Allosteric Communication in the Dynein Motor Domain

Bhabha, Gira; Cheng, Hui‐Chun; Zhang, Nan; Moeller, Arne; Liao, Maofu; Speir, Jeffrey A.; Cheng, Yifan; Vale, Ronald D.

doi:10.1016/j.cell.2014.10.018

Cited by 108 publications

(288 citation statements)

References 65 publications

(92 reference statements)

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“…We therefore assume that these two sites are unoccupied and that nucleotide occupancy of the Pex1 subunits has a major effect on subunit spacing. A correlation between subunit spacing and nucleotide occupancy has also been observed in recent structures of dynein (50). In our ATPγS structure, some of the occupied sites might contain ADP, as the differences from the ADP structure are only small and ATPγS can slowly be hydrolyzed or be contaminated with ADP.…”

Section: Discussionmentioning

confidence: 79%

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Blok

Tan

Wang

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Members of the AAA family of ATPases assemble into hexameric double rings and perform vital functions, yet their molecular mechanisms remain poorly understood. Here, we report structures of the Pex1/Pex6 complex; mutations in these proteins frequently cause peroxisomal diseases. The structures were determined in the presence of different nucleotides by cryo-electron microscopy. Models were generated using a computational approach that combines Monte Carlo placement of structurally homologous domains into density maps with energy minimization and refinement protocols. Pex1 and Pex6 alternate in an unprecedented hexameric double ring. Each protein has two N-terminal domains, N1 and N2, structurally related to the single N domains in p97 and N-ethylmaleimide sensitive factor (NSF); N1 of Pex1 is mobile, but the others are packed against the double ring. The N-terminal ATPase domains are inactive, forming a symmetric D1 ring, whereas the C-terminal domains are active, likely in different nucleotide states, and form an asymmetric D2 ring. These results suggest how subunit activity is coordinated and indicate striking similarities between Pex1/Pex6 and p97, supporting the hypothesis that the Pex1/Pex6 complex has a role in peroxisomal protein import analogous to p97 in ER-associated protein degradation.Pex1 | Pex6 | AAA ATPase | cryo-electron microscopy | peroxisome T he AAA (ATPases associated with diverse cellular activities) family of ATPases contains a large number of proteins that perform important functions in cells (1). Many members of this family form hexamers. These hexamers consist either of a single ring of ATPase domains or of stacked rings formed by tandem ATPase domains in a single polypeptide chain (type I and II ATPases, respectively). Both classes of AAA ATPases often use the energy of ATP hydrolysis to move macromolecules. Examples of single-ring ATPases include the F1 ATPase (2), which rotates a polypeptide inside its central pore, ClpX (3), which moves polypeptides into the proteolytic chamber of ClpP, and the helicase gp4 of T7 phage (4), which pulls a DNA strand through its center. Double-ring ATPases generally act on polypeptides. Prominent members of this family include N-ethylmaleimide sensitive factor (NSF), p97/VCP (valosin-containing protein), and Hsp104 in eukaryotes and ClpB in bacteria (5-7). NSF dissociates SNARE complexes generated during membrane fusion, p97/VCP plays a role in many processes, including ERassociated protein degradation (ERAD), and Hsp104 and ClpB disassemble protein aggregates.The molecular mechanism of many hexameric AAA ATPases is only poorly understood, particularly for those that move polypeptide chains. In addition, the mechanism appears to differ among the known examples. For the F1 ATPase, it has been established that ATPase domains hydrolyze ATP continuously in a strictly consecutive manner around the ring (2). In contrast, in another single-ring ATPase, ClpX, several ATPase domains hydrolyze ATP in sporadic bursts, either simultaneously or in short succession...

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Section: Discussionmentioning

confidence: 79%

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Blok

Tan

Wang

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…However, recent reports relate linker conformation to dynein's ATPase activities. In the absence of load, ATP at AAA3 blocks reorientation of the linker from the post-to the prepowerstroke conformation (9). In addition, binding of the cofactor Lis1, which mechanically obstructs linker movements, uncouples AAA1's ATPase activities from changes in MT-binding affinity (44).…”

Section: Discussionmentioning

confidence: 99%

“…Although AAA3 plays an important role in controlling dynein-MT attachment (22,23,25), the details are just emerging. By probing dynein-MT interactions in the absence of load (9,34) and with force applied to the dynein C terminus (34), DeWitt et al and Bhabha et al concluded that AAA3 must be in a posthydrolysis state for ATP-induced, AAA1-mediated MT release. Our MTBR and C-terminal pulling results support these findings, but if tension is applied via the linker, then AAA1-mediated MT release is allowed when AAA3 enters the ATP state.…”

Section: Discussionmentioning

confidence: 99%

“…Finally, we dissect AAA1-and AAA3-mediated nucleotide-induced modulation of dynein's inherent response to force, identifying (i) a previously undescribed weakening of MT attachment caused by ADP binding at AAA3 and (ii) a novel function for the linker in the AAA3-mediated "gating" of the nucleotide-dependent regulation of dynein-MT binding by AAA1. When tension is absent or applied via dynein's C terminus, ATP binding to AAA1 induces MT release only if AAA3 is in the posthydrolysis state, as described recently (9,34). However, under more physiological conditions in which tension is applied to the linker, ATP binding to AAA3 is sufficient to "open" the regulatory gate.…”

Section: Significancementioning

confidence: 99%

“…The stalk configuration influences both MT affinity and ATPase activity (5) and thereby mediates bidirectional allosteric communication between the AAA ring and the MTBD (3,6). Finally, a ∼10-nm "linker" also emerges from the ring and undergoes cyclic reorientations that generate force and displacement (7)(8)(9).…”

mentioning

confidence: 99%

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Cytoplasmic dynein regulates its attachment to microtubules via nucleotide state-switched mechanosensing at multiple AAA domains

Nicholas

Berger

Rao³

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

114

212

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Cytoplasmic dynein is a homodimeric microtubule (MT) motor protein responsible for most MT minus-end-directed motility. Dynein contains four AAA+ ATPases (AAA: ATPase associated with various cellular activities) per motor domain (AAA1-4). The main site of ATP hydrolysis, AAA1, is the only site considered by most dynein motility models. However, it remains unclear how ATPase activity and MT binding are coordinated within and between dynein's motor domains. Using optical tweezers, we characterize the MT-binding strength of recombinant dynein monomers as a function of mechanical tension and nucleotide state. Dynein responds anisotropically to tension, binding tighter to MTs when pulled toward the MT plus end. We provide evidence that this behavior results from an asymmetrical bond that acts as a slip bond under forward tension and a slip-ideal bond under backward tension. ATP weakens MT binding and reduces bond strength anisotropy, and unexpectedly, so does ADP. Using nucleotide binding and hydrolysis mutants, we show that, although ATP exerts its effects via binding AAA1, ADP effects are mediated by AAA3. Finally, we demonstrate "gating" of AAA1 function by AAA3. When tension is absent or applied via dynein's C terminus, ATP binding to AAA1 induces MT release only if AAA3 is in the posthydrolysis state. However, when tension is applied to the linker, ATP binding to AAA3 is sufficient to "open" the gate. These results elucidate the mechanisms of dynein-MT interactions, identify regulatory roles for AAA3, and help define the interplay between mechanical tension and nucleotide state in regulating dynein motility.cytoplasmic dynein | mechanosensing | optical tweezers | AAA+ ATPases | microtubules N umerous eukaryotic cellular processes require motion and force generated by cytoskeletal motor proteins, among which cytoplasmic dynein (hereinafter, "dynein") is unique for its size, complexity, and versatility. As a homodimeric, divergent AAA+ ATPase (AAA: ATPase associated with various cellular activities), dynein drives the majority of microtubule (MT) minusend-directed motility in most eukaryotes (1). The motor functions as a massive protein complex (2), but its catalytic core consists of two identical heavy chains, each with six AAA modules (AAA1-6) linked in tandem to form a ring (Fig. 1A). AAA1-4 bind nucleotides, whereas AAA5 and -6 are structural (3, 4). A ∼15-nm "stalk" emerging from AAA4 (3, 4) separates the AAA modules from the MT-binding domain (MTBD). The stalk configuration influences both MT affinity and ATPase activity (5) and thereby mediates bidirectional allosteric communication between the AAA ring and the MTBD (3, 6). Finally, a ∼10-nm "linker" also emerges from the ring and undergoes cyclic reorientations that generate force and displacement (7-9).For dynein to "walk," one motor domain ("head") must remain MT-bound while the other moves (10-13), thus requiring coordination of the "internal" cycles of both heads. Dynein may use allosteric mechanosensing (possibly through the stalk) to differentiate be...

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Mg²⁺‐free ATP regulates the processivity of native cytoplasmic dynein

et al. 2019

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Cytoplasmic dynein, a microtubule‐based motor protein, is responsible for many cellular functions ranging from cargo transport to cell division. The various functions are carried out by a single isoform of cytoplasmic dynein, thus requiring different forms of motor regulation. A possible pathway to regulate motor function was revealed in optical trap experiments. Switching motor function from single steps to processive runs could be achieved by changing Mg2+ and ATP concentrations. Here, we confirm by single molecule total internal reflection fluorescence microscopy that a native cytoplasmic dynein dimer is able to switch to processive runs of more than 680 consecutive steps or 5.5 μm. We also identified the ratio of Mg2+‐free ATP to Mg.ATP as the regulating factor and propose a model for dynein processive stepping.

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Allosteric Communication in the Dynein Motor Domain

Cited by 108 publications

References 65 publications

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Cytoplasmic dynein regulates its attachment to microtubules via nucleotide state-switched mechanosensing at multiple AAA domains

Mg²⁺‐free ATP regulates the processivity of native cytoplasmic dynein

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Allosteric Communication in the Dynein Motor Domain

Cited by 108 publications

References 65 publications

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Unique double-ring structure of the peroxisomal Pex1/Pex6 ATPase complex revealed by cryo-electron microscopy

Cytoplasmic dynein regulates its attachment to microtubules via nucleotide state-switched mechanosensing at multiple AAA domains

Mg2+‐free ATP regulates the processivity of native cytoplasmic dynein

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Mg²⁺‐free ATP regulates the processivity of native cytoplasmic dynein