Project description:PROTON GRADIENT REGULATION 5 (PGR5) plays a critical role in generating proton motive force across thylakoid membranes and supporting photoprotection under fluctuating light in C3 plants. It is proposed that this function is achieved by regulating cyclic electron flow around Photosystem I. During the evolutionary transition from C3 to C4 photosynthesis, PGR5 abundance in leaves has increased, coinciding with an enhancement in cyclic electron flow rate. To investigate the role of PGR5 in C4 photosynthesis and photoprotection, we generated Setaria viridis (a model C4 monocot) lines with null PGR5 alleles. We demonstrate that loss of PGR5 severely impairs the establishment of proton motive force, photosynthetic control, and energy-dependent non-photochemical quenching at high irradiances, leading to a loss of Photosystem I activity under light stress. Furthermore, plants lacking PGR5 exhibit drastically reduced growth and photosynthesis when grown under fluctuating daylight; however, they are less severely affected than C3 pgr5 mutants. This relative tolerance arises from the ability of S. viridis lacking PGR5 to maintain significant levels of photosynthetic control, in contrast to C3 mutants. Additionally, in the absence of PGR5 and qE, a slower-relaxing, zeaxanthin-dependent form of non-photochemical quenching supports survival under fluctuating light, albeit at the cost of reduced photochemical efficiency and assimilation. Our findings highlight the essential role of PGR5 in enabling efficient C4 photosynthesis under fluctuating light by regulating photosynthetic control and energy-dependent non-photochemical quenching. This study also uncovers the interplay between multiple photoprotective mechanisms safeguarding C4 photosynthesis under light stress.

Project description:Advancement in fluorescence imaging techniques enables the study of protein dynamics and localization with unprecedented spatiotemporal resolution. However, current imaging tools are unable to elucidate dynamic protein interactomes underlying imaging observations. In contrast, proteomics tools such as proximity labeling enable the analysis of protein interactomes at a single time point but lack information about protein dynamics. We herein developed Silicon-rhodamine-enabled Identification (SeeID) for near-infrared light controlled proximity labeling that could bridge the gap between imaging and proximity labeling. SeeID was benchmarked through characterization of various organelle-specific proteomes and the KRAS protein interactome. The fluorogenic nature of SiR allows for intracellular proximity labeling with high subcellular specificity. Leveraging SiR as both a fluorophore and a photocatalyst, we developed a protocol that allows the study of dynamic protein interactomes of Parkin during mitophagy. We discovered the association of the proteasome complex with Parkin at early time points, indicating the involvement of the ubiquitin-proteasome system for protein degradation in the early phase of mitophagy. In addition, by virtue of the deep tissue penetration of near-infrared light, we achieved spatiotemporally controlled proximity labeling in vivo across the mouse brain cortex with a labeling depth of ~2 mm using an off-the-shelf 660 nm LED light set-up.

Project description:Activity-dependent protein synthesis is critical for determining changes in dendritic proteomes underlying brain function, yet the mechanisms governing these changes are lacking. Here, we combined proximity-based labeling of dendritic transcriptome, translatome, and proteome to study the dynamics of RNA regulation in activated synapses. We discovered that depolarization leads to a switch from RNAs translated under basal conditions to new translation of previously unrecognized subsets of depolarization-dependent transcripts. Dynamically regulated RNAs bound by specific regulatory proteins, including NOVA1, FMRP, and ELAVLs, rapidly generate proteins with roles in mitochondrial regulation, RNA metabolism, translational control, and synaptic signaling in dendrites. Knockdowns of activity-induced dendritic RNAs altered neuronal physiology, underscoring how dynamic switches in the regulation of RNAs encoding coordinated sets of proteins underlie synaptic plasticity.

Project description:Activity-dependent protein synthesis is critical for determining changes in dendritic proteomes underlying brain function, yet the mechanisms governing these changes are lacking. Here, we combined proximity-based labeling of dendritic transcriptome, translatome, and proteome to study the dynamics of RNA regulation in activated synapses. We discovered that depolarization leads to a switch from RNAs translated under basal conditions to new translation of previously unrecognized subsets of depolarization-dependent transcripts. Dynamically regulated RNAs bound by specific regulatory proteins, including NOVA1, FMRP, and ELAVLs, rapidly generate proteins with roles in mitochondrial regulation, RNA metabolism, translational control, and synaptic signaling in dendrites. Knockdowns of activity-induced dendritic RNAs altered neuronal physiology, underscoring how dynamic switches in the regulation of RNAs encoding coordinated sets of proteins underlie synaptic plasticity.

Project description:Off-the-shelf proximity labeling

Project description:Proximity labeling with genetically encoded enzymes is widely used to study protein-protein interactions in cells. However, the resolution and accuracy of proximity labeling methods are limited by a lack of control over the enzymatic labeling process. Here, we present a high spatial and temporal resolution technology that can be activated on demand using light, for high accuracy proximity labeling. Our system, called Light Activated BioID (LAB), is generated by fusing the two halves of the split-TurboID proximity labeling enzyme to the photodimeric proteins CRY2 and CIB1. Using live cell imaging, immunofluorescence, western blotting, and mass spectrometry, we show that upon exposure to blue light, CRY2 and CIB1 dimerize, reconstitute the split-TurboID enzyme, and biotinylate proximate proteins. Turning off the light halts the biotinylation reaction. We validate LAB in different cell types and demonstrate that it can identify known binding partners of proteins while reducing background labeling and false positives.

Project description:Proximity labeling traditionally identifies interactomes of a single protein or RNA, though this approach limits mechanistic understanding of biomolecules functioning within complex systems. Here, we demonstrate a strategy for deciphering ligand-induced changes to global biomolecular interactions by enabling proximity labelling at the mesoscale, across an entire cellular system. By inserting nanoscale proximity labelling catalysts throughout chromatin, this system, MesoMap, provided new insights into how HDAC inhibitors regulate gene expression. Furthermore, it revealed that the orphaned drug candidate, SR-1815, regulates disease-linked Syngap1 gene expression through direct inhibition of kinases implicated in both neurological disorders and cancer. Through precise mapping of global chromatin mobility, MesoMap promotes insights into how drug-like chemical probes induce transcriptional dynamics within healthy and disease-associated cellular states.

Project description:Proximity labeling traditionally identifies interactomes of a single protein or RNA, though this approach limits mechanistic understanding of biomolecules functioning within complex systems. Here, we demonstrate a strategy for deciphering ligand-induced changes to global biomolecular interactions by enabling proximity labelling at the mesoscale, across an entire cellular system. By inserting nanoscale proximity labelling catalysts throughout chromatin, this system, MesoMap, provided new insights into how HDAC inhibitors regulate gene expression. Furthermore, it revealed that the orphaned drug candidate, SR-1815, regulates disease-linked Syngap1 gene expression through direct inhibition of kinases implicated in both neurological disorders and cancer. Through precise mapping of global chromatin mobility, MesoMap promotes insights into how drug-like chemical probes induce transcriptional dynamics within healthy and disease-associated cellular states.

Project description:Proximity labeling traditionally identifies interactomes of a single protein or RNA, though this approach limits mechanistic understanding of biomolecules functioning within complex systems. Here, we demonstrate a strategy for deciphering ligand-induced changes to global biomolecular interactions by enabling proximity labelling at the mesoscale, across an entire cellular system. By inserting nanoscale proximity labelling catalysts throughout chromatin, this system, MesoMap, provided new insights into how HDAC inhibitors regulate gene expression. Furthermore, it revealed that the orphaned drug candidate, SR-1815, regulates disease-linked Syngap1 gene expression through direct inhibition of kinases implicated in both neurological disorders and cancer. Through precise mapping of global chromatin mobility, MesoMap promotes insights into how drug-like chemical probes induce transcriptional dynamics within healthy and disease-associated cellular states.

Project description:Proximity labeling traditionally identifies interactomes of a single protein or RNA, though this approach limits mechanistic understanding of biomolecules functioning within complex systems. Here, we demonstrate a strategy for deciphering ligand-induced changes to global biomolecular interactions by enabling proximity labelling at the mesoscale, across an entire cellular system. By inserting nanoscale proximity labelling catalysts throughout chromatin, this system, MesoMap, provided new insights into how HDAC inhibitors regulate gene expression. Furthermore, it revealed that the orphaned drug candidate, SR-1815, regulates disease-linked Syngap1 gene expression through direct inhibition of kinases implicated in both neurological disorders and cancer. Through precise mapping of global chromatin mobility, MesoMap promotes insights into how drug-like chemical probes induce transcriptional dynamics within healthy and disease-associated cellular states.