Modulating Intra-Nuclear LC3 with Small Molecules Rescues Cells from a Docetaxel-Induced Phenotype

Abstract

AbstractNucleus-associated autophagy has been described as a cellular metabolic response by which nuclear material is actively degraded. This degradation occurs after stress, such as nuclear damage or the onset of tumorigenesis. Here we describe a nucleus-associated autophagic process distinct from other forms of selective autophagy in human cell lines. We found that although nuclear localization of MAP1LC3B (LC3) is not dependent on particular nuclear importins, knockdown of nuclear importins, which causes nuclear stress, can induce a nuclear autophagic response. Our characterization of this autophagic phenomenon was facilitated by chemical modulation of the process via two compounds discovered previously in a high content analysis. These small molecules bidirectionally regulate nuclear LC3 in human renal, pancreatic, and bladder cell lines. One molecule (NSC31762 or DTEP) enhances nuclear LC3 puncta and increases lysosomal targeting of LC3. This compound also decreases the nuclear envelope protein LaminB1. Another molecule (NSC279895 or DIHI) reduces the nuclear localization of LC3. Finally, we applied these chemical tools in the setting of mitotic-disruptor induced nuclear stress. The compound DIHI, shown to reduce nuclear autophagic puncta, diminished the mitotic disruptor effect. These new tools will allow for deeper exploration of nucleus-associated autophagies, and could serve as proof-of-principle in guiding new therapies for diseases involving nuclear stress.