Marine fish spermatozoa: racing ephemeral swimmers

Cosson, Jacky; Groison, Anne-Laure; Suquet, Marc; Fauvel, Christian; Dréanno, Catherine; Billard, Roland

doi:10.1530/rep-07-0522

Cited by 145 publications

(170 citation statements)

References 117 publications

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“…During spermatogenesis, sperm cells are prepared for accomplishing their fertilizing task for which they need to fully exploit their swimming ability immediately and as fast as possible in order to encounter the egg. The initial velocity is very high at activation, but motility duration lasts for periods ranging only 40 s to 20 min as an energetic consequence of the high velocity (Cosson et al 2008). As possible to see the fish spermatozoa are much different from mammalian one.…”

Section: Wwwintechopencommentioning

confidence: 99%

“…The fish sperm cells are homogenous; all spermatozoa can be activated at the same time and then swim with very similar characteristics at a certain time point post-activation. In many fish species, the flagellum is 50-60 mm long with a ribbon shape (presence of fins) instead of cylindrical; thus, the flagellum appears brighter by dark-field microscopy, allowing clear visualization of wave shapes (Cosson et al 2008). Just for knowledge, the head of investigated us rainbow trout spermatozoa is ovoid-shaped, measuring about 3 x 1.3 µm in diameter and possess any acrosome.…”

Section: Wwwintechopencommentioning

confidence: 99%

See 1 more Smart Citation

Vitrification Technique - New Possibilities for Male Gamete Low-Temperature Storage

Isachenko¹,

Mallmann²,

Rahimi³

et al. 2012

Current Frontiers in Cryobiology

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Section: Wwwintechopencommentioning

confidence: 99%

Section: Wwwintechopencommentioning

confidence: 99%

Vitrification Technique - New Possibilities for Male Gamete Low-Temperature Storage

Isachenko¹,

Mallmann²,

Rahimi³

et al. 2012

Current Frontiers in Cryobiology

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“…Studies in fish indicated that environmental osmotic changes trigger sperm motility [1,2]. Interestingly, in most mammalian species examined, the sperm journey from the male to female reproductive tract also experiences a natural osmotic decrease [3,4], implicating that an osmotic stress response upon ejaculation is evolutionarily conserved for normal sperm function.…”

Section: Introductionmentioning

confidence: 99%

Aquaporin3 is a sperm water channel essential for postcopulatory sperm osmoadaptation and migration

et al. 2010

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In the journey from the male to female reproductive tract, mammalian sperm experience a natural osmotic decrease (e.g., in mouse, from ~415 mOsm in the cauda epididymis to ~310 mOsm in the uterine cavity). Sperm have evolved to utilize this hypotonic exposure for motility activation, meanwhile efficiently silence the negative impact of hypotonic cell swelling. Previous physiological and pharmacological studies have shown that ion channel-controlled water influx/efflux is actively involved in the process of sperm volume regulation; however, no specific sperm proteins have been found responsible for this rapid osmoadaptation. Here, we report that aquaporin3 (AQP3) is a sperm water channel in mice and humans. Aqp3-deficient sperm show normal motility activation in response to hypotonicity but display increased vulnerability to hypotonic cell swelling, characterized by increased tail bending after entering uterus. The sperm defect is a result of impaired sperm volume regulation and progressive cell swelling in response to physiological hypotonic stress during male-female reproductive tract transition. Time-lapse imaging revealed that the cell volume expansion begins at cytoplasmic droplet, forcing the tail to angulate and form a hairpin-like structure due to mechanical membrane stretch. The tail deformation hampered sperm migration into oviduct, resulting in impaired fertilization and reduced male fertility. These data suggest AQP3 as an essential membrane pathway for sperm regulatory volume decrease (RVD) that balances the "trade-off" between sperm motility and cell swelling upon physiological hypotonicity, thereby optimizing postcopulatory sperm behavior.

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“…Sperm velocity represents a global combination of several parameters such as head dimension (diameter of head), beat frequency, length of flagellum and physical parameters of wave propagation like wave length and amplitude [43], which contributes differentially to energetic exhaustion. Velocities of spermatozoa are greatest immediately after activation [4], for example, in halibut 150-180 μm/s [81,82], in fugu 160 μm/s [83], in cod 65-100 μm/s [84] or 130 μm/s [64], in hake 130 μm/s [64,85], in tuna 215-230 μm/s [86], in turbot 220 μm/s [70,87] and in sea bass 120 μm/s (straight line velocity) [69,88]. High initial velocity leads to shortened total duration of motility, because fish spermatozoa mostly rely on their preaccumulated energy store for operating their propulsive motors [4,9].…”

Section: Evaluation Of Fish Sperm Motility Parametersmentioning

confidence: 99%

“…Sperm migrating in high viscosity fluids commonly exhibits larger numbers of waves though of lower amplitudes [86,107]. Thus, an increase in viscosity by addition of viscous compounds in the swimming medium actually leads to a lowering of propulsive velocity of the sperm [86].…”

Section: +mentioning

confidence: 99%

Biophysics of Fish Sperm Flagellar Movement: Present Knowledge and Original Directions

Prokopchuk¹,

Cosson²

2017

Cytoskeleton - Structure, Dynamics, Function and Disease

Self Cite

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A fish spermatozoon has a minimalist structure: head, mid-piece and flagellum with the active inner core, called "axoneme". The axoneme represents a cylindrical scaffold of microtubular doublets arranged around a pair of single microtubules and assorted along the entire length with the dynein-ATPase motors. The mechanisms of wave generation along the flagellum becomes possible due to sliding of microtubules relative to each other and their propagation is a result of a balance between mechanical constraints and intra-flagellar biochemical actors that generate force.How fish sperm flagella mechanics adapt to external constraints, such as vicinity of surfaces or viscosity, during the very short period of motility? By use of high-speed video microscopy, stroboscopic system, modelisation and simulation approaches, we show that fish sperm flagella respond to physical and chemical signals from environment in a very brief period of time.This review chapter presents a brief description of the biological and biochemical features that characterize fish spermatozoa. Then it describes the biophysical aspects of flagellar movement covering various topics involved in fish sperm motility and offering a compilation of the recent knowledge acquired on different physical properties, such as wave propagation, energetics, hydrodynamics, temperature, viscosity, axonemal microtubules dynamics, among other aspects.

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Marine fish spermatozoa: racing ephemeral swimmers

Cited by 145 publications

References 117 publications

Vitrification Technique - New Possibilities for Male Gamete Low-Temperature Storage

Vitrification Technique - New Possibilities for Male Gamete Low-Temperature Storage

Aquaporin3 is a sperm water channel essential for postcopulatory sperm osmoadaptation and migration

Biophysics of Fish Sperm Flagellar Movement: Present Knowledge and Original Directions

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