马尾松二代无性系种子园的花期同步性

doi:10.11707/j.1001-7488.20190117

摘要/Abstract

摘要： [目的]研究马尾松二代种子园无性系的开花物候特征、花期同步性、结实状况及气候影响因子，评价无性系花期同步性规律，指导种子园经营生产及提高种子遗传品质与产量。[方法]连续2年对浙江省淳安县姥山林场马尾松二代无性系矮化种子园的22个无性系进行花期、花量和结实性状调查，分析其开花物候与花期同步指数。[结果]各无性系雌雄球花整体花期持续时间为8~17天，2014年始花期相对于2013年滞后约6天，且持续时间缩短约6天。整体水平上，年度内雌球花及雄球花的各花期时长差异较小；无性系的始花期和盛花期的物候特征年度间存在差异，2014年无性系内雌雄球花开花的同步性更强。无性系的开花物候受气候因素影响较大，这使得无性系间开花同步程度降低，花期同步指数变异增加，2013年和2014年花期同步指数变化范围分别为0.041~0.556和0.284~0.802，无性系的平均变异系数分别为32.3%和16.8%。各无性系分别作为父、母本时，年度内无性系花期整体同步性水平差异较小，表现出无性系作为父本时的散粉期整体的同步性要高于作为母本时的可授粉期的同步性。年度间无性系作为父、母本及自交的花期同步指数均有极显著差异，2014年各无性系的花期同步指数在整体水平均高于2013年，但自交指数在年度间无显著差异。相关分析表明，雌球花越多的无性系的球果数越多；而雌球花花期持续时间越长的无性系座果率越高；不同年度的雌球花盛花期和花期的持续时间均与千粒质量指标呈显著或极显著正相关。[结论]浙江姥山林场马尾松二代无性系种子园雌、雄球花的花期具有较好的同步性，无性系间没有出现花期不遇现象。无性系交配组合的雌球花可授粉期和雄球花的散粉期影响了种子园无性系的种实品质及座果率。连续2年的观测表明无性系间花期整体同步性水平存在差异，且这种差异与二代种子园无性系的亲本遗传背景有关。各无性系分别作为父、母本时，表现出无性系作为父本时的散粉期整体的同步性要高于作为母本时的可授粉期的同步性，无性系作为父本和母本时花期同步指数呈负相关，且种子园内存在1/3无性系具有高于异交平均水平的自交可能性，是马尾松二代种子园管理和无性系再选择应综合考虑的因素。

关键词: 马尾松, 二代种子园, 无性系, 花期同步性

Abstract: [Objective] The flowering phenology, flowering synchronism, seed setting and impacting climate factors of clones of the second-generation clonal seed orchard of Pinus massoniana were studied to evaluate the synchronization rule of clones, guide seed orchard management and production as well as improve seed genetic quality and yield.[Method] For two consecutive years, we investigated 22 clones in dwarfed second-generation clonal seed orchard of Pinus massoniana into the normal flowering and fruiting period in Laoshan Forest Farm in Chun'an County of Zhejiang province, including flowering phase, flower number and fruit characteristics, to analyze the flowering phenology and flowering synchrony index.[Result] The flowering period of both female and male flowers of all clones was 8-17 days. The initial flowering in 2014 was 6 days later than in 2013, and the lasting period was shortened by about 6 days relative to 2013. Overall, there were small differences in flowering period between female and male flowers in the same year, bigger differences were found among years in the initial time and peak time of flowering, and the flowering of female and male flowers of the same clone were more synchronized in 2014. The flowering phenology of clones was different greatly between the two years, related to climate during the flowering phase, which caused decrease of flowering synchronicity and increase of variation of flowering synchrony index, ranging from 0.041 to 0.556 and 0.284 to 0.802 respectively in 2013 and 2014. The average coefficient of variation of clones was 32.3% and 16.8%, respectively. When a clone was used respectively as male and female parent, the difference level of flowering synchronization was small within the same year. The level of flowering synchronization in male parent was higher than that as female parent. There was a significant difference between the two years in synchronism index when respectively used as male, female parent and for selfing. Compared with 2013, the flowering synchronization index in 2014 was significantly increased, but there was no significant difference in self-compatibility index between the two years. Correlation analysis showed that the clones with more female flowers had more fruits; and the clones with longer flowering period of female flowers had higher fruit-setting rate. There was significant positive correlation between the peaking time and flowering duration of female flowers and the weight of thousand seeds.[Conclusion] The second-generation clonal seed orchard of Pinus massoniana in Laoshan Forest Farm of Zhejiang Province had good flowering synchrony between female and male flowers, no asynchrony was found among the clones. The pollinating period of female flowers and the pollen dispersing period of male flowers of the mating pairs affected the quality of seeds and fruit setting rate. The synchronism of clone was influenced by meteorological factors. Observations in two consecutive years indicated that there were differences among clones in flowering synchronization level, which was made by the differences in flowering phenology of clone, and the differences were related to the genetic background of the parental clones in the second generation clonal seed orchard. The synchronicity of pollen dispersion period was higher when used as male parent than the synchronicity of the pollinating period when used as female parent. The flowering synchronization index showed a negative correlation when a clone uses respectively as male and female parent. The possibility of self-crossing of 1/3 of the clones in the seed orchard was higher than the average level of out-crossing, which was the factor that should be taken into account in the management of seed orchard and the selection of clones.

Key words: Pinus massoniana, second-generation seed orchard, clones, flowering synchronism

中图分类号:

S722.8⁺3

陈坦, 张振, 楚秀丽, 金国庆, 周志春, 丰忠平. 马尾松二代无性系种子园的花期同步性[J]. 林业科学, 2019, 55(1): 146-156.

Chen Tan, Zhang Zhen, Chu Xiuli, Jin Guoqing, Zhou Zhichun, Feng Zhongping. The Flowering Synchronicity of Second-Generation Clonal Seed Orchard of Masson Pine (Pinus massoniana)[J]. Scientia Silvae Sinicae, 2019, 55(1): 146-156.

参考文献

陈晓阳. 1994. 杉木种子园生殖系统和遗传改良的研究. 北京:北京林业大学博士学位论文.
(Chen X Y. 1994. Studies on reproductive system and genetic improvement of Cunninghamia lanceolata seed orchard. Beijing:PhD thesis of Beijing Forestry University.[in Chinese])
陈晓阳,潘其敏,沈熙环. 1995. 杉木种子园开花物候特点的研究. 北京林业大学学报, 17(1):10-18.
(Chen X Y, Pan Q M, Shen X H. 1995. Study on the flowering phenology of Cunninghamia lanceolata seed orchard. Journal of Beijing Forestry University, 17(1):10-18.[in Chinese])
金国庆,秦国峰,周志春,等. 1998. 马尾松无性系种子园球果产量的遗传变异. 林业科学研究,11(3):277-284.
(Jin G Q, Qin G F, Zhou Z C, et al. 1998. Genetic variation of cone production in clonal seed orchard of Pinus massoniana. Forest Research, 11(3):277-284.[in Chinese])
李悦, 王晓茹, 李伟, 等. 2010. 油松种子园无性系花期同步指数稳定性分析. 北京林业大学学报, 32(5):88-93.
(Li Y, Wang X R, Li W, et al. 2010. Flowering synchronization stability of clones among plant ages in a seed orchard of Pinus tabulaeformis. Journal of Beijing Forestry University, 32 (5):88-93.[in Chinese])
吕东, 张宏斌, 李秉新, 等. 2016. 青海云杉无性系开花特性及种子园花粉流时空变化. 东北林业大学学报, 44 (3):68-73.
(Lü D, Zhang H B, Li B X, et al. 2016. Flowering characters of Picea crassifolia clones and temporal-spatial variation of pollen flow in Picea crassifolia orchard. Journal of Northeast Forestry University, 44(3):68-73.[in Chinese])
沈熙环. 1994. 种子园优质高产技术. 北京:中国林业出版社, 159-167.
(Shen X H. 1994. Seed orchard techniques for high genetic quality. Beijing:China Forestry Publishing House, 159-167.[in Chinese])
谭小梅, 金国庆, 张一, 等. 2011. 截干矮化马尾松二代无性系种子园开花结实的遗传变异. 东北林业大学学报, 39(4):39-42.
(Tan X M, Jin G Q, Zhang Y, et al. 2011. Genetic variation of flowering and fruiting in dwarfed second-generation clonal seed orchard of Pinus massoniana. Journal of Northeast Forestry University, 39(4):39-42.[in Chinese])
唐效蓉,李宇珂,夏合新,等. 2016. 马尾松二代种子园无性系开花物候观测. 林业科学研究, 29(3):436-441.
(Tang X R, Li Y K, Xia H X, et al. 2016. The analysis of flowering phenology of clones in Guiyang Pinus massoniana second-generation seed orchard. Forest Research, 29(3):436-441.[in Chinese])
谢焰锋,张卓文,高大雄,等. 2013. 马尾松种子园花粉散发及其空间分布特征. 华中农业大学学报, 32(6):32-37.
(Xie Y F, Zhang Z W, Gao D X, et al. 2013. The distribution and spatial distribution of pollen in Pinus massoniana seed orchard. Journal of Huazhong Agricultural University, 32(6):32-37.[in Chinese])
杨汉波,张蕊,宋平,等. 2017. 木荷种子园无性系开花物候及同步性分析. 林业科学研究, 30(4):551-558.
(Yang H B, Zhang R, Song P, et al. 2017. Flowering phenology and synchronization of clones among plant ages in a seed orchard of Schima superba. Forest Research, 30(4):551-558.[in Chinese])
张冬梅,沈熙环,张华新,等. 2004. 油松种子园交配系统的时空变化研究. 林业科学, 40(1):70-77.
(Zhang D M, Shen X H, Zhang H X, et al. 2004. Study on temporal and spatial change of the mating system in a seed orchard of Pinus tabulaeformis. Scientia Silvae Sinicae, 40(1):70-77.[in Chinese])
张华新,陈丛梅. 2001. 油松无性系开花物候特点的研究. 林业科学研究, 14(3):288-296.
(Zhang H X, Chen C M. 2001. Study on the characteristics of flowering phenology of Pinus tabulaeformis clones. Forest Research, 14(3):288-296.[in Chinese])
Askew G R, Blush T D. 1990. An index of phenological overlap in flowing for clonal seed orchards. Silvae Genetica, 39 (3/4):168-171.
Banziger M, Setimala P S, Hodson D. 2006. Breeding for improved abiotic stress tolerance in maize adapted to Southern Africa. Agricultural Water Management, 80(1/3):212-224.
Bilir N, Kang K S, Zang D, et al. 2004. Fertility variation and status number between a base population and a seed orchard of Pinus brutia. Silvae Genetica, 53(4):161-163.
Byram T D, Lowe W J, Megriff J A. 1986. Clonal and annual variation in cone production in loblolly pine seed orchards. Forestry Scientific, 32(4):1067-1073.
Codesido V, Merlo E, Fernandezlopez J. 2005. Variation in reproductive phenology in a Pinus radiata seed orchard in northern Spain. Silvae Genetica, 54(4/5):246-256.
Funda T, Chen C C, Liewlaksaneeyanawinc C, et al. 2008. Pedigree and mating system analyses in a western larch (Larix occidentalis Nutt.) experimental population. Annals of Forest Science, 65:705.
Funda T, Lstiburak M, Lachout P, et al. 2009. Optimization of combined genetic gain and diversity for collection and deployment of seed orchard crops. Tree Genetics & Genomes,5(4):583-593.
Gunaga R P, Vasudeva R. 2009. Overlap index:a measure to assess flowering synchrony among teak (Tectona grandis Linn. f) clones in seed orchards. Current Science, 97(6):941-946.
El-Kassaby Y A. 1984. Reproductive phenology and its impact on genetically improved seed production in a Douglas-fir seed production in a Douglas-fir seed orchard. Silvae Genetica, 33(4):120-125.
El-Kassaby Y A, Reynolds S. 1990. Reproductive phenology, parental balance and supplemental mass pollination in a Sitka spruce seed orchard. Forest Ecology Management, 31:45-54.
El-Kassaby Y A, Funda T, Lai B S K. 2010. Female reproductive success variation in a Pseudotsuga menziesii seed orchard as revealed by pedigree reconstruction from a bulk seed collection. Journal of Heredity, 101(2):164-168.
Torimaru T, Wang X R, Fries A, et al. 2009. Evaluation of pollen contamination in an advanced scots pine seed orchard. Silvae Genetica, 58(5/6):262-269.

[1]	叶钰倩, 赵家豪, 刘畅, 关庆伟. 间伐强度对马尾松人工林根际与非根际土壤中性糖特征的影响[J]. 林业科学, 2019, 55(8): 28-35.
[2]	邓秀秀, 肖文发, 曾立雄, 雷蕾, 施征. 马尾松幼苗光合产物的运输与分配特征[J]. 林业科学, 2019, 55(7): 27-34.
[3]	金国庆, 张振, 余启新, 冯随起, 丰忠平, 赵世荣, 周志春. 马尾松2个世代种子园6年生家系生长的遗传变异与增益比较[J]. 林业科学, 2019, 55(7): 57-67.
[4]	朱嘉磊, 薄慧娟, 李璇, 文春燕, 王江, 聂立水, 田菊, 宋莲君. 不同毛白杨无性系林分蓄积量的长期水氮耦合效应[J]. 林业科学, 2019, 55(5): 27-35.
[5]	李亚藏, 冯仲科. 气候敏感的马尾松生物量相容性方程系统研建[J]. 林业科学, 2019, 55(5): 65-73.
[6]	王好运, 吴峰, 朱小坤, 谢维斌. 叶型对马尾松幼苗生长及叶绿素荧光特征的影响[J]. 林业科学, 2019, 55(3): 183-192.
[7]	陈金磊, 方晰, 辜翔, 李雷达, 刘兆丹, 王留芳, 张仕吉. 中亚热带2种森林群落组成、结构及区系特征[J]. 林业科学, 2019, 55(2): 159-172.
[8]	罗晓蔓, 丁贵杰, 王艺. 菌根化马尾松苗木根际土壤浸提物有效成份及其对种子萌发的影响[J]. 林业科学, 2018, 54(8): 32-38.
[9]	金玲, 刘明国, 董胜君, 吴月亮, 张欣. 97个山杏无性系的遗传多样性及SSR指纹图谱[J]. 林业科学, 2018, 54(7): 51-61.
[10]	姚虹宇, 刘亚敏, 张盛楠, 刘玉民, 周文颖, 王针针. 外源柠檬酸对铝胁迫下马尾松生理特性的影响[J]. 林业科学, 2018, 54(7): 155-164.
[11]	王晴, 齐建东, 崔晓晖, 李伟. 改进型遗传算法在种子园无性系配置设计中的应用[J]. 林业科学, 2018, 54(4): 30-37.
[12]	魏永成, 刘青华, 周志春, 徐六一, 陈雪莲, 郝焰平. 不同抗性马尾松接种松材线虫后针叶内化学信号物质的变化[J]. 林业科学, 2018, 54(2): 119-125.
[13]	辜夕容, 倪亚兰, 江亚男, 贾豪. 接种双色蜡蘑对酸性铝胁迫下马尾松幼苗生长、养分和铝吸收与分布的影响[J]. 林业科学, 2018, 54(2): 170-178.
[14]	尹焕焕, 刘青华, 周志春, 余启新, 丰忠平. 马尾松产脂性状与生长性状的无性系变异及相关性[J]. 林业科学, 2018, 54(12): 82-91.
[15]	高尚坤, 肖文发, 曾立雄, 雷蕾, 黄志霖, 王松. 马尾松人工林干扰对土壤微生物群落结构的短期影响[J]. 林业科学, 2018, 54(12): 92-101.