J. Japan. Soc. Hort. Sci. 59 (3) : 559-564. 1990.

Flowering Response of Byassicoraphanus (Brassica oleyacea x Rap hanus sativus) and Hakuran (B. x napus) in Relation to Endogenous Gibberellins

Ming Hua LONG, Hiroshi OKUBOand Kunimitsu FUJIEDA Laboratory of Horticultural Science, Faculty of Agriculture Kyushu University, Fukuoka 812

Summary

Flowering response in intergeneric hybrid Brassicoraphanus (Brassica oleracea x Raphanus sativus, 2n = 36) and interspecific hybrid Hakuran (B. x napus, 2n = 38) was compared to their parental species with respect to their endogenous gibberellin (GA) contents. Flowering response of both hybrids was similar to that of their seed vernalization type parental spe- cies, e.g., R. sativus and B. campestris, respectively, but sensitivity of progenies to vernali- zation treatment was lowered and still unstable. Endogenous GA increased in hybrids and parental species after seed vernalization, but the GA content in vernalized hybrid seedlings was not intermediate compared to levels in the vernalized parental species. Increase in the endogenous GA in the vernalized plants was independent of the flowering response to ver- nalization.

ran in relation to the changes in endogenous Introduction gibberellins (GA) in comparison with those of their Since Cruciferae encompasses different groups parental species. This may be one approach to having different chromosome numbers, breeding of study the role of GA in the flowering phenomenon. new types of the plants useful for various purposes Materials and Methods has been emphasized (17,21) and proved to be pos- sible through artificial interspecific and intergeneric Plant materials and growing conditions hybridization (10,11,18, 23). Brassicoraphanus (2n = 36), which originated from the progeny of Intergeneric hybrid Brassico rap hanus, strain `K Brassica oleracea x Raphanus sativus, is an am- -11' , interspecific hybrid Hakuran cv. Shoren phidiploid (5). It possesses stable and strong and their parental species, Brassica oleracea var. resistance to clubroot disease and the resistance is capitata cvs. Tenkou and Miikechusei, Brassica dominant. Because of this breeding potential, Bras- campestris pekinensis group cvs. Kenshin and sicoraphanus is considered to be a useful bridge Tamanishiki and Raphanus sativus cv. Nanpou- plant for breeding clubroot resistant cruciferous daikon were used in the experiment. plants (28). Hakuran (B. x napus, 2n = 38) is another Seed vernalization : Seeds were germinated on amphidiploid derived from the progeny of Brassi- moistened filter paper in petri dishes at 25°C for ca oleracea x B. campestris. It is a new type head- 48 hr. After germination, they were vernalized at ing vegetable and a promising bridge plant for 5° f 1°C for 15 or 25 days. Nonvernalized seeds introducing disease resistance from B. oleracea to (control) were soaked in petri dishes at 25°C for B. campestris and exchanging valuable characters 48 hr just prior to the end of the vernalization to between B. oleracea, B. campestris and other Bras- provide seedlings of approximately the same size sica species (18). However, the flowering behavior as the vernalized ones. Both treated and control and its inheritance of these hybrid plants have populations of seedlings were planted in plastic been poorly understood. The purpose of the containers filled with vermiculite on June 2, 1987, present study was to examine the effects of ver- and grown in a glasshouse until July 2, 1987. nalization treatment on Brassicoraphanus and Haku- Green plant vernalization : Nonvernalized seed- lings were transplanted in plastic pots (9.5 x 15 cm) Received for publication May 2, 1989. filled with a mixture of vermiculite and soil (1:1

559 560 M. H. LONG,H. OKUBOAND K. FUJIEDA vlv) and grown at 200 and 25°C in the Biotron In- ity of dwarf rice seedlings to GA (19). After rins- stitute, Kyushu University on November 5, 1987, ing, bioassays were conducted in the same manner under natural light conditions. Sixty days after as described previously (20). The amounts of en- sowing, a subsample of 6 plants was transferred to dogenous GA-like substances (sum of the activities a cold glasshouse to be vernalized for 40 days by at Rf 0.2 to 0.4 and 0.6 to 0.8 on the chromato- natural low temperature. After vernalization, plants grams) were expressed as GA3 equivalents calcu- were returned to 20° or 25°C and grown until lated using a standard curve obtained from the March 31, 1988. Another subsample of 6 nonver- response of the rice seedlings to GA3. nalized control plants were kept growing at 20° or Results 25°C. During the seed and green plant vernalization Seed vernalization : After a 25-day vernalization treatments, plants were fertilized with a 0.1% so- treatment, `Tenkou' (Brassica oleracea var. capita- lution of a compound fertilizer, OK-F-1 (Otsuka ta) and all the control plants did not form any Chemical Co., Ltd.), as required. Dates of flower flower bud during the period of the experiment. bud appearance and anthesis were recorded. The Flower bud formation was 100% in `K-11' (Bras- shoot apexes of plants which had not yet reached sicoraphanus ), `Kenshin' and `Tamanishiki' (Brassi- the visible stage of flower bud appearance were ca campestris pekinensis group) and `Nanpou examined under a dissecting microscope. -daikon' (Raphanus sativus ), whereas it was Seeds for plants destined for endogenous gib- 10% in `Shoren' (Hakuran) (Table 1). Flowering berellin assay were sown on March 1, 1988, after rate was 100% in `Kenshin' and `Nanpou-daikon' a 30-day vernalization treatment; then were grown and 30% in `K-11', but no flowering occurred in `Tamanishiki' and `Shoren' in a glasshouse. The cultural methods were the . After a 10-day vernali- same as those described above. zation treatment, although `Nanpou-daikon' and `Kenshin' formed flower buds Fifteen- or 20-gram fresh weight samples (whole , only the plants of plants except roots and yellow or senescing leaves) the former reached anthesis. were harvested 5 and 15 days after planting for The days from sowing vernalized seeds to the the extraction of endogenous gibberellins. All sam- appearance of flower buds and first bloom in both ples were kept at -40°C in a deep freezer until intergeneric and interspecific hybrid plants cor- analyzed. responded closely to those of their seed vernalization-type parental species (Table 2). Extraction, separation, purification and bioassay of Green plant vernalization : Flower buds were ob- endogenous gibberellins served in all the vernalized plants (Table 3). All Extraction and separation procedures were the the plants flowered except `Miikechusei' cabbage same as those described before (15). After obtain- which showed less sensitivity to vernalization treat- ing the acidic fraction, the ethyl acetate was re- ment. Only 67% of the `Miikechusei' plants flow- moved under reduced pressure and the residue ered at 20°C; none flowered at 25°C. None of the which was dissolved in a solution of acetone- control intergeneric and interspecific hybrid plants methanol (1:1, vlv) was passed through a Sepha- or their parental species flowered. dex LH-20 column (1.5 x 35 cm). Elution of all GA- After green plant vernalization treatment, the like substances was achieved with a solution of days to appearance of flower buds and the first 0.5-1.2 column volume proportion. The acetone- anthesis in both hybrid plants closely approximat- methanol eluate was evaporated and the residue ed those of their seed vernalization-type parental was dissolved in 5% methanol to purify the extract species (Table 4). further with Sep-Pak C18, as described earlier (15). The amount of endogenous GA-like substances After sterilization and rinsing, seeds of dwarf was higher in 5-day old seedlings resulting from rice (Oryza sativa L. cv. Tan-ginbozu) were treat- vernalized seeds than in those obtained from non- ed with a solution of 20 mg/liter Uniconazol-P (S- vernalized ones (Table 5). In vernalized `Shoren' 07, Sumitomo Chemical Co., Ltd.), an inhibitor of and `Nanpou-daikon', the large increase in the GA GA biosynthesis (13), for 24 hr at 25°C in the was proportionate to the flowering response ob- dark. The treatment was to increase the sensitiv- tained by vernalization. Although seed vernaliza- FLOWERING RESPONSE OF BRA SSICORAPHANUS AND HAKURAN 561

Table 1. Effects of seed vernalization treatment on percentage of flower bud appearance and flowering.

Table 2. Effects of seed vernalization treatment on days to flower bud appear- ance and flowering after sowing.

Table 3. Effects of green plant vernalization treatment and growth temperature (20° or 25°C) on percentage of flower bud appearance and flowering. 562 M. H. LONG, H. OKUBO AND K. FUJIEDA

Table 4. Effects of green plant vernalization and growth temperature (20° or 25°c) on days to flower bud appearance and to flowering.

Table 5. Effect of seed vernalization on endogenous gibberellin content.

tion was effective for flowering in `K-11' and seed vernalization type, i.e., the mode of in- `Kenshin' , it increased GA level slightly. Seed ver- heritance of seed vernalization type is dominant nalization increased GA levels in `Miikechusei' but over green plant vernalization type. The phenome- had no effect on flowering. The GA level in inter- non of the flowering response not only in `Shoren' generic hybrid `K-11' was lower than that in its but also in `K-11' may be explained by Kagawa's parental species, radish and cabbage, whereas it hypothesis. The low percentage of flowering in was higher in interspecific hybrid `Shoren' than in seed-vernalized plants of `Shoren' and `K-11' in its parental species, Chinese cabbage and cabbage. spite of the 100% appearance of flower buds and the high percentage of flowering in their parental Discussion species, suggest that the sensitivity of these There are two types of vernalization in Crucifer- hybrids to seed vernalization is weaker and less ae crops : seed vernalization and green plant ver- stable than that of their seed vernalization type nalization. Brassica campestris and R. sativus parents. represent the former and B. oleracea the latter (24); In Cruciferae crops, interspecific hybrids have our results agree with this concept. Both inter- been used to introduce genes for disease generic hybrid `K-11' and interspecific hybrid resistance (3, 4, 6, 9) and to overcome cross incom- `Shoren' were shown to be seed vernalization type patibility (16). It is considered that genes for plants. Kagawa (14) reported that interspecific flowering response could be also transferred. In hybrids between the seed and the green plant ver- the subtropics such as Bangladesh, India or nalization types of Brassica crops are to be the Pakistan, rapeseed plants (Brassica napus) fail to FLOWERING RESPONSE OF BRA SSI CORAPHANUSAND HAKURAN 563

complete their reproductive phase (2) or flower too 4. AYOTTE, R., P. M. HARNEYand V. S. MACHADO. late to produce an economically competitive seed 1988. The transfer of triazine resistance from yield (22). Production of cabbage seeds is difficult Brassica napus L. to B. oleracea L. III. First back- in tropical and subtropical countries because cab- cross to parental species. Euphytica 38 :137-142. 5. FUKUSHIMA,E. 1945. Cytogenetic studies on bage is a cold-temperature crop, even though it is Brassica and Raphanus. I. Studies on the inter- an important and popular vegetable there (8). This generic F1 hybrids between Brassica and Rapha- points out the necessity to breed seed vernalization nus. Jour. Dept. Agri., Kyushu Imp. Univ. type interspecific hybrids between cabbage and 7 : 281-400. Chinese cabbage. This is made possible by trans- 6. COWERS,S. 1982. The transfer of characters mitting the seed vernalization character of Chinese from Brassica campestris L. to Brassica napus cabbage into cabbage (12). Therefore, it is sup- L.: Production of clubroot-resistant oil-seed rape posed that Brassicoraphanus and Hakuran could be (B. napus ssp. oleifera ). Euphytica 31: 971-976. 7. HARADA, H. 1962. Etude des substances used as bridge plants to transfer the genes con- ' trolling vernalization from B naturelles de croissance en relation avec la florai- . campestris or R. sati- son. Isolement dune substance de montaison. Rev. vus into B. oleracea to breed early flowering gen. Bot. 69: 210-297. cultivars. However, it has been shown difficult to 8. HARJADA,S.S. and H. C. WIEN.1987. Vegetable obtain hybrids by crossing Brassicoraphanus and cultivar testing in the tropics. HortScience Hakuran with cabbage because of seed abortion 22: 1216-1219. and cross incompatibility in our experiment (Long 9. HONMA, S. and 0. HEECKT. 1960. Results of et al., unpublished). Alternative breeding methods crossing Brassica pekinensis (Lour.) Rupr. with B. to overcome these difficulties is necessary. oleracea L. var. acephala Dc. Euphytica 9 : 243-246. 10. HOSODA,T. 1950. On new types of Brassica Increase in endogenous GA after vernalization is napus obtained from artificial amphidiploids. I. A reported in some plants (7, 25, 26, 27). Amagasa et new type as forage crop. Ikushu Kenkyu 4 : 91-95. al. (1) reported that endogenous GA content in the 11. HOSODA,T. 1961. Studies on the breeding of amphidiploid obtained from B. oleracea x B. cam- new types of napus crops by means of artificial pestris always showed an intermediate amount be- synthesis in genomes of genus Brassica. Memo. tween those in its parents. They concluded that Fac. Agri. Tokyo Univ. Education 7 : 1-94. there is a difference between the two parents in 12. HOSSAIN, M. M., H. INDEN and T. ASAHIRA. the potential of GA production, the inheritance of 1988. Intergeneric and interspecific hybrids through in vitro ovule culture in the Cruciferae. which is incomplete dominance. The results in our Plant Sci. 58: 121-128. experiment indicates that the increase in the en- 13. IZUMI,K., Y. KAMIYA,A. SAKURAI,H. OSHIOand dogenous GA by seed vernalization is independent N. TAKAHASHI.1985. Studies of sites of action of of the flowering response to the treatment. The a new plant growth retardant (E)-1-(4-chloro- potential of GA production in these species might phenyl)-4,4-dimethyl-2-(1, 2, 4-triazol-l-yl)-1-pent- be controlled by more complicated genetic en-3-ol (S-3307) and comparative effects of its mechanisms. stereoisomers in a cell-free system from Cucurbi- ta maxima. Plant & Cell Physiol. 26: 821-827. 14. KAGAWA,A. 1971. Studies on the inheritance of Literature cited flower inductive habits in Brassica crops. Res. Bull. 1. AMAGASA, T., H. TAKAHASHI and H. SUGE. Fac. Agric. Gifu Univ. 31: 41-62. 1987. Effects of vernalization and photoperiod on 15. LONG, M.H., H. OKUBO and K. FUJIEDA. the flowering of Brassica oleracea var. alboglabra, 1988. Effects of near-ultraviolet elimination on B. campestris var. chinensis and their amphidiploid. growth and endogenous gibberellin activities in Rep. Inst. Agr. Res. Tohoku Univ. 36: 9-19. spinach. Sci. Bull. Fac. Agr., Kyushu Univ. 2. AKBAR, M. A. 1987. Artificial Brassica napus 42: 157-162. flowering in Bangladesh. Theor. Appl. Genet. 16. MACKAY,G. R. 1977. The introgression of S al- 73 : 465-468. leles into forage rape Brassica napus L. from tur- 3. AYOTTE, R., P. M. HARNEY and V. S. MACHADO. nip, Brassica campestris L. ssp. rapifera. Euphytica 1987. The transfer of triazine resistance from 26: 511-519. Brassica napus L. to B. oleracea L. I. Production of 17. NAMAI,H., M. SARASHIMAand T. HOSODA. 1980. F1 hybrids through embryo rescue. Euphytica Interspecific and intergeneric hybridization breed- 36: 615-624. ing in Japan. p. 191-203. In : S. Tsunoda et al. 564 M. H. LONG,H. OKUBOAND K. FUJIEDA

(eds.). Brassica crops and wild allies. Japan Scien- Press, Tokyo. tific Societies Press, Tokyo. 23. SHIMIZU,S., K. KANAZAWAand T. KOBAYASHI. 18. NISHI, S. 1981. Hakuran, an interspecific hybrid 1962. Studies on the breeding of Chinese cabbage between Chinese cabbage and common cabbage. for resistance to soft rot. Part III. The breeding p.385-391. In : N. S. Talekar and T. D. Griggs of the resistant variety `Hiratsuka No.1' by inter- (eds.). Chinese cabbage. Proc. 1st Int. Symp., specific crossing. Bull. Hort. Res. Sta., Japan AVRDC, Taiwan. A1:157-174. 19. NISHIJIMA, T. and N. KATSURA. 1988. Impro- 24. SHINOHARA,S. 1959. Genecological studies on the vement of rice seedling test method for gibberel- phasic development of flowering centering on the lins by uniconazol treatment (tentative translation crucif erous crops, especially on the role of vernali- by the authors from the original Japanese title). zation on ripening seeds. Tech. Bull. Shizuoka Abstr. Japan. Soc. Hort. Sci. Autumn Meet. Pref. Agric. Exp. Sta. 6: 1-166. 368-369. (In Japanese). 25. SUGE,H. 1970. Changes of endogenous gibberel- 20. OKUBO,H. and S. UEMOTO.1985. Changes in en- lins in vernalized radish plants. Plant & Cell Phys- dogenous gibberellin and auxin activities during iol. 11: 729-735. first internode elongation in tulip flower stalk. 26. SUGE,H. 1980. Vernalization and gibberellins in Plant & Cell Physiol. 26: 709-719. pea. J. Japan. Soc. Hort. Sci. 49:203-210. 21. OLSSON,G. and S. ELLERSTROM.1980. Polyploidy 27. SUGE, H. and A. OSADA.1966. Inhibitory effect breeding in Europe. p. 167-190. In.: S. Tsunoda of growth retardants on the induction of flowering et al. (eds.). Brassica crops and wild allies. Japan in winter wheat. Plant & Cell Physiol. 7 : 617-630. Scientific Societies Press, Tokyo. 28. XING, G.M., M.H. LONG, S. TANAKA and 22. PRAKASH,S. 1980. Cruciferous oilseeds in India. K. FUJIEDA.1989. Clubroot resistance in Bras- p. 151-153. In : S. Tsunoda et al. (eds.). Brassica sicoraphanus. J. Fac. Agr., Kyushu Univ. crops and wild allies. Japan Scientific Societies 33: 189-194.

Bηssゴoo名妙 勿 鰍sお よ びバ クラ ンに お け る

花 成 反 応 と内生 ジベ レ リン

龍 明華 ・大久保 敬 ・藤枝 國光 九州大学農学部812福 岡市東区箱崎

摘 要

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も鈍 感 で は あ る が 種 子 春 化 型 と な っ た.緑 植 物 春 化 処