Production of transgenic rats via lentiviral transduction and xenogeneic transplantation of spermatogonial stem cells

Spermatogonial stem cells (SSCs) continue to proliferate in the testis to support spermatogenesis throughout life, which makes them ideal targets for germline modification. Although recent success in the production of transgenic and knockout animals using SSCs has opened up new experimental possibilities, several problems, including the low efficiency of germ cell transplantation and poor fertility rates, remain to be resolved. In the present study, we took advantage of the xenogeneic transplantation to resolve these problems. Rat SSCs were transduced in vitro with a lentiviral vector that expressed enhanced green fluorescent protein (EGFP), and then transplanted into the testes of immunodeficient mice. The transduced rat SSCs produced EGFP-expressing spermatogenic cells, and microinsemination using these cells was used to produce transgenic rats, which stably transmitted the transgene to the next generation. Thus, xenogeneic transplantation is a powerful strategy for transgenesis, and smaller xenogeneic surrogates can be used for male germline modification using SSCs.     

The testicular soma of Tsc22d3 knockout mice supports spermatogenesis and germline transmission from spermatogonial stem cell lines upon transplantation

Spermatogonial stem cells (SSCs) are adult stem cells that are slowly cycling and self‐renewing. The pool of SSCs generates very large numbers of male gametes throughout the life of the individual. SSCs can be cultured in vitro for long periods of time, and established SSC lines can be manipulated genetically. Upon transplantation into the testes of infertile mice, long‐term cultured mouse SSCs can differentiate into fertile spermatozoa, which can give rise to live offspring. Here, we show that the testicular soma of mice with a conditional knockout (conKO) in the X‐linked gene Tsc22d3 supports spermatogenesis and germline transmission from cultured mouse SSCs upon transplantation. Infertile males were produced by crossing homozygous Tsc22d3 floxed females with homozygous ROSA26‐Cre males. We obtained 96 live offspring from six long‐term cultured SSC lines with the aid of intracytoplasmic sperm injection. We advocate the further optimization of Tsc22d3‐conKO males as recipients for testis transplantation of SSC lines.     

Establishment of a proteome profile and identification of molecular markers for mouse spermatogonial stem cells

Spermatogonial stem cells (SSCs) are undifferentiated cells that are required to maintain spermatogenesis throughout the reproductive life of mammals. Although SSC transplantation and culture provide a powerful tool to identify the mechanisms regulating SSC function, the precise signalling mechanisms governing SSC self‐renewal and specific surface markers for purifying SSCs remain to be clearly determined. In the present study, we established a steady SSC culture according to the method described by Shinohara's lab. Fertile progeny was produced after transplantation of cultured SSCs into infertile mouse testis, and the red fluorescence exhibited by the culture cell membranes was stably and continuously transmitted to the offspring. Next, via advanced mass spectrometry and an optimized proteomics platform, we constructed the proteome profile, with 682 proteins expressed in SSCs. Furthermore bioinformatics analysis showed that the list contained several known molecules that are regulated in SSCs. Several nucleoproteins and membrane proteins were chosen for further exploration using immunofluorescence and RT‐PCR. The results showed that SALL1, EZH2, and RCOR2 are possibly involved in the self‐renewal mechanism of SSCs. Furthermore, the results of tissue‐specific expression analysis showed that Gpat2 and Pld6 were uniquely and highly expressed in mouse testes and cultured SSCs. The cellular localization of PLD6 was further explored and the results showed it was primarily expressed in the spermatogonial membrane of mouse testes and cultured SSCs. The proteins identified in this study form the basis for further exploring the molecular mechanism of self‐renewal in SSCs and for identifying specific surface markers of SSCs.     

Motility and fertility of stallion spermatozoa isolated in bovine serum albumin

Semen from three mature stallions was used in an attempt to isolate a population of highly motile spermatozoa. An ejaculate of semen, collected from each stallion at 7-day intervals for 35 days, was evaluated for percentage of motile spermatozoa and rate of progressive motility (scale 1 to 4). Two milliliters of semen were layered over 6 ml of 3% bovine serum albumin (BSA) in 13 × 125 mm columns at room temperature (RMT) or in a warm water bath (WB). After a 30-minute separation period, the top semen layer and the upper and lower halves of the BSA fraction were separately withdrawn from columns and reevaluated. In both the RMT and WB separation columns, percent motile spermatozoa and progressive motility decreased in the top semen fraction as compared to initial values for these parameters. Percentage of motile spermatozoa in the lower BSA fractions increased (P<.01) to 58.7 and 65.7 following separation at RMT and in a WB, respectively. Also, there was a significant increase in rate of progressive motility rate for spermatozoa in the lower BSA fraction of both the RMT and WB treatments.In a second experiment 30 Quater Horse mares were artificially inseminated to compare fertility of spermatozoa isolated in BSA with raw semen diluted with either Tyrode's solution or BSA. The pregnancy rate for 10 mares inseminated with 100 × 10⁶ live isolated spermatozoa was not different from that of control mares inseminated with the same number of live untreated spermatozoa. Foaling rates were 70, 40 and 60% for the isolated, Tyrode and BSA treatment groups respectively.     

Influence of season on characteristics of the ejaculate from bulls in an artificial insemination centre in Nigeria

The influence of season on the ejaculate characteristics of Zebu, Friesian and their crossbred bulls in an A.I. programme in Nigeria was investigated over a 2-year period.Ejaculate volume, sperm concentration, percent morphologically normal spermatozoa and percent live spermatozoa were significantly higher in the rainy season than in the dry season. Total spermatozoa per ejaculate averaged 3.32 × 10⁹ and 10.10 × 10⁹ for the dry and rainy seasons respectively. Corresponding proportions of total morphologically defective spermatozoa per ejaculate were 14.05% and 6.46%. Percent live spermatozoa were 82.34% and 84.61% while the corresponding sperm concentrations were 0.97 × 10⁹ rmand 1.74 × 10⁹ for the dry and rainy seasons respectively. All differences were statistically significant (P < 0.05).Ejaculate quality was better during the rainy season. Consequently semen collected and frozen during the rainy season may produce higher fertility rates in an A.I. programme.     

Cyclic AMP and genetic sterility of a male restricted (H re /+) mutant of Rattus

Restricted (H ^re /+) male rats marked by a coat color pattern have normal testes at birth. By 9 days postpartum, testes of the mutant animals are smaller than normal and by approximately 90 days of age the animals are sterile. The genetically sterile testes are totally devoid of spermatogonial cells, spermatocytes, spermatids, and spermatozoa, with only Sertoli cells remaining in the seminiferous tubules. Cyclic AMP concentrations in the whole testes (and the seminiferous tubules) of the mutant males are approximately 10–35% greater than in testes of control males when tested at intervals from 5 to 120 days of age. The possible role of excess cyclic AMP in reducing the rate of mitotic division of spermatogonial cells while enhancing differentiation of spermatogonial cells into spermatozoa is discussed. Such a change in the respective rates of mitotic and meiotic divisions would ultimately deplete the mutant testes of all spermatogonial cells.     

Genetic analysis of the clonal origin of regenerating mouse spermatogenesis following transplantation

Spermatogonial transplantation provides a straightforward approach to quantify spermatogonial stem cells (SSCs). Because donor-derived spermatogenesis is regenerated in the form of distinct colonies, the number of functional SSCs can be obtained by simply counting the number of colonies established in recipient testes. However, this approach is legitimate only when one colony arises from one stem cell (one colony-one stem cell hypothesis). In this study, we evaluated the validity of this hypothesis. Two populations of donor cells were obtained from the testes of two transgenic mouse lines and mixed at a 1:1 ratio. Following transplantation of the cell mixture, donor-derived colonies were visualized and individually excised, and genomic DNA was extracted from each colony. Based on unique marker genes of the two transgenic lines, the genotype of the cells contained in a colony was examined by polymerase chain reaction. A colony was determined to be clonal when only one transgene was detected. The results showed that 100% and 90% of colonies were clonal when <5 and 19 colonies were formed per recipient testis, respectively. However, the clonality of colonies decreased as the colony number per recipient testis or the length of each colony increased. These results support the one colony-one stem cell hypothesis and demonstrate that spermatogonial transplantation provides a highly quantitative assay for SSCs; however, these conclusions are applicable under a defined transplantation condition.     

The dependence of the growth rate and meat content of young boars on semen parameters and conception rate

Boars have a decisive impact on the progress in pig production, however, there is no recent information about the optimal growth parameters during the rearing period for modern breed later used in artificial insemination (AI) stations. Therefore, the objective of the research was to conduct semen parameter and conception rate analyses on the basis of growth rate and meat content assessments made during the rearing of AI boars of different genotypes. The study was carried out between 2010 and 2014 and included 184 boars in five breed combinations: 46 Polish Large White, 50 Polish Landrace, 27 Pietrain, 36 Duroc×Pietrain and 25 Hampshire×Pietrain. Boars were qualified by daily gains and meat content assessment (between 170 and 210 days of life). A total number of 38 272 ejaculates were examined (semen volume (ml), spermatozoa concentration (×10⁶ ml⁻¹), total number of spermatozoa (×10⁹) and number of insemination doses from one ejaculate (n)). The fertility was determined by the conception rate (%). Semen volume, spermatozoa concentration and conception rate (P<0.01), followed by the total number of spermatozoa and insemination doses (P<0.05) were characterized by the highest variability in relation to breed of boars. The effect of daily gains was reported for spermatozoa concentration, number of insemination doses, conception rate (all P<0.01) and total number of spermatozoa (P<0.05). The peak of growth for spermatozoa concentration, total number of spermatozoa, insemination doses and conception rate was achieved for 800 to 850 g gains. Meat content affected semen volume, number of insemination doses and conception rate (P<0.05). Rearing boars while maintaining daily gains at the 800 to 850 g level and 62.5% to 65% meat content helps AI stations to increase the efficiency and economic profitability, and the number of insemination doses to increase by up to 300 doses/boar within a year. The analyses of growth parameters may help increase the efficiency and economic viability of AI stations.     

Efficacy of TEPA as a “sperm label” for competitive fertilization studies in the rabbit

In this paper, the conditions necessary to use TEPA [tris (1-aziridinyl)] effectively as a label for spermatozoa in competitive fertilization are established. The fertilizing ability of rabbit spermatozoa treated with 0 and 0.8 mg TEPA/ml was compared at insemination doses of 1, 5, 20, and 40 × 10⁶ spermatozoa. Fertility was assessed by collecting ova from 64 does 48 to 52 h after insemination. TEPA blocked all but 4% of the ova from developing when 1 × 10⁶ spermatozoa were inseminated, but fertility was reduced. When 5 × 10⁶ spermatozoa were inseminated following treatment with 0, 0.6 or 1.2 mg of TEPA/ml, the fertility was 83, 74 and 50% (P<0.05), and the percentage of ova containing more than four blastomeres was 83, 11 and 5% (P<0.05), respectively. The 0.6% TEPA level was selected for a competitive fertilization trial. Equal numbers of sperm from pure Dutch-color and albino sires were combined so that either both types were untreated, only the ‘albino’ semen was treated, only the ‘Dutch’ semen was treated, or both were treated. Does were inseminated with 5 × 10⁶ sperm and allowed to kindle. The litter sizes were 5.6, 3.1, 2.7, and 0 young, and the proportion of Dutch-color progeny was 63, 97, 0 and 0%, respectively, confirming the effectiveness of TEPA as a “label”. Only one of 60 young born resulted from fertilization by a TEPA-treated spermatozoon, demonstrating that few embryos fully escape the TEPA block. Thus, the TEPA concentration and sperm numbers were established to use TEPA effectively as a label for spermatozoa in competitive fertilization studies.     

Fertility of ram semen after storage at 5°C

In five experiments, fertilization, early (18–19-day) pregnancy, and lambing were examined after insemination with semen stored at 5°C in tris-fructose-egg yolk diluent.After deposition into uterine horns by surgical insemination of semen stored for 0 (control), 2, 4, 6, 8, 9 or 10 days, fertilized eggs were recovered in $\text{32}\text{34}\text{,}\text{16}\text{16}\text{,}\text{21}\text{22}\text{,}\text{15}\text{20}$, $\text{9}\text{17}\text{,}\text{2}\text{18}$ and $\text{1}\text{15}$ ewes; the 18–19-day pregnancy rates determined by progesterone assay were $\text{32}\text{48}\text{,}\text{15}\text{28}\text{,}\text{11}\text{20}\text{,}\text{12}\text{20}\text{,}\text{9}\text{20}$, $\text{2}\text{20}$ and $\text{1}\text{21}$ for the respective storage periods. There was a linear decrease in fertilization rates beyond 4 days of storage and in early pregnancy rates after 6 days of storage (P<0.001). The decline with time of storage in the fertilization rate was not associated with an increase in early embryonic loss. Surgical insemination with semen stored for 0, 4, 6, 8, 9 and 10 days resulted in 53, 35, 40, 25, 5, and 0% lambing.Single cervical (normal) insemination of a total of 281 ewes with 0, 1, 2 or 3-day-old semen, using within each semen treatment 90 × 10⁶ and 180 × 10⁶ spermatozoa, yielded mean lambing rates of 60.0, 34.3, 33.8, and 17.1%; and after using 150 × 10⁶ and 300 × 10⁶ spermatozoa in a total of 393 ewes the mean lambing rates for the above semen treatments were 69.0, 46.4, 36.1, and 24.2% (linear, P < 0.001). In both tests the lambing results were better after insemination of the higher number of spermatozoa, but the slope of decline in fertility with age of semen was not affected by the sperm dose.When single and double cervical inseminations were performed in a total of 411 ewes, with 150 × 10⁶ and 300 × 10⁶ spermatozoa per inseminate, the lambing rates for semen stored for 0, 1, 2 and 3 days were 57.7, 30.4, 26.8, and 4.7% after single insemination, and 66.7, 56.8, 46.4, and 41.5% after double inseminations. The sperm dose within method of insemination and semen treatment had no effect. The lambing rate was better after double than single insemination (P<0.001), but the slope of decline in fertility with age of semen was not significantly affected by number of inseminations.In the final experiment, involving 408 ewes, 300 μg of prostaglandin F₂α added to the inseminate did not improve the fertility of fresh semen or semen stored for 1 day.     

Direct injection of foreign DNA into mouse testis as a possible in vivo gene transfer system via epididymal spermatozoa.

We have attempted to transfect testicular spermatozoa with plasmid DNA by direct injection into testes to obtain transgenic animals [this technique was thus termed "testis-mediated gene transfer (TMGT)"]. When injected males were mated with superovulated females 2 and 3 days after injection, (i) high efficiencies (more than 50%) of gene transmission were achieved in the mid-gestational F0 fetuses, (ii) the copy number of plasmid DNA in the fetuses was estimated to be less than 1 copy per diploid cell, and (iii) overt gene expression was not found in these fetuses. These findings suggest the possibility that plasmid DNA introduced into a testis is rapidly transported to the epididymis and then incorporated by epididymal spermatozoa. The purpose of this study was to elucidate the mechanism of TMGT by introducing trypan blue (TB) or Hoechst 33342 directly into testis. We found that TB is transported to the ducts of the caput epididymis via rete testis within 1 min after testis injection, and TB reached the corpus and cauda epididymis within 2-4 days after injection. Staining of spermatozoa isolated from any portion of epididymis was observed 4 days after injection of a solution containing Hoechst 33342. Injection of enhanced green fluorescent protein (EGFP) expression vector/liposome complex into testis resulted in transfection of epithelial cells of epididymal ducts facing the lumen, although the transfection efficiency appeared to be low. In vivo electroporation toward the caput epididymis immediately after injection of EGFP expression vector into a testis greatly improved the uptake of foreign DNA by the epididymal epithelial cells. PCR analysis using spermatozoa isolated from corpus and cauda epididymis 4 days after injection of a DNA/liposome complex into testis revealed exogenous DNA in these spermatozoa even after treatment with DNase I. These findings indicate that exogenous DNA introduced into tesits is rapidly transported to epididymal ducts via the rete testis and efferent ducts, and then incorporated by epithelial cells of epididymis and epididymal spermatozoa.     

Sperm motility and fertilizing ability of frozen spermatozoa of males (XY) and neomales (XX) of perch (Perca fluviatilis)

The objective of this study was to freeze sperm of sex‐reversed females (neomales) of perch and to test their fertilization ability. Sperm used was testicular (TSN), collected from females that have been inverted by means of externally administered 17‐alpha methyltestosterone. Sperm collected from intact males (SSNM) of the same origin were used as control. Prior to freezing, both TSN and SSNM were diluted into 300 mm glucose solution at the ratio of 1 : 6 and DMSO was used as cryoprotectant (10% final concentration). Crypreservation was performed in 0.5 ml straws placed into a polystyrene box, three cm above the liquid nitrogen level for 10 min and thereafter transferred fully into liquid nitrogen. Samples were thawed in 40°C water bath for 8 s and used for the fertilization experiments. Spermatozoa concentration of fresh TSN and SSNM were estimated with 45.3 × 10⁹ and 37.8 × 10⁹ spermatozoa ml^?1, respectively. Both sperm velocity and motility showed significant decreases in the TSN (134.6 μm s^?1 and 12.8%) compared to the SSNM (203.2 μm s^?1 and 94.7%) at 10 s after sperm activation. However, no differences were observed in terms of hatching rates between fresh TSN and SSNM (42.5 vs 49.3%) at fertilization densities of 12 × 10⁵ spermatozoa per egg. Frozen/thawed SSNM exhibited similar hatching rates at 12 × 10⁵ and 2.4 × 10⁵ spermatozoa per egg (37.2% vs 29.1%). Hatching rates for frozen/thawed TSN were about 7.3% with 12 × 10⁵ spermatozoa per egg and did not show any difference at 2.4 × 10⁵ spermatozoa per egg (6.6%). Stripped sperm of normal perch can be successfully frozen. Squeezing of the testes is not a good method for collection of testicular sperm resulting into low velocity, motility and hatching rate. To understand the influences of neomales on sperm quality on reproductive success further studies should be performed addressing a full assay of motility and fertility criteria when using stripped sperm from normal males and neomales. Additionally, the results indicate that many of sex reversed perch neomales are not able to release sperm and that for further studies some well spermiating neomales must to be selected.     

Semen backflow after insemination and its effect on fertilisation results in sows

The aim of the present study was to investigate the volume of and number of spermatozoa in semen backflow during and after insemination, and the effect of backflow on fertilisation results assessed at day 5 of pregnancy. Multiparous sows (n=140) were artificially inseminated with either (1, 3 or 6)×10⁹ mixed spermatozoa from three boars in a constant volume of 80 ml. Backflow of semen was measured three times: during insemination (M1); during the first half hour after insemination (M2); and from 0.5 h until about 2.5 h after insemination (M3). Transrectal ultrasonography was performed at intervals of 4 h to determine the time of ovulation. Sows were sacrificed at 120±0.4 h after ovulation to assess the results of fertilisation. Every sow had some backflow and the variation in volume, and number of spermatozoa within the backflow was high. The average semen backflow within 2.5 h after insemination was 70±3.4% of the volume and 25±1.4% of the spermatozoa of the inseminated dosage. The concentration of the backflow (% of the inseminated dosage) decreased with time after insemination from 65% at M1 to 40% and 26% at M2 and M3, respectively. The correlations between volume and number of spermatozoa were high: r=0.97, r=0.73 and r=0.81 in M1, M2 and M3, respectively. More than 5% of the inseminated spermatozoa in backflow during insemination affected fertilisation negatively in those sows inseminated with 1×10⁹ spermatozoa (P<0.05). Backflow after insemination had no effect on fertilisation results (P>0.05). Timing of insemination relative to ovulation and oestrus were not related to backflow during or after insemination (P>0.05). Of the sows which had backflow, those of parity 1 tended to have the highest proportion of sows with more than 5 ml backflow (47%; n=8 of 17) compared with sows from parity 2 and higher (24%; n=14 of 59) (P=0.075). It was concluded that excessive backflow of semen during insemination had a negative effect on fertilisation results when sows where inseminated with only 1×10⁹ spermatozoa. Causes of variation in backflow between sows were not clearly identifiable.     

Electroejaculation in chimpanzees and gorillas and artificial insemination in chimpanzees

Electroejaculation was performed in 3 chimpanzees, 1 pygmy chimpanzee, and 2 gorillas with an instrument that delivers a modified sine wave current with a frequency of 24 Hz. The current stimuli were applied by a rectal probe with longitudinal electrodes. The electrical parameters varied from 6 to 12 V and from 30 to 40 mA for response of erection and lay between 8 and 18 V and between 40 and 145 mA during semen emission. Eleven chimpanzee semen samples showed the following data (x ± SD): total volume 1.9 ± 1.3 ml, volume of the liquid fraction 0.3 ± 0.2 ml, spermatozoa per ejaculate 743 ± 376 × 10⁶, sperm motility 52.7 ± 9.6%, morphologically abnormal spermatozoa 12.2 ± 7.5%. From an adult gorilla, three semen samples were collected, in each case without spermatozoa. The electrostimulation of a 6-year-old gorilla led to an erection, but not to semen emission. Three female chimpanzees were inseminated with fresh or frozen semen, each of them within three different estrous cycles. None of these inseminations led to a pregnancy.     

Transplantation of expanded bone marrow‐derived very small embryonic‐like stem cells (VSEL‐SCs) improves left ventricular function and remodelling after myocardial infarction

Adult bone marrow‐derived very small embryonic‐like stem cells (VSEL‐SCs) exhibit a Sca‐1⁺/Lin^–/CD45^– phenotype and can differentiate into various cell types, including cardiomyocytes and endothelial cells. We have previously reported that transplantation of a small number (1 × 10⁶) of freshly isolated, non‐expanded VSEL‐SCs into infarcted mouse hearts resulted in improved left ventricular (LV) function and anatomy. Clinical translation, however, will require large numbers of cells. Because the frequency of VSEL‐SCs in the marrow is very low, we examined whether VSEL‐SCs can be expanded in culture without loss of therapeutic efficacy. Mice underwent a 30 min. coronary occlusion followed by reperfusion and, 48 hrs later, received an intramyocardial injection of vehicle (group I, n= 11), 1 × 10⁵ enhanced green fluorescent protein (EGFP)‐labelled expanded untreated VSEL‐SCs (group II, n= 7), or 1 × 10⁵ EGFP‐labelled expanded VSEL‐SCs pre‐incubated in a cardiogenic medium (group III, n= 8). At 35 days after myocardial infarction (MI), mice treated with pre‐incubated VSEL‐SCs exhibited better global and regional LV systolic function and less LV hypertrophy compared with vehicle‐treated controls. In contrast, transplantation of expanded but untreated VSEL‐SCs did not produce appreciable reparative benefits. Scattered EGFP⁺ cells expressing α‐sarcomeric actin, platelet endothelial cell adhesion molecule (PECAM)‐1, or von Willebrand factor were present in VSEL‐SC‐treated mice, but their numbers were very small. No tumour formation was observed. We conclude that VSEL‐SCs expanded in culture retain the ability to alleviate LV dysfunction and remodelling after a reperfused MI provided that they are exposed to a combination of cardiomyogenic growth factors and cytokines prior to transplantation. Counter intuitively, the mechanism whereby such pre‐incubation confers therapeutic efficacy does not involve differentiation into new cardiac cells. These results support the potential therapeutic utility of VSEL‐SCs for cardiac repair.     

Sperm motility and seminal fluid composition in the burbot, Lota lota

Sperm motility and composition of the seminal fluid in Lota lota were investigated. Fives after motility initiation, 88.2 ± 12.4% of the spermatozoa were motile, their mean average path swimming velocity was 61.6 ± 16.3 μm s^?1 and their principal swimming type the linear motion (77.4 ± 20.9%). In distilled water the rate of motile spermatozoa decreased to 0% in 40s. In 25–50 mosmol kg^?1 electrolyte (NaCl) or non-electrolyte (glucose, sucrose) solutions, motility was prolonged for 10s and these solutions can therefore increase the efficiency of artificial fertilization when used for sperm motility activation. When semen was diluted in electrolyte or non-electrolyte solutions with osmolalities higher than 50 mosmol kg^?1, sperm motility rates and swimming velocities decreased, and at osmolalities of 400 mosmol kg^?1 motility was completely suppressed. In the seminal fluid with an osmolality of 290.08 ± 45.22 mosmol kg^?1, sodium levels of 139.86 ± 23.79 mmol × 1^?1, potassium levels of 11.59 ± 2.45 mmol × 1^?1 and calcium levels of 0.20 ± 0.08 mmol × 1^?1, sperm motility was inhibited. Under in vitro conditions, artificial saline solutions resembling the seminal plasma composition and 400 mosmol kg^?1 NaCl or glucose solutions were useful as motility inhibiting solutions for predilution of semen. Sperm motility was not affected by pH 7.5–9.0, but at pH 6 the motility rate and the swimming velocity were reduced; seminal fluid pH was 8.47 ± 0.02. Therefore buffering of the artificial saline solutions can provide more stabile conditions for semen during storage and activation. Temperature optimum of semen was between 2 and 5°C. At higher temperatures semen became spontaneously motile. Therefore, controlled temperature conditions are an important factor for handling of semen. The qualitative, organical composition of seminal fluid was similar as in other fresh water teleosts.     

Artificial insemination of ewes with frozen-thawed semen at a synchronised oestrus. 2. Effect of dose of spermatozoa and site of intrauterine insemination on fertility

Three experiments were conducted to examine the effect of dose of inseminate, number of uterine horns inseminated and site of insemination on subsequent fertility of Merino ewes after synchronisation of oestrus, with progestagen-impregnated sponges (inserted for 12 days) and an injection of PMSG, and intrauterine insemination with frozen-thawed semen.The percentages of ewes lambing after insemination with 0.5, 5, 25 and 50 × 10⁶ spermatozoa were 29.3, 26.8, 56.3 and 62.1% respectively. A similar trend was observed in a second test resulting in 23.5, 38.8 and 53.1% ewes lambing after insemination with 5, 10 and 20 × 10⁶ spermatozoa respectively.The percentage of ewes lambing was higher for ewes inseminated in two uterine horns than one horn (76.8 vs. 44.9, P < 0.001). When semen was deposited in the tip, middle and bottom of the uterine horn, the percentages of ewes lambing and lambs born per ewe inseminated were 43.6 and 52.7, 52.8 and 84.9, and 41.2 and 64.7% respectively. Although site of insemination did not affect the percentage of ewes lambing, the percentage of lambs born per ewe inseminated was higher after insemination in the middle of the uterine horn than at the other sites (P < 0.001).     

Cryopreservation of Atlantic salmon Salmo salar sperm: effects on sperm physiology

The objective of this study was to determine the effect of freezing on the function in Atlantic salmon Salmo salar spermatozoa. The semen was frozen in Cortland's medium + 1.3M dimethyl sulphoxide + 0.3M glucose + 2% bovine serum albumin (final concentration) in a ratio of 1:3 (semen:cryoprotectant) as the treatment (T) and fresh semen as the control (F). Straws of 0·5 ml of sperm suspension were frozen in 4 cm of N₂L. They were thawed in a thermoregulated bath (40° C). After thawing, the percentage of spermatozoa with fragmented DNA [transferase dUTP (deoxyuridine triphosphate) nick‐end labelling (TUNEL)], plasma membrane integrity (SYBR‐14/PI) and mitochondrial membrane potential (ΔΨMMit, JC‐1) were evaluated by flow cytometry and motility was evaluated by optical microscope under stroboscopic light. The fertilization rates of the control and treatment semen were tested at a sperm density of 1·5 × 10⁷ spermatozoa oocyte^?1, by observation of the first cleavages after 16 h incubation at 10° C. In the cryopreserved semen (T), the mean ± s.d . DNA fragmentation was 4·8 ± 2·5%; plasma membrane integrity 75·2 ± 6·3%; mitochondrial membrane potential 51·7 ± 3·6%; motility 58·5 ± 5·3%; curved line velocity (V_CL) 61·2 ± 17·4 µm s^?1; average‐path velocity (V_AP) 50·1 ± 17·3 µm s^?1; straight‐line velocity (V_SL) 59·1 ± 18·4 µm s^?1; fertilization rate 81·6 ± 1·9%. There were significant differences in the plasma membrane integrity, mitochondrial membrane potential, motility, fertilization rate, V_CL, V_AP and V_SL compared with the controls (P < 0·05). Also the mitochondrial membrane potential correlated with motility, fertilization rate, V_CL and V_SL (r = 0·75; r = 0·59; r = 0·77 and r = 0·79, respectively; P < 0·05); and the fertilization rate correlated with V_CL and V_SL (r = 0·59 and r = 0·55, respectively).     

Spermatogenic activities of the left and right testes of hemicastrated and intact cockerels

One hundred cockerels of the Hacco strain were reared in deep litter. At 5 weeks of age the left testes of 30 cockerels and right testes of another 30 cockerels were surgically removed. The remaining cockerels were sham operated. At 10, 15, 20 and 25 weeks of age equal numbers from each group were killed. The rate of testis growth, the spermatid/spermatozoa reserve for each genital tract, and the relative spermatogenic activity (i.e., spermatid/sperm per g of testicular tissue) were determined for the left and right testes at the different ages.At 10 weeks of age only spermatids were found in all the testes, with concomitant very low relative spermatogenic activities. The weights of the testes increased with age and compensatory hypertrophy occurred in the testes of the hemicastrates from 15 weeks of age. The mean of the sperm reserve of the left (7.391 × 10⁹ sperm) and right (8.66 × 10⁹ sperm) genital tracts of hemicastrates contained significantly more (P < 0.05) sperm than the sum of the means of the sperm reserves in the left and right genital tracts (5.19 × 10⁹sperm) of the intact cockerels at 25 weeks of age.The relative spermatogenic activities varied with age but the pattern was similar for all cockerels, with the activities of the testes of the hemicastrates being significantly higher (P < 0.5). In all cases the values for the right testes were higher than those for the corresponding left testes.At 15 weeks of age both spermatids and spermatozoa were found in 71.4% and 100% of the right and left testes of the hemicastrates, respectively, and in 25% of the left testes of the intact cockerels. Only spermatids were found in the right testes of the intact cockerels.Hemicastration caused the right testes of the hemicastrates to produce sperm earlier than those of intact cockerels. The left testes in all cases produced sperm earlier than the corresponding right testes. Hemicastration enhanced sperm numbers per g testes (i.e., relative spermatogenic activity).     

Availability of subfertile transgenic rats expressing the c-myc gene as recipients for spermatogonial transplantation

The spermatogonial transplantation system was applied to evaluate stem cell kinetics and niche quality and to produce gene-modified animals using the stem cells after homologous recombination-based selection. This study was designed to determine whether the transplanted spermatogonia were able to proliferate and differentiate in male rats expressing the c-myc transgene under control of the human metallothionein IIA promoter (MT-myc Tg rats). Donor testicular cells were prepared from heterozygous chicken beta actin (CAG)/enhanced green fluorescent protein (EGFP)-transgenic rats (EGFP Tg rats) during the second week after birth and injected into the seminiferous tubules of the MT-myc Tg rats (line-A and -B; both subfertile) or rats pretreated with busulfan to remove endogenous spermatogonia. Three to four months after transplantation, cell colonies with EGFP fluorescence were detected in 36% (4/11), 40% (8/20), and 71% (5/7) of the transplanted testes in line-A MT-myc Tg rats, line-B MT-myc Tg rats, and busulfan-treated rats, respectively. No EGFP-positive colonies were detected when wild-type male rats were used as recipients (0/7; testis-basis). The histopathological and immunofluorescent examination of the serial sections from the transplanted testes showed normal spermatogenesis of the donor spermatogonia, but atrophy of the recipient seminiferous tubules. Microinsemination with round spermatids and mature spermatozoa derived from EGFP-positive testes in line-A rats resulted 26% (10/39 transferred) and 23% (11/48 transferred) full-term offspring, respectively. Thus, the MT-myc Tg male rats were suitable as potent recipients for spermatogonial transplantation without any chemical pretreatment to remove the endogenous spermatogonia.