NBR1 was discovered as an autophagy receptor not long after the first described vertebrate autophagy receptor p62/SQSTM1. Since then, p62 has currently been mentioned in >10,000 papers on PubMed, while NBR1 is mentioned in <350 papers. Nonetheless, evolutionary analysis reveals that NBR1, and likely also selective autophagy, was present already in the last eukaryotic common ancestor (LECA), while p62 appears first in the early Metazoan lineage. Furthermore, yeast-selective autophagy receptors Atg19 and Atg34 represent NBR1 homologs. NBR1 is the main autophagy receptor in plants that do not contain p62, while most animal taxa contain both NBR1 and p62. Mechanistic studies are starting to shed light on the collaboration between mammalian NBR1 and p62 in the autophagic degradation of protein aggregates (aggrephagy). Several domains of NBR1 are involved in cargo recognition, and the list of known substrates for NBR1-mediated selective autophagy is increasing. Lastly, roles of NBR1 in human diseases such as proteinopathies and cancer are emerging.
It is becoming increasingly clear that the Atg8 family of autophagy proteins have roles not only in the cytoplasm, but also in the cell nucleus. In this issue, Jiménez-Moreno et al. (2023. J. Cell Biol.https://doi.org/10.1083/jcb.201910133) report that nuclear LC3B binds to the LIM homeodomain transcription factor LMX1B and acts as a cofactor for LMX1B-mediated transcription of autophagy genes, providing stress protection and ensuring survival of midbrain dopaminergic neurons.
Macroautophagy (hereafter referred to as autophagy) degrades a variety of cellular components. A poorly understood area is autophagic degradation of nuclear substrates, or "nuclear autophagy". It remains unclear what can be degraded by autophagy from the mammalian nuclei. We began our study by investigating the nuclear binding partners of ATG8 family proteins that play important roles in recognizing autophagy substrates. We systematically evaluated the ATG8 nuclear interactome in primary human cells and in mouse brain, identifying hundreds of novel interactions. We continued our study by evaluating the nuclear proteomes of cellular senescence, a stable form of cell cycle arrest program associated with inflammation, in which nuclear autophagy is involved. Combined with the ATG8 nuclear interactome data, we identified WSTF, a component of the ISWI chromatin remodeling complex, as a novel substrate of nuclear autophagy. The degradation of WSTF, mediated by a direct interaction with the GABARAP isoform of ATG8, promotes chromatin accessibility of inflammatory genes and induces senescence-associated inflammation. Furthermore, WSTF directly binds the p65 subunit of NF-κB and inhibits its acetylation, thus blocking inflammatory gene expression in the setting of senescence, cancer, and pathogen infection. In addition, we show that loss of WSTF is required for the immuno-surveillance of oncogenic Ras in mouse liver; forced expression of WSTF inhibited tumor-suppressive inflammation and led to the development of liver tumors. Taken together, our study provides a global view of mammalian nuclear autophagy and reveals a novel nuclear inhibitor of inflammation implicated in diverse pathological contexts. Targeting WSTF may be broadly valuable as therapeutic intervention of inflammatory diseases.
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