![Figure 2. Impact (in vitro and ex vivo) of CD14+HLA-DRlo cells from CLL patients on T cells. (A) The dose-dependent suppressive activity of FACS-sorted CD14+HLA-DRlo cells from CLL patients (n = 4) was evaluated in coculture experiments with autologous T cells activated by means of anti-CD2, -CD3, and -CD28 microbeads. Proliferation of T cells was assessed based on the VPD450 dye dilution after 5 days by FACS and compared with stimulated T cells alone (set as 100% T-cell proliferation). (B) Correlation of the T-cell count with the proportion of CD14+HLA-DRlo cells in the peripheral blood of CLL patients. (C) Patients were grouped based on their MDSC (equals CD14+HLA-DRlo cells) frequency (less than the median [n = 24] and greater than the median [n = 24]). Frequency of PD1+ cells among CD4+/CD8+ T cells was compared between the groups. (D) Time until doubling of the patients’ lymphocyte counts was compared in the 2 groups using a Gehan-Breslow-Wilcoxon test. (E) T-cell activation based on mean fluorescence index (MFI) levels of CD69, CD137, and HLA-DR, respectively, in the CD4+ and CD8+ T-cell compartment was compared between the groups. (F) Representative dot plot of a FACS-based T-cell maturation analysis. CD4+ and CD8+ T cells were divided into CD27+CD45RA+ naïve (NA) cells, CD27+CD45RAneg central memory (CM), CD27negCD45RAneg effector memory cells, and CD27negCD45RA+ effector memory RA+ cells (EMRA) cells. Proportions of these T-cell subsets were analyzed in both patient groups. The bars represent the standard error of the mean. *P < .05; **P < .01.](https://ash.silverchair-cdn.com/ash/content_public/journal/blood/124/5/10.1182_blood-2013-12-546416/2/750f2.jpeg?Expires=1722401496&Signature=iEir-ocBpskok1QPn-VIIkYSYlaPCBhOD46gujvHuSPbLQuc71wanfIAqxCdcf1w8p2GsyM2N3JOGDmxoiwDhPYvxa09DWiuCNez1eT-XQgiqvs22Da7AG~HaMyG84XtAZvqNgtJrkwzdD4CarrzoxFXi~LantubzZoYZpj7eIZlTCA4ahRiXvXwsyXFFBQlSJHSi6oa8ANZQRPXc33KZxcUev9coH4WAJAgng6N3ajDfZcUM9DT2UXizjEDwIIy120m16EohOg~NnMn7C0KteiI8upPO447JPvk-nW53ai~kYqSk6dE6LuaPQqSfHA1LInhsEMIf1BgbTww6r~LaA__&Key-Pair-Id=APKAIE5G5CRDK6RD3PGA)
Impact (in vitro and ex vivo) of CD14+HLA-DRlo cells from CLL patients on T cells. (A) The dose-dependent suppressive activity of FACS-sorted CD14+HLA-DRlo cells from CLL patients (n = 4) was evaluated in coculture experiments with autologous T cells activated by means of anti-CD2, -CD3, and -CD28 microbeads. Proliferation of T cells was assessed based on the VPD450 dye dilution after 5 days by FACS and compared with stimulated T cells alone (set as 100% T-cell proliferation). (B) Correlation of the T-cell count with the proportion of CD14+HLA-DRlo cells in the peripheral blood of CLL patients. (C) Patients were grouped based on their MDSC (equals CD14+HLA-DRlo cells) frequency (less than the median [n = 24] and greater than the median [n = 24]). Frequency of PD1+ cells among CD4+/CD8+ T cells was compared between the groups. (D) Time until doubling of the patients’ lymphocyte counts was compared in the 2 groups using a Gehan-Breslow-Wilcoxon test. (E) T-cell activation based on mean fluorescence index (MFI) levels of CD69, CD137, and HLA-DR, respectively, in the CD4+ and CD8+ T-cell compartment was compared between the groups. (F) Representative dot plot of a FACS-based T-cell maturation analysis. CD4+ and CD8+ T cells were divided into CD27+CD45RA+ naïve (NA) cells, CD27+CD45RAneg central memory (CM), CD27negCD45RAneg effector memory cells, and CD27negCD45RA+ effector memory RA+ cells (EMRA) cells. Proportions of these T-cell subsets were analyzed in both patient groups. The bars represent the standard error of the mean. *P < .05; **P < .01.
