Theoretical Analysis of Microtubule Dynamics at All Times

Li, Xin; Kolomeisky, Anatoly B.

doi:10.1021/jp507206f

Cited by 10 publications

(6 citation statements)

References 30 publications

(106 reference statements)

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“…While our focus was on GTP hydrolysis and GTP‐cap size maintenance to trigger catastrophes, more recent modeling has demonstrated the emergence of a “stochastic cap” arising from modeling unbinding events between protofilaments (Margolin et al, 2012). Additionally, modeling microscopic details has been shown to be useful for predicting the effect of MT aging on increased catastrophe rates (Li & Kolomeisky, 2014). Thus, despite the limitations of this study, primarily the low concentration of the isolated protein and the presence of even lower concentrations of copurified proteins, our ability to assemble MTs from an unusual plant source provides an opportunity to examine the diversity of available tubulins to further refine our models.…”

Section: Discussionmentioning

confidence: 99%

Polymerization kinetics of tubulin from mung seedlings modeled as a competition between nucleation and GTP‐hydrolysis rates

et al. 2021

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Microtubules (MTs) form physiologically important cytoskeletal structures that are assembled by tubulin polymerization in nucleation‐ and guanosine triphosphate (GTP)‐dependent manner. GTP hydrolysis competes with the addition of monomers, to determine the GTP‐cap size, and the onset of shrinkage, which alternates with growth. Multiple theoretical models of MT polymerization dynamics have been reconciled to the kinetics of animal brain tubulins, but more recently, rapid kinetics seen in Arabidopsis tubulin polymerization suggest the need to sample a wider diversity in tubulin polymerization kinetics and reconcile it to theory. Here, we isolated tubulin from seedlings of Vigna sp. (mung bean), compared polymerization kinetics to animal brain tubulin, and used a computational model to understand the differences. We find that activity‐isolated mung tubulin polymerizes in a nucleation‐dependent manner, based on turbidimetry, qualitatively similar to brain tubulin, but with a 10‐fold smaller critical concentration. GTP‐dependent polymerization kinetics also appear to be transient, indicative of high rates of GTP hydrolysis. Computational modeling of tubulin nucleation and vectorial GTP hydrolysis to examine the effects of high nucleation and GTP‐hydrolysis rates predicts a dominance of the latter in determining MT lengths and numbers. Microscopy of mung tubulin filaments stabilized by GMPCPP or taxol results in few and short MTs, compared to the many long MTs arising from goat tubulin, qualitatively matching the model predictions. We find GTP‐hydrolysis outcompetes nucleation rates in determining MT lengths and numbers.

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Section: Discussionmentioning

confidence: 99%

Polymerization kinetics of tubulin from mung seedlings modeled as a competition between nucleation and GTP‐hydrolysis rates

et al. 2021

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“…We utilized both the simplified and detailed computational models because each has particular strengths for addressing problems related to MT dynamics. The simplified model has fewer kinetic parameters, all of which are directly comparable to parameters in typical analytical models (i.e., mathematical equations), and it is similar to single-protofilament models that have been used by other authors (e.g., Padinhateeri et al, 2012;Li and Kolomeisky, 2014;Aparna et al, 2017). Thus, the simplified model is useful for testing analytical model predictions relating biochemical properties to individual filament level and bulk population level behaviors.…”

Section: Computational Models: Simplified Model and Detailed Modelmentioning

confidence: 99%

Behaviors of individual microtubules and microtubule populations relative to critical concentrations: dynamic instability occurs when critical concentrations are driven apart by nucleotide hydrolysis

Jonasson

Mauro

et al. 2020

MBoC

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“…Even for the apparently simple case of a single protofilament, solving these models is difficult and requires sophisticated mathematical techniques. Recently two important cases, the vectorial and random hydrolysis models, were solved analytically, meaning that mathematical expressions could be derived that give the growth speed and catastrophe frequency in terms of the molecular rate constants [65–69] ( see Box 1 for further details). The expressions can then be readily compared to experimental data.…”

Section: Models Of Catastrophementioning

confidence: 99%

Regulation of Microtubule Growth and Catastrophe: Unifying Theory and Experiment

Bowne-Anderson

Hibbel

Howard

2015

Trends in Cell Biology

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Recent studies have found that microtubule-associated proteins (MAPs) can regulate the dynamical properties of microtubules in unexpected ways. For most MAPs, there is an inverse relationship between their effects on the speed of growth and the frequency of catastrophe, the conversion of a growing microtubule to a shrinking one. Such a negative correlation is predicted by the standard GTP-cap model, which posits that catastrophe is due to loss of a stabilizing cap of GTP-tubulin at the end of a growing microtubule. However, many other MAPs, notably Kinesin-4 and combinations of EB1 with XMAP215, contradict this general rule. In this review, we show that a more nuanced, but still simple, GTP-cap model, can account for the diverse regulatory activities of MAPs.

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Theoretical Analysis of Microtubule Dynamics at All Times

Cited by 10 publications

References 30 publications

Polymerization kinetics of tubulin from mung seedlings modeled as a competition between nucleation and GTP‐hydrolysis rates

Polymerization kinetics of tubulin from mung seedlings modeled as a competition between nucleation and GTP‐hydrolysis rates

Behaviors of individual microtubules and microtubule populations relative to critical concentrations: dynamic instability occurs when critical concentrations are driven apart by nucleotide hydrolysis

Regulation of Microtubule Growth and Catastrophe: Unifying Theory and Experiment

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