Development of novel strategies for the isolation of piglet testis cells with a high proportion of gonocytes
Yanfei Yang A , Mehran Yarahmadi A and Ali Honaramooz A BA Department of Veterinary Biomedical Sciences, Western College of Veterinary Medicine, University of Saskatchewan, 52 Campus Drive, Saskatoon, Saskatchewan S7N 5B4, Canada.
B Corresponding author. Email: ali.honaramooz@usask.ca
Reproduction, Fertility and Development 22(7) 1057-1065 https://doi.org/10.1071/RD09316
Submitted: 31 December 2009 Accepted: 6 February 2010 Published: 20 August 2010
Abstract
Gonocytes have germline stem cell potential and are present in the neonatal testis, comprising 5–10% of freshly isolated testis cells. Maximising the number and proportion of gonocytes among freshly isolated testis cells will greatly facilitate their subsequent purification and in vitro study and manipulation. Seven experiments were conducted to evaluate the effects of multiple factors on the efficiency of testis cell isolation from neonatal pigs. We found that the use of a lysis buffer led to elimination of erythrocytes without adversely affecting testis cell isolation. Approximately ninefold as many live cells could be harvested by enzymatic digestion of testis tissues compared with mechanical methods. Digestion with collagenase–hyaluronidase–DNase followed by trypsin resulted in the highest recovery of live cells. However, the proportion of gonocytes (∼7%) did not differ between the mechanical and enzymatic methods of testis cell isolation. Pretreatment of the tissue with cold enzymes increased the recovery of live testis cells. New strategies of combining a gentle enzymatic digestion with two rounds of vortexing resulted in the isolation of testis cells with very high gonocyte proportion. The efficiency of these novel methods could be further optimised to collect testis cells with a gonocyte proportion of approximately 40%. This novel three-step testis cell isolation strategy can be completed within 1 h and can harvest approximately 17 × 106 live gonocytes per g testis tissue. Therefore, in addition to elucidating the effects of several factors on testis cell isolation, we developed a novel strategy for the isolation of testis cells that yielded approximately 40% gonocytes in the freshly isolated cells (i.e. four- to eight-fold higher than the proportions obtained using current strategies). This strategy has instant applications in the purification of gonocytes.
Additional keywords: enzymatic cell isolation, pig, spermatogonial stem cell.
Acknowledgements
The authors thank Brian Andries and his staff, especially Margot Meiklejohn, at the Prairie Swine Center Inc. (Saskatoon, SK, Canada), Mahsa Abrishami for technical assistance, Dr Murray Woodbury for critical review of the manuscript, the University of Saskatchewan Colleges of Graduate Studies and Veterinary Medicine for scholarships (to Y.Y.) and the Natural Sciences and Engineering Research Council (NSERC) of Canada for grants (to A.H.) to support this project.
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