ALBERT

Description: Chronic lymphocytic leukemia (CLL), characterized by accumulation of CD5+CD19+sIgM+ B lymphocytes in peripheral blood and lymphoid organs, is classified into indolent and aggressive forms. Patients with indolent CLL generally survive 5 to 10 years and do not require treatment until severe symptoms, while those with aggressive CLL show resistant to standard treatment and survive less than 24 months. While emerging B cell antigen receptor directed therapies are promising, resistance to such therapies pose problems warranting novel therapeutic approaches. MicroRNA (miR) profiling revealed lower expression of miR-29b in aggressive CLL associated with survival, drug resistance and poor prognosis via its up-regulation of anti-apoptotic proteins myeloid leukemia cell differentiation protein 1 (Mcl1) and oncogenic T-cell leukemia 1 (Tcl1). Thus, specific overexpression of miR-29b in B-CLL cells could be a potential therapy for aggressive CLL patients. Despite the promise, short circulation half-life, limited cellular uptake and off-target effects on non-desirable tissues pose a challenge for miR-based therapies. To promote efficiency and specificity of miR-29b delivery, we developed neutral immunonanoparticles with selectivity to CLL via targeting tumor antigen ROR1, which is expressed in over 95% of CLL but not normal B cells. We optimized a novel 2A2-immunoliposome (2A2-ILP) recognizing surface ROR1 on primary CLL cell to promote internalization and miR-29b uptake (n=6, p=0.042*). About 20-fold increased uptake of miR-29b was achieved with 2A2-ILP-miR-29b formulation compared to control. Further ROR1 targeted delivery of miR29b resulted in significant downregulation of DNMT1 and DNMT3a mRNA and protein (n=3, DNMT1: p= 0.0115*; DNMT3a: p=0.0231*, SP1; p=0.0031**) in primary CLL cells and a human CLL cell line OSU-CLL. Consistent with the downregulation of DNMTs, decreased global DNA methylation was observed in OSU-CLL cell line one week post- treatment with 2A2-ILP-miR-29b (n=3, p=0.0003***). To further study the in vivo ROR1-targeting efficiency of 2A2-ILP-miR-29b, we used our recently described Eµ-hROR1x Tcl1 CLL mouse model that develops CLL like disease with human ROR1 antigen in leukemic CD19+CD5+ B cells. Using hROR1+CD19+CD5+ leukemic cell engraftment model, we showed significant in-vivo efficacy of ROR1-ILP-miR-29b formulation associated with a) decreased number of circulating leukemic B220+CD5+ cells b) reduced splenomegaly (p=0.0461*, 2A2-29b: n=9; PBS: n=8) c) with extended survival (p=0.0075**, 2A2-29b: n=9; IgG-29b: n=7; 2A2-SC: n=7; PBS: n=8). In summary, 2A2-ILP effectively delivered functional miR-29b, resulting in downregulation of DNMT1 and DNMT3a, reduction of hypermethylation and anti-leukemic activity. Ongoing studies are aimed at understanding miR-29b mediated in-vivo methylome reprograming using our novel hROR1xTcl1 transgenic mouse model and ROR1-targeted miR-29b delivery formulation. Figure 1. Figure 1. Disclosures Byrd: Acerta Pharma BV: Research Funding.

Description: Chronic lymphocytic leukemia (CLL) occurs in 2 major forms: aggressive and indolent. Low miR-29b expression in aggressive CLL is associated with poor prognosis. Indiscriminate miR-29b overexpression in the B-lineage of mice causes aberrance, thus warranting the need for selective introduction of miR-29b into B-CLL cells for therapeutic benefit. The oncofetal antigen receptor tyrosine kinase orphan receptor 1 (ROR1) is expressed on malignant B-CLL cells, but not normal B cells, encouraging us with ROR1-targeted delivery for therapeutic miRs. Here, we describe targeted delivery of miR-29b to ROR1+ CLL cells leading to downregulation of DNMT1 and DNMT3A, modulation of global DNA methylation, decreased SP1, and increased p21 expression in cell lines and primary CLL cells in vitro. Furthermore, using an Eμ-TCL1 mouse model expressing human ROR1, we report the therapeutic benefit of enhanced survival via cellular reprograming by downregulation of DNMT1 and DNMT3A in vivo. Gene expression profiling of engrafted murine leukemia identified reprogramming of cell cycle regulators with decreased SP1 and increased p21 expression after targeted miR-29b treatment. This finding was confirmed by protein modulation, leading to cell cycle arrest and survival benefit in vivo. Importantly, SP1 knockdown results in p21-dependent compensation of the miR-29b effect on cell cycle arrest. These studies form a basis for leukemic cell–targeted delivery of miR-29b as a promising therapeutic approach for CLL and other ROR1+ B-cell malignancies.