Engineered endosymbionts that modulate primary macrophage function and attenuate tumor growth by shifting the tumor microenvironment

Cody S Madsen, Ashley V Makela, Chima V Maduka, Emily M Greeson, Anthony Tundo, Evran Ural, Satyajit H Kulkarni, Ahmed Zarea, Matti Kiupel, Maryam Sayadi, Christopher H Contag
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Abstract

Modulating gene expression in macrophages can be used to improve tissue regeneration and to redirect tumor microenvironments (TME) toward positive therapeutic outcomes. We have developed Bacillus subtilis as an engineered endosymbiont (EES) capable of residing inside the eukaryotic host cell cytoplasm and controlling the fate of macrophages. Secretion of mammalian transcription factors (TFs) from B. subtilis that expresses listeriolysin O (LLO; allowing the EES to escape destruction by the macrophage) modulated expression of surface markers, cytokines and chemokines, indicating functional changes in a macrophage/monocyte cell line. The engineered B. subtilis LLO TF strains were evaluated in murine bone marrow-derived macrophages (BMDMs) by flow cytometry, chemokine/cytokine profiling, metabolic assays and RNA-Seq. Delivery of TFs by the EES shifted BMDM gene expression, production of cytokine and chemokines and metabolic patterns, indicating that the TF strains could guide primary macrophage function. Thereafter, the ability of the TF strains to alter the TME was characterized in vivo, in an orthotopic murine model of triple-negative breast cancer to assess therapeutic effects. The TF strains altered the TME by shifting immune cell composition and attenuating tumor growth. Additionally, multiple doses of the TF strains were well-tolerated by the mice. The use of B. subtilis LLO TF strains as EES showed promise as a unique cancer immunotherapy by directing immune function intracellularly. The uses of EES could be expanded to modulate other mammalian cells over a range of biomedical applications.
通过改变肿瘤微环境来调节原发性巨噬细胞功能并抑制肿瘤生长的工程内生菌
调节巨噬细胞中的基因表达可用于改善组织再生,并将肿瘤微环境(TME)导向积极的治疗结果。我们开发了枯草芽孢杆菌(Bacillus subtilis),作为一种工程内共生菌(EES),它能够驻留在真核宿主细胞的细胞质内并控制巨噬细胞的命运。从表达李斯特溶菌素O(LLO;允许EES逃避巨噬细胞的破坏)的枯草杆菌中分泌哺乳动物转录因子(TFs),可调节表面标志物、细胞因子和趋化因子的表达,表明巨噬细胞/单核细胞系发生了功能性变化。通过流式细胞仪、趋化因子/细胞因子分析、代谢测定和 RNA-Seq 等方法,对工程化的枯草杆菌 LLO TF 菌株在小鼠骨髓巨噬细胞(BMDMs)中的表现进行了评估。通过 EES 输送的 TF 改变了 BMDM 的基因表达、细胞因子和趋化因子的产生以及代谢模式,这表明 TF 菌株可以引导初级巨噬细胞的功能。随后,在三阴性乳腺癌小鼠模型中,对TF菌株改变TME的能力进行了体内鉴定,以评估治疗效果。TF菌株通过改变免疫细胞组成和抑制肿瘤生长来改变TME。此外,小鼠对多剂 TF 菌株的耐受性良好。使用枯草杆菌 LLO TF 菌株作为 EES,通过在细胞内引导免疫功能,有望成为一种独特的癌症免疫疗法。EES的用途还可扩展到调节其他哺乳动物细胞,从而实现一系列生物医学应用。
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