Protein tyrosine phosphatase–σ regulates hematopoietic stem cell–repopulating capacity
Mamle Quarmyne, … , Nelson J. Chao, John P. Chute
Mamle Quarmyne, … , Nelson J. Chao, John P. Chute
Published November 21, 2014
Citation Information: J Clin Invest. 2015;125(1):177-182. https://doi.org/10.1172/JCI77866.
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Brief Report Hematology

Protein tyrosine phosphatase–σ regulates hematopoietic stem cell–repopulating capacity

Abstract

Hematopoietic stem cell (HSC) function is regulated by activation of receptor tyrosine kinases (RTKs). Receptor protein tyrosine phosphatases (PTPs) counterbalance RTK signaling; however, the functions of receptor PTPs in HSCs remain incompletely understood. We found that a receptor PTP, PTPσ, was substantially overexpressed in mouse and human HSCs compared with more mature hematopoietic cells. Competitive transplantation of bone marrow cells from PTPσ-deficient mice revealed that the loss of PTPσ substantially increased long-term HSC-repopulating capacity compared with BM cells from control mice. While HSCs from PTPσ-deficient mice had no apparent alterations in cell-cycle status, apoptosis, or homing capacity, these HSCs exhibited increased levels of activated RAC1, a RhoGTPase that regulates HSC engraftment capacity. shRNA-mediated silencing of PTPσ also increased activated RAC1 levels in wild-type HSCs. Functionally, PTPσ-deficient BM cells displayed increased cobblestone area–forming cell (CAFC) capacity and augmented transendothelial migration capacity, which was abrogated by RAC inhibition. Specific selection of human cord blood CD34+CD38CD45RAlin PTPσ cells substantially increased the repopulating capacity of human HSCs compared with CD34+CD38CD45RAlin cells and CD34+CD38CD45RAlinPTPσ+ cells. Our results demonstrate that PTPσ regulates HSC functional capacity via RAC1 inhibition and suggest that selecting for PTPσ-negative human HSCs may be an effective strategy for enriching human HSCs for transplantation.

Authors

Mamle Quarmyne, Phuong L. Doan, Heather A. Himburg, Xiao Yan, Mai Nakamura, Liman Zhao, Nelson J. Chao, John P. Chute

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Figure 2

PTPσ regulates RAC1 activation in HSCs, and RAC1 inhibition abrogates the Ptprs–/– BM cell migration capacity.

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PTPσ regulates RAC1 activation in HSCs, and RAC1 inhibition abrogates th...
(A) At left, flow cytometric analysis of RAC1-GTP levels in BM KSL cells from Ptprs+/+ and Ptprs–/– mice is shown. Numbers represent the percentages of Rac1-GTP+ cells. At right, mean percentages of RAC1-GTP+ KSL cells are shown in Ptprs–/– and Ptprs+/+ mice. *P = 0.008 (n = 3, t test). (B) At left, flow cytometric analysis of RAC1-GTP levels in wild-type BM KSL cells treated with scramble shRNA or PTPσ shRNA is shown. Numbers represent the percentages of RAC1-GTP+ cells. At right, scatter plot of percentage of RAC1-GTP+ KSL cells is shown in each group. Horizontal bars represent mean values. *P = 0.01 (n = 6, t test). (C) Poisson statistical analysis of a limiting dilution assay of 5-week CAFCs from Ptprs–/– versus Ptprs+/+ BM cells. The CAFC frequency for Ptprs–/– BM cells was 1 in 839 cells versus 1 in 3,801 cells for Ptprs+/+ BM cells (n = 10/group, P = 0.0001). (D) Mean numbers of CFCs are shown from the lower chambers of transendothelial migration assays containing Ptprs+/+ BM cells and Ptprs–/– BM cells, treated with and without EHT1864. *P < 0.0001 (n = 12, t test) for total CFCs; **P < 0.0001 for total CFCs (n = 6, t test).