Pistillate flower development and pollen tube growth mode during the delayed fertilization stage in Corylus heterophylla Fisch
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- 作者:Jianfeng Liu (1)
Huidi Zhang (1)
Yunqing Cheng (1)
Salih Kafkas (2)
Murat Güney (2) - 关键词:Hazelnut ; Fertilization ; Pollen tube growth ; Corylus heterophylla Fisch
- 刊名:Plant Reproduction
- 出版年:2014
- 出版时间:September 2014
- 年:2014
- 卷:27
- 期:3
- 页码:145-152
- 全文大小:1,634 KB
- 参考文献:1. Alireza G, Me G, Talaie A, Vezvaie A (2004) Studies on self-incompatibility alleles in some progenies of hazelnut ( / Corylus avellana L.) using fluorescence microscope. Int J Agric Biol 6:113-15
2. Beyhan N, Marangoz D (2007) An investigation of the relationship between reproductive growth and yield loss in hazelnut. Sci Hortic 113:208-15 CrossRef
3. Boavida LC, Varela MC, Feijo JA (1999) Sexual reproduction in the cork oak ( / Quercus suber L.). I. The progamic phase. Sex Plant Reprod 11:347-53 CrossRef
4. Borgardt SJ, Nixon KC (2003) A comparative flower and fruit anatomical study of / Quercus acutissima, a biennial-fruiting oak from the / Cerris group (Fagaceae). Am J Bot 90(11):1567-584 CrossRef
5. Botta R, Vergano G, Me G, Vallania R (1995) Floral biology and embryo development in chestnut ( / Castanea sativa Mill.). HortScience 30(6):1283-286
6. Cecich RA (1997) Pollen tube growth in Quercus. Forest Sci 43:140-46
7. Dahl AE, Fredrikson M (1996) The timetable for development of maternal tissues sets the stage for male genomic selection in / Betula pendula (Betulaceae). Am J Bot 83:895-02 CrossRef
8. Germain E (1994) The reproduction of hazelnut ( / Corylus avellana L.): a review. Acta Hortic 351:195-09
9. Kaufmane E, Rumpunen K (2002) Pollination, pollen tube growth and fertilization in / Chaenomeles japonica (Japanese quince). Sci Hortic 94(3):257-71 CrossRef
10. Liu JF, Cheng YQ, Yan K, Liu Q, Wang ZW (2012) The relationship between reproductive growth and blank fruit formation in / Corylus heterophylla Fisch. Sci Hortic 136:128-34 CrossRef
11. Liu JF, Cheng YQ, Liu CM, Zhang CJ, Wang ZW (2013) Temporal changes of disodium fluorescein transport in hazelnut during fruit development stage. Sci Hortic 150:348-53 CrossRef
12. Lombard PB, Sugal D (1988) Putrescine influences ovule senescence, fertilization time, and fruit set in ‘Comice-pear. J Am Soc Hortic Sci 113(5):708-12
13. Me G, Emanuel E, Botta R, Vallania R (1989) Embryo development in ‘Tonda Gentile delle Langhe-hazelnut. Hortsci 24:122-25
14. Shen JH, Shen Y, Li W, Shang Y, Ding J, Li R (2007) Studies on pollen viability and fertilization of / Clivia miniata Regel. Acta Hortic Sin 34(5):1249-256
15. Sogo A, Tobe HM (2005) Intermittent pollen-tube growth in pistils of alders (Alnus). Proc Natl Acad Sci USA 102:8770-775 CrossRef
16. Sogo A, Tobe H (2006a) Mode of pollen-tube growth in pistils of / Myrica rubra (Myricaceae): a comparison with related families. Ann Bot 97:71-7 CrossRef
17. Sogo A, Tobe H (2006b) The evolution of fertilization modes independent of the micropyle in Fagales and ‘pseudoporogamy- Plant Syst Evol 259:73-0 CrossRef
18. Sogo A, Tobe H (2006c) Delayed fertilization and pollen-tube growth in pistils of / Fagus japonica (Fagaceae). Am J Bot 93(12):1748-756 CrossRef
19. Sogo A, Jaffre T, Tobe H (2004a) Pollen-tube growth and fertilization mode in / Gymnostoma (Casuarinaceae): their characteristics and evolution. J Plant Res 117:249-51
20. Sogo A, Noguchi J, Jaffre T, Tobe H (2004b) Pollen-tube growth pattern and chalazogamy in / Casuarina equisetifolia (Casuarinaceae). J Plant Res 117:37-6 CrossRef
21. Williams JH, Friedman WE, Arnold ML (1999) Developmental selection within the angiosperm style: using gamete DNA to visualize interspecific pollen competition. Proc Natl Acad Sci USA 96:9201-206 CrossRef
22. Wunnachit W, Jenner C, Sedgley M (1992) Pollen vigour and composition in relation to andromonoecy in cashew ( / Anacardium occidentale L.: Anacardiaceae). Sex Plant Reprod 5(4):264-69 CrossRef
23. Zhang B, Wang ZJ, Jin SH, Xia GH, Huang YJ, Huang JQ (2012) A pattern of unique embryogenesis occurring via apomixis in / Carya cathayensis. Biol Plant 56(4):620-27 CrossRef - 作者单位:Jianfeng Liu (1)
Huidi Zhang (1)
Yunqing Cheng (1)
Salih Kafkas (2)
Murat Güney (2)
1. College of Life Sciences, Jilin Normal University, Siping, 136000, Jilin Province, China
2. Department of Horticulture, Faculty of Agriculture, University of Cukurova, Adana, 01330, Turkey - ISSN:2194-7961
文摘
Unlike most angiosperms, in which fertilization occurs within several days after pollination, fertilization in hazel (Corylus Spp.) is delayed by two to three and a half months. However, the female inflorescences or young fruits are too hard or lignified to be dissected according to regular paraffin sectioning technique. So, what the nature of development during the extended progamic phases of hazel remains unknown. The female inflorescence development and pollen tube growth mode during the delayed fertilization stage in hazel were investigated by improved paraffin sectioning and aniline blue staining of pollen tubes. The results showed ovaries and ovules of hazel were invisible at the time of blooming. Early ovary and ovule primordium began to form from 15 to 20?days after blooming, respectively. Integument and mature embryo sacs differentiated from the nucellus on 40th and 55th day after blooming, respectively. Pollen tubes were retarded in the bottom of the style or the pollen tube cavity (PTC, a specifical lignified cavity structure at the bottom of style for pollen tube to rest during progamic phase) for about 26?days. Then, the pollen tubes were observed to leave the PTC and began to enter the ovary. After that, a single pollen tube passed through the vicinity of the micropyle. Finally, pollen tubes turned a corner and penetrated the embryo sac through the tissue of the chalaza instead of micropyle on 52 and 55?days after blooming, respectively. The results of more in-depth information will be beneficial to better understanding of the delayed fertilization process in hazel.