Project description:Endoplasmic reticulum (ER) plasticity and ER-phagy are intertwined processes essential for maintaining ER dynamics. We investigated the interplay between two isoforms of the ER-phagy receptor FAM134B in regulating ER remodeling in differentiating myoblasts. During myogenesis, the canonical FAM134B1 is degraded, while its isoform FAM134B2 is transcriptionally upregulated. The switch, favoring FAM134B2, indicates its significance as a regulator of ER morphology during myogenesis. FAM134B2 partial reticulon homology domain, with its rigid conformational characteristics, enables an efficient ER reshaping. FAM134B2 action increases in the active phase of differentiation leading to ER restructuring via ER-phagy, which then reverts to physiological levels when myotubes are mature and the ER reorganized. Knocking out both FAM134B isoforms in myotubes results in aberrant proteome landscape and the formation of dilated ER structures, both of which are rescued by FAM134B2 re-expression. Our results underscore how the fine tuning of FAM134B isoforms and ER-phagy orchestrate the ER dynamics during myogenesis providing insights into the molecular mechanisms governing ER homeostasis in muscle cells.

Project description:Proteomic landscape of human myoblasts and differentiated myotubes

Project description:Endoplasmic reticulum (ER) plasticity and ER-phagy are intertwined processes essential for maintaining ER dynamics. We investigated the interplay between two isoforms of the ER-phagy receptor FAM134B in regulating ER remodeling in differentiating myoblasts. During myogenesis, the canonical FAM134B1 is degraded, while its isoform FAM134B2 is transcriptionally upregulated. The switch, favoring FAM134B2, indicates its significance as a regulator of ER morphology during myogenesis. FAM134B2 partial reticulon homology domain, with its rigid conformational characteristics, enables an efficient ER reshaping. FAM134B2 action increases in the active phase of differentiation leading to ER restructuring via ER-phagy, which then reverts to physiological levels when myotubes are mature and the ER reorganized. Knocking out both FAM134B isoforms in myotubes results in aberrant proteome landscape and the formation of dilated ER structures, both of which are rescued by FAM134B2 re-expression. Our results underscore how the fine tuning of FAM134B isoforms and ER-phagy orchestrate the ER dynamics during myogenesis providing insights into the molecular mechanisms governing ER homeostasis in muscle cells.

Project description:IP-MS interactome of FAM134B1 and FAM134B2 complexes (bimolecular complementation affinity purification (BiCAP) system)

Project description:Proteomic landscape of primary murine myoblasts and differentiated myotubes

Project description:Proteomic landscape of Fam134b knockout C2C12 reconstituted with hFAM134B1 or hFAM134B2

Project description:Lysosomal isolation and mass spectrometry analysis from wild-type C2C12 myotubes and Fam134bknockout C2C12 myotubes

Project description:IP-MS interactome of FAM134B1 and FAM134B2 in C2C12 cells differentiated into myotubes

Project description:Proteomic landscape of Fam134b knockout myoblasts and myotubes

Project description:Proteomic profile of C2C12 myoblasts and differentiated myotubes