Our integrative genomic and functional analysis identified transforming acidic coiled-coil–containing protein 2 (TACC2) as a chronic obstructive pulmonary disease (COPD) candidate gene. Here, we found that smokers with COPD exhibit a marked decrease in lung TACC2 protein levels relative to smokers without COPD. Single cell RNA sequencing reveals that TACC2 is expressed primarily in lung epithelial cells in normal human lungs. Furthermore, suppression of TACC2 expression impairs the efficiency of homologous recombination repair and augments spontaneous and cigarette smoke extract–induced (CSE-induced) DNA damage and cytotoxicity in immortalized human bronchial epithelial cells. By contrast, enforced expression of TACC2 attenuates the CSE effects. We also found that CSE enhances TACC2 degradation via the ubiquitin-proteasome system mediated by the ubiquitin E3 ligase subunit, F box L7. Furthermore, cellularly expressed TACC2 proteins harboring naturally occurring mutations exhibited altered protein lifespan coupled with modified DNA damage repair and cytotoxic responses. CS triggers emphysematous changes accompanied by accumulated DNA damage, apoptosis of alveolar epithelia, and lung inflammation in Tacc2–/– compared with Tacc2+/+ mice. Our results suggest that CS destabilizes TACC2 protein in lung epithelia by the ubiquitin proteasome system, leading to subsequent DNA damage, cytotoxicity, and emphysema.
Rama K. Mallampalli, Xiuying Li, Jun-Ho Jang, Tomasz Kaminski, Aki Hoji, Tiffany Coon, Divay Chandra, Starr Welty, Yaqun Teng, John Sembrat, Mauricio Rojas, Yutong Zhao, Robert Lafyatis, Chunbin Zou, Frank Sciurba, Prithu Sundd, Li Lan, Toru Nyunoya
The genetic deletion of TACC2 augments cigarette smoke–induced DNA damage and emphysema.