喜旱莲子草茎叶解剖结构从原产地到入侵地的变异式样

长期以来人们一直认为,外来种入侵及其危害是由于一个物种从原产地到入侵地其环境因子改变(如天敌压力的减弱等)而导致的。近年来,越来越多的研究者开始认识到,生物入侵过程实际上是一个现代人类活动影响下的物种的快速进化过程,生物入侵的进化遗传学已成为入侵生物学研究中最活跃的分支之一。作者比较了来自原产地(阿根廷)和入侵地(中国和美国)的喜旱莲子草(Alternantheraphiloxeroides)的11个种群在茎、叶解剖结构方面的变异式样,发现所研究的19个性状在原产地(阿根廷)和入侵地(中国和美国)的变异情况明显不同:在原产地种群中,共有9个性状指标存在显著差异,遗传率在49–89%之间,这9个性状是气孔密度、气孔指数、茎直径、髓腔直径、维管柱直径、皮层厚度、维管柱面积比、髓腔面积比和叶形指数;而在入侵地种群间,19个性状指标均无明显差异。这表明喜旱莲子草从原产地到入侵地其遗传多样性降低;入侵地喜旱莲子草种群间的形态变异主要为表型可塑性。根据19个形态指标对喜旱莲子草11个种群进行主成分分析和聚类,结果显示:所有入侵地种群和原产地的Ar1种群(SantaFé,59°49′W,29°16′S)聚为一类,原产地的Ar4(Tandil,59°03′W,37°11′S)单独聚为一类,原产地的其他4个种群聚为一类。表明Ar1种群可能与入侵中国的喜旱莲子草在基因型上更为接近。这一结果为进一步揭示喜旱莲子草入侵机理(如杂交适应性)和在原产地寻求对应天敌的生物防治工作提供了基础数据。     

洲际入侵植物生态位稳定性研究进展

人类活动引起的大规模洲际物种交换与生物入侵, 改变了当地生态系统结构与功能, 使生物多样性受到日益严重的威胁。本文通过综合分析主要国家和地区入侵植物的地理起源, 发现洲际入侵主要包括东亚—北美、东亚—南美、欧洲—南非、欧洲—北美、欧洲—东亚、北美—大洋洲等, 这些洲际入侵造成的后果往往比陆内入侵更为严重。利用物种分布模型(SDMs)预测入侵物种潜在分布范围是有效管理和提早预防生物入侵的重要依据, 但这些模型的一个关键假定是: 入侵物种的生态位在空间和时间上是保守的、稳定的。然而, 对于远离原产地种群并能快速适应新生境的洲际入侵植物来说, 生态位可能发生显著的变化。入侵种能否在入侵地保持原有的生态位, 取决于制约其生态分布的限制因素和生态过程在不同地区间是否发生变化。本文中作者总结了洲际入侵与陆内入侵的生态与进化过程的异同点, 认为这些限制物种原产地分布的因素如扩散限制、种间互作、适应性进化、生态可塑性和种群遗传特性等均可能导致入侵物种生态位的改变。建议下一步的研究应该重视: (1)对生态位属性进行多尺度的研究, 包括时间、空间、环境或系统发育等几个方面; (2)对比生态位稳定与发生偏移的物种特性, 确定什么样的入侵物种更容易改变原有的生态位; (3)进行生态位时间动态格局研究, 探讨生态位变化的倾向、历史速率和偏移程度, 以便判定生态位变化趋势。这些研究结果将会进一步提高物种分布模型的预测能力, 有助于更为准确地揭示气候变化和物种入侵对生物多样性的影响。     

The impacts of warming and nitrogen addition on competitive ability of native and invasive populations of Plantago virginica

全球变化因子(如增温和氮沉降)可能会影响生物入侵,但是这些因子如何影响入侵物种的表现并进一步调节入侵物种与本地竞争者之间的相互作用仍不清楚。本文通过为期五个月的温室实验,研究了增温(开顶式增温箱,+0.62°C)和氮添加(4.2 g N m⁻²)对入侵物种北美 车前(Plantago virginica)原产地和入侵地种群与本地车前草(Plantago asiatica)竞争的影响。实验结果表明,在增温及其与氮添加处理(W × N) 的相互作用下,P. virginica的入侵种群(PV-In)和原产地种群(PV-Na)在与本地竞争者P. asiatica竞争时具有不同的生物量分配策略。其中,PV-Na在与P. asiatica竞争时增加了地下生物量,而PV-In增加了地上生物量。我们还发现,P. virginica对增温和氮添加比P. asiatica的反应更强 烈。增温显著降低了P. virginica的竞争能力,这表明P. virginica比P. asiatica对增温的响应更为敏感。同样,在竞争条件下,氮添加及 其和增温交互作用减少了PV-In地下生物量,但增加了PV-Na地上和总生物量。这些发现表明,P. virginica在入侵过程中改变了生物量分配 策略,PV-In展示出更具弹性的竞争能力以适应环境变化(特别是增温)。这些发现可能有助于我们预测气候变化下的植物入侵并制定相应的 管理策略。     

喜旱莲子草对遮荫的可塑性反应:入侵地与原产地种群的比较

表型可塑性可能在外来植物的成功入侵和随后的扩散中起到至关重要的作用。一些研究者推测喜旱莲子草(Alternanthera philoxeroides)入侵地种群可能比原产地种群对光强具有更强的可塑性反应。为了验证该假说,我们在正常光照和遮荫(30%正常光照)条件下研究了喜旱莲子草原产地(阿根廷)和入侵地(美国)种群在形态特征和生物量分配上是否存在显著差异。结果表明:(1)喜旱莲子草对光照强度具有很强的可塑性。在遮荫处理下,其根冠比和分枝生物量比显著降低,而比茎长和比叶面积显著增加;(2)原产地和入侵地喜旱莲子草的总生物量和比叶面积对遮荫的可塑性没有显著差异。入侵地种群的根冠比、分枝强度和比茎长的可塑性显著小于原产地种群;(3)无论在正常或低光照条件下,入侵地种群的根冠比(–20.8%)、分枝强度(–54.6%)、比茎长(–18.5%)和比叶面积(–8.6%)均显著低于原产地种群。这些结果表明,喜旱莲子草对光照强度具有很强的可塑性,这可能是该物种可以分布于从河岸带草丛到疏林灌丛等各种生境的主要原因;从原产地到入侵地,喜旱莲子草与耐阴性有关的性状对光照的可塑性显著降低,可能是该物种在入侵地能够形成单优势种群的主要原因。     

An invading annual plant benefits less from soil biota and has reduced competitive power with a resident grass

弱化的植物-土壤生物共生关系降低了一年生入侵植物与本地物种的竞争能力 植物与土壤生物,特别是与丛枝菌根真菌(AMF)的关系,可能对外来植物在新环境中的建立和扩张发挥着至关重要的作用。但是,植物对AMF的依赖是否会在入侵后发生变化,及其如何影响与本 地物种的竞争仍然知之甚少。通过同质园实验,我们研究了入侵物种北美车前(Plantago virginica)的原产地(美国)和入侵地(中国)种群对AMF的响应,以及在有无竞争者的情况下这些响应是否发生变化。研究结果显示,原产地种群始终具有较高的AMF侵染率,并且其生物量和种子产量都受益于AMF。不同的是, 入侵地种群从AMF中获得的收益较少,甚至在存在竞争者的情况下,AMF的侵染使得入侵种群的生物量有所降低。入侵种群的这种低菌根依赖度可能与受到本地竞争者的更大抑制作用有关。北美车前入侵地和原产地种群对AMF的不同响应表明,其对菌根真菌的依赖性在入侵中国的过程中发生了改变。我们的发现表明,这种减少的依赖性会使入侵植物在种间竞争中付出一定的代价。     

微生物入侵影响因素研究进展

探明生物入侵的影响因素能够有效防治生物入侵,减少其对生态系统的破坏,但现有的入侵研究主要集中于动植物入侵,对微生物入侵关注较少。本文综述了外来微生物自身属性、入侵地生物和非生物状况以及外来种和土著种之间差异等对微生物入侵的影响,比较了微生物入侵与动植物入侵、微生物定殖之间的差别,提出了今后需要进一步加强的研究内容。外来微生物入侵受其自身种系、形态、大小等特性,入侵地生物多样性、天敌、有效资源等生物或非生物因子,以及外来-本地种谱系距离、生态位差异、相对适应性差异等三方面因素共同影响,但不同因素之间的关联度、交互性及相对贡献仍不清楚。外来微生物入侵过程与动植物入侵过程、微生物定殖过程有诸多类似之处,但同时也存在不少差异。今后,需加强研究外来微生物独特性状(如:持留状态和群体感应等)对其入侵影响,关注微生物进入新环境的存活数量、扩散范围和影响程度,加强利用定殖研究中常用的微生物作为入侵物种验证经典入侵理论,以及注重观察全球变化下外来微生物的入侵趋势和区分微生物在不同入侵阶段的主要影响因素。     

再谈生物入侵

生物入侵就是某种物种从它的原产地,通过非自然途径迁移到新的生态环境的过程。这些被称为生物入侵者的物种或外来种（在新区定殖,建立自然种群的生物）,其中一部分是有益的,如玉米、红薯、马铃薯等,已为世界公认,但另一部分有害：由于其有广泛的适应性,极强的繁殖能力,不仅会对“入侵领地”的生物多样性形成威胁,破坏生态平衡,还会给人类社会造成难以估量的损失。１生物入侵对社会经济的危害 如果一个物种在新的生存环境中不受食物竞争以及天敌伤害等因素制约,那么它很可能无节制地繁衍,种群迅速扩大,发展成为当地新的优势种…     

Differences in seed properties and germination between native and introduced populations of Triadica sebifera

很多入侵植物的种子比原产地植物的种子萌发的更快,这可能有利于它们成功入侵。为了理解生物入侵过程,对入侵植物的入侵种群 和原产地种群的种子特性和萌发特征同时进行评估极为必要。本研究中,我们以乌桕(Triadica sebifera)为研究对象探究种子萌发和种子 特征的种内差异。 我们利用采于2017年的乌桕种子,来自中国的12个原产地种群和美国的12个引入地种群,测定种子的物理性状(体积、重量、种皮硬度和种皮厚度)和化学特性[种仁的粗脂肪、可溶性蛋白质、糖、赤霉素(GA)和脱落酸(ABA)],并在中国的温室中测定种子的发芽率和萌发时间。此外,我们在美国用采自2016年和2017年的种子开展了研究地点(中国和美国)和种子采集年份(2016年和2017年)对种子萌发影响的比较实验。 来自引入地的种子要比来自原产地的种子萌发更快。种子的物理和化学特性测定结果表明：与原产地种子相比,引入地种子更大、种仁内含有的赤霉素浓度以及GA:ABA比更高,但粗脂肪含量较低。种子重量、种皮硬度、种皮厚度、种仁脱落酸、可溶性蛋白质和糖含量在引入地和原产地之间没有显著差异。在中国和美国温室间的种子萌发率具有相关性,但种群的萌发率具有年际变化。我们的研究结果表明,体积较大和赤霉素含量较高的种子可能有助于快速萌发,这可能也有利于乌桕在引入地的入侵。     

新书介绍

生物入侵:中国外来入侵植物图谱(编著者:万方浩,刘全儒,谢明等)内容提要:本书为"生物入侵:中国外来入侵物种"系列图鉴之一。共收录了142种重要的入侵植物,介绍了入侵植物的学名、英文名、中文异名、形态特征、识别要点、生境及危害、控制措施、中国分     

我国区域间生物入侵的现状及防治

区域间生物入侵是指国家内部不同区域间物种入侵所引发的危害。由于我国生态系统错综多样,国内人员、物品流动频繁且不易监控,因此区域间生物入侵危害已经十分严峻。本文主要以我国以及国外已有的区域间生物入侵事件为例,分析其主要的入侵途径、危害与防治措施。区域间生物入侵主要通过引种、运输、人为干扰等途径,可以造成土著种灭绝、基因污染、生物多样性降低等危害。全球气候变化、南水北调等大型工程建设以及海峡两岸交流等领域是今后我国区域间生物入侵研究的主要方向。     

Invasion success of non-indigenous aquatic and semi-aquatic plants in their native and introduced ranges. A comparison between their invasiveness in North America and in France

Aquatic and semi-aquatic plants comprise few species worldwide, yet the introduction of non-indigenous plants represents one of the most severe examples of biological invasions. My goal is to compare the distribution and the biology of aquatic and semi-aquatic plants in their introduced ranges and in their native ranges. The primary objective of this study is to test the hypothesis that invasive species have evolved traits likely to increase their success in the new range. I made two reciprocal comparisons, i.e. I compared European species in France and in North America, and North American species in France and in North America. Twenty-seven species were classified according to their invasiveness in their introduced area. I␣found six invasive macrophyte species in France native to North America and 17 invasive species in North America native to Europe. Four species are invasive in both areas. There is no general tendency for macrophytes to be more vigorous in their introduced ranges. Most non-indigenous aquatic and semi-aquatic species are potentially invasive or widespread and well-established in their introduced country, while few species seem to be restricted in their distribution.     

Invasive alien plants in China: role of clonality and geographical origin

Biological invasions have become a significant threat to the global environment. Unfortunately, to date there is no consensus on invasion mechanisms and predictive models. Controversies range from whether we can reliably predict which species may become invasive to which species characteristics (e.g., life history, taxonomic groups, or geographic origin) contribute to the invasion processes. We examined 126 invasive alien plant species in China to understand the role of clonality and geographical origin in their invasion success. These species were categorized into three groups (I, II, III) based on their invasiveness in terms of current spatial occupation and the degree of damage to invaded habitats. Clonal plants consisted of almost half (44%) of the 126 invasive species studied, and consisted of 66% of 32 the most invasive alien plant species (Group I). There was a significant positive relationship between clonality and species invasiveness. A 68% of the 126 species studied originated in the continent of America (North and/or South America). These preliminary findings support that America is the primary geographical origin of invasive alien plant species in China and that clonality of the invasive plant species contributed significantly to the their invasiveness. The results suggest an urgent need at the global scale to investigate the mechanisms whereby plant clonal growth influences plant invasions, and the need for a focus at regional scale to examine factors affecting the exchange of invasive plant species between America and China.     

Genetic differences in growth of an invasive tree species

Invasive plants are often more vigorous in their introduced ranges than in their native ranges. This may reflect an innate superiority of plants from some habitats or an escape from their enemies. Another hypothesis proposes that invasive plants evolve increased competitive ability in their introduced range. We present the results of a 14-year common garden experiment with the Chinese Tallow Tree ( Sapium sebiferum ) from its native range (Asia), place of introduction to North America (Georgia) and areas colonized a century later (Louisiana and Texas). Invasive genotypes, especially those from recently colonized areas, were larger than native genotypes and more likely to produce seeds but had lower quality, poorly defended leaves. Our results demonstrate significant post-invasion genetic differences in an invasive plant species. Post-introduction adaptation by introduced plants may contribute to their invasive success and make it difficult to predict problem species.     

Large Shift in Symbiont Assemblage in the Invasive Red Turpentine Beetle

Changes in symbiont assemblages can affect the success and impact of invasive species, and may provide knowledge regarding the invasion histories of their vectors. Bark beetle symbioses are ideal systems to study changes in symbiont assemblages resulting from invasions. The red turpentine beetle (Dendroctonus valens) is a bark beetle species that recently invaded China from its native range in North America. It is associated with ophiostomatalean fungi in both locations, although the fungi have previously been well-surveyed only in China. We surveyed the ophiostomatalean fungi associated with D. valens in eastern and western North America, and identified the fungal species using multi-gene phylogenies. From the 307 collected isolates (147 in eastern North America and 160 in western North America), we identified 20 species: 11 in eastern North America and 13 in western North America. Four species were shared between eastern North America and western North America, one species (Ophiostoma floccosum) was shared between western North America and China, and three species (Grosmannia koreana, Leptographium procerum, and Ophiostoma abietinum) were shared between eastern North America and China. Ophiostoma floccosum and O. abietinum have worldwide distributions, and were rarely isolated from D. valens. However, G. koreana and L. procerum are primarily limited to Asia and North America respectively. Leptographium procerum, which is thought to be native to North America, represented >45% of the symbionts of D. valens in eastern North America and China, suggesting D. valens may have been introduced to China from eastern North America. These results are surprising, as previous population genetics studies on D. valens based on the cytochrome oxidase I gene have suggested that the insect was introduced into China from western North America.     

Multi level ecological fitting: indirect life cycles are not a barrier to host switching and invasion

Many invasive species are able to escape from coevolved enemies and thus enjoy a competitive advantage over native species. However, during the invasion phase, non‐native species must overcome many ecological and/or physiological hurdles before they become established and spread in their new habitats. This may explain why most introduced species either fail to establish or remain as rare interstitials in their new ranges. Studies focusing on invasive species have been based on plants or animals where establishment requires the possession of preadapted traits from their native ranges that enables them to establish and spread in their new habitats. The possession of preadapted traits that facilitate the exploitation of novel resources or to colonize novel habitats is known as ‘ecological fitting’. Some species have evolved traits and life histories that reflect highly intimate associations with very specific types of habitats or niches. For these species, their phenological windows are narrow, and thus the ability to colonize non‐native habitats requires that a number of conditions need to be met in accordance with their more specialized life histories. Some of the strongest examples of more complex ecological fitting involve invasive parasites that require different animal hosts to complete their life cycles. For instance, the giant liver fluke, Fascioloides magna, is a major parasite of several species of ungulates in North America. The species exhibits a life cycle whereby newly hatched larvae must find suitable intermediate hosts (freshwater snails) and mature larvae, definitive hosts (ungulates). Intermediate and definitive host ranges of F. magna in its native range are low in number, yet this parasite has been successfully introduced into Europe where it has become a parasite of native European snails and deer. We discuss how the ability of these parasites to overcome multiple ecophysiological barriers represents an excellent example of ‘multiple‐level ecological fitting’.     

Bridgehead Effect in the Worldwide Invasion of the Biocontrol Harlequin Ladybird

Recent studies of the routes of worldwide introductions of alien organisms suggest that many widespread invasions could have stemmed not from the native range, but from a particularly successful invasive population, which serves as the source of colonists for remote new territories. We call here this phenomenon the invasive bridgehead effect. Evaluating the likelihood of such a scenario is heuristically challenging. We solved this problem by using approximate Bayesian computation methods to quantitatively compare complex invasion scenarios based on the analysis of population genetics (microsatellite variation) and historical (first observation dates) data. We applied this approach to the Harlequin ladybird Harmonia axyridis (HA), a coccinellid native to Asia that was repeatedly introduced as a biocontrol agent without becoming established for decades. We show that the recent burst of worldwide invasions of HA followed a bridgehead scenario, in which an invasive population in eastern North America acted as the source of the colonists that invaded the European, South American and African continents, with some admixture with a biocontrol strain in Europe. This demonstration of a mechanism of invasion via a bridgehead has important implications both for invasion theory (i.e., a single evolutionary shift in the bridgehead population versus multiple changes in case of introduced populations becoming invasive independently) and for ongoing efforts to manage invasions by alien organisms (i.e., heightened vigilance against invasive bridgeheads).     

Present and future distribution of three aquatic plants taxa across the world: decrease in native and increase in invasive ranges

Inland aquatic ecosystems are vulnerable to both climate change and biological invasion at broad spatial scales. The aim of this study was to establish the current and future potential distribution of three invasive plant taxa, Egeria densa, Myriophyllum aquaticum and Ludwigia spp., in their native and exotic ranges. We used species distribution models (SDMs), with nine different algorithms and three global circulation models, and we restricted the suitability maps to cells containing aquatic ecosystems. The current bioclimatic range of the taxa was predicted to represent 6.6–12.3% of their suitable habitats at global scale, with a lot of variations between continents. In Europe and North America, their invasive ranges are predicted to increase up to two fold by 2070 with the highest gas emission scenario. Suitable new areas will mainly be located to the north of their current range. In other continents where they are exotic and in their native range (South America), the surface areas of suitable locations are predicted to decrease with climate change, especially for Ludwigia spp. in South America (down to ?55% by 2070 with RCP 8.5 scenario). This study allows to identify areas vulnerable to ongoing invasions by aquatic plant species and thus could help the prioritisation of monitoring and management, as well as contribute to the public awareness regarding biological invasions.     

Biological invasions in soil: DNA barcoding as a monitoring tool in a multiple taxa survey targeting European earthworms and springtails in North America

Biological invasions are increasingly recognized as a potent force altering native ecosystems worldwide. Many of the best documented cases involve the massive invasions of North America by plant and animal taxa native to Europe. In this study, we use DNA barcoding to survey the occurrence and genetic structure of two major groups of soil invertebrates in both their native and introduced ranges: Collembola and earthworms. Populations of ten species of earthworms and five species of Collembola were barcoded from both continents. Most of these species exhibited a similar genetic structure of large and stable populations in North America and Europe, a result supporting a scenario of multiple invasions. This was expected for earthworm species involved in human economic activities, but not foreseen for Collembola species de facto unintentionally introduced. This study also establishes that invasive species surveys employing DNA barcoding gain additional resolution over those based on morphology as they allow evaluation of cryptic lineages exhibiting different invasion histories.     

Nursery habitat characteristics of an invasive,omnivorous fish

Understanding habitat use and reproductive biology of invasive species is essential to predicting invasions, designing early detection programs, and developing management plans. The rudd (Scardinius erythrophthalmus; Linnaeus, 1758) is an omnivorous fish native to Europe and western Asia that has been translocated to several countries in western Europe, New Zealand, North America, and Africa. However, little is known about early life history of rudd, particularly in invaded ecosystems, limiting our ability to predict invasions and create early detection and control programs. The upper Niagara River has the most abundant population of rudd in North America and has been the focus of several ecological investigations. Our study identified critical nursery habitats by determining which nearshore habitat factors were most strongly associated with presence of age-0 rudd. We found that emergent vegetation was the most important habitat characteristic associated with the presence of age-0 rudd. When emergent vegetation was not present, rudd were more likely to be present at sites with abundant submerged aquatic vegetation. Additionally, the odds of rudd presence decreased as distance to the nearest wetland increased. These findings can be used to create habitat-driven predictive models of rudd invasion and guide early detection programs for rudd outside their native range.

     

Deciphering the worldwide invasion of the Asian long‐horned beetle: A recurrent invasion process from the native area together with a bridgehead effect

Retracing introduction routes is crucial for understanding the evolutionary processes involved in an invasion, as well as for highlighting the invasion history of a species at the global scale. The Asian long‐horned beetle (ALB) Anoplophora glabripennis is a xylophagous pest native to Asia and invasive in North America and Europe. It is responsible for severe losses of urban trees, in both its native and invaded ranges. Based on historical and genetic data, several hypotheses have been formulated concerning its invasion history, including the possibility of multiple introductions from the native zone and secondary dispersal within the invaded areas, but none have been formally tested. In this study, we characterized the genetic structure of ALB in both its native and invaded ranges using microsatellites. In order to test different invasion scenarios, we used an approximate Bayesian “random forest” algorithm together with traditional population genetics approaches. The strong population differentiation observed in the native area was not geographically structured, suggesting complex migration events that were probably human‐mediated. Both native and invasive populations had low genetic diversity, but this characteristic did not prevent the success of the ALB invasions. Our results highlight the complexity of invasion pathways for insect pests. Specifically, our findings indicate that invasive species might be repeatedly introduced from their native range, and they emphasize the importance of multiple, human‐mediated introductions in successful invasions. Finally, our results demonstrate that invasive species can spread across continents following a bridgehead path, in which an invasive population may have acted as a source for another invasion.