垂叶榕隐头果内小蜂群落结构与生境关系的初步研究

垂叶榕(Ficusbenjamina)是一种世界上广泛栽培的绿化树种,但是关于其隐头果内小蜂群落结构的研究国内外很少涉及。我们根据植被覆盖度和干扰程度差异在西双版纳州勐仑镇选择了3块不同的样地,采集垂叶榕隐头果180个,统计其中的榕小蜂种类和数量。结果表明:共鉴定出榕小蜂13种,隶属于膜翅目小蜂总科中的8个属,其中Eupristinakoningsbergeri为传粉榕小蜂,其余12种为非传粉小蜂;3个样地中的小蜂群落多样性指数、丰富度存在显著差异,植被覆盖度高、干扰小的样地内小蜂群落多样性指数、丰富度显著高于其他样地;非传粉小蜂在产卵时更倾向于选择植被覆盖度高、干扰相对小的生境,且非传粉小蜂的存在对传粉榕小蜂的繁殖有着显著的负面影响。     

西双版纳聚果榕隐头果内小蜂群落结构及种间关系

聚果榕Ficus racemosa Linn.是雌雄同株榕树,它是西双版纳热带雨林生态系统中的一个常见种群。聚果榕必须依靠聚果榕小蜂Ceratosolen fusciceps Mayr传粉才能获得有性繁殖,而聚果榕小蜂又必须依靠聚果榕隐头果内短柱花繁衍后代,两者间形成了种间专一的互惠共生体系。同时,在其隐头果内还存在一个复杂的非传粉小蜂功能群,它们主要是榕树种子和传粉榕小蜂的寄生者。在云南省西双版纳自治州勐腊县勐仑镇选取了5个样地,对聚果榕单果内小蜂群落组成和种间相互关系进行研究。在不同时间段采集聚果榕单果242个,共收集小蜂366660头。聚果榕隐头果内有6种小蜂,隶属小蜂总科Chalcidoidae中的榕小蜂科Agaonidae、长尾小蜂科Caliimomidae、金小蜂科Pteromalidae,其中榕小蜂科中的C．fusciceps是聚果榕唯一的传粉者。金小蜂科中的Apocryta westwoodi Grandi和Apocryta sp.两个种是榕小蜂的寄生者,它们的寄生是传粉榕小蜂的种群数量减少因素之一。长尾小蜂科中Platyneura agraensis Joseph,Platyneura mayri Rasplus和Platyneura testacea Motschulsky3个种是寄生榕树种子或与榕小蜂争夺食物(瘿花)资源的小蜂类群,它们的出现与发生,致使聚果榕正在发育成种子的长柱小花形成瘿花,同时一部分种类把卵寄生在已被榕小蜂产卵的短柱小花子房中与榕小蜂争夺食物资源,致使榕小蜂食物资源的匮乏而死亡,对传粉小蜂种群有明显的影响。传粉小蜂从花托口钻入隐头果内,在隐头果内的长柱小花传粉和短柱小花子房中产卵,5种非传粉小蜂从隐头果外部把产卵器刺穿果肉把卵产在小花子房上。通过对5块样地隐头果内小蜂群落的综合分析发现,传粉榕小蜂为优势种群,而Apocryta sp.种的数量最少。在传粉及非传粉小蜂自然群体中各种类性比明显具有偏雌现象。小蜂群落表现异常的是聚果榕孤立株的样地,该样地传粉小蜂个体数量明显下降,非传粉小蜂个体数量则增加,各小蜂种群之间竞争激烈,出现C．fusciceps和P．mayri两个优势种。     

笔管榕榕小蜂的群落结构与物种多样性

笔管榕为桑科榕属落叶乔木,雌雄同株,为福建地区的常见树种。笔管榕榕果内生活着多种榕小蜂,它们与笔管榕共同构成了榕树-榕小蜂共生体系。通过全年(2011年7月至2012年7月间)对福州地区不同样地的30株笔管榕进行的定时、定点、定株观察与采集,在15批次830个榕果中,共收集到50817头榕小蜂。笔管榕榕果内有7种小蜂,隶属于小蜂总科中的6个科(亚科)7个属,其中榕小蜂科的Platyscapa ishiiana为传粉小蜂,其余6种为非传粉小蜂,分别属于金小蜂科、广肩小蜂科、姬小蜂科及隐针榕小蜂亚科。非传粉小蜂中的Philotrypesis sp.、Acophila mikii、Otitesella ako、Sycophila sp.和Sycobiomorpha sp.小蜂几乎在全年的每个月都可采集到,属常见种。Aprostocetus sp.全年仅收集到2头,为偶见种。笔管榕榕果内的榕小蜂种类在不同月份、不同季节没有明显变化,但不同种类榕小蜂的数量变化明显。在笔管榕榕小蜂群落结构中,全年有9个月均是传粉小蜂占优势,但在1月、9月和11月的采集批次中,非传粉小蜂占优势。非传粉小蜂(Acophila mikii、Sycophila sp.、Philotrypesis sp.和Otitesella ako)常呈爆发性发生,每批次中往往是1-2种的非传粉小蜂数量较多,但不同批次,数量较多的非传粉小蜂种类往往不同,因此在小蜂群落结构中未见某种非传粉小蜂占明显优势。福州地区笔管榕榕果内小蜂群落的的多样性指数为0.72,均匀度指数为0.37,丰富度指数为0.55,优势集中性指数为0.68。分析了6种小蜂的性比,结果表明:传粉小蜂的性比极度偏雌,非传粉小蜂虽然也偏性,但均高于传粉小蜂,推测榕小蜂性比与雄蜂的翅型和交配场所有关。非传粉小蜂的数量和传粉小蜂总数、雌蜂数和雄蜂数均呈极显著负相关,和性比呈极显著正相关关系,说明非传粉小蜂对传粉小蜂的雌、雄蜂都有负面影响,且传粉小蜂雌蜂减少的幅度大于传粉小蜂雄蜂,从而导致其性比升高。非传粉小蜂中Acophila mikii、Sycobiomorpha sp.、Otitesella ako Ishii为造瘿类群,Philotrypesis sp.、Sycophila sp.属于寄居者或寄生者类群,非传粉小蜂中的寄生或寄居类群与造瘿类群相比,对传粉小蜂的负面影响更大。研究结果为榕-蜂协同进化研究,以及城市绿化和生物多样性保护提供科学依据。     

垂叶榕上16种榕小蜂的种群动态

传粉榕小蜂和榕树的互利共生是传粉昆虫与植物间协同进化的典范。在榕果(榕树的隐头状花序)内,还生活着多种非传粉榕小蜂。这些生活在密闭榕果内由传粉榕小蜂和非传粉榕小蜂组成的群落对研究群落生态学有很大价值。然而,对生存在单一榕树的榕果内的所有榕小蜂的种群动态了解很少,特别是缺少相对长期的连续数据。通过野外近3a观察和采样,研究了垂叶榕榕小蜂群落结构和榕小蜂的种群动态。共记录榕小蜂16种;各种榕小蜂根据发生规律可分为常见种和偶见种,Eupristina koningsbergeri,Philotrypesis sp.1,Philotrypesis sp.4,Philotrypesis sp.5,Sycoscapter sp.1,Walkerella benjamini,Walkerella sp.1,Sycophila sp.2,Sycobia sp.2为常见种;Sycobia sp.1,Acophila sp.1,Sycophila sp.1,Ormyrus sp.1等为偶见种。每种榕小蜂在单果上的数量随季节呈波动变化,季节对榕小蜂群落的多样性和均匀性无显著影响。除了传粉榕小蜂外,Sycoscapter sp.1也是优势种类之一。传粉榕小蜂的数量与非传粉榕小蜂总数间呈显著负相关。传粉榕小蜂与非传粉榕小蜂几乎都呈负相关,而与Walkerella sp.1在数量上呈显著正相关。Sycobia sp.2与Sycophila sp.2在同一瘿中出现,数量上呈显著正相关。但其它非传粉榕小蜂种类在数量上的相关性较为复杂,可能是造成各种榕小蜂数量波动的一个原因。     

细叶榕榕小蜂群落结构及动态变化

细叶榕为桑科榕属植物,雌雄异株,广泛分布于印度-澳大利亚(Asia-Australasia)榕树植物分布中心区,它既是热带雨林的主要树种,也是庭院和行道绿化的常见树种。通过全年定时、定点、定株观察与采集,对福州2个样地19株细叶榕隐头果内小蜂群落结构及其动态进行研究。全年在两个样地530个隐头果内共收集到小蜂26318只。发现细叶榕隐头果内有17种小蜂,隶属小蜂总科Chalcidoidae中的榕小蜂科(Agaonidae)、隐针榕小蜂亚科(Epichrysomallinae)、金小蜂科(Pteromalidae)、广肩小蜂科(Eurytomidae)和刻腹小蜂科(Ormyridae),其中榕小蜂科的Eupristina verticillata是细叶榕唯一的传粉者,传粉方式为主动传粉,其性比为0.16,具明显偏雌现象;非传粉小蜂中,有翅雄蜂的榕小蜂(Odontofroggatia galili,O.quinifuniculus,O.corneri,Sycophila sp.1,Sycophila sp.2,Meselatus bicolor)的性比(0.46—0.55)较高,无翅雄蜂的榕小蜂(P.taiwanensis,Sycoscaptergajimaru,W.microcarpae)的性比(0.31—0.37)较低,而既具有翅雄蜂又具无翅雄蜂的非传粉榕小蜂(P.okinavensis)性比(0.47)居中。榕小蜂的性比可能与其交配行为策略有关。在细叶榕小蜂群落结构中,传粉小蜂E.verticillata的重要值占绝对优势,非传粉小蜂O.galili和Sycophila sp.2的重要值仅次于传粉小蜂。根据榕小蜂发生数量及连续性,可将细叶榕隐头果中的榕小蜂分为常见种和偶见种,E.verticillata、Odontofroggatia galili、Walkerella microcarpae、Sycophila sp.1、Sycophila sp.2和Philotrypesis okinavensis为常见种,其余11个种为偶见种。传粉小蜂和非传粉小蜂的种类和数量呈现明显的季节性变化。2月至6月期间,每月出现的榕小蜂种类较少,仅3—4种,单果内平均有传粉小蜂48.88只,非传粉小蜂13.64只;7月至翌年1月间,每月出现的榕小蜂种类较多,达6—13种,单果内平均有传粉小蜂24.38只,非传粉小蜂18.89只,表明,7月—翌年1月单果内传粉小蜂数量比较于2—6月极显著降低(P<0.001),而单果内非传粉小蜂数量极显著提高(P=0.001),同时种类也显著增加。雄花期榕小蜂的种类与数量取决于雌花期产卵榕小蜂的种类与数量,而雨量、气温以及雌花期花序果数量对产卵小蜂的数量,以及小蜂产卵行为都可能产生影响。本研究结果可为城市绿化和热带雨林生物多样性保护提供科学依据。     

福州大叶榕隐头果内的小蜂群落结构与多样性

对福州2个样地10株大叶榕果内小蜂群落组成和物种多样性进行研究。全年在两个样地267个隐头果内共收集到小蜂13458只。发现大叶榕隐头果内有7种小蜂,隶属小蜂总科Chalcidoidae中的榕小蜂科Agaonidae、金小蜂科Pteromalidae的隐针榕小蜂亚科Epichrysomallinae、锥尾榕小蜂亚科Otitesellinae和延腹榕小蜂亚科Sycoryctinae;广肩小蜂科Eurytomidae、刻腹小蜂科Ormyridae、姬小蜂科Eulophidae,其中榕小蜂科的Platyscapa coronata是大叶榕唯一的传粉者,传粉方式为主动传粉;非传粉榕小蜂的雄性多型现象普遍。传粉与非传粉小蜂的性比明显具有偏雌现象。传粉小蜂性比为0.19±0.07,非传粉小蜂中Camarothorax bismasculinus小蜂性比为0.36±0.10;Walkerella sp.小蜂性比为0.36±0.22,Sycoscapter sp.小蜂性比为0.31±0.22,Sycophila sp.小蜂性比为0.35±0.13。雄性多型现象可能是导致非传粉小蜂性比提高的原因之一。根据各种榕小蜂发生数量及连续性,可将大叶榕隐头果中的榕小蜂分为常见种和偶见种,Platyscapa coronata、Camarothorax bismasculinus、Walkerella sp.、Sycoscapter sp.和Sycophila sp.为常见种,Omyrus sp.和Aprostocetus sp.为偶见种。偶见种的存在对常见种的数量几乎没有影响,偶见种利用的是榕果内未饱和的一部分资源,也可能是榕果为偶见种的发生预留了空间和资源。首次发现姬小蜂科的昆虫寄生在榕果内,且有一定的种群数量,为姬小蜂科昆虫分类及其生物学、生态学特性研究提供了基础资料。在大叶榕小蜂群落结构中,传粉小蜂和非传粉小蜂的种类和数量呈现明显的季节性。冬-春季(12-翌年5月)榕果内小蜂的种类和数量较多,传粉榕小蜂是优势种,其重要值达到0.42,榕果种子结实率高;夏-秋季(6-11月间)小蜂种类和数量略少,Camarothorax bismasculinus和Sycophila sp.是优势种,其重要值分别为0.56和0.28,而传粉小蜂的重要值仅为0.025,此期大叶榕榕果中几乎找不到传粉小蜂,榕果结实率极低,对大叶榕的繁殖利益有较大的负面影响。雨水和高温等不良气候,可能是导致夏-秋季雄花期榕果内的传粉小蜂数量骤减的主要原因。两个实验样地的小蜂群落结构组成没有明显差异,年变化趋势相似。研究结果为城市绿化和热带雨林生物多样性保护提供科学依据。     

歪叶榕非传粉小蜂的繁殖策略及其对榕-蜂共生系统的影响

2004年8月至2005年8月在西双版纳热带植物园内,通过广泛收集歪叶榕榕小蜂标本、非传粉小蜂产卵行为学观察和阻止传粉者入果等实验方法,研究了我国西双版纳热带雨林下的一种榕树——歪叶榕Ficus cyrtophylla的榕小蜂群落组成结构、非传粉小蜂的繁殖策略以及它们对榕-蜂共生系统的影响。结果表明,歪叶榕中除了具有唯一传粉榕小蜂Blastophag sp.以外,还具有3种非传粉小蜂Platyneura sp.、Philotrypesis sp.和Sycoscapter sp.。在歪叶榕榕小蜂群落中,传粉榕小蜂占整个群落总数的92.21%,是群落的最主要组成者;主要的非传粉小蜂是Sycoscaptersp.,占5.78%; 其次是Philotrypesissp.,占1.84%,而Platyneurasp.仅占群落总数的0.17%。歪叶榕中的非传粉小蜂通过各自产卵时间和食性分化的策略来利用榕果中的资源繁殖后代。非传粉小蜂寄生使传粉榕小蜂的总数和其雌蜂数量都显著地降低,但是对传粉小蜂雄蜂数量没有显著影响,从而导致传粉榕小蜂的雄性性比显著地增加。这说明非传粉小蜂在选择寄居宿主时具有明显的倾向性,而且更多地将卵产于含有雌性传粉小蜂的瘿花之中。因此,非传粉小蜂通过减少雌性传粉小蜂的数量而降低了榕树的雄性适合度,从而在一定程度上对榕 蜂共生系统的稳定存在和发展产生了负面影响。     

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.     

高榕小蜂群落结构及物种多样性的初步研究

在西双版纳地区采集干、湿两季5个样株的高榕(Ficus altissima)隐头果,单果收蜂,鉴定蜂种,共获高榕隐头果内小蜂标本18 000多号,隶属膜翅目5科9属14种。然后对样株小蜂群落结构、组成、性比及物种多样性进行对比研究。小蜂群落的结构和组成在干、湿两季有着明显的差异：湿季隐头果内的小蜂种类比干季丰富。另外,受人为干扰较少的样株隐头果内小蜂种类比受严重干扰的样株丰富。高榕的非传粉小蜂主要由造瘿者组成,寄生小蜂和寄居性小蜂仅占很少一部分;干、湿两季的小蜂群落多样性指数均很低,虽然在湿季群落内小蜂的丰富度指数较高,但不如干季小蜂分布得均匀;相同季节的小蜂群落均为中等相似,不同季节的2个榕树小蜂群落为中等不相似,有的树对达到极不相似水平;高榕隐头果内传粉小蜂的雄雌性比(♂：♀)较低,为0.14：1,而非传粉小蜂的雄雌性比相对较高,多在1：1左右。以上研究结果表明,西双版纳地区高榕隐头果内的小蜂受不同季节温湿度、人为干扰程度等因素的影响,保护并改善西双版纳地区的生态环境对丰富高榕隐头果小蜂物种多样性有重要意义。     

一种非传粉榕小蜂的繁殖策略及其对榕—蜂互利共生系统的影响

为了解非传粉榕小蜂与榕树—传粉榕小蜂互利共生系统的作用方式和作用强度, 从而揭示它们长期稳定共存的原因, 作者于2008年在西双版纳热带植物园研究了钝叶榕(Ficus curtipes)非传粉榕小蜂Walkerella sp.与榕—蜂互利共生系统的相互关系。我们野外直接观察Walkerella sp.的产卵繁殖行为, 并对Walkerella sp.和传粉榕小蜂进行控制放蜂实验。实验包括4类处理榕果: 传粉榕小蜂单种放蜂果, Walkerella sp.单种放蜂果, Walkerella sp.与传粉榕小蜂混合放蜂果, 自然果。结果表明, Walkerella sp.在榕果外产卵, 并且可以将卵产在多个榕果上。单因素方差分析结果表明: 混合放蜂果和自然果内传粉榕小蜂后代数量差异不大(P = 0.46), 但都显著低于传粉榕小蜂单种放蜂果(P < 0.01); 在传粉榕小蜂单种放蜂果以及混合放蜂果内种子数量不存在显著差异(P = 0.33), 但都显著高于自然果(P < 0.01)。自然果内Walkerella sp.后代数量与传粉榕小蜂数量呈显著的相关关系, 而在混合放蜂果内两者呈低度负相关。Walkerella sp.与种子数量在自然果和混合放蜂果都不存在显著的相关关系。单因素方差分析结果表明, Walk-erella sp.单种放蜂果、混合放蜂果及自然果中Walkerella sp.数量不存在显著差异(P < 0.01)。对自然果内所有种类小蜂的相关分析表明: Walkerella sp.与其他非传粉榕小蜂都不存在显著的相关关系, 这说明不存在寄居或复寄生的非传粉榕小蜂种类控制Walkerella sp.的数量。而Walkerella sp.之所以没有完全利用榕果内的小花资源繁殖后代, 是由于产卵量有限和后代必须依靠传粉榕小蜂雄虫打开苞片口才能离开榕果, 必须给传粉小蜂留下一些繁殖资源。     

垂叶榕榕小蜂群落及种间互作网络季节动态

群落中的物种相互作用构成了复杂的生态网络。有关物种的数量和组成的季节性动态变化已有较多的研究, 但是对于生态网络的动态变化知之甚少。揭示生态网络的动态变化对于理解群落的稳定性以及群落的动态变化过程和机理具有重要意义。本研究以垂叶榕(Ficus benjamina)榕小蜂群落为研究对象, 分别在西双版纳的干季和雨季采集了榕小蜂的种类和数量信息。比较了两个季节榕小蜂群落的动态变化以及共存网络的参数(例如网路直径、连接数、嵌套性和群落矩阵温度)变化。结果显示: 雨季榕果内传粉榕小蜂Eupristina koningsbergeri所占比例高于干季, 传粉榕小蜂的种群数量也高于干季, 而在干季非传粉榕小蜂的种类增加(干季15种小蜂, 雨季14种)。从榕树-传粉榕小蜂互利共生系统的适合度来看, 干季非传粉小蜂的增加对传粉榕小蜂和榕树的适合度是不利的。在干季, 共存网络物种间的连接数(干季0.95, 雨季0.47)多于雨季, 群落矩阵温度(干季23.24, 雨季2.64)也显著高于雨季。表明干季榕小蜂群落组成及种间关系较雨季更为复杂而多样, 高的矩阵温度暗示群落受到的干扰更大。     

Chaos of Wolbachia Sequences Inside the Compact Fig Syconia of Ficus benjamina (Ficus: Moraceae)

Figs and fig wasps form a peculiar closed community in which the Ficus tree provides a compact syconium (inflorescence) habitat for the lives of a complex assemblage of Chalcidoid insects. These diverse fig wasp species have intimate ecological relationships within the closed world of the fig syconia. Previous surveys of Wolbachia, maternally inherited endosymbiotic bacteria that infect vast numbers of arthropod hosts, showed that fig wasps have some of the highest known incidences of Wolbachia amongst all insects. We ask whether the evolutionary patterns of Wolbachia sequences in this closed syconium community are different from those in the outside world. In the present study, we sampled all 17 fig wasp species living on Ficus benjamina, covering 4 families, 6 subfamilies, and 8 genera of wasps. We made a thorough survey of Wolbachia infection patterns and studied evolutionary patterns in wsp (Wolbachia Surface Protein) sequences. We find evidence for high infection incidences, frequent recombination between Wolbachia strains, and considerable horizontal transfer, suggesting rapid evolution of Wolbachia sequences within the syconium community. Though the fig wasps have relatively limited contact with outside world, Wolbachia may be introduced to the syconium community via horizontal transmission by fig wasps species that have winged males and visit the syconia earlier.     

Disturbance effects on community structure of Ficus tinctoria fig wasps in Xishuangbanna, China: Implications for the fig/fig wasp mutualism

Abstract  Fig trees are important components of tropical forests, because their fruits are eaten by so many vertebrates, but they depend on pollinating fig wasps to produce mature fruits. Disturbance to habitat structure can have a major impact on insect diversity and composition, potentially reducing fruit yields. We investigated the impact of habitat disturbance on the fig wasp community associated with male figs of Ficus tinctoria in Xishuangbanna, China. The community comprised one pollinator species Liporrhopalum gibbosae and six non-pollinating wasp species: Sycoscapter sp.1, Philotrypesis ravii , Philotrypesis sp.1, Neosycophila omeomorpha , Sycophila sp.1, and Walkerella sp.1. More disturbed areas were characterized by higher temperatures, less shade, and more vehicle noise. The response of the fig wasp community was complex, with no simple relationship between intensity of disturbance and pollinator abundance. However, the sex ratios (proportion of male progeny) of pollinators increased significantly in more disturbed areas. We conclude that potential changes in fig wasp community composition brought about by disturbance, are unpredictable, with unclear consequences for tropical rainforest biodiversity.     

How to be a fig wasp down under: The diversity and structure of an Australian fig wasp community

Endophytic insects and their parasitoids provide valuable models for community ecology. The wasp communities in inflorescences of fig trees have great potential for comparative studies, but we must first describe individual communities. Here, we add to the few detailed studies of such communities by describing the one associated with Ficus rubiginosa in Australia. First, we describe community composition, using two different sampling procedures. Overall, we identified 14 species of non-pollinating fig wasp (NPFW) that fall into two size classes. Small wasps, including pollinators, gallers and their parasitoids, were more abundant than large wasps (both galler and parasitoid species). We show that in figs where wasps emerge naturally, the presence of large wasps may partly explain the low emergence of small wasps. During fig development, large gallers oviposit first, before and around the time of pollination, while parasitoids lay eggs after pollination. We further show that parasitoids in the subfamily Sycoryctinae, which comprise the majority of all individual NPFWs, segregate temporally by laying eggs at different stages of fig development. We discuss our results in terms of species co-existence and community structure and compare our findings to those from fig wasp communities on other continents.     

榕小蜂温度耐受性及其对种间共存关系的影响

全球已知有约800种榕属(Ficus)植物, 主要分布在热带, 部分种类延伸至亚热带地区。温度是限制榕‒蜂共生系统分布北界的主要因素, 也显著影响榕树及其榕小蜂的繁殖成功, 其中榕小蜂对温度的响应更加敏感。榕小蜂只有在一定的温度范围内才能保持正常的生理机能, 其对温度耐受能力直接影响榕果内小蜂种群数量和群落内种间关系。然而目前对榕小蜂温度耐受性的研究尚少, 榕小蜂的温度耐受能力如何影响榕果内小蜂的共存关系还未见报道。本文研究了分布于西双版纳的2种雌雄同株和1种雌雄异株榕树果内传粉榕小蜂和非传粉小蜂的温度耐受能力。结果表明: 3种传粉榕小蜂对高温的耐受性极差, 相对于雌雄同株的高榕(F. altissima)和聚果榕(F. racemosa)传粉榕小蜂, 雌雄异株的鸡嗉子榕(F. semicordata)传粉榕小蜂对低温有增强的耐受趋势。聚果榕小蜂群落结构显示: 在适宜其生长的西双版纳地区, 传粉榕小蜂的数量占绝对优势, 在温度较低的季节其数量显著减少; 而非传粉榕小蜂呈相反模式, 较强的温度耐受能力使其在低温的雾凉季维持了较高的种群数量。鸡嗉子榕果内非传粉小蜂Sycoscapter trifemmensis相对于Philotrypesis dunia有更强的温度耐受能力, 在种群数量和种间关系上有更多的竞争优势及数量。榕小蜂的温度耐受性差异在物种分布、种间关系的维持和共存上起了重要作用, 本研究结果为阐明榕小蜂种间共存的维持机制提供了科学依据。     

Divvying up an incubator: How parasitic and mutualistic fig wasps use space within their nursery microcosm

Differential occupancy of space can lead to species coexistence. The fig–fig wasp pollination system hosts species-specific pollinating and parasitic wasps that develop within galls in a nursery comprising a closed inflorescence, the syconium. This microcosm affords excellent opportunities for investigating spatial partitioning since it harbours a closed community in which all wasp species are dependent on securing safe sites inside the syconium for their developing offspring while differing in life history, egg deposition strategies and oviposition times relative to nursery development. We determined ontogenetic changes in oviposition sites available to the seven-member fig wasp community of Ficus racemosa comprising pollinators, gallers and parasitoids. We used species distribution models (SDMs) for the first time at a microcosm scale to predict patterns of spatial occurrence of nursery occupants. SDMs gave high true-positive and low false-positive site occupancy rates for most occupants indicating species specificity in oviposition sites. The nursery microcosm itself changed with syconium development and sequential egg-laying by different wasp species. The number of sites occupied by offspring of the different wasp species was negatively related to the risk of syconium abortion by the plant host following oviposition. Since unpollinated syconia are usually aborted, parasitic wasps ovipositing into nurseries at the same time as the pollinator targeted many sites, suggesting response to lower risk of syconium abortion owing to reduced risk of pollination failure compared to those species ovipositing before pollination. Wasp life history and oviposition time relative to nursery development contributed to the co-existence of nursery occupants.     

High incidences and similar patterns of Wolbachia infection in fig wasp communities from three different continents

Abstract Wolbachia are endosymbiotic bacteria that infect numerous arthropod species. Previous studies in Panama and Australia revealed that the majority of fig wasp species harbor Wolbachia infections, but that similar patterns of incidence have evolved independently with different wasp species and Wolbachia strains on the two continents. We found Wolbachia infections in 25/47 species (53%) of fig wasp associated with 25 species of Chinese figs. Phylogenetic analyses of Wolbachia wsp sequences indicated that very similar strains are not obviously found in either closely related or ecologically linked fig wasps species. The extremely high prevalence of Wolbachia in fig wasps (over 50% of species infected) is not constrained by geographical origin and is a recurrent theme of fig wasp/Wolbachia interactions.     

Contrasting patterns of fig wasp communities along Mt. Wilhelm,Papua New Guinea

The fig (Moraceae) and pollinating fig wasp (Agaonidae) mutualism is best known as a model system for the study of coevolution in plant–pollinator interactions and its central role in shaping vertebrate communities in tropical forests. Figs also host myriad antagonistic parasitic fig wasps which impose costs on both partners threatening mutualism stability. Spatiotemporal variation in parasitic wasp abundance is a key factor in mitigating these effects. Because fig wasps are temperature sensitive and likely vary in their ability to traverse environmental gradients, we expect community assemblages and abundance of both pollinating and non-pollinating fig wasps to respond to changes along an elevational gradient. In the present study, we compare the fig wasp communities and abundance of three fig species growing along the slopes of the Mount Wilhelm altitudinal gradient in Papua New Guinea. We quantified wasps from over 100 male fig trees and calculated seed set for 55 female trees along each of the species’ distribution on the transect. Our results show that the abundance of both pollinating and non-pollinating fig wasps follow a mid-elevation peak, consistent with fig species richness found in the same transect. The patterns, however, are different according to the host's species distribution. Seed set remained relatively constant along the gradient for all species with some decrease along higher elevations, potentially affecting connectivity along the gradient. As suggested for insects in general, temperature and habitat diversity appear to play a fundamental role in the species richness and abundance of fig wasps.