Effect of osmotic immobilization on refrigerated storage and cryopreservation of sperm from a viviparous fish, the green swordtail Xiphophorus helleri

In this study, refrigerated storage and cryopreservation of sperm from the green swordtail Xiphophorus helleri were investigated. Previous cryopreservation research in this species utilized motile sperm because unlike in most fish species, Xiphophorus sperm can remain continuously motile after collection for a week with refrigerated storage. However, this species reproduces by internal fertilization, and given the significant requirements for motility within the female reproductive tract and potential limitations on sperm energetic capacities, immobilization of sperm prior to insemination could be used to improve fertilization success. Thus, the goal in this study was to use osmotic pressure to inhibit the motility of sperm after collection from X. helleri, and to test the effect of immobilization on refrigerated storage and cryopreservation. The objectives were to: (1) estimate the motility of sperm at different osmotic pressures, and determine an osmotic pressure suitable for immobilization; (2) cryopreserve the immobilized sperm, and estimate the motility after thawing with or without dilution, and (3) compare motility of non-immobilized and immobilized sperm after thawing, centrifugation, and washing to remove cryoprotectant. Motility was determined when sperm were suspended in 11 different osmotic pressures (24-500 mOsmol/kg) of Hanks' balanced salt solution (HBSS). Motility was observed between 116 and 425 mOsmol/kg. Sperm were not motile when the osmolality was lower than 116 or higher than 425 mOsmol/kg. Motility of the immobilized (non-motile) sperm could be activated by changing the osmotic pressure to 291-316 mOsmol/kg, and motility of immobilized sperm from hypertonic HBSS (425 mOsmol/kg) was significantly higher than that from hypotonic HBSS (145 mOsmol/kg) after 48 h of storage. At an osmolality of 500 mOsmol/kg, HBSS was used as extender to maintain immobilized sperm during cryopreservation with glycerol as the cryoprotectant. High motility (approximately 55%) was obtained in sperm after thawing when cryopreserved with 10-15% glycerol, and dilution of thawed sperm in fresh HBSS (1:4; V:V) was found to decrease the motility significantly. No difference was found in the motility of thawed sperm cryopreserved with 14% glycerol and extended in 310 and 500 mOsmol/kg HBSS. Washing by centrifugation prolonged the motility of thawed sperm from 24 to 72 h in HBSS at 310 and 500 mOsmol/kg. This study showed that sperm from X. helleri could be immobilized by use of specific osmotic pressures, and that the immobilization did not affect sperm motility after thawing. The immobilization of sperm by osmotic pressure could minimize reduction of the energetic capacities necessary for insemination, traversal, and residence within the female reproductive tract, and fertilization.     

Relationship between semen characteristics and body size in Barbus barbus L. (Teleostei: Cyprinidae) and effects of ions and osmolality on sperm motility

The objectives of the present study were to determine the relationships among length and weight of males, sperm volume, spermatozoa concentration, total number of spermatozoa, ionic contents and osmolality of seminal plasma in Barbus barbus. The effect of osmolality on sperm motility parameters after activation in NaCl, KCl, or sucrose solutions was also examined. There were significant correlations between spermatozoa concentration – length (R = + 0.7) and – weight (R = + 0.8) of males. No significant correlations were observed between the total number of spermatozoa, sperm volume, and length and weight of males. Seminal plasma osmolality was higher when the total number of spermatozoa (R = + 0.6) and sperm volume (R = + 0.6) were higher. Sperm motility and velocity was positively correlated with osmolality (R = + 0.5). The correlation between sperm motility and K⁺ was negative (R = 0.5), but positively correlated with Ca²⁺ (R = 0.8), Na⁺ (R = 0.8), and Cl⁻ (R = 0.8). There was a rapid decrease (P < 0.05) in sperm motility parameters after sperm activation. Just after sperm activation, beating waves propagated along the full length of flagella. At latter stages post sperm activation, the waves appeared only in proximal part of the flagellum. The highest spermatozoa velocity and percentage of motility were observed at 215–235 mOsmol kg^− 1 in NaCl, KCl or sucrose. The tip of the flagellum became curled into a loop shape which shortened the flagellum after activation of sperm in distilled water. B. barbus sperm is very similar to that of other cyprinids in terms of ionic contents and osmolality of the seminal plasma, mechanism of sperm activation and behavior and motility of sperm during swimming period.     

Relationships between reproductive characteristics in male Vimba vimba L. and the effects of osmolality on sperm motility

In Vimba vimba, GSI, sperm volume, and spermatozoa concentration range from 3.4-7.4 %, 0.1-1.1 ml, and 13.3-34.8 × 10⁹ spz ml⁻¹, respectively. Gonad mass (r = 0.90) and sperm volume (r = 0.35) significantly correlated with weight of males. Significant correlation was also found between gonad mass and length of males (r = 0.85). Sperm motility (r = 0.99) and velocity (r = 098) significantly decreased after activation in Tris-HCl 20 mM, pH 8.5. Osmolality of the seminal plasma was 273.2 mOsmol kg⁻¹. Sperm motility and velocity were significantly affected by the osmolality of the activation medium (P < 0.01). Hyper-osmolality compared to seminal plasma osmolality totally suppressed the sperm activation. At 15 s post-activation, the sperm motility significantly decreased at 240 mOsmol kg⁻¹ in KCl or NaCl media. The highest sperm motility and velocity (at 60 s post-activation) were observed at 200 mOsmol kg⁻¹ in NaCl, KCl, or sucrose media. In all treatments, the tip of the flagellum of spermatozoa became curled into a loop shape after activation of sperm in distilled water containing 20 mM Tris-HCl, pH 8.5 that shortened the flagellum.     

Freeze-thawing as the factor of spontaneous activation of spermatozoa motility in common carp (Cyprinus carpio L.)

In the present study, we investigated the possibility of spontaneous carp spermatozoa activation by freeze-thawing. To evaluate this, the parameters of spermatozoa motility percentage, velocity, ATP content level and fertility rate of sperm were used. The motility and velocity of spermatozoa activated by freeze-thawing were characterized by motile spermatozoa with a median value of 16% and a velocity of 98 μm/s. In addition, the motility and velocity of sperm from the thawed samples were significantly lower than in the control (median value of 100% for sperm motility and 175 μm/s for sperm velocity). Furthermore, a spontaneously activated spermatozoa motility terminated within five minutes post-thaw time. After freeze-thawing the ATP level significantly decreased with post-thaw time (46 nmol ATP/10⁹ and 10 nmol ATP/10⁹ at 25 s and 10 min after thawing, respectively). Fertility of spermatozoa was not significantly affected within 10 min post-thaw. On the other hand, the fertility of frozen-thawed sperm was significantly lower if compared to fresh sperm. We conclude that the freeze-thawing procedure spontaneously activated spermatozoa motility in common carp. However, this activation did not negatively affect the fertility of frozen-thawed sperm.     

Sperm cryopreservation of the critically endangered olive barb (Sarpunti) Puntiussarana (Hamilton, 1822)

The present study focused on development of a sperm cryopreservation protocol for the critically endangered olive barb Puntiussarana (Hamilton, 1822) collected from two stocks within Bangladesh and reared in the Fisheries Field Laboratory, Bangladesh Agricultural University (BAU). The sperm were collected in Alsever’s solution prepared at 296 mOsmol kg⁻¹. Sperm were activated with distilled water (24 mOsmol kg⁻¹) to characterize motility. Maximum motility (90%) was observed within 15 s after activation, and sperm remained motile for 35 s. Sperm activation was evaluated in different osmolalities and motility was completely inhibited when osmolality of the extender was ?287 mOsmol kg⁻¹. To evaluate cryoprotectant toxicity, sperm were equilibrated with 5%, 10% and 15% each of dimethyl sulfoxide (DMSO) and methanol. Sperm motility was noticeably reduced within 10 min, when sperm were equilibrated with 15% DMSO, indicating acute toxicity to spermatozoa and therefore this concentration was excluded in further trials. Sperm were cryopreserved using DMSO at concentrations of 5% and 10% and methanol at 5%, 10% and 15%. The one-step freezing protocol (from 5 °C to −80 °C at 10 °C/min) was carried out in a computer-controlled freezer (FREEZE CONTROL® CL-3300; Australia) and 0.25-ml straws containing spermatozoa were stored in liquid nitrogen for 7–15 days at −196 °C. The highest motility in thawed sperm 61 ± 8% (mean ± SD) was obtained with 10% DMSO. The fertilization and hatching rates were 70% and 37% for cryopreserved sperm, and 72% and 62% for fresh sperm. The protocol reported here can be useful for hatchery-scale production of olive barb. The use of cryopreserved sperm can facilitate hatchery operations, and can provide for long-term conservation of genetic resources to contribute in the recovery of critically endangered fish such as the olive barb.     

Sperm motility of the marine teleosts Boops boops, Diplodus sargus, Mullus barbatus and Trachurus mediterraneus

The spermatozoa of Boops boops, Diplodus sargus, Mullus barbatus, and Trachurus mediterraneus were motile in sea water, and in electrolyte solutions (NaCl) and non-electrolyte solutions (glucose) with an osmolality of 600–1000 mosmol kg^?1. Their mean motility rate 10 s after initiation was about 80%, while about 10% of the motile spermatozoa moved non-linearly, 45% linearly, and 45% circularly. The average path swimming velocity was significantly higher in M. barbatus (about 90 μm s^?1) than in the other species (70 μm s^?1). The number of motile spermatozoa decreased to 0% within 50 s after initiation of motility in T. mediterraneus, within 90 s in M. barbatus . In B. boops and D. sargus about 90% of the spermatozoa stopped movement during the first 90 s of the motility period, while the rest remained motile for 2–3 h. Motility of B. boops and D. sargus spermatozoa was reversibly suppressed in the seminal plasma, and in electrolyte and non-electrolyte solutions of 100–200 mosmol kg^?1. The trigger for motility activation was hyperosmolality (700–1000 mosmol kg^?1). Motility of M. barbatus and T. mediterraneus sperm was only partly suppressed in the seminal plasma since freshly collected semen contained about 25–50% locally motile spermatozoa. When sperm was activated immediately after collection with electrolyte and non-electrolyte solutions of 700–1000 mosmol kg^?1 spermatozoa moved progressively. The motility of those spermatozoa which had not yet been motile after collection was completely and reversibly suppressed in M. barbatus at osmolalities of 1200 mosmol kg^?1, and at osmolalities of 100–200 mosmol kg^?1 in T. mediterraneus . Therefore two triggers were necessary for initiation of motility. The nature of the first trigger was uncertain, the second trigger was a switch to hypoosmolality in M. barbatus and to hyperosmolality in T. mediterraneus . The sperm organisation of B. boops, D. sargus, M. barbatus and T. mediterraneus revealed species-specific parameters which could not be related with the sperm motility behaviour.     

Sperm motility characteristics of wild Atlantic salmon (Salmo salar L.) and sea trout (Salmo trutta m. trutta L.) as a basis for milt selection

The aim of the study was to determine the sperm motility parameters in wild Atlantic salmon and sea trout to define criteria important for selection of milt for controlled fertilisation. Parameters for these species were determined in the fish migrating into north‐western rivers of Poland at spawning time. Eight motility parameters percentage of motile sperm (MOT), curvilinear velocity (VCL), average path velocity (VAP), straight line velocity (VSL), linearity (LIN), straightness (STR), amplitude of lateral head displacement (ALH), beat cross frequency (BCF) and motility duration were subjected to computer‐assisted sperm analysis (CASA). Milt of most individuals studied representing both salmon and trout showed spermatozoa density of 12–22 × 10⁹ ml^?1 and a high percentage of motile sperm (>70%). In general, spermatozoa swim progressively with slightly curved trajectories (mean STR = 70%, LIN = 65%) and velocity VCL of 180 μm s^?1 (salmon) and 190 μm s^?1 (trout), at 10 s post‐activation. Such sperm is easily accessible in the wild populations of salmon and sea trout and is recommended for use in reproduction trials. The spermatozoa of sea trout seem to show a greater tendency to follow curvilinear trajectories than those of salmon, both in the beginning and the final phase of motion. In the first phase of motility, the values and time dependencies of the motility parameters were similar in both species. In the end phase of movement differences in LIN and BCF time dependencies were found in the samples representing the two species. In salmon the linearity and beat cross frequency remained stable in this phase, contrary to the patterns in sea trout for which LIN decreased while BCF increased in the end period of movement. Durations of movement were similar in both species (ranges of 20–40 s).     

Fertilization environment of the non-copulating marine sculpin, Hemilepidotus gilberti

To clarify the extracellular environment for external fertilization in the non-copulating marine sculpin Hemilepidotus gilberti, sperm motility was measured in NaCl, KCl, mannitol solutions, seawater, and ovarian fluid. Spermatozoa of H. gilberti actively moved in seminal plasma the moment they were removed from the genital papilla. Spermatozoa showed higher motility in NaCl solution at osmolalities between 300–400 mOsmol kg^-1. In KCl and in mannitol solutions, spermatozoa actively moved at osmolalities between 500 and 800 mOsmol kg^-1, and at osmolality 300 mOsmol kg ^-1, respectively. The ovarian fluid was a transparent and viscous gelatinous material, rich in sodium with an osmolality of 340 mOsmol kg^-1. Sperm motility in the ovarian fluid lasted more than 90 min, which was six times longer than in seawater. This sperm motility under conditions isotonic to body fluid is similar to that of copulating marine sculpins rather than to other non-copulating marine fishes. In addition, eggs of H. gilberti could be fertilized in the ovarian fluid. This suggests that external fertilization takes place under physiological conditions similar to the internal conditions of the ovary provided by the ovarian fluid, which isolates the eggs from sea water for several hours after spawning. This manner of fertilization is thought to be one of the evolutionary pre-adaptations allowing copulation among marine sculpins.     

Dynamics of ATP and movement in Eurasian perch (Perca fluviatilis L.) sperm in conditions of decreasing osmolality

Repetitive activation of perch (Perca fluviatilis L.) sperm motility was investigated in this study. The first phase of sperm motility activation was initiated by dilution in a 260 mM glucose solution (75% motility). The second phase of motility was achieved by adding water to previously activated sperm, so that the glucose concentration dropped to 220 mM (24% motility). Finally, the third phase was obtained by further addition of water (down to 90 mM glucose) to the activated sperm suspension (15% motility). Parallel measurements of sperm ATP content were also made. The median value for nonactivated sperm was 43.9 nmol ATP/10⁹ spermatozoa. The ATP concentration decreased significantly from 35 to 7 nmol ATP/10⁹ spermatozoa after successive activations of motility in the above glucose solutions. Sperm velocity ranged in value from 25 to 330 μm/sec at 10 sec postactivation, from 10 to 290 μm/sec at 30 sec, and from 0 to 200 μm/sec at 45 sec. A model postulating several classes in the population of spermatozoa is developed, tentatively accounting for such successive activation. Possible further application of multiple sperm activation is discussed.     

Urinary bladder, ionic composition of seminal fluid and urine with characterization of sperm motility in tench (Tinca tinca L.)

A small urinary bladder attached to the seminal duct in caudal part of the abdominal cavity was registered for the first time in dissected males of tench. The urinary bladder wall was of whitish color and the bladder contained 0.5–2 ml of urine. When collected in the experiment, the tench sperm was white‐colored. Spermatozoa density is highly variable due to contamination by urine, and the latter additionally activates spontaneous motility of the spermatozoa. Seminal fluid contains ions such as Na⁺ (18.4 ± 1.3 mm ), K⁺ (1.9 ± 0.6 mm ), Ca²⁺ (0.6 ± 0.2 mm ) and Mg²⁺ (0.5 ± 0.1 mm ), leading to osmolality of 230 ± 82 mOsmol kg^?1 depending on the dilution by urine. Urea was detected in urine samples uncontaminated by sperm with an osmolality of 85 ± 58 mOsmol kg^?1. Urine also contained high concentrations of ions such as Na⁺ (30.9 ± 8.9 mm ), K⁺ (4.3 ± 2.9 mm ), Ca²⁺ (0.9 ± 0.5 mm ) and Mg²⁺ (0.6 ± 0.2 mm ). The spontaneous sperm activation by urine was up to 100%, but could be prevented by collection in an immobilizing solution. Motility was observed for 90–100% spermatozoa just after their transfer to distilled water or in a swimming medium (SM, 30–45 mm KCl) with a velocity of 120–140 μm s^?1. A flagellar beat frequency of 60–70 Hz and forward motility lasted up to 80 s in distilled water, and up to 180 s in SM at room temperature.     

Effects of osmolality on sperm morphology, motility and flagellar wave parameters in Northern pike (Esox lucius L.)

Northern pike (Esox lucius L.) spermatozoa are uniflagellated cells differentiated into a head without acrosome, a midpiece and a flagellar tail region flanked by a fin structure. Total, flagellar, head and midpiece lengths of spermatozoa were measured and show mean values of 34.5, 32.0, 1.32, 1.17 μm, respectively, with anterior and posterior widths of the midpiece measuring 0.8 and 0.6 μm, respectively. The osmolality of seminal plasma ranged from 228 to 350 mOsmol kg⁻¹ (average: 283.88 ± 33.05). After triggering of sperm motility in very low osmolality medium (distilled water), blebs appeared along the flagellum. At later periods in the motility phase, the tip of the flagellum became curled into a loop shape which resulted in a shortening of the flagellum and a restriction of wave development to the proximal part (close to head). Spermatozoa velocity and percentage of motile spermatozoa decreased rapidly as a function of time postactivation and depended on the osmolality of activation media (P < 0.05). In general, the greatest percentage of motile spermatozoa and highest spermatozoa velocity were observed between 125 and 235 mOsmol kg⁻¹. Osmolality above 375 mOsmol kg⁻¹ inhibited the motility of spermatozoa. After triggering of sperm motility in activation media, beating waves propagated along the full length of flagella, while waves appeared dampened during later periods in the motility phase, and were absent at the end of the motility phase. By increasing osmolality, the velocity of spermatozoa reached the highest value while wave length, amplitude, number of waves and curvatures also were at their highest values. This study showed that sperm morphology can be used for fish classification. Sperm morphology, in particular, the flagellar part showed several changes during activation in distilled water. Sperm motility of pike is inhibited due to high osmolality in the seminal plasma. Osmolality of activation medium affects the percentage of motile sperm and spermatozoa velocity due to changes in flagellar wave parameters.     

Comparison of sperm velocity, motility and fertilizing ability between firstly and secondly activated spermatozoa of common carp (Cyprinus carpio)

The objective of the study was to compare carp sperm motility performances (sperm velocity and motility rates) from 10 males including fertilizing ability (hatching rates from 10 males and eight females) as a function of time elapsed after sperm exposure to activation medium in two situations: firstly activated sperm and sperm which had terminated swimming and was ‘re‐activated’ after incubation in a K⁺ rich (200 mm KCl) non‐swimming solution. In case of both initial (first) and secondly activated spermatozoa, the motility was triggered in hatchery solution (HAS, 11.2 mOsmol) and in carp activation solution (CAS, 128.9 mOsmol) containing 45 mm NaCl, 5 mm KCl, 30 mm Tris–HCl while also adjusted to a pH of 8.0. First time activated sperm showed significantly higher relative motility, sperm velocity and fertilizing ability compared to re‐activated sperm. The carp spermatozoa (in either first or second activation) rapidly lost their fertilizing ability as a function of exposure time of sperm to diluents prior to addition to eggs: this shows that spermatozoa must be in contact with eggs as soon as their motility is triggered. When sperm was firstly activated in CAS and also activated a second time in CAS (labeled CASCAS) the hatching rate was significantly higher at egg contact after 10, 20, 30, and 120 s of activation. Also at 20 s after the second activation of the sperm higher sperm motility was observed compared to the first activation. This study showed that incubation of spermatozoa in a K⁺‐rich incubation medium can mitigate the affects of structural damages occurring in re‐activated sperm, which may help spermatozoa to increase their motility and fertilization. To our knowledge, the results presented in this study document for the first time that fertilization can be achieved with sperm re‐activated a second time while being exposed to a incubation medium that permits ATP reloading within the flagellum. Previous studies have show the potential for recovery of motility, however, the effect on possible fertilization is hitherto unknown. It critical outcome of the study clearly indicated the need for avoiding the use of different, subsequent activation media (e.g. first and second activation) but only on the same medium for both steps (see above CASCAS).     

Combined effects of physicochemical variables (pH and salinity) on sperm motility: characterization of sperm motility in European sea bass Dicentrarchus labrax

Gamete activation in fish is an important step in terms of artificial fertilization of oocytes, cryopreservation studies and other experimental manipulations. Salinity and pH differences in activation media affect to sperm motility and fertilizing ability. These experiments were therefore designed to investigate the combined effects of pH (range 5.0–9.0) and salinity (20, 30, 37, and 45‰) of activation media on sperm motility of European sea bass Dicentrarchus labrax. The best results were obtained at salinity 37‰ and a pH of 9.0. Our results also demonstrated that non-progressive motility at salinity 45‰ was observed in the range of 5.0–9.0 pH. In conclusion, spermatozoa can be motile at a wide range of pH and salinity values although the percent of motile spermatozoa and motility duration are negatively affected by low pH values.     

Characterization of zebra mussel (Dreissena polymorpha) sperm motility: duration of movement, effects of cations, pH and gossypol

We have examined effects of time after activation, pH, sodium and potassium, and gossypol concentrations on sperm motility of zebra mussel (Dreissena polymorpha). Zebra mussel spermatozoa appeared to have remarkable viability in the fresh water in comparison with freshwater fish sperm. Duration of sperm motility in fresh water is possibly one of the longest among freshwater animals, since it was not significantly changed 3 h after incubation at room temperature (20 °C) or 24 h of incubation at ±0 °C. High osmotic pressure suppresses sperm motility and effects of sodium and potassium are similar. Spermatozoa were inactive at acid pH and became gradually motile when exposed to pH 6.0–9.0. Gossypol appeared to be a very potent spermicidal agent and inhibited motility. This compound also inhibited fertilization. We observed some differences in gossypol effects on spermatozoa between North American and European zebra mussels. These data on zebra mussel sperm biology may be useful for better handling of gametes under laboratory conditions.     

Motility activation and metabolism characteristics of spermatozoa of the black-lip-pearl oyster Pinctada margaritifera var: cumingii (Jameson, 1901)

Motility of Pinctada margaritifera (Linnaeus, 1758); var: cumingii (Jameson, 1901) (P. margaritifera) spermatozoa collected from gonads are not immediately activated at spawning in seawater (SW) but motility occurs when spermatozoa are transferred into alkaline seawater (pH ranging from 9.0 to 11.4). This motility-activating effect of alkaline pH is reversed when pH is shifted back to more acidic values. In both cases, activity of sperm (% motile cells) increases gradually after alkaline pH activation then lasts for several minutes. The characteristics of these fully motile spermatozoa are described in details at the level of flagella: the wave amplitude and wave-length range 5 to 6 μm and 15 μm respectively, while the flagellar beat frequency is approximately 49 Hz. The velocity of sperm displacement is from 220 to 230 μm/sec. The general swimming pattern is almost circular: the head trajectories describe portions of circles intercalated with small linear segments. Spermatozoa saved in natural seawater at 4°C retain potent motility for several days and can be subsequently activated by alkaline seawater. Respiration and ATP concentration were measured in 3 conditions: regular seawater (pH 7.8), artificial diluent (pH 8.2), and alkaline Tris-buffered seawater (pH 10.5). Results show that sperm respiration rates are higher whereas ATP levels are lower in the latter two media.     

Effects of osmolality and ions on the motility of stripped and testicular sperm of freshwater-and seawater-acclimated tilapia, Oreochromis mossambicus

A significantly higher concentration of testicular spermatozoa was obtained from freshwater Oreochromis mossambicus (9·9×10⁹ spermatozoa ml⁻¹) than seawater O. mossambicus (4·6×10⁹ spermatozoa ml⁻¹). The mean osmolality of the urine of freshwater fish (78·5 mOsmol kg⁻¹) was significantly different from that of seawater fish (304·8 mOsmol kg⁻¹). The mean length of the mid-piece of the spermatozoa together with the tail was more variable in freshwater O. mossambicus (8·80±0·23μm) than in seawater specimens (8·27±0·18 μm). Stripped sperm of freshwater O. mossambicus was highly contaminated by urine which was a good activator of sperm motility in O. mossambicus held in both fresh and sea water. The osmolality for initiation of motility in freshwater O. mossambicus spermatozoa was from 0 to 333 mOsmol kg⁻¹ while for seawater O. mossambicus spermatozoa it was from 0 to 1022 mOsmol kg⁻¹. The optimum osmolality for motility was from 70 to 333 mOsmol kg⁻¹ for freshwater O. mossambicus spermatozoa and from 333 to 645 mOsmol kg⁻¹ for seawater fish. In freshwater O. mossambicus spermatozoa, the presence of 20 mM CaCl₂ increased the permissive osmolality of NaCl from 184 to 645 mOsmol kg⁻¹. For seawater O. mossambicus spermatozoa, solutions of NaCl devoid of CaCl₂ were unable initiate motility, but the addition of 1·5 to 30 mM CaCl₂ to the NaCl solution (0–934 mOsmol kg₁) had a full motility initiating effect.     

Influence of osmolality and ions on the activation and characteristics of zebrafish sperm motility

Despite the prevalence of zebrafish as a model scientific organism, understanding sperm function in this species is essentially limited to observations that osmotic shock initiates motility. During natural spawning, sperm encounter a range of environmental salinities as well as freshwater mixed with egg-associated ovarian fluid (OF), thus sperm are likely to be exposed to saline prior to egg contact. Effects of saline on sperm function in this model species are unknown, but likely to be important. Using computer assisted sperm analysis, this study addressed the effects of osmolality of spawning media and ionic composition and pH on the proportion of sperm becoming motile at activation (motility), as well as sperm velocity and path. When activated with tap water, motility was maximal (80%) at 10 s (earliest time measured), declining to 5% by 87 s postactivation. With activation at moderate osmolalities (∼160-200 mmol/kg) initial motility was decreased relative to low osmolality, increased from 10 to 30 s, and subsequently declined less rapidly (motility in 80 mM NaCl was 35%, 80%, and 60% at 10, 30 and 147 s, respectively). Thus, moderate osmolality increased duration, but introduced a temporal lag in motility onset. With moderate osmolalities, the rate of velocity decay was less than that with tap water activation. Sodium chloride and sucrose similarly impacted both motility and velocity. Replacement of NaCl with KCl, pH values ranging from 6.8 to 8.4, or the presence of gadolinium were without effect. Motility, but not velocity, was slightly supressed by Ca²⁺. Therefore, whereas pH and concentrations of Ca²⁺ or K⁺ of OF are unlikely to impact fertility via sperm motility, the OF contribution to spawning media osmolality may have pronounced effects on motility and velocity of sperm, factors previously correlated with fertility in other species.     

Ionic factors affecting motility,respiration and fertilization rate of the sperm of the bivalvePecten maximus (L.)

Fertilization of the scallopPecten maximus occurs after gametes were naturally released in sea water by the bivalve which has undergone stimulation. The motility of the spermatozoa requires their dilution in sea water (1/40). Dilution triggers an immediate increase of oxygen consumption by sperm, reflecting an activation of a cyanide-sensitive respiration of a cellular origin. When scallops were stimulated by thermal shocks or by serotonin injection, sperm sampled at the urogenital pore output duct shows a respiration-motility activation after sea water dilution which is not seen in sperm scarified from the gonad. Dilution of kidney-sampled sperm into acidic (pH 5) or Na⁺-free artificial sea water reversibly inhibits both respiration and motility. In all cases fertilization rate of sperm is correlated to the increase of respiratory rate and motility measured after dilution in different media. Whether the scallop was stimulated or not, the pH of haemolymph and pericardic fluids were one pH unit below the value of sea water, the pH of the gonad and of the kidney tissues being more acidic (6.5 in average). Our results suggest that the acidic pH of the genital tract maintains the spermatozoa in a quiescent state and that capacitation occurs when male gametes move from the gonad to the kidney from where it is naturally released.Abbreviations ASW artificial sea water - SW sea water - TRIS trishydroxymethyl-aminomethane     

Measurement of the sperm motility index via the sperm quality analyzer and its relationship to other qualitative sperm parameters

Sperm parameters such as the concentration and percentage of motile spermatozoa are commonly used to assess semen quality. The sperm quality analyzer (SQA) is a device that detects variations in the optical density of motile spermatozoa, providing a sperm motility index (SMI) that is based on various sperm parameters including the concentration, morphology and acrosomal status of motile spermatozoa. The relationship between SMI values of frozen-thawed bovine spermatozoa undergoing swelling in a hypoosmotic medium (100 mOsm/L) and other sperm parameters were evaluated. Frozen semen specimens from 3 bulls were thawed and washed with Ham's F-10 supplemented with 3% BSA and split into 3 (0.2 mL) aliquots. The aliquots were diluted with 1.0 mL of Ham's F-10 (Aliquot 1), isotonic sodium citrate (Aliquot 2), and hypotonic sodium citrate (Aliquot 3). The osmotic pressure of the media used for dilution of Aliquots 1 and 2 was 300 mOsm/L, while that for Aliquot 3 was 100 mOsm/L. Following dilution, the aliquots were incubated for 30 min and manually assessed at 5-min intervals for the percentage and grade of motility (Grades 0 to 4) as well as for the percentage of swollen spermatozoa. Sperm samples were simultaneously evaluated by SQA to obtain the SMI values at the same 5-min intervals during the 30-min incubation. Significant correlations were observed between SMI values and other sperm parameters in Aliquot 3 (P < 0.05). The results indicated that the SMI values obtained from frozen-thawed bovine spermatozoa exposed to a 100 mOsm/L diluent, which causes optimal swelling of spermatozoa, are highly correlated to other sperm parameters. The SQA unit, as applied in this study, can be used for rapid and reliable screening of sperm samples.     

Sperm quality evaluation in Solea senegalensis during the reproductive season at cellular level

Sperm quality seems to be one of the reasons for the reproduction constraints faced by Senegalese sole (Solea senegalensis) aquaculturists. Previous studies in this species indicated that the sperm quality of individuals kept in culture varies throughout the year and that different sperm subpopulations can be identified in ejaculates according to the motility pattern of spermatozoa. Aiming to better understand factors affecting sole sperm quality in captivity, sperm of 11 males was assessed during the reproductive season using different parameters: motility characteristics using CASA analysis; cell plasma membrane resistance to seawater hyperosmolarity; DNA fragmentation with single-cell gel electrophoresis; and early apoptosis, labeled with Annexin-V FITC. Computer-assisted sperm analyses motility data were treated using multivariate analysis to identify the presence of different spermatozoa subpopulations according to their motility pattern. Four distinct sperm subpopulations were obtained: Subpop1, which includes fast linear spermatozoa; Subpop2, made up of fast nonlinear spermatozoa; Subpop3, which includes slow linear spermatozoa; and Subpop4, which contains slow nonlinear spermatozoa. The sperm subpopulation structure varied with time after activation and with male. Low cell resistance to the seawater hyperosmotic conditions was noticed. The Annexin-V assay allowed the identification of an apoptotic population ranging from 6% to 20%. A high percentage of cells (64.1%) showed a DNA fragmentation level below 30%, but these values varied significantly between males. DNA fragmentation appears to be related to cell membrane resistance to hyperosmotic conditions faced by the cells when in contact with seawater. This condition seems to modulate the composition of the motile sperm population and performance after activation. This phenomenon could be related to the spermatozoa maturation process.