11 research outputs found
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Probing cellular protein complexes using single-molecule pull-down.
Proteins perform most cellular functions in macromolecular complexes. The same protein often participates in different complexes to exhibit diverse functionality. Current ensemble approaches of identifying cellular protein interactions cannot reveal physiological permutations of these interactions. Here we describe a single-molecule pull-down (SiMPull) assay that combines the principles of a conventional pull-down assay with single-molecule fluorescence microscopy and enables direct visualization of individual cellular protein complexes. SiMPull can reveal how many proteins and of which kinds are present in the in vivo complex, as we show using protein kinase A. We then demonstrate a wide applicability to various signalling proteins found in the cytosol, membrane and cellular organelles, and to endogenous protein complexes from animal tissue extracts. The pulled-down proteins are functional and are used, without further processing, for single-molecule biochemical studies. SiMPull should provide a rapid, sensitive and robust platform for analysing protein assemblies in biological pathways
Single molecule fret study on the mechanism of RecA mediated strand exchange
RecA plays a critical role during double strand break repair via homologous recombination. During the strand exchange reaction, RecA forms a helical filament on single stranded (ss) DNA that searches for homology and exchanges complementary base pairs with a homologous double strand (ds) DNA to form a new heteroduplex. The study of strand exchange in ensemble assays is limited by the diffusion limited homology search process which masks the subsequent strand exchange reaction. We developed a single molecule fluorescence assay with a few basepair and milliseconds resolution which can separate initial docking from the subsequent propagation of joint molecule formation. Our data suggests that propagation occurs in 3 bp increments with destabilization of the incoming dsDNA and concomitant pairing with the reference ssDNA. Our model for strand exchange links structural models of RecA to its catalytic function.
Next, we investigated the mechanism of RecA mediated homology search. Using tools with high spatiotemporal resolution to observe the encounter complex between the RecA filament and dsDNA, we present evidence in support of the “sliding model” wherein a RecA filament diffuses on a dsDNA track. Our results suggest that the sliding of the dsDNA relative to the RecA filament can explain the rapid changes in FRET which we have observed upon the docking of non-homologous dsDNA to the RecA filament. We further show that homology can be identified during such sliding. Sliding is thermally driven and occurs in the absence of ATP hydrolysis. Furthermore, homology recognition and basepairing can involve as few as 6 bp of complementarity. Our observation presents an example of how a multi-protein complex bound to DNA can serve as a vehicle enabling homology search processes via 1-D sliding.
Finally, we demonstrate how an extension of the two color FRET assay to measure four colors simultaneously allows us to measure the correlation of reaction completion between the two ends of a single synaptic complex. We expect that this method will enable a multi dimensional analysis of independent reaction coordinates with broad applications in measuring the correlated dynamics of more complex biological system
Direct observation of autoubiquitination for an integral membrane ubiquitin ligase in ERAD
Abstract The endoplasmic reticulum associated degradation (ERAD) pathway regulates protein quality control at the endoplasmic reticulum. ERAD of lumenal and membrane proteins requires a conserved E3 ubiquitin ligase, called Hrd1. We do not understand the molecular configurations of Hrd1 that enable autoubiquitination and the subsequent retrotranslocation of misfolded protein substrates from the ER to the cytosol. Here, we have established a generalizable, single-molecule platform that enables high-efficiency labeling, stoichiometry determination, and functional assays for any integral membrane protein. Using this approach, we directly count Hrd1 proteins reconstituted into individual proteoliposomes. We report that Hrd1 assembles in different oligomeric configurations with mostly monomers and dimers detected at limiting dilution. By correlating oligomeric states with ubiquitination in vitro, we conclude that Hrd1 monomers are inefficient in autoubiquitination while dimers efficiently assemble polyubiquitin chains. Therefore, our results reveal the minimal composition of a Hrd1 oligomer that is capable of autoubiquitination. Our methods are broadly applicable to studying other complex membrane protein functions using reconstituted bilayer systems
HP1 oligomerization compensates for low-affinity H3K9me recognition and provides a tunable mechanism for heterochromatin-specific localization.
HP1 proteins traverse a complex and crowded chromatin landscape to bind with low affinity but high specificity to histone H3K9 methylation (H3K9me) and form transcriptionally inactive genomic compartments called heterochromatin. Here, we visualize single-molecule dynamics of an HP1 homolog, the fission yeast Swi6, in its native chromatin environment. By tracking single Swi6 molecules, we identify mobility states that map to discrete biochemical intermediates. Using Swi6 mutants that perturb H3K9me recognition, oligomerization, or nucleic acid binding, we determine how each biochemical property affects protein dynamics. We estimate that Swi6 recognizes H3K9me3 with ~94-fold specificity relative to unmodified nucleosomes in living cells. While nucleic acid binding competes with Swi6 oligomerization, as few as four tandem chromodomains can overcome these inhibitory effects to facilitate Swi6 localization at heterochromatin formation sites. Our studies indicate that HP1 oligomerization is essential to form dynamic, higher-order complexes that outcompete nucleic acid binding to enable specific H3K9me recognition
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ATP-independent diffusion of double-stranded RNA binding proteins
The proteins harboring double-stranded RNA binding domains (dsRBDs) play diverse functional roles such as RNA localization, splicing, editing, export, and translation, yet mechanistic basis and functional significance of dsRBDs remain unclear. To unravel this enigma, we investigated transactivation response RNA binding protein (TRBP) consisting of three dsRBDs, which functions in HIV replication, protein kinase R(PKR)-mediated immune response, and RNA silencing. Here we report an ATP-independent diffusion activity of TRBP exclusively on dsRNA in a length-dependent manner. The first two dsRBDs of TRBP are essential for diffusion, whereas the third dsRBD is dispensable. Two homologs of TRBP, PKR activator and R3D1-L, displayed the same diffusion, implying a universality of the diffusion activity among this protein family. Furthermore, a Dicer-TRBP complex on dsRNA exhibited dynamic diffusion, which was correlated with Dicer's catalytic activity. These results implicate the dsRNA-specific diffusion activity of TRBP that contributes to enhancing siRNA and miRNA processing by Dicer