Reciprocal cross-compatibility in cut rose breeding

Abstract

Rose breeding companies have developed new rose varieties in response to increasing demands for color, fragrance and shapes. Hybridization is one of the most important methods of creating new rose variations. Breeders focus on fertility, reproduction, and a high number of seeds per fruit. In the present study, four Rosa genotypes (‘Jumilia’, ‘Black Magic’, ‘Tineke’, ‘Black Baccara’) were crossed to assess genetic compatibility, seed formation potential and germination rate. The results showed that all genotypes were tetraploid, and pollen germination varied from 11.36% to 23.41%. The highest crossability rate (94.44%) was found in the ‘Black Baccara’ × ‘Jumilia’ combination, followed by ‘Black Magic’ × ‘Jumilia’ (60%). The highest seed yields were obtained in ‘Jumilia’ × ‘Tineke’ (60.50). ‘Tineke’ × ‘Jumilia’ (43.74) showed the second highest number of seeds per fruit, whereas limited success was determined in cross ‘Jumilia’ × ‘Black Magic (2.25). The maximum germination percentage was found in ‘Jumilia’ when crossed with ‘Tineke’. Significant variations were recorded for the weight of hips and weight of fruit. The PCA-biplot results indicated a positive correlation between crossability rate and seed production efficiency. Overall, the choice of parents was crucial for the crossability indices, which are the average crossability rate and seed production efficiency.

References

1. Abdolmohammadi, M., Jafarkhani, K.M., Zakizadeh, H., Hamidoghli, Y. (2014). In vitro embryo germination and interploidy hybridization of rose (Rosa Sp). Euphytica, 255–264. https://doi.org/101007/S10681-014-1098-0
2. Abejide, D.R., Falusi, O.A., Daudu, O.A.Y., Gado, A., Dangana, M.C., Lateef, A.A. (2013). Assessment of pollen production, viability and germinability three sesame cultivars. Int. J. Appl. Biol. Res., 5(1), 62–71.
3. AIPH and Union Fleurs (2018). AIPH and Union Fleurs Publish 2018 International Statistics Yearbook – Flowers & Plants. Holland, 66.
4. Atram, V.R., Panchabhai, D.M., Patıl, S., Badge, S. (2015). Crossing efficiency studies in hybrid tea rose varieties. Bioscan, 10(4), 2019–2025.
5. Baydar, H., Erbas, S., Kazaz, S. (2016). Variations in floral characteristics and scent composition and the breeding potential in seed-derived oil-bearing Roses (Rosa damascena Mill.). Turk. J. Agric. Forest., 40(4), 560–569.
6. Crespel, L., Gudin, S., Meynet, J., Zhang, D. (2002). Aflp-based estimation of 2n gametophytic heterozygosity in two parthenogenetically derived diploids of Rosa hybrida L. Theor. Appl. Genet., 104, 451–456.
7. Cruden R.W., Lyon, D.L. (1989). Facultative xenogamy: Examination of a mixed mating system. In: J.H. Bock, Y.B. Linhart (eds), The evolutionary ecology of plants. Westview Press, Boulder, Colorado, 171–207.
8. Datta S.K. (2018). Breeding of new ornamental varieties: rose. Curr. Sci., 114(6), 1194–1206. https://doi.org/10.18520/cs/v114/i06/1194-1206
9. De Vries, D.P., Dubois, A.M. (1996). Factors affecting fruit and seed set in hybrid tea rose ‘Sonia’. Acta Hortic., 226, 223–230.
10. Debener, T., Mattiesch, L. (1995). Genetic analysis of molecular markers in crosses between diploid roses. In: II International Rose Symposium, 424, 249–252.
11. Dogan, E., Kazaz, S., Kılıç, T., Dursun, H., Ünsal, H.T., Uran, M. (2020). A research on determination of the performance Rosa Damascena Mill. as pollen source in rose breeding by hybridization. J. Fac. Agric., Special Issue, 194–201.
12. Dogan, E., Kılıç, T., Kazaz, S. (2022). The effects of seed parents success in cut rose breeding. Düzce Univ. Faculty Forestry, 18(2), 461–471.
13. Erlanson, E.W. (1938). Phylogeny and polyploidy in Rosa. New Phytol., 37, 72–81.
14. Eti, S. (1991). Bazı Meyve Tür ve Çeşitlerinde Değişik in vitro Testler Yardımıyla Çiçek Tozu Canlılık ve Çimlenme Yeteneklerinin Belirlenmesi [Determination of flower powder viability and germination capabilities of some fruit species and varieties by using different in vitro tests]. Cukurova J. Agric. Food Sci., 6(1), 69–80. In Turkish.
15. Fagerlind, F. (1954). Influence of the pollen-giver on the production of hips, achenes and seeds in the ‘Canina Roses’. Acta Hortic. Berg., 16, 121–168. In Turkish.
16. Farooq, A., Lei, S., Nadeem, M., Asif, A., Akhtar, G., Butt, S.Ş. (2016). Cross compatibility in various scented rosa species breeding. Pak. J. Agric. Sci., 53(4), 863–869.
17. Finch-Savage, W.E, Leubner-Metzger, G. (2006). Seed dormancy and the control of germination. New Phytol., 171, 501–523.
18. Gudin, S. (1992). Influence of bud chilling on subsequent reproductive fertility in roses. Sci. Hortic., 51,139–144.
19. Gudin, S. (1995). Rose improvement: a breeder’s experience. Acta Hortic., 420, 125–128.
20. Gudin, S. (2001). Rose breeding technologies. Acta Hortic., 547, 23–33.
21. Gudin, S., Arene, L. (1991). Influence of the pH of the stigmatic exudate on male–female interaction in Rosa hybrida L. Sex. Plant Reprod. 149(4), 110–112.
22. Gudin, S., Arene, L. (1992). Putrescine increases effective pollination period in roses. Hort. Technol., 2, 211–213.
23. Gudin, S., Arene, L., Chavagnat, A., Bulard, C. (1990). Influence of endocarp thickness on rose achene germination: genetic and environmental factors. HortScience, 25(7), 786–788.
24. Jacob, Y., Ferrero, F. (2003). Pollen grains and tubes. Encyclopedia of Rose Sci., 2, 518–523.
25. Jones, H.G. (2004). Plants and microclimate: a quantitative approach to environmental plant physiology. Cambridge University Press.
26. Jian, H.Y., Zhang, H., Tang, K.X., Li, S.F., Wang, Q.G. (2010). Decaploidy in Rosa praelucens, Byhouwer (Rosaceae) endemic to Zhongdian Plateau, Yunnan, China. Caryology, 63, 162–167.
27. Kazaz, S., Karagüzel, Ö., Aydınşakir, K., Kaya, A.S. (2010). Topraksız Kültürde Kesme Gül Yetiştiriciliği [The cul¬tivation of roses on soilless culture]. IV. Süs Bitkileri Kongresi, 22–24 October 2010, Mersin. In Turkish.
28. Kazaz, S., Dogan, E., Kılıç, T., Şahin, E.G., Dursun, H., Tuna, G. (2020). Does pollination with scented Rose genotypes as pollen source affect seed set? J. Agric. Fac. Ege Univ., 57(3), 393–399. https://doi.org/10.20289/zfdergi.637793
29. Khan, M.F, Hafiz, I.A., Khan, M.A, Abbasi, N.A., Habib, U., Shah, M.K.N. (2020). Mitigation of seed dormancy and microsatellite analysis of hybrid population of garden roses (Rosa hybrida). Sci. Hortic., 262(1). http://dx.doi.org/10.1016/j.scienta.2019.109044
30. Khan, M.F, Hafiz I.A, Khan, M.A, Abbasi, N.A, Habib, U., Shah, M.K.N. (2021). Determination of pollen fertility and hybridization success among Rosa hybrida. Pakistan J. Bot. 53(5), 1791–1800. http://dx.doi.org/10.30848/PJB2021-5(15)
31. Kılıç, T. (2023). Identifying successful combinations by fertility index in old garden roses and hybrid tea roses crosses. PeerJ, 11, e15526. http://doi.org/10.7717/peerj.15526
32. Krussmann, G. (1981). The complete book of Roses. Timber Press Portland Oregon, 531.
33. Lawrence, B.M. (1997). Progress in essential oils. Perfumer & Flavorist, 22(5),71–83.
34. Leus, L. (2005). Resistance breeding for powdery mildew (Podosphaera Pannosa) and black spot (Diplocarpon Rosae) in roses. Fac. Biosci. Eng., Ghent University, Belgium. http://hdl.handle.net/1854/LU-471624
35. Leus, L., Van Laere, K., De Riek, J., Van Huylenbroeck, J. (2018). Rose. In: J. Van Huylenbroeck (ed.), Ornamental Crops. Handbook of Plant Breed. 11, Springer International Publishing Ag, Part of Springer Nature, 719–767. https://doi.org/10.1007/978-3-319-90698-0_27
36. Liu, Z., Boachon, B., Lugan, R., Tavares, R., Erhardt, M., Mutterer, J., Demais, V., Pateyron, S., Brunaud, V., Ohnishi, T. (2015). A conserved cytochrome P450 evolved in seed plants regulates flower maturation. Mol. Plant, 8, 1751–1765. https://doi.org/10.1016/j.molp.2015.09.002
37. MacPhail, J.V., Kevan, P.G. (2009). Review of the breeding systems of wild roses (Rosa spp.). Floricult. Ornam. Biotechnol. 3, special issue, 1–13.
38. Martins, E.S, Davide, L.M.C., Miranda, G.J., Barizon, J.O., Souza, Jr F., Carvalho, R.P., Gonçalves, M.C. (2017). In vitro pollen viability of maize cultivars at different times of collection. Cienc. Rural, 47(2). https://doi.or¬g/10.1590/0103-8478cr20151077
39. Meral, D.E. (2023). Crossability of miniature rose and quantitative and qualitative traits in hybrids. Front. Plant Sci., 14, 1244426. https://doi.org/10.3389/fpls.2023.1244426
40. Miler, N., Wozny, A. (2021). Effect of pollen genotype, temperature and period of storage on in vitro germinability and in vivo seed set in chrysanthemum preliminary study. Agronomy 11(12), 2395. https://doi.org/10.3390/agrono¬my11122395
41. Morey, D. (1959). Observations on the genetics of doubleness in Roses. Am. Rose Ann. 44, 113–116.
42. Nadeem, M. (2012). Morphogenetic analysis and exploitation of heterosis among hipbearing hybrid roses. D. Phil. Thesis, University of Agriculture, Pakistan.
43. Nadeem, M., Akond, M., Riaz, A., Qasim, M., Younis, A., Farooq, A. (2013). Pollen morphology and viability relates to seed production in hybrid roses. Plant Breed. Seed Sci., 68, 25–38. https://doi.org/10.2478/V10129-011-0078-Y
44. Nadeem, M., Wang, X., Akond, M., Awan, F.S., Khan, A.I., Riaz, A., Younıs, A. (2014). Hybrid identification, morphological evaluation and genetic diversity analysis of Rosa × hybrida by SSR markers. Aust. J. Crop. Sci., 8, 183–190.
45. Oh, J.S., Hwang, P.S., Chung, W.B. (2005). Degree of heterosis and heterobeltiosis in F1 hybrids of eggplant. J. Life Sci., 15, 132–135.
46. Ogilvie, I., Cloutier, D., Arnold, N., Jui, P.Y. (1991). The effect of gibberellic acid on fruit and seed set in crosses of garden and winter hardy Rosa accessions. Euphytica, 52, 119–123. https://doi.org/10.1007/BF00021324
47. Perez, S., Moore, J.N. (1985). Prezygotic endogenous bar¬riers to interspecific hybridization in Prunus. J. Am. Soc. Hortic. Sci., 110, 267–273.
48. Pipino, L., Scariot, V., Gaggero, L., Mansuino, A., Van Labeke, M.C., Giovannini, A. (2011). Enhancing seed germination in hybrid tea roses. Propag. Ornam. Plants, 11(3), 111–118.
49. Rajapakse, S., Byrne, D. H., Zhang, L., Anderson, N., Arumuganathan, K., Ballard, R.E. (2001). Two genetic linkage maps of tetraploid Roses. Theor. Appl. Genet., 103, 575–583. https://doi.org/10.1007/PL00002912
50. Roberts, A. (2003). Encyclopedia of Rose science. Academic Press, Elsevier, Oxford, 30–33.
51. Semeniuk, P., Stewart, R.N., Uhring, J. (1963). Induced secondary dormancy of rose embryos. Proc. Amer. Soc. Hort. Sci., 83, 825–828.
52. Stone, J.L., Thompson, J.D, Dent-Acosta, S.J. (1995). Assessment of pollen viability in hand-pollination experiments: A review. Am. J. Bot., 82(9), 1186–1197. https://doi.org/10.2307/2446073
53. Sulusoglu, M., Cavusoglu, A. (2014). In vitro pollen viability and pollen germination in cherry laurel (Prunus laurocerasus L.). Sci. World J., 657123. https://doi.org/10.1155/2014/657123
54. Täckholm, G. (1923). Zytologische Studien Uber Die Gattung Rosa [Cytological studies on the genus Rosa]. Acta Hortic. Berg, 97–381. In German.
55. Tuna, M. (2016). IV. Flow Sitometri ve Tarımsal Araştırmalarda Kullanımı Uygulamalı Eğitim Programı [Applied training programme on flow cytometry and its use in agricultural research]. Namık Kemal University Faculty of Agriculture Department of Field Crops, 29–30 January 2016. Tekirdağ. In Turkish.
56. Ueckert, J.A. (2014). Understanding and manipulating polyploidy in garden roses. Masterthesis, Texas A&M University.
57. Ueda, Y., Hirata, T. (1989). Pollen fertility in Roses. Japan. J. Palynol., 35(2), 1–7.
58. Yokoya, K., Roberts, A.V., Mottley, J., Lewis, R., Brandham, P.E. (2000). Nuclear DNA amounts in Roses. Ann. Bot., 85(4), 557–561. https://doi.org/10.1006/anbo.1999.1102
59. Zlesak, D.C. (2005). The effects of short-term drying on seed germination in rosa. Hortscience, 40(6), 1931–1932.
60. Zlesak, D.C. (2007). Rose: Rosa hybrida. In: Flower breeding and genetics, N.O. Anderson (ed.), Springer, Minnesota, 695–740.