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Vetokh A.N., Volkova L.A., Iolchiev B.S., Tomgorova E.K., Volkova N.A. Genetic modification of roosters' germ cells using various methodological approaches. Sel'skokhozyaistvennaya Biologiya [Agricultural Biology], 2020, Vol. 55, № 2, p. 306-314.
(how to cite this article)

doi: 10.15389/agrobiology.2020.2.306eng

UDC: 636.52/.58:575.2.084:577.21:57.086.86

Supported financially by Russian Foundation for Basic Research, grant No. 18-29-07079 and the Ministry of Science and Higher Education of Russia, theme No. АААА-А18-118021590132-9.

 

GENETIC MODIFICATION OF ROOSTERS’ GERM CELLS USING VARIOUS METHODOLOGICAL APPROACHES

A.N. Vetokh, L.A. Volkova, B.S. Iolchiev, E.K. Tomgorova, N.A. Volkova

Ernst Federal Science Center for Animal Husbandry,60, pos. Dubrovitsy, Podolsk District, Moscow Province, 142132 Russia, e-mail anastezuya@mail.ru (✉ corresponding author), ludavolkova@inbox.ru, baylar1@mail.ru, tomgorova@rambler.ru, natavolkova@inbox.ru

ORCID:
Vetokh A.N. orcid.org/0000-0002-2865-5960
Tomgorova E.K. orcid.org/0000-0001-5398-8815
Volkova L.A. orcid.org/0000-0002-9407-3686
Volkova N.A. orcid.org/0000-0001-7191-3550
Iolchiev B.S. orcid.org/0000-0001-5386-726

Received January 13, 2020

 

Gonad germ cells of male farm birds are considered as promising target cells for introducing recombinant DNA for the purpose of targeted genetic modification of their genome. Germ cell precursors (primordial germ cells and spermatogonia cells) are of most interest for modifications. The transplantation of these transformed cells and their successful colonization in the gonads of recipient individuals would allow a population of transformed mature germ cells — sperm — to be obtained, which can be used for female insemination in order to obtain transgenic offspring. The results of studies on the genetic modification of rooster germ cells by transfection of primordial germ cells in embryos and spermatogenous cells in the testes were presented in this work. The novelty of the research consists in the development and optimization of individual stages of local transformation in roosters’ spermatogenic cells in vivo to obtain a genetically modified sperm. Our aim was to evaluate the effectiveness of the genetic transformation in roosters’ germ cells using various methodological approaches. The study was carried out with poultry (Gallus gallus domesticus) of the Russian White breed. Primordial germ cells were isolated from 6-day-old embryos. The resulting culture of PGCs was transformed by electroporation using the Neon system (Thermo Fisher Scientific, USA). For transfection, the ZsGreen1-N1 plasmid (Addgene, USA) with the ZsGreen gene under the CMV promoter was used. Transformed cells in the amount of 400, 700 and 1000 were introduced into the dorsal aorta of 2.5-day-old embryos. The embryos of the control group were injected with DMEM growth medium in the dorsal aorta. To transform spermatogenic cells in vivo, a viral preparation was used, which was injected directly into the testes of roosters by multiple injection. The introduction of the viral drugs was carried out once at the age of 3 or 4 months and twice at the age of 3 and 4 months. The viral preparation at a concentration of 1×107 CFU/ml was introduced at the rate of 0.5 ml per testis. The lentiviral vector contained the ZsGreen reporter gene under the CMV promoter. Histological sections of the testes from experimental males were obtained and analyzed to assess the efficiency of colonization and development of donor primordial germ cells (PGCs) in the gonads of recipients, as well as to evaluate the effectiveness of spermatogenic cell transformation in vivo. As a control, we used histological sections of the testes from non-transgenic roosters, selected on the basis of analogues (age, breed). The fertilizing ability of the sperm from experimental roosters and the proportion of embryos with ZsGreen gene expression were evaluated. The transformation efficiency of target cells was determined by expression of the ZsGreen reporter gene using a Nikon Ni-U microscope (Nikon, Japan). The chicken embryonic cell culture obtained in the first stage of the experiment consisted of the several types of cells. The proportion of PGCs did not exceed 3 %. The percentage of PGCs in the cell suspension increased to 81 % after separating the different types of embryonic cells by adhesion. The cell culture transformation efficiency of PGCs was 12 %.The presence of fluorescent spermatogenic cells in the testes seminiferous tubules was established both with the introduction of transformed donor PGCs and with a lentiviral vector. With the introduction of donor PGCs at a concentration of 400, 700 and 1000 cells per embryo, the percentage of chickens with transformed germ cells was 16 %, 23 % and 26 %, respectively. With the twofold introduction of the viral drug into the testes at the age of 3 and 4 months, the highest transformation efficiency of spermatogenic testicular cells in vivo was established, which amounted to 10 %. With a single injection of the viral drug, this indicator was 2 times lower. The possibility of using the obtained individuals with transformed germ cells to obtain transgenic offspring is shown. The efficiency of obtaining transgenic embryos is 6-10 %.

Keywords: roosters, embryos, primordial germ cells, spermatogenic cells, lentiviral vector, transgenesis.

 

REFERENCES

  1. Olive V., Cuzin F. The spermatogonial stem cell: from basic knowledge to transgenic technology. The International Journal of Biochemistry & Cell Biology, 2005, 37(2): 246-250 CrossRef
  2. Han J.Y. Germ cells and transgenesis in chickens. Comparative Immunology, Microbiology and Infectious Diseases, 2009, 32(2): 61-80 CrossRef
  3. Chojnacka-Puchta L., Kasperczyk K., Płucienniczak G., Sawicka D., Bednarczyk M. Primordial germ cells (PGCs) as a tool for creating transgenic chickens. Polish Journal of Veterinary Sciences, 2012, 15(1): 181-188 CrossRef
  4. Macdonald J., Glover J.D., Taylor L., Sang H.M., McGrew M.J. Characterisation and germline transmission of cultured avian primordial germ cells. PLoS ONE, 2010, 5(11): e15518 CrossRef
  5. Zheng Y., Zhang Y., Qu R., He Y., Tian X., Zeng W. Spermatogonial stem cells from domestic animals: progress and prospects. Reproduction, 2014, 147(3): 65-74 CrossRef
  6. Li B., Sun G., Sun H., Xu Q., Gao B., Zhou G., Zhao W., Wu X., Bao W., Yu F., Wang K., Chen G. Efficient generation of transgenic chickens using the SSCs in vivo and ex vivo transfection. Science China Series C: Life Sciences, 2008, 51: 734-742 CrossRef
  7. Cooper C.A., Challagulla A., Jenkins K.A., Wise T.G., O’Neil T.E., Morris K.R., Tizard M.L., Doran T.J. Generation of gene edited birds in one generation using sperm transfection assisted gene editing (STAGE). Transgenic Res., 2017, 26: 331-347 CrossRef
  8. Takashima S. Biology and manipulation technologies of male germline stem cells in mammals. Reproductive Medicine and Biology, 2018, 17(4): 398-406 CrossRef
  9. Nakamura Y., Usui F., Miyahara D., Mori T., Ono T., Takeda K., Nirasawa K., Kagami H., Tagami T. Efficient system for preservation and regeneration of genetic resources in chicken: concurrent storage of primordial germ cells and live animals from early embryos of a rare indigenous fowl (Gifujidori). Reproduction, Fertility and Development, 2010, 22(8): 1237-1246 CrossRef
  10. Tyack S.G., Jenkins K.A., O’Neil T.E., Wise T.G., Morris K.R., Bruce M.P., McLeod S., Wade A.J., McKay J., Moore R.J., Schat K.A., Lowenthal J.W., Doran T.J. A new method for producing transgenic birds via direct in vivo transfection of primordial germ cells. Transgenic Research, 2013, 22(6): 1257-1264 CrossRef
  11. Yu F., Ding L.-J., Sun G.-B., Sun P.-X., He X.-H., Ni L.-G., Li B.-C. Transgenic sperm produced by electrotransfection and allogeneic transplantation of chicken fetal spermatogonial stem cells. Molecular Reproduction and Development, 2010, 77(4): 340-347 CrossRef
  12. Hong Y.H., Moon Y.K., Jeong D.K., Han J.Y. Improved transfection efficiency of chicken gonadal primordial germ cells for the production of transgenic poultry. Transgenic Research, 1998, 7(4): 247-252 CrossRef
  13. Macdonald J., Taylor L., Sherman A., Kawakami K., Takahashi Y., Sang H. M., McGrew M.J. Efficient genetic modification and germ-line transmission of primordial germ cells using piggyBac and Tol2 transposons. Proceedings of the National Academy of Sciences, 2012, 109(23): E1466-E1472 CrossRef
  14. Li B., Sun G., Sun H., Xu Q., Gao B., Zhou G., Zhao W., Wu X., Bao W., Yu F., Wang K., Chen G. Efficient generation of transgenic chickens using the spermatogonial stem cells in vivo and ex vivo transfection. Science China Series C: Life Sciences, 2008, 51(8): 734-742 CrossRef
  15. Scott B.B., Velho T.A., Sim S., Lois C. Applications of avian transgenesis. ILAR Journal, 2010, 51(4): 353-361 CrossRef
  16. Kalina J., Šenigl F., Mičáková A., Mucksová J., Blažková J., Yan H., Poplštein M., Hejnar J., Trefil P. Retrovirus-mediated in vitro gene transfer into chicken male germ line cells. Reproduction, 2007, 134(3): 445-453 CrossRef
  17. Allioli N., Thomas J.-L., Chebloune Y., Nigon V.-M., Verdier G., Legras C. Use of retroviral vectors to introduce and express the β-galactosidase marker gene in cultured chicken primordial germ cell. Developmental Biology, 1994, 165(1): 30-37 CrossRef
  18. Dobrinski I., Avarbock M.R., Brinster R.L. Germ cell transplantation from large domestic animals into mouse testes. Molecular Reproduction and Development, 2000, 57(3): 270-279 CrossRef
  19. Brinster R.L. Germline stem cell transplantation and transgenesis. Science, 2002, 296(5576): 2174-2176 CrossRef
  20. Honaramooz A.1., Megee S.O., Dobrinski I. Germ cell transplantation in pigs. Biology of Reproduction, 2002, 66(1): 21-28 CrossRef
  21. Kim B.-G., Kim Y.-H., Lee Y.-A., Kim B.-J., Kim K.-J., Jung S.-E., Chung H.-J., Hwang S., Choi S.-H., Kim M.J., Kim D.-H., Kim I.C., Kim M.K., Kim N.-H., Kim C.G., Ryu B.-Y. Production of transgenic spermatozoa by lentiviral transduction and transplantation of porcine spermatogonial stem cells. Tissue Engineering and Regenerative Medicine, 2014, 11(6): 458-466 CrossRef
  22. Rodriguez-Sosa J.R., Dobson H., Hahnel A. Isolation and transplantation of spermatogonia in sheep. Theriogenology, 2006, 66(9): 2091-2103 CrossRef
  23. Honaramooz A., Behboodi E., Megee S.O., Overton S.A., Galantino-Homer H., Echelard Y., Dobrinski I. Fertility and germline transmission of donor haplotype following germ cell transplantation in immunocompetent goats. Biology of Reproduction, 2003, 69(4): 1260-1264 CrossRef
  24. Oatley J.M. Spermatogonial stem cell biology in the bull: development of isolation, culture, and transplantation methodologies and their potential impacts on cattle production. Bioscientifica Proceedings, 2019, 7 RDRRDR10 CrossRef
  25. Trefil P., Bakst M.R., Yan H., Hejnar J., Kalina J., Mucksová J. Restoration of spermatogenesis after transplantation of c-Kit positive testicular cells in the fowl. Theriogenology, 2010, 74(9): 1670-1676 CrossRef
  26. Benesova B., Mucksova J., Kalina J., Trefil P. Restoration of spermatogenesis in infertile male chickens after transplantation of cryopreserved testicular cells. British Poultry Science, 2014, 55(6): 837-845 CrossRef
  27. Kim Y.M., Park J.S., Yoon J.W., Choi H.J., Park K.J., Ono T., Han J.Y. Production of germline chimeric quails following spermatogonial cell transplantation in busulfan-treated testis. Asian Journal of Andrology, 2018, 20(4): 414-416 CrossRef
  28. Naito M., Harumi T., Kuwana T. Long term in vitro culture of chicken primordial germ cells isolated from embryonic blood and incorporation into germline of recipient embryo. The Journal of Poultry Science, 2010, 47(1): 57-64 CrossRef
  29. Sawicka D., Chojnacka-Puchta L. Effective transfection of chicken primordial germ cells (PGCs) using transposon vectors and lipofection. Folia Biologica, 2019, 67(1): 45-52 CrossRef
  30. Min S., Qing S.Q., Hui Y.Y., Zhi F.D., Rong Q.Y., Feng X., Chun L.B. Generation of antiviral transgenic chicken using spermatogonial stem cell transfected in vivo. African Journal of Biotechnology, 2011, 10(70): 15678-15683 CrossRef

 

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