Wei Ziqin, Mu Hongfang, Qiu Fangfang, Zhao Minghui, Zhang Xiaojing, Li Wenbin, Jia Hai, Wang Rong
School of Pharmacy, Lanzhou University, Lanzhou, China.
PLA Key Laboratory of the Plateau of the Environmental Damage Control, The 940th Hospital of Logistics Support Force of PLA, Lanzhou, China.
Front Physiol. 2025 Apr 8;16:1520246. doi: 10.3389/fphys.2025.1520246. eCollection 2025.
Previous research has demonstrated that the hypoxic environment at high altitudes significantly alters the pharmacokinetics of many drugs, reducing their efficacy and increasing adverse effects. A key factor in this altered drug metabolism is the inhibition of ATP-binding cassette subfamily B member 1 (ABCB1), an efflux transporter protein, in the liver tissues of plateau rats. Rat ABCB1, encoded by the and genes, has two isoforms functionally analogous to human ABCB1. Histone acetylation, an epigenetic mechanism, may regulate ABCB1 transcription in hypoxic conditions by modifying chromatin structure and interacting with signaling pathways. However, its role in ABCB1 transcriptional regulation under hypoxia remains unclear. Based on this, the present study employed the BRL cell line to establish a hypoxia model, aiming to investigate the histone acetylation-mediated regulatory mechanisms of ABCB1 expression under hypoxic conditions, with the ultimate goal of providing novel theoretical foundations for rational drug use in high-altitude regions.
Establishment of BRL hypoxia model: BRL cell viability was detected by CCK-8 assay, and HIF-1α expression was measured by RT-qPCR and Western blot. After treating the BRL hypoxia model with HDAC inhibitors, ABCB1 and HDAC5 expression were detected by RT-qPCR, Western blot, and immunofluorescence. Rhodamine 123 accumulation assay was performed to examine the effect of HDAC inhibitors on ABCB1 functional activity. HDAC5 was targeted by siRNA technology to detect ABCB1 and H3K9ac expression. CUT&Tag assay was used to measure H3K9ac levels at the ABCB1 promoter region. After SAHA treatment of the BRL hypoxia model, SP1 expression was detected by RT-qPCR and Western blot. Combined treatment with SAHA and siRNA targeting SP1 was performed to detect ABCB1 expression. Co-immunoprecipitation and fluorescence colocalization assays were conducted to examine interactions among SP1, HDAC5, and ABCB1.
After hypoxic culture for different durations, cell viability decreased while HIF-1α expression increased, indicating the successful establishment of the BRL hypoxia model. In the BRL hypoxia model, ABCB1 and SP1 expression decreased while HDAC5 expression increased. After SAHA treatment, ABCB1 and SP1 expression were upregulated while HDAC5 was downregulated. Rhodamine 123 accumulation assay showed that SAHA could enhance ABCB1 functional activity by inducing its expression. After HDAC5 was knocked down using siRNA, ABCB1 and H3K9ac expression increased, and ABCB1 functional activity was enhanced. CUT&Tag assay demonstrated that H3K9ac levels at the promoter region decreased in the BRL hypoxia model, while HDAC5 inhibition increased H3K9ac levels at this region. After SP1 was knocked down using siRNA, the inductive effect of SAHA on ABCB1 was blocked. Co-immunoprecipitation and fluorescence colocalization showed interactions among SP1, HDAC5, and ABCB1.
In BRL cells, HDAC5 may be recruited by SP1 to form a complex, reducing free HDAC5, increasing H3K9ac at the promoter, and activating ABCB1 transcription. In the BRL hypoxia model, disruption of the SP1-HDAC5 complex increased free HDAC5, lowered H3K9ac at the promoter, and suppressed ABCB1 transcription. These results suggest that HDAC inhibitors enhance ABCB1 expression in hypoxic environments, indicating that combining HDAC inhibitors with therapeutic agents could mitigate reduced drug efficacy and adverse effects caused by ABCB1 suppression.
先前的研究表明,高海拔地区的缺氧环境会显著改变许多药物的药代动力学,降低其疗效并增加不良反应。这种药物代谢改变的一个关键因素是高原大鼠肝脏组织中ATP结合盒亚家族B成员1(ABCB1)(一种外排转运蛋白)受到抑制。大鼠ABCB1由 和 基因编码,有两种与人类ABCB1功能类似的亚型。组蛋白乙酰化作为一种表观遗传机制,可能通过修饰染色质结构并与信号通路相互作用,在缺氧条件下调节ABCB1转录。然而,其在缺氧状态下对ABCB1转录调控中的作用仍不清楚。基于此,本研究采用BRL细胞系建立缺氧模型,旨在探究缺氧条件下组蛋白乙酰化介导的ABCB1表达调控机制,最终目的是为高海拔地区合理用药提供新的理论基础。
BRL缺氧模型的建立:采用CCK-8法检测BRL细胞活力,通过RT-qPCR和蛋白质免疫印迹法检测缺氧诱导因子-1α(HIF-1α)表达。用组蛋白去乙酰化酶(HDAC)抑制剂处理BRL缺氧模型后,通过RT-qPCR、蛋白质免疫印迹法和免疫荧光法检测ABCB1和HDAC5表达。进行罗丹明123蓄积试验以检测HDAC抑制剂对ABCB1功能活性的影响。利用小干扰RNA(siRNA)技术靶向HDAC5,检测ABCB1和组蛋白H3赖氨酸9乙酰化(H3K9ac)表达。采用切割与标签(CUT&Tag)试验检测ABCB1启动子区域的H3K9ac水平。用辛二酰苯胺异羟肟酸(SAHA)处理BRL缺氧模型后,通过RT-qPCR和蛋白质免疫印迹法检测特异性蛋白1(SP1)表达。联合使用SAHA和靶向SP1的siRNA进行处理,检测ABCB1表达。进行免疫共沉淀和荧光共定位试验,以检测SP1、HDAC5和ABCB1之间的相互作用。
在不同时长的缺氧培养后,细胞活力下降而HIF-1α表达增加,表明成功建立了BRL缺氧模型。在BRL缺氧模型中,ABCB1和SP1表达降低,而HDAC5表达增加。SAHA处理后,ABCB1和SP1表达上调,HDAC5表达下调。罗丹明123蓄积试验表明,SAHA可通过诱导ABCB1表达增强其功能活性。使用siRNA敲低HDAC5后,ABCB1和H3K9ac表达增加,ABCB1功能活性增强。CUT&Tag试验表明,BRL缺氧模型中 启动子区域的H3K9ac水平降低,而抑制HDAC5可增加该区域的H3K9ac水平。使用siRNA敲低SP1后,SAHA对ABCB1的诱导作用被阻断。免疫共沉淀和荧光共定位显示SP1、HDAC5和ABCB1之间存在相互作用。
在BRL细胞中,SP1可能招募HDAC5形成复合物,减少游离HDAC5,增加 启动子处的H3K9ac,并激活ABCB1转录。在BRL缺氧模型中,SP1-HDAC5复合物的破坏增加了游离HDAC5,降低了 启动子处的H3K9ac,并抑制了ABCB1转录。这些结果表明,HDAC抑制剂可增强缺氧环境下ABCB1的表达,提示将HDAC抑制剂与治疗药物联合使用可减轻因ABCB1抑制导致的药物疗效降低和不良反应。
