fig).

Integration of loxP site into intron 7 of aldh1a2
We designed a 110 base long HDR template oligonucleotide (Fig 4g) and injected it into embryos which were also injected with aldh1a2 sgRNA1 and nCas9n mRNA.Integration of the loxP site was readily detected in pooled DNA of injected embryos as described in Materials and Methods.Embryos were raised to adulthood and seven incrosses (14 F0 fish) were screened for germline transmission of integration of the loxP site by nested PCR.Five pairs were positive by nested 5' and 3' PCR.In three cases, loxP integrations transmitted through the germline also contained an insertion of additional sequences within the 5' homology arm (S9 Fig) .One founder pair (R9x10) transmitted a precise integration of the loxP site, and 3/8 individual embryos analyzed were found to be heterozygous for the loxP-containing allele.Founder pair R13x14 transmitted integration of the loxP site with a single nucleotide substitution within the 5' homology arm.Adult F1s raised from these crosses were genotyped by PCR (S9 Fig) .Three out of fourteen adults from pair R9x10 proved to be heterozygous for an allele containing a precise integration of the loxP site, designated aldh1a2 tpl139 (Fig 4h).One out of twelve adults from the F1 family R13x14 was heterozygous for the loxP integration with a single nucleotide substitution, and we established a backup loxP-containing allele, designated Genotyping of 16 phenotypically normal 3 dpf embryos from a cross between F1 fish heterozygous for aldh1a2 tpl139 loxP knock-in results in Mendelian ratios of aldh1a2 tpl139/tpl139 (red arrows), aldh1a2 tpl139/wt (yellow arrows) and aldh1a2 wt/wt embryos.PCR fragments from two of the embryos were sequenced to further confirm homozygosity for the loxP site.https://doi.org/10.1371/journal.pgen.1007754.g004aldh1a2 tpl140 .Two F1 fish heterozygous for aldh1a2 tpl139 were incrossed, and all embryos appeared phenotypically normal at 5 days post fertilization.Sixteen were genotyped for the presence of the loxP site, and four were found to be homozygous (Fig 4i).We concluded that integration of the loxP site into intron 7 does not significantly impair expression of aldh1a2.

Integration of loxP site into the 5' UTR of tcf21
In contrast to the first four large, multiple exon genes that we targeted, tcf21 is a small, twoexon gene, making it impossible to integrate both loxP sites into introns.We speculated that the 5' UTR might be a suitable target for loxP integration.First, the loxP site does not contain ATG codons that would cause premature translation initiation.Second, most regulatory transcription factor binding sites are expected to be upstream of the transcription initiation site (not immediately downstream), making it less likely that the integration of a loxP site would disrupt a transcription factor binding site.Finally, 3' UTRs may contain regulatory elements such as microRNA binding sites which are rather difficult to predict.We designed two short guides targeting the 5' UTR of tcf21, and both were reasonably efficient at inducing DSBs (S10 Fig) .We decided to first perform loxP integration into the tcf21 sgRNA5 target site and designed a HDR repair oligonucleotide with asymmetric arms (S11 Fig) .Embryos injected with tcf21 sgRNA5, nCas9n mRNA and the HDR oligonucleotide were raised to adulthood and screened for germline transmission of the loxP site.Out of nine incrosses, three were positive for germline transmission of a loxP site by nested PCR.One had an insertion of approximately 100 nucleotides and was not analyzed further.Single embryos from the other two transmitter pairs were analyzed.An incomplete loxP site was identified in one of the pairs, and integration of a full loxP site without indels was found in the second pair (tcfinxB).Siblings of analyzed embryos from tcfinxB were raised to adulthood and genotyped.Of twenty-four siblings that were genotyped, four were positive by PCR for integration of the loxP site.All four were sequenced and were found to have the same precise integration, designated tcf21 tpl144 (S11 Fig) .To test for the possibility that integration of loxP site impairs expression of tcf21, we crossed tcf21 tpl144 F1 fish to a previously established tcf21 frameshift mutant tcf21 tp119 [15].All embryos were phenotypically normal, demonstrating that the loxP-containing allele tcf21 tpl144 is functionally wild type.

Discussion
We have used oligonucleotide-mediated homology directed repair to integrate loxP sites into five different locations in the zebrafish genome: intron 1 of tbx20, intron 2 of tbx20, intron 7 of fleer, intron 7 of aldh1a2, and the 5' UTR of tcf21.Across all five loci, we have observed remarkably high rates germline transmission and germline mosaicism: the median rate of germline transmission of a complete loxP site was 6.3% (1 out of 16 F0 fish screened), while the median rate of germline mosaicism was 20% (1 out of 5 F1 fish screened from germlinetransmitting founders) (S3 Table ).A conditional mutagenesis workflow based on our experience is provided in Fig 5 .Our data clearly demonstrates the feasibility of conditional mutagenesis by oligonucleotidemediated sequential integration of loxP sites into the zebrafish genome.Two aspects of our method are likely to have contributed to its success.First, based on the previous observation of a high rate of indels at the junctions between the integrated sequences and homology arms [15], we flanked the loxP site by 3-nucleotide spacer sequences.A loxP site consists of an 8-base core flanked by 13-base inverted repeats.The melting temperature of the inverted repeats is calculated at 32˚C, meaning that a loxP site may form a hairpin in zebrafish embryos.The 3-nucleotide spacers may have facilitated homology-directed repair by providing spacing Upon deciding which exon to flox, we recommend sequencing the target sites to identify polymorphisms compared to reference genome.Next, sgRNAs should be designed and tested by either direct sequencing of PCR fragments, T7 endonuclease assay or loss of a restriction enzyme site on bulk DNA from pooled embryos.Once active sgRNAs have been identified, experiments integrating the first loxP site should be performed.In the absence of conclusive data that certain HDR template performs significantly better than others (such experiments are not practical at the only level that matters-germline transmission), we recommend using the design we successfully used to integrate loxP into fleer, aldh1a2 and tcf21: antisense to PAM, with 49-base 5' homology arm and 21-base 3' homology arm, with 3-nucleotide spacers flanking loxP site.As injected embryos are being raised, we then recommend to optimize nested PCR screening conditions DNA from pools of injected embryos.We found "plain" Taq polymerases (NEB between the hairpin and homology arms.Indeed, successful oligonucleotide-mediated integration of the mlox site, which has 3 substitutions in one of the inverted repeats, has been reported by two laboratories [20,21].We have not directly compared the efficacy of oligonucleotide templates with short or long homology arms, but 110-base long oligonucleotides with a longer 5' arm, antisense to the PAM, have been successfully used in the majority of our experiments, leading us to recommend this particular design.Further gains in HDR efficiency may be achieved by using phosphorothioate-modified oligonucleotides [48,49].The second aspect of our method is screening for germline transmission by nested PCR.Over the course of our work, we have used several different loxP-specific primers and find that even in nested PCR, different loxP-specific primers need to be tested with different genomic primers to identify optimal pairs.The palindromic nature of the loxP site likely contributes to poor performance of loxP-specific primers. Given that it takes a considerable amount of time to engineer a conditional mutant, it makes sense to ensure that the mutant will display a phenotype as early as possible.This is a two-step process.To determine the likelihood that the selected gene will be required for biological function of interest, it may be important to examine the expression of homologs which may provide identical or similar biochemical activity, as we have done for retinal dehydrogenases in regenerating hearts.Second, it is important to ensure that loss of the exon selected for floxing will lead to a severe or null phenotype.Using aldh1a2 as the model locus, we demonstrate that a pair of sgRNAs can be used to direct very efficient excision of the target exon.While our sgRNA target sites were less than 500 base pairs apart, larger deletions can also be readily induced using sgRNAs spaced over 15 kilobases apart [50].An additional benefit of a deletion allele is that it can be crossed to Cre drivers of interest, eliminating the need to backcross the floxed allele to obtain homozygotes (Fig 5).
An alternative way to ensure that a conditional mutant will display a phenotype of interest is to start from a Cre-revertible Gene Breaking Transposon allele [36,[41][42][43].The very high efficiency of Cre/lox recombination makes it possible to establish a line homozygous for Crereverted GBT allele with minimal effort.Only one loxP site then needs to be integrated to convert such Cre-reverted gene traps into fully conditional alleles, as demonstrated with fleer.
One of the challenges of using CRISPR/Cas9 to integrate loxP sites into the introns is that intronic sequences are often of low complexity, have low G/C content, and are repetitive.These features may limit targeting possibilities by making it difficult to design highly efficient #M0270, Thermofisher Scientific 2x PCR Master Mix Cat# AB-0575/DC and #EP0402, or similar) to be most suitable for nested PCR.In contrast, high-performance mixes such as Platinum Taq (Thermofisher #10966026) or Kapa 2G Fast ReadyMix + dye (Kapa Biosystems-KM5101) yield very high background and may only be used for the second (nested) reaction.It is also very helpful if primers for one end of the nested PCR are anchored within an exon.We recommend generating a deletion allele in parallel with integration of the first loxP site.Once highly active sgRNAs are identified, we recommend injecting a pair of sgRNAs flanking the exon to be floxed in order to confirm that removal of selected exon will yield an overt phenotype.We have been able to very efficiently delete exon 8 of aldh1a2 using sgRNAs spaced just over 450 base pairs, but larger deletions are certainly feasible too (1,2).An additional benefit of a deletion allele is that it can be crossed to Cre drivers of interest, eliminating the need to back-cross floxed allele to obtain homozygotes.Screening for germline transmission should be performed by nested PCR on pools of embryos obtained from incross.Positive crosses should be analyzed by performing short flanking PCR (ideally under 400 base pairs) on DNA from individual embryos.Bands corresponding to loxP-containing allele should be extracted from gel and sequenced to ensure presence of intact loxP site.Siblings of screened embryos should be raised to adulthood and loxP-positive F1s should be identified by flanking PCR as well.Two strategies can be used for integration of the second loxP site.If speed is the main priority, loxP-positive F1s can be in-crossed and second sgRNA/HDR oligonucleotide can be injected.The main drawback of this strategy that there is only 50% likelihood that the second loxP site will integrate into a chromosome already containing the first loxP.It is therefore necessary to genotype adults for presence of the first loxP site before out-crossing.Even though we successfully used this strategy to engineer a floxed allele of tbx20, we consider it impractical and would generally recommend to first generate adults homozygous for the first loxP site, incross them and then inject the second sgRNA/ HDR oligonucleotide.https://doi.org/10.1371/journal.pgen.1007754.g005sgRNAs.Requirement for GC-rich 5'-NGG-3' PAM sequence poses an additional complication.Nonetheless, we were able to find suitable targets in each gene and intron of interest.We have used several methods to assess guide RNA activity: T7 endonuclease assay, loss of restriction enzyme site, and direct sequencing of PCR fragments [15,46].Activity assessment is always performed on DNA extracted from a pool of at least 10 embryos, thus providing a quantitative estimate of average editing efficiency.In our experience, about half of the guides meet the minimum requirement of at least 50% editing efficiency.CRISPR/Cas9 systems recognizing A/T-rich PAMs, such as Cpf1 [51,52], will make editing of intronic sites even more straightforward.
Conditional mutagenesis relies on the availability of high quality, tissue-specific drivers of tamoxifen-inducible Cre recombinase.In the mouse, the majority of drivers have been engineered by integrating CreERT2 into the specific loci, thus likely fully recapitulating the expression of the "driver" gene.In zebrafish, drivers are typically engineered by Tol2-mediated transgenesis of an expression cassette.High activity of Tol2 transposase [53][54][55] means that many lines, at least initially, are multicopy, with each copy subject to position effects (for extreme examples, see [56][57][58]).As we have shown for two different copies of ubb:CreERT2, it is not sufficient to validate a given transgenic construct; the specific transgene integration, as a single-copy transgenic line, has to be validated for use in loss-of-function experiments.
Our genome editing experiments were performed in three different genetic backgrounds: AB (tbx20), TLF (aldh1a2 and tcf21), and undefined pet store-derived (fleer).The majority of our experiments were performed in the United States, but initial integrations of loxP sites into tbx20 were recovered in Germany.We therefore believe that our conditional mutagenesis methodology can be readily adapted by any laboratory and performed in any genetic background.Additionally, the oligonucleotide templates we used for homology directed repair are both inexpensive and widely available.The ability to efficiently generate conditional mutants in zebrafish offers new possibilities for understanding the roles of pleiotropic genes, and essential for studies of post-embryonic processes such as regeneration.

Ethics statement
All animal experiments described in this manuscript have been approved by Temple University IACUC committee under protocol numbers ACUP 4354, ACUP 4709 and ACUP 4164.nCas9n mRNA synthesis nCas9n was prepared as previously described [15].pT3TS-nCas9n [59] was linearized with XbaI and transcribed using the T3 mMessage mMachine in vitro transcription kit (Thermo-Fisher Scientific AM1348).Transcribed mRNA was purified using the Qiagen RNeasy MinElute kit (74204), diluted to 150 ng/μL in RNAse free water (ThermoFisher Scientific AM9937) and 2 μL aliquots were made.Aliquots were stored at -80˚C.

sgRNA synthesis
sgRNA was prepared as previously described [15].We used cloning-free PCR method similar to the ones described previously [60,61] to produce sgRNA synthesis template.We first performed PCR using guide-specific and M13F primers on DR274 [62] template.Guide-specific and all other primers used in this study are listed in S4 Table .We then performed agarose gel electrophoresis and purified the bands using GeneJet Gel Extraction kit (ThermoFisher Scientific K0692).Purified band was used as the template for the second PCR reaction with sgT7 and sgRNA-R primers.The obtained PCR fragment was purified using GeneJet PCR purification kit (ThermoFisher Scientific K0702) and used as the template for in vitro transcription using MEGAshortScript T7 transcription kit (AM1354).After RNA synthesis, concentration of sgRNA was assessed by agarose gel electrophoresis.Concentration was estimated by comparing to RiboRuler RNA ladder (SM1833).Unpurified transcription reaction mix was diluted to approximately 60 ng/μL and 8 μL aliquots were made.Aliquots were stored at -80˚C.

Microinjection
An 8 μL aliquot of sgRNA was thawed and mixed with 2 μL aliquot of nCas9n mRNA.3 nL of mix were injected into the yolks of 1-cell zebrafish embryos as described previously [15,63].
Appropriate loxP HDR oligonucleotide was diluted to 50 ug/μL in RNAse free water, and 1 nL was injected into the yolks of zebrafish embryos immediately after the RNA injection.
To test for loxP integration, PCR reactions were performed using different combinations of flanking and loxP-specific primers, either on pools of 10-20 injected embryos or on 8 individual embryos.

Screening for germline transmission of loxP integrations by nested PCR
Embryos from F0 incross or outcross were pooled into batches of 20 and DNA prepped.Three batches from each pair were tested for loxP integrations by nested PCR (gene specific primers described below).The first flanking PCR was run and amplification was confirmed by gel electrophoresis.The PCR was purified, diluted 1:100 with water, and 1 μL was used as a template for the 5' and 3' nested reactions.Siblings from positive crosses were raised to adulthood.All PCR reactions were performed using either NEB 2X Taq Master Mix, Thermo Scientific Taq or Kapa 2G Fast ReadyMix.DNA ladders used were Thermo Scientific GeneRuler DNA ladder (SM0331) and ThermoFisher Scientific 100 bp DNA ladder (#SM0241)(Fig 1d).

Screening F1s for loxP integrations by short flanking PCR
Adult F1 fish were tail clipped, DNA prepped, and genotyped by running a short flanking PCR (gene specific primers described below) designed to amplify approximately 450 bp or less.PCRs were run on 2% agarose gels, and amplicons of appropriate size were purified and sequenced to confirm loxP integration.All PCR reactions were performed using either NEB 2X Taq Master Mix, Thermofischer Scientific Taq or Kapa 2G Fast ReadyMix.DNA ladders used were Thermo Scientific GeneRuler DNA ladder.

Reversion of the fleer gene trap
Fish containing the fleer GBT were incrossed and embryos were injected with 25 pg Cre mRNA.After being raised to adulthood, the injected fish were tail clipped and genotyped for the reverted gene trap using the flrUTR-F1/Tol2-F8 primer pair.
fleer tpl141 : Embryos from the outcross of the heterozygous floxed fleer tpl141 to wt were injected with 25 pg Cre mRNA.Individual embryos were genotyped by PCR for the presence of the intron 7 loxP site using the flrEx7-F1/flrIn7-R4 primer pair, for the presence of the intron 1 loxP site using the flrUTR-F1/loxP-R1 primer pair, and for the excision product using the tol2-R7/flrIn7-R4 primer pair.

Tamoxifen inducible CreERT2 mediated excision of floxed exons
Fish heterozygous for either floxed tbx20 tpl145 or fleer tpl141 were crossed to the transgenic line Tg(ubi:CreERT2).Embryos were screened for GFP (transgene marker) at 2dpf, and GFP positive embryos were split and incubated with either 5 μM 4-HT or ethanol (control) for 24 hours.Individual embryos were DNA prepped and genotyped using the primer pair tbx20In1-F4/tbx20In2-R1 for tbx20, or as described for Cre injection for fleer.

Expression of RA-synthesizing enzymes in the regenerating zebrafish heart
Expression values of RA-synthesizing genes (aldh1a2 and aldh8a1) in zebrafish hearts at various time points post sham operation or cardiac injury were extracted from the whole-genome RNAseq datasets previously published [45] Fragments per kilobase of transcript per million mapped reads (FPKM values) were summarized and presented in S3 Fig.

Mutagenesis of aldh1a2
aldh1a2sgRNA1 and aldh1a2sgRNA4 were co-injected along with nCas9n mRNA as previously described.Injected fish were raised to adulthood, crossed, and screened for germline transmission of deletion alleles by PCR using the aldh1a2-F2/aldh1a2-R6 primer pair.Siblings were raised to adulthood, tail-clipped, and screened for the presence of the deletion by 3 primer PCR using the primers aldh1a2-F4/aldh1a2-R1/aldh1a2-R6.

Fig 1 .
Fig 1. Efficient integration of loxP sites into the first and second introns of tbx20.a. Diagram of the tbx20 locus.Exons are drawn to scale, introns not to scale.The number below each intron-exon junction indicates reading frame phase.b.Target sites of two highly active intronic tbx20 sgRNAs, tbx20 sgRNA9 and tbx20 sgRNA10, flanking exon 2. Sequence corresponding to single guide RNA is shown in blue, PAM motif is in bold, and expected Cas9 cut site is indicated by a red x.c-f.Integration of loxP site into intron 2 of tbx20.c.The single stranded oligonucleotide used for homology-directed repair was in sense strand with regard to the PAM and had loxP (aqua) site flanked by 3 nucleotide spacer sequences (grey), and 21 nucleotide long homology arms.d.Representative image of the 5' nested PCR reaction used to screen pools of F1 embryos.L, 100 bp DNA ladder (ThermoFisherScientific).1-13, PCR on pools of embryos from 5 different F1 in-crosses (pools from the same F0 pair are grouped, loxP-positive cross is underlined in red).C1 control DNA from embryos injected with tbx20 sgRNA9 and tbx20sg9-loxP HDR oligonucleotide.C2, control DNA from embryos injected with tbx20 sgRNA10 and tbx20sg10-loxP HDR oligonucleotide.e. PCR genotyping of tail clips of adult F1 fish from the F0 in-cross underlined in red in d.Red arrows indicate fish heterozygous for the loxP-containing allele.Yellow arrows indicate fish which likely contain one loxP-containing allele, but presumably lack the wild type allele due to a deletion inherited from the other parent.f.Sequence of the recovered tpl135 allele containing integration of the full-length loxP site with 10-nucleotide partial target site duplication at the 5' of the HDR oligonucleotide.g, h.Experimental design for integration of loxP site into intron 1 of tbx20.g.The single stranded oligonucleotide used for homology-directed repair was antisense to the PAMcontaining strand and had loxP site flanked by 3-nucleotide spacer sequences, 62-nucleotide 5' homology arm and 18-nucleotide 3' homology arm.h.Sequence of the recovered tpl136 allele containing perfect integration of the loxP site.

Fig 2 .
Fig 2. Generation and testing of a conditional ("floxed") tbx20 allele.a. Experimental design.b.Genotyping of adult fish for intron 2 loxP site.c. Results of nested PCR screening for loxP integration into intron 1. d. Sequence of intron 1 loxP integration in recovered tpl145 floxed tbx20 allele.e. Genotyping of "F1" adults.Primer binding sites are shown as black arrows, loxP sites as red or blue triangles, exon as an open box.f, g.Induction of tbx20 loss of function by injection of Cre mRNA.f.One quarter of embryos obtained by in-crossing tbx20 tpl145 heterozygotes and injected with Cre mRNA display a consistent, severe heart development defect.g.Genotyping of embryos with severe heart defects (lanes 1-3) and phenotypically normal siblings (lanes 4-8).L, GeneRuler DNA Ladder (ThermoFisher Scientific).Genotyping lanes 1 and 5 correspond to images in f. h, i. Induction of tbx20 deletion by 4-hydroxytamoxifen.tbx20 tpl145 heterozygote was crossed to Tg(ubi:CreERT2) line.GFP-positive embryos were collected at 2dpf and /128, 28%) with severe heart defects.k.Confirmation of Cre-mediated excision of the second intron of tbx20 by sequence analysis.l, m.Analysis of excision efficiency by qPCR.l.Excision efficiency was assessed by qPCR in embryos treated with 4-HT at various concentrations at different time points and in two different ubb:CreERT2 driver lines.The yaxis indicates un-excised tpl 145 normalized to the untreated control.m.Images of tbx20 phenotypes shown after treatment with 4-HT.Individuals 1, 2, and 3 from l correspond to images labeled 1, 2, and 3. https://doi.org/10.1371/journal.pgen.1007754.g002 3 μM 4-HT (Fig 2l, S1 Table

Fig 3 .
Fig 3. Conversion of a Cre-revertible Gene Breaking Transposon (GBT) allele to a conditional allele.a. Diagram of the fleer locus.Exons drawn to scale, introns not to scale.Below each intron-exon junction reading frame phase is indicated.b.Diagram of the fleer gene trap allele flr tpl19 .c. Diagram flr tpl19R locus reverted by Cre-mediated excision of the gene trap cassette.d.Diagram of flr sgRNA3 target site and antisense oligonucleotide HDR template.e.Sequence of loxP integration into intron 7, resulting in floxed fleer allele tpl141.f, g, h.Cre-mediated excision of exons 2-7 of fleer.f.Induction of fleer deletion by Cre mRNA.g.One quarter of embryos obtained by in-crossing fleer tpl141 heterozygotes and injected with Cre mRNA display a phenotype consistent with fleer tpl19 homozygotes in h, including formation of kidney cysts shown in g' and h'.i.Sequence of the excision amplicon.https://doi.org/10.1371/journal.pgen.1007754.g003 Sibling F1s were raised to adulthood and genotyped.Two out of seventeen analyzed F1 fish from incross A were found to be heterozygous for a deletion of 484 base pairs (Fig 4c, S7 Fig).One out of fifteen analyzed F1 fish from incross B was found to be heterozygous for a deletion of 466 base pairs (Fig 4c, S7 Fig).

Fig 4 .
Fig 4. Mutagenesis of aldh1a2.a. Diagram of the aldh1a2 locus.Exons drawn to scale, introns not to scale.Below each intron-exon junction reading frame phase is indicated.b.Two highly active intronic aldh1a2 sgRNAs, aldh1a2 sgRNA1 and aldh1a2 sgRNA4, flank exon 8. Sequence corresponding to single guide RNA is shown in blue, PAM motif is in bold, and expected Cas9 cut site is indicated by a red x.c.Two independent aldh1a2 exon 8 deletion alleles recovered after co-injection of aldh1a2 sgRNA1 and aldh1a2 sgRNA4 along with nCas9n mRNA.For Sanger sequencing of the alleles, see S3 Fig. d, e. Deletion of exon 8 of aldh1a2 results in expected loss-of-function phenotype.F1 fish heterozygous for aldh1a2 tpl137 and aldh1a2 tpl138 deletions were crossed to each other.d.Images of 3 dpf embryos displaying wild type (top) and the expected aldh1a2 loss of function phenotypes: lack of pectoral fins, shortened hindbrain brain and cardiac edema.In addition, most of the 3 dpf embryos displaying these phenotypes had curved tails (d, bottom) consistent with uneven left/right somite numbers.e. aldh1a2 tpl137/tpl138 trans-heterozygotes lack pectoral fin buds as revealed by loss of tbx18 expression at 32 hpf.f.Expression of tcf21 persists in the first and second branchial arches of aldh1a2 tpl137/tpl138 trans-heterozygotes at 32 hpf.g.Diagram of the HDR template oligonucleotide used to knock in the loxP into aldh1a2 sgRNA1 target site.h.Sequencing of the precise loxP knockin allele.Additional knock-in alleles recovered from other F0 families are shown in S5 Fig. i.Genotyping of 16 phenotypically normal 3 dpf embryos from a cross between F1 fish heterozygous for aldh1a2 tpl139 loxP knock-in results in Mendelian ratios of aldh1a2 tpl139/tpl139 (red arrows), aldh1a2 tpl139/wt (yellow arrows) and aldh1a2 wt/wt embryos.PCR fragments from two of the embryos were sequenced to further confirm homozygosity for the loxP site.

Fig 5 .
Fig 5. Conditional mutagenesis pipeline.Upon deciding which exon to flox, we recommend sequencing the target sites to identify polymorphisms compared to reference genome.Next, sgRNAs should be designed and tested by either direct sequencing of PCR fragments, T7 endonuclease assay or loss of a restriction enzyme site on bulk DNA from pooled embryos.Once active sgRNAs have been identified, experiments integrating the first loxP site should be performed.In the absence of conclusive data that certain HDR template performs significantly better than others (such experiments are not practical at the only level that matters-germline transmission), we recommend using the design we successfully used to integrate loxP into fleer, aldh1a2 and tcf21: antisense to PAM, with 49-base 5' homology arm and 21-base 3' homology arm, with 3-nucleotide spacers flanking loxP site.As injected embryos are being raised, we then recommend to optimize nested PCR screening conditions DNA from pools of injected embryos.We found "plain" Taq polymerases (NEB