Collective dynein transport of the nucleus by pulling on astral microtubules during <scp><i>Saccharomyces cerevisiae</i></scp> mitosis

Jain, Kunalika; Khetan, Neha; Yadav, Shivani A.; Palani, Saravanan; Athale, Chaitanya A.

doi:10.1002/yea.3552

Cited by 6 publications

(3 citation statements)

References 64 publications

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“…Previous models have proposed that modulation of the force can be achieved by changes in the number of motors, the individual force per motor, the attachment and detachment rate of motors, and microtubule dynamics, as seen in other systems ( Sutradhar et al. , 2015 ; Jain et al. , 2021 ).…”

Section: Discussionmentioning

confidence: 99%

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

Khatri

Brugière

Athale

et al. 2022

MBoC

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Cellular functions like cell division are remarkably conserved across phyla. However the evolutionary principles of cellular organization that drive it are less well explored. Thus, an essential question remains: to what extent cellular parameters evolve without altering the basic function they sustain? Here we have observed 6 different nematode species for which the mitotic spindle is positioned asymmetrically during the first embryonic division. Whereas the C. elegans spindle undergoes oscillations during its displacement, the spindle elongates without oscillations in other species. We asked which evolutionary changes in biophysical parameters could explain differences in spindle motion while maintaining a constant output. Using laser microsurgery of the spindle we revealed that all species are subjected to cortical pulling forces, of varying magnitudes. Using a viscoelastic model to fit the recoil trajectories and with an independent measurement of cytoplasmic viscosity, we extracted the values of cytoplasmic drag, cortical pulling forces and spindle elasticity for all species. We found large variations in cytoplasmic viscosity whereas cortical pulling forces and elasticity were often more constrained. In agreement with previous simulations, we found that increased viscosity correlates with decreased oscillation speeds across species. However, the absence of oscillations despite low viscosity in some species, can only be explained by smaller pulling forces. Consequently, we find that spindle mobility across the species analyzed here is characterized by a tradeoff between cytoplasmic viscosity and pulling forces normalized by the size of the embryo. Our work provides a framework for understanding mechanical constraints on evolutionary diversification of spindle mobility.

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Section: Discussionmentioning

confidence: 99%

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

Khatri

Brugière

Athale

et al. 2022

MBoC

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“…Long-range directed motion of the SPB is expected during mitosis when the nucleus orients towards the bud and the spindle elongates to separate the chromosome masses of mother and daughter cell (Fig. 7a), but some directed motion of the SPB may also occur in other phases of the cell cycle due to the forces exerted on it by microtubules (42, 43). When fitting individual tracks, we observe a significant fraction of persistently moving SPB (13% with a confidence interval of 95%, Fig.…”

Section: Resultsmentioning

confidence: 99%

Detecting directed motion and confinement in single-particle trajectories using hidden variables

Simon,

Ramadier,

Fonquernie

et al. 2024

Preprint

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Single-particle tracking is a powerful tool for understanding protein dynamics and characterizing microenvironments. As the motion of unconstrained nanoscale particles is governed by Brownian diffusion, deviations from this behavior are biophysically insightful. The stochastic nature of particle movement and the presence of localization error, however, pose a challenge for robust classification of non-Brownian motion. Here, we present aTrack, a versatile tool for classifying and extracting key parameters of tracks in Brownian, confined or directed motion. Our tool quickly and accurately determines estimates motion parameters from individual tracks and categorizes its motion state. Further, our tool can analyze populations of tracks and determine the most likely number of motion states. We demonstrate the working range of our approach on simulated tracks and show the application of our tool for characterizing particle motion in cells and biosensing applications. Our tool is implemented as a stand-alone software package, making it simple to analyze track data.

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“…We found variations in the net pulling forces, by a factor of ~10, between species. Previous models have proposed that modulation of the force can be achieved by changes in the number of motors, the individual force per motor, the attachment and detachment rate of motors, and microtubule dynamics, as seen in other systems (Sutradhar et al, 2015, Jain et al, 2021. Establishing transgenic lines, in particular to follow live microtubules, in these different species is a necessary step towards more quantitative measurements of these parameters.…”

Section: Discussionmentioning

confidence: 99%

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

Khatri

Brugière

Athale

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Cells are the basic unit of biological organization, and their division is remarkably conserved across phyla. However from an evolutionary perspective, it remains unclear how much cellular parameters can diverge, without altering the basic function they sustain. We address the mechanics of asymmetric mitotic spindle positioning during the first embryonic division of six nematode species. We propose a viscoelastic model of spindle positioning and mobility that can provide a physical explanation of why in C. elegans it undergoes oscillations during elongation, whereas most others lack oscillations. To test this model, we measured the pulling forces and opposing cytoplasmic drag by a combination of laser ablation of the anaphase spindle and tracking of intracellular granules. While centrosomes of all species recoil on spindle cutting, quantitative differences correlate with the cytoplasmic viscosity. In fact, increased viscosity correlates with decreased oscillation speeds of intact spindles across species. However, the absence of oscillations despite low viscosity in some species, can only be explained by smaller pulling forces. Consequently, we find that spindle mobility across the species analyzed here is characterized by a tradeoff between cytoplasmic viscosity and pulling forces. Our work provides a framework for understanding mechanical constraints on evolutionary diversification of spindle mobility.

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Collective dynein transport of the nucleus by pulling on astral microtubules during Saccharomyces cerevisiae mitosis

Cited by 6 publications

References 64 publications

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

Detecting directed motion and confinement in single-particle trajectories using hidden variables

Evolutionary divergence of anaphase spindle mechanics in nematode embryos constrained by antagonistic pulling and viscous forces

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