![Figure 2. HSC, progenitor, and lineage reconstitution by β-/γ-catenin negative BM precursors. (A) Density plots show the abundance of CD45.2+ BM cells in the lineage-negative (lin−) hematopoietic progenitor compartment of mice reconstituted with a mixture of experimental (CD45.2+) and wild-type (CD45.1+) BM cells. Shown are the abundances of LSK cells (lin−, Sca-1+ CD117+), multipotent progenitors (lin− Sca-1− CD117+), common lymphoid progenitors (lin− CD127+ CD117low), and lymphoid-primed multipotent progenitor (lin− Sca-1+ CD117+, CD135+) among CD45.2+ cells. (B) Gated CD45.2+ BM cells were analyzed for the presence of myeloid (granulocytes, CD11b+, GR1+, and monocytes, CD11b+ GR1−), erythroid (CD71+ TER119+) and lymphoid (B220+) lineage cells. B-cell development was further dissected by the separation into CD43+ B220+ (fraction A-C′,46), CD43− B220+ IgM− (fraction D), and B220+ IgM+ (fraction E, F) subsets. Data show a representative analysis (of a total of 5 to 7 performed using 3 independent donor fetuses) after 7 months of reconstitution of secondary recipients. In panels A and B, numbers on graphs are percentage of total cells in the delineated regions. (C) PCR for β- and γ-catenin deletion on genomic DNA isolated from CD45.2+ BM cells 7 months after competitive reconstitution with catenin deleted BM. The mutant (indicated as null) and wild-type (wt) γcatenin alleles are detected as 150 bp and 300 bp PCR products, respectively. The floxed (indicated as lox) and deleted (Δ-) β-catenin alleles yield 183 bp and 481 bp bands, respectively. (D) Quantification of β-catenin deletion by Southern analysis of Sac1 restricted genomic DNA isolated from CD45.2+ BM cells 7 months after competitive reconstitution with β-catenin–deleted BM. The floxed (indicated as lox), deleted (Δ) and wild-type (wt) β-catenin alleles give rise to 7.4-, 5.2-, and 4.0-kb fragments, respectively. Note the virtually complete deletion of the β-cateninlox allele on Cre-mediated recombination. (E) Total cellular lysates from flow sorted wild-type (CD45.1+) and mutant (CD45.2+) BM cells of the indicated genotypes were subjected to immunoblot analysis with mAbs to the COOH terminus of β-catenin (clone 14) and to tubulin (to ensure equal protein loading). Note the virtually complete absence of the full-size β-catenin protein upon Cre–mediated recombination. The smaller β-catenin protein species fail to interact with TCF-1 and do not interfere with TCF/LEF mediated transcription (see “Discussion” and Figure S1 [available on the Blood website; see the Supplemental Materials link at the top of the online article]).](https://ash.silverchair-cdn.com/ash/content_public/journal/blood/111/1/10.1182_blood-2007-07-102558/3/zh80030811830002.jpeg?Expires=1724176016&Signature=XKHo7V7LBBe-HhrL7HyOHwSqa~pXuEyVYypjC5HWW-Gz-qVJCpYAwtxf1hYCR1SI8xR27FVFx3P8ReYFrFFjM5cjNQsSf0JuYpIaH3eezliksl~B2nLV7LuGFKYPKGDS~uCT4dJlPUaK~HOBRMwtkrWkWG06SK8Q861yocPrxobwhCVnaQQaGDfJluOC~zwJbHzpc1-VNBQmuUW4ZvhEgGCgMpkwFHntiqHT-cBCc5h1RyWy-eMatqyRM6Kfr2B1cmDZe8~kqJPGUyWh4I7qcaLuJhj3OteiRHb-RvgnJmHHWg-Xp2UR1QGJIwpBH6QM96LMZqVhK~uEMJetmC5KIQ__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
HSC, progenitor, and lineage reconstitution by β-/γ-catenin negative BM precursors. (A) Density plots show the abundance of CD45.2+ BM cells in the lineage-negative (lin−) hematopoietic progenitor compartment of mice reconstituted with a mixture of experimental (CD45.2+) and wild-type (CD45.1+) BM cells. Shown are the abundances of LSK cells (lin−, Sca-1+ CD117+), multipotent progenitors (lin− Sca-1− CD117+), common lymphoid progenitors (lin− CD127+ CD117low), and lymphoid-primed multipotent progenitor (lin− Sca-1+ CD117+, CD135+) among CD45.2+ cells. (B) Gated CD45.2+ BM cells were analyzed for the presence of myeloid (granulocytes, CD11b+, GR1+, and monocytes, CD11b+ GR1−), erythroid (CD71+ TER119+) and lymphoid (B220+) lineage cells. B-cell development was further dissected by the separation into CD43+ B220+ (fraction A-C′,46 ), CD43− B220+ IgM− (fraction D), and B220+ IgM+ (fraction E, F) subsets. Data show a representative analysis (of a total of 5 to 7 performed using 3 independent donor fetuses) after 7 months of reconstitution of secondary recipients. In panels A and B, numbers on graphs are percentage of total cells in the delineated regions. (C) PCR for β- and γ-catenin deletion on genomic DNA isolated from CD45.2+ BM cells 7 months after competitive reconstitution with catenin deleted BM. The mutant (indicated as null) and wild-type (wt) γcatenin alleles are detected as 150 bp and 300 bp PCR products, respectively. The floxed (indicated as lox) and deleted (Δ-) β-catenin alleles yield 183 bp and 481 bp bands, respectively. (D) Quantification of β-catenin deletion by Southern analysis of Sac1 restricted genomic DNA isolated from CD45.2+ BM cells 7 months after competitive reconstitution with β-catenin–deleted BM. The floxed (indicated as lox), deleted (Δ) and wild-type (wt) β-catenin alleles give rise to 7.4-, 5.2-, and 4.0-kb fragments, respectively. Note the virtually complete deletion of the β-cateninlox allele on Cre-mediated recombination. (E) Total cellular lysates from flow sorted wild-type (CD45.1+) and mutant (CD45.2+) BM cells of the indicated genotypes were subjected to immunoblot analysis with mAbs to the COOH terminus of β-catenin (clone 14) and to tubulin (to ensure equal protein loading). Note the virtually complete absence of the full-size β-catenin protein upon Cre–mediated recombination. The smaller β-catenin protein species fail to interact with TCF-1 and do not interfere with TCF/LEF mediated transcription (see “Discussion” and Figure S1 [available on the Blood website; see the Supplemental Materials link at the top of the online article]).
