外来传粉者对本地植物‒传粉者相互作用的影响

doi:10.17520/biods.2024443

生物多样性 ›› 2025, Vol. 33 ›› Issue (2): 24443. DOI: 10.17520/biods.2024443 cstr: 32101.14.biods.2024443

外来传粉者对本地植物‒传粉者相互作用的影响

张婵¹(), 赵苏雅¹, 张欣然¹, 王依凡¹, 王林林²^,^*()()

1.河南师范大学生命科学学院, 河南新乡 453007
2.中国科学院昆明植物研究所东亚植物多样性与生物地理学重点实验室, 昆明 650201

收稿日期:2024-10-11 接受日期:2024-12-03 出版日期:2025-02-20 发布日期:2025-03-17
通讯作者: *E-mail: wanglinlin0328@mail.kib.ac.cn
基金资助:
国家自然科学基金(32271604);国家自然科学基金(32370229);国家级大学生创新创业训练计划项目(202410476018)

Impacts of alien pollinators on native plant‒pollinator interactions

Zhang Chan¹(), Zhao Suya¹, Zhang Xinran¹, Wang Yifan¹, Wang Linlin²^,^*()()

1 College of Life Sciences, Henan Normal University, Xinxiang, Henan 453007, China
2 Key Laboratory for Plant Diversity and Biogeography of East Asia, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming 650201, China

Received:2024-10-11 Accepted:2024-12-03 Online:2025-02-20 Published:2025-03-17
Contact: *E-mail: wanglinlin0328@mail.kib.ac.cn
Supported by:
National Natural Science Foundation of China(32271604);National Natural Science Foundation of China(32370229);National Undergraduate Innovation and Entrepreneurship Training Program(202410476018)

摘要/Abstract

摘要：

随着虫媒作物对传粉服务的需求日益增加, 导致人工养殖的外来传粉者在全球范围内数量激增并大面积扩散, 对本地植物‒传粉者之间的互利关系造成极大影响, 严重威胁当地生物多样性和生态系统稳定性。该文综述了外来传粉者对本地植物、本地传粉者以及传粉网络3个方面的影响。(1)外来传粉者与本地传粉者在形态特征和访花行为上的差异, 使其对本地植物而言往往是低效或者无效的传粉者, 从而对植物的繁殖成功造成负面影响; 但是在传粉限制环境中, 外来传粉者也可能起到重要的补充授粉作用。外来传粉者特定的访花偏好和对本地传粉者访花行为的影响会改变植物的花粉流和基因流, 从而使植物种群的遗传结构发生变化。此外, 外来传粉者会对植物的资源分配策略和花部结构发育施加新的选择压力, 进而引导花部特征的适应性演变。(2)外来传粉者与本地传粉者会形成资源竞争或捕食关系, 还可能干扰本地传粉者的生殖过程或造成病原体传播, 从而对本地传粉者的物种多样性和丰富度构成极大威胁。(3)由于大多数外来传粉者都是泛化传粉者, 促使它们能够很快整合到新生境的传粉网络中, 与本地植物形成大量新的连接, 往往使整个传粉网络的泛化水平和嵌套化程度升高, 最终对传粉网络的稳定性产生深远影响。目前, 我国针对外来传粉者的研究主要侧重于农业授粉应用, 今后, 应该更加重视外来传粉者进入自然生态系统后对本地开花植物、传粉者以及两者之间互作网络的结构和功能的影响机制研究, 需要全面考虑物种、群落和生态系统3个不同的层次, 同时扩展研究的地理尺度和时间尺度, 在研究中注意结合新技术和新方法, 并考虑全球变暖和农业集约化等趋势的影响。在外来传粉者在我国的分布区持续扩大的现状下, 为保护本地植物和传粉者物种多样性, 维持自然生态系统的原真性和稳定性, 需要: (1)做好外来传粉者的引种规划和防控管理工作; (2)建立本地传粉者自然保护区, 确定优先保护物种和优先保护区域; (3)大力开发和保护本地传粉者为农作物提供授粉服务, 避免引入外来传粉者而导致生态危害。

关键词: 外来传粉者, 本地植物, 本地传粉者, 传粉网络

Abstract

Background & Aim: In recent years, the global rise in demand for pollination services of insect-pollinated crops has led to a surge in the use of managed alien pollinators. This extensive proliferation significantly impacts mutualistic relationship between native plants and pollinators, posing serious threats to local biodiversity and ecosystem stability.

Progresses: This article reviews the impacts of alien pollinators on native plants, native pollinators and pollination networks. (1) Morphological and behavioral differences between alien and native pollinators often render the former inefficient or ineffective pollinators for native plants, negatively affecting plant reproductive success. However, in pollination-limited environments, alien pollinators may supplement pollination effectively. The specific flower-visiting preferences of alien pollinators and their impact on the flower-visiting behavior of native pollinators alter pollen flow, gene flow, and consequently, the genetic structure of plant populations. In addition, alien pollinators also exert new selective pressures on floral traits, driving adaptive evolution in plant populations. (2) Alien pollinators may outcompete or prey on native pollinators, disrupt their reproductive process, or spread of pathogens, thereby threatening the diversity and abundance of native pollinators species. (3) As generalist species, alien pollinators integrate rapidly into the pollination networks, forming numerous new connections with native plants. This often increases the generalization and nestedness of the entire pollination network, profoundly affecting its stability.

Prospects: In China, research on alien pollinators has mainly focused on their agricultural pollinations. In the future, we should: (1) Investigate the mechanisms trough which alien pollinators impact native flowering plants, pollinators, and the structure and function of pollination network. (2) Expand research level across species, communities and ecosystems. (3) Broaden the geographical and temporal scales of research, incorporating advanced technologies and methodologies, while accounting for global warming and agricultural intensification.

Suggestions: Given the continuous expansion of alien pollinator distribution in China, measures are urgently needed to protect native plant and pollinator diversity, and to maintain ecosystem authenticity and stability. (1) Strategic planning is necessary for the introduction and management of alien pollinators. (2) Establish native pollinator nature reserves, with priority species and conservation area. (3) Additionally, the promotion and conservation of native pollinators are essential to provide sustainable pollination services for crops, and to avoid ecological damage caused by the introduction of alien pollinators.

Key words: alien pollinators, native plants, native pollinators, pollination network

张婵, 赵苏雅, 张欣然, 王依凡, 王林林 (2025) 外来传粉者对本地植物‒传粉者相互作用的影响. 生物多样性, 33, 24443. DOI: 10.17520/biods.2024443.

Zhang Chan, Zhao Suya, Zhang Xinran, Wang Yifan, Wang Linlin (2025) Impacts of alien pollinators on native plant‒pollinator interactions. Biodiversity Science, 33, 24443. DOI: 10.17520/biods.2024443.

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2024443

https://www.biodiversity-science.net/CN/Y2025/V33/I2/24443

参考文献 123

[1]	Aizen MA, Harder LD (2009) The global stock of domesticated honey bees is growing slower than agricultural demand for pollination. Current Biology, 19, 915-918. DOI PMID
[2]	Aizen MA, Smith-Ramírez C, Morales CL, Vieli L, Sáez A, Barahona-Segovia RM, Arbetman MP, Montalva J, Garibaldi LA, Inouye DW, Harder LD (2019) Coordinated species importation policies are needed to reduce serious invasions globally: The case of alien bumblebees in South America. Journal of Applied Ecology, 56, 100-106.
[3]	An JD, Wu J, Peng WJ, Tong YM, Guo ZB, Li JL (2007) Foraging behavior and pollination ecology of Bombus lucorum L. and Apis mellifera L. in greenhouse peach garden. Chinese Journal of Applied Ecology, 18, 1071-1078. (in Chinese with English abstract)
	[ 安建东, 吴杰, 彭文君, 童越敏, 国占宝, 李继莲 (2007) 明亮熊蜂和意大利蜜蜂在温室桃园的访花行为和传粉生态学比较. 应用生态学报, 18, 1071-1078.]
[4]	Biesmeijer JC, Roberts SPM, Reemer M, Ohlemüller R, Edwards M, Peeters T, Schaffers AP, Potts SG, Kleukers R, Thomas CD, Settele J, Kunin WE (2006) Parallel declines in pollinators and insect-pollinated plants in Britain and the Netherlands. Science, 313, 351-354. DOI PMID
[5]	Bishop GA, Fijen TPM, Raemakers I, van Kats RJM, Kleijn D (2024) Bees go up, flowers go down: Increased resource limitation from late spring to summer in agricultural landscapes. Journal of Applied Ecology, 61, 431-441.
[6]	Blaauw BR, Isaacs R (2014) Larger patches of diverse floral resources increase insect pollinator density, diversity, and their pollination of native wildflowers. Basic and Applied Ecology, 15, 701-711.
[7]	Boecking O, Genersch E (2008) Varroosis-the ongoing crisis in bee keeping. Journal of Consumer Protection and Food Safety, 3, 221-228.
[8]	Boggs CL (2016) The fingerprints of global climate change on insect populations. Current Opinion in Insect Science, 17, 69-73. DOI PMID
[9]	Burkle LA, Alarcón R (2011) The future of plant-pollinator diversity: Understanding interaction networks across time, space, and global change. American Journal of Botany, 98, 528-538. DOI PMID
[10]	Cane JH, Tepedino VJ (2017) Gauging the effect of honey bee pollen collection on native bee communities. Conservation Letters, 10, 205-210.
[11]	Cappa F, Cini A, Bortolotti L, Poidatz J, Cervo R (2021) Hornets and honey bees: A coevolutionary arms race between ancient adaptations and new invasive threats. Insects, 12, 1037.
[12]	Celebrezze T, Paton DC (2004) Do introduced honeybees (Apis mellifera, Hymenoptera) provide full pollination service to bird-adapted Australian plants with small flowers? An experimental study of Brachyloma ericoides (Epacridaceae). Austral Ecology, 29, 129-136.
[13]	Chalcoff VR, Sasal Y, Graham LE, Vázquez DP, Morales CL (2022) Invasive bumble bee disrupts a pollination mutualism over space and time. Biological Invasions, 24, 1439-1452.
[14]	Chen WF, An JD, Dong J, Ding KF, Gao S (2011) Flower-visiting behavior and pollination ecology of different bee species on greenhouse strawberry. Chinese Journal of Ecology, 30, 290-296. (in Chinese with English abstract)
	[ 陈文锋, 安建东, 董捷, 丁克法, 高山 (2011) 不同蜂在温室草莓园的访花行为和传粉生态学比较. 生态学杂志, 30, 290-296.]
[15]	Cook LM, Saccheri IJ (2013) The peppered moth and industrial melanism: Evolution of a natural selection case study. Heredity, 110, 207-212. DOI PMID
[16]	Corcos D, Cappellari A, Mei M, Paniccia D, Cerretti P, Marini L (2020) Contrasting effects of exotic plant invasions and managed honeybees on plant-flower visitor interactions. Diversity and Distributions, 26, 1397-1408.
[17]	Dáttilo W, Cruz CP, Luna P, Ratoni B, Hinojosa-Díaz IS, Neves FS, Leponce M, Villalobos F, Guevara R (2022) The impact of the honeybee Apis mellifera on the organization of pollination networks is positively related with its interactive role throughout its geographic range. Diversity, 14, 917.
[18]	de M Santos GM, Aguiar CML, Genini J, Martins CF, Zanella FCV, Mello MAR (2012) Invasive Africanized honeybees change the structure of native pollination networks in Brazil. Biological Invasions, 14, 2369-2378.
[19]	Dick CW (2001) Genetic rescue of remnant tropical trees by an alien pollinator. Proceedings of the Royal Society B: Biological Sciences, 268, 2391-2396.
[20]	Dick CW, Etchelecu G, Austerlitz F (2003) Pollen dispersal of tropical trees (Dinizia excelsa: Fabaceae) by native insects and African honeybees in pristine and fragmented Amazonian rainforest. Molecular Ecology, 12, 753-764. PMID
[21]	do Carmo RM, Franceschinelli EV, da Silveira FA (2004) Introduced honeybees (Apis mellifera) reduce pollination success without affecting the floral resource taken by native pollinators. Biotropica, 36, 371-376.
[22]	do Nascimento AC, Montalva J, Lucia M, de Paiva Silva D (2023) Suitable areas for the invasion expansion of Xylocopa bees in South America. Journal of Applied Entomology, 147, 23-35.
[23]	Dobelmann J, Felden A, Lester PJ (2023) An invasive ant increases deformed wing virus loads in honey bees. Biology Letters, 19, 20220416.
[24]	Dohzono I, Kunitake YK, Yokoyama J, Goka K (2008) Alien bumble bee affects native plant reproduction through interactions with native bumble bees. Ecology, 89, 3082-3092. DOI PMID
[25]	Duan YW, Liu JQ (2007) Pollinator shift and reproductive performance of the Qinghai-Tibetan Plateau endemic and endangered Swertia przewalskii(Gentianaceae). Biodiversity and Conservation, 16, 1839-1850.
[26]	Dupont YL, Hansen DM, Valido A, Olesen JM (2004) Impact of introduced honey bees on native pollination interactions of the endemic Echium wildpretii (Boraginaceae) on Tenerife, Canary Islands. Biological Conservation, 118, 301-311.
[27]	Elbgami T, Kunin WE, Hughes WOH, Biesmeijer JC (2014) The effect of proximity to a honeybee apiary on bumblebee colony fitness, development, and performance. Apidologie, 45, 504-513.
[28]	Eynard C, Galetto L (2002) Pollination ecology of Geoffroea decorticans (Fabaceae) in central Argentine dry forest. Journal of Arid Environments, 51, 79-88.
[29]	Faria RR, Araujo AC (2015) Fruit set of distylous Psychotria carthagenensis Jacq. (Rubiaceae) mediated by Apis mellifera (Apidae) and species of Augochloropsis(Halictidae). Acta Botanica Brasilica, 29, 278-281.
[30]	Forup ML, Memmott J (2005) The relationship between the abundances of bumblebees and honeybees in a native habitat. Ecological Entomology, 30, 47-57.
[31]	Geldmann J, González-Varo JP (2018) Conserving honey bees does not help wildlife. Science, 359, 392-393. DOI PMID
[32]	Geslin B, Gauzens B, Baude M, Dajoz I, Fontaine C, Henry M, Ropars L, Rollin O, Thébault E, Vereecken NJ (2017) Massively introduced managed species and their consequences for plant-pollinator interactions. Advances in Ecological Research, 57, 147-199.
[33]	Giannini TC, Garibaldi LA, Acosta AL, Silva JS, Maia KP, Saraiva AM, Guimarães PR Jr, Kleinert AMP (2015) Native and non-native supergeneralist bee species have different effects on plant-bee networks. PLoS ONE, 10, e0137198.
[34]	Gilpin AM, Collette JC, Denham AJ, Ooi MKJ, Ayre DJ (2017) Do introduced honeybees affect seed set and seed quality in a plant adapted for bird pollination? Journal of Plant Ecology, 10, 721-729.
[35]	Goka K, Okabe K, Yoneda M, Niwa S (2001) Bumblebee commercialization will cause worldwide migration of parasitic mites. Molecular Ecology, 10, 2095-2099. DOI PMID
[36]	González-Varo JP, Albaladejo RG, Aparicio A, Arroyo J (2010) Linking genetic diversity, mating patterns and progeny performance in fragmented populations of a Mediterranean shrub. Journal of Applied Ecology, 47, 1242-1252.
[37]	González-Varo JP, Biesmeijer JC, Bommarco R, Potts SG, Schweiger O, Smith HG, Steffan-Dewenter I, Szentgyörgyi H, Woyciechowski M, Vilà M (2013) Combined effects of global change pressures on animal-mediated pollination. Trends in Ecology & Evolution, 28, 524-530.
[38]	González-Varo JP, Vilà M (2017) Spillover of managed honeybees from mass-flowering crops into natural habitats. Biological Conservation, 212, 376-382.
[39]	Goulson D (2003) Effects of introduced bees on native ecosystems. Annual Review of Ecology, Evolution, and Systematics, 34, 1-26.
[40]	Goulson D, Nicholls E, Botías C, Rotheray EL (2015) Bee declines driven by combined stress from parasites, pesticides, and lack of flowers. Science, 347, 1255957.
[41]	Goulson D, Sparrow KR (2009) Evidence for competition between honeybees and bumblebees; effects on bumblebee worker size. Journal of Insect Conservation, 13, 177-181.
[42]	Graham KK, Eaton K, Obrien I, Starks PT (2019) Anthidium manicatum, an invasive bee, excludes a native bumble bee, Bombus impatiens, from floral resources. Biological Invasions, 21, 1089-1099.
[43]	Graystock P, Blane EJ, McFrederick QS, Goulson D, Hughes WOH (2016) Do managed bees drive parasite spread and emergence in wild bees? International Journal for Parasitology: Parasites and Wildlife, 5, 64-75. DOI PMID
[44]	Gross CL, MacKay D (1998) Honeybees reduce fitness in the pioneer shrub Melastoma affine(Melastomataceae). Biological Conservation, 86, 169-178.
[45]	Guo Y, Fu BC, Qin GJ, Song HL, Wu WQ, Shao YQ, Altaye SZ, Yu LS (2019) Proteome analysis reveals a strong correlation between olfaction and pollen foraging preference in honeybees. International Journal of Biological Macromolecules, 121, 1264-1275. DOI PMID
[46]	Guo Y, Song ZQ, Zhang XF, Song HL, Wu WQ, Shao YQ (2017) Comparison of pollinating effects for the alfalfa between Apis mellifera L. and Bombus terrestris L. Chinese Journal of Applied Entomology, 54, 1008-1014. (in Chinese with English abstract)
	[ 郭媛, 宋卓琴, 张旭凤, 宋怀磊, 武文卿, 邵有全 (2017) 西方蜜蜂和地熊蜂为紫花苜蓿授粉效果比较. 应用昆虫学报, 54, 1008-1014.]
[47]	Hargreaves AL, Harder LD, Johnson SD (2009) Consumptive emasculation: The ecological and evolutionary consequences of pollen theft. Biological Reviews, 84, 259-276.
[48]	Harrison T, Winfree R (2015) Urban drivers of plant-pollinator interactions. Functional Ecology, 29, 879-888.
[49]	Huang JX, An JD (2018) Species diversity, pollination application and strategy for conservation of the bumblebees of China. Biodiversity Science, 26, 486-497. (in Chinese with English abstract) DOI
	[ 黄家兴, 安建东 (2018) 中国熊蜂多样性、人工利用与保护策略. 生物多样性, 26, 486-497.] DOI
[50]	Huang SQ, Guo YH (2000) Research progress of pollination biology. Chinese Science Bulletin, 45, 225-237. (in Chinese)
	[ 黄双全, 郭友好 (2000) 传粉生物学的研究进展. 科学通报, 45, 225-237.]
[51]	Hung KLJ, Kingston JM, Lee A, Holway DA, Kohn JR (2019) Non-native honey bees disproportionately dominate the most abundant floral resources in a biodiversity hotspot. Proceedings of the Royal Society B: Biological Sciences, 286, 20182901.
[52]	Inoue MN, Suzuki-Ohno Y (2023) Long-term monitoring of changes in the native bumblebee community after alien species (Bombus terrestris) invasion and estimation of factors affecting its abundance. Apidologie, 54, 28.
[53]	Inoue MN, Yokoyama J, Washitani I (2008) Displacement of Japanese native bumblebees by the recently introduced Bombus terrestris (L.) (Hymenoptera: Apidae). Journal of Insect Conservation, 12, 135-146.
[54]	Ish-Am G, Eisikowitch D (1993) The behaviour of honey bees (Apis mellifera) visiting avocado (Persea americana) flowers and their contribution to its pollination. Journal of Apicultural Research, 32, 175-186.
[55]	Iwasaki JM, Hogendoorn K (2022) Mounting evidence that managed and introduced bees have negative impacts on wild bees: An updated review. Current Research in Insect Science, 2, 100043.
[56]	Ji R, Xie BY, Yang GH, Li DM (2003) From introduced species to invasive species—A case study on the Italian bee Apis mellifera L. Chinese Journal of Ecology, 22, 70-73. (in Chinese with English abstract)
	[ 季荣, 谢宝瑜, 杨冠煌, 李典谟 (2003) 从有意引入到外来入侵——以意大利蜂Apis mellifera L.为例. 生态学杂志, 22, 70-73.]
[57]	Kanbe Y, Okada I, Yoneda M, Goka K, Tsuchida K (2008) Interspecific mating of the introduced bumblebee Bombus terrestris and the native Japanese bumblebee Bombus hypocrita sapporoensis results in inviable hybrids. Naturwissenschaften, 95, 1003-1008.
[58]	Kato M, Kawakita A (2004) Plant-pollinator interactions in New Caledonia influenced by introduced honey bees. American Journal of Botany, 91, 1814-1827. DOI PMID
[59]	Kenta T, Inari N, Nagamitsu T, Goka K, Hiura T (2007) Commercialized European bumblebee can cause pollination disturbance: An experiment on seven native plant species in Japan. Biological Conservation, 134, 298-309.
[60]	Kondo NI, Yamanaka D, Kanbe Y, Kunitake YK, Yoneda M, Tsuchida K, Goka K (2009) Reproductive disturbance of Japanese bumblebees by the introduced European bumblebee Bombus terrestris. Naturwissenschaften, 96, 467-475.
[61]	Kraus FB, Szentgyörgyi H, Rożej E Rhode M, Moroń D, Woyciechowski M, Moritz RFA (2011) Greenhouse bumblebees (Bombus terrestris) spread their genes into the wild. Conservation Genetics, 12, 187-192.
[62]	Li HY, Luo AC, Hao YJ, Dou FY, Kou RM, Orr MC, Zhu CD, Huang DY (2021) Comparison of the pollination efficiency of Apis cerana with wild bees in oil-seed camellia fields. Basic and Applied Ecology, 56, 250-258.
[63]	Liu YJ, Zhao TR, Zhao FY (2013) Melissopalynology and trophic niche of Apis cerana ceraca and Apis mellifera ligustica in Yunnan Province of Southwest China. Chinese Journal of Applied Ecology, 24, 205-210. (in Chinese with English abstract) PMID
	[ 刘宇佳, 赵天瑞, 赵风云 (2013) 云南中华蜜蜂与意大利蜜蜂的蜂蜜孢粉学和营养生态位. 应用生态学报, 24, 205-210.]
[64]	Kettlewell B (1973) The Evolution of Melanism:The Study of a Recurring Necessity. Clarendon Press, Oxford.
[65]	Magrach A, González-Varo JP, Boiffier M, Vilà M, Bartomeus I (2017) Honeybee spillover reshuffles pollinator diets and affects plant reproductive success. Nature Ecology & Evolution, 1, 1299-1307.
[66]	Maimaitituerxun R, Abdusalam A (2023) Exploring the influence of petal and stamen color on pollinator and reproductive success in Punica granatum. Biodiversity Science, 31, 22633. (in Chinese with English abstract) DOI
	[ 热依拉穆·麦麦提吐尔逊, 艾沙江·阿不都沙拉木 (2023) 石榴花瓣和雄蕊对其传粉过程与繁殖成功的影响. 生物多样性, 31, 22633.] DOI
[67]	Mallinger RE, Gaines-Day HR, Gratton C (2017) Do managed bees have negative effects on wild bees?: A systematic review of the literature. PLoS ONE, 12, e0189268.
[68]	Meng BD, Ren XX, Gong XY, Chen XL, Hu XL, Qing Z, Li LS, Zhou DY, Dong K (2019) Effect of Apis mellifera L. on the foraging behavior of Apis cerana F. Chinese Journal of Applied Entomology, 56, 1070-1078. (in Chinese with English abstract)
	[ 孟柏达, 任晓晓, 龚雪阳, 陈新兰, 胡晓玲, 卿卓, 李林庶, 周丹银, 董坤 (2019) 西方蜜蜂对东方蜜蜂采集行为及食物资源利用的影响. 应用昆虫学报, 56, 1070-1078.]
[69]	Mouillard-Lample L, Gonella G, Decourtye A, Henry M, Barnaud C (2023) Competition between wild and honey bees: Floral resources as a common good providing multiple ecosystem services. Ecosystem Services, 62, 101538.
[70]	Mu JP, Peng YH, Xi XQ, Wu XW, Griffin JN, Niklas KJ, Sun SC (2014) Domesticated honey bees evolutionarily reduce flower nectar volume in a Tibetan lotus. Ecology, 95, 3161-3172.
[71]	Mu JP, Wu QG, Yang YL, Huang M, Grozinger CM (2018) Plant reproductive strategies vary under low and high pollinator densities. Oikos, 127, 1081-1094.
[72]	Naeem M, Yuan XL, Huang JX, An JD (2018) Habitat suitability for the invasion of Bombus terrestris in East Asian countries: A case study of spatial overlap with local Chinese bumblebees. Scientific Reports, 8, 11035.
[73]	Ni S, McCulloch GA, Kroos GC, King TM, Dutoit L, Foster BJ, Hema K, Jandt JM, Peng M, Dearden PK, Waters JM (2024) Human-driven evolution of color in a stonefly mimic. Science, 386, 453-458. DOI PMID
[74]	Norfolk O, Gilbert F, Eichhorn MP (2018) Alien honeybees increase pollination risks for range‐restricted plants. Diversity and Distributions, 24, 705-713.
[75]	Page ML, Williams NM (2023) Honey bee introductions displace native bees and decrease pollination of a native wildflower. Ecology, 104, e3939.
[76]	Pascual Tudanca MP, Debandi H, Vázquez DP (2024) Managed honeybee hives negatively affect the reproduction of native plants in a dryland nature reserve. Journal of Applied Ecology, 61, 1301-1311.
[77]	Portman ZM, Tepedino VJ, Tripodi AD, Szalanski AL, Durham SL (2018) Local extinction of a rare plant pollinator in Southern Utah (USA) associated with invasion by Africanized honey bees. Biological Invasions, 20, 593-606.
[78]	Potts SG, Biesmeijer JC, Kremen C, Neumann P, Schweiger O, Kunin WE (2010) Global pollinator declines: Trends, impacts and drivers. Trends in Ecology & Evolution, 25, 345-353.
[79]	Potts SG, Vulliamy B, Dafni A, Ne’eman G, Willmer P (2003) Linking bees and flowers: How do floral communities structure pollinator communities? Ecology, 84, 2628-2642.
[80]	Praz CJ, Müller A, Dorn S (2008) Host recognition in a pollen-specialist bee: Evidence for a genetic basis. Apidologie, 39, 547-557.
[81]	Prendergast KS, Ollerton J (2022) Impacts of the introduced European honeybee on Australian bee-flower network properties in urban bushland remnants and residential gardens. Austral Ecology, 47, 35-53. DOI
[82]	Ramsey MW (1988) Differences in pollinator effectiveness of birds and insects visiting Banksia menziesii(Proteaceae). Oecologia, 76, 119-124. DOI PMID
[83]	Requier F, Rome Q, Chiron G, Decante D, Marion S, Menard M, Muller F, Villemant C, Henry M (2019) Predation of the invasive Asian hornet affects foraging activity and survival probability of honey bees in Western Europe. Journal of Pest Science, 92, 567-578.
[84]	Rymer PD, Whelan RJ, Ayre DJ, Weston PH, Russell KG (2005) Reproductive success and pollinator effectiveness differ in common and rare Persoonia species(Proteaceae). Biological Conservation, 123, 521-532.
[85]	Sáez A, Morales CL, Ramos LY, Aizen MA (2014) Extremely frequent bee visits increase pollen deposition but reduce drupelet set in raspberry. Journal of Applied Ecology, 51, 1603-1612.
[86]	Sanguinetti A, Singer RB (2014) Invasive bees promote high reproductive success in Andean orchids. Biological Conservation, 175, 10-20.
[87]	Scaccabarozzi D, Guzzetti L, Pioltelli E, Brundrett M, Aromatisi A, Polverino G, Vallejo-Marin M, Cozzolino S, Ren ZX (2024) Evidence of introduced honeybees (Apis mellifera) as pollen wasters in orchid pollination. Scientific Reports, 14, 14076. DOI PMID
[88]	Shi XY, Huang DY, Xu HL, Ren ZX, Lu YH, An JD, Zou Y, Liu YH, Ouyang F, Chester D, Mu JP, He CL, Luo AR, Cheng R, Zhou QS, Niu ZQ, Zhou X, Zhao L, Martini M, Ma CS, Cheng WD, Chen X, Orr M, Peng WJ, Zhu CD (2024) Pollinator diversity, pollination services, and conservation in agroecosystems: A mini‐review on the successes and challenges in China. Integrative Conservation, 3, 104-111.
[89]	Smith-Ramírez C, Ramos-Jiliberto R, Valdovinos FS, Martínez P, Castillo JA, Armesto JJ (2014) Decadal trends in the pollinator assemblage of Eucryphia cordifolia in Chilean rainforests. Oecologia, 176, 157-169. DOI PMID
[90]	Stout JC, Goulson D (2001) The use of conspecific and interspecific scent marks by foraging bumblebees and honeybees. Animal Behaviour, 62, 183-189.
[91]	Stout JC, Morales CL (2009) Ecological impacts of invasive alien species on bees. Apidologie, 40, 388-409.
[92]	Su RJ, Dai WF, Yang YL, Wang XL, Gao R, He MY, Zhao C, Mu JP (2022) Introduced honey bees increase host plant abundance but decrease native bumble bee species richness and abundance. Ecosphere, 13, e4085.
[93]	Sun Q, Zhao XN, Wu L, Zhao JM, Yang YF, Zhang YW (2021) Differences in pollination efficiency among three bee species in a greenhouse and their effects on yield and fruit quality of northern highbush ‘bluecrop’ blueberry. HortScience, 56, 603-607. DOI
[94]	Sun SG, Huang SQ, Guo YH (2013) Pollinator shift to managed honeybees enhances reproductive output in a bumblebee-pollinated plant. Plant Systematics and Evolution, 299, 139-150.
[95]	Tan K, Wang ZW, Yang MX, Fuchs S, Luo LJ, Zhang ZY, Li H, Zhuang D, Yang S, Tautz J, Beekman M, Oldroyd BP (2012) Asian hive bees, Apis cerana, modulate dance communication in response to nectar toxicity and demand. Animal Behaviour, 84, 1589-1594.
[96]	Thompson CE, Biesmeijer JC, Allnutt TR, Pietravalle S, Budge GE (2014) Parasite pressures on feral honey bees (Apis mellifera sp.). PLoS ONE, 9, e105164.
[97]	Thomson D (2004) Competitive interactions between the invasive European honey bee and native bumble bees. Ecology, 85, 458-470.
[98]	Thomson DM (2006) Detecting the effects of introduced species: A case study of competition between Apis and Bombus. Oikos, 114, 407-418.
[99]	Tian LX, Wang S, Fang XH, Xu XL (2022) Applications and challenges of bee pollination in facility agriculture. Journal of Environmental Entomology, 44, 1143-1153. (in Chinese with English abstract)
	[ 田丽霞, 王甦, 方锡红, 徐希莲 (2022) 传粉蜂在设施农业中的应用及挑战. 环境昆虫学报, 44, 1143-1153.]
[100]	Timberlake TP, Vaughan IP, Memmott J (2019) Phenology of farmland floral resources reveals seasonal gaps in nectar availability for bumblebees. Journal of Applied Ecology, 56, 1585-1596. DOI
[101]	Torné-Noguera A, Rodrigo A, Osorio S, Bosch J (2016) Collateral effects of beekeeping: Impacts on pollen-nectar resources and wild bee communities. Basic and Applied Ecology, 17, 199-209.
[102]	Traveset A, Richardson DM (2006) Biological invasions as disruptors of plant reproductive mutualisms. Trends in Ecology & Evolution, 21, 208-216.
[103]	Tylianakis JM, Laliberté E, Nielsen A, Bascompte J (2010) Conservation of species interaction networks. Biological Conservation, 143, 2270-2279.
[104]	Valido A, Rodríguez-Rodríguez MC, Jordano P (2019) Honeybees disrupt the structure and functionality of plant-pollinator networks. Scientific Reports, 9, 4711. DOI PMID
[105]	Vanbergen AJ, Espíndola A, Aizen MA (2018) Risks to pollinators and pollination from invasive alien species. Nature Ecology & Evolution, 2, 16-25.
[106]	Walther-Hellwig K, Fokul G, Frankl R, Büchler R, Ekschmitt K, Wolters V (2006) Increased density of honeybee colonies affects foraging bumblebees. Apidologie, 37, 517-532.
[107]	Wang LL (2020) Plant-pollinator Interaction Networks in the Changing Alpine Meadows on the Northeastern Qinghai- Tibet Plateau. PhD dissertation, Kunming Institute of Botany, Chinese Academy of Sciences, Kunming. (in Chinese with English abstract)
	[ 王林林 (2020) 青藏高原东北部人为干扰下的高寒草甸传粉网络研究. 博士学位论文, 中国科学院昆明植物研究所, 昆明.]
[108]	Wang LL, Huang ZY, Dai WF, Yang YP, Duan YW (2024) Mixed effects of honey bees on pollination function in the Tibetan alpine grasslands. Nature Communications, 15, 8164.
[109]	Watts S, Ovalle DH, Herrera MM, Ollerton J (2012) Pollinator effectiveness of native and non-native flower visitors to an apparently generalist Andean shrub, Duranta mandonii (Verbenaceae). Plant Species Biology, 27, 147-158.
[110]	Weaver JR, Ascher JS, Mallinger RE (2022) Effects of short-term managed honey bee deployment in a native ecosystem on wild bee foraging and plant-pollinator networks. Insect Conservation and Diversity, 15, 634-644.
[111]	Whelan RJ, Ayre DJ, Beynon FM (2009) The birds and the bees: Pollinator behaviour and variation in the mating system of the rare shrub Grevillea macleayana. Annals of Botany, 103, 1395-1401.
[112]	Xiao YA, Li XH, Cao YS, Dong M (2016) The diverse effects of habitat fragmentation on plant-pollinator interactions. Plant Ecology, 217, 857-868.
[113]	Yang GH (2005) Harm of introducing the western honeybee Apis mellifera L. to the Chinese honeybee Apis cerana F. and its ecological impact. Acta Entomologica Sinica, 48, 401-406. (in Chinese with English abstract)
	[ 杨冠煌 (2005) 引入西方蜜蜂对中蜂的危害及生态影响. 昆虫学报, 48, 401-406.]
[114]	Yang L, Hao Y, Zeng ZJ, Peng WJ (2024) 2023 Report on the development of apiculture industry and technology. Chinese Journal of Animal Science, 60, 342-346. (in Chinese)
	[ 杨磊, 郝悦, 曾志将, 彭文君 (2024) 2023年蜂产业与技术发展报告. 中国畜牧杂志, 60, 342-346.]
[115]	Young HJ, Dunning DW, von Hasseln KW (2007) Foraging behavior affects pollen removal and deposition in Impatiens capensis(Balsaminaceae). American Journal of Botany, 94, 1267-1271.
[116]	Yu LS, Zou YD, Cao YF, Bi SD, Wu HZ, Ding J, Xie WF (2008) Comparative study on the niches of Apis mellifera ligustica and Apis cerana cerana. Acta Ecologica Sinica, 28, 4575-4581. (in Chinese with English abstract)
	[ 余林生, 邹运鼎, 曹义锋, 毕守东, 巫厚长, 丁建, 解文飞 (2008) 意大利蜜蜂(Apis mellifera ligustica)与中华蜜蜂(Apis cerana ceraca)的生态位比较. 生态学报, 28, 4575-4581.]
[117]	Yuan B, Fan XM, Hu FL, Luo YB (2024) New perspective on pollen toxicity in Camellia oleifera. Journal of Integrative Plant Biology, 66, 2310-2312.
[118]	Yuan XL, Naeem M, Zhang H, Liang C, Huang JX, An JD (2018) Evaluation of reproductive disturbance to Chinese bumblebees by the European bumblebee, Bombus terrestris (Hymenoptera: Apidae). Acta Entomologica Sinica, 61, 348-359. (in Chinese with English abstract)
	[ 袁晓龙, Muhammad Naeem, 张红, 梁铖, 黄家兴, 安建东 (2018) 欧洲地熊蜂对我国本土熊蜂的生殖干扰评估. 昆虫学报, 61, 348-359.] DOI
[119]	Zhang H, Liu WP, Wei W, Zhao KX, Lu HH, Li HY, Zhou ZY, Niu ZQ, Zhu CD, Huang DY (2022) Pollinator communities diversity in the main Camellia oleifera producing areas of China. Chinese Journal of Applied Entomology, 59, 1223-1239. (in Chinese with English abstract)
	[ 张欢, 刘文平, 魏玮, 赵凯旋, 陆欢欢, 李红英, 周泽扬, 牛泽清, 朱朝东, 黄敦元 (2022) 中国油茶主产区传粉昆虫群落多样性分析. 应用昆虫学报, 59, 1223-1239.]
[120]	Zhang WF, Luo YB (2024) Non-associative learning underlies pollination interaction of pollinators and flowering plants. National Science Open, 3, 20230031.
[121]	Zhang X, Zhou DY, Zhao WZ, Liu YQ, Wang JM, He SY (2013) Habitat proximity or overlap of the Asian bee (Apis cerana) and European (Apis mellifera) emerge new pathogens. Apiculture of China, 64(Z2), 20-23. (in Chinese with English abstract)
	[ 张炫, 周丹银, 赵文正, 刘意秋, 汪建民, 和绍禹 (2013) 东西方蜜蜂生境重叠导致的新病原扩散. 中国蜂业, 64(Z2), 20-23.]
[122]	Zhao DX, Su XL, Hua QY, Tou LJ, Chen DX (2019) The comparative studies of pollination behaviors between Apis cerana and Apis mellifera in blueberry. Journal of Environmental Entomology, 41, 187-192. (in Chinese with English abstract)
	[ 赵东绪, 苏晓玲, 华启云, 钭凌娟, 陈东晓 (2019) 意大利蜜蜂和中华蜜蜂为蓝莓授粉的行为比较研究. 环境昆虫学报, 41, 187-192.]
[123]	Zhou ZY, Zhang H, Liang C, Zou Y, Dong J, Yuan XL, Huang JX, An JD (2015) Foraging preference of the honeybee Apis mellifera and the bumblebee Bombus lantschouensis (Hymenoptera: Apidae) in peach greenhouse. Acta Entomologica Sinica, 58, 1315-1321. (in Chinese with English abstract)
	[ 周志勇, 张红, 梁铖, 邹宇, 董捷, 袁晓龙, 黄家兴, 安建东 (2015) 西方蜜蜂和兰州熊蜂在设施桃园的访花偏好性比较. 昆虫学报, 58, 1315-1321.]

外来传粉者对本地植物‒传粉者相互作用的影响

Impacts of alien pollinators on native plant‒pollinator interactions

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献 123

相关文章 6

编辑推荐

Metrics

本文评价

[1]	赵秋杰, 郭辉军, 孟广涛, 钟明川, 尹俊, 刘倬橙, 李品荣, 陈力, 陶毅, 秋生, 王红, 赵延会. 放牧对蜜蜂的影响及其生态修复建议[J]. 生物多样性, 2023, 31(5): 23037-.
[2]	王亚, 王玮倩, 王钦克, 李晓霞, 刘延, 黄乔乔. 土壤养分对菊科一年生入侵种和本地种繁殖性状的影响[J]. 生物多样性, 2021, 29(1): 1-9.
[3]	土艳丽,王力平,王喜龙,王林林,段元文. 利用昆虫携带的花粉初探西藏入侵植物印加孔雀草在当地传粉网络中的地位[J]. 生物多样性, 2019, 27(3): 306-313.
[4]	闫静, 张晓亚, 陈雪, 王月, 张风娟, 万方浩. 三叶鬼针草与不同本地植物竞争对土壤微生物和土壤养分的影响[J]. 生物多样性, 2016, 24(12): 1381-1389.
[5]	方强, 黄双全. 传粉网络的研究进展: 网络的结构和动态[J]. 生物多样性, 2012, 20(3): 300-307.
[6]	党伟光, 高贤明, 王瑾芳, 李爱芳. 紫茎泽兰入侵地区土壤种子库特征[J]. 生物多样性, 2008, 16(2): 126-132.