On-demand reprogramming of immunosuppressive microenvironment in tumor tissue via multi-regulation of carcinogenic microRNAs and RNAs dependent photothermal-immunotherapy using engineered gold nanoparticles for malignant tumor treatment

IF 12.8 1区医学 Q1 ENGINEERING, BIOMEDICAL

Biomaterials Pub Date : 2024-11-08 DOI:10.1016/j.biomaterials.2024.122956

Li Chen , Wenjun Tang , Jie Liu , Man Zhu , Wenyun Mu , Xiaoyu Tang , Tao Liu , Zeren Zhu , Lin Weng , Yumeng Cheng , Yanmin Zhang , Xin Chen

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引用次数: 0

Abstract

The frequent immune escape of tumor cells and fluctuating therapeutic efficiency vary with each individual are two critical issues for immunotherapy against malignant tumor. Herein, we fabricated an intelligent core-shell nanoparticle (SNAs@CCM_R) to significantly inhibit the PD-1/PD-L1 mediated immune escape by on-demand regulation of various oncogenic microRNAs and perform RNAs dependent photothermal-immunotherapy to achieve precise and efficient treatment meeting the individual requirements of specific patients by in situ generation of customized tumor-associated antigens. The SNAs@CCM_R consisted of antisense oligonucleotides grafted gold nanoparticles (SNAs) as core and TLR7 agonist imiquimod (R837) functionalized cancer cell membrane (CCM) as shell, in which the acid-labile Schiff base bond was used to connect the R837 and CCM. During therapy, the acid environment of tumor tissue cleaved the Schiff base to generate free R837 and SNAs@CCM. The SNAs@CCM further entered tumor cells via CCM mediated internalization, and then specifically hybridized with over-expressed miR-130a and miR-21, resulting in effective inhibition of the migration and PD-L1 expression of tumor cells to avoid their immune escape. Meanwhile, the RNAs capture also caused significant aggregation of SNAs, which immediately generated photothermal agents within tumor cells to perform highly selective photothermal therapy under NIR irradiation. These chain processes not only damaged the primary tumor, but also produced plenty of tumor-associated antigens, which matured the surrounding dendritic cells (DCs) and activated anti-tumor T cells along with the released R837, resulting in the enhanced immunotherapy with suppressive immune escape. Both in vivo and in vitro experiments demonstrated that our nanoparticles were able to inhibit primary tumor and its metastasis via multi-regulation of carcinogenic microRNAs and RNAs dependent photothermal-immune activations, which provided a promising strategy to reprogram the immunosuppressive microenvironment in tumor tissue for better malignant tumor therapy.

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利用工程金纳米粒子对致癌微RNA和RNA依赖性光热免疫疗法进行多调控，按需重编肿瘤组织中的免疫抑制微环境，用于恶性肿瘤治疗。

肿瘤细胞的频繁免疫逃逸和因人而异的疗效波动是恶性肿瘤免疫治疗的两大关键问题。在此，我们制备了一种智能核壳纳米粒子（SNAs@CCMR），通过按需调控各种致癌微RNA，显著抑制PD-1/PD-L1介导的免疫逃逸，并通过原位生成定制的肿瘤相关抗原，进行RNAs依赖性光热免疫治疗，实现符合特定患者个体需求的精准高效治疗。SNAs@CCMR由反义寡核苷酸接枝金纳米粒子（SNAs）为核，TLR7激动剂咪喹莫特（R837）功能化癌细胞膜（CCM）为壳组成，其中R837与CCM之间采用酸性希夫碱连接。在治疗过程中，肿瘤组织的酸性环境会裂解希夫碱，生成游离的 R837 和 SNAs@CCM。SNAs@CCM 通过 CCM 介导的内化作用进一步进入肿瘤细胞，然后与过度表达的 miR-130a 和 miR-21 特异性杂交，从而有效抑制肿瘤细胞的迁移和 PD-L1 表达，避免其免疫逃逸。同时，RNAs 的捕获也会引起 SNAs 的显著聚集，SNAs 会立即在肿瘤细胞内产生光热剂，在近红外照射下进行高选择性光热治疗。这些连锁过程不仅破坏了原发肿瘤，还产生了大量肿瘤相关抗原，使周围的树突状细胞（DC）成熟，并与释放的 R837 一起激活了抗肿瘤 T 细胞，从而增强了抑制性免疫逃逸的免疫治疗效果。体内和体外实验均表明，我们的纳米颗粒能够通过多重调控致癌微RNA和RNA依赖的光热免疫激活抑制原发性肿瘤及其转移，这为重编程肿瘤组织中的免疫抑制微环境以更好地治疗恶性肿瘤提供了一种前景广阔的策略。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Biomaterials 工程技术-材料科学：生物材料

CiteScore

26.00

自引率

2.90%

发文量

565

审稿时长

46 days

期刊介绍： Biomaterials is an international journal covering the science and clinical application of biomaterials. A biomaterial is now defined as a substance that has been engineered to take a form which, alone or as part of a complex system, is used to direct, by control of interactions with components of living systems, the course of any therapeutic or diagnostic procedure. It is the aim of the journal to provide a peer-reviewed forum for the publication of original papers and authoritative review and opinion papers dealing with the most important issues facing the use of biomaterials in clinical practice. The scope of the journal covers the wide range of physical, biological and chemical sciences that underpin the design of biomaterials and the clinical disciplines in which they are used. These sciences include polymer synthesis and characterization, drug and gene vector design, the biology of the host response, immunology and toxicology and self assembly at the nanoscale. Clinical applications include the therapies of medical technology and regenerative medicine in all clinical disciplines, and diagnostic systems that reply on innovative contrast and sensing agents. The journal is relevant to areas such as cancer diagnosis and therapy, implantable devices, drug delivery systems, gene vectors, bionanotechnology and tissue engineering.