K. Aathavan scite author profile

Homomeric ring-ATPases perform many vital and varied tasks in the cell, ranging from chromosome segregation to protein degradation. Here we report the first direct observation of the inter-subunit coordination and the step size of such a ring-ATPase, the dsDNA packaging motor in the bacteriophage φ29. Using high-resolution optical tweezers, we find that packaging occurs in increments of 10 bp. Statistical analysis of the preceding dwell times reveals that multiple ATPs bind during each dwell, and application of high force reveals that these 10-bp increments are composed of four 2.5-bp steps. These results indicate that the hydrolysis cycles of the individual subunits are highly coordinated via a mechanism novel for ring-ATPases. In addition, a step size that is a non-integer number of base pairs demands new models for motor-DNA interactions.

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Mechanism of Force Generation of a Viral DNA Packaging Motor

Chemla

Aathavan

Michaelis

et al. 2005

Cell

264

352

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A large family of multimeric ATPases are involved in such diverse tasks as cell division, chromosome segregation, DNA recombination, strand separation, conjugation, and viral genome packaging. One such system is the Bacillus subtilis phage phi 29 DNA packaging motor, which generates large forces to compact its genome into a small protein capsid. Here we use optical tweezers to study, at the single-molecule level, the mechanism of force generation in this motor. We determine the kinetic parameters of the packaging motor and their dependence on external load to show that DNA translocation does not occur during ATP binding but is likely triggered by phosphate release. We also show that the motor subunits act in a coordinated, successive fashion with high processivity. Finally, we propose a minimal mechanochemical cycle of this DNA-translocating ATPase that rationalizes all of our findings.

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A Viral Packaging Motor Varies Its DNA Rotation and Step Size to Preserve Subunit Coordination as the Capsid Fills

Liu

Chistol

Hetherington

et al. 2014

Cell

138

174

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SUMMARY Multimeric, ring-shaped molecular motors rely on the coordinated action of their subunits to perform crucial biological functions. During these tasks, motors often change their operation in response to regulatory signals. Here, we investigate a viral packaging machine as it fills the capsid with DNA and encounters increasing internal pressure. We find that the motor rotates the DNA during packaging and that the rotation per basepair increases with filling. This change accompanies a reduction in the motor’s step size. We propose that these adjustments preserve motor coordination by allowing one subunit to make periodic, specific, and regulatory contacts with the DNA. At high filling, we also observe the down-regulation of the ATP-binding rate and the emergence of long-lived pauses, suggesting a throttling-down mechanism employed by the motor near the completion of packaging. This study illustrates how a biological motor adjusts its operation in response to changing conditions, while remaining highly coordinated.

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Substrate interactions and promiscuity in a viral DNA packaging motor

Aathavan

Politzer

Kaplan

et al. 2009

Nature

108

145

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The ASCE superfamily of proteins consists of structurally similar ATPases associated with diverse cellular activities involving metabolism and transport of proteins and nucleic acids in all forms of life1. A subset of these enzymes are multimeric ringed pumps responsible for DNA transport in processes including genome packaging in adenoviruses, herpesviruses, poxviruses, and tailed bacteriophages2. While their mechanism of mechanochemical conversion is beginning to be understood3, little is known about how these motors engage their nucleic acid substrates. Do motors contact a single DNA element, such as a phosphate or a base, or are contacts distributed over multiple parts of the DNA? In addition, what role do these contacts play in the mechanochemical cycle? Here we use the genome packaging motor of the Bacillus subtilis bacteriophage φ294 to address these questions. The full mechanochemical cycle of the motor, whose ATPase is a pentameric-ring5 of gene product 16, involves two phases-- an ATP loading dwell followed by a translocation burst of four 2.5-bp steps6 triggered by hydrolysis product release7. By challenging the motor with a variety of modified DNA substrates, we find that during the dwell phase important contacts are made with adjacent phosphates every 10-bp on the 5’-3’ strand in the direction of packaging. In addition to providing stable, long-lived contacts, these phosphate interactions also regulate the chemical cycle. In contrast, during the burst phase, we find that DNA translocation is driven against large forces by extensive contacts, some of which are not specific to the chemical moieties of DNA. Such promiscuous, non-specific contacts may reflect common translocase-substrate interactions for both the nucleic acid and protein translocases of the ASCE superfamily1.

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Motor-Substrate Interactions in a Ring ATPase

Kaplan

Aathavan

Politzer

et al. 2010

Biophysical Journal

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K. Aathavan

Intersubunit coordination in a homomeric ring ATPase

Mechanism of Force Generation of a Viral DNA Packaging Motor

A Viral Packaging Motor Varies Its DNA Rotation and Step Size to Preserve Subunit Coordination as the Capsid Fills

Substrate interactions and promiscuity in a viral DNA packaging motor

Motor-Substrate Interactions in a Ring ATPase

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