西双版纳地区犬蝠和棕果蝠食性的初步研究

犬蝠和棕果蝠是西双版纳地区较为常见的两个果蝠物种,大多数时间内它们同域分布,共同利用当地许多野生果实。从2004年6月至12月,我们采用拾遗法、粪便分析法以及种子萌发鉴定法并结合雾网采样对西双版纳地区这两种果蝠的食性进行了初步研究。结果发现犬蝠利用11科18种植物的果实,2科2种植物的叶片;而棕果蝠利用9科12种植物的果实,1科1种植物的叶片。研究发现雨季(6－10月)两种果蝠食物类型在本地区重叠程度较高,它们共同利用的植物类型占记录植物类型总数的65%。在干旱季节(11－12月),棕果蝠避开与犬蝠在食物方面的竞争而去别的地力开拓食物资源。     

两种果蝠对光叶桑(Morus macroura)果实的取食及种子传播

从2005年3月到2006年5月,在中国科学院西双版纳热带植物园沟谷雨林保护区内研究了两种果蝠——棕果蝠（Rousettus leschenaulti）和犬蝠（Cynopterus sphinx）取食光叶桑（Morus macroura）果实的行为、夜栖息地分布、散布种子方式及范围等。借助月光对果蝠的行为进行直接观察,发现它们的取食活动一般在天黑20～40min开始,取食高峰发生在22：00～22：30和23：00～23：30之间,这两个取食高峰期平均取食次数（平均值±标准误）为（13．5±2．5）和（15．0±2．3）次,最低的取食频率发生在19：00～19：30和20：30-21：00之间,分别取食（0．2±0．2）和（0．7±0．5）次。果蝠很少在母树上取食成熟的果实,相反它们用嘴叼下果实并携带到夜栖息地去进食,通常这些夜栖息地是具有密闭树冠、密集枝条的树种。夜栖息地在母树周围的分布根据环境中适合它们栖息的树种和分布而决定,不同母树周围其夜栖息地分布具有非常大的变异与空间异质性。钝叶榕（Ficus curtipes）、铁力木（Mesua ferrea）和糖胶树（Alstonia scholaris）是果蝠最喜爱的夜栖息地。在同样的情况下,尽管需要飞行更远的距离,两种果蝠都比较喜欢寻找具有许多枝条和小枝并且有复杂树冠的树木作为夜栖息地。两种果蝠取食光叶桑果实时,一部分种子通过消化道消化后被排泄出来,另外的一部分伴随着咀嚼后的果渣被吐出来,通过这两种方式,散布了大量的种子,再加上在飞行中也有排泄的习性,它们传播的种子在空间上更广泛。     

两种果蝠对光叶桑(Morus macroura)果实的取食及种子传播

从2005年3月到2006年5月,在中国科学院西双版纳热带植物园沟谷雨林保护区内研究了两种果蝠——棕果蝠(Rousettus leschenaulti)和犬蝠(Cynopterus sphinx)取食光叶桑(Morus macroura) 果实的行为、夜栖息地分布、散布种子方式及范围等。借助月光对果蝠的行为进行直接观察,发现它们的取食活动一般在天黑20~40 min开始,取食高峰发生在22: 00~22: 30 和23:00~23:30之间,这两个取食高峰期平均取食次数(平均值±标准误)为(13.5±2.5)和(15.0±2.3)次,最低的取食频率发生在19: 00~19: 30和20: 30~21: 00之间,分别取食(0.2±0.2)和(0.7±0.5)次。果蝠很少在母树上取食成熟的果实,相反它们用嘴叼下果实并携带到夜栖息地去进食,通常这些夜栖息地是具有密闭树冠、密集枝条的树种。夜栖息地在母树周围的分布根据环境中适合它们栖息的树种和分布而决定,不同母树周围其夜栖息地分布具有非常大的变异与空间异质性。钝叶榕(Ficus curtipes)、铁力木(Mesua ferrea) 和糖胶树(Alstonia scholaris) 是果蝠最喜爱的夜栖息地。在同样的情况下,尽管需要飞行更远的距离,两种果蝠都比较喜欢寻找具有许多枝条和小枝并且有复杂树冠的树木作为夜栖息地。两种果蝠取食光叶桑果实时,一部分种子通过消化道消化后被排泄出来,另外的一部分伴随着咀嚼后的果渣被吐出来,通过这两种方式,散布了大量的种子,再加上在飞行中也有排泄的习性,它们传播的种子在空间上更广泛。     

西双版纳地区4种榕树果实的资源分配及其种子萌发特性

为了解榕树果实的资源分配和种子萌发特征,对西双版纳地区的垂叶榕(Ficus benjamina)、高山榕(F.altissima)、聚果榕(F.racemosa)和无柄雅榕(F.concinna)的果实营养、繁殖资源分配,以及种子萌发特性进行了研究。结果表明,4种榕果的营养分配存在差异,榕果重的种类果肉亦多,榕果大者果腔较大,且种子数量较多,但雄花和榕小蜂数量不一定多。榕果分配给雌性功能及雄性功能繁殖的小花比例也不相同,聚果榕在雌性功能上的分配显著大于雄性功能,其它3种榕果则分配于雄性功能的资源比雌性功能的多,但程度不同。此外,4种榕树的种子大小及重量存在显著的种间差异,以至于影响到种子的萌发率及根茎生长,果实最大的聚果榕种子最多,萌发率高,但由于种子最小,其根茎生长缓慢且短;果实适中的垂叶榕和高山榕种子较大,不但萌发率较高,其根茎生长也较快;果实和种子都小的无柄雅榕,种子萌发率低,根茎生长慢。生长在水热环境好的榕树比生长在相对贫瘠环境的榕树,由于极少面临水热光照等限制,更容易进化出较小的种子,萌发能力和速度也相对较差。这说明不同生境中榕树进化出了不同的繁殖分配机制及资源利用策略来适应环境变化。     

广州地区犬蝠的食性

2004年5月—2006年4月采用拾遗法、粪便内容物分析法及实地观察对广州地区常见的食果蝙蝠¬—犬蝠(Cynopterus sphinx)进行了食性研究。对26份食物残留物和粪便样品的分析结果表明：犬蝠的食物包含13科21种的植物果实,3科3种的植物叶片,如：蒲桃（Syzygium jambos）、蒲葵（Livistona subglobosa）及龙眼（Dimocarous longan）的果实。其食性随果实的成熟季节而出现明显的季节性变化,夏秋两季大量食用各种水果,而在食物欠缺的春冬两季则主要食用棕榈科蒲葵的种子。广州地区犬蝠的繁殖期在每年的5—10月。     

三种旧大陆狐蝠科蝙蝠舌长度及结构比较

为探讨旧大陆食果和食蜜蝙蝠的食性类型不同是否造成其取食器官舌长度及结构的差异,本研究以2种食果蝙蝠犬蝠（Cynopterus sphinx）和棕果蝠（Rousettus leschenaultii）以及1种食蜜蝙蝠长舌果蝠（Eonycteris spelaea）为研究对象,比较了这3个物种间舌的差异。犬蝠、棕果蝠和长舌果蝠伸入直径为2 cm试管的最大舌长度L1（包括伸入试管的吻部和吻部以外的舌长）,分别为（29.19?0.52）mm、（35.05?0.82）mm、（49.34?1.64）mm;伸出吻端外部的舌长L3分别为（16.25?0.53）mm、（19.25?0.79）mm、（31.88?1.56）mm;与体重转换后的最大舌长度,即转换L1分别为（8.57?0.17）mm/3√g、（7.90?0.27）mm/3√g、（12.41?0.40）mm/3√g;与体重转换后的伸出吻端外部的舌长,即转换L3分别为（4.77?0.16）mm/3√g、（4.34?0.22）mm/3√g、（8.01?0.38）mm/3√g;与体重转换后的解剖舌长分别为（5.56?0.16）mm/3√g、（5.35?0.14）mm/3√g、（6.65?0.38）mm/3√g。此5个参数种间比较均差异显著,食蜜类的长舌果蝠的5个参数均显著长于食果类犬蝠和棕果蝠的。通过比较3种蝙蝠的舌结构发现,长舌果蝠的舌尖尖细且具有毛刷状丝状乳头结构,舌面及两侧凹槽较多;犬蝠和棕果蝠的舌尖钝圆,舌面乳头和凹槽较少而平缓。本文结果表明,旧大陆食蜜蝙蝠与食果蝙蝠在舌长度和舌结构上存在明显差异,可能与捕食行为上的差异有关。     

钝叶榕榕果内榕小蜂的产卵顺序及其群落结构

通过对钝叶榕榕小蜂行为的观察以及榕果内各类小花的统计,研究了钝叶榕12种榕小蜂的产卵行为和群落结构.结果表明：钝叶榕中除了传粉榕小蜂Eupristina sp.进入果腔产卵以外,还有2种非传粉榕小蜂（杨氏榕树金小蜂和Lipothymus sp.）与传粉榕小蜂在同一时期进入果腔产卵,其他9种非传粉榕小蜂（Walkerella sp.、Micranisa sp.、Sycophilomorpha sp.、Philotrypesis sp.、Sycosapter sp.、Sycobia sp.、Ficomila sp.、Ormyrus sp.和Sycophila sp.）在果外产卵;在钝叶榕榕小蜂群落中,传粉榕小蜂占整个群落总数的62.11%,是该群落的优势种,杨氏榕树金小蜂和Lipothymus sp.分别占整个群落总数的27.19%和4.71%,其他9种非传粉榕小蜂占5.99%.钝叶榕中的非传粉榕小蜂通过各自产卵时序和幼虫食性分化的繁殖策略来分配榕果中的资源,以实现自身繁殖.非传粉榕小蜂与传粉榕小蜂的数量变化呈显著负相关,但非传粉榕小蜂与榕果内的种子没有相关性.     

丛毛垂叶榕种子萌发的光敏感性及其生态意义

以丛毛垂叶榕（Ficns benjamina L．var．nuda）种子为实验材料,研究了温度、光照、植物激素（GA3、6-BA、乙烯）和含氮化合物（硝普钠、亚硝酸盐和硝酸盐）对种子萌发的影响,讨论了光在丛毛垂叶榕种子萌发中的生态意义。在交替光照下（14h光照,10h黑暗,12μmol m^-2s^-1）,种子在15℃、20℃、25℃、30℃、35℃、40℃和30℃,20℃下的最终萌发率分别为87．5％、100％、100％、100％、98％、89％和100％;种子的平均萌发时间分别为34．7d、16．3d、5．6d、4．8d、6．4d、9d和6．3d。黑暗条件下,种子在15℃、20℃、25℃、30℃、35℃、40℃和30℃／20℃下萌发35d,种子的萌发率为零;添加交替光照后,种子迅速萌发。0．5～20μmol m^-2s^-1的光照强度显著地增加种子的最终萌发率,不同的光照强度对种子的最终萌发率没有明显的影响,但影响种子的萌发速率。在24h光暗周期下,种子的最终萌发率随着光期长度的增加而显著提高。在连续光照下处理24h、36h和48h后能够促进种子在随后的连续黑暗中萌发。不同浓度的GA3、6-BA、乙烯、硝普钠、NaNO3和NaNO2处理不能代替光照在黑暗条件下促进种子萌发,添加交替光照后,种子迅速获得萌发能力。丛毛垂叶榕种子的上述萌发行为与其长期适应热带雨林的生境密切相关。     

食果鸟类在红豆杉天然种群形成中的作用

2005年10月初至2006年2月,在南京中山植物园研究了红豆杉(Taxus chinensis)天然更新种群的分布格局,野外定点观察了鸟类对红豆杉种子的取食行为,记录了红豆杉落果的命运,分析了食果鸟类在红豆杉种群形成中的作用。结果表明:红豆杉天然更新种群集中分布于距母树群10m以外面积约0.5hm2的山坡上,全部红豆杉幼苗、幼树共213株,主要分布在中下坡;幼苗和幼树的空间水平格局符合聚集分布特征。"果实"成熟后,一部分被鸟类直接在树上取食,一部分掉落母树下地面。经过对结实母树的定点、连续观察,记录到4种鸟类取食红豆杉"果实",其中红嘴蓝鹊(Urocissa erythrorhyncha)和白头鹎(Pyc-nonotus sinensis)为主要的取食者和传播者。食果鸟类整吞"果实",消化果肉(假种皮)后,种子经消化道随粪便排出,以此过程传播种子。在取食完红豆杉"果实"后,食果鸟类多飞向坡上。坡上排水良好,有适量的荫蔽,生境适宜红豆杉种子萌发和幼苗的成长。因此,食果鸟类将种子传播至适宜萌发和生长的环境中,对该红豆杉种群的天然更新起主要作用。同时,鸟类传播对于红豆杉种群扩散、占据新的生境也有着特殊的意义。     

西双版纳鸡嗉果榕内一种非传粉小蜂的性比调节

对西双版纳广泛分布的鸡嗉果榕（Ficus semicordata）雄树上寄生的一种非传粉榕小蜂Apocryptophagus sp.进行控制梯度放蜂实验,结合产卵行为、交配行为观察,定量研究了该种非传粉榕小蜂的性比率.结果表明：Apocryptophagus sp.雌蜂在传粉榕小蜂（Ceratosolen gravelyi）产卵后的第3天开始访问榕果,从果外完成产卵,产卵时间持续2d左右.发育成熟以后,其雄蜂几乎与传粉榕小蜂雄蜂同时羽化,雄蜂咬开寄生有其雌蜂的瘿花并进行交配,雌蜂交配后从瘿花内羽化出来离开榕果,去寻找新的处于接受期的榕果,而雄蜂一直留在其寄生的榕果内直至死亡.后代性比与局域配偶竞争理论预测一致：性比偏雌,随着在同一榕果产卵的繁殖雌蜂数量的增加,后代性比上升;同时,单个榕果内的后代数量也上升,而平均后代数量却显著下降.在个体水平上,当1头雌蜂在榕果上产卵时,后代性比与后代数量呈显著的负相关关系.     

Germination responses of four pioneer plant species after passage through the gut of a frugivorous Neotropical bat

Seed passage through the guts of bats potentially influences germination in different ways: physically, chemically and biologically. To evaluate the influence of a Neotropical bat on the seed germination of four pioneer plant species, an experiment was conducted. Considering the positive influence of bats on germination and the possibility of observing non-viability caused by microorganisms, we hypothesized that (i) seeds subjected to passage through bat guts without the influence of microorganisms have a higher germination potential. Considering the different ecological requirements for the germination of plant species, we also hypothesized that (ii) the four plant species present different germination parameters. The germination of seeds from feces and fruits in the presence and absence of microorganisms was compared for each plant species and among the four plant species. The ingestion of seeds by bats and the presence of microorganisms either improved or did not influence the germination parameters of plants, but the direction of the effects did not support the hypothesis in all cases. The germination parameters differed among most plant species except between Ficus adhatodifolia and F. guaranitica. Our findings indicate that the influence of bats on seeds depends on the microorganisms and singularities of plant species.     

Tracking Bat‐Dispersed Seeds Using Fluorescent Pigment1

Tracking the dispersal of seeds by fruit‐eating animals in tropical rain forests is crucial to further our understanding of plant–frugivore interactions and their impacts upon forest regeneration and plant population dynamics. We tested the feasibility of tracking bat‐dispersed seeds in a Philippine lowland rain forest with the help of fluorescent pigment. The powder was mixed with acetone and sprayed to ripe fruits of fig trees, i.e., Ficus septica and F. variegata. During nightly monitoring using a hand‐held ultraviolet lamp bat deposits (seed‐containing spat outs and feces) could successfully be detected. Distances and directions of deposit sites to the focal trees were recorded and seed shadow areas were analyzed. Bats dispersed most of the seeds less than 50 m away from the parent plants resulting in seed shadow areas < 0.30 ha in size. An in situ fruit preference experiment showed that fluorescent powder is unlikely to deter bats from feeding on ripe figs. In conclusion, the technique is simple, inexpensive, noninvasive, applicable to different fields of research and allows one to follow the fate of seeds from known sources.     

Disperser- vs. Establishment-Limited Distribution of a Riparian Fig Tree (Ficus insipida) in a Costa Rican Tropical Rain Forest1

Studies were conducted at the La Selva Biological Station in Costa Rica and in a greenhouse in California to determine the factors accounting for the nonrandom distribution of the riparian fig tree Ficus insipida Willd. along streams in the La Selva Biological Reserve and adjacent deforested lands. We also evaluated the potential seed dispersers of this tree relative to the role of the fruit‐eating fish Brycon guatemalensis that previously was proposed to be an important disperser of F. insipida seeds in this system. At La Selva, we recorded the fig‐foraging activities of vertebrates at fruiting F. insipida trees, surveyed for the presence or absence of F. insipida along streams of different sizes, and determined the fate of fig seedlings transplanted in different riparian habitats. In the greenhouse, we measured seed germination and seedling survival and growth under different light and soil pH conditions mimicking natural conditions. The findings provided evidence that (1) the tree occurs along the larger streams running through forest habitat and only along smaller streams with relatively high light availability; (2) bats (Artibeus spp.) and fish are the major dispersers of F. insipida seeds; (3) the seedlings are subject to mortality not only from low light conditions but also from treefalls, frequent flooding, and bank erosion; and (4) high light levels and near neutral soil pH result in relatively better seed germination, faster growth, and higher survival rates of seedlings. Overall, our results suggest that this fig tree is dispersed mainly by bats and fish and is more establishment‐limited than disperser‐limited in its local distribution in the La Selva rain forest habitat.     

Seed Dispersal of Morus macroura (Moraceae) by Two Frugivorous Bats in Xishuangbanna, SW China

The dispersal of Morus macroura seeds by two species of frugivorous bats ( Rousettus leschenaulti and Cynopterus sphinx ) was studied in a forest at Xishuangbanna Tropical Botanical Garden in Southwest China from March to May 2005. Feeding roosts were identified within 500 m around parent trees and the types and number of seed loads under each roost were recorded. We found feeding roost density decreased with increasing distance from the parent, but found no correlation between distance and seed deposition. The effect of bat digestion on seed germination was investigated, and we found that germination percentage of all treatments involving ingestion by bats was significantly lower than control seeds and some germination parameters of seeds from different treatments changed.     

西双版纳热带雨林对叶榕传粉生物学

研究了西双版纳热带雨林地区雌雄异株植物对叶榕(Ficus hispida L.)的生物学、传粉物候学以及榕小蜂(Ceratosolen solmsi marchali Mayr)的传粉和繁殖行为.研究结果表明:雌雄异株的对叶榕与其他雌雄同株的榕属植物不同,它的种子形成与传粉者有着更为复杂的相互关系.对叶榕一年结隐花果6～8次,结果高峰期4～5次,其中雄性植株仅产生花粉和孕育榕小蜂,而雌性植株(无雄蕊)则需榕小蜂带花粉进入隐花果内,进行传粉授精,使之发育成种子.对叶榕的成熟花粉不能从花药开裂处自行散发出来,必须由榕小蜂采集才能散落.榕小蜂雌蜂羽化、交配后,找到雄花区,用足、触角、口器在推动中采集花粉.雌蜂飞出熟榕果找寻雌株或雄株榕树上的幼嫩隐花果,一般需3～67 min;一部分雌蜂在雄株中寻找幼嫩的隐花果,进去产卵繁殖,另一部分雌蜂则寻找雌株雌花期嫩隐花果进去传粉.雌蜂在雌株榕树的隐花果内传粉时间为15～23 h,在雄株榕树的隐花果内产卵时间为6～9 h.对叶榕小蜂在雌株上进入单个隐花果的数量多少关系到雌花结实率;观察表明,每个隐花果最佳进蜂数为2头;榕小蜂传粉后榕树成熟种子形成率在54.1%～82.5%之间,平均为73.8%;而在雄株上雌蜂进蜂数量则关系到榕小蜂在隐花果内的产卵率,每个隐花果最佳进蜂数为3～4头,产卵率在72.3%～93.8%之间,平均为84.4%.     

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。     

西双版纳热带雨林对叶榕传粉生物学(英)

研究了西双版纳热带雨林地区雌雄异株植物对叶榕 (FicushispidaL .)的生物学、传粉物候学以及榕小蜂(CeratosolensolmsimarchaliMayr)的传粉和繁殖行为。研究结果表明 :雌雄异株的对叶榕与其他雌雄同株的榕属植物不同 ,它的种子形成与传粉者有着更为复杂的相互关系。对叶榕一年结隐花果 6～ 8次 ,结果高峰期 4～ 5次 ,其中雄性植株仅产生花粉和孕育榕小蜂 ,而雌性植株 (无雄蕊 )则需榕小蜂带花粉进入隐花果内 ,进行传粉授精 ,使之发育成种子。对叶榕的成熟花粉不能从花药开裂处自行散发出来 ,必须由榕小蜂采集才能散落。榕小蜂雌蜂羽化、交配后 ,找到雄花区 ,用足、触角、口器在推动中采集花粉。雌蜂飞出熟榕果找寻雌株或雄株榕树上的幼嫩隐花果 ,一般需 3～ 6 7min ;一部分雌蜂在雄株中寻找幼嫩的隐花果 ,进去产卵繁殖 ,另一部分雌蜂则寻找雌株雌花期嫩隐花果进去传粉。雌蜂在雌株榕树的隐花果内传粉时间为 15～ 2 3h ,在雄株榕树的隐花果内产卵时间为 6～ 9h。对叶榕小蜂在雌株上进入单个隐花果的数量多少关系到雌花结实率 ;观察表明 ,每个隐花果最佳进蜂数为 2头 ;榕小蜂传粉后榕树成熟种子形成率在 5 4 .1%～ 82 .5 %之间 ,平均为 73.8% ;而在雄株上雌蜂进蜂数量则关系到榕小蜂在隐花果内的产卵率 ,     

Attraction of Fruit-Eating Bats with Essential Oils of Fruits: A Potential Tool for Forest Restoration

Previous tests with essential oils from ripe chiropterochoric fruits suggested they can be used to attract and capture fruit-eating bats inside forest remnants. Here we evaluated the efficiency of these oils to attract frugivorous bats to open areas. We performed field tests with artificial fruits impregnated with essential oils of the genera Piper or Ficus that were attached to two groups of mist-nets set 50 m outside the border of a forest remnant. One group of artificial fruits received the corresponding oil isolated through hydrodistillation and the other received water only. Fruits with oils attracted significantly more fruit-eating bats, especially Artibeus lituratus that regularly crosses open habitats to reach other forest remnants. The highly significant attraction of A. lituratus by the oil of Piper was unexpected, since this bat is a specialist on Ficus fruits. We hypothesize that in habitats with no fruit available it is possible to attract frugivorous bats with the odor of several ripe fruit species. Furthermore, we verified that almost half of the individuals captured defecated seeds, indicating that the oils also attract recently fed bats, even when their preferred food is available nearby. This technique potentially may increase seed rain at specific locations, being particularly promising to restoration projects.     

Substrate water potential constraints on germination of the strangler fig Ficus aurea (Moraceae)

Palms are the most common support hosts for strangler fig (Ficus aurea) in the tropical dry forest. At Hummingbird Cay Tropical Field Station in the Bahamas, viable F. aurea seeds scattered on open soil germinate within 6 d in the laboratory at 27C in light or darkness. To test the hypothesis that water relations between seed and substrate can restrict the site of F. aurea establishment, fig seeds were imbibed in mannitol solutions with water potential (psi) from 0 MPa to -2.0 MPa. At psi > -1.0 MPa, germination ranges from 70 to 90%. Below -1.0 MPa, germination drops under 4%. Seedling growth rate slows linearly with decreasing psi, due to reduced cell enlargement in the radicle. Sensitivity of F. aurea seeds to psi stress is similar to that of mesophytic crops with "threshold' psi of -1.2 to -1.5 MPa, below which germination and/or seedling growth stops. F. aurea shows no evidence of xerophytic adaptation in germination physiology. In the field, psi of humus in palm leaf bases does not drop below -1.0 to -1.1 MPa, while humus in terrestrial sites reaches psi F. aurea germination and seedling growth is met by humus in palm leaf bases, not by terrestrial sites. In dry forests, this restricts F. aurea establishment to the crown of palm trees.     

The effect of bat (Rousettus aegyptiacus) dispersal on seed germination in eastern Mediterranean habitats

The fruit-bat Rousettus aegyptiacus (Pteropodidae) in Israel consumes a variety of cultivated and wild fruits. The aim of this study was to explore some of its qualities as a dispersal agent for six fruit-bearing plant species. The feeding roosts of the fruit-bat are located an average of 30 m from its feeding trees and thus the bats disperse the seeds away from the shade of the parent canopy. The bat spits out large seeds but may pass some (2%) of the small seeds (<4 mg) through its digestive tract. However, neither the deposited seeds nor the ejected seeds (except in one case) had a significantly higher percentage germinating than intact seeds. Although the fruit-bat did not increase the percentage germinating, seeds of three plant species subject to different feeding behaviors (deposited in feces or spat out as ejecta) had a different temporal pattern of germination from the intact seeds. The combined seed germination distribution generated by these different treatments is more even over time than for each treatment alone. It is sugested that this increases asynchronous germination and therefore enhances plant fitness by spreading the risks encountered during germination, especially in eastern Mediterranean habitats where the pattern of rainfall is unpredictable.