Figure 1.
RET is functionally active in CD34+CD38– HSPCs, and cell surface expression enriches for HSC function. (A) Kinase activity alterations between CD34+CD38– HSPCs (green) and CD34+CD38+ HPCs (lilac). (B) Process network enrichment for significantly altered kinases and phosphorylation events from panel A. (C) z-normalized geometric mean fluorescence intensity of cell surface RET within the indicated populations. Significance was tested by using a paired Student t test for individual cord blood donors tested (N = 9). (D) Plot depicting frequencies and confidence interval for REThi (red) and RETlow (blue) CD34+CD38– cell in vivo engraftment at limiting dilution after 12 weeks (N = 3 mice per dose tested). (E) Table of 1/stem cell frequency numerical data calculated from the in vivo limiting dilution analysis presented in panel D, including: estimated stem cell frequency, upper and lower intervals of estimation, χ2 test, and estimated P value.

RET is functionally active in CD34+CD38HSPCs, and cell surface expression enriches for HSC function. (A) Kinase activity alterations between CD34+CD38 HSPCs (green) and CD34+CD38+ HPCs (lilac). (B) Process network enrichment for significantly altered kinases and phosphorylation events from panel A. (C) z-normalized geometric mean fluorescence intensity of cell surface RET within the indicated populations. Significance was tested by using a paired Student t test for individual cord blood donors tested (N = 9). (D) Plot depicting frequencies and confidence interval for REThi (red) and RETlow (blue) CD34+CD38 cell in vivo engraftment at limiting dilution after 12 weeks (N = 3 mice per dose tested). (E) Table of 1/stem cell frequency numerical data calculated from the in vivo limiting dilution analysis presented in panel D, including: estimated stem cell frequency, upper and lower intervals of estimation, χ2 test, and estimated P value.

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