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BIOTROPIA  NO. 23, 2004 : 40 - 46 

PRESERVATION OF GARUT RAMS SPERMATOZOON AS A SOURCE                                         
OF MALE GERM PLASM 

ARIEF BOEDIONO'*, HERDISU, and MUHAMMAD RIZAL' 

'Faculty of Veterinary Medicine, Bogor Agricultural University, Bogor 16680, Indonesia 
2 Center for the Assessment and Application of Farming Technology, Agency for the 

Assessment and Application of Technology, Jakarta, Indonesia 

ABSTRACT 

This study was conducted to examine the quality of ejaculated sperm by Garut rams to be used for artificial 
insemination (AI) and viability of sperm that were collected from preserved cauda epididymis (4°C up to 12 days) for 
assisted reproductive technology. The semen was collected by artificial vagina, with the sperm motility, live sperm, 
acrosomal intact, and intact plasma membrane observed. Sperm motility was 75%, while for the live sperm, intact plasma 
membrane and sperm abnormality were 91.5%, 90.0%, and 1.8%, respectively. In the other study, sperm was collected 
from cauda epididymis by aspiration method and diluted in different media: 1) Brackett Oliphant (BO) media and 2) 
modified Phosphate Buffer Saline (mPBS). Evaluation of sperm motility and intact plasma membrane were 
conducted after washing, counting and dilution of the sperm. The results of this study showed that the sperm motility and 
intact plasma membrane could be maintained better in BO rather than PBS medium although they were not statistically 
different (P>0.05). At day 12 of preservation, the motility and intact plasma membrane of sperm collected from cauda 
epididymis were 0.7% and 1.33% for motility and plasma membrane intact, respectively. These findings showed that the 
Garut rams semen was qualified for AI and frozen processing; in vitro embryo production by introducing the assisted 
reproductive technology such as intracytoplasmic sperm injection (ICSI) could be applied by using the sperm collected from 
preserved cauda epididymis until 12 days of preservation at 4°C. 

Keywords :   Reproduction/spcrmatogenesis/inscmination/Garut rams/small ruminant 

INTRODUCTION 

Indonesia is a country with tremendous amounts of genetic resources and biodiversity. In 
Indonesia, the percentage of meat and wool produced by sheep as a small ruminant in West Java 
Province is approximately 46.2% (Anonymous 1999). One of the ruminants is Garut sheep, 
endemic to Indonesia, and potential for meat production. Moreover, they have a good 
performance for sheep contest. The population of Garut sheep decreased from 7.6 million in 1997 
to 7.2 million in 2001. 

In an attempt to increase the Garut sheep population, several efforts should be done to 
maintain the population. Application of reproduction biotechnology such as artificial insemination 
(AI) and in vitro embryo production are the solutions. Artificial insemination has been routinely 
done in large ruminants such as cattle and 

* Correspondence: Arief Boediono, Lab. of Embryology, Dept. of Anatomy, Fac. of Veterinary Medicine Bogor 
AgriculturalUniversity, Jalan Agatis, IPB Campus Darmaga, Bogor 16680, Indonesia. E-mail: abl@cbn.net.id 

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BIOTROPIA NO. 23, 2004 

buffaloes. However, in small ruminants like sheep and goat this technique should be modified 
according to the small size of the reproductive tract. Sperm usually was collected from 
ejaculation for artificial insemination procedure. Collected sperms were then diluted for fresh 
sperm insemination, sperm preservation or sperm cryopreservation. In the case of dead ram, 
sperm was collected from cauda epididymis. 

Epididymal sperm may be the last chance to ensure preservation of genetic materials after 
injury or death of a valuable male. Studies have been conducted to determine if epididymal 
sperm can be used to produce viable embryos and offsprings. Iwamatsu and Chang (1971) 
have reported successful fertilization of mouse oocytes using epididymal sperm. Fuller and 
Whittingham (1996) reported the production of normal mouse fetuses after IVF using epididymal 
sperm that had been cooled at 4°C. Sperm collected from the caudal epididymides has been used for 
both IVF and intracytoplasmic sperm injection (ICSI) in domestic cats (Pope et al. 1998). Caprine 
epididymal sperm has also been reported for use in the production of IVF embryos to the 
blastocyst stage (Song and Iritani 1988), and production of an IVF goat offspring born from 
artificial insemination (Slash et al. 2000). 

From recent studies, viable epididymal sperm can be harvested post-mortem for possible 
use in assisted reproductive technologies (ART). Most of the species evaluated so far, produce 
more viable sperm when the testicles are stored at 4°C, prior to harvesting the epididymal sperm. 
The objective of this study was to identify an alternative to collect ovine ejaculate and 
epididymal sperm for subsequent fertilization. 

MATERIALS AND METHODS 

Sperm Collection 

Ejaculated sperm. Sperm ejaculate was collected from 5 healthy Garut rams by using 
artificial vagina. The artificial vagina consists of a hose 20 to 25 cm in length and 5 to 7 cm in 
diameter, with a rubber liner. The temperature of artificial vagina was set between 42 to 46°C, and 
it is necessary to lubricate it with K-Y jelly. At the time of the ram mounts to the ewe, his penis 
was gently guided inside the artificial vagina connected with a warm tube (37°C) to avoid the 
cold shock. After ejaculation, the tube containing the semen was removed and placed in a water 
bath at 30°C. 

Testicle Preservation 

Ovine testicles were collected as pairs from mature rams from a slaughterhouse. One pair 
of testicle (control testicle) was processed shortly after the rams were slaughtered (day-0), 
while the other testicle of the pair was processed and stored at 4°C up to 12 days of preservation. 
Collected sperms were evaluated daily. 

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                   Preservation of garut rams spermatozoon - Arief Boediono and Muhammad Rizal 

Epididymal sperm. After storage at 4°C, each testicle was allowed to warm at room 
temperature (25°C) for not more than 30 minutes. During this warming period, the testicle was 
dissected away from the connecting tissues. Sperm dilution media (Bracket! and Oliphant, BO 
and modified phosphate buffer saline, mPBS) were warmed in water bath to 37°C prior to 
exposure to the epididymal sperm. Sperm was collected from the cauda epididymis region by 
aspiration method. Briefly, sperm was collected by aspiration using 21G needle connected to 3 ml 
spuit already filled with 1 ml warmed dilution media. Collected sperm was then washed by 
centri-fugation at 500G for 3 minutes to create sperm pellet. The supernatant was discarded and the 
pellet was resuspended in sperm dilution media. 

Evaluation 

The volume of ejaculated sperm was recorded in each collection. Microscopic evaluation of 
the sperm was done including the sperm concentration, motility, percentage of live sperm, intact 
plasma membrane, and morphology. For epididymal sperm, analysis was done on percentage of 
sperm motility and intact plasma membrane. 

An evaluation of live and dead sperm was done by eosin-negrosin staining. The appearing red 
sperms were considered dead, otherwise they are alive. The sperm which had an intact plasma 
membrane was shown by coiled sperm tail after incubation in hypo-osmotic solution at 37°C for 30 
min (Correa and Zavos 1994). Hypo-osmotic solution contained 0.032 M NaCl in destilled water. 

Data were analyzed using the simple one-way ANOVA to make comparisons between 
testicle pairs and Duncan's test to identify the difference in means between the treatment groups. 

RESULTS AND DISCUSSION 

Ejaculated sperm was successfully collected from 5 rams. The mean number of Garut ram 
ejaculated sperm was 3463 x 106 sperm rnL"', with the average volume of semen per ejaculation of 
0.7 mL (Table 1). By comparison, the volume of semen per ejaculation was 1.7 mL in St. Croix 
sheep (Feradis 1999), and 1.05 mL in Suffolk sheep (Boland et.al. 1985). The difference had 
correlation with individual factors such as age, body weight, and breed (Hafez and Hafez 2000). 

The motility and percentage of live sperm of Garut ram ejaculation were 75.0% and 91.5%, 
respectively. These-results were higher than that reported previously in St. Croix (64.0% and 
76.0% for motility and percentage of live sperm, respectively) (Sirman and Situmorang 1987). 

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BIOTROPIA NO. 23, 2004 

The percentage of intact plasma membrane of Garut ram ejaculated sperm was 90.0%. This 
was higher than the percentage of intact plasma membrane of St. Croix sheep ejaculated sperm i.e. 
86.3% (Feradis 1999). When sperm was exposed to hypo-osmotic solution, the spermatozoa that 
had intact plasma membrane would be swollen. If the sperm have intact plasma membrane, the 
water that influx into the cell could not come out from the cell. The percentage of intact plasma 
membrane had positive correlation with sperm motility. 

No single test accurately predicted fertility of a sperm sample; however, examining 
various physical characteristics of semen could determine greater fertility potential. Processing 
semen for artificial insemination or sperm freezing depends on semen quality. Analysis of ram 
semen involves obtaining maximum information about the physiology status of testicular and 
epididymis functions by examining one or several ejaculations. In general, the minimal 
requirements for semen processing (fresh or frozen semen) would include: at least 65% motility, 
concentration 700 x 106 sperm mL"', and less than 20% morphological abnormalities (Hafez and 
Hafez 2000). 

Motility and intact plasma membrane of sperm collected from cauda epididymis could be 
found up to 24 hours of incubation in vitro both in mPBS or BO medium. At the time of 
collection sperm motility was 58.0% in mPBS medium and 55.7% in BO medium. They decreased 
gradually during the in vitro incubation up to 24 hours (0.3% in mPBS and 0.6% in BO 
medium) (Figure 1). Intact plasma membrane of sperm collected from cauda epididymis was 
60.0% in mPBS and 56.7% in BO medium at the time of sperm collection. The intact plasma 
membrane in both media during in vitro incubation exhibited a declining pattern, as with sperm 
motility. However, the intact plasma membrane was higher than sperms motility after 18 hours 
of incubation. This was shown by some of the immotile sperm that had intact plasma 
membrane. In this case, spermatozoa may be used for in vitro fertilization by injection of single 
sperm directly into the oocyte cytoplasm called intracytoplasmic sperm injection (ICSI). 

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Preservation of garut rams spermatozoon — Aricf Boediono and Muhammad Rizal 

 1812 Incubation 
Incubation Period (hours)

60.0 ■ Mot mPBS    

Q Mot BO 

□Q MPI 

□mPBS Q 

  

Figure 1. Motility and intact plasma membrane of sperm collected from cauda epididymis after incubation in vitro 
in different medium. Mot mPBS: sperm motility in mPBS medium, Mot BO: sperm motility in BO medium; 
MPI mPBS: intact plasma membrane of sperm in mPBS medium, MPI BO: intact plasma membrane in BO 
medium. 

The sperm motility and intact plasma membrane of sperm collected from cauda 
epididymis decreased significantly after 2 days of preservation at 4°C. However, 0.7% motile 
sperm and 1.3% sperm with intact plasma membrane were found after 12 days of preservation 
(Figure 2). 

According to motility and live sperm, Rizal et al. (2004) reported that sperm collected from 
testicles after 3 days of preservation at 5°C could be used for artificial insemination or in vitro 
embryo production of sheep. Epididymal sperm was used in a goat in vitro embryo production 
that resulted in cleavage and development of blastocyst, although none of the blastocysts were 
transfered to the recipients (Song and Iritani 1988). Further work is needed to optimize the in vitro 
embryo production, through micro-fertilization procedure. The valuable sperm has the ability to 
fertilize the oocytes and, therefore, could increase the chances of propagating valuable 
genetics. 

Intracytoplasmic sperm injection (ICSI) could initiate the early embryo development to 
cleavage in goat oocyte (Boediono 2001). Moreover, Cochran et al. (1998) reported that live 
IVF offsprings from oocyte donor mares have been produced by using ICSI procedure. 
Although there has been some success using assisted reproductive technologies, more 
researches are needed to improve the efficiency of the procedures. 

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CONCLUSIONS 

These results indicate that Garut rams semen was qualified for AI and frozen processing, and 
motile sperm can still be collected from cauda epididymis after being stored at 4°C up to 12 days. 
Sperm cooled in the testicle at 4°C could be used in assisted reproductive technologies 
(intracytoplasmic sperm injection) for the untimely death of a valuable sheep and an effective tool 
to conserve important genetic resources. This study investigated the standard parameter of sperm 
analysis. It would stand to reason that further investigations with particular emphasis on chromatin 
damage and/or fertility are suggested. 

ACKNOWLEDGEMENTS 

We would like to thank Lesan Putra Breeding Farm, Bogor for providing the Garut rams. 
This research was partly financed by SEAMEO-BIOTROP FY 2003, No.l05/Res/III/2003. 

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              Preservation of garut rams spermatozoon - Arief Boediono and Muhammad Rizal 

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