The RNA-binding protein RBM39 scaffolds an m⁶A-dependent RNA decay complex that destabilizes Tat transcripts and restricts HIV-1 reactivation.
Xiaohui Deng, Siyi Xie, Mo Zhou, Quyu Yuan, Shuangxin Wu, Peiming Huang, Minghua Chen, Jianteng Zeng, Pengle Guo, Jie Qin, Cancan Chen, Jiaye Liu, Bingfeng Liu, Xin He, Liqin Sun
Abstract
Open AccessThe persistence of latent HIV-1 reservoirs remains a critical barrier to functional curing AIDS, as current latency-reversing agents (LRAs) exhibit limited clinical efficacy. While RNA modifications like N⁶-methyladenosine (m⁶A) regulate viral replication, their role in maintaining HIV-1 latency is poorly defined. Here, we identify the RNA-binding protein RBM39 as a scaffold organizing an m⁶A-dependent silencing complex that enforces viral latency. Through proteomic and functional analyses, we demonstrate that RBM39 recruits the m⁶A reader YTHDC1 and the RNA helicase DDX5, forming a tripartite complex that accelerates Tat RNA decay and enforces viral quiescence. Genetic or pharmacological degradation of RBM39 (using the clinically explored molecular glue indisulam) potently reactivates latent HIV-1 in J-Lat cell models, primary CD4⁺ T cells from people living with HIV-1 (PLWH), and synergizes with established LRAs (Bryostatin-1, JQ-1, SAHA) to broadly activate proviral reservoirs. Our work reveals a previously unrecognized host pathway in which RBM39-organized RNA decay complexes silence HIV-1 through epitranscriptomic regulation of Tat. In addition to establishing RBM39 as a promising therapeutic target for addressing the limitations of current "shock and kill" strategies, our findings establish a novel mechanistic framework for m⁶A-dependent regulation of viral gene expression. This framework may serve as a valuable reference for investigating similar regulatory mechanisms in other latent viral infections or oncogenic processes where RNA methylation plays a pivotal role.