Figure 1
Figure 1. Phenotypic and gene expression response of K562 and K562Runx1KD cells to TPA treatment. (A) Quantitative RT-PCR and Western blot analysis of RUNX1 expression in untreated (U.T) and TPA-treated (TPA) cells as well as in TPA-treated cells stably expressing shRNA-miR (K562RUNX1KD), which knocked down RUNX1 expression (KD) compared with nonsilencing shRNA-miR control (Neg). Quantitative RT-PCR data are mean ± SD of 2 independent experiments performed in triplicates. Western blot of nuclear extract using anti-RUNX1 antibodies. Emerin was used as control of protein loading (supplemental data). (B) Proliferation assay using K562-TPA Neg (red) and KD (blue) cells. A total of 1 × 106 cells were grown in culture and counted every 24 hours. TPA was added 48 hours after seeding of cells. Data are mean ± SD of 2 independent experiments performed in triplicates. (C) Cell morphology changes. Representative microscopic images of May-Grunwald-Giemsa stained untreated (U.T), TPA, TPA Neg, and TPA KD K562 cells. Images were viewed with a Nikon Eclipse 800 microscope with a 100×/1.25 numeric aperture oil objective lens, captured using a Nikon DXM1200 digital camera, and processed with Nikon ACT-1 2.63 software. (D) Expression of megakaryocytic markers in K562 (Control) and K562RUNX1KD (KD) in response to TPA. Quantitative RT-PCR analysis of ITGA2B (CD41), ITGB3 (CD61), and CD9 expression in K562 cells. Data are mean ± SD of 2 independent experiments performed in quadruplicates. The decreased expression in TPA-treated K562RUNX1KD relative to K562 control was significant (P < .01) for all 3 markers. Primers used for quantitative RT-PCR assays are listed in supplemental Table 2. (E) TPA-induced transcriptional changes. Genes are plotted based on their expression level (log scale) in K562-TPA cells versus their basal level in untreated cells. Genes showing 2-fold (1 in log scale) increase or decrease in expression levels are indicated in green or red, respectively. Indicated are examples of up-regulated genes known to play an important role in megakaryocytic differentiation along with the reference TRPV6 gene. (F) RUNX1 knockdown impaired TPA-induced transcriptional activation. Gene expression levels in K562-TPA versus K562Runx1KD-TPA cells, stably expressing a TPA-responsive RUNX1 shRNA-miR, are shown in supplemental Table 1. Note the change in RUNX1-dependent expression of genes indicated in panel E. (G) Change in RUNX1-dependent transcriptional regulation in TPA-treated cells. Genes were divided into groups according to differential expression after TPA treatment. Shown are boxplots representing the expression change distribution in K562Runx1KD cells (blue) and K562CONTROL (red) for each group of genes. In RUNX1 expression KD, transcriptional repression (left section) did not change, whereas transcriptional activation (right section) was almost completely abolished.

Phenotypic and gene expression response of K562 and K562Runx1KD cells to TPA treatment. (A) Quantitative RT-PCR and Western blot analysis of RUNX1 expression in untreated (U.T) and TPA-treated (TPA) cells as well as in TPA-treated cells stably expressing shRNA-miR (K562RUNX1KD), which knocked down RUNX1 expression (KD) compared with nonsilencing shRNA-miR control (Neg). Quantitative RT-PCR data are mean ± SD of 2 independent experiments performed in triplicates. Western blot of nuclear extract using anti-RUNX1 antibodies. Emerin was used as control of protein loading (supplemental data). (B) Proliferation assay using K562-TPA Neg (red) and KD (blue) cells. A total of 1 × 106 cells were grown in culture and counted every 24 hours. TPA was added 48 hours after seeding of cells. Data are mean ± SD of 2 independent experiments performed in triplicates. (C) Cell morphology changes. Representative microscopic images of May-Grunwald-Giemsa stained untreated (U.T), TPA, TPA Neg, and TPA KD K562 cells. Images were viewed with a Nikon Eclipse 800 microscope with a 100×/1.25 numeric aperture oil objective lens, captured using a Nikon DXM1200 digital camera, and processed with Nikon ACT-1 2.63 software. (D) Expression of megakaryocytic markers in K562 (Control) and K562RUNX1KD (KD) in response to TPA. Quantitative RT-PCR analysis of ITGA2B (CD41), ITGB3 (CD61), and CD9 expression in K562 cells. Data are mean ± SD of 2 independent experiments performed in quadruplicates. The decreased expression in TPA-treated K562RUNX1KD relative to K562 control was significant (P < .01) for all 3 markers. Primers used for quantitative RT-PCR assays are listed in supplemental Table 2. (E) TPA-induced transcriptional changes. Genes are plotted based on their expression level (log scale) in K562-TPA cells versus their basal level in untreated cells. Genes showing 2-fold (1 in log scale) increase or decrease in expression levels are indicated in green or red, respectively. Indicated are examples of up-regulated genes known to play an important role in megakaryocytic differentiation along with the reference TRPV6 gene. (F) RUNX1 knockdown impaired TPA-induced transcriptional activation. Gene expression levels in K562-TPA versus K562Runx1KD-TPA cells, stably expressing a TPA-responsive RUNX1 shRNA-miR, are shown in supplemental Table 1. Note the change in RUNX1-dependent expression of genes indicated in panel E. (G) Change in RUNX1-dependent transcriptional regulation in TPA-treated cells. Genes were divided into groups according to differential expression after TPA treatment. Shown are boxplots representing the expression change distribution in K562Runx1KD cells (blue) and K562CONTROL (red) for each group of genes. In RUNX1 expression KD, transcriptional repression (left section) did not change, whereas transcriptional activation (right section) was almost completely abolished.

Close Modal
This Feature Is Available To Subscribers Only

or Create an Account

Close Modal
Close Modal