Proximity labeling reveals novel interactomes in live Drosophila tissue

• Published in: bioRxiv
• Main Authors: Mannix, Katelynn M, Starble, Rebecca M, Kaufman, Ronit S, Cooley, Lynn
• Format: Paper
• Language: English
• Published: Cold Spring Harbor Cold Spring Harbor Laboratory Press 06.02.2019
• Subjects: Actin; Biotinylation; Canals (anatomy); Cell signaling; Cytoskeleton; Drosophila; Enzymes; Gametogenesis; Germ cells; Insects; Oogenesis; Prey; Proteins; RNA-mediated interference
• DOI: 10.1101/542795

Gametogenesis is dependent on intercellular communication facilitated by stable intercellular bridges connecting developing germ cells. During Drosophila oogenesis, intercellular bridges (referred to as ring canals) have a dynamic actin cytoskeleton that drives their expansion to a diameter of 10μm. While multiple proteins have been identified as components of ring canals (RCs), we lack a basic understanding of how RC proteins interact together to form and regulate the RC cytoskeleton. We optimized a procedure for proximity-dependent biotinylation in live tissue using the APEX enzyme to interrogate the RC interactome. APEX was fused to four different RC components (RC-APEX baits) and 55 unique high-confidence preys were identified. The RC-APEX baits produced almost entirely distinct interactomes that included both known RC proteins as well as uncharacterized proteins. The proximity ligation assay was used to validate close-proximity interactions between the RC-APEX baits and their respective preys. Further, an RNAi screen revealed functional roles for several high-confidence prey genes in RC biology. These findings highlight the utility of enzyme-catalyzed proximity labeling for protein interactome analysis in live tissue and expand our understanding of RC biology.