Lu Yen-Ting, Chen Tzu-Yu, Lin Hsin-Hung, Chen Ya-Wen, Lin Yu-Xiu, Le Duy-Cuong, Huang Yen-Hua, Wang Andrew H-J, Lee Cheng-Chung, Ling Thai-Yen
Graduate Institute of Pharmacology, National Taiwan University College of Medicine, Taipei, Taiwan.
MediDiamond Inc., Taipei, Taiwan.
J Extracell Vesicles. 2025 Feb;14(2):e70044. doi: 10.1002/jev2.70044.
Acetaminophen (APAP) overdose can cause severe liver injury and life-threatening conditions that may lead to multiple organ failure without proper treatment. N-acetylcysteine (NAC) is the accepted and prescribed treatment for detoxification in cases of APAP overdose. Nonetheless, in acute liver failure (ALF), particularly when the ingestion is substantial, NAC may not fully restore liver function. NAC administration in ALF has limitations and potential adverse effects, including nausea, vomiting, diarrhoea, flatus, gastroesophageal reflux, and anaphylactoid reactions. Mesenchymal stromal cell (MSC)-based therapies using paracrine activity show promise for treating ALF, with preclinical studies demonstrating improvement. Recently, MSC-derived extracellular vesicles (EVs) have emerged as a new therapeutic option for liver injury. MSC-derived EVs can contain various therapeutic cargos depending on the cell of origin, participate in physiological processes, and respond to abnormalities. However, most therapeutic EVs lack a distinct orientation upon entering the body, resulting in a lack of targeting specificity. Therefore, enhancing the precision of natural EV delivery systems is urgently needed. Thus, we developed an advanced targeting technique to deliver modified EVs within the body. Our strategy aims to employ bioorthogonal click chemistry to attach a targeting molecule to the surface of small extracellular vesicles (sEVs), creating exogenous chimeric antigen receptor-modified sEVs (CAR-sEVs) for the treatment. First, we engineered azido-modified sEVs (N-sEVs) through metabolic glycoengineering by treating MSCs with the azide-containing monosaccharide N-azidoacetyl-mannosamine (Ac4ManNAz). Next, we conjugated N-sEVs with a dibenzocyclooctyne (DBCO)-tagged single-chain variable fragment (DBCO-scFv) that targets the asialoglycoprotein receptor (ASGR1), thus producing CAR-sEVs for precise liver targeting. The efficacy of CAR-sEV therapy in ALF models by targeting ASGR1 was validated. MSC-derived CAR-sEVs reduced serum liver enzymes, mitigated liver damage, and promoted hepatocyte proliferation in APAP-induced injury. Overall, CAR-sEVs exhibited enhanced hepatocyte specificity and efficacy in ameliorating liver injury, highlighting the significant advancements achievable with cell-free targeted therapy.
对乙酰氨基酚(APAP)过量可导致严重肝损伤及危及生命的状况,若未得到妥善治疗,可能会引发多器官功能衰竭。N-乙酰半胱氨酸(NAC)是公认的用于APAP过量解毒的处方治疗药物。然而,在急性肝衰竭(ALF)中,尤其是摄入量大时,NAC可能无法完全恢复肝功能。在ALF中使用NAC存在局限性和潜在不良反应,包括恶心、呕吐、腹泻、肠胃胀气、胃食管反流和类过敏反应。基于间充质基质细胞(MSC)的疗法利用旁分泌活性,在治疗ALF方面显示出前景,临床前研究已证明有所改善。最近,MSC衍生的细胞外囊泡(EVs)已成为肝损伤的一种新治疗选择。MSC衍生的EVs可根据来源细胞包含各种治疗性物质,参与生理过程并对异常情况作出反应。然而,大多数治疗性EVs进入体内后缺乏明确的导向性,导致缺乏靶向特异性。因此,迫切需要提高天然EV递送系统的精准度。于是,我们开发了一种先进的靶向技术,以便在体内递送修饰后的EVs。我们的策略旨在利用生物正交点击化学将靶向分子连接到小细胞外囊泡(sEVs)表面,创建用于治疗的外源性嵌合抗原受体修饰的sEVs(CAR-sEVs)。首先,我们通过用含叠氮化物的单糖N-叠氮乙酰甘露糖胺(Ac4ManNAz)处理MSC,通过代谢糖工程改造出叠氮修饰的sEVs(N-sEVs)。接下来,我们将N-sEVs与靶向去唾液酸糖蛋白受体(ASGR1)的二苯并环辛炔(DBCO)标记的单链可变片段(DBCO-scFv)偶联,从而产生用于精确肝脏靶向的CAR-sEVs。通过靶向ASGR1,验证了CAR-sEV疗法在ALF模型中的疗效。在APAP诱导的损伤中,MSC衍生的CAR-sEVs降低了血清肝酶水平,减轻了肝损伤,并促进了肝细胞增殖。总体而言,CAR-sEVs在改善肝损伤方面表现出增强的肝细胞特异性和疗效,突出了无细胞靶向治疗可取得的重大进展。
