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	Fig. 1 Single gene disruption targeting genes involved in NC development in X. tropicalis embryos. a Schematic diagram of sgRNA-guided Cas9 nuclease interacting with the DNA target site. The red letters indicate the target site, the green letters indicate the PAM and the blue letters indicate the sequence of tracer RNA. b Schematic drawing of Cas9 target site (protospacer). The protospacer adjacent motif (PAM) 3′ to the protospacer is highlighted in red. The seed region which consists of 12 nucleotides immediate 5′ to PAM is shown in blue. c T7E1 assay of somatic mutations induced by pax3, snai1, ctnnb, sox9, or Ap2α sgRNAs and Cas9 nuclease. d Somatic mutation rate calculated from T7E1 assay in (c). e DNA sequences targeted by sgRNAs at the indicated gene loci and representative somatic mutations induced in X. tropicalis embryos. PAM is underlined and highlighted in green. Deleted sequences are highlighted in gray with red dashes while insertions are indicated by lowercase letters in blue. The parentheses enclosed the number of deleted or inserted base pairs, while the square brackets show the frequencies of the mutation in the sequenced samples
	Fig. 2 Duplex indel mutations in single embryo. a, d T7E1 assay of duplex indel mutations in the loci of pax3 and zic1 (a) or snail1 and snail2 (d) in five single embryos. b, e Quantification of the T7E1 assay in (a) or (d). c, f Representative sequencing data confirmed the indel mutations induced at the two target loci in one single embryo
	Fig. 3 Segmental deletions and inversions induced by Cas9 and a pair of sgRNAs in X. tropicalis embryos. a Schematic diagram showing the structure of X. tropicalis pax3 and snail1 genes, and the sgRNA targeting sequences and their locations in the two genes. b Schematic diagram illustrating detection of segmental deletion and inversion at targeted loci with PCR. c, d PCR assay and subsequent sequencing detected segmental deletions and inversion at pax3 locus (c) and snail1 locus (d). The embryos injected with Cas9 and indicated sgRNAs were collected at 2 days after fertilization. Five embryos were pooled for DNA extraction. T1, embryos injected with Cas9 mRNA and sgRNA T1; T2, embryos injected with Cas9 mRNA and sgRNA T2; T1 + T2, embryos injected with mixture of Cas9 mRNA, sgRNA T1 and sgRNA T2. F forward primer; R reverse primer
	Fig. 4 Off-target effects of CRISPR/Cas9 in X. tropicalis evaluated via T7E1 assay. a Representative gel image of T7E1 digested off-target amplicons. The percentage under panels indicated the frequencies of off-target effects. b Quantification of the cleavage frequencies of all off-target sites. No clear and specific bands after T7E1 assay were generated at sox9-579 and lrig3-E306 loci. The cutting efficiencies at sox9-579 and lrig3-E306 sites were calculated by sequencing results. Red dash line indicated 10 % in indels efficiency
	Fig. 5 Double-nicking induced efficient genome editing with lower off-target effects. a Two sgRNA targeting sites in sox9. Letters in blue is the target site 1 while letters in red is the target site 2. The red arrows point the predicted cleavage sites, and the PAMs are underlined. b Sequencing data of the indels induced by D10A and the sgRNA pairs. Letters in bold is the wild type sequence, red dashes indicate deletions. c T7E1 assay of genome editing induce by wide-type Cas9 or by D10A. d Quantification of the T7E1 assay shown in (c). e Mutagenesis at a representative off-target locus (sox9-600) induced by Cas9 and sox9 T1gRNA or by D10A and sox9 T1 and T2 sgRNAs. PCR was performed to amplify the targeted sox9-600 locus. Amplicons harboring targeted gene fragments were TA-cloned into pMD-18T. The indel mutagenesis rates were calculated by direct sequencing. (f) Comparison of the off-target efficiency induced by D10A with double nicking versus wide type Cas9 with sox9 sgRNA

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