Research Article
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Year 2017, Volume: 22 Issue: 2, 243 - 252, 15.12.2017
https://doi.org/10.17557/tjfc.357426

Abstract

References

  • Abdullaev, F.I. 2002. Cancer chemopreventive and tumoricidal properties of saffron (Crocus sativus L.). Exp biol med. 227(1): 20-25.
  • Alavi-Kia, S., S. Mohammadi, S. Aharizad and M. Moghaddam. 2008. Analysis of genetic diversity and phylogenetic relationships in Crocus genus of Iran using inter-retrotransposon amplified polymorphism. Biotechnol Biotec Eq. 22 (3): 795-800.
  • Alsayied, N.F., J.A. Fernández, T. Schwarzacher and J. Heslop-Harrison. 2015. Diversity and relationships of Crocus sativus and its relatives analysed by inter-retroelement amplified polymorphism (IRAP). Ann Bot-London. 116(3): 359-368.
  • Andeden, E.E., F.S. Baloch, M. Derya, B. Kilian and H. Ozkan. 2013. iPBS-Retrotransposons-based genetic diversity and relationship among wild annual Cicer species. J Plant Biochem Biot. 22(4): 453-466.
  • Arslan, N., A. Ozer and R. Akdemir. 2007. Cultivation of saffron (Crocus sativus L.) and effects of organic fertilizers to the flower yield. Paper read at I International Medicinal and Aromatic Plants Conference on Culinary Herbs. 826.
  • Babaei, S., M. Talebi, M. Bahar and H. Zeinali. 2014. Analysis of genetic diversity among saffron (Crocus sativus) accessions from different regions of Iran as revealed by SRAP markers. Sci Hortic-Amsterdam. 171: 27-31.
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  • Baloch, F.S., M. Derya, E.E. Andeden, A. Alsaleh, G. Comertpay, B. Kilian and H. Ozkan. 2015b. Inter-primer binding site retrotransposon and inter-simple sequence repeat diversity among wild Lens species. Biochem Syst Ecol. 58: 162-168.
  • Baránek, M., M. Meszáros, J. Sochorová, J. Čechová and J. Raddová. 2012. Utility of retrotransposon-derived marker systems for differentiation of presumed clones of the apricot cultivar Velkopavlovická. Sci Hortic-Amsterdam. 143: 1-6.
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  • Bento, M., H.S. Pereira, M. Rocheta, P. Gustafson, W. Viegas and M. Silva. 2008. Polyploidization as a retraction force in plant genome evolution: sequence rearrangements in Triticale. PLoS One. 3(1): e1402.
  • Biswas, M.K., M. Baig, Y.J. Cheng and X.X. Deng. 2010. Retro-transposon based genetic similarity within the genus Citrus and its relatives. Genet Resour Crop Ev. 57(7): 963-972.
  • Branco, C. J., E.A. Vieira, G. Malone, M.M. Kopp, E. Malone, A. Bernardes, C.C. Mistura, F. I. Carvalho and C.A. Oliveira. 2007. IRAP and REMAP assessments of genetic similarity in rice. J Appl Genetics. 48(2): 107-113.
  • Brandizzi, F. and M. Grilli Caiola. 1998. Flow cytometric analysis of nuclear DNA in Crocus sativus and allies (Iridaceae). Plant Syst Evol. 211(3): 149-154.
  • Busconi, M., L. Colli, R.A. Sánchez, M. Santaella, M. D.L.M. Pascual, O. Santana, M. Roldán and J.A. Fernández. 2015. AFLP and MS-AFLP analysis of the variation within saffron crocus (Crocus sativus L.) germplasm. PLoS One. 10(4): e0123434.
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  • Castillo, R., J.A. Fernández and L. Gómez-Gómez. 2005. Implications of carotenoid biosynthetic genes in apocarotenoid formation during the stigma development of Crocus sativus and its closer relatives. Plant Physiol. 139(2): 674-689.
  • Comertpay, G., F. Baloch, M. Derya, E. Andeden, A. Alsaleh, H. Surek and H. Ozkan. 2015. Population structure of rice varieties used in Turkish rice breeding programs determined using simple-sequence repeat and inter-primer binding site-retrotransposon data. Genet Mol Res. 15(1).
  • D’Onofrio, C., G. De Lorenzis, T. Giordani, L. Natali, A. Cavallini and G. Scalabrelli. 2010. Retrotransposon-based molecular markers for grapevine species and cultivars identification. Tree Genet Genomes. 6(3): 451-466.
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  • Erol, O., H.B. Kaya, L. Sik, M. Tuna, L. Can and M.B. Tanyolac. 2014. The genus Crocus, series Crocus (Iridaceae) in Turkey and 2 East Aegean islands: a genetic approach. Turk J Biol. 38(1): 48-62.
  • Fang-Yong, C. and L. Ji-Hong. 2014. Germplasm genetic diversity of Myrica rubra in Zhejiang Province studied using inter-primer binding site and start codon-targeted polymorphism markers. Sci Hortic-Amsterdam. 170: 169-175.
  • Fernández, J.A. 2004. Biology, biotechnology and biomedicine of saffron. Recent Research Developments in Plant Science. 127-159.
  • Fernández, J.A. 2006. Anticancer properties of saffron, Crocus sativus Linn. Advances in phytomedicine. 2: 313-330.
  • Frello, S. and J. Heslop-Harrison. 2000. Repetitive DNA sequences in Crocus vernus Hill (Iridaceae): the genomic organization and distribution of dispersed elements in the genus Crocus and its allies. Genome. 43(5): 902-909.
  • Frizzi, G., M. Miranda, C. Pantani and F. Tammaro. 2007. Allozyme differentiation in four species of the Crocus cartwrightianus group and in cultivated saffron (Crocus sativus). Biochem Syst Ecol. 35(12): 859-868.
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GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS

Year 2017, Volume: 22 Issue: 2, 243 - 252, 15.12.2017
https://doi.org/10.17557/tjfc.357426

Abstract

Saffron (Crocus L.) is a member of Crocoideae, the biggest of four subfamilies in the Iridaceae family. It has 2n = 3x = 24 chromosomes and is triploid; thus, it is sterile. In previous research, different molecular DNA markers were used but molecular characterization and genetic diversity of this complex genus have not yet been clarified. Therefore, current study aimed to determine the molecular characterization of saffron and its close relative species using inter-primer binding site (iPBS)-retrotransposon markers. Eighty-three iPBS-retrotransposon primers were used in 28 C. sativus genotypes and 17 close relative species of saffron to identify their genetic diversity. Sixteen polymorphic iPBS-retrotransposon primers generated a total of 401 polymorphic scorable bands. The mean PIC value, Nei’s genetic diversity and Shannon’s information index (I) were calculated as 0.85, 0.16 and 0.29, respectively. The results of the Unweighted Pair Group Method with Arithmetic mean UPGMA dendrogram and Principal Coordinates Analysis PCoA analysis indicated a spatial representation of the relative genetic distances among 28 saffron samples and the 17 close relative species were categorized under two distinct groups. Saffron genotypes showed very limited genetic variation and according to the iPBS-retrotransposon data, its close relatives were C. cartwrightianus and C. pallasii subsp. pallasii.

References

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  • Alavi-Kia, S., S. Mohammadi, S. Aharizad and M. Moghaddam. 2008. Analysis of genetic diversity and phylogenetic relationships in Crocus genus of Iran using inter-retrotransposon amplified polymorphism. Biotechnol Biotec Eq. 22 (3): 795-800.
  • Alsayied, N.F., J.A. Fernández, T. Schwarzacher and J. Heslop-Harrison. 2015. Diversity and relationships of Crocus sativus and its relatives analysed by inter-retroelement amplified polymorphism (IRAP). Ann Bot-London. 116(3): 359-368.
  • Andeden, E.E., F.S. Baloch, M. Derya, B. Kilian and H. Ozkan. 2013. iPBS-Retrotransposons-based genetic diversity and relationship among wild annual Cicer species. J Plant Biochem Biot. 22(4): 453-466.
  • Arslan, N., A. Ozer and R. Akdemir. 2007. Cultivation of saffron (Crocus sativus L.) and effects of organic fertilizers to the flower yield. Paper read at I International Medicinal and Aromatic Plants Conference on Culinary Herbs. 826.
  • Babaei, S., M. Talebi, M. Bahar and H. Zeinali. 2014. Analysis of genetic diversity among saffron (Crocus sativus) accessions from different regions of Iran as revealed by SRAP markers. Sci Hortic-Amsterdam. 171: 27-31.
  • Baloch, F.S., A. Alsaleh, L.E.S. de Miera, R. Hatipoglu, V. Ciftci, T. Karakoy, M. Yildiz and H. Ozkan. 2015a. DNA based iPBS-retrotransposon markers for investigating the population structure of pea (Pisum sativum) germplasm from Turkey. Biochem Syst Ecol. 61: 244-252.
  • Baloch, F.S., M. Derya, E.E. Andeden, A. Alsaleh, G. Comertpay, B. Kilian and H. Ozkan. 2015b. Inter-primer binding site retrotransposon and inter-simple sequence repeat diversity among wild Lens species. Biochem Syst Ecol. 58: 162-168.
  • Baránek, M., M. Meszáros, J. Sochorová, J. Čechová and J. Raddová. 2012. Utility of retrotransposon-derived marker systems for differentiation of presumed clones of the apricot cultivar Velkopavlovická. Sci Hortic-Amsterdam. 143: 1-6.
  • Basti, A.A., E. Moshiri, A.A. Noorbala, A.H. Jamshidi, S.H. Abbasi and S. Akhondzadeh. 2007. Comparison of petal of Crocus sativus L. and fluoxetine in the treatment of depressed outpatients: a pilot double-blind randomized trial. Prog Neuro-Psychoph. 31(2): 439-442.
  • Bento, M., H.S. Pereira, M. Rocheta, P. Gustafson, W. Viegas and M. Silva. 2008. Polyploidization as a retraction force in plant genome evolution: sequence rearrangements in Triticale. PLoS One. 3(1): e1402.
  • Biswas, M.K., M. Baig, Y.J. Cheng and X.X. Deng. 2010. Retro-transposon based genetic similarity within the genus Citrus and its relatives. Genet Resour Crop Ev. 57(7): 963-972.
  • Branco, C. J., E.A. Vieira, G. Malone, M.M. Kopp, E. Malone, A. Bernardes, C.C. Mistura, F. I. Carvalho and C.A. Oliveira. 2007. IRAP and REMAP assessments of genetic similarity in rice. J Appl Genetics. 48(2): 107-113.
  • Brandizzi, F. and M. Grilli Caiola. 1998. Flow cytometric analysis of nuclear DNA in Crocus sativus and allies (Iridaceae). Plant Syst Evol. 211(3): 149-154.
  • Busconi, M., L. Colli, R.A. Sánchez, M. Santaella, M. D.L.M. Pascual, O. Santana, M. Roldán and J.A. Fernández. 2015. AFLP and MS-AFLP analysis of the variation within saffron crocus (Crocus sativus L.) germplasm. PLoS One. 10(4): e0123434.
  • Caiola, M.G., P. Caputo and R. Zanier. 2004. RAPD analysis in Crocus sativus L. accessions and related Crocus species. Biol Plantarum. 48(3): 375-380.
  • Castillo, R., J.A. Fernández and L. Gómez-Gómez. 2005. Implications of carotenoid biosynthetic genes in apocarotenoid formation during the stigma development of Crocus sativus and its closer relatives. Plant Physiol. 139(2): 674-689.
  • Comertpay, G., F. Baloch, M. Derya, E. Andeden, A. Alsaleh, H. Surek and H. Ozkan. 2015. Population structure of rice varieties used in Turkish rice breeding programs determined using simple-sequence repeat and inter-primer binding site-retrotransposon data. Genet Mol Res. 15(1).
  • D’Onofrio, C., G. De Lorenzis, T. Giordani, L. Natali, A. Cavallini and G. Scalabrelli. 2010. Retrotransposon-based molecular markers for grapevine species and cultivars identification. Tree Genet Genomes. 6(3): 451-466.
  • Doyle, J.J. J.L. Doyle. 1987. A rapid DNA isolation procedure for small quantities of fresh leaf tissue. Phytochemical Bulletin. 19:11-15.
  • Erol, O., H.B. Kaya, L. Sik, M. Tuna, L. Can and M.B. Tanyolac. 2014. The genus Crocus, series Crocus (Iridaceae) in Turkey and 2 East Aegean islands: a genetic approach. Turk J Biol. 38(1): 48-62.
  • Fang-Yong, C. and L. Ji-Hong. 2014. Germplasm genetic diversity of Myrica rubra in Zhejiang Province studied using inter-primer binding site and start codon-targeted polymorphism markers. Sci Hortic-Amsterdam. 170: 169-175.
  • Fernández, J.A. 2004. Biology, biotechnology and biomedicine of saffron. Recent Research Developments in Plant Science. 127-159.
  • Fernández, J.A. 2006. Anticancer properties of saffron, Crocus sativus Linn. Advances in phytomedicine. 2: 313-330.
  • Frello, S. and J. Heslop-Harrison. 2000. Repetitive DNA sequences in Crocus vernus Hill (Iridaceae): the genomic organization and distribution of dispersed elements in the genus Crocus and its allies. Genome. 43(5): 902-909.
  • Frizzi, G., M. Miranda, C. Pantani and F. Tammaro. 2007. Allozyme differentiation in four species of the Crocus cartwrightianus group and in cultivated saffron (Crocus sativus). Biochem Syst Ecol. 35(12): 859-868.
  • Gailite, A. and D. Rungis. 2012. An initial investigation of the taxonomic status of Saussurea esthonica Baer ex Rupr. utilising DNA markers and sequencing. Plant Syst Evol. 298(5): 913-919.
  • Goldblatt, P., T.J. Davies, J.C. Manning, M. Van Der Bank and V. Savolainen. 2006. Phylogeny of Iridaceae subfamily Crocoideae based on a combined multigene plastid DNA analysis. Aliso. 22: 399-411.
  • Gribbon, B., S. Pearce, R. Kalendar, A. Schulman, L. Paulin, P. Jack, A. Kumar and A. Flavell. 1999. Phylogeny and transpositional activity of Ty1-copia group retrotransposons in cereal genomes. Mol Gen Genet. 261(6): 883-891.
  • Guo, D.L., M.X. Guo, X.G. Hou and G.H. Zhang. 2014. Molecular diversity analysis of grape varieties based on iPBS markers. Biochem Syst Ecol. 52: 27-32.
  • Hadizadeh, F., S. Mohajeri and M. Seifi. 2010. Extraction and purification of crocin from saffron stigmas employing a simple and efficient crystallization method. Pak J Bio Sci. 13(14): 691.
  • Harpke, D., A. Carta, G. Tomović, V. Ranđelović, N. Ranđelović, F. R. Blattner and L. Peruzzi. 2015. Phylogeny, karyotype evolution and taxonomy of Crocus series Verni (Iridaceae). Plant Syst Evol. 301(1): 309-325.
  • Harpke, D., S. Meng, T. Rutten, H. Kerndorff and F.R. Blattner. 2013. Phylogeny of Crocus (Iridaceae) based on one chloroplast and two nuclear loci: ancient hybridization and chromosome number evolution. Mol Phylogenet Evol. 66(3): 617-627.
  • Huson, D.H. and D. Bryant. 2006. Application of phylogenetic networks in evolutionary studies. Mol Biol Evol. 23(2): 254-267.
  • Kafkas, S. 2006. Phylogeny, evolution and biodiversity in the genus Pistacia (Anacardiaceae). Plant genome: biodiversity and evolution 1 (part C). 525-557.
  • Kalendar, R., K. Antonius, P. Smýkal and A. H. Schulman. 2010. iPBS: a universal method for DNA fingerprinting and retrotransposon isolation. Theor Appl Genet. 121(8): 1419-1430.
  • Kalendar, R., A. Flavell, T. Ellis, T. Sjakste, C. Moisy and A.H. Schulman. 2011. Analysis of plant diversity with retrotransposon-based molecular markers. Heredity. 106(4): 520-530.
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There are 77 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Aysun Gedık This is me

Duygu Ates This is me

Semih Erdogmus This is me

Gonul Comertpay This is me

Muhammed Bahattin Tanyolac

Hakan Ozkan This is me

Publication Date December 15, 2017
Published in Issue Year 2017 Volume: 22 Issue: 2

Cite

APA Gedık, A., Ates, D., Erdogmus, S., Comertpay, G., et al. (2017). GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS. Turkish Journal Of Field Crops, 22(2), 243-252. https://doi.org/10.17557/tjfc.357426
AMA Gedık A, Ates D, Erdogmus S, Comertpay G, Tanyolac MB, Ozkan H. GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS. TJFC. December 2017;22(2):243-252. doi:10.17557/tjfc.357426
Chicago Gedık, Aysun, Duygu Ates, Semih Erdogmus, Gonul Comertpay, Muhammed Bahattin Tanyolac, and Hakan Ozkan. “GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY IPBS-RETROTRANSPOSONS”. Turkish Journal Of Field Crops 22, no. 2 (December 2017): 243-52. https://doi.org/10.17557/tjfc.357426.
EndNote Gedık A, Ates D, Erdogmus S, Comertpay G, Tanyolac MB, Ozkan H (December 1, 2017) GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS. Turkish Journal Of Field Crops 22 2 243–252.
IEEE A. Gedık, D. Ates, S. Erdogmus, G. Comertpay, M. B. Tanyolac, and H. Ozkan, “GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS”, TJFC, vol. 22, no. 2, pp. 243–252, 2017, doi: 10.17557/tjfc.357426.
ISNAD Gedık, Aysun et al. “GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY IPBS-RETROTRANSPOSONS”. Turkish Journal Of Field Crops 22/2 (December 2017), 243-252. https://doi.org/10.17557/tjfc.357426.
JAMA Gedık A, Ates D, Erdogmus S, Comertpay G, Tanyolac MB, Ozkan H. GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS. TJFC. 2017;22:243–252.
MLA Gedık, Aysun et al. “GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY IPBS-RETROTRANSPOSONS”. Turkish Journal Of Field Crops, vol. 22, no. 2, 2017, pp. 243-52, doi:10.17557/tjfc.357426.
Vancouver Gedık A, Ates D, Erdogmus S, Comertpay G, Tanyolac MB, Ozkan H. GENETIC DIVERSITY OF CROCUS SATIVUS AND ITS CLOSE RELATIVE SPECIES ANALYZED BY iPBS-RETROTRANSPOSONS. TJFC. 2017;22(2):243-52.

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