Tovar LM , Burgos CF , Yévenes GE , Moraga-Cid G , Fuentealba J , Coddou C , Bascunan-Godoy L , Catrupay C , Torres A , Castro PA .

             ATP binding
             central nervous system development
             neural tube development

Xla Wt + carbenoxolone (Fig. 2 DEF)

	Figure 1. Cx46 and Cx32 transcripts are enriched during Xenopus laevis Neurulation. (A) RT-qPCR of Cx43, Cx46, Cx45, Cx32, Cx26, Cx31, and Cx25 in the process of formation of the neural tube of Xenopus laevis N = 4. (B) Comparative analysis of expression of Cxs in the closure of the neural tube of Xenopus laevis N = 4. Transcriptional expression was normalized to the sub-1 control gene. One-way ANOVA, Dunnett’s correction, (* = p < 0.05; ** = p < 0.01; *** = p < 0.001; **** = p < 0.0001; ns = not significant). The error bars of the data correspond to the standard deviation.
	Figure 2. Pharmacological blockade of Cxs with CBX induces NTDs. (A) The diagram depicts the stage (Stg) where CBX was initially applied to embryos (Stg 12.5 = 14 hpf). (B) Representative photographs of embryos at stg 20 under control conditions (top) or treated with CBX (30 or 50 μM, middle and bottom, respectively). Dashed white lines mark the border between superficial neural and non-neural ectoderm, and dashed black lines indicate midline. Red arrowheads indicate the distance of neural folds (closed phenotype = normal; open phenotype = abnormal); scale bar = 500 μm. (C) The graph shows the percentage of open and closed phenotypes of embryos treated in the absence (control = ctl) or presence of CBX (3–300 µM; IC50 = 21.05 μM ± 1.22). (D) Quantification of open phenotype in embryos at stg 20 treated with CBX (IC50 = 58.56 μM ± 2.98). (E) The phenotype of tadpoles (stg 41–43) treated with CBX at stg 12.5–20. Scale bar = 1 mm. (F) The graph shows the effect of CBX on the length of Xenopus tadpoles. Independent fertilized embryos (N = 6) were analyzed for conditions (10 experimental replicates). One-way ANOVA, Dunnett’s correction, (*** = p < 0.001; **** = p < 0.0001; ns = not significant). Error bars represent the standard deviation.
	Figure 3. Lucifer Yellow uptake is modulated by FGF2 and DTT in neural plates. (A–G) Representative images of the neural tube closure process in the control condition, DTT, DTT/CBX, DTT/ENX, FGF2, FGF2/CBX, and FGF2/ENX. (A’–G’) Neural plate cell fluorescence, illustrating LY uptake in control conditions, DTT, DTT/CBX, DTT/ENX, FGF2, FGF2/CBX, and FGF2/ENX. Scale bar: 200 µm. The upper panel images show a magnification of the boxes in (A’,B’,E’) signaling LY uptake, respectively. Scale bar (A’’,B’’,E’’): 20 μm. Scale bar magnified boxes: 20 μm. (H) Comparison of positive LY cells under redox potential (DTT) and FGF2 conditions, quantification normalized to control condition (MMR 10%). (I) Quantification of LY cells after exposure to DTT. (J) Quantification of LY cells after exposure to FGF2. N = 3 groups of independent fertilized embryos and 5 replicates for each condition. One-way ANOVA, Bonferroní comparison test, (** = p < 0.01; **** = p < 0.0001; ns = not significant). Error bars for data represent standard deviation.
	Figure 4. ATP Release during neurulation is regulated by HCs-Cxs modulators. Using luminescence assays (A), extracellular and intracellular ATP (nM) were quantified and normalized to the calibration curve. (B) Embryos treated with redox potentials. (C) Embryos treated with mitogenic factors. The results correspond to at least four experiments conducted independently (N = 4), for each condition. One-way ANOVA, Bonferroní comparison test, (* = p < 0.05; ** = p < 0.01; *** = p < 0.001; **** = p < 0.0001; ns = not significant.). The error bars for the data represent the standard deviation.
	Figure 5. Cavities identified in the hemichannel of connexin 46. Hemichannel is visualized in a 90° rotation (x-axis). (A) Structure of HC-Cx46 representing the three best cavities; cavity 1 = 0.795, cavity 12 = 0.883, and cavity 17 = 0.634 calculation carried out with Fpocket. (B–D) The chain structure of Cx46 represents the three best cavities found by Fpocket. Summary table, detailing drugability score, amino acid residues, chains, and domains.
	Figure 6. Molecular docking of CBX and ENX in the structure of HCs-Cx46. (A–C) Representative interaction between HCs-Cx46, CBX (magenta), and ENX (light blue) in the three cavity predicted previously. All the chains are identical, each monomer is represented with a different color to facilitate the identification of the regions between subunits. Comparison of CBX/ENX docking in the NT domains of HCs-Cx46. 2D diagram of the interactions identified for HCs-Cx46. The CBX and ENX binding site residues that interact with the NT of HC-Cx46 are shown schematically and colored according to their physicochemical properties. The arrows indicate the directionality of the hydrogen bond and the degraded line represent a salt bridge. Plots of docking scores and theoretical binding ΔG between CBX/ENX interactions with HCs-Cx46.
	Figure S1. RT-PCR for Cx43, Cx46, Cx45, Cx32, Cx26, Cx31 y Cx25 at different stages of the development of Xenopus laevis. Lane 1. Gas (Gastrula stage 10), Lane 2. Ely (early stage 12.5), Lane 3. Int (Intermediate stage 14), Lane 4. Lte (Late stage 19-20), Lane 5. A.B. (Adult Brain) and Lane 6. Mcr (Marker 100 bp).
	Figure S2. Pharmacological blockade of Cxs with ENX induces NTDs. A. The diagram depicts the stage (Stg) where ENX was initially applied to embryos (Stg 12.5 = 14 hpf). B. Representative photographs of embryos at stg 20 under control conditions (top) or treated with ENX (30 or 50 M, middle and bottom, respectively). Dashed white lines mark the border between superficial neural and non-neural ectoderm, dashed black lines indicate midline. Red arrow heads indicate the distance of neural folds (closed phenotype= normal; open phenotype= abnormal); scale bar = 500 μm C. The graph shows the percentage of open and closed phenotype of embryos treated in the absence (control= ctl) or presence of ENX (3-300 µM; IC50= 47.83 μM ± 2.31) D. Quantification of open phenotype in embryos at stg 20 treated with ENX (IC50= 67.74 μM ± 4.19). E. Phenotype of tadpoles (stg 41-43) treated with ENX at stg 12.5-20. Scale bar = 1 mm. F. The graph shows the effect of CBX on the length of Xenopus tadpoles. Independent fertilized embryos (N=6) were analyzed for condition (10 experimental replicates). One-way ANOVA, Dunnett's correction, ** = p<0.01; *** = p<0.001; ns= not significant). Error bars represent the standard deviation.
	Figure S3. Molecular docking and involved amino acids of HC-Cx46 with carbenoxolone and enoxolone. A-F. Determination of CBX and ENX interaction site in HCs-Cx46, determined AutoDock Vina; summary table of amino acid residues involved in HC-Cx46/CBX (A, C, E) and HC-Cx46/ENX (B, D, F) interaction. Interactions with best binding energy score (-6.2 Kcal/mol (pocket 1); -4.8 Kcal/mol (pocket 12); -7.7 Kcal/mol (pocket 17) CBX) (-6.3 Kcal/mol (pocket 1); -5.3 Kcal/mol (pocket 12); -7.8 Kcal/mol (pocket 17) ENX). In blue (CBX) and green (ENX), regions identified for the docking of pharmacological blockers in HCsCx46.
	Figure S4. Cx46 is expressed during Neurulation in Xenopus laevis. A, Representative western blot showing the expression of cx46 in different stages of Neurulation in Xenopus. Lane 1 corresponds to stage 12; lanes 2 corresponds to stage 15; lane 3 corresponds to stage 20. A molecular weight marker is indicated with an arrow. B. Densitometric quantification of cx46 signal normalized by the total amount of protein loaded in each lane. Bars correspond to average ± ES. (** = p<0.01; n=4). C. Dot Blot Assay Anti-Cx46. a-c. Positive control (peptide sequence: CRLPSRNSRHSSNRS). d. Mouse cerebral Cortex. e. Xenopus laevis embryos stage 20.

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