动物与植物种子更新的关系I.对象,方法及意义

大多数植物靠种子库来更新。种子从离开母体到建成幼苗的过程中始终受动物活动的影响。动物对种子既有取食消耗的不利一面,又有将其扩散到适于发芽的安全地点的有利一面,二者处于一种利弊权衡状态。研究动物与植物种子更新的关系,有助于揭示种群动态的机制,理解动物和植物之间协同进化的规律,了解生态系统演替及其组分之间的关系,认识取食种子的动物在生态系统中的作用,进而为生态系统维持和生物多样性保护提供科学依据及有效     

啮齿动物的贮藏行为与植物种子的扩散

绝大多数啮齿动物一方面取食大量的植物种子和果实,另一方面通过其贮食行为将植物种子和果实搬运到远离母树的地点,即扩散,并将它们分散埋藏在落叶下或浅表的土层中,从而影响种子和果实的时空分布,最后导致幼苗在有利的条件下发生和建成,实现植物更新。啮齿动物与植物种子和果实之间已广泛形成了互惠或协同进化的关系。啮齿动物的贮食行为主要通过以下几个过程对植物种子和果实的扩散产生影响：选择、搬运和埋藏以及随后对种子和幼苗存活和死亡的影响等。本综述了啮齿动物对植物种子和果实贮藏的研究结果,以期为进一步开展啮齿动物的贮食行为在植物种子和果实的扩散中的作用的研究提供参考。     

动物与植物种子更新的关系Ⅰ.对象、方法与意义

大多数植物靠种子库来更新。种子从离开母体到建成幼苗的过程中始终受动物活动的影响。动物对种子既有取食消耗的不利一面,又有将其扩散到适于发芽的安全地点的有利一面,二者处于一种利弊权衡状态。研究动物与植物种子更新的关系,有助于揭示种群动态的机制,理解动物和植物之间协同进化的规律,了解生态系统演替及其组分之间的关系,认识取食种子的动物在生态系统中的作用,进而为生态系统维持和生物多样性保护提供科学依据及有效措施。目前对动物与森林更新关系的研究主要以栎、松等代表树种为研究对象。已知鼠类和鸟类是大型种子主要的捕食者和扩散者。     

啮齿动物对种子的传播

简要介绍了扩散、传播植物种子的啮齿动物种类、它们传播的植物种子种类,以及啮齿动物对植物种子扩散、传播的主动、被动方式及双方在这一体系中的互惠关系和可能存在的协同进化关系。     

鼠类对山杏(Prunus armeniaca)种子扩散及存活作用研究

虽然有关鼠类搬运森林种子的证据已很清楚,但这些被移走种子的存活情况却知之甚少.提出了一个新的标记和跟踪种子的方法--标签法,即将种子拴一带有编码的细长金属片,研究了北京东灵山地区山杏(Prunus armeniaca)种子的扩散距离和存活率.于1998年6月19～20日,7月3日和10月23日共在24个样点释放1440粒山杏种子.几乎所有释放的种子在10d内被鼠类取走.夏天释放的种子比秋天释放的种子消失的速度快.大多数种子的扩散距离在20m以内,小于鼠类的活动距离.鼠类吃掉种子的速度很快,但当种子变得稀少时,种子存活率有所提高.山杏种子6、7月份的每日存活率小于其它月份的每日存活率.     

第四届国际食果动物与种子扩散研讨会

二十世纪七十年代以来,食果动物与种子扩散关系已成为生态学领域的研究热点之一。因为它不仅涉及动植物之间的协同进化问题,而且与生物多样性保护、森林退化和破碎化和外来种入侵等当前环境问题密切相关。国际食果动物与种子扩散研讨会先后在墨西哥（第一届和第二届）、巴西分别于1986年、1993年和2000年已成功举行了三届,     

植物大年结实及其与动物贮食行为之间的关系

大年结实(mast seeding)是多生年植物种群周期性同步大量繁殖的一种自然现象。大年结实作为植物适应环境条件、提高繁殖能力的一种策略而备受关注, 但其驱动机制和进化意义尚存在较大争议。在依赖动物扩散种子的植物中, 大年结实被认为是一种调控动物贮食行为、提高种子扩散效率, 并最终增加繁殖成功率的一种策略; 动物介导的植物间互作可能是促进植物共存的进化驱动力。本文简要梳理了大年结实现象的各种假说, 提出了一个包括气候、资源、动植物互作的理解大年结实机制的概念框架, 并着重讨论了大年结实和动物贮食行为之间的关系及其进化和生态意义。建议未来研究需要借助长期生态监测和分子生物学方法, 揭示植物大年结实与动物贮食行为之间的生态与进化过程。     

不同扰动生境中动物对酸苔菜种子的捕食和散布

有效的种子散布是木本植物形成入侵种需要经历的过程之一,但在预测入侵种时却常常被忽略.紫金牛科东方紫金牛(Ardisia elliptica)原产热带亚洲而在北美成为入侵植物,分布在云南南部的其同属种酸苔菜(A.solariacea)与之具有相似的生物学特征.本文以酸苔菜为研究对象,于2004年12月至次年2月分别在人为干扰轻的野象谷和人为干扰重的植物园进行酸苔菜的种子散布及捕食研究,试图了解生境变化对其种子散布和种子捕食的影响.结果表明,酸苔菜在两地的种子散布者均为白喉冠鹎(Alophoixus pallidus)、黑冠黄鹎(Pycnonotus melanicterus)和灰眼短脚鹎(Iole propinqua),但3种食果实鸟类的组成比例、拜访行为、频率及种子捕食者的影响在两地均不相同.人为干扰轻的野象谷生境中白喉冠鹎、黑冠黄鹎与灰眼短脚鹎的拜访频率分别为25%、32%和26%.取食后的第一次停栖地点有4%在10 m以外;人为干扰重的植物园生境中3种鸟的拜访频率分别为67%、8%、5%,取食后的第一次停栖地点有26%在10 m以外.人工摆放种子试验表明,地面上种子捕食者主要是啮齿类;在两生境中种子捕食率均较低(2-6%),但野象谷生境中种子捕食率仍显著高于植物园生境.野象谷生境中种子还受到象鼻虫幼虫的危害,危害率为17.9±3.5%(n=512);而植物园生境中未发现种子被象鼻虫危害(n=489).干扰对生境中的动物组成及行为造成了明显影响,并可能通过种子散布与捕食的改变而间接影响与其有密切关系植物的种群动态.     

凋落物和土壤覆盖对动物取食和搬运辽东栎种子的影响

在六盘山区的华北落叶松人工林,研究了清除凋落物、凋落物覆盖和土壤覆盖(以不清除凋落物直接将种子投放于森林地表为对照)等处理对动物取食和搬运辽东栎种子的影响.结果表明:种子释放3d后,凋落物和土壤覆盖处理种子均具有较高的留存率(分别为10.7％和7.0％);释放14 d后,土壤覆盖处理种子的留存率仍最高(0.7％),但凋落物覆盖处理种子的留存率为0.凋落物和土壤覆盖处理种子的就地取食率很高(分别为45.9％和41.5％);清除凋落物处理种子的就地取食率最低(27.0％),但其被搬运后的取食率最高(49.8％);凋落物覆盖、清除凋落物和土壤覆盖处理种子被动物搬运后的埋藏率均显著高于对照(P＜0.01).种子被动物搬运后集中分布于5 m以内,尤其在＜1 m和l～2m两个距离组的分布频率更高;种子被搬运后取食的平均距离大干埋藏的平均距离,以土壤覆盖和凋落物覆盖处理最大,分别为2.38 m±0.55 m和1.44m±0.26 m.     

Cloning capacity helps seeds of Garcinia xanthochymus counter animal predation

Seed predators have the potential to act as agents of natural selection that influence seed traits and seed fates, which in turn affect the whole plant population dynamic. Accordingly, plants deploy a variety of mechanisms (e.g., resistance and tolerance strategies) to lessen the impact of predation on seed crop or on an individual seed. In this study, we described a novel mechanism, seed cloning strategy, in a tropical plant species in countering animal predation. By conducting field‐ and laboratory‐based germination experiments, we found that both rodent damaged and artificially damaged seed fragments of a large‐seeded tree Garcinia xanthochymus (Clusiaceae) could successfully germinate and establish as seedlings. Tissue culture experiments revealed that G. xanthochymus has no endosperm in seeds, and its seed fragments own strong capacity of differentiation and cloning. Seed damage negatively affected seedling growth and germination, but the seed germination rate was remarkably high. Our study suggests that, seed cloning capacity, adopted by the large‐seeded tree G. xanthochymus may act as a novel strategy counteract for seed predation and would play a significant role in stabilizing the mutualism between plant and animals.     

Role of small rodents in the seed dispersal process: Microcavia australis consuming Prosopis flexuosa fruits

Understanding the functional role of animal species in seed dispersal is central to determining how biotic interactions could be affected by anthropogenic drivers. In the Monte Desert, mammals play different functional roles in Prosopis flexuosa seed dispersal, acting as opportunistic frugivores (endozoochorous medium‐sized and large mammals) or seed hoarders (some small sigmodontine rodents). Our objective was assessing the functional role of Microcavia australis, a small hystricognathi rodent, in the fruit removal and seed deposition stages of P. flexuosa seed dispersal, compared to sympatric sigmodontine rodents. In situ, we quantified fruit removal by small rodents during non‐fruiting and fruiting periods, and determined the distance seeds were transported, particularly by M. australis. In laboratory experiments, we analysed how M. australis stores seeds (through scatter‐ or larder‐hoarding) and how many seeds are left in caches as living seeds, relative to previous data on sigmodontine rodents. To conduct field studies, we established sampling stations under randomly chosen P. flexuosa trees at the Ñacuñán Man and Biosphere Reserve. We analysed fruit removal by small rodents and seed dispersal distance by M. australis using camera traps focused on P. flexuosa fruits covered with wire screen, which only allowed entry of small animals. In laboratory trials, we provided animals with a known number of fruits and assessed seed conditions after removal. Small rodents removed 75.7% of fruit supplied during the non‐fruiting period and 53.2% during the fruiting period. Microcavia australis and Graomys griseoflavus were the main fruit removers. Microcavia australis transported seeds to a mean distance of 462 cm and cached seeds mainly in scatter‐hoards, similarly as Eligmodontia typus. All transported seeds were left in fruit segments or covered only by the endocarp, never as predated seeds. Microcavia australis disperses P. flexuosa seeds by carrying fruits away from a source to consume them and then by scatter‐hoarding fruits and seeds.     

A seed predator drives the evolution of a seed dispersal mutualism

Although antagonists are hypothesized to impede the evolution of mutualisms, they may simultaneously exert selection favouring the evolution of alternative mutualistic interactions. We found that increases in limber pine (Pinus flexilis) seed defences arising from selection exerted by a pre-dispersal seed predator (red squirrel Tamiasciurus hudsonicus) reduced the efficacy of limber pine's primary seed disperser (Clark's nutcracker Nucifraga columbiana) while enhancing seed dispersal by ground-foraging scatter-hoarding rodents (Peromyscus). Thus, there is a shift from relying on primary seed dispersal by birds in areas without red squirrels, to an increasing reliance on secondary seed dispersal by scatter-hoarding rodents in areas with red squirrels. Seed predators can therefore drive the evolution of seed defences, which in turn favour alternative seed dispersal mutualisms that lead to major changes in the mode of seed dispersal. Given that adaptive evolution in response to antagonists frequently impedes one kind of mutualistic interaction, the evolution of alternative mutualistic interactions may be a common by-product.     

Interspecific synchrony of seed rain shapes rodent‐mediated indirect seed–seed interactions of sympatric tree species in a subtropical forest

Animal‐mediated indirect interactions play a significant role in maintaining the biodiversity of plant communities. Less known is whether interspecific synchrony of seed rain can alter the indirect interactions of sympatric tree species. We assessed the seed dispersal success by tracking the fates of 21 600 tagged seeds from six paired sympatric tree species in both monospecific and mixed plots across 4 successive years in a subtropical forest. We found that apparent mutualism was associated with the interspecific synchrony of seed rain both seasonally and yearly, whereas apparent competition or apparent predation was associated with interspecific asynchrony of seed rain either seasonally or yearly. We did not find consistent associations of indirect interactions with seed traits. Our study suggests that the interspecific synchrony of seed rain plays a key role in the formation of animal‐mediated indirect interactions, which, in turn, may alter the seasonal or yearly seed rain schedules of sympatric tree species.     

植物天然更新过程中种子和幼苗死亡的影响因素

植物天然更新包括有种子搬运、种子库动态、种子萌发和幼苗定居等过程。从种子生产到幼苗定居的更新是植物生活史中最为敏感的阶段之一 ,多种因素的影响种子和幼苗的命运。其中包括 :( 1 )动物取食或病原体侵袭。种子在扩散和搬运过程中 ,易被小哺乳动物或无脊椎动物取食。蛀虫也可以使种子失去萌芽能力。病原体感染种子和幼苗 ,容易引起种子和幼苗的死亡。 ( 2 )异质生境的影响。在不同生境中 ,光照条件、土壤水分和化学成分等因子的组合严重影响种子和幼苗的命运。 ( 3 )干扰的影响。小尺度和大尺度的干扰都可以影响到植物更新时种子和幼苗的命运。林窗作为特殊的干扰体系 ,为不同种类植物提供了更新的机会。 ( 4 )繁殖体特征。种子大小、质量和保护色等特征影响种子和幼苗在更新过程中的生存。种子休眠期间 ,由于生理衰老和腐烂的原因使种子失去活力而不能萌发。 ( 5 )密度和距离制约。母株附近由于密度竞争的影响 ,种子和幼苗死亡率都较高。     

How plants manipulate the scatter-hoarding behaviour of seed-dispersing animals

Some plants that are dispersed by scatter-hoarding animals appear to have evolved the ability to manipulate the behaviour of those animals to increase the likelihood that seeds and nuts will be stored and that a portion of those items will not be recovered. Plants have achieved this in at least four ways. First, by producing large, nutritious seeds and nuts that are attractive to animals and that stimulate hoarding behaviour. Second, by imposing handling costs that cause animals to hoard rather than to eat items immediately. These handling costs can take one of two forms: physical barriers (e.g. hard seed coats) that take time to remove and secondary chemicals (e.g. tannins) that impose metabolic costs. Third, by masting, where a population of plants synchronizes reproductive effort, producing large nut crops at intervals of several years. Mast crops not only satiate seed predators, but also increase the amount of seed dispersal because scatter-hoarding animals are not easily satiated during caching (causing animals to store more food than they can consume) but are satiated during cache recovery. And fourth, by producing seeds that do not emit strong odours so that buried seeds are less likely to be discovered. These, and perhaps other, traits have increased the relative success of plant species with seeds dispersed by scatter-hoarding animals.     

Climate change and plant regeneration from seed

At the core of plant regeneration, temperature and water supply are critical drivers for seed dormancy (initiation, break) and germination. Hence, global climate change is altering these environmental cues and will preclude, delay, or enhance regeneration from seeds, as already documented in some cases. Along with compromised seedling emergence and vigour, shifts in germination phenology will influence population dynamics, and thus, species composition and diversity of communities. Altered seed maturation (including consequences for dispersal) and seed mass will have ramifications on life history traits of plants. Predicted changes in temperature and precipitation, and thus in soil moisture, will affect many components of seed persistence in soil, e.g. seed longevity, dormancy release and germination, and soil pathogen activity. More/less equitable climate will alter geographic distribution for species, but restricted migratory capacity in some will greatly limit their response. Seed traits for weedy species could evolve relatively quickly to keep pace with climate change enhancing their negative environmental and economic impact. Thus, increased research in understudied ecosystems, on key issues related to seed ecology, and on evolution of seed traits in nonweedy species is needed to more fully comprehend and plan for plant responses to global warming.     

A comparative analysis of seed and cone characteristics and seed-dispersal strategies of three pines in the subsection Sabinianae

The seed-dispersal systems of Coulter pine (Pinus coulteri), gray pine (P. sabiniana), and Torrey pine (P. torreyana), all of the subsection Sabinianae, are not well understood. These pines occur in arid and semi-arid foothills and mountains of California that are subjected to frequent fires. Cone and seed traits of these three California pines are compared to those of four species of pines (sugar pine, P. lambertiana; Jeffrey pine, P. jeffreyi; ponderosa pine, P. ponderosa; and lodgepole pine, P. contorta) that occur in more mesic environments in the nearby Sierra Nevada mountains. The cones of the Sabinianae pines are large with thick, dense scales, and the scales of gray and Coulter pines are armed with sharp, recurved spines. The seeds of all three species are large, and those of gray and Torrey pines are nearly wingless. In contrast, the Sierra Nevada pines have small to medium-sized seeds with large wings that are initially dispersed by the wind. Heavy wing loading of the Sabinianae pine seeds causes them to fall rapidly, and they are not dispersed far by wind. However, animals remove the fallen seeds rapidly, and rodents and jays scatter hoarded many seeds in the soil. This caching activity results in seedling establishment. The unusual morphology of the cones and seeds of the Sabinianae pines is interpreted as a combination of traits that attract animal dispersers, thwart the foraging activities of seed predators, and promote the survival of seeds in an environment subject to frequent fires.