养分供应对3种舞花姜属植物繁殖方式的影响

doi:10.17521/cjpe.2006.0019

摘要/Abstract

摘要：

该研究选用的3种舞花姜属植物中,毛舞花姜(Globba barthei)和双翅舞花姜(G. schomburgkii)自然条件下开花不结实,以珠芽进行繁殖;异果舞花姜(G. racemosa)则同时以种子和珠芽进行繁殖。在人工栽培条件下,高养分处理显著增加毛舞花姜的珠芽干重((1.11±0.10) g vs. (3.08±0.69) g,p=0.010 7)、珠芽数量((30.58±2.92) vs. (74.74±9.73),p=0.000 4)、珠芽大小((10.5±1.48) mg vs. (53.50±11.42) mg,p=0.001 5)、植株营养体重((3.99±0.23) g vs. (9.67±1.17) g,p=0.000 2)和双翅舞花姜的珠芽数量((51.74±3.64) vs. (108.71±21.52),p=0.018 1)。不同养分条件下两种舞花姜的开花数量无显著差异。人工去除珠芽、花对两种舞花姜植株当年生花和珠芽的数量无显著影响(p<0.05)。自然条件下异果舞花姜不同居群间珠芽大小、珠芽数、珠芽重、果实重、种子数和营养体重等均存在极显著差异(p<0.001)。异果舞花姜各居群植株珠芽数和营养体重(r=0.901,p<0.05)、珠芽重和珠芽大小 (r=0.849,p<0.05) 呈显著正相关;果实重和种子数(r=0.998,p<0.05) 呈显著正相关。土壤因子主成分分析表明前3个主成分提供的信息量分别为50.575%、18.204% 和11.883%,其中第一主成分中的全氮(0.959)、速效氮(0.885)和有机质(0.821)负荷量最大,第二主成分中土壤速效磷(0.824)负荷量最大。植株营养体重和土壤速效磷极显著正相关(r=0.906,p<0.01),珠芽大小与全氮(r=0.798)、速效氮(r=0.780)和有机质(r=0.821)均呈显著正相关(p<0.05)。果实重和种子数与土壤因子相关性不显著(p<0.05)。3种舞花姜的无性繁殖器官更易受到养分供应的影响,有性繁殖器官对养分供应变化响应不显著,有性和无性繁殖之间似不存在补偿关系。

关键词: 舞花姜属, 有性繁殖, 无性繁殖, 营养生长, 土壤因子

Abstract:

Among the three Globba species in this study, Globba barthei and G. schomburgkii propagated only by bulbils and with no seed set while G. racemosa propagated by both seeds and bulbils under natural conditions. The aim of this study was to understand the effect of nutrition supply on the relative levels of sexual and asexual reproduction of these three species in both natural and artificial conditions and to determine whether there is compensatory mechanism that enhances sexual reproduction when asexual reproduction is constrained and vise versa.
For G. barthei and G. schomburgkii, young seedlings propagated by bulbils were planted in flowerpots (30 cm in diameter) and placed under a rain and insect proof greenhouse in XTBG. The soil medium in the flowerpots was composed of forest soil (2), coarse sand (2), peat (2) and scattered brick (1). Treatments in the experiment included: 1) high-level fertilizer supply consisted of 150 ml per pot of a 5% mixed fertilizer (N:P:K=15:15:15) once every two weeks; 2) high-level fertilizer supply (same as treatment (1)) plus removal of flowers buds everyday; 3) high-level fertilizer supply (same as treatment (1)) plus removal of bulbils once a week; 4) low-level fertilizer supply (only water supplied) 5) low-level fertilizer plus removal of flower buds everyday; 6) low-level fertilizer plus removal of bulbils once a week. The results showed that 1) high-level fertilizer supply significantly increased bulbil dry weight ((1.11±0.10) gvs. (3.08±0.69) g,p=0.010 7), bulbil number ((30.58±2.92) vs. (74.74±9.73),p=0.000 4), bulbil size ((10.5±1.48) mg vs. (53.50±11.42) mg,p=0.001 5) and vegetative organ dry weight ((3.99±0.23) g vs. (9.67±1.17) g,p=0.000 2) of G. barthei and the bulbil number ((51.74±3.64) vs. (108.71±21.52),p=0.018 1) of G. schomburgkii; 2) different levels of fertilizer supply did not significantly affect the flower number of the two species (p>0.05); 3) removing bulbils or flowers had no significant effect on the number of flowers or the bulbils in the current year (p>0.05).
ForG. racemosa, we collected 30 individuals from six native populations throughout Yunnan Province and measured the biomass and size of sexual and asexual organs of each individual. Meanwhile, we collected three soil samples from each of the six populations and analyzed the physical and chemical characteristics of the soil samples. The bulbil size, bulbil number, bulbil dry weight, fruit dry weight, seed number and vegetative organ dry weight among the six populations varied significantly (p<0.001). Bulbil number was positively correlated to vegetative organ dry weight (r=0.901, p<0.05), bulbil dry weight was positively correlated to bulbil size (r=0.849, p<0.05). Fruit dry weight was positively correlated to seed number(r=0.998; p<0.05). A principal component analysis on soil factors of the six populations indicated that the three principal factors could explain 50.58%, 18.20% and 11.88% of the total variation. Total nitrogen, available nitrogen and soil organic matter wese the main factors of the first principal component, and the loading values were 0.959, 0.885 and 0.821, respectively. Available phosphorous was the main factor for the second factor with a loading value of 0.824. Vegetative organ dry weight had a significant positive relationship with available phosphorous (r=0.906, p<0.01), bulbil size was positively related to total nitrogen (r=0.798, p<0.05), available nitrogen (r=0.780, p<0.05) and soil organic matter(r=0.821, p<0.05). Fruit dry weight and seed number were not significantly correlated to any soil factors.
As a whole, the asexual organs of the threeGlobba plants were more sensitive to different levels of nutrient supply whereas the sexual organs did not show any significant response. Compensatory mechanisms between sexual and asexual reproduction were not detected in these three species.

Key words: Globba, Sexual reproduction, Asexual reproduction, Vegetative growth, Soil factors

高秀霞, 陈进, 周会平, 白智林. 养分供应对3种舞花姜属植物繁殖方式的影响. 植物生态学报, 2006, 30(1): 132-139. DOI: 10.17521/cjpe.2006.0019

GAO Xiu-Xia, CHEN Jin, ZHOU Hui-Ping, BAI Zhi-Lin. THE EFFECT OF NUTRIENT SUPPLY ON SEXUAL AND ASEXUAL REPRODUCTION OF THREE SPECIES OF GLOBBA. Chinese Journal of Plant Ecology, 2006, 30(1): 132-139. DOI: 10.17521/cjpe.2006.0019

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图/表 7

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居群 Population	经纬度 Latitude and longitude	海拔(m) Altitude	居群大小 (hm²) Population size	土壤水分状况 Soil water supply	受干扰程度 Degree of disturbance	土壤类别 Soil group
1	22°53' N, 99°48' E	1 700	5~10	丰富Rich	中Slight	红壤Red earths
2	24°05' N, 99°44' E	1 873	5~10	少Little	强Intense	黄棕壤Yellow brown earths
3	24°04' N, 97°48' E	1 136	10~20	丰富Rich	少Little	黄壤Yellow earths
4	24°25' N, 97°50' E	1 456	10~20	极丰富Very rich	少Little	红壤Red earths
5	24°35' N, 97°40' E	1 352	10~20	少Little	强Intense	黄红壤Yellow red earths
6	24°56' N, 102°29' E	2 100	10~20	极少Very little	中Slight	黄棕壤Yellow brown earths

居群 Population	经纬度 Latitude and longitude	海拔(m) Altitude	居群大小 (hm²) Population size	土壤水分状况 Soil water supply	受干扰程度 Degree of disturbance	土壤类别 Soil group
1	22°53' N, 99°48' E	1 700	5~10	丰富Rich	中Slight	红壤Red earths
2	24°05' N, 99°44' E	1 873	5~10	少Little	强Intense	黄棕壤Yellow brown earths
3	24°04' N, 97°48' E	1 136	10~20	丰富Rich	少Little	黄壤Yellow earths
4	24°25' N, 97°50' E	1 456	10~20	极丰富Very rich	少Little	红壤Red earths
5	24°35' N, 97°40' E	1 352	10~20	少Little	强Intense	黄红壤Yellow red earths
6	24°56' N, 102°29' E	2 100	10~20	极少Very little	中Slight	黄棕壤Yellow brown earths

土壤因子Soil factors	主分量1 Compent 1	主分量2 Compent 2	主分量3 Compent 3
pH值 pH value	0.594	0.319	0.649
有机质Organic matter	0.821^*	0.331	-0.303
速效氮Available nitrogen	0.885^*	0.140	-0.336
速效磷Available phosphorous	-0.223	0.824^*	0.305
速效钾Available potassium	0.726	0.005	0.104
全氮Total nitrogen	0.959^*	0.094	-0.201
全磷Total phosphorous	0.742	-0.265	0.280
全钾Total potassium	-0.436	0.6847	-0.319
各分量贡献率 Rate of variance (%)	50.575	18.204	11.883
累计贡献率 Cumulative rate (%)	50.575	68.779	80.662

土壤因子Soil factors	主分量1 Compent 1	主分量2 Compent 2	主分量3 Compent 3
pH值 pH value	0.594	0.319	0.649
有机质Organic matter	0.821^*	0.331	-0.303
速效氮Available nitrogen	0.885^*	0.140	-0.336
速效磷Available phosphorous	-0.223	0.824^*	0.305
速效钾Available potassium	0.726	0.005	0.104
全氮Total nitrogen	0.959^*	0.094	-0.201
全磷Total phosphorous	0.742	-0.265	0.280
全钾Total potassium	-0.436	0.6847	-0.319
各分量贡献率 Rate of variance (%)	50.575	18.204	11.883
累计贡献率 Cumulative rate (%)	50.575	68.779	80.662

	全氮 Total nitrogen	速效氮 Available nitrogen	速效磷 Available phosphorous	有机质 Soil organic matter
果实重FMA	-0.377	-0.467	-0.153	-0.210
种子数SNU	-0.398	-0.463	-0.114	-0.231
珠芽数BNU	-0.417	-0.462	0.724	-0.092
珠芽重BMA	0.403	0.392	0.777^*	0.604
珠芽大小BSI	0.798^*	0.780^*	0.388	0.821^*
繁殖体重RMA	-0.118	-0.218	0.366	0.190
营养体重VMA	-0.402	-0.379	0.906^**	-0.057
果实重/珠芽重FBM	-0.444	-0.599	-0.252	-0.270
果实重/营养体重FVM	-0.422	-0.612	-0.319	-0.259
珠芽重/营养体重BVM	0.672	0.740	-0.502	0.317
繁殖体重/营养体重RVM	0.253	0.116	-0.893^**	0.053