内含子
RNA沉默
核糖核酸
生物
细胞质
细胞生物学
RNA剪接
核糖核酸酶P
铝元素
内生
第二组内含子
化学
遗传学
基因
机制(生物学)
酶
核糖核酸酶
分子生物学
内源性逆转录病毒
作者
Chaorui Duan,Luke Buerer,Cory Bowers,Allison J. Taggart,Mara H. O’Brien,Sarah Gunasekera,Chien-Ling Lin,Jing Wang,Yi Zeng,Jonathan P. Staley,Alger M. Fredericks,Sean F. Monaghan,Anastasia Welch,Nathaniel E. Clark,Daxing Gao,Nico Marr,Shen-Ying Zhang,J. Casanova,William G. Fairbrother
摘要
Loss of the lariat debranching enzyme DBR1 causes cytoplasmic accumulation of intron lariats, but why this reduces cell-intrinsic immunity is unclear. Here, we show that intronic inverted repeats Alu (IR Alus), normally degraded after splicing, form long double-stranded RNA (dsRNA) structures when lariats escape recycling. Viral introns evolve under pressure to avoid dsRNA, whereas human introns are enriched for them. Using computational, immunostaining, and genomic approaches, we demonstrate that DBR1 deficiency elevates cytoplasmic dsRNA and attenuates RNase L and PKR signaling. Our data suggest high levels of IR Alu dsRNA titrate PKR, potentially providing a mechanistic explanation for viral susceptibility in DBR1-deficient cells. Cytoplasmic RIP-seq against dsRNA finds introns to be a more abundant source of IR Alus than 3' UTRs in WT cells. Our findings suggest the high load of IR Alus in introns creates a situation where the efficiency of lariat recycling is a powerful modulator of endogenous dsRNA levels in human cells.
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