木瓜榕传粉生物学

 木瓜榕（Ficus auriculata Lour.）是雌雄异株植物,它只有通过大果榕小蜂（Ceratosolen emarginatus Mayr）传粉才能获得有性繁殖,大果榕小蜂也仅在木瓜榕雄果内产卵才得以繁衍后代。经两年来的实验和研究结果表明：木瓜榕繁殖能力在不同季节随进蜂量的多少而变化,雌树在4月和11月出现的两次结果高峰期与进蜂量最多的时期相遇;同时雄树与雌树在11月挂果高峰期重叠,导致该期进入雄果产卵的雌蜂量减少,进蜂量高峰推迟到部分雄果成熟、只有稀少接受果的3月下旬和4月上旬。木瓜榕在与大果榕小蜂互惠共生的进化历程中,逐渐完善了自身保证远交的繁殖机制,它们在不同程度上受到雌雄异熟、雌雄异株和短花柱雌花不亲和3种机制的共同作用。温湿度对大果榕小蜂访果行为有明显的影响,在温湿度变化缓和的早晚,有利于榕小蜂出行,雌蜂访果最为频繁。大果榕小蜂活动最佳的温湿度是：温度20～24 ℃之间、湿度85%～93%之间;温度高于29 ℃、湿度低于58% 或风雨天均不利于该蜂出行活动。榕小蜂日活动高峰的出现先后在不同季节略有差异,高温高湿的夏季榕小蜂活动出现早,7∶40达高峰;秋季榕小蜂活动推迟,高峰出现在11∶00;干凉的冬季最晚,13∶00才到达高峰。通过人工套袋、放蜂传粉试验,平均进8头的隐头果传粉效率最高,单果平均种子数量为11 247粒,结实率50.8%,未受精的败育花8 207朵;平均进蜂4头以下或10头以上的隐头果,由于花粉量不足或者雌蜂争夺资源的损伤使种子量下降,平均结实率分别达37.2% 和44.4%;放蜂试验结果与大量调查自然界中每果进蜂量和结实率的结果一致。     

西双版纳鸡嗉果榕小蜂繁殖和传粉行为

鸡嗉果榕 Ficus semicordata Buch.-Ham.ex J. E. Sm.是西双版纳地区常见的榕属植物,它是热带雨林生态系统中的一类先锋树种,当热带雨林被破坏后,它最先在林缘、沟谷和路边迅速生长起来,是热带和亚热带地区森林生态系统恢复初期一类重要物种。在西双版纳通过不同样地定树、定期生态学观察和室内剖查不同生长时期的鸡嗉果榕隐头果的方法,对榕小蜂繁殖和传粉行为进行了研究,结果表明,鸡嗉果榕雌雄异株,在西双版纳一年结2～3次隐头果,雌株隐头果内小花由榕小蜂传粉后产生种子。雄株则产生雄花和中性小花,中性小花专门供给传粉小蜂产卵繁殖后代。鸡嗉果榕小蜂Ceratosolen gravelyi Grandi是鸡嗉果榕唯一的传粉昆虫。传粉小蜂的雄蜂比雌蜂早羽化30～90 min,一部分雄虫羽化后,在虫瘿上爬动寻找雌蜂寄生的瘿花,一找到雌蜂寄生的瘿花,就咬破虫瘿的一个小口,把生殖器伸进瘿花与雌蜂交配,一部分雄蜂则在果肉上咬出蜂口。雌蜂交配后,顶大交配孔出蜂爬到雄花区采集花粉,然后,飞出寻找鸡嗉果榕雌花期的嫩隐头果传粉和繁殖后代。到鸡嗉果榕雌株传粉的小蜂能飞翔300～500 m,进果腔传粉行为长达5～27 h,传完粉3～5 h在果腔内死亡。到雄株上繁殖的小蜂一般飞翔在20～100 m左右近距离寻找嫩隐头果,进果腔产卵,每只小蜂在无干扰的情况下可产400多粒卵。除传粉榕小蜂外,在鸡嗉果榕雄株隐头果上还有4种植食、造瘿和复寄生等非传粉小蜂,它们对传粉小蜂的种群繁衍影响很大,常使传粉小蜂的种群数量降低25～70%。每个隐头果内进传粉小蜂量多少对鸡嗉果榕和榕小蜂繁殖有关,最佳进蜂量为3只,高或低于最佳进蜂量对鸡嗉果榕树和它的传粉小蜂繁殖均不利。     

聚果榕传粉榕小蜂传粉与产卵之间的权衡

【目的】榕树(Ficus)依赖专性榕小蜂(Agaonidae)传粉,同时为传粉榕小蜂提供繁衍后代的场所,两者形成动植物间经典的协同进化关系。在雌花期果内,榕小蜂需在有限的存活时间内完成传粉和产卵,而传粉榕小蜂如何在传粉与产卵之间进行权衡仍然是悬而未解的问题。本研究旨在明确传粉榕小蜂——一种栉颚榕小蜂Ceratosolen sp.在雌雄同株的聚果榕Ficus racemosa雌花期果内的行为活动及繁殖模式。【方法】借助测微尺测量聚果榕榕果雌花花柱长度与传粉榕小蜂(Ceratosolen sp.)产卵器长度,通过显微视频记录传粉榕小蜂在雌花期果内搜索、传粉及产卵行为;结合单果控制性引蜂试验,测定不同阶段榕小蜂个体大小、孕卵量、携粉量,以及雄花期最终繁殖的榕小蜂后代和榕果种子数量。【结果】聚果榕雌花花柱长度存在树间变异,榕小蜂产卵器长度比绝大多数的雌花花柱长,说明该小蜂可以产卵于大部分的雌花子房里。通常个体大的榕小蜂孕卵量更多,但个体大小与携粉量之间相关性不显著。观察发现,榕小蜂进入雌花期榕果内,前6 h集中产卵,可产下孕卵量的95%,平均搜索用时27 s,产卵用时46 s,此期间传粉行为少见,花粉筐中携带花粉量亦无明显变化;榕小蜂进果后6-24 h,主要执行传粉,其行为主动,连贯高效,单次传粉用时平均为2 s,最终可传完携粉量的80%。控制引蜂试验也证实榕小蜂进入榕果内前6 h主要执行产卵繁殖后代,之后6-24 h主要执行传粉以繁殖榕树种子。【结论】在雌雄同株的聚果榕雌花期榕果内,榕小蜂先产卵、后传粉。本研究首次展示了传粉榕小蜂在聚果榕雌花期榕果内的产卵和传粉行为,并获得与行为相匹配的产卵量和传粉繁殖量,反映了具主动传粉行为的榕小蜂在传粉和产卵之间存在时间和数量上的权衡。     

雌花期榕小蜂进入榕果的行为及其活动时间

在西双版纳,钝叶榕传粉榕小蜂Eupristina sp.和杨氏榕树金小蜂Diaziella yangi均在雌花期进入钝叶榕果内繁殖和传粉,比较研究它们进入榕果的行为和活动时间。结果显示:在搜寻苞片处进蜂口时,2种榕小蜂的种内均出现打斗行为,并且杨氏榕树金小蜂的打斗更为激烈,但种间没有打斗行为发生,杨氏榕树金小蜂总是等待钝叶榕传粉榕小蜂先期进入榕果,然后才跟随着进入。在搜寻和进入苞片口通道阶段,钝叶榕传粉榕小蜂均比杨氏榕树金小蜂花费较长时间;而在果腔内产卵、传粉的时间,2种榕小蜂均最多不超过3d。相似的进蜂过程和活动时间,可能是2种榕小蜂与寄主榕树长期协同进化的结果。     

薜荔榕小蜂对薜荔和爱玉子雌花期榕果挥发物的行为反应

薜荔和爱玉子均属雌雄异株桑科榕属植物,两者互为原变种与变种的关系,分别与薜荔传粉小蜂和爱玉子传粉小蜂(二者互为隐存种)建立了专性共生关系,榕树榕果挥发物在维系传粉小蜂与其寄主的共生关系上起着重要作用。利用Y型嗅觉仪测定薜荔榕小蜂(薜荔和爱玉子的传粉小蜂)对薜荔和爱玉子雌花期榕果挥发物的行为反应。结果表明:(1)雌花期果型的大小对薜荔榕小蜂行为反应无显著影响,薜荔大、小果型雌花期雌(雄)榕果挥发物对其传粉小蜂均具有强烈的吸引作用;(2)榕果挥发物浓度影响薜荔榕小蜂行为反应,薜荔、爱玉子雌花期雌(雄)榕果挥发物对其传粉小蜂的吸引作用均可能存在阈值反应,即榕果挥发物浓度未超过阈值时,雌花期榕果挥发物对传粉小蜂的吸引作用与挥发物浓度成正相关关系,而一旦超过阈值,榕果挥发物对传粉蜂的吸引作用显著下降,表明寄主榕果挥发物浓度影响传粉小蜂的寄主定位;(3)薜荔传粉小蜂对低浓度爱玉子雌花期雌(雄)榕果挥发物、爱玉子传粉小蜂对低浓度薜荔雌花期雌(雄)榕果挥发物均既无趋向也无驱避行为;薜荔传粉小蜂对高浓度的爱玉子雌花期雌(雄)榕果挥发物表现为显著的驱避行为,而爱玉子传粉小蜂对高浓度薜荔雌(雄)雌花期榕果挥发物表现为显著的趋向行为,因此,薜荔传粉小蜂与爱玉子传粉小蜂存在寄主专一性不对称现象,爱玉子传粉小蜂进入薜荔雌(雄)果内传粉或产卵的可能性较大,而福州地区的薜荔传粉小蜂可能难以进入爱玉子雌(雄)果内传粉或产卵。本研究结果将为榕-蜂共生体系的化学生态学理论研究以及爱玉子栽培提供科学依据。     

影响对叶榕及其传粉者繁殖的生态学因素

在西双版纳,分别统计了对叶榕(Ficus hispida)雌花期雌雄果的进蜂量和花后期雌雄果繁殖的多个特征值,以此来探讨自然条件下,影响对叶榕及其传粉榕小蜂(Ceratosolen solmsi marchali)繁殖的因素。结果表明:单果内有效进蜂数量是影响种子生产和传粉榕小蜂繁殖的首要因素,而雌花期进果的传粉榕小蜂并不是都能全部进入果腔传粉或产卵,大部分蜂还未进到果腔就被夹死在顶生苞片层的通道里,能进入雌果内传粉的榕小蜂为(2.72±2.04)只·果^-1,约占总进蜂量的52%;而在雄果里,能进入果腔的蜂量只有(2.08±1.65)只·果^-1,占35%左右。由于雌果内的雌花显著比雄果内的雌花多,结合单果进蜂量雌多雄少的格局,最终单果生产的种子数量 (1 891.63 ± 471.53)比传粉榕小蜂的数量 (367.20 ± 208.02) 多5倍有余。在雌果里,供给传粉的雌花数量与所生产的种子数量之间呈显著的正相关,而没有接受到花粉或不能正常受精的雌花数量与种子数量呈显著的负相关。雄果不仅生产花粉,也是传粉榕小蜂繁殖的场所,在相关于传粉榕小蜂自身繁殖力的因子中,传粉榕小蜂产卵制造的瘿花数量对其种群数量有最大的影响;影响次之的是发育过程中死亡的个体数量,它可降低30%左右的传粉榕小蜂数量;影响排在第三位的是寄主的雌花数量。此外,3类非传粉者的存在,单果内平均可减少30多只传粉小蜂。     

聚果榕传粉榕小蜂传粉与产卵之间的权衡

【目的】榕树(Ficus)依赖专性榕小蜂(Agaonidae)传粉,同时为传粉榕小蜂提供繁衍后代的场所,两者形成动植物间经典的协同进化关系。在雌花期果内,榕小蜂需在有限的存活时间内完成传粉和产卵,而传粉榕小蜂如何在传粉与产卵之间进行权衡仍然是悬而未解的问题。本研究旨在明确传粉榕小蜂——一种栉颚榕小蜂Ceratosolen sp.在雌雄同株的聚果榕Ficus racemosa雌花期果内的行为活动及繁殖模式。【方法】借助测微尺测量聚果榕榕果雌花花柱长度与传粉榕小蜂(Ceratosolen sp.)产卵器长度,通过显微视频记录传粉榕小蜂在雌花期果内搜索、传粉及产卵行为;结合单果控制性引蜂试验,测定不同阶段榕小蜂个体大小、孕卵量、携粉量,以及雄花期最终繁殖的榕小蜂后代和榕果种子数量。【结果】聚果榕雌花花柱长度存在树间变异,榕小蜂产卵器长度比绝大多数的雌花花柱长,说明该小蜂可以产卵于大部分的雌花子房里。通常个体大的榕小蜂孕卵量更多,但个体大小与携粉量之间相关性不显著。观察发现,榕小蜂进入雌花期榕果内,前6 h集中产卵,可产下孕卵量的95%,平均搜索用时27 s,产卵用时46 s,此期间传粉行为少见,花粉筐中携带花粉量亦无明显变化;榕小蜂进果后6-24 h,主要执行传粉,其行为主动,连贯高效,单次传粉用时平均为2 s,最终可传完携粉量的80%。控制引蜂试验也证实榕小蜂进入榕果内前6 h主要执行产卵繁殖后代,之后6-24 h主要执行传粉以繁殖榕树种子。【结论】在雌雄同株的聚果榕雌花期榕果内,榕小蜂先产卵、后传粉。本研究首次展示了传粉榕小蜂在聚果榕雌花期榕果内的产卵和传粉行为,并获得与行为相匹配的产卵量和传粉繁殖量,反映了具主动传粉行为的榕小蜂在传粉和产卵之间存在时间和数量上的权衡。     

榕树隐头花序挥发物组成及其传粉榕小蜂寄主识别行为

榕树(Ficus spp.)通过挥发性化学物质来吸引传粉榕小蜂(Agaonidae),这种特异性的化学信号释放存在着两种模式,一种是释放多种化合物的"泛化"模式,另一种是释放不常见单一化合物的"专化"模式。为揭示榕树(Ficus microcarpa)及其传粉榕小蜂Eupristina verticillata之间的化学通讯机制,该研究采用固相微萃取法提取榕树隐头花序不同发育期(花前期、雌花期传粉前后、间花期、雄花期和花后期)释放的挥发物,并用气相色谱-质谱联用仪鉴定挥发物成分,分析其变化动态,再通过Y型嗅觉仪检测榕树传粉榕小蜂对各发育期隐头花序的行为反应。结果表明:榕树隐头花序释放的挥发性化合物共鉴定出21种,主要是脂肪酸衍生物、萜类化合物和芳香族化合物。不同发育期隐头花序的挥发物组分差异明显,雌花期传粉前后的挥发物差异表现为传粉后萜类化合物含量下降,脂肪酸衍生物含量增加,特别是传粉前含量较高的特征化合物2-庚酮和3-辛酮消失,D-柠檬烯含量下降,而可巴烯、环己烷和2-己烯醛含量上升。行为检测的结果也表明:雌花期隐头花序对传粉榕小蜂的吸引作用最强,而雄花期的隐头花序释放的挥发物对传粉榕小蜂有趋避作用,形成了对传粉榕小蜂"推拉"的互作模式。有多种化合物在榕树传粉榕小蜂的寄主识别过程中发挥作用,表明榕树及其传粉榕小蜂的互惠共生关系是通过多种化合物的"泛化"策略来维系的。     

传粉榕小蜂与非传粉小蜂间寄主识别行为的趋同进化

在高度专性传粉的榕树-榕小蜂互惠共生系统中普遍存在着一些非传粉小蜂,它们中的一些种类进入果腔后也能为榕树传粉,且在形态和物候上已与传粉榕小蜂发生了趋同进化。但其寄主识别行为是否也与传粉榕小蜂发生了趋同进化还不得而知。我们在西双版纳选择了钝叶榕(Ficuscurtipes)及其3种进果繁殖小蜂开展了相关的行为实验。3种小蜂中,1种是钝叶榕的专性传粉榕小蜂(Eupristina sp.),另外2种是寄居性非传粉小蜂(杨氏金小蜂Diaziellayangi和Lipothymus sp.),这2种非传粉小蜂进入果腔后也像传粉榕小蜂那样为钝叶榕传粉。我们以钝叶榕不同发育时期的榕果及这3种小蜂为材料,采用Y型嗅觉仪观察了这3种小蜂对各发育时期榕果和信息化学物质6-甲基-5-庚烯-2-醇、6-甲基-5-庚烯-2-酮及这2种化合物的混合物的选择行为。结果表明,当提供雌花期榕果与其他发育时期榕果和空气对照供这3种小蜂选择时,它们均显著地偏向于选择雌花期榕果;当提供雄花期榕果与其他发育时期榕果和空气对照供这3种小蜂选择时,它们均显著地偏向于选择其他发育时期榕果和空气对照,即都会避开雄花期榕果;此外,这3种小蜂均对钝叶榕雌花期果释放的一种主要化合物6-甲基-5-庚烯-2-醇的同一剂量(1μL)表现出显著的偏好。这一结果为传粉榕小蜂与非传粉小蜂间的寄主识别行为趋同进化的假说提供了证据。     

高榕雌花期传粉榕小蜂和欺骗性小蜂的繁殖特点

榕树及其专一性传粉榕小蜂组成了动植物界最为经典的协同进化关系,传粉榕小蜂演化出欺骗性是非常罕见的。在雌雄同株的高榕隐头果内,共存着一种传粉榕小蜂Eupristina altissima和一种欺骗性的小蜂Eupristina sp.,两种小蜂在雌花期进入隐头果内繁殖,但有不同的繁殖特点。对比研究了两种小蜂从成虫羽化到产卵和传粉这个阶段的雌蜂个体大小、孕卵量及繁殖差异,结果表明:羽化期两种雌蜂的平均个体小,经飞行小个体的雌蜂易死亡,大个体雌蜂到达接受树,但通过苞片通道,一些个体较大的传粉榕小蜂被夹死导致进入果腔的雌蜂相对小,而欺骗性小蜂易通过苞片以至进入果腔的雌蜂个体较大。两种未产卵雌蜂均表现为个体大者孕卵量较多,但两种雌蜂的平均孕卵量没有差异。即使有充足雌花资源产卵,两种雌蜂均未产完所有卵,产卵后两种雌蜂卵巢中的卵量均显著减少,遗留下的卵量两种小蜂间没有差异。传粉榕小蜂只有部分个体传完所携带花粉,并表现为传粉越成功的雌蜂,产卵越多。存在种内竞争时,两种小蜂的产卵量均减少,传粉榕小蜂的传粉效率也降低。在种间竞争背景下,欺骗性小蜂产卵更成功,传粉榕小蜂的产卵和传粉量均受到极大抑制。研究结果说明雌花期隐头果内传粉榕小蜂只适量利用雌花资源产卵繁殖后代,更有效地传粉繁殖榕树种子,这可能是维持榕-蜂互惠系统稳定共存的重要机制之一;欺骗者稳定存在需降低与传粉者的直接竞争,而欺骗者和传粉者分散在不同果内,甚至是不同的树上繁殖是理想的繁殖策略。     

Some pollinators are more equal than others: Factors influencing pollen loads and seed set capacity of two actively and passively pollinating fig wasps

The nursery pollination system of fig trees (Ficus) results in the plants providing resources for pollinator fig wasp larvae as part of their male reproductive investment, with selection determining relative investment into pollinating wasps and the pollen they carry. The small size of Ficus pollen suggests that the quantities of pollen transported by individual wasps often limits male reproductive success. We assessed variation in fig wasp pollen loads and its influence on seed production in actively pollinated (Ficus montana) and passively pollinated (Ficus carica) dioecious fig trees.The ratios of number of male flowers on number of female flowers in a glasshouse-maintained F. montana population were highly variable. When fig wasps were introduced into receptive female figs, the resulting seed numbers were strongly linked to the numbers of pollinators that had been seeking access to pollen, relative to the number of anthers in their natal figs. In F. carica estimates of the amounts of pollen produced per fig and the quantities of pollen carried by emerging fig wasps suggest that less than 10% of the pollen is transported. Pollinators of F. carica that emerged earlier from figs carried more pollen, and also generated more seeds when introduced into receptive female figs.We show here that all pollinators are not equally valuable and producing more pollinators is not necessarily a good option in terms of Ficus male fitness. Previous results on F. montana figs showed that only around half of the flowers where pollinators lay eggs produced adult offspring. The amount of pollen collected by young female fig wasps may be a major determinant of their reproductive success.     

Chemosensory attraction of fig wasps to substances produced by receptive figs

In the mutualism between figs (Ficus spp., Moraceae) and their species-specific fig wasp pollinators (Hymenoptera: Agaonidae), location of a receptive host tree by the adult insect is a critical step. The adult female wasp lives only a few days, and must usually fly to a different tree than her natal tree to locate receptive figs. Trees in receptive phase often occur at very low densities. Reproductive success of both fig and wasp depends on trasmission of a very strong signal by the plant. Some evidence exists for the role of olfaction in location of receptive hosts by fig wasps, but very little work has been done on the chemical ecology of host location and host specificity. Here the first experimental evidence is presented for long-distance olfactory attraction of wasps by volatile substances produced by receptive figs, and for short-distance or contact chemostimulation by host volatiles that elicit entry of the wasp into the fig. In studies usingFicus carica L., pentane extracts of receptive-phase figs attract the pollinatorBlastophaga psenes L. from distances of at least 5 m in the field. Short-distance chemostimulation was demonstrated in laboratory bioassays. Pentane extracts of receptive figs, when painted onto the ostiole of non-receptive figs, elicit entry of pollinator wasps. Figs emit volatile compounds attractive to pollinating wasps only during the period of receptivity; pentane extracts of non-receptive figs are not attractive. A simple reliable procedure is described to compare the attractivity of different types of extracts (total, internal, and external extracts) and of different fractions, in the first step towards identifying attractant substances.     

Dispersal of adult female fig wasps 1. Arrivals and departures

Ficus burtt-davyi, like most other fig species (Ficus, Moraceae), is exclusively pollinated by its own unique species of fig wasp, in this caseElisabethiella baijnathi (Chalcidoidea, Agaonidae). Because fig crop development on any one tree is usually synchronised, the small and short-lived female wasps have to migrate and find other trees bearing figs which are at suitable stage of development for oviposition. However, the likelihood of successful location and subsequent arrival at a new host tree is dependent on distance and the effect of environmental factors such as wind and temperature. This study examines the relationship between ambient temperatures and the timing of fig wasps emergence from their natal figs and the commencement of their dispersal flight. The behaviour of the wasps arriving at figs which were ready to be pollinated was also examined. The female wasps did not appear to distinguish between the figs and other parts of the tree when in flight. However, after landing on the tree their search for figs was more directed as they visited more figs than leaves. Short-range recognition of figs appears to be by contact chemo-reception, but the wasps showed a preference for entering figs which did not already contain a female wasp.     

Fig volatiles: Their role in attracting pollinators and maintaining pollinator specificity

Each fig tree species (Ficus) is totally dependent on a specific species of wasp for pollination and the larvae of these wasps only develop in the ovules of their specificFicus host. Because the fig crop on any particular tree is generally highly synchronized, the shortlived female wasps must leave their natal tree in order to find figs which are suitable for oviposition. Chemical volatiles produced by figs when they are ready for pollination are thought to be the means by which the wasps detect a suitable host. Gas chromatograms of the fig volatiles of 7 species ofFicus showed them to be species specific. Age related changes in the volatile profiles were noted as extra volatiles are produced when the figs were ready for pollination.     

Sexual differences in the attractiveness of figs to pollinators: females stay attractive for longer

1. Figs on male dioecious fig trees (Ficus, Moraceae) are breeding sites for pollinator fig wasps (Hymenoptera, Agaonidae), but figs on female plants are traps that produce only seeds. As the short‐lived fig wasps cannot reproduce in female figs, natural selection should favour individuals that avoid them. Several studies have failed to detect such discrimination, a result attributed to inter‐sexual mimicry and ‘selection to rush’ in the wasps, but their experiments failed to explicitly take into account fig age (how long they had been waiting to be pollinated). 2. We compared the relative attraction of male and female figs of known ages of the South East Asian Ficus montana Burm. f. to its pollina tor Liporrhopalum tentacularis Grandi and examined how the reproductive success of the plant and its pollinator change with the age of the figs. 3. Mean retention time for un‐pollinated figs on female plants was 16 days whereas in male figs it was 12 days. Female figs remained attractive for up to 2 weeks, although the wasps were less willing to enter older figs. After pollinator entry, receptivity continued for several days, lasting longer in figs entered by a single wasp. Consistent with abortion rates, attractiveness persisted longer in female figs. Older figs produced fewer fig wasp offspring, but similar numbers of seeds. 4. The sexual differences in floral longevity in F. montana may represent part of a previously un‐recognised reproductive strategy in some fig trees that allows male plants to ‘export’ pollinators while also maintaining a resident fig wasp population.     

Age at pollination modifies relative male and female reproductive success in a monoecious fig tree

Plants that depend on a single species of insect pollinator must often contend with infrequent and unpredictable visitation. Prolongation of floral receptivity comes at the cost of reduced male and/or female reproductive success among older flowers. Fig trees (Ficus spp.) have a highly specific pollination symbiosis and individual inflorescences (syconia) that remain receptive for days or weeks. Reproductive success in monoecious fig trees involves production of both seeds and fig wasp offspring. We assessed whether the reproductive output of individual syconia changes with the length of time they waited for pollination, and whether the relative female and male reproductive success also changes. A pollination experiment was conducted in an SE Asian monoecious fig tree Ficus curtipes, in which receptive syconia were covered with mesh bags to exclude wasps and pollinated by single pollinators of this fig tree at their different receptive ages. When the syconia matured their size and contents were recorded. Seed quality was also assessed. The results showed that pollinators entered syconia that had been waiting for up to 36?days. The frequencies of abortions among syconia pollinated at different ages were low throughout. The number of un-utilised flowers increased progressively in older syconia. Seed production was highest in syconia entered on the first day of receptivity, whereas pollinator production peaked in syconia pollinated on day 12, then declined in older syconia. Consequently, overall reproductive efficiency declined with syconium age and floral sex allocation became more male-biased in older syconia. Older syconia also produced lighter seeds. These results suggest that un-pollinated syconia of F. curtipes can remain receptive for several weeks. This makes pollination of each syconium more likely, but at the cost of reduced productivity and with more ovules allocated to male function. However, the prolongation of floral receptivity has significance for the co-adaptation between syconia and fig wasps and for the evolution of the fig tree-fig wasp symbiosis.     

Phenological Adaptations in Ficus tikoua Exhibit Convergence with Unrelated Extra-Tropical Fig Trees

Flowering phenology is central to the ecology and evolution of most flowering plants. In highly-specific nursery pollination systems, such as that involving fig trees (Ficus species) and fig wasps (Agaonidae), any mismatch in timing has serious consequences because the plants must balance seed production with maintenance of their pollinator populations. Most fig trees are found in tropical or subtropical habitats, but the dioecious Chinese Ficus tikoua has a more northerly distribution. We monitored how its fruiting phenology has adapted in response to a highly seasonal environment. Male trees (where fig wasps reproduce) had one to three crops annually, whereas many seed-producing female trees produced only one fig crop. The timing of release of Ceratosolen fig wasps from male figs in late May and June was synchronized with the presence of receptive figs on female trees, at a time when there were few receptive figs on male trees, thereby ensuring seed set while allowing remnant pollinator populations to persist. F. tikoua phenology has converged with those of other (unrelated) northern Ficus species, but there are differences. Unlike F. carica in Europe, all F. tikoua male figs contain male flowers, and unlike F. pumila in China, but like F. carica, it is the second annual generation of adult wasps that pollinate female figs. The phenologies of all three temperate fig trees generate annual bottlenecks in the size of pollinator populations and for female F. tikoua also a shortage of fig wasps that results in many figs failing to be pollinated.     

Different Stimuli Reduce Attraction to Pollinators in Male and Female Figs in the Dioecious Fig Ficus hispida

Fig trees ( Ficus ) and their obligate pollinating wasps (Hymenoptera, Chalcidoidea, Agaonidae) are a classic example of a coevolved mutualism. Pollinating wasps are attracted to figs only when figs are receptive. It has been shown that figs will lose their attraction to pollinators sooner in monoecious and male dioecious figs when multiple pollinators have entered the enclosed inflorescence. However, little is known about the nature of the stimulus inducing the loss of attraction. By conducting experiments on the functionally dioecious fig, Ficus hispida , we show that (1) different stimuli induce the loss of attraction in each sex, pollination in female figs, and oviposition in male figs; and (2) foundress number affects the loss of attraction in both sexes only when the prerequisites ( i.e ., pollination in female figs and oviposition in male figs) have been satisfied. In general, the more foundresses that enter, the earlier the fig will lose its receptivity. We argue that the stimuli in male and female figs are adaptations to the fulfillment of its respective reproduction.