Ida Marie Zobbe Sjøgaard scite author profile

Prestel

et al. 2019

Selective autophagy has emerged as an important mechanism by which eukaryotic cells control the abundance of specific proteins. This mechanism relies on cargo recruitment to autophagosomes by receptors that bind to both the ubiquitin-like AUTOPHAGY8 (ATG8) protein through ATG8-interacting motifs (AIMs) and to the cargo to be degraded. In plants, two autophagy cargo receptors, ATG8-interacting protein 1 (ATI1) and 2 (ATI2), were identified early on, but their molecular properties remain poorly understood. Here, we show that ATI1 and ATI2 are transmembrane proteins with long N-terminal intrinsically disordered regions (IDRs). The N-terminal IDRs contain the functional AIMs, and we use nuclear magnetic resonance spectroscopy to directly observe the disorder-order transition of the AIM upon ATG8 binding. Our analyses also show that the IDRs of ATI1 and ATI2 are not equivalent, because ATI2 has properties of a fully disordered polypeptide, while ATI1 has properties more consistent with a collapsed pre-molten globule-like conformation, possibly as a consequence of a higher content of π-orbital-containing amino acid residues. Finally, we show that a sizable fraction of ATI2, but not ATI1, is phosphorylated in planta.

The N-coil and the globular N-terminal domain of plant ARGONAUTE1 are interaction hubs for regulatory factors

Kausika

et al. 2023

Preprint

The effector complex of RNA interference (RNAi) contains at its core an ARGONAUTE (AGO) protein bound to a small guide RNA. AGO proteins adopt a two-lobed structure in which the N-terminal (N) and Piwi-Argonaute-Zwille (PAZ) domains make up one lobe, while the middle (MID) and Piwi domains make up the other. Specific biochemical functions of PAZ, MID and Piwi domains of eukaryotic AGO proteins have been described, but the functions of the N-terminal domain remain less clear. Here, we use yeast two-hybrid screening with the N-terminal domain of the founding member of the AGO protein family, arabidopsis AGO1, to reveal that it interacts with many factors involved in regulated proteolysis. Interaction with a large group of proteins, including the autophagy cargo receptors ATI1 and ATI2, requires residues in a short, linear region, the N-coil, that joins the MID-Piwi lobe in the three-dimensional structure of AGO. In contrast, the F-box protein AUF1 interacts with AGO1 independently of the N-coil and requires distinct residues in the globular N domain itself. Mutation of AGO1 residues necessary for interaction with protein degradation factors in yeast stabilizes reporters fused to the AGO1 N-terminal domain in plants, supporting their in vivo relevance. Our results define distinct regions of the N domain implicated in protein-protein interaction, and point to a particular importance of the AGO1 N-coil as a site of interaction with regulatory factors.

The N-coil and the globular N-terminal domain of plant ARGONAUTE1 are interaction hubs for regulatory factors

Kausika

et al. 2023

The effector complex of RNA interference (RNAi) contains at its core an ARGONAUTE (AGO) protein bound to a small guide RNA. AGO proteins adopt a two-lobed structure in which the N-terminal (N) and Piwi-Argonaute-Zwille (PAZ) domains make up one lobe, while the middle (MID) and Piwi domains make up the other. Specific biochemical functions of PAZ, MID and Piwi domains of eukaryotic AGO proteins have been described, but the functions of the N domain remain less clear. Here, we use yeast two-hybrid screening with the N domain of the founding member of the AGO protein family, arabidopsis AGO1, to reveal that it interacts with many factors involved in regulated proteolysis. Interaction with a large group of proteins, including the autophagy cargo receptors ATI1 and ATI2, requires residues in a short, linear region, the N-coil, that joins the MID-Piwi lobe in the three-dimensional structure of AGO. In contrast, the F-box protein AUF1 interacts with AGO1 independently of the N-coil and requires distinct residues in the globular N domain itself. Mutation of AGO1 residues necessary for interaction with protein degradation factors in yeast stabilizes reporters fused to the AGO1 N domain in plants, supporting their in vivo relevance. Our results define distinct regions of the N domain implicated in protein-protein interaction, and point to a particular importance of the AGO1 N-coil as a site of interaction with regulatory factors.

Distinction between small RNA-bound and free ARGONAUTE via an N-terminal protein-protein interaction site

Oksbjerg

et al. 2022

Preprint

ARGONAUTE (AGO) proteins bind to small non-coding RNAs to form RNA Induced Silencing Complexes (RISCs). In the RNA-bound state, AGO proteins are stable while RNA-free AGOs undergo regulated proteolysis or associate with chaperonesen routeto RISC maturation. Molecular determinants unique to RNA-free AGO that allow its specific recognition and degradation remain poorly characterized. Here, we show that the Arabidopsis autophagy cargo receptor ATI1 interacts with unloaded AGO1 via multiple interaction sites that include direct contact to a confined, linear region in AGO1, the N-coil. The N-coil is accessible to antibodies preferentially in the RNA-free state of AGO1, and influences its degradation ratein vivo. These results provide insight into the molecular basis for specific recognition of the RNA-free state of eukaryotic AGO proteins, and introduce a new tool for its further study.

Distinction between small RNA-bound and free ARGONAUTE via an N-terminal protein-protein interaction site

Prestel

et al. 2023

Preprint

ARGONAUTE (AGO) proteins bind to small non-coding RNAs to form RNA Induced Silencing Complexes (RISCs). In the RNA-bound state, AGO proteins are stable while RNA-free AGOs turn over rapidly. Molecular determinants unique to RNA-free AGO that allow its specific recognition and degradation remain unknown. Here, we show that a confined, linear region in Arabidopsis AGO1, the N-coil, is accessible to antibodies preferentially in the RNA-free state of AGO1. Reanalysis of hydrogen-deuterium exchange data on human Ago2 indicates similar structural flexibility of the N-coil depending on small RNA binding. Unloaded Arabidopsis AGO1 interacts with the autophagy cargo receptor ATI1 via direct contact to specific amino acid residues in the N-coil, and mutation of residues required for ATI1 interaction reduces the degradation rate of unloaded AGO1 in vivo. These results provide insight into the molecular basis for specific recognition and degradation of the RNA-free state of eukaryotic AGO proteins.