Suzuki S , Sasaki K , Fukazawa T .

             interleukin-11-mediated signaling pathway
             tissue regeneration

	Figure 1. X. laevis Il11ra.L functions as an Il11 receptor component. (A) Gene expression involved in Il11 signaling in the XTC-YF cell line. (B–D) Oocyte culture supernatants were subjected to SDS-PAGE, followed by (B) CBB staining and (C) Western blotting using anti-FLAG antibody and (D) mouse IgG2b isotype control. Size of the synthesized proteins estimated by their amino acid sequences was: Il11, 22.2 kDa; Lif, 25.5 kDa; and GST, 28.4 kDa. Arrowheads in (B) indicate the synthesized proteins. The 66.4-kDa bands (asterisk) in (B) the CBB staining represent BSA contained in the culture medium. (E–Q) Detection of XTC-YF P-Stat3 nuclear translocation by immunostaining. (Top) P-Stat3 signal is shown in red. (Middle) Nuclei were stained with DAPI. (Bottom) Merged images of P-Stat3 and DAPI staining. Data shown are representative of 3 independent experiments (except the experimental condition of Il11 50 ng/mL; n = 2). Scale bars: 50 µm. Raw images of the gel and blots are shown in Fig. S8.
	Figure 3. il11ra.L is widely and constitutively expressed in the intact tadpole and regenerating tail. (A) In situ hybridization of il11ra.L on a section of intact tadpole (upper) with an antisense probe, and (lower) with a sense probe. Anterior is left and dorsal is up. Scale bars: 500 µm. n = 4. (B–D) In situ hybridization of il11ra.L in a section of a regenerating tail. Anterior is left and dorsal is up. Arrowheads indicate notable signals. Scale bars: 500 µm. High magnification images of boxed areas in (C) and (D) are shown below. Scale bars: 100 µm. 1 dpa, n = 5; 3 dpa, n = 4; 5 dpa, n = 5.
	Figure 4. il11ra.L KO cells can contribute to form the regenerated tail. Estimated mutation ratio at the guide RNA #1 target site of the developmental and regenerated tail of each individual is shown. Linked points represent the same individual. n = 24. P = 0.44, paired t-test. Representative result of 2 experiments is shown. The result of the second experiment is shown in Fig. S7.
	Supplementary Fig. S1 Expression of Il11 signaling molecules in XTC-YF culture cell line and establishment of XTC-YF il11ra.L KO cell lines. (A) Expression levels of genes related to Il11 signaling measured by quantitative RT-PCR using 3 lots of RNA extracted from XTC-YF. Relative expression levels of the genes normalized by those of ef1a are shown in logarithmic scale. Bars indicate the mean value. (B and C) Genomic il11ra.L sequences of established XTC-YF il11ra.L KO cell lines. (B) KO1 and KO2 were established with guide RNA #1, (C) KO3 and KO4 were established with guide RNA #2. PAM, protospacer adjacent motif.
	Supplementary Fig. S2 Construction of mRNAs of (left) N-terminal 3×flag-tagged il11.L, (center) N-terminal 3×flag-tagged gst, and (right) C-terminal flag-tagged lif.L.
	Supplementary Fig. S3 Heteroduplex mobility assay (HMA) for detection of gene editing. (A) Schematic figure of HMA. (B and C) HMA on amputated tails. Genomic loci including the target site of (B) guide RNA #1 or (C) #2 were amplified by PCR. Smeared bands representing multiple heteroduplexes are shown from the PCR products derived from embryos injected with guide RNA and cas9 mRNA (KD), whereas single bands are shown from control embryos injected with only cas9 mRNA (cas9). Numbers represent the serial numbers of samples. M, Marker lane. Full-length gel images are presented in Fig. S9.
	Supplementary Fig. S4 Expression of genes that are significantly upregulated in cas9 24 hpa tail stumps compared with cas9 0 hpa tail, and 0 and 24 hpa il11ra.L KD tail stumps. TPM, transcriptions per million.
	Supplementary Fig. S5 il11ra.L expression in single cell RNA-seq of regenerating tails reported by Aztekin et al.1 is visualized with the web platform (Xenopus tail regeneration at single cell resolution; https://marionilab.cruk.cam.ac.uk/XenopusRegeneration/).
	Supplementary Fig. S6 Schematic of the putative mechanism of Il11 function. (A) Putative models of the mechanism of Il11 function. Direct model; Il11 directly activates stem cells or precursors of each tissue in the tail. Indirect model; Il11 triggers downstream events that activate stem cells or precursors of each tissue in the tail. Il11R, Il11 receptor complex. (B) Experimental procedure. (C) Putative behaviors of il11ra.L KO cells in both models and results of the mutation ratio comparison.
	Supplementary Fig. S7 Second result of the mutation ratio estimation of developmental and regenerated tails. n=16. P=0.79, paired t-test.

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