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Tolerogenic dendritic cells (tolDCs) that dampen T cell responses can be induced from blood monocytes in vitro using factors such as Vitamin D3 (VitD),dexamethasone,IL‐10,or rapamycin. However,challenges remain in obtaining robust and efficient generation of cell therapy‐based tolDCs without compromising their viability. We recently reported that CCR2‐dependent recruitment of monocytic cells,with the capacity to dampen T‐helper responses,occurs in mice treated with a single‐stranded oligonucleotide (ssON). Here,we investigated the effects of this immunomodulatory noncoding ssON on differentiating human monocytes towards DC in the presence of IL‐4 and GM‐CSF (moDC). The moDC differentiated in the presence of ssON upregulated CD1a but also increased their expression of PD‐L1. The differentiation of monocytes to moDC in the presence of ssON introduced transcriptomic changes,many of which overlapped with VitD‐moDC and resulted in moDCs with altered lipopolysaccharide (LPS)‐responsiveness. Moreover,ssON‐moDC exhibited a low capacity to stimulate alloreactive T cells in vitro and instead promoted the induction of CD4+FoxP3+CD25+ T cells. Experiments using chemical reagents support a role for PPAR‐γ in the generation of ssON‐moDC. Collectively,our data show that monocytes differentiated with IL‐4,GM‐CSF,and ssON generate cells with phenotypic and functional characteristics of tolDCs. In this article,the authors elucidated the immunoregulatory role of an oligonucleotide (ssON) that favors the induction of human tolerogenic dendritic cells (DC). The tolerogenic profile was evidenced by reduced responsiveness to lipopolysaccharides (LPS) (A). Importantly,the tolerogenic DCs had upregulated PD‐L1 molecules and functionally inhibited the proliferation of alloreactive T cells and induced FoxP3+ Tregs (B). This study envisions the development of ssON as therapeutic for rebalancing overactive T‐helper cell responses. View Publication

In stem cell biology,a long-held structure–function relationship is the domed colony morphology and naïve pluripotency for mouse or human pluripotent stem cells. This link has provided a convenient way to recognize bona fide naïve pluripotent cells during derivation,passaging and characterization. However,the molecular basis of this link remains poorly understood. Results: We show that a loss of domed morphology may not impact the overall genetic architecture of naïve pluripotency in mouse embryonic stem cells (mESCs). We first generated stable mESC lines by knocking out Myh9 that encodes non-muscle myosin heavy chain IIA,resulting in colonies deprived of the typical domed morphology,but competent to differentiate into the three germ layers and chimeric mice. Modulating cell morphologies with inhibitors against kinases known to regulate myosin pathway also phenocopy the knockout in wild type mESCs. Conclusions: These results provide evidence that the domed morphology and potency can be uncoupled and suggest that domed structure is not a pre-requisite for acquiring and maintaining naïve pluripotency. View Publication

EVI1-rearranged acute myeloid leukemia (AML) with inv(3)(q21q26) or t(3;3)(q21q26) represents a distinct and aggressive subtype characterized by poor prognosis and limited treatment options. However,the optimal strategy to overcome resistance to conventional therapy remains elusive. Building upon observations correlating EVI1 overexpression with reduced sensitivity to venetoclax,a BH3-mimetic BCL-2 inhibitor,we investigated the mechanisms of resistance to venetoclax in combination with hypomethylating agents in inv(3)/t(3;3) AML cells. Utilizing novel murine models recapitulating inv(3) AML with concomitant SF3B1 mutations,we conducted comprehensive phenotypic and transcriptomic analyses in the presence or absence of venetoclax-containing therapy. Despite initial therapeutic responses,manifested as partially prolonged survival and myeloid differentiation,resistant leukemic cells demonstrated enhanced dependency on BRD4 and MYB pathways with a dormant phenotype. Notably,inhibition of either BRD4 or MYB significantly augmented the efficacy of venetoclax and hypomethylating agents in both murine and patient-derived AML models harboring inv(3) and SF3B1 mutations. These findings elucidate the transcriptional dynamics underlying venetoclax resistance and propose alternative therapeutic strategies targeting BRD4 and MYB as promising avenues for improving outcomes in patients with EVI1-rearranged AML. Our work highlights the necessity for innovative combination therapies to address the multifaceted mechanisms of resistance in this high-risk leukemia subtype. View Publication

Chimeric antigen receptor (CAR) T cell therapy has transformed the treatment landscape of hematologic cancers by engineering T cells to specifically target and destroy cancer cells. Monitoring CAR T cell activity and function is essential for optimizing therapeutic outcomes,but existing tools for CAR detection are often limited in specificity and functional assessment capability. Methods: We developed dextran multimers by conjugating multiple CAR-specific antigens to a dextran backbone. The multimers were compared to previously reported antigen tetramers for their ability to stain and detect CAR T cells. Because these multimers incorporate the CAR target antigen,they uniquely enable assessment of CAR T cell functionality. We tested the staining and functional properties of the multimers across a range of CAR constructs with different affinities,using flow cytometry and microscopy. Results: The dextran multimers demonstrated high specificity and sensitivity in staining CAR T cells,with adjustable antigen density to optimize binding. Dextran multimers also enabled effective clustering and subsequent activation of CARs,showing their utility as both a staining and functional assessment tool. The multimers revealed that CARs with different affinities and clustering tendencies displayed varied binding and activation in response to different antigen densities. Conclusions: Dextran multimers offer a dual advantage as versatile reagents for both staining and functional analysis of CAR T cells. Their capacity to engage CARs with the specific antigen provides a valuable platform for evaluating CAR functionality,informing CAR design improvements,and enhancing therapeutic precision. View Publication

Assessment of Fc receptors and immune cells in breast cancer enables development of tailored engineering strategies for tumor-targeting monoclonal antibodies with enhanced immune-stimulating and anticancer attributes by combining glycoengineering and Fc mutations. AbstractFc engineering to enhance antibody effector functions harbors the potential to improve therapeutic effects. Understanding FcγR expression and distribution in the tumor microenvironment prior to and following treatment may help guide immune-engaging antibody design and patient stratification. In this study,we investigated FcR-expressing immune effector cells in HER2+ and triple-negative breast cancers (TNBC),including neoadjuvant chemotherapy–resistant disease. FcγRIIIa expression,FcγRIIIa+ NK cells,and classically activated (M1-like) macrophages correlated with improved anti-HER2 antibody efficacy. FcγRIIIa protein and FcγRIIIa+ NK cells and macrophages were present in primary TNBC and retained in treatment-resistant tumors. FcγRIIIa was spatially associated with folate receptor alpha–positive (FRα+) tumor areas at baseline and in residual tumors following neoadjuvant chemotherapy. Wild-type and Fc-engineered antibodies recognizing two breast cancer–associated antigens,HER2 and the emerging TNBC target FRα,were designed and generated to have increased FcγRIIIa-expressing effector cell engagement. The combination of glycoengineering,including fucose removal from the N-linked Fc glycan,and Fc point mutations greatly increased antibody affinity for and retention on FcγRIIIa. The Fc-engineered antibodies enhanced immune effector activity against HER2+ breast cancer and TNBC,altering proinflammatory cytokine production by NK cells and tumor-conditioned macrophages and skewing macrophages toward proinflammatory states. Furthermore,the Fc-engineered antibodies restricted orthotopic HER2+ and FRα+ breast cancer xenograft growth at doses suboptimal for equivalent wild-type antibodies and recruited FcγRIIIa-expressing cells into tumors. Antibody design through combined glycoengineering and Fc point mutations to enhance FcγRIIIa engagement of tumor-infiltrating effector cells may be a promising strategy for developing therapies for patients with aggressive and treatment-resistant breast cancers.Significance:Assessment of Fc receptors and immune cells in breast cancer enables development of tailored engineering strategies for tumor-targeting monoclonal antibodies with enhanced immune-stimulating and anticancer attributes by combining glycoengineering and Fc mutations. View Publication