Figure 7
Epigenetic alteration in HTLV-1–infected cells within asymptomatic carriers. (A) Box plot showing EZH2 expression in subpopulations from HTLV-1–infected individuals. P, D, and N represent subpopulations from indolent ATL (n = 3) and asymptomatic HTLV-1 carriers (n = 2). P indicates CD7+/CADM1− cells; D indicates CD7+/CADM1+ cells; N indicates CD7−/CADM1+ cells. Acu-N indicates CD7−/CADM1+ cells from acute-type ATL. (B) Box plot showing relative expression levels of the H3K27me3-dependent silenced 856 genes (defined in supplemental Figure 4) in the subpopulations from HTLV-1–infected individuals and acute-type ATL (*P < 1E−4). (C) Venn diagram showing the relationship between disease progression and H3K27me3 gain. The 3 subgroups were classified according to the disease stages (stage I indicates P to D progression; stage II indicates D to N progression; stage III indicates indolent N to acute-type N progression). Each gene set was defined as (1) H3K27me3 gain (LogFC > 1) in acute-type ATL compared with normal CD4+ T cells and (2) decreased expression (FC < −1.5, P < .05) at the stages. (D) Microscopy data showing representative H3K27me3 level in CD4+/CADM1+ and CD4+/CADM1− subpopulations within asymptomatic carriers (n = 3). The scale bars indicate 20 μm. (E) Graph showing the results of μChIP assay with anti-H3K27me3 antibody and control IgG in CD4+/CADM1+ and CD4+/CADM1− subpopulations derived from asymptomatic carriers (n = 3, mean ± SD). Promoter region of the H3K27me3-regulated genes were tested. (F) Graph showing the population size of CD4+/CADM1+ cells in the presence or absence of 5 μM GSK126 treatment of 9 days (n = 14; *P < .05).

Epigenetic alteration in HTLV-1–infected cells within asymptomatic carriers. (A) Box plot showing EZH2 expression in subpopulations from HTLV-1–infected individuals. P, D, and N represent subpopulations from indolent ATL (n = 3) and asymptomatic HTLV-1 carriers (n = 2). P indicates CD7+/CADM1 cells; D indicates CD7+/CADM1+ cells; N indicates CD7/CADM1+ cells. Acu-N indicates CD7/CADM1+ cells from acute-type ATL. (B) Box plot showing relative expression levels of the H3K27me3-dependent silenced 856 genes (defined in supplemental Figure 4) in the subpopulations from HTLV-1–infected individuals and acute-type ATL (*P < 1E−4). (C) Venn diagram showing the relationship between disease progression and H3K27me3 gain. The 3 subgroups were classified according to the disease stages (stage I indicates P to D progression; stage II indicates D to N progression; stage III indicates indolent N to acute-type N progression). Each gene set was defined as (1) H3K27me3 gain (LogFC > 1) in acute-type ATL compared with normal CD4+ T cells and (2) decreased expression (FC < −1.5, P < .05) at the stages. (D) Microscopy data showing representative H3K27me3 level in CD4+/CADM1+ and CD4+/CADM1 subpopulations within asymptomatic carriers (n = 3). The scale bars indicate 20 μm. (E) Graph showing the results of μChIP assay with anti-H3K27me3 antibody and control IgG in CD4+/CADM1+ and CD4+/CADM1 subpopulations derived from asymptomatic carriers (n = 3, mean ± SD). Promoter region of the H3K27me3-regulated genes were tested. (F) Graph showing the population size of CD4+/CADM1+ cells in the presence or absence of 5 μM GSK126 treatment of 9 days (n = 14; *P < .05).

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