Rastegar-Pouyani Nima, Abdolvahab Mohadeseh Haji, Farzin Mohammad Amin, Zare Hamed, Kesharwani Prashant, Sahebkar Amirhossein
Department of Pharmacology and Toxicology, Tehran University of Medical Sciences, Tehran, Iran; Recombinant Proteins Department, Breast Cancer Research Center, Motamed Cancer Institute, ACECR, Tehran, Iran.
Recombinant Proteins Department, Breast Cancer Research Center, Motamed Cancer Institute, ACECR, Tehran, Iran.
Tissue Cell. 2024 Dec;91:102624. doi: 10.1016/j.tice.2024.102624. Epub 2024 Nov 19.
Cancer-associated fibroblasts (CAFs) are a heterogeneous cell population within the tumor that have recently come into the spotlight. By extracellular matrix (ECM) remodeling and robust cross-talk with cancer cells via different secretions such as cytokines, chemokines, and growth factors, CAFs contribute to cancer progression and poorer prognoses in patients. Novel candidates have been developed to inhibit CAFs; however, due to safety and efficacy issues, none have successfully passed clinical trials. Despite these shortcomings, one concept embraced by many researchers is to repurpose non-oncology drugs with potential anti-cancer properties for cancer treatment. One such example is pirfenidone (PFD), an oral anti-fibrotic medication, primarily administered for idiopathic pulmonary fibrosis. Emerging evidence suggests that PFD has promising anti-cancer effects, mainly manifesting through targeting CAFs. With inhibitory effects on CAFs, PFD restricts cancer proliferation, metastasis, immunosuppression, drug resistance, and tumor stiffness. To improve efficacy and minimize adverse effects, several innovative approaches have been proposed for targeting CAFs via PFD. Interestingly, combination therapy comprising PFD and chemotherapeutics e.g. doxorubicin has shown synergistic anti-cancer effects while protecting normal tissue. Furthermore, novel drug delivery systems, e.g. biomimetic liposomes and multilayer core-shell nanoparticles, have enhanced the pharmacokinetic properties of PFD and further increased its intratumoral delivery. Single-cell RNA sequencing (scRNA-seq) has also been suggested to characterize different subpopulations of CAFs and design precise PFD-based therapeutic strategies. Herein, we discuss the promising anti-cancer effects of PFD via inhibition of CAFs. We then provide findings on novel PFD-based approaches to target CAFs using combination therapy, nanocarrier-based drug delivery, and scRNA-seq.
癌症相关成纤维细胞(CAFs)是肿瘤内的一种异质性细胞群,最近受到了关注。通过细胞外基质(ECM)重塑以及经由细胞因子、趋化因子和生长因子等不同分泌物与癌细胞进行强有力的相互作用,CAFs促进癌症进展并导致患者预后较差。已开发出新型候选药物来抑制CAFs;然而,由于安全性和有效性问题,尚无药物成功通过临床试验。尽管存在这些缺点,但许多研究人员所接受的一个概念是将具有潜在抗癌特性的非肿瘤药物重新用于癌症治疗。吡非尼酮(PFD)就是这样一个例子,它是一种口服抗纤维化药物,主要用于治疗特发性肺纤维化。新出现的证据表明,PFD具有有前景的抗癌作用,主要通过靶向CAFs表现出来。PFD对CAFs具有抑制作用,可限制癌症增殖、转移、免疫抑制、耐药性和肿瘤硬度。为了提高疗效并将不良反应降至最低,已提出了几种通过PFD靶向CAFs的创新方法。有趣的是,包含PFD和化疗药物(如阿霉素)的联合疗法已显示出协同抗癌作用,同时还能保护正常组织。此外,新型药物递送系统,如仿生脂质体和多层核壳纳米颗粒,增强了PFD的药代动力学特性,并进一步增加了其在肿瘤内的递送。单细胞RNA测序(scRNA-seq)也被建议用于表征CAFs的不同亚群,并设计基于PFD的精确治疗策略。在此,我们讨论PFD通过抑制CAFs产生的有前景的抗癌作用。然后,我们提供了关于使用联合疗法、基于纳米载体的药物递送和scRNA-seq靶向CAFs的新型基于PFD方法的研究结果。
