Post-copulatory sexual selection is associated with sperm aggregate quality in<i>Peromyscus</i>mice

Hook, Kristin A.; Weber, William; Fisher, Heidi S.

doi:10.1101/2020.02.08.939975

Cited by 4 publications

(4 citation statements)

References 66 publications

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“…The cross-talk between the mechanical micro-environment of living matter and this intrinsic ability of living systems to actively generate self-sustained motion governs pattern formation and self-organization in important biological processes including collective transport of sperm cells in confined tubes [8], shaping bacterial biofilms [9,10], tissue regeneration [11] and sculpting organ development [12]. Not only does the mechanical micro-environment provide geometrical constraints for active materials [13], but it is also often endowed with viscoelastic properties that allow for time-dependent responses to activity-induced stresses and deformations [2,14].…”

Section: Introductionmentioning

confidence: 99%

Activity pulses induce spontaneous flow reversals in viscoelastic environments

Plan

Yeomans

Doostmohammadi

2021

J. R. Soc. Interface.

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Complex interactions between cellular systems and their surrounding extracellular matrices are emerging as important mechanical regulators of cell functions, such as proliferation, motility and cell death, and such cellular systems are often characterized by pulsating actomyosin activities. Here, using an active gel model, we numerically explore spontaneous flow generation by activity pulses in the presence of a viscoelastic medium. The results show that cross-talk between the activity-induced deformations of the viscoelastic surroundings and the time-dependent response of the active medium to these deformations can lead to the reversal of spontaneously generated active flows. We explain the mechanism behind this phenomenon based on the interaction between the active flow and the viscoelastic medium. We show the importance of relaxation time scales of both the polymers and the active particles and provide a phase space over which such spontaneous flow reversals can be observed. Our results suggest new experiments investigating the role of controlled pulses of activity in living systems ensnared in complex mircoenvironments.

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Section: Introductionmentioning

confidence: 99%

Activity pulses induce spontaneous flow reversals in viscoelastic environments

Plan

Yeomans

Doostmohammadi

2021

J. R. Soc. Interface.

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“…A prediction that follows this hypothesis is that species that produce sperm aggregates should have sperm with shorter flagella, but we found no evidence for this prediction in Peromyscus, nor was it observed in diving beetles [29]. Furthermore, sperm aggregates that conjoin in a head-to-head orientation, such as in Peromyscus, are wider, not longer, than a single cell, which will differentially impact the additive force from the cells and their motility [34,37]. Given the diverse mechanisms by which sperm conjugates form in other taxonomic groups [26,27], including in other rodents in which sperm form 'trains' by latching onto (which was not certified by peer review) is the author/funder.…”

Section: Discussionmentioning

confidence: 76%

“…While most Peromyscus species produce sperm with an overall similar morphological design [3, see exceptions within], evidence collected from museum specimens suggests significant interspecific variation in sperm head dimensions across this genus [35]. Moreover, across the genus, all sperm are released as single cells, but some species produce sperm that loosely adhere to one another at their head region, forming sperm aggregates that vary in size [36,37] and in the relatedness of cells that associate with one another [30]. Theoretical models predict that the two-dimensional aspect ratio [36] and three-dimensional shape [34] of sperm heads in the deer mouse (Peromyscus maniculatus) facilitate their aggregation.…”

Section: Introductionmentioning

confidence: 99%

The social shape of sperm: Using an integrative machine-learning approach to examine sperm ultrastructure and collective motility

Hook

Yang

Campanello

et al. 2020

Preprint

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Sperm are one of the most morphologically diverse cell types in nature, yet they also exhibit remarkable behavioral variation, including the formation of collective groups of cells that swim together for motility or transport through the female reproductive tract. Here we take advantage of the natural variation in sperm traits observed across Peromyscus mice to test the hypothesis that the morphology of the rodent sperm head influences their sperm aggregation behavior. Using machine learning and traditional morphometric approaches to quantify and analyze their complex shapes, we show that the elongation of the sperm head is the most distinguishing morphological trait in these rodents and, as predicted, significantly associates with collective sperm movements obtained from in vitro observations. We then successfully use neural network analysis to predict the size and proportion of sperm aggregates from sperm head morphology and show that species whose sperm feature relatively wider heads aggregate more often and form larger groups, providing support for the theoretical prediction that an adhesive region around the equatorial region of the sperm head mediates these unique gametic interactions. Together these findings advance our understanding of how even subtle variation in sperm design can drive differences in sperm function and performance.Subject AreasEvolution, Cellular Biology, Behavior

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“…Cooperation between sperm is a behaviour that assists them on their way to the fertilization site and enhances their chance to reach the oocyte. It is thought that sperm cooperative motion evolved to improve motility under high selection pressure in a competitive context ( 12 ).…”

Section: Introductionmentioning

confidence: 99%

Bundle formation of sperm: Influence of environmental factors

Soler

Hidalgo²,

Fekete³

et al. 2022

Front. Endocrinol.

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Cooperative behaviour of sperm is one of the mechanisms that plays a role in sperm competition. It has been observed in several species that spermatozoa interact with each other to form agglomerates or bundles. In this study, we investigate the effect of physical and biochemical factors that will most likely promote bundle formation in bull sperm. These factors include fluid viscosity, swim-up process, post-thaw incubation time and media additives which promote capacitation. While viscosity does not seem to influence the degree of sperm bundling, swim-up, post-thaw migration time and suppressed capacitation increase the occurrence of sperm bundles. This leads to the conclusion that sperm bundling is a result of hydrodynamic and adhesive interactions between the cells which occurs frequently during prolonged incubation times.

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Post-copulatory sexual selection is associated with sperm aggregate quality inPeromyscusmice

Cited by 4 publications

References 66 publications

Activity pulses induce spontaneous flow reversals in viscoelastic environments

Activity pulses induce spontaneous flow reversals in viscoelastic environments

The social shape of sperm: Using an integrative machine-learning approach to examine sperm ultrastructure and collective motility

Bundle formation of sperm: Influence of environmental factors

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