Genome Mapping Studies in Olives
Year 2017,
Volume: 7 Issue: 1, 33 - 37, 30.06.2017
Nurengin Mete
,
Öznur Çetin
Abstract
Olive tree is one of the plant species firstly cultivated by humankind and considered as a part of Mediterranean
culture. Numerous varieties have emerged in different countries as a result of natural hybridizations originated in
the time passed from cultivation of olive to the present day. Depending on this, preliminary molecular studies
conducted on olive were mostly carried out in order to determine genetic variability. On the other hand, studies
have been conducted regarding linkage mapping and determination of QTLs in the recent years. Number of
studies on determination of quantitative trait loci in olive is very limited. However, an effective marker that can
be used as early selection criteria have not been developed until today. Related studies have still continued.
References
- Atienza, S.G., Rosa, R. de la., Leo´n, L., Martı´n, A. and Belaj, A., 2014. Identification of QTL for agronomic traits of importance for olive breeding. Mol Breeding DOI 10.1007/s11032-014-0070-y.
Belaj, A., Domínguez-García, M.C., Atienza, S.G., Martín-Urdíroz, N., De la Rosa, R., Satovic, Z., Martín, A., Kilian, A., Trujillo, I., Valpuesta, V. and Del Río, C., 2011. Developing a core collection of olive (Olea europaeaL.) based on molecular markers (DArTs, SSRs, SNPs) and agronomic traits. Tree Genet. Genomes. Doi: 10.1007/s11295-011-0447-6.
Ben Sadok, I., Celton, J-M., Essalouh, L., Zine El Aabidine, A., Garcia, G., Martinez, S., Grati-Kamoun, N., Rebai, A., Costes, E. and Khadari, B., 2013. QTL mapping of flowering and fruiting traits in olive. PLoS ONE 8(5):e62831.
Bitonti, M.B., Cozza, R., Chiappetta, A., Contento, A., Mineli, S., Ceccarelli, M., Gelati, M.T., Maggini, F., Baldoni, L. and Cionini, P.G., 1999. Amount and organization of the heterochromatin in Olea europaea and related species. Heredity 83:188–195.
Bracci, T., Busconi, M., Fogher, C. and Sebastiani, L., 2011. Molecular studies in olive (Olea europaea L.): overview on DNA markers applications and recent advances in genome analysis. Plant Cell Reports April 2011, Volume 30, Issue 4, pp 449-462.
Cervera, M.T., Storme, V., Ivens, B., Gusmao, J., Lıu, B.H., Hostyn, V., Slycken, J.V., Montagu, M.V. and Boerjan, W., 2001. Dense Genetic Linkage maps of Three Populus Species (Populus deltoides, P. nigra and P. trichocarpa) Based on AFLP and Microsatelli te Markers. Genetics, 158: 787–809.
Cetin, Ö., Mete, N., Kaya, H., Şahin, M., Hakan, M., Sefer, F., Güloğlu, U., 2016. Zeytinde (Olea europaea L.) Bağlantı Haritalarının Oluşturulması ve Bazı Özellikleri Kontrol Eden Genlerle İlişkili Kantitatif Özellik Lokuslarının (QTL) Saptanması. Tarımsal Araştırmalar ve Politikalar Genel Müdürlüğü. TAGEM/BBAD/12/A08/P06/3. Proje Sonuç Raporu.
De la Rosa, R., Angiolillo, A., Guerrero, C., Pellegrini, M., Rallo, L., Besnard, G., Bervillé, A., Martin, A. and Baldoni, L., 2003. A first linkage map of olive (Olea europea L.) cultivars using RAPD, AFLP, RFLP and SSR markers. Theor. Appl. Genet, 106: 1273–1282.
Dolezel, J., Bartos, J., Voglmayr, H. and Greilhuber, J., 2003. Nuclear DNA content and genome size of trout and human. Cytometry Part A 51A: 127–128.
Dominguez-Garcia, M.C., Belaj, A., de la Rosa, R., Satovic, Z., Heller-Uszynska, K., Kilian, A., Martin, A. and Atienza, S.G., 2012. Development of DArT markers in olive (Olea europaea L.) and usefulness in variability studies and genome mapping. Scientia Horticulturae. 136, 50-60.
El Aabidine, A.Z.; Charafi, J.; Grout, C.; Doligez, A.; Santoni, S.; Moukhli, A.; Jay-Allemand, C.; El Modafar, C. and Khadari, B., 2010. Construction of a genetic linkage map for the olive based on AFLP and SSR markers, Crop Science Vol. 50, No. 6, pp. 2291-2302. ISSN 1435-0645.
Grattapaglia, D. and Sederoff, R., 1994. Genetic Linkage Maps of Eucalyptus grandis and Eucalyptus urophylla using A Pseudo-Testcross: Mapping Strategy and RAPD Markers. Genet i cs, 137: 1121-1137.
İpek, A., Gülen, H., Barut, E., Yalçınkaya, E., Öz, A.T. ve A.Tangu, N., 2008. Moleküler markörler kullanılarak önemli bazı standart zeytin çeşit ve melezlerinin DNA profillerinin belirlenmesi ve gen haritasının çıkarılması. Proje No: TOVAG-105 O 071. 67s.
İpek, A., Yılmaz, K., Sıkıcı, P., Tangu, NA., Öz, AT., Bayraktar, M., İpek, M., Gülen, H., SNP Discovery by GBS in Olive and the Construction of a High-Density Genetic Linkage Map. Biochemical Genetics June 2016, Volume 54, Issue 3, pp 313-325.
Khadari, B., El Aabidine, A.Z. and Grout, C., 2010. A Genetic Linkage Map of Olive Based on Amplified Fragment Length Polymorphism, Intersimple Sequence Repeat and Simple Sequence Repeat Markers J. Am. Soc. Hort. Sci., 135(6):548-555.
Loureiro, J., Rodriguez, E., Costa, A. and Santos, C., 2007. Nuclear DNA content estimations in wild olive (Olea europaea L. ssp. europaea var. sylvestris Brot.) and Portuguese cultivars of O. europaeausing flow cytometry. Genet Resour Crop Evol 54:21–25.
Mete, N. 2015. Zeytinde Genom Haritasının Oluşturulması ve Meyve Olgunlaşmasını Kontrol Eden Genlerle İlişkili DNA Markörlerinin Saptanması, Ege Üniversitesi, Doktora tezi, Bornova/İzmir. (https://tez.yok.gov.tr/UlusalTezMerkezi/TezGoster?key=X-M9ZoIuIoNTj2P7iY13hbyWFBPuG4_3NXXo9A3e1dCdplUDjvZJqErO-Vr3qa8O)
Rugini, E., Panelli, G., Ceccarelli, M. and Muganu, M., 1996. Isolation of triploid and tetraploid olive (Olea europaeaL.) plants from mixoploid cv. ‘Frantoio’ and ‘Leccino’ mutants by in vivo and in vitro selection. Plant Breed 115:23–27.
Scott, L.J., Shepherd, M., Nikles, D.G. and Henry, R.J., 2005. Low efficiency of pseudo-test-cross mapping design was consistent with limited genetic diversity and low heterozygosity in hoop pine (Arau-caria cunninghamiiAraucariaceae). Tree Genet. Genomes 1:124–134.
Vienne, D., 2003. Construction of Genetic Linkage Maps. In: Molecular Markers in Plant Genetics and Biotechnology D. Vienne (ed.) Science Publishers Inc. pp. 47-79.
Wu, S-B., Collins, G. and Sedgley, M., 2004. A moleculer linkage map of olive (Olea europaea L.) based on RAPD, microsatellite, and SCAR markers, Genome vol: 47. p: 26-35.
Zeytinde Genom Haritalama Çalışmaları
Year 2017,
Volume: 7 Issue: 1, 33 - 37, 30.06.2017
Nurengin Mete
,
Öznur Çetin
Abstract
Zeytin ağacı, insanoğlu tarafından ilk kültüre alınan bitki türlerinden birisi olup Akdeniz kültürünün bir parçası
olarak görülmektedir. Zeytinin kültüre alınmasından günümüze kadar geçen süre içerisinde oluşan doğal
melezlenmeler neticesinde farklı ülkelerde birçok çeşit ortaya çıkmıştır. Buna bağlı olarak zeytinde yapılan ilk
moleküler çalışmalar daha çok genetik çeşitliliğin belirlenmesi amacıyla yürütülmüştür. Bununla birlikte son
yıllarda bağlantı (linkage) haritalama ve QTL lokuslarının belirlenmesine yönelik çalışmalar gerçekleştirilmektedir. Zeytinde kantitatif karakter lokuslarının belirlenmesine yönelik çalışmalar oldukça azdır. Ancak günümüze
kadar erken seleksiyon kriteri olarak kullanılabilecek etkili bir markör geliştirilememiştir. Buna yönelik
çalışmalar halen devam etmektedir.
References
- Atienza, S.G., Rosa, R. de la., Leo´n, L., Martı´n, A. and Belaj, A., 2014. Identification of QTL for agronomic traits of importance for olive breeding. Mol Breeding DOI 10.1007/s11032-014-0070-y.
Belaj, A., Domínguez-García, M.C., Atienza, S.G., Martín-Urdíroz, N., De la Rosa, R., Satovic, Z., Martín, A., Kilian, A., Trujillo, I., Valpuesta, V. and Del Río, C., 2011. Developing a core collection of olive (Olea europaeaL.) based on molecular markers (DArTs, SSRs, SNPs) and agronomic traits. Tree Genet. Genomes. Doi: 10.1007/s11295-011-0447-6.
Ben Sadok, I., Celton, J-M., Essalouh, L., Zine El Aabidine, A., Garcia, G., Martinez, S., Grati-Kamoun, N., Rebai, A., Costes, E. and Khadari, B., 2013. QTL mapping of flowering and fruiting traits in olive. PLoS ONE 8(5):e62831.
Bitonti, M.B., Cozza, R., Chiappetta, A., Contento, A., Mineli, S., Ceccarelli, M., Gelati, M.T., Maggini, F., Baldoni, L. and Cionini, P.G., 1999. Amount and organization of the heterochromatin in Olea europaea and related species. Heredity 83:188–195.
Bracci, T., Busconi, M., Fogher, C. and Sebastiani, L., 2011. Molecular studies in olive (Olea europaea L.): overview on DNA markers applications and recent advances in genome analysis. Plant Cell Reports April 2011, Volume 30, Issue 4, pp 449-462.
Cervera, M.T., Storme, V., Ivens, B., Gusmao, J., Lıu, B.H., Hostyn, V., Slycken, J.V., Montagu, M.V. and Boerjan, W., 2001. Dense Genetic Linkage maps of Three Populus Species (Populus deltoides, P. nigra and P. trichocarpa) Based on AFLP and Microsatelli te Markers. Genetics, 158: 787–809.
Cetin, Ö., Mete, N., Kaya, H., Şahin, M., Hakan, M., Sefer, F., Güloğlu, U., 2016. Zeytinde (Olea europaea L.) Bağlantı Haritalarının Oluşturulması ve Bazı Özellikleri Kontrol Eden Genlerle İlişkili Kantitatif Özellik Lokuslarının (QTL) Saptanması. Tarımsal Araştırmalar ve Politikalar Genel Müdürlüğü. TAGEM/BBAD/12/A08/P06/3. Proje Sonuç Raporu.
De la Rosa, R., Angiolillo, A., Guerrero, C., Pellegrini, M., Rallo, L., Besnard, G., Bervillé, A., Martin, A. and Baldoni, L., 2003. A first linkage map of olive (Olea europea L.) cultivars using RAPD, AFLP, RFLP and SSR markers. Theor. Appl. Genet, 106: 1273–1282.
Dolezel, J., Bartos, J., Voglmayr, H. and Greilhuber, J., 2003. Nuclear DNA content and genome size of trout and human. Cytometry Part A 51A: 127–128.
Dominguez-Garcia, M.C., Belaj, A., de la Rosa, R., Satovic, Z., Heller-Uszynska, K., Kilian, A., Martin, A. and Atienza, S.G., 2012. Development of DArT markers in olive (Olea europaea L.) and usefulness in variability studies and genome mapping. Scientia Horticulturae. 136, 50-60.
El Aabidine, A.Z.; Charafi, J.; Grout, C.; Doligez, A.; Santoni, S.; Moukhli, A.; Jay-Allemand, C.; El Modafar, C. and Khadari, B., 2010. Construction of a genetic linkage map for the olive based on AFLP and SSR markers, Crop Science Vol. 50, No. 6, pp. 2291-2302. ISSN 1435-0645.
Grattapaglia, D. and Sederoff, R., 1994. Genetic Linkage Maps of Eucalyptus grandis and Eucalyptus urophylla using A Pseudo-Testcross: Mapping Strategy and RAPD Markers. Genet i cs, 137: 1121-1137.
İpek, A., Gülen, H., Barut, E., Yalçınkaya, E., Öz, A.T. ve A.Tangu, N., 2008. Moleküler markörler kullanılarak önemli bazı standart zeytin çeşit ve melezlerinin DNA profillerinin belirlenmesi ve gen haritasının çıkarılması. Proje No: TOVAG-105 O 071. 67s.
İpek, A., Yılmaz, K., Sıkıcı, P., Tangu, NA., Öz, AT., Bayraktar, M., İpek, M., Gülen, H., SNP Discovery by GBS in Olive and the Construction of a High-Density Genetic Linkage Map. Biochemical Genetics June 2016, Volume 54, Issue 3, pp 313-325.
Khadari, B., El Aabidine, A.Z. and Grout, C., 2010. A Genetic Linkage Map of Olive Based on Amplified Fragment Length Polymorphism, Intersimple Sequence Repeat and Simple Sequence Repeat Markers J. Am. Soc. Hort. Sci., 135(6):548-555.
Loureiro, J., Rodriguez, E., Costa, A. and Santos, C., 2007. Nuclear DNA content estimations in wild olive (Olea europaea L. ssp. europaea var. sylvestris Brot.) and Portuguese cultivars of O. europaeausing flow cytometry. Genet Resour Crop Evol 54:21–25.
Mete, N. 2015. Zeytinde Genom Haritasının Oluşturulması ve Meyve Olgunlaşmasını Kontrol Eden Genlerle İlişkili DNA Markörlerinin Saptanması, Ege Üniversitesi, Doktora tezi, Bornova/İzmir. (https://tez.yok.gov.tr/UlusalTezMerkezi/TezGoster?key=X-M9ZoIuIoNTj2P7iY13hbyWFBPuG4_3NXXo9A3e1dCdplUDjvZJqErO-Vr3qa8O)
Rugini, E., Panelli, G., Ceccarelli, M. and Muganu, M., 1996. Isolation of triploid and tetraploid olive (Olea europaeaL.) plants from mixoploid cv. ‘Frantoio’ and ‘Leccino’ mutants by in vivo and in vitro selection. Plant Breed 115:23–27.
Scott, L.J., Shepherd, M., Nikles, D.G. and Henry, R.J., 2005. Low efficiency of pseudo-test-cross mapping design was consistent with limited genetic diversity and low heterozygosity in hoop pine (Arau-caria cunninghamiiAraucariaceae). Tree Genet. Genomes 1:124–134.
Vienne, D., 2003. Construction of Genetic Linkage Maps. In: Molecular Markers in Plant Genetics and Biotechnology D. Vienne (ed.) Science Publishers Inc. pp. 47-79.
Wu, S-B., Collins, G. and Sedgley, M., 2004. A moleculer linkage map of olive (Olea europaea L.) based on RAPD, microsatellite, and SCAR markers, Genome vol: 47. p: 26-35.