Applicability of an in-house Chelex-100 DNA isolation method for extracting genetic material from sterlet (Acipenser ruthenus) embryos

Abdel-Latif, A., Osman, G. (2017). Comparison of three genomic DNA extraction methods to obtain high DNA quality from maize. Plant Methods, 13(1), 1-9. Search in Google Scholar

Abouseadaa, H. H., Osman, G. H., Ramadan, A. M., Hassanein, S. E., Abdelsattar, M. T., Morsy, Y. B., Bahieldin, A. (2015). Development of transgenic wheat (Triticum aestivum L.) expressing avidin gene conferring resistance to stored product insects. BMC Plant Biology, 15, 183-190. Search in Google Scholar

Bobe, J. (2015). Egg quality in fish: Present and future challenges. Animal Frontiers, 5(1), 66-72. Search in Google Scholar

Boscari, E., Barmintseva, A., Pujolar, J. M., Doukakis, P., Mugue, N., Congiu, L. (2014). Species and hybrid identification of sturgeon caviar: a new molecular approach to detect illegal trade. Molecular Ecology Resources, 14, 489-498. Search in Google Scholar

Chandra, G., Fopp-Bayat, D. (2021). Trends in aquaculture and conservation of sturgeons: A review of molecular and cytogenetic tools. Reviews in Aquaculture, 13(1), 119-137. Search in Google Scholar

Claassen, S., du Toit, E., Kaba, M., Moodley, C., Zar, H. J., Nicol, M. P. (2013). A comparison of the efficiency of five different commercial DNA extraction kits for extraction of DNA from faecal samples. Journal of Microbiological Methods, 94(2), 103-110. Search in Google Scholar

Couch, J. A., Fritz, P. J. (1990). Isolation of DNA from Plants High in Polyphenolics, Plant Molecular Biology Reports, 8(1): 8-12. Search in Google Scholar

Di Pinto, A., Forte, V., Guastadisegni, M. C., Martino, C., Schena, F. P., Tantillo, G. (2007). A comparison of DNA extraction methods for food analysis. Food Control, 18(1), 76-80. Search in Google Scholar

Dittrich-Schrodero, G., Wingfield, M.J., Klein, H., Slippers, B. (2012). DNA extraction techniques for DNA barcoding of minute gall-inhabiting wasps. Molecular Ecology Resources, 12, 109-115. Search in Google Scholar

Fatira, E., Havelka, M., Labbe, C., Depince, A., Iegorova, V., Psenicka, M., Saito, T. (2018). Application of interspecific Somatic Cell Nuclear Transfer (iSCNT) in sturgeons and an unexpectedly produced gynogenetic sterlet with homozygous quadruple haploid. Scientific Reports, 8, 1-11. Search in Google Scholar

Fopp-Bayat, D. (2007). Verification of meiotic gynogenesis in Siberian sturgeon (Acipenser berii Brandt) using microsatellite DNA and cytogenetical markers. Journal of Fish Biology, 71, 478-485. Search in Google Scholar

Fopp-Bayat, D., Kuzniar, P., Kolman, R., Liszewski, T., Kucinski, M. (2015). Genetic analysis of six sterlet (Acipenser ruthenus) populations-recommendations for the plan of restitution in the Dniester River. Iranian Journal of Fisheries Sciences, 14(3), 634-645. Search in Google Scholar

Fredricks, D. N., Smith, C., Meier, A. (2005). Comparison of six DNA extraction methods for recovery of fungal DNA as assessed by quantitative PCR. Journal of Clinical Microbiology, 43(10), 5122-5128. Search in Google Scholar

Garrick, R. C., Bonatelli, I. A., Hyseni, C., Morales, A., Pelletier, T. A., Perez, M. F., Rice, E., Satler, J. D., Symula, R. E., Thome, M. T. C., Carstens, B. C. (2015). The evolution of phylogeographic datasets. Molecular Ecology, 24, 1164-1171. Search in Google Scholar

Guo, W., Jiang, L., Bhasin, S., Khan, S. M., Swerdlow, R. H. (2009). DNA extraction procedures meaningfully influence qPCR-based mtDNA copy number determination. Mitochondrion, 9, 261-265. Search in Google Scholar

Hajibabaei, M., Dewaard, J. R., Ivanova, N. V., Ratnasingham, S., Dooh, R. T., Kirk, S. L., Mackie, P. M., Hebert, P. D. (2005). Critical factors for assembling a high volume of DNA barcodes. Philosophical Transactions of the Royal Society B: Biological Sciences, 360, 1959-1967. Search in Google Scholar

Havelka, M., Fujimoto, T., Hagihara, S., Adachi, S., Arai, K. (2017). Nuclear DNA markers for identification of Beluga and Sterlet sturgeons and their interspecific Bester hybrid. Scientific Reports, 7, 1-8. Search in Google Scholar

Holden, M., Blasic, J., Bussjaeger, L., Kao, C., Shokere, L., Kendall, D., Freese, L., Jenkins, G. (2003). Evaluation of extraction methodologies for corn kernel (Zea mays) DNA for detection of trace amounts of biotechnology-derived DNA. Journal of Agricultural and Food Chemistry, 51, 2468-2474. Search in Google Scholar

Huang, K., Ritland, K., Dunn, D. W., Qi, X., Guo, S., Li, B. (2016). Estimating relatedness in the presence of null alleles. Genetics, 202(1), 247-260. Search in Google Scholar

Kashiwagi, T., DeLonay, A. J., Braaten, P. J., Chojnacki, K. A., Gocker, R. M., Heist, E. J. (2020). Improved genetic identification of acipenseriform embryos with application to the endangered pallid sturgeon Scaphirhynchus albus. Journal of Fish Biology, 96, 486-495. Search in Google Scholar

Khosravinia, H., Murthy, H.N., Parasad, D.T., Pirany, N. (2007). Optimizing factors influencing DNA extraction from fresh whole avian blood. African Journal of Biotechnology, 6, 481-486. Search in Google Scholar

Korentovich, M., Litvinenko, A. (2018). Artificial production of siberian sturgeon fingerlings for restocking the Siberian Rivers of the Ob’- Irtysh Basin: A Synthesis. In: The Siberian Sturgeon (Acipenser baerii Brandt 1869) (Ed.) P. Williot, G. Nonnotte, M. Chebanov, Farming Springer International Publishing, Volume 2, Cham: 181-216. Search in Google Scholar

Ludwig, A. (2006). A sturgeon view on conservation genetics. European Journal of Wildlife Research, 52, 3-8. Search in Google Scholar

Maqsood, H.M., Ahmad, S.M. (2017). Advances in molecular markers and their applications in aquaculture and fisheries. Genetics of Aquatic Organisms, 1(1), 27-41. Search in Google Scholar

McQuown, E. C., Sloss, B. L., Sheehan, R. J., Rodzen, J., Tranah, G. J., May, B. (2000). Microsatellite analysis of genetic variation in sturgeon: new primer sequences for Scaphirhynchus and Acipenser. Transactions of the American Fisheries Society, 129, 1380-1388. Search in Google Scholar

Park, C., Lee, S. Y., Kim, D. S., Nam, Y. K. (2013). Embryonic development of Siberian sturgeon Acipenser baerii under hatchery conditions: An image guide with embryological descriptions. Fisheries and Aquatic Sciences, 16, 15-23. Search in Google Scholar

Psenicka, M., Saito, T., Linhartova, Z., Gazo, I. (2015). Isolation and transplantation of sturgeon early-stage germ cells. Theriogenology, 83, 1085-1092. Search in Google Scholar

Ruggeri, P., Splendiani, A., Di Muri, C., Fioravanti, T., Santojanni, A., Leonori, I., ... Caputo Barucchi, V. (2016). Coupling demographic and genetic variability from archived collections of European anchovy (Engraulis encrasicolus). PloSone, 11(3), e0151507. https://doi.org/1-0.1371/journal.pone.0151507 Search in Google Scholar

Schiebelhut, L.M., Abboud, S.S., Gómez Daglio, L.E., Swift, H.F., Dawson, M. N. (2017). A comparison of DNA extraction methods for high-throughput DNA analyses. Molecular Ecology Resources, 17(4), 721-729. Search in Google Scholar

Wakchaure, R., Ganguly, S., Qadri, K., Praveen, P. K., Mahajan, T. (2015). Importance of transgenic fish to global aquaculture: a review. Fisheries and Aquaculture Journal, 6(04), 8-11. Search in Google Scholar

Yalçınkaya, B., Yumbul, E., Mozioğlu, E., Akgoz, M. (2017). Comparison of DNA extraction methods for meat analysis. Food Chemistry, 221, 1253-1257. Search in Google Scholar

Yue, G.H., Wang, L. (2017). Current status of genome sequencing and its applications in aquaculture. Aquaculture, 468, 337-347. Search in Google Scholar

Zetzsche, H., Klenk, H. P., Raubach, M. J., Knebelsberger, T., Gemeinholzer, B. (2008). Comparison of methods and protocols for routine DNA extraction in the DNA Bank Network. In: Systematics (Ed.) R. Gradstein, S. Klatt, F. Normann, P. Weigelt, R. Willmann, R. Wilson, Universitätsverlag Göttingen, Göttingen Germany: 354. Search in Google Scholar

Zhang, X., Wu, W., Li, L., Ma, X., Chen, J. (2013). Genetic variation and relationships of seven sturgeon species and ten interspecific hybrids. Genetics Selection Evolution, 45, 21. Search in Google Scholar