中国特有植物血水草开花物候与生殖特性

于2008年3-5月对分布在井冈山的血水草(Eomecon chionantha Hance )5个自然种群的开花物候进行了观察,运用开花振幅、相对开花强度和开花同步性等指数研究了其开花物候特征及其对该种生殖成功的影响.结果表明:血水草开花时间为3月下旬-5月上旬,种群花期历时24 ～46 d,个体平均开花持续时间为11～21 d,单花花期一般为3～5d;井冈山血水草种群的开花物候进程呈单峰曲线模式具有一个开花高峰期,表现出一种“集中开花模式”;与大多数亚热带植物一样,血水草具有较低的相对开花强度,分布频率集中在10％ ～30％.开花物候指数与生殖间的相关分析结果表明:始花时间与花期持续时间呈显著负相关,而与开花数和坐果率呈显著正相关;花期持续时间与开花数和坐果率呈显著正相关;同步性指数与始花时间、开花数、花期持续时间呈负相关.血水草“集中开花模式”是其在长期的进化过程中适应周围气候条件及生境的一种生殖保障.     

巫山淫羊藿开花物候与生殖特征

研究巫山淫羊藿(Epimedium wushanense)3个种群的开花物候进程和生殖特征,分析了不同种群中的花部特征、开花物候指数和结实率差异,以及开花物候指数对巫山淫羊藿生殖成功的影响。结果表明:巫山淫羊藿花期为3月初到4月中下旬,种群开花一般历时22～27d;单株花期(花序)约12～17d;单花花期一般为3～4d。3个种群的个体水平的开花振幅曲线呈单峰型曲线,均具有较高的开花同步指数,表现出一种集中开花式样。相关分析表明:坐果数与开花高峰期、终花期、花期持续时间和花蕾数均呈极显著正相关,但坐果数与始花期无相关关系。开花物候变异系数分析表明:3个种群中花期持续时间、单花持续时间、终花期、开花高峰期和坐果数差异极显著;总花数、开花振幅和结实率差异显著;开花同步指数和始花期无显著差异性。3个种群中除同步性指数外,其余指数的变异系数均有差异,此外,巫山淫羊藿中结实率受到距的长短的影响。表明巫山淫羊藿的开花物候和生殖特征受到微环境的影响,同时生殖特征还受到花部特征距的影响。     

准噶尔无叶豆的开花物候与生殖特征

 为了研究沙漠稀有植物准噶尔无叶豆(Eremosparton songoricum)的开花物候特征及其对生殖成功的影响, 2005和2006年连续两年对其自然种群的开花物候和开花过程中的花部表型变化进行了观察, 并运用相对开花振幅、开花强度和开花同步性等开花物候指数研究了开花物候特征。结果表明: 准噶尔无叶豆在5月下旬至6月中下旬开花, 其种群、个体、花序和单花的花期分别历时26~29 d、8~10 d、5~7 d和2~3 d。单花开花进程依其形态和散粉特征可分为散粉前期、散粉初期、散粉盛期和凋谢期4个时期。其个体水平的开花物候进程(开花振幅曲线)呈渐进式单峰曲线, 具有很高的开花同步指数, 表现出一种集中开花的模式。开花物候指数与座果数之间的相关分析结果表明, 始花日期与花期持续时间存在负相关关系, 而与开花数和座果数存在正相关关系; 花期持续时间与开花数和座果数存在显著正相关关系。准噶尔无叶豆个体开花物候在很大程度上是由其遗传因子决定的, 而开花物候在年度间的变异, 可能是由于荒漠气候的差异(主要是水分和温度的差异)所引起的。作为沙漠窄域分布特有种, 准噶尔无叶豆在环境和人为干扰的双重选择压力下, 为了吸引更多的传粉者访问而达到生殖成功, 形成了大量集中开花的模式。     

濒危植物长柄双花木开花物候与生殖特性

研究了长柄双花木开花过程中花部表型的变化。连续4a对其野生种群、1a对人工种群的开花物候进行了观察,并运用相对开花强度和同步性等开花物候指数分析了开花物候对其生殖的影响。结果如下：长柄双花木开花时间为9月上、中旬至11月中、下旬;单花花期一般为6～7d,单花依其形态和散粉特征可以分为4个时期：散粉前期、散粉初期、散粉盛期和凋谢期。个体开花持续时间49～55d,种群花期历时63～71d。种群内不同年度间开花物候指数没有显著差异,而种群间则存在显著差异,野生种群开花进程为渐进式单峰曲线。人工种群则为“钟”形曲线,二者均属于“集中开花模式”。长柄双花木具有2个相对开花强度的分异趋势,这种分异趋势具有进化意义。开花物候指数与生殖间的相关分析表明,始花时间与开花数量、座果率及花期长度之间均具显著负相关关系,而开花数量与花期长度之间则呈显著正相关,但均为线性相关。长柄双花木开花物候在种群间的差异和种群内年度间的相似性说明,其开花时间可能是由与其相关的复杂的微生境特征和(或)由其遗传因子决定的,同时也反映了种群间的遗传分异和种群内个体间的遗传一致性。作为一种濒危物种,长柄双花木在这种环境的选择压力之下,形成了“大量、集中开放的花”的开花模式,吸引到更多的传粉者的访问,从而达到生殖成功。     

金城山柔毛淫羊藿的开花物候与生殖特性

采用实地观测的方法,对南充市金城山三个不同生境中柔毛淫羊藿的开花物候特征及其生殖特性进行了研究。结果表明:柔毛淫羊藿花期为3月上旬至4月上旬,其种群、个体、花序和单花的花期分别历时30~41、22~34、9~18和4~8 d。三个生境中柔毛淫羊藿种群的开花物候进程基本相同,均呈单峰集中开花式样,因而能够吸引更多的传粉者访问而达到生殖成功。开花物候指数与坐果数之间的相关分析结果表明,坐果数与始花日期存在显著的负相关关系,与花期持续时间和开花数均呈极显著的正相关关系。揭示了药用植物柔毛淫羊藿的开花物候特征与生殖特性。     

大花百子莲的开花物候与生殖特性

连续2年对引种植物大花百子莲在中国上海市人工种群的开花物候、结实情况进行观测记录,从不同水平分析了大花百子莲的开花物候对其生殖的影响。结果显示:（1）大花百子莲在引种地的开花时间为6月初至7月末;种群花期历时40 d左右,单株花期在14～31 d波动,单花寿命主要为2～3 d;2年的开花振幅平均在6朵·株^-1·d^-1左右,花朵开放百分率值在3.69%~4.87%左右,平均开花式样为11~17朵。（2）大花百子莲种群内2007年比2008年的各项开花物候指标均提前6～9 d;种群开花进程为渐进式的双峰曲线;种群花期重叠时间较长,2年的平均开花同步指数分别为0.663、0.695;植株个体相对开花强度主要分布频度为50%～70%。（3）开花物候指数与座果率的相关分析表明,始花时间与开花数目、座果数、花期长度呈显著负相关关系,开花数目与座果数、花期长度以及花期长度与座果数均呈显著正相关关系,同一花序内单花所发育成果实的数量与单花开放时间呈极显著负相关关系。研究表明,大花百子莲始花时间早的植株比始花时间晚的植株花期更长,开花数目多的植株比开花数目少的植株花期更长,花期长的植株比花期短的植株座果率更高;而且在同一花序上,越早开放的单花其结实的可能性越大。作为引种植物,大花百子莲开花物候年度间具有相似性,说明其在引种地可以适应环境压力,形成稳定的开花时间与开花模式;较长的花期重叠和大量的开花数目可以吸引较多的传粉者访问,为其生殖成功奠定了良好基础。     

川南城市园林中紫薇开花物候变化特征及其影响因素

为了明确城市园林中紫薇(Lagerstroemia indica)开花物候的变化特征,探讨花期影响因素和指导开花植物配置,对川南城市园林栽培的紫薇植株进行定期观测,记录了紫薇的2011—2014年开花物候,分析个体、群体水平上物候事件的差异以及植株大小和气候因子的影响。结果表明:紫薇个体在6月初至9月中旬进入花期,末花期多在10月,花期持续8~137 d,具有60~90 d花期的植株比例最高;不同年份开花植株比例和物候特征存在一定差异,种群水平花期持续时间最短为2014年的106 d,最长为2012年的130 d;但开花植株数量的时间格局总体相似,始花期与花期持续时间之间相关性显著;基径显著影响紫薇的开花物候特征,较大的植株往往开花较早,并且具有更长的花期;紫薇的盛花期多集中在7—9月;开花植株数量与前一个月的平均气温呈显著正相关,与同期温度、降雨量相关性不显著;紫薇开花物候在气候因子影响下年际间存在明显差异,也表现出一定规律性格局;园林中多样化的个体物候有利于维持群体水平上花期的观赏性,选择大植株可获得较稳定的观赏效果。     

蒙古莸的开花物候与生殖特征

通过对蒙古莸自然种群和人工种群的开花物候进程观察,统计不同种群的结实率,分析开花物候对其生殖成功的影响。结果表明:(1)蒙古莸花期在7月末至9月中旬,人工种群较自然种群的开花物候明显提前,其中始花期提早4～5d,但两个种群的花期持续天数基本一致。(2)蒙古莸个体间具有较高的开花同步性,不同种群蒙古莸植株的开花同步性指数均大于0.80,且自然种群略高;晴好天气下绝大多数花朵都集中在上午10:00以前开放,阴雨天则延迟开放或者不开放,这种"集中开花模式"增加了传粉者的访问频率,是蒙古莸提高生态适应性、保障其生殖成功的一种表现。(3)开花物候指数与结实数之间的相关分析表明,花序水平上,开花数及花期持续时间与结实数呈极显著正相关关系。     

浙江低山地区多用途植物无患子的开花物候特征

无患子(Sapindus mukorossi Gaertn.)是我国长江以南地区传统的重要绿化树种,其果皮富含皂苷,种仁富含油脂,是国家林业局审定的新型木本油料树种之一。为研究多用途树种无患子在浙江低山地区的开花特征,2012年和2013年连续两年对位于浙江省天台县9年生无患子人工林在群体、个体、花序和单花水平进行开花物候观测和比较,并运用开花日期、相对开花强度和同步性等指数研究了无患子开花物候特征。观察结果显示:无患子花呈浅黄白色,花的类型有雄花和两性花,没有发现雌花。雄花较两性花大(花径分别为5.09 mm和3.72 mm),雄蕊多为8枚,个别7或9、10枚;雌蕊退化仅留下浅绿色凸起。两性花花萼稍抱拢,花药藏于花被片下,雄蕊大多8枚,极少数7枚或9枚,柱头高于花药并伸出花苞,子房一般具3室,极少数4室或仅2室。无患子2012年的开花进程略早于2013年,其花期集中在在5月中旬至6月上旬,单花从花蕾膨大到花朵凋谢一般为8—9 d。在2012年和2013年,无患子在群体、个体和花序水平的花期约为30 d、20 d、11 d和28 d、19 d、13 d。个体水平的开花振幅均呈单峰曲线,年际间相似性较高;开花同步性在个体水平同步性较高(同步指数为0.868),表现出一种大量、集中的开花式样;相对开花强度在单株间分布范围相对宽泛,但主要分布在30%—40%,在年际间和年际内均呈现极显著差异。花期同步指数在两年的变异范围分别是0.81—0.97和0.70—0.98,不同单株开花同步性在年际内差异极显著,但在年际间差异性则不显著。由此可见,无患子的生殖资源分配存在明显的时空差异,较长的花期可以减少非法花粉的干扰、保持其种群基因多样性,遗传因子是决定无患子开花物候的主要因素,生态环境对无患子开花物候的影响还需进一步研究,本研究以期为探索无患子开花的主要限制因子奠定基础。     

多枝柽柳春夏两季开花物候特征与生殖特性

为了研究多枝柽柳的两季开花物候特征与生殖特性,对分布于古尔班通古特沙漠南缘莫索湾荒漠区的多枝柽柳自然种群各水平的开花物候指数、开花过程中的花部特征变化和结实特性进行了观察和统计。结果表明:(1)多枝柽柳春花期为5月下旬至6月上旬,表现为"集中开花模式",夏花期为6月中旬至9月上旬,表现为"持续开花模式"。(2)多枝柽柳春、夏花期的群体、个体、花序和单花水平的花期持续时间分别为14d、10d、3d、1d和85d、77d、2d、1d。(3)花序水平上夏花期始花日期、开花持续时间、开花数和座果数两两之间均存在显著相关关系。(4)两季花期间单花水平的开花进程与形态结构没有明显差异。(5)春花期的结实率显著高于夏花期,但两季花期结籽率差异不显著。(6)春花期昆虫访花次数显著高于夏花期。(7)两季花期的花粉活力没有明显差异,春花期的柱头可授性持续时间比夏花期长。研究认为,古尔班通古特沙漠南缘莫索湾荒漠区的生境条件恶劣,多枝柽柳特殊的春、夏两季开花结实特性在一定程度上提高了其生殖成功的可能性,是对特殊生境的适应性表现。     

Phenological synchrony affects interaction strength of an exotic weevil with Platte thistle,a native host plant

Phenological synchrony of a consumer population with its resource populations is expected to affect interaction intensity. We quantified phenological variation and synchrony of populations of an invasive Eurasian flower head weevil, Rhinocyllus conicus, that consumes florets, ovules, and seeds of developing flower heads of a native North American thistle, Cirsium canescens, in Sand Hills prairie in Nebraska, USA. Variation in timing of adult activity among weevil populations was larger than variation in timing of flower head development among C. canescens populations, and it drove the observed variation in the phenological synchrony between weevil and host plant populations. Furthermore, the degree of phenological synchrony between populations was significant in explaining variation in weevil egg load on the newly acquired host plant. Because population growth of C. canescens is limited by predispersal seed losses to floral herbivores, variation in the synchrony of herbivore and plant flowering will affect the density of the plant population. These results provide strong quantitative support for the hypothesis that the synchrony of insect activity with plant resources can determine the magnitude of impact of floral herbivores on their host plant populations.     

Consequences of variation in flowering phenology for seed head herbivory and reproductive success in Erigeron glaucus (Compositae)

Summary We examined the relationship between flowering phenology, reproductive success (seed production only), and seed head herbivory for 20 similarly sized clones of Erigeron glaucus growing at Bodega Bay Reserve, northern California, USA. Although clones tended to reach peak flowering on the same date, they differed in the proportion of their total flowers produced around that date (flowering synchrony). Clones also differed in the number and density of flower heads presented at any one time to pollinators and herbivores (floral display). Both of these characteristics had consequences for herbivory and plant reproductive success. The proportion of flower heads damaged by insect herbivores was greater for clones that concentrated flowering activity during the main flowering period for the population as a whole (high synchrony) compared to clones that spread flowering out temporally. The primary reason for this result was that clones with low flowering synchrony produced a significant proportion of their flower heads during the fall and therefore, escaped attack by the tephritid fly, Tephritis ovatipennis. Clones with intermediate synchrony had lower seed success (total number of viable seeds produced over the year) than clones with either low or high synchrony. The proportion of flower heads damaged by insect herbivores and number of tephritid flies reared from flower heads were both negatively correlated to floral display while seed head mass and germination rates were positively related to display. Thus, clones which produced dense floral displays were favored both in terms of reduced herbivory and increased successful seed production.     

Dissecting components of flowering pattern: size effects on female fitness

Flowering synchrony is essential for plant reproductive success, especially in the case of small‐sized populations of self‐incompatible species. Closely related to synchrony, flowering intensity influences pollinator attraction and pollinator movements. Thus, a high flowering intensity may increase pollinator attraction but, at the same time, may also increase the probability of geitonogamous pollinations. Depending on the mating system, the female fitness of plants in small populations may be affected by both the positive effects of higher flowering synchrony and pollinator attraction and the negative effects of geitonogamous pollinations induced by a high flowering intensity. It was hypothesized that different‐sized plants in a population would show contrasting flowering patterns, resulting in differences in pollinator behaviour. These influences could result in differences in mating and female reproductive success. This hypothesis was tested by studying the flowering pattern of Erodium paularense (Geraniaceae), a rare and endangered endemic of central Spain. The temporal distribution of flower production was explored throughout the reproductive season, and the probability of xenogamy and geitonogamy and their relationship to plant size and fitness components were calculated. The analysis of this partially self‐compatible species showed diverse flowering patterns related to different plant sizes. Small plants produced a larger number of seeds per fruit in spite of having lower values of flowering synchrony. By contrast, large plants produced a larger number of seeds from geitonogamous pollinations. The effect of different flower displays and outcrossing rates on seed set varied throughout the season in the different groups. Our findings highlight the relevance of individual plant size‐dependent phenology on female reproductive success and, in particular, on the relationship between flowering synchrony and fitness. © 2008 The Linnean Society of London, Botanical Journal of the Linnean Society, 2008, 156 , 227–236.     

Vulnerability and determinants of reproductive success in the narrow endemic Antirrhinum microphyllum (Scrophulariaceae)

The breeding system and flowering phenology of the narrow endemic Antirrhinum microphyllum (Scrophulariaceae) were studied in order to assess the main factors affecting female reproductive success and to identify existing or potential threats to the viability of its populations. Hand-pollination experiments showed that A. microphyllum is an allogamous self-incompatible species. In both populations studied, the flowering season was 4 mo long and mean flowering duration per plant was about 1 mo. Peak flower production took place between mid-April and mid-May and overlapped with the period of activity of the main pollinator, Rhodanthidium sticticum (Megachilidae). Estimated mean number of seeds produced per plant was 9391, showing that population viability is not presently limited by seed output. The study of the direct and indirect effects of plant size, phenological traits (first flowering date, flowering duration, and flowering synchrony), and distance to neighbor plants on reproductive success was performed using structural equation modeling (SEM). In both populations, number of flowers and plant size were the main factors that determined the total number of fruits produced by a plant. First flowering date and flowering synchrony also affected fruit production. Multisample comparison of path coefficients for the two populations rejected the possibility that reproductive patterns could be described by one single model.     

海南凤仙花不同海拔种群的传粉生物学

凤仙花属(Impatiens)植物具有极为广泛的多样性和类型各异的特化传粉者, 被誉为“双子叶的兰花”, 受到众多传粉生物学家的关注。本文以海南特有种海南凤仙花(Impatiens hainanensis)为研究对象, 对3个不同海拔梯度的种群进行了开花生物学特性和开花物候、花器官结构、花粉活力和柱头活性、传粉者种类和访花行为及繁育系统的比较研究。结果表明: 单花花期4.10 ± 0.46 d, 雄性期和雌性期分别约为3.15 ± 0.24 d和0.95 ± 0.36 d; 种群开花峰期在8月初, 高海拔种群的花期高峰相对滞后。低、中海拔种群花粉活力呈现先升高后下降的趋势, 以开花第2 d花粉活力最高; 高海拔种群花粉活力随开花时间推移逐渐下降; 柱头活性随开花时间的推移而增强, 高海拔种群开花各天次均较低、中海拔种群低。主要传粉昆虫为黄黑无垫蜂(Amegilla leptocoma)和绿条无垫蜂(A. zonata), 低、中海拔种群以黄黑无垫蜂为主, 高海拔种群以绿条无垫蜂为主。未观察到自动自花授粉和无融合生殖现象, 人工授粉能明显增加坐果率(75-90%), 自然坐果率在高海拔种群相对较低(40-60%), 说明存在较强的传粉者限制。海南凤仙花的保护需要同时关注其有效传粉者的保护, 促进有效传粉昆虫在不同海拔种群之间的往来, 保证种群间的花粉流与种子流, 维持海南凤仙花的种群遗传多样性与有效种群大小。     

Positive effects of flower abundance and synchronous flowering on pollination success,and pollinia dispersal in rewardless Changnienia amoena (Orchidaceae)

Pollination success and pollen dispersal in natural populations depend on the spatial‐temporal variation of flower abundance. For plants that lack rewards for pollinators, pollination success is predicted to be negatively related to flower density and flowering synchrony. We investigated the relationships between pollination success and flower abundance and flowering synchrony, and estimated pollinia dispersal distance in a rewardless species, Changnienia amoena (Orchidaceae). The results obtained in the present study revealed that male pollination success was negatively influenced by population size but was positively affected by population density, whereas female pollination success was independent of both population size and density. Phenotypic analysis suggested that highly synchronous flowering was advantageous through total pollination success, which is in contrast to previous studies. These results indicate that pollination facilitation rather than competition for pollinator visits occurs in this rewardless plant. The median distance of pollinia dispersal was 11.5 m (mean distance = 17.5 m), which is comparable to that of other rewardless plants but longer than for rewarding plants. However, pollen transfer occured mainly within populations; pollen import was a rare event. Restricted gene flow by pollinia and seeds probably explains the previous population genetic reporting a high degree of genetic differentiation between populations. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 99 , 477–488.