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S. doi:10.1371/journal.pone.0060903.gxenopus CTLA-4 chimeras showed a similar pattern to human the chimeric trout CTLA-4 displayed an almost linear relationship between cycling and surface CTLA-4 (Homotaurine Figure 2D) typical of a cell surface protein, again suggesting impaired CTLA-4 endocytosis in trout. To directly measure the rates of endocytosis we stained the cell surface pool of CTLA-4 on ice with an unconjugated antibody. Cells were then warmed to 37uC for the indicated time-points to allow any internalisation 1676428 of surface CTLA-4 to take place. Cells were then placed on ice, and any CTLA-4 remaining at the cell surface detected with an Alexa647 conjugated secondary antibody. Accordingly, in this assay the loss of Alexa647 staining over time reflects endocytosis of CTLA-4. Using this assay, human CTLA-4 showed a comparable rate of endocytosis to the 22948146 chimeric xenopus and chicken constructs (Figure 3A), internalising 50 or more within 5 minutes. In contrast, chimeric trout CTLA-4 showed a much slower rate of endocytosis taking at least 30 minutes to achieve 50 internalisation. Nevertheless, chimeric trout CTLA-4 did internalise compared to a control CTLA-4 chimera with a cytoplasmic domain from CD86, which is a plasma membrane resident in CHO cells (Figure 3A). However, it was clear that even for surface proteins (CTLA-4-CD86) there was a small decrease in signal over time in this assay, which was not due to endocytosis, further SMER-28 chemical information emphasising the much reduced endocytic nature of the trout chimera. Since internalisation of CTLA-4 occurs via an AP-2 mediated, clathrin-dependent pathway [3,5,6], treatment with hypertonic sucrose can be used to inhibit the formation of clathrin-coated vesicles [13]. We therefore tested the effect of sucrose treatment on human CTLA-4 and the chimeric constructs. As shown in figure 3B sucrose treatment inhibited the endocytosis of CTLA-4 molecules. In particular the more rapid endocytosis seen in chicken, xenopus and human CTLA-4 chimeras (relative to trout) was prevented by sucrose treatment. Overall, this data suggests that the chimeras internalise via a clathrin dependent pathway. The transferrin receptor is well characterized and internalizes by clathrin-dependent endocytosis using signals encoded in the cytoplasmic tail [14]. Using transferrin as a marker for the clathrin pathway, we compared the co-localisation of the CTLA-4 chimeras with transferrin. Cells were incubated with transferrin AlexaFluor633 and anti-CTLA-4 PE at 37uC for 45 minutes and subsequently fixed and analysed by confocal microscopy. This revealed that human, chicken and xenopus CTLA-4 co-localised with transferrin in intracellular vesicles, suggesting CTLA-4 internalisation overlaps with the transferrin receptor consistent with both proteins utilizing the clathrin-dependent pathway (Figure 3C). Additionally, this assay revealed limited but detectable co-localisation between trout CTLA-4 and transferrin, further suggesting that trout CTLA-4 does internalise via clathrin albeit at a reduced rate. Whilst trout CTLA-4 lacked the conserved YVKM internalisation motif found in mammals, it did appear to have a putative YxxF motif [12], which could possibly mediate endocytosis. We therefore tested whether this motif contributed to the internalisation observed with the chimeric trout CTLA-4. We mutated this tyrosine residue to a valine and examined the behaviour of this mutant in CHO cells. A comparison of internalisation rates indicated the VGNF mut.S. doi:10.1371/journal.pone.0060903.gxenopus CTLA-4 chimeras showed a similar pattern to human the chimeric trout CTLA-4 displayed an almost linear relationship between cycling and surface CTLA-4 (Figure 2D) typical of a cell surface protein, again suggesting impaired CTLA-4 endocytosis in trout. To directly measure the rates of endocytosis we stained the cell surface pool of CTLA-4 on ice with an unconjugated antibody. Cells were then warmed to 37uC for the indicated time-points to allow any internalisation 1676428 of surface CTLA-4 to take place. Cells were then placed on ice, and any CTLA-4 remaining at the cell surface detected with an Alexa647 conjugated secondary antibody. Accordingly, in this assay the loss of Alexa647 staining over time reflects endocytosis of CTLA-4. Using this assay, human CTLA-4 showed a comparable rate of endocytosis to the 22948146 chimeric xenopus and chicken constructs (Figure 3A), internalising 50 or more within 5 minutes. In contrast, chimeric trout CTLA-4 showed a much slower rate of endocytosis taking at least 30 minutes to achieve 50 internalisation. Nevertheless, chimeric trout CTLA-4 did internalise compared to a control CTLA-4 chimera with a cytoplasmic domain from CD86, which is a plasma membrane resident in CHO cells (Figure 3A). However, it was clear that even for surface proteins (CTLA-4-CD86) there was a small decrease in signal over time in this assay, which was not due to endocytosis, further emphasising the much reduced endocytic nature of the trout chimera. Since internalisation of CTLA-4 occurs via an AP-2 mediated, clathrin-dependent pathway [3,5,6], treatment with hypertonic sucrose can be used to inhibit the formation of clathrin-coated vesicles [13]. We therefore tested the effect of sucrose treatment on human CTLA-4 and the chimeric constructs. As shown in figure 3B sucrose treatment inhibited the endocytosis of CTLA-4 molecules. In particular the more rapid endocytosis seen in chicken, xenopus and human CTLA-4 chimeras (relative to trout) was prevented by sucrose treatment. Overall, this data suggests that the chimeras internalise via a clathrin dependent pathway. The transferrin receptor is well characterized and internalizes by clathrin-dependent endocytosis using signals encoded in the cytoplasmic tail [14]. Using transferrin as a marker for the clathrin pathway, we compared the co-localisation of the CTLA-4 chimeras with transferrin. Cells were incubated with transferrin AlexaFluor633 and anti-CTLA-4 PE at 37uC for 45 minutes and subsequently fixed and analysed by confocal microscopy. This revealed that human, chicken and xenopus CTLA-4 co-localised with transferrin in intracellular vesicles, suggesting CTLA-4 internalisation overlaps with the transferrin receptor consistent with both proteins utilizing the clathrin-dependent pathway (Figure 3C). Additionally, this assay revealed limited but detectable co-localisation between trout CTLA-4 and transferrin, further suggesting that trout CTLA-4 does internalise via clathrin albeit at a reduced rate. Whilst trout CTLA-4 lacked the conserved YVKM internalisation motif found in mammals, it did appear to have a putative YxxF motif [12], which could possibly mediate endocytosis. We therefore tested whether this motif contributed to the internalisation observed with the chimeric trout CTLA-4. We mutated this tyrosine residue to a valine and examined the behaviour of this mutant in CHO cells. A comparison of internalisation rates indicated the VGNF mut.

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