Supplementary MaterialsSupplementary information, Figure S1: Schematic of intracellular fucosylation mediated by Slc35c1 and Fut9. the sensitivity of cells to ricin, whereas its overexpression renders cells more resistant to the toxin. Thus, we have provided unprecedented insights into an evolutionary conserved modular sugar code that can be manipulated to control ricin toxicity. encodes a GDP-fucose transporter residing in the Golgi and encodes a Golgi 1,3-fucosyltransferase (Supplementary information, Figure S1A)15,16. To investigate potential roles of these genes and of fucosylation in ricin toxicity, we generated mouse embryonic stem cells (mESCs, haploid state) harboring a reversible gene trap in the first exon of or (Supplementary information, Figure S1B). Mutant clones harboring the gene trap in the sense MPT0E028 orientation (knockout, KO) were GFP-positive (GFP+). Their respective wild-type (WT) sister clones, generated by infection with a virus encoding both mCherry and Cre recombinase, which reverses the gene trap and reconstitutes WT gene expression, were mCherry+. Loss of or in diploid murine ESCs did not affect embryonic stem cell identity, pluripotency (Supplementary information, Figure S1C), growth rates or survival, as indicated by constant ratios of GFP+/mCherry+ cells in culture. Upon treatment with ricin, however, multiple independently targeted and KO clones (GFP+) showed a survival advantage over reverted WT sister clones (mCherry+; Figure 1A and Supplementary information, Figure S2A). In line with previous findings10,11, and KO single-cell clones (diploid) showed an 10-fold increase in the LD50 of ricin compared to their WT sister clones (Figure 1B and ?and1C).1C). A comparable phenotype of increased resistance was observed when we used the ricin homologue RCA120 (Supplementary information, Figure S2B). Open in a separate window Figure 1 Loss of and protects cells from ricin toxicity. (A) Randomly mutagenized single-cell mESC clones were exposed to ricin (2 ng/ml) for 10 days and ratios of GFP+/mCherry+ cells were measured. Isolated, ricin-resistant, mutant clones were then analyzed via inverse PCR and their integration sites were determined. All clones were found to harbor the MPT0E028 gene trap in sense orientation at the indicated intronic sites (green arrows) of either (asterisks) or (black triangles). (B) Survival of mESCs harboring a gene trap in either or in sense (KO) MPT0E028 or antisense (WT) orientation in the presence of the indicated concentrations of ricin. Alamar Blue cell viability assay was used to determine cell survival. Data are representative of three independent experiments. (C) Independent and mutant (KO) and reverted WT mESC sister clones were grown in the presence or absence of ricin (8 ng/ml). Representative images are shown. Scale bar, 100 m. (D) Mixed populations of unlabeled WT and mutant (KO) mESCs were exposed to different concentrations of ricin for 3 days. The amount of fucose (detected by AAL) and Lewis X (SSEA-1, CD15) expressing cells was monitored by immunofluorescence microscopy (upper panels) and flow cytometry (lower panels). Scale bar, 50 m. Slc35c1 and Fut9 are required to generate the Lewis X epitope (SSEA-1, CD15; Supplementary information, Figure S1A), a prominent stem cell marker17. Indeed, and KO mESC clones lacked the fucose-containing SSEA-1 epitope on their cell surfaces (Supplementary information, Figure S2C). Loss of fucosylation was validated by reduced staining with Lectin MPT0E028 (AAL; Supplementary information, Figure S2D), which selectively binds fucose. Next, we generated mixed cell populations of (or WT (gene. Loss of Slc35c1 activity strongly protected MEFs from various concentrations of ricin, even at late time points (Figure 2A and ?and2B;2B; Supplementary information, Figure S3A). Notably, KO MEFs completely lacked fucosylated structures (Figure 2C). As ricin ingestion can lead to accidental intoxication19, we investigated intestinal organoid cultures (mini-guts) generated from WT and KO mice (Supplementary information, Figure S3B). As expected, ricin treatment of WT organoids triggered pronounced morphological changes and loss of regenerative capacity compared to untreated controls. However, in the presence of ricin, KO organoids showed improved morphological integrity and increased survival compared Mouse monoclonal to CD19.COC19 reacts with CD19 (B4), a 90 kDa molecule, which is expressed on approximately 5-25% of human peripheral blood lymphocytes. CD19 antigen is present on human B lymphocytes at most sTages of maturation, from the earliest Ig gene rearrangement in pro-B cells to mature cell, as well as malignant B cells, but is lost on maturation to plasma cells. CD19 does not react with T lymphocytes, monocytes and granulocytes. CD19 is a critical signal transduction molecule that regulates B lymphocyte development, activation and differentiation. This clone is cross reactive with non-human primate to WT controls (Figure 2D and ?and2E;2E; Supplementary information, Figure S3B). Moreover, splenocytes isolated from KO mice survived significantly higher doses of ricin than those from WT mice (Supplementary information, Figure S3C). Finally, homozygous KO mice that were exposed to sub-lethal dosages of ricin showed decreased weight loss compared to WT littermates (Supplementary information, Figure S3D). Thus, Slc35c1 plays a broad role.