Three-dimensional motion of avian spermatozoa

Observations have been made on spermatozoa from the domestic fowl, quail and pigeon (non-passerine birds) and also from the starling and zebra finch (passerine birds). In free motion, all these spermatozoa roll (spin) continuously about the progression axis, whether or not they are close to a plane surface. Furthermore, the direction of roll is consistently clockwise (as seen from ahead). The flagellar wave has been shown to be helical and dextral (as predicted) for domestic fowl sperm when they swim rapidly in low viscosity salines. Calculations have shown that their forward velocity is consistent with their induced angular velocity but that the size of the sperm head is suboptimal for progression speed under these conditions. Dextrally helical waves also occur on the distal flagellum of fowl, quail and pigeon sperm in high viscosity solutions. But in other cases, the mechanism of torque-generation is more problematical. The problem is most profound for passerine sperm, in that typically these cells spin rapidly while seeming to remain virtually straight. Because there is no evidence for a helical wave on these flagella, we have considered other possible means whereby rotation about the local flagellar axis (self-spin) might be achieved. Sometimes, passerine sperm, while maintaining their spinning motion, adopt a fixed curvature; this must be an instance of bend-transfer circumferentially around the axonemal cylinder-though the mechanism is obscure. It is suggested that the self-spin phenomenon may be occurring in non-passerine sperm that in some circumstances spin persistently, yet without expressing regular helical waves. More complex waves are apparent in non-passerine sperm swimming in high viscosity solutions: added to the small scale bends is a large scale, sinistrally helical curvature of the flagellum. It is argued that the flagellum follows this sinistrally helical path (i.e. "screws" though the fluid) because of the shape of the sperm head and the angle at which the flagellum is inserted into it. These conclusions concerning avian sperm motility are thought to have relevance to other animal groups. Also reported are relevant aspects of flagellar ultrastructure for pigeon and starling sperm.     

Freezing of stored, chilled dog spermatozoa

The aims of this study were to find out if dog spermatozoa can be stored chilled for 1 or 2 days prior to freezing without a deterioration in post-thaw vitality and longevity, and to compare two extenders; the Uppsala Equex-2 (UE-2) and a TRIS egg yolk extender (EYT). Pooled dog semen was frozen immediately after collection, or was extended and stored at 4 degrees C for 1 or 2 days before freezing. Sperm motility and acrosome integrity were evaluated before freezing and for 6h post thaw at 38 degrees C, while sperm plasma membrane integrity was evaluated post thaw. There were no effects of pre-freeze storage time or extender on post-thaw motility or plasma membrane integrity, but a significant effect of extender (P < 0.0153) on post-thaw acrosomal integrity was found, UE-2 being better than EYT. There was a significant (P < 0.0001) negative effect of post-thaw storage time on acrosome integrity, but this was not influenced by pre-freeze storage time or extender. In conclusion, we found that dog spermatozoa can be frozen after 1 or 2 days of cold storage without significant deterioration in post-thaw motility, acrosome integrity or sperm plasma membrane integrity compared to when frozen immediately after collection. The UE-2 extender was superior to the EYT extender for freezing of cold stored dog spermatozoa.     

Freezing tolerance in embryos and spermatozoa of the sea urchin

Late embryos of the sea urchin survive freezing, at least for a short period of time, at ?196 °C in the presence of a cryoprotectant. The freezing tolerance in glycolated embryos is greater in advanced developmental stages. High rates of both cooling and warming during a freezethaw sequence were more dangerous in one-cell embryos than in late ones. Both ethylene glycol and DMSO exerted a significant protection against freezing injury on embryos in all the stages after fertilization, but not on unfertilized egg cells. Cryopreservation of sea urchin sperm at ?196 °C in the presence of 1.5 m ethylene glycol has been achieved for 3 days. The fertilizability of eggs inseminated by frozen-thawed sperm was more than two-thirds. Nearly all the eggs thus fertilized developed to normal gastrulae.     

Temperature-dependent inhibition of motility in spermatozoa from different avian species

This study demonstrates that the pattern of temperature-dependent inhibition of chicken sperm motility at 40 degrees C in vitro, and its release by calcium, is also found in drake spermatozoa and, partially, in turkey spermatozoa. However, no such temperature-dependent inhibition was found in spermatozoa from Japanese quail and Houbara bustard, for which physiological levels of calcium at 40 degrees C had an inhibitory and no effect on sperm motility, respectively. Thus, on the basis of this evidence on the regulation of avian sperm motility in vitro, the hypothesis that oviducal sperm storage tubules might immobilise spermatozoa by providing a calcium-free environment in vivo does not appear to be universally applicable to all species of birds.     

Freezing of epididymal spermatozoa from dogs after cool storage for 2 or 4 days

An experiment was conducted to investigate the freezing ability of canine epididymal spermatozoa after cool storage at 5 degrees C for 2 or 4 days. Spermatozoa were collected from the caudae epididymidis from 16 dogs. Total motility, plasma membrane integrity and acrosome integrity were evaluated immediately on harvesting, and after 2 and 4 days of storage at 5 degrees C, and at 0 and 2 h post-thaw at 37 degrees C. Sperm motility decreased significantly during cold storage, compared to freshly harvested spermatozoa (P < 0.001). Although there was no significant effect of pre-freeze storage time on post-thaw motility, there was a tendency towards decreased motility in spermatozoa that had been stored for 4 days, compared to spermatozoa that were frozen immediately after collection (P = 0.09). The number of post-thaw spermatozoa with an intact plasma membrane was decreased in spermatozoa cold-stored for 4 days (P < 0.001). There was no significant effect of pre-freeze storage time on the acrosomal status of post-thaw spermatozoa. In conclusion, canine epididymal spermatozoa were stored at 5 degrees C for up to 4 days without a clear detrimental effect on post-thaw motility and acrosome integrity, but storage may have decreased post-thaw motility. Results were, however, generally low.     

Roles of antioxidants on prolonged storage of avian spermatozoa in vivo and in vitro

This review focuses on natural and assisted prevention against lipid peroxidation in avian spermatozoa. The presence of high levels of n-6 polyunsaturated fatty acids (PUFAs) in the plasma membrane creates favorable conditions for the formation of peroxidative products, a major cause of membrane damage which may ultimately impair male fertility. However, a complex antioxidant system involving vitamin C, vitamin E and GSH is naturally present in avian semen. Coupled with a battery of enzymatic defenses (e.g., SOD, GSH-Px either Se- or non-Se-dependent), this system acts to prevent or restrict the formation and propagation of peroxides. The presence of specialized sites dedicated to prolonged sperm storage in avian females raises the question of durable protection of sperm membranes against peroxidation. Preliminary observations have revealed the presence of a specific antioxidant system at these sites in which vitamin C could exert a major role. From a practical standpoint, the extensive use of artificial insemination in poultry, along with the emergence in some species of workable techniques to cryopreserve spermatozoa, demand better control of peroxidation occurring in the plasma membrane of spermatozoa before or during storage. Dietary supplementation with vitamin E is effective in limiting lipid peroxidation of sperm plasma membranes, both in chickens and turkeys. In addition, organic Se with or without vitamin E stimulates Se-GSH-Px activity in seminal plasma. Preliminary observations in female chickens have also revealed the effectiveness of dietary supplementation with vitamin E, organic selenium or both to sustain fertility in aging flocks.     

Comparative cryopreservation of avian spermatozoa: benefits of non-permeating osmoprotectants and ATP on turkey and crane sperm cryosurvival

A comparative approach was used to evaluate the cryosurvival of turkey and crane sperm frozen in a dimethylacetamide (DMA) cryodiluent supplemented with osmoprotectants and ATP. A range (6-26%) of DMA concentrations was used alone or in combination with ATP (30, 60 or 118mM) or one of the following osmoprotectants: (1) sucrose (turkey, 8.0%; crane, 5.0%); (2) 5.0% sucrose and 5.0% trehalose; or (3) betaine hydrochloride (0.1, 0.2 or 0.4mM). The viability of thawed sperm was assessed using the nigrosin-eosin stain and sperm motility was determined using the hanging-drop technique. For semen frozen only with DMA, post-thaw sperm motility was greatest (P<0.05) for the 6.0%, 10.0% and 18% concentrations, regardless of species. Turkey sperm frozen with the sucrose/trehalose combination had greater (P<0.05) post-thaw motility for all DMA treatments compared to DMA alone. The lowest concentration of the osmoprotectant betaine hydrochloride substantially improved turkey sperm viability post-thaw in all treatments compared to DMA alone (P<0.05). The post-thaw motility of crane sperm was improved (P<0.05) with a combination of 18.0%, 24.0% or 26.0% DMA and 30mM ATP. Moreover, in the presence of osmoprotectants, crane sperm motility decreased as the osmoprotectant concentration increased. The lowest concentration of ATP also improved crane sperm viability post-thaw, especially for DMA concentrations 18% or greater. The combination of sucrose and trehalose improved (P<0.05) crane sperm viability only with 6% and 10% DMA. These data affirm that there are avian-specific differences in sperm survival after cryopreservation and suggest that post-thaw survival can be enhanced by including species-based osmoprotectant/ATP combinations in a cryodiluent where DMA is the cryoprotectant.     

Comparative cryopreservation of avian spermatozoa: effects of freezing and thawing rates on turkey and sandhill crane sperm cryosurvival

In beef cows, reduced energy intake delays first ovulation postpartum and is associated with lesser insulin, IGF-I and leptin concentrations. However, the close relationship among these hormones mask their individual roles in the reinitiation of ovarian activity. A β-adrenergic receptor agonist (βAR) was used to increase body condition score (BCS) and yet reduce body fat and leptin serum concentration to determine the specific role of leptin in the postpartum ovarian activity. Beef cows (n=77) with BCS 3.1 ± 1.4 received 2 kg/day of feed containing 0 or 0.15 mg/kg of zilpaterol (a synthethic βAR), for 33 days. Estrus was induced with a progestin implant applied for 9 d and cows in estrus were bred by artificial insemination (AI). Zilpaterol administration increased (P<0.05) daily weight gain, muscle depth and BCS, with no changes in back fat depth, reducing fat to muscle ratio (P<0.05). At the time of AI, insulin (38%) and IGF-I (26%) concentrations were less in zilpaterol-treated cows (P<0.05), but leptin concentration was unaffected. Ovulation rate and animal with luteal activity after estrus induction were also reduced by 35% (P=0.05) and 56.5% (P=0.007), respectively, in zilpaterol-treated cows. Logistic regression estimates for BCS (P=0.016) and IGF-I concentration (P=0.03) were positively related with the occurrence of luteal activity. In addition, whilst back fat (P=0.009) had a positive effect on luteal activity, leptin concentration did not show a significant relationship. In conclusion, despite an increase in body weight and a positive change in BCS, the reduction in insulin and IGF-I concentrations, associated with βAR treatment, reduced the response to induction of estrus. However only IGF-I, but not leptin or insulin, significantly influenced the odds for the occurrence of luteal activity after estrous induction in cattle with poor BCS.     

Detection of lipid peroxidation in frozen-thawed avian spermatozoa using C(11)-BODIPY(581/591)

The aim of this study was to perform flow cytometric analysis of C11-BODIPY581/591 oxidation in fowl and geese sperm as a marker for membrane lipid peroxidation (LPO) and to establish if the cryopreservation process would make sperm membranes more susceptible to oxidative stress. The experiment was carried out on 10 meat type line Flex roosters and 10 White Koluda® geese. The semen was collected two times a week, by dorso-abdominal massage method and pooled from 10 individuals of each species. Fowl semen samples were subjected to cryopreservation using the “pellet” method and Dimethylacetamide (DMA) as a cryoprotectant. Geese semen samples were cryopreserved in plastic straws in a programmable freezing unit with Dimethyloformamide (DMF) as the cryoprotectant. A fluorescent lipid probe C11-BODIPY581/591 provided with two double bonds that are oxidized during their contact with ROS, was used for the purpose of the assessment of the LPO in freshly diluted semen samples and frozen-thawed semen samples. This probe changes its color according to its state (non peroxidized: red; peroxidized: green). Flow cytometric analysis was used to monitor these changes. The White Koluda® geese fresh semen had a higher level of LPO than the Flex fresh semen (P > 0.01). The cryopreservation of fowl semen significantly (P > 0.01) increased the percentage of live and dead spermatozoa with lipid peroxidation. In frozen-thawed semen of White Koluda® geese the percentage of live spermatozoa with LPO significantly decreased (P > 0.05) whereas significantly (P > 0.01) higher level of dead cells with LPO was observed. There were significant differences between the two studied species. After thawing, the percentage of live and dead spermatozoa with lipid peroxidation was higher in fowl semen than in geese semen (P > 0.01). In conclusion, our data clearly indicate the existence of species specific differences in susceptibility of spermatozoa to the oxidation of PUFAs in the cell membranes, where such oxidation is caused by cryopreservation. This study shows that avian spermatozoa are vulnerable to radicals and frozenthawed sperm have higher level of LPO than fresh sperm. According to our observation, fowl semen is more susceptible to LPO than geese semen.     

Osmotic tolerance of avian spermatozoa: influence of time, temperature, cryoprotectant and membrane ion pump function on sperm viability

Potential factors influencing sperm survival under hypertonic conditions were evaluated in the Sandhill crane (Grus canadensis) and turkey (Meleagridis gallopavo). Sperm osmotolerance (300-3000 mOsm/kg) was evaluated after: (1) equilibration times of 2, 10, 45 and 60 min at 4 °C versus 21 °C; (2) pre-equilibrating with dimethylacetamide (DMA) or dimethylsulfoxide (Me₂SO) at either 4 °C or 21 °C; and (3) inhibition of the Na⁺/K⁺ and the Na⁺/H⁺ antiporter membrane ionic pumps. Sperm viability was assessed using the eosin-nigrosin live/dead stain. Species-specific differences occurred in response to hypertonic conditions with crane sperm remaining viable under extreme hypertonicity (3000 mOsm/kg), whereas turkey sperm viability was compromised with only slightly hypertonic (500 mOsm/kg) conditions. The timing of spermolysis under hypertonic conditions was also species-specific, with a shorter interval for turkey (2 min) than crane (10 min) sperm. Turkey sperm osmotolerance was slightly improved by lowering the incubation temperature from 21 to 4 °C. Pre-equilibrating sperm with DMA reduced the incidence of hypertonic spermolysis only in the crane, at both room and refrigeration temperature. Inhibiting the Na⁺/K⁺ and the Na⁺/H⁺ antiporter membrane ion pumps did not impair resistance of crane and turkey spermatozoa to hypertonic stress; pump inhibition actually increased turkey sperm survival compared to control sperm. Results demonstrate marked species specificity in osmotolerance between crane and turkey sperm, as well as in the way temperature and time of exposure affect sperm survival under hypertonic conditions. Differences are independent of the role of osmotic pumps in these species.     

Freezing human ES cells

Here we demonstrate how our lab freezes HuES human embryonic stem cell lines. A healthy, exponentially expanding culture is washed with PBS to remove residual media that could otherwise quench the Trypsin reaction. Warmed 0.05% Trypsin-EDTA is then added to cover the cells, and the plate allowed to incubate for up to 5 mins at room temperature. During this time cells can be observed rounding, and colonies lifting off the plate surface. Gentle repeated pipetting will remove cells and colonies from the plate surface. Trypsinized cells are placed in a standard conical tube containing pre-warmed hES cell media to quench remaining trypsin, and then spun. Cells are resuspended growth media at a concentration of approximately one million cells in one mL of media, a concentration such that one frozen aliquot is sufficient to resurrect a culture on a 10 cm plate. After cells are adequately resuspended, ice cold freezing media is added at equal volume. Cell suspensions are mixed thoroughly, aliquoted into freezing vials, and allowed to slowly freeze to -80 C over 24 hours. Frozen cells can then moved to the vapor phase of liquid nitrogen for long term storage, or remain at -80 for approximately six months.     

Freezing of rat macrophages

The effect of freeze-thawing was studied in cryoprotected (10% dimethyl sulfoxide) rat peritoneal macrophages. Recovery after post-thaw washing was about 50%. Phagocytosis of latex particles seemed unhampered by this procedure, whereas the abilty to adhere to glass and the amount of Fc and C₃ receptors were moderately reduced. Low temperature preservation of macrophages might be a useful storage method, as it is for lymphocytes and tissue culture cells.