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Iron-induced luminescence as a method for assessing lipid peroxidation of frozen–thawed goat spermatozoa

Published online by Cambridge University Press:  01 July 2007

P. Gogol*
Affiliation:
Department of Biotechnology of Animal Reproduction, National Research Institute of Animal Production, Krakowska 1, 32-083 Balice, Poland
A. Wierzchoś-Hilczer
Affiliation:
Department of Biotechnology of Animal Reproduction, National Research Institute of Animal Production, Krakowska 1, 32-083 Balice, Poland
M. Cegła
Affiliation:
Department of Biotechnology of Animal Reproduction, National Research Institute of Animal Production, Krakowska 1, 32-083 Balice, Poland

Abstract

Freezing/thawing procedures induce enhanced reactive oxygen species (ROS) formation in mammalian sperm and these ROS may be a cause for the decrease in sperm function following cryopreservation. In the present study, we used a chemiluminescence method to detect ROS-induced damage in goat spermatozoa. Iron-induced luminescence of fresh and frozen/thawed sperm cells was assessed using a luminometer. It was shown that the freezing/thawing procedure had a significant effect on some luminescence parameters. Semen freezing significantly increased the values of integral, peak max, T.half (rise) and T.max (peak) parameters. A significant correlation was observed between the percentage of motile spermatozoa and integral, peak max and T.half (rise) parameters. In conclusion, the results of the present study indicate that measurement of induced luminescence can be an alternative, sensitive and relatively simple method for assessing the effect of cryopreservation on oxidative damage to spermatozoa.

Type
Full Paper
Copyright
Copyright © The Animal Consortium 2007

Introduction

Freezing and thawing, two major steps in cryopreservation of spermatozoa, have a major effect on cell structure and function (Hammerstedt et al., Reference Hammerstedt, Graham and Nolan1990). The freezing–thawing cycle causes damage to the plasma membrane (Hammerstedt et al., Reference Hammerstedt, Graham and Nolan1990), reduces motility and the fertilising ability of spermatozoa (Hammerstedt, Reference Hammerstedt1993) and induces premature capacitation and nuclear decondensation (Cormier et al., Reference Cormier, Sirard and Beiley1997). Even in the presence of cryoprotectants such as glycerol, egg yolk and milk, significant structural alterations take place. In recent years, antioxidants have been tested in combination with basic common cryoprotectants to minimise the damage caused by freezing and thawing. The beneficial effects of antioxidants provide indirect evidence that an oxidative stress occurs during cryopreservation (Alvarez and Storey, Reference Alvarez and Storey1992; Chen et al., Reference Chen, Foote and Brockett1993; Sanchez-Partida et al., Reference Sanchez-Partida, Setchell and Maxwell1997). This has been confirmed by studies which showed that reactive oxygen species (ROS) are produced during freezing and thawing of bovine (Chatterjee and Gagnon, Reference Chatterjee and Gagnon2001) and equine spermatozoa (Ball et al., Reference Ball, Vo and Baumber2001).

One of the major biological processes associated with ROS is lipid peroxidation. Lipid peroxidation proceeds with the extraction of hydrogen and the formation of a number of reactive intermediates that can result in a chain reaction or propagation of peroxidation within the membrane (Aitken et al., Reference Aitken, Harkiss and Buckingham1993a; Storey, Reference Storey1997). Mammalian sperm cells are particularly sensitive to oxidative damage due to the high level of easily peroxidisable polyunsaturated fatty acids (Jones et al., Reference Jones, Mann and Sherins1979) and fairly low activity of the enzymatic anti-oxidative system. The attack of free radicals on unsaturated fatty acid-rich lipids of sperm cell membranes leads to an irreversible decrease in membrane fluidity (Borst et al., Reference Borst, Visser, Kouptsova and Visser2000), alteration in membrane permeability and metabolism (Jones et al., Reference Jones, Mann and Sherins1979; Ohyashiki et al., Reference Ohyashiki, Ohtsuka and Mohri1988; Ohta et al., Reference Ohta, Mohri and Ohyashiki1989) and reduced sperm ability to penetrate the egg (Aitken et al., Reference Aitken, Harkiss and Buckingham1993b; Kodama et al., Reference Kodama, Kuribayashi and Gagnon1996).

In view of the importance of lipid peroxidation in defective sperm function, quantification of this process is of some diagnostic significance. At present, the most widely used assay for lipid peroxidation involves the measurement of malondialdehyde (MA), a small molecular mass degradation product of peroxidative process that can be measured by virtue of its capacity to form adducts with thiobarbituric acid (Aitken et al., Reference Aitken, Harkiss and Buckingham1993a). Although the method is sensitive and can detect the end-point reaction product of lipid peroxidation, it is relatively elaborate and provides only an indirect measure of lipid peroxidation (Pap et al., Reference Pap, Drummen, Post, Rijken and Wirtz2000). Moreover, MA only accounts for around 5% of the products generated during lipid peroxidation (Marshall et al., Reference Marshall, Warso and Lands1985). Other extremely toxic lipid peroxidation products such as 4-hydroxynonenal, which are known to be present in semen and to have a powerful inhibitory effect on sperm function, are not accounted for in the MA assay (Selley et al., Reference Selley, Lacey, Bartlett, Copeland and Ardlie1991).

Recently, the application of a fluorescent fatty acid probe, C11-BODIPY581/591, has been described in a number of studies as a means to monitor lipid peroxidation in living cells (Borst et al., Reference Borst, Visser, Kouptsova and Visser2000; Pap et al., Reference Pap, Drummen, Post, Rijken and Wirtz2000; Ball and Vo, Reference Ball and Vo2002). The probe shifts from red to green upon oxidation, and the ratio of red and green fluorescence has been used as a measurement of lipid peroxidation. The dye is relatively non-fluorescent in solution and has been evaluated by a fluorescence microplate reader, by epifluorescence microscopy, by confocal microscopy and by flow cytometry (Pap et al., Reference Pap, Drummen, Post, Rijken and Wirtz2000). The fluorescence changes in C11-BODIPY581/591 reflect indirectly the oxidation of unsaturated fatty acids (Borst et al., Reference Borst, Visser, Kouptsova and Visser2000).

Chemiluminescence is considered to be an alternative and potentially sensitive method to assess the oxidation or auto-oxidation of lipids (Miyazawa et al., Reference Miyazawa, Fujimoto and Usuki1994; Albertini and Abuja, Reference Albertini and Abuja1998). In several studies, the luminescence signal has been correlated with other indicators of lipid peroxidation, such as the MA concentration (Doi et al., Reference Doi, Iwasaki, Masubuchi, Nishigaki and Horie2002), the concentration of exogenously added lipid hydroperoxides (Guajardo et al., Reference Guajardo, Terrasa and Catala2002) and the content of conjugated dienes (Albertini and Abuja, Reference Albertini and Abuja1998), confirming that low-level chemiluminescence can serve as an indicator of lipid peroxidative damage. In the case of spermatozoa, however, the intensity of spontaneous luminescence is extremely weak and thus difficult to measure. Earlier studies (Laszczka et al., Reference Laszczka, Godlewski, Kwiecińska, Rajfur, Sitko, Szczęśniak-Fabiańczyk and Sławiński1995; Sławiński et al., Reference Sławiński, Godlewski, Gumińska, Kędryna, Kwiecińska, Laszczka, Szczęśniak-Fabiańczyk and Wierzuchowska1998; Gogol, Reference Gogol2005; Gogol and Szczęśniak-Fabiańczyk, Reference Gogol and Szczęśniak-Fabiańczyk2006) have shown that recording the iron ion-induced luminescence can be an alternative and relatively simple method of measuring sperm lipid peroxidation.

The aim of the present study was to evaluate the effect of the freezing/thawing process on iron ion-induced luminescence of buck sperm as an indicator of cell oxidative damage.

Material and methods

Semen

Five healthy, adult goat bucks were used in this study. Semen was collected from February to May using an artificial vagina. Semen was processed using a modified Corteel cryopreservation procedure (Kareta and Cegła, Reference Kareta and Cegła1999) in a milk–glycerol extender, frozen in 0.25 ml plastic straws using liquid nitrogen vapour and stored in liquid nitrogen.

Frozen straws were thawed in a 37°C water bath for 30 s immediately before use. Freshly ejaculated semen as well as thawed semen samples from the same bucks were also evaluated for luminescence parameters and sperm progressive motility.

Luminescence measurements

Luminescence was measured at 20°C using a Berthold AutoLumat LB953 luminometer equipped with a cooled photomultiplier with a spectral response range from 370 to 620 nm. Prior to measurement of luminescence, spermatozoa were separated from the seminal plasma and diluents by two-fold centrifugation (700 × g for 15 min) and resuspended in 0.9% NaCl to a final concentration of 200 × 106 cells per ml.

To 500 μl of the washed sperm suspension at a concentration of 200 × 106 cells per ml, 10 μl of 5 mmol/l luminol was added. Emission was induced by adding (using automated injector system) 100 μl 0.3 mmol/l FeSO4 solution (final concentration 0.05 mmol/l).

Immediately after injection of FeSO4 solution, light emission kinetics was measured for 300 s (Figure 1). After complete measurements, the following luminescence parameters were calculated: integral – total integral of the measurement signals (counts × 105 per integration time); peak max (c.p.s. × 103) – height of highest peak; slope max (c.p.s. × 102) – maximum slope value of curve; T.slope max – time at maximum slope; T.half (rise) – time at half ‘peak max’ height in ascending direction; T.max (peak) – time at peak maximum; T.half (fall) – time at half ‘peak max’ height in descending direction.

Figure 1 Kinetics of induced luminescence of goat spermatozoa.

Assessment of sperm motility

The percentage of progressive motile spermatozoa was evaluated under a contrast phase microscope equipped with a heated plate at 37°C.

Statistical analysis

Results are expressed as means ± s.e. Data were subjected to variance analysis according to the GLM procedure of the Statistical Analysis Systems Institute (2001).

The significance of differences between means was tested by the least squares method using the LS means procedure. The correlations between luminescence parameters and motility were calculated using Spearman’s rank method.

Results

The effect of freezing/thawing on luminescence parameters and sperm motility is shown in Table 1. Semen freezing significantly increased the values of integral (P < 0.01), peak max (P < 0.01), T.half (rise) (P < 0.05) and T.max (peak) (P < 0.05) parameters. No significant differences between fresh and frozen sperm in the values of slope max, T.slope max and T.half (fall) parameters were observed. The proportion of motile spermatozoa decreased after semen freezing by 30.6% (P < 0.01).

Table 1 The effect of freezing–thawing on luminescence parameters and motility of goat spermatozoa (mean ± s.e.)

a,b Means within a row with different superscripts are significantly different at P < 0.05.

A,B Means within a row with different superscripts are significantly different at P < 0.01.

A significant correlation was observed between the percentage of motile spermatozoa and integral, peak max and T.half (rise) parameters (Table 2). Integral (r = −0.80) and peak max (r = −0.74) were luminescence parameters that were the most strongly correlated with sperm motility. No significant correlation was found between T.max (peak) and T.half (fall) parameters and the percentage of motile spermatozoa.

Table 2 Correlations between luminescence parameters and sperm motility

P < 0.05 was considered significant.

Differences between males in the luminescence parameters were observed (Tables 3 and 4). In both fresh and frozen semen, the sperm of buck C was characterised by the lowest, and the sperm of buck B by the highest, values of integral and peak max parameters.

Table 3 Results of luminescence measurement and sperm motility for fresh semen (mean ± s.e.)

a,b,c Means within a row with different superscripts are significantly different at P < 0.05.

A,B,C,D Means within a row with different superscripts are significantly different at P < 0.01.

Table 4 Results of luminescence measurement and sperm motility for frozen semen (mean ± s.e.)

a,b,c Means within a row with different superscripts are significantly different at P < 0.05.

A,B Means within a row with different superscripts are significantly different at P < 0.01.

Discussion

In the present study, induced luminescence (photon emission) measurements were used to determine oxidative damage to goat spermatozoa. Earlier studies covering measurements of the spectral distribution of sperm emission and analysis of the relationships between the concentration of Fe ions and intensity of induced luminescence show that this biophysical phenomenon is strictly related to lipid peroxidation (Sławiński et al., Reference Sławiński, Godlewski, Gumińska, Kędryna, Kwiecińska, Laszczka, Szczęśniak-Fabiańczyk and Wierzuchowska1998; Gogol, Reference Gogol2005). Ferrous ions have been used extensively to induce rapid lipid peroxidation in a variety of cell types including spermatozoa (Jones et al., Reference Jones, Mann and Sherins1979; Aitken et al., Reference Aitken, Harkiss and Buckingham1993a; Storey, Reference Storey1997; Gomez et al., Reference Gomez, Irvine and Aitken1998). The ferrous ion promotes the catalysis of lipid peroxides to alkoxyl and peroxyl radicals, which appear to be important in the propagation of the chain reaction of lipid peroxidation in the sperm membrane (Aitken et al., Reference Aitken, Harkiss and Buckingham1993a). In these radical chain reactions, electron-excited molecules are generated and then radiatively deactivated, which manifests itself as an emission of light (chemiluminescence, ultraweak photon emission). Our study is evidence that the kinetics and intensity of induced lipid peroxidation of sperm can be observed based on changes in the intensity of luminescence recorded. Our method enables the total level of ROS (generated during the lipid peroxidation process) to be determined (integral parameter) as well as the observation of the reaction kinetics probably related to the antioxidant capacity of sperm. It is supposed that higher sperm antioxidant activity gives flatter kinetic curve. This means the lower peak max and slope max values and the bigger difference between T.half (rise) and T.half (fall). Dissection of the luminescence signal into more parameters then only the integral one makes possible to obtain more detailed information about the processes that take place in the sperm cells.

The rapid increase in luminescence intensity after freezing/thawing of semen, which was accompanied by a decrease in sperm motility, demonstrates that the phospholipids present in goat spermatozoa readily undergo peroxidation.

The decreased motility of spermatozoa may occur due to the action of free radicals under oxidative stress. There are several possible mechanisms behind the decreased motility of spermatozoa connected with oxidative stress. The most often cited is peroxidation of membrane lipids (Aitken et al., Reference Aitken, Clarkson and Fisher1989, Reference Aitken, Harkiss and Buckingham1993a and Reference Aitken, Harkiss and Buckingham1993b). The attack of free radicals on the unsaturated fatty acid-rich lipids of sperm cell membranes leads to irreversible reduction of membrane fluidity and to the damage of cell membrane-related ATPases, which are responsible for regulation of the intracellular level of ions necessary to maintain normal sperm motility (Ohta et al., Reference Ohta, Mohri and Ohyashiki1989).

The lipid peroxidation process in spermatozoa leads to the creation of substances having cytotoxic properties, such as MA and 4-hydroxynonenol (Aitken et al., Reference Aitken, Paterson, Fisher, Buckingham and Van Duin1995). Low concentrations of these substances have been shown to inhibit a large number of cellular enzymes and functions, including anaerobic glycolysis limiting ATP generation by the sperm cell (Comporti, Reference Comporti1989).

De Lamiranda and Gagnon (Reference De Lamiranda and Gagnon1992) suggest that ROS are responsible for the loss of spermatozoal motility through decreased phosphorylation of axonemal proteins required for sperm movement.

The above free radical processes that occur under oxidative stress conditions can explain the relationships between photon emission parameters and sperm motility. A similar relationship between the potential for iron-induced MA generation as an indicator of lipid peroxidation and human sperm movement was reported by Kobayashi et al. (Reference Kobayashi, Miyazaki, Natori and Nozawa1991) and Aitken et al. (Reference Aitken, Harkiss and Buckingham1993a).

Analysis of the effect of freezing on the values of particular luminescence parameters and the correlation between sperm motility and luminescence parameters indicate that integral and peak max are the luminescence parameters particularly useful for determining the ROS-induced damage at the level of the sperm plasma membrane.

The large individual differences shown between luminescence parameters (which determine the sperm sensitivity to lipid peroxidation) show the possibility of using luminescence measurements when selecting males whose semen is highly suitable for freezing.

In conclusion, our findings confirm that an oxidative stress occurs during semen cryopreservation and demonstrate that measurement of induced luminescence can be a sensitive and relatively simple method for assessing the effect of freezing and thawing on oxidative damage to spermatozoa.

References

Aitken, RJ, Clarkson, JS, Fisher, S 1989. Generation of reactive oxygen species, lipid peroxidation and human sperm function. Biology of Reproduction 41, 183197.CrossRefGoogle ScholarPubMed
Aitken, RJ, Harkiss, D, Buckingham, DW 1993a. Analysis of lipid peroxidation mechanisms in human spermatozoa. Molecular Reproduction and Development 35, 302315.CrossRefGoogle ScholarPubMed
Aitken, RJ, Harkiss, D, Buckingham, DW 1993b. Relationship between iron-catalysed lipid peroxidation potential and human sperm function. Journal of Reproduction and Fertility 98, 257265.CrossRefGoogle ScholarPubMed
Aitken, RJ, Paterson, M, Fisher, H, Buckingham, DW, Van Duin, M 1995. Redox regulation of tyrosine phosphorylation in human spermatozoa and its role in the control of human sperm function. Journal of Cell Science 108, 20172025.CrossRefGoogle ScholarPubMed
Albertini, R, Abuja, PM 1998. Monitoring of low-density lipoprotein oxidation by low-level chemiluminescence. Free Radical Research 29, 7583.CrossRefGoogle ScholarPubMed
Alvarez, JG, Storey, BT 1992. Evidence of increased lipid peroxidative damage and loss of superoxide dismutase activity as a mode of sublethal cryodamage to human sperm during cryopreservation. Journal of Andrology 13, 232241.CrossRefGoogle ScholarPubMed
Ball, BA, Vo, AT, Baumber, J 2001. Generation of reactive oxygen species by equine spermatozoa. American Journal of Veterinary Research 62, 508515.CrossRefGoogle ScholarPubMed
Ball, BA, Vo, A 2002. Detection of lipid peroxidation in equine spermatozoa based upon the lipophilic fluorescent dye C11–BODIPY581/591. Journal of Andrology 23, 259269.CrossRefGoogle Scholar
Borst, JW, Visser, NV, Kouptsova, O, Visser, AJ 2000. Oxidation of unsaturated phospholipids in membrane bilayer mixtures is accompanied by membrane fluidity changes. Biochimica et Biophysica Acta 1487, 6173.CrossRefGoogle ScholarPubMed
Chatterjee, S, Gagnon, C 2001. Production of reactive oxygen species by spermatozoa undergoing cooling, freezing, and thawing. Molecular Reproduction and Development 59, 451458.CrossRefGoogle ScholarPubMed
Chen, Y, Foote, RH, Brockett, CC 1993. Effect of sucrose, trehalose, hypotaurine, taurine, and blood serum on survival of frozen bull sperm. Cryobiology 30, 423431.CrossRefGoogle ScholarPubMed
Comporti, M 1989. Three models of free radical-induced cell injury. Chemico-Biological Interactions 72, 156.CrossRefGoogle ScholarPubMed
Cormier, N, Sirard, MA, Beiley, JL 1997. Premature capacitation of bovine spermatozoa is initiated by cryopreservation. Journal of Andrology 18, 461468.CrossRefGoogle ScholarPubMed
De Lamiranda, E, Gagnon, C 1992. Reactive oxygen species and human spermatozoa. II. Depletion of adenosine triphosphate plays an important role in the inhibition of sperm motility. Journal of Andrology 13, 379386.CrossRefGoogle Scholar
Doi, H, Iwasaki, H, Masubuchi, Y, Nishigaki, R, Horie, T 2002. Chemiluminescence associated with the oxidative metabolism of salicylic acid in rat liver microsomes. Chemico-Biological Interactions 140, 109119.CrossRefGoogle ScholarPubMed
Gogol, P 2005. Iron-induced luminescence of boar spermatozoa cells. Annals of Animal Science 5, 9198.Google Scholar
Gogol, P, Szczęśniak-Fabiańczyk, B 2006. Effect of long-term storage on induced photon emission of boar spermatozoa. Czech Journal of Animal Science 51, 6165.CrossRefGoogle Scholar
Gomez, E, Irvine, DS, Aitken, RJ 1998. Evaluation of a spectrophotometric assay for the measurement of malondialdehyde and 4-hydroxyalkenals in human spermatozoa: relationship with semen quality and sperm function. International Journal of Andrology 21, 8194.CrossRefGoogle ScholarPubMed
Guajardo, MH, Terrasa, AM, Catala, A 2002. Retinal fatty acid binding protein reduce lipid peroxidation stimulated by long-chain fatty acid hydroperoxideson rod outer segments. Biochimica et Biophysica Acta 1581, 6574.CrossRefGoogle ScholarPubMed
Hammerstedt, RH 1993. Maintenance of bioenergetic balance in sperm and prevention of lipid peroxidation: review of the effect on design of storage preservation systems. Reproduction, Fertility and Development 5, 675690.CrossRefGoogle ScholarPubMed
Hammerstedt, RH, Graham, JK, Nolan, JP. 1990. Cryopreservation of mammalian sperm: what we ask them to survive? Journal of Andrology 11, 7388.Google Scholar
Jones, R, Mann, T, Sherins, RJ 1979. Peroxidative breakdown of phospholipids in human spermatozoa, spermicidal properties of fatty acid peroxides, and protective action of seminal plasma. Fertility and Sterility 31, 531537.CrossRefGoogle ScholarPubMed
Kareta, WCegła, M 1999. Mrożenie nasienia kozłów. Materiały instruktażowe. Instytut Zootechniki, Kraków, Poland.Google Scholar
Kobayashi, T, Miyazaki, T, Natori, M, Nozawa, S 1991. Protective role of superoxide dismutase in human sperm motility: superoxide dismutase activity and lipid peroxide in human seminal plasma and spermatozoa. Human Reproduction (Oxford, England) 6, 987991.CrossRefGoogle ScholarPubMed
Kodama, H, Kuribayashi, Y, Gagnon, C 1996. Effect of sperm lipid peroxidation on fertilization. Journal of Andrology 17, 151157.CrossRefGoogle ScholarPubMed
Laszczka, A, Godlewski, M, Kwiecińska, T, Rajfur, Z, Sitko, D, Szczęśniak-Fabiańczyk, B, Sławiński, J 1995. Ultraweak luminescence of spermatozoa. Current Topics in Biophysics 19, 2031.Google Scholar
Marshall, PJ, Warso, MA, Lands, WEM 1985. Selective microdetermination of lipid hydroperoxides. Analytical Biochemistry 145, 192199.CrossRefGoogle ScholarPubMed
Miyazawa, T, Fujimoto, K, Usuki, R 1994. Rapid estimation of peroxide content of soybean oil by measuring thermoluminescence. Journal of the American Oil Chemists’ Society 71, 343345.CrossRefGoogle Scholar
Ohta, A, Mohri, T, Ohyashiki, T 1989. Effect of lipid peroxidation on membrane-bound Ca2+-ATPase activity of the intestinal brush-border membranes. Biochimica et Biophysica Acta 984, 151157.CrossRefGoogle ScholarPubMed
Ohyashiki, T, Ohtsuka, T, Mohri, T 1988. Increase of the molecular rigidity of the protein conformation in the intestinal brush-border membranes by lipid peroxidation. Biochimica et Biophysica Acta 939, 383392.CrossRefGoogle ScholarPubMed
Pap, EH, Drummen, GP, Post, JA, Rijken, PJ, Wirtz, KW 2000. Fluorescent fatty acid to monitor reactive oxygen in single cells. Methods in Enzymology 319, 603612.CrossRefGoogle ScholarPubMed
Sanchez-Partida, LG, Setchell, BP, Maxwell, WMC 1997. Epididymal compounds and antioxidants in diluents for the frozen storage of ram spermatozoa. Reproduction, Fertility, and Development 9, 689696.CrossRefGoogle ScholarPubMed
Selley, ML, Lacey, MJ, Bartlett, MR, Copeland, CM, Ardlie, NG 1991. Content of significant amounts of a cytotoxic end-product of lipid peroxidation in human semen. Journal of Reproduction and Fertility 92, 291298.CrossRefGoogle ScholarPubMed
Sławiński, J, Godlewski, M, Gumińska, M, Kędryna, T, Kwiecińska, T, Laszczka, A, Szczęśniak-Fabiańczyk, B, Wierzuchowska, D 1998. Stress-induced peroxidation and ultraweak photon emission of spermatozoa cells. Current Topics in Biophysics 22, 195203.Google Scholar
Statistical Analysis Systems Institute 2001. SAS user’s guide statistics, version 8.2. SAS Institute Inc., Cary, NC, USA.Google Scholar
Storey, BT 1997. Biochemistry of the induction and prevention of lipoperoxidative damage in human spermatozoa. Molecular Human Reproduction 3, 203213.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1 Kinetics of induced luminescence of goat spermatozoa.

Figure 1

Table 1 The effect of freezing–thawing on luminescence parameters and motility of goat spermatozoa (mean ± s.e.)

Figure 2

Table 2 Correlations between luminescence parameters and sperm motility

Figure 3

Table 3 Results of luminescence measurement and sperm motility for fresh semen (mean ± s.e.)

Figure 4

Table 4 Results of luminescence measurement and sperm motility for frozen semen (mean ± s.e.)