2018
DOI: 10.1098/rsif.2018.0702
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Cellular geometry controls the efficiency of motile sperm aggregates

Abstract: Sperm that swim collectively to the fertilization site have been observed across several vertebrate and invertebrate species, with groups ranging in size from sperm pairs to massive aggregates containing hundreds of cells. Although the molecular mechanisms that regulate sperm–sperm adhesion are still unclear, aggregation can enhance sperm motility and thus offer a fertilization advantage. Here, we report a thorough computational investigation on the role of cellular geometry in the performance of sperm… Show more

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Cited by 18 publications
(36 citation statements)
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“…Using an integrative methodical and analytical approach that combines traditional morphometry and machine learning, we characterized sperm head shape variation and investigated its role in collective motility in the Peromyscus lineage. Our results support the theoretical predictions that sperm with a smaller head aspect ratio (i.e., relatively wider head), are more likely to aggregate and to form larger aggregates when they do [34,36]. Moreover, we find that variation in sperm head dimensions across these captive species is consistent with previously recorded morphological diversity observed from museum samples [35], supporting the use of high-throughput morphometric methods.…”
Section: Discussionsupporting
confidence: 90%
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“…Using an integrative methodical and analytical approach that combines traditional morphometry and machine learning, we characterized sperm head shape variation and investigated its role in collective motility in the Peromyscus lineage. Our results support the theoretical predictions that sperm with a smaller head aspect ratio (i.e., relatively wider head), are more likely to aggregate and to form larger aggregates when they do [34,36]. Moreover, we find that variation in sperm head dimensions across these captive species is consistent with previously recorded morphological diversity observed from museum samples [35], supporting the use of high-throughput morphometric methods.…”
Section: Discussionsupporting
confidence: 90%
“…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: 61%
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“…Improving our understanding of which benefits underlie sociality among extant species will allow us to test whether some benefits tend to drive the evolution of sociality, with other benefits accruing secondarily. In addition, this framework could be applied at the sub-organismal level, potentially explaining the group sizes of cellular aggregations such as sperm cells 144, 145 , erythrocytes and platelets 146–148 , and some immune cells 149151 . Taking a high-level view of sociality across the tree of life, while abstracting away many of the finer details, may therefore be a powerful approach towards a deeper understanding of one of the major evolutionary transitions.…”
Section: Discussionmentioning
confidence: 99%