OBJECTIVES: CD33 is a cell surface marker of committed myelomonocytic precursors and circulating monocytes, and is also found on acute myeloid leukemia (AML) cells. CD33 belongs to a family of sialic acid-binding cell surface proteins named Siglecs, among which there are 7 other functional CD33-related Siglecs (CD33rSiglecs). We sought to characterize the spectrum of expression of the other CD33rSiglecs on bone marrow precursors and AML cells and asked if they can potentially serve as targets for therapy. METHODS: Cell surface CD33rSiglecs were analyzed by flow cytometry. The ability of certain anti-Siglec antibodies to target toxin-mediated cell killing of Siglec-expressing cell lines was characterized and compared. RESULTS: We demonstrate that Siglecs-3, -5, -6, -7, and -9 are expressed on subsets of normal bone marrow precursors, including promonocytes and myelocytes. Furthermore, most AML (but not ALL) cells express these Siglecs. There is substantial variability in Siglec type and expression level between cases, with each having a unique "CD33rSiglec fingerprint." Individual anti-Siglec antibodies along with a saporin toxin-conjugated secondary antibody can target myelomonocytic leukemia cells for death, and targeting of multiple Siglecs improves cell killing. Cytotoxicity was further enhanced by sialidase treatment of target cells, which improves antibody binding. We also confirmed that antibody binding induced rapid internalization of Siglecs from the cell surface, which is a requirement for cell killing via saporin. CONCLUSIONS: Multiple CD33rSiglecs are expressed on normal and malignant myelomonoyctic cells. Targeting these Siglecs, possibly in combinations, could improve anti-CD33 antibody therapy or be used as an alternative to anti-CD33.
OBJECTIVES:CD33 is a cell surface marker of committed myelomonocytic precursors and circulating monocytes, and is also found on acute myeloid leukemia (AML) cells. CD33 belongs to a family of sialic acid-binding cell surface proteins named Siglecs, among which there are 7 other functional CD33-related Siglecs (CD33rSiglecs). We sought to characterize the spectrum of expression of the other CD33rSiglecs on bone marrow precursors and AML cells and asked if they can potentially serve as targets for therapy. METHODS: Cell surface CD33rSiglecs were analyzed by flow cytometry. The ability of certain anti-Siglec antibodies to target toxin-mediated cell killing of Siglec-expressing cell lines was characterized and compared. RESULTS: We demonstrate that Siglecs-3, -5, -6, -7, and -9 are expressed on subsets of normal bone marrow precursors, including promonocytes and myelocytes. Furthermore, most AML (but not ALL) cells express these Siglecs. There is substantial variability in Siglec type and expression level between cases, with each having a unique "CD33rSiglec fingerprint." Individual anti-Siglec antibodies along with a saporin toxin-conjugated secondary antibody can target myelomonocytic leukemia cells for death, and targeting of multiple Siglecs improves cell killing. Cytotoxicity was further enhanced by sialidase treatment of target cells, which improves antibody binding. We also confirmed that antibody binding induced rapid internalization of Siglecs from the cell surface, which is a requirement for cell killing via saporin. CONCLUSIONS: Multiple CD33rSiglecs are expressed on normal and malignant myelomonoyctic cells. Targeting these Siglecs, possibly in combinations, could improve anti-CD33 antibody therapy or be used as an alternative to anti-CD33.
Authors: Christopher J Scott; Waleed M Marouf; Derek J Quinn; Richard J Buick; Selinda J Orr; Ryan F Donnelly; Paul A McCarron Journal: Pharm Res Date: 2007-08-03 Impact factor: 4.200
Authors: Miriam Y Kim; Kyung-Rok Yu; Saad S Kenderian; Marco Ruella; Shirley Chen; Tae-Hoon Shin; Aisha A Aljanahi; Daniel Schreeder; Michael Klichinsky; Olga Shestova; Miroslaw S Kozlowski; Katherine D Cummins; Xinhe Shan; Maksim Shestov; Adam Bagg; Jennifer J D Morrissette; Palak Sekhri; Cicera R Lazzarotto; Katherine R Calvo; Douglas B Kuhns; Robert E Donahue; Gregory K Behbehani; Shengdar Q Tsai; Cynthia E Dunbar; Saar Gill Journal: Cell Date: 2018-05-31 Impact factor: 41.582
Authors: Jing Chang; Haiyong Peng; Brian C Shaffer; Sivasubramanian Baskar; Ina C Wecken; Matthew G Cyr; Gustavo J Martinez; Jo Soden; Jim Freeth; Adrian Wiestner; Christoph Rader Journal: Cancer Immunol Res Date: 2018-07-06 Impact factor: 11.151