Bo Sun scite author profile

Subcellular membrane-less organelles consist of proteins with low complexity domains. Many of them, such as hnRNPA1, can assemble into both a polydisperse liquid phase and an ordered solid phase of amyloid fibril. The former mirrors biological granule assembly, while the latter is usually associated with neurodegenerative disease. Here, we observe a reversible amyloid formation of hnRNPA1 that synchronizes with liquid–liquid phase separation, regulates the fluidity and mobility of the liquid-like droplets, and facilitates the recruitment of hnRNPA1 into stress granules. We identify the reversible amyloid-forming cores of hnRNPA1 (named hnRACs). The atomic structures of hnRACs reveal a distinct feature of stacking Asp residues, which contributes to fibril reversibility and explains the irreversible pathological fibril formation caused by the Asp mutations identified in familial ALS. Our work characterizes the structural diversity and heterogeneity of reversible amyloid fibrils and illuminates the biological function of reversible amyloid formation in protein phase separation.

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ATP-induced helicase slippage reveals highly coordinated subunits

Sun

Johnson

Patel

et al. 2011

Nature

104

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Helicases are vital enzymes that carry out strand separation of duplex nucleic acids during replication, repair, and recombination1,2. Bacteriophage T7 gene product 4 is a model hexameric helicase which has been observed to utilize dTTP, but not ATP, to unwind dsDNA as it translocates from 5′ to 3′ along ssDNA2–6. Whether and how different subunits of the helicase coordinate their chemo-mechanical activities and DNA binding during translocation is still under debate1,7. Here we address this question using a single molecule approach to monitor helicase unwinding. We discovered that T7 helicase does in fact unwind dsDNA in the presence of ATP and the unwinding rate is even faster than that with dTTP. However unwinding traces showed a remarkable sawtooth pattern where processive unwinding was repeatedly interrupted by sudden slippage events, ultimately preventing unwinding over a substantial distance. This behavior was not observed with dTTP alone and was greatly reduced when ATP solution was supplemented with a small amount of dTTP. These findings presented an opportunity to use nucleotide mixtures to investigate helicase subunit coordination. We found T7 helicase binds and hydrolyzes ATP and dTTP by competitive kinetics such that the unwinding rate is dictated simply by their respective Vmax, KM, and concentrations. In contrast, processivity does not follow a simple competitive behavior and shows a cooperative dependence on nucleotide concentrations. This does not agree with an uncoordinated mechanism where each subunit functions independently, but supports a model where nearly all subunits coordinate their chemo-mechanical activities and DNA binding. Our data indicate that only one subunit at a time can accept a nucleotide while other subunits are nucleotide-ligated and thus interact with the DNA to ensure processivity. Such subunit coordination may be general to many ring-shaped helicases and reveals a potential mechanism for regulation of DNA unwinding during replication.

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Impediment of E. coli UvrD by DNA-destabilizing force reveals a strained-inchworm mechanism of DNA unwinding

Sun

Wei

Zhang

et al. 2008

EMBO J

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Escherichia coli UvrD is a non-ring-shaped model helicase, displaying a 3 0 -5 0 polarity in DNA unwinding. Using a transverse magnetic tweezer and DNA hairpins, we measured the unwinding kinetics of UvrD at various DNAdestabilizing forces. The multiform patterns of unwinding bursts and the distributions of the off-times favour the mechanism that UvrD unwinds DNA as a dimer. The two subunits of the dimer coordinate to unwind DNA processively. They can jointly switch strands and translocate backwards on the other strand to allow slow (B40 bp/s) rewinding, or unbind simultaneously to allow quick rehybridization. Partial dissociation of the dimer results in pauses in the middle of the unwinding or increases the translocation rate from B40 to B150 nt/s in the middle of the rewinding. Moreover, the unwinding rate was surprisingly found to decrease from B45 to B10 bp/s when the force is increased from 2 to 12 pN. The results lead to a strained-inchworm mechanism in which a conformational change that bends and tenses the ssDNA is required to activate the dimer.

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Bo Sun

Structural basis for reversible amyloids of hnRNPA1 elucidates their role in stress granule assembly

ATP-induced helicase slippage reveals highly coordinated subunits

Impediment of E. coli UvrD by DNA-destabilizing force reveals a strained-inchworm mechanism of DNA unwinding

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