入侵性害虫桦潜叶蜂生活史及土壤生态适应性

doi:10.11707/j.1001-7488.LYKX20220077

摘要/Abstract

摘要：

目的: 研究吉林地区新发现一种害虫桦潜叶蜂的生活习性与环境相关性，为控制该害虫扩散为害提供科学依据。方法: 采用DNA分子鉴定与形态学特征相结合的方法，明确该虫的分类地位；运用室内及野外对比观察法记录害虫的生活习性，描述各虫态。于林间采用固定样方调查法，记录越冬前土壤内桦潜叶蜂老熟幼虫、做茧量及成虫羽化量。采用模拟成虫羽化季节月平均降水量对测试样地进行间隔周期为3天人工浇水处理，至成虫羽化。测定并记录土壤含水量、土壤温度以及土壤化学性质对羽化的影响。结果: 该虫为桦潜叶蜂，在吉林首次发现为害白桦。在吉林年发生2代，世代不整齐。6月上旬，始见羽化的成虫，在白桦的下层叶片以幼虫潜叶危害；6月下旬至7月上旬，第一代幼虫大多数幼虫脱叶落入浅土层中，少数于叶片内化蛹，并羽化出成虫，继续危害白桦中、上部嫩叶，8月下旬至9月上旬，以老熟幼虫脱叶入土，主要在5~10 cm做土茧越冬。第一代羽化成虫自白桦叶片近地处开始产卵，成虫单叶产卵4~6枚，虫口密度急剧增加则全叶均被害，严重造成落叶。第一代老熟幼虫于白桦叶片上表皮和栅栏层之间或土壤表层化蛹，第２代成虫羽化后向树冠上层迁移产卵为害。卵孵化周期为10天，幼虫共6龄。田间观察，在干旱年份羽化延迟，直至降雨成虫可陆续羽化。经土壤理化性质与翌年成虫羽化量相关性分析及冗余分析表明，土壤含水量是决定桦潜叶蜂为害发生及发生量变化的关键决定因子，相对较高的土壤含水量显著的促进成虫羽化，土壤pH、含氮量与羽化量正相关，而土壤温度对越冬后成虫羽化基本不构成影响；其他因素土壤全碳、全氮及全磷含量等对土壤中的桦潜叶蜂末龄幼虫生存无影响。结论: 在吉林地区首次发现的桦潜叶蜂，已形成区域性为害；该虫扩散受环境因素及土壤含水量影响较大，其中土壤含水量是影响成虫羽化量及羽化时间的关键要素，其次为土壤pH、含氮量，而其他理化性对越冬后成虫羽化基本不构成影响。

关键词: 桦潜叶蜂, 土壤含水量, 土壤温度, 羽化

Abstract:

Objective: This study examined the correlation between the living habits of a newly recorded pest, the birch leaf miner, in Jilin, and the environment, in order to provide a strategic basis for controlling the dispersal of the pest. Method: A combination method of DNA molecular identification with morphological characteristics was used to clarify the taxonomic status of the insect. The indoor and field comparative observation methods were used to record the habits of the pest and describe various insect stages. A fixed sample survey was performed in the forest to assess the number of mature larvae, cocoons and adult moths in the soil before overwintering. The test plots were artificially watered at 3 days intervals to imitate the average monthly precipitation during the adult moulting season until adult moulting. We measured and recorded the effects of soil water content, soil temperature and soil chemical properties on moulting. Result: The results showed that the insect is Profenusa thomsoni, which was for the first time found to infest birch trees in Jilin. The insect had two generations a year in Jilin, with irregular generations. In early June, the emergence of adult occurred. The larvae were discovered in the lower leaves of birch trees, and the first generation of larvae was observed from late June to early July, during which most of the larvae shed their leaves and fell into the shallow soil layer, while a few of them pupated in the leaves and emerged as adults. From late August to early September, the mature larvae escaped from the leaves into the soil and made soil cocoons mainly in the 5–10 cm layer for overwinter. The first generation of adult pinnipeds started to lay eggs near the birch leaves, and the adults laid 4–6 eggs in a single leaf. The first generation of mature larvae pupated between the upper epidermis and the fence layer of birch leaves or on the soil surface. The second generation of adults migrated to the upper canopy to lay eggs after eclosion. The egg incubation cycle was 10 days and the larvae had 6 instars. In drought years, the eclosion was delayed in the field until rainfall, when the adults were able to successively moult. Through correlation and redundancy analyses between soil physical and chemical properties and adult eclosion in the following year, it was showed that soil water content was the key determinant of the occurrence and amount of birch leafminer pests, and a relatively high soil water content significantly promoted adult eclosion. There was a positive correlation between soil pH, nitrogen content, and eclosion rate, while soil temperature had little impact on adult eclosion after overwintering. The other factors, such as soil total carbon, nitrogen and phosphorus content, posed no impacts on the survival of last instar larvae of the birch leafminer in soil. Conclusion: The birch leafminer has been found for the first time in the Jilin area and has formed a regional infestation. In this study, the life history and soil ecological adaptations of the insect have been evaluated, and the spread of the insect is mainly restricted by environmental factors and soil water content, among which soil water content controls the amount and timing of adult eclosion, followed by soil pH and nitrogen content, while other physical and chemical properties basically presents little effect on adult eclosion after overwintering.

Key words: Profenusa thomsoni, soil water content, soil temperature, eclosion

中图分类号:

Q969.94
S714

胡靓,邢蒙恩,房鸿嫄,刘瀚予,杜志琦,王楠,孙艳梅,范文忠,冯立超. 入侵性害虫桦潜叶蜂生活史及土壤生态适应性[J]. 林业科学, 2023, 59(5): 121-127.

Liang Hu,Meng’en Xing,Hongyuan Fang,Hanyu Liu,Zhiqi Du,Nan Wang,Yanmei Sun,Wenzhong Fan,Lichao Feng. Life History and Soil Ecological Adaptability of Profenusa thomsoni(Hymenoptera: Tenthredinidae), an Invasive Birch Leaf Miner[J]. Scientia Silvae Sinicae, 2023, 59(5): 121-127.

图/表 5

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参考文献 0

	Andersen J C, Van Driesche R G, Crandall R S, et al. Successful biological control of the ambermarked birch leafminer, Profenusa thomsoni (Hymenoptera: Tenthredinidae), in Anchorage, Alaska: Status 15 years after release of Lathrolestes thomsoni (Hymenoptera: Ichneumonidae) . Biological Control, 2021, 152, 104449. doi: 10.1016/j.biocontrol.2020.104449
	Benson R B. 1959. Further studies on the Fenusini (Hymenoptera: Tenthredinidae). Proceedings of the Royal Entomological Society of London, Series B, Taxonomy, 28(5–6): 90−92.
	Britton W E. A European leaf-miner of birch. Journal of Economic Entomology, 1924, 17, 601. doi: 10.1093/jee/17.5.601
	Coulson S J, Hodkinson I D, Wooley C, et al. Effects of experimental temperature elevation on high-arctic soil microarthropod populations. Polar Biology, 1996, 16 (2): 147- 153. doi: 10.1007/BF02390435
	Danks H V. Dehydration in dormant insects. Journal of Insect Physiology, 2000, 46 (6): 837- 852. doi: 10.1016/S0022-1910(99)00204-8
	Digweed S C, Langor D W. Distributions of leafmining sawflies (Hymenoptera: Tenthredinidae) on birch and alder in northwestern Canada. The Canadian Entomologist, 2004, 136 (5): 727- 731. doi: 10.4039/n03-096
	Digweed S C, Macquarrie C, Langor D W, et al. Current status of invasive alien birch-leafmining sawflies (Hymenoptera: Tenthredinidae) in Canada, with keys to species. Canadian Entomologist, 2009, 141 (3): 201- 235. doi: 10.4039/n09-003
	Digweed S C, Spence J R, Langor D W. Exotic birch-leafmining sawflies (Hymenoptera: Tenthredinidae) in Alberta: distributions, seasonal activities, and the potential for competition. The Canadian Entomologist, 1997, 129 (2): 319- 333. doi: 10.4039/Ent129319-2
	Digweed S C. Oviposition preference and larval performance in the exotic birch-eafmining sawfly Profenusa thomsoni . Entomologia Experimentalis et Applicata, 2006, 120 (1): 41- 49. doi: 10.1111/j.1570-7458.2006.00418.x
	Everatt M J, Convey P, Bale J S, et al. Responses of invertebrates to temperature and water stress: a polar perspective. Journal of Thermal Biology, 2015, 54, 118- 132. doi: 10.1016/j.jtherbio.2014.05.004
	Haris A. Sawflies of the Cserhat mountains (Hymenoptera: Symphyta). Natura Somogyiensis, 2021, 37, 25- 40.
	Holmstrup M. The ins and outs of water dynamics in cold tolerant soil invertebrates. Journal of Thermal Biology, 2014, 45, 117- 123. doi: 10.1016/j.jtherbio.2014.09.001
	Irwin J T, Lee Jr R E. Mild winter temperatures reduce survival and potential fecundity of the goldenrod gall fly, Eurosta solidaginis (Diptera: Tephritidae) . Journal of Insect Physiology, 2000, 46 (5): 655- 661. doi: 10.1016/S0022-1910(99)00153-5
	Martin J L. The bionomics of Profenusa thomsoni (Konow) (Hymenoptera: Tenthredinidae) a leaf-mining sawfly on Betula spp1 . The Canadian Entomologist, 1960, 92 (5): 376- 384. doi: 10.4039/Ent92376-5
	Progar R A, Kruse J J, Lundquist J E, et al. An entomopathogenic fungus and nematode prove ineffective for biocontrol of an invasive leaf miner Profenusa thomsoni in Alaska . Biocontrol Science and Technology, 2015, 25 (4): 373- 382. doi: 10.1080/09583157.2014.977224
	Ross H H. The nearctic sawflies of the genus Fenusa (Hymenoptera, Tenthredinidae) . Transactions of the Illinois State Academy of Science, 1936, 29, 263- 266.
	Schönrogge K, Altenhofer E. 1992. On the biology and larval parasitoids of the leaf-mining sawflies Profenusa thomsoni (Konow) and P. pygmaea (Konow) (Hymenoptera, Tenthredinidae). Entomologist’s Monthly Magazine, 128: 99−108.
	Simon C, Frati F, Beckenbach A, et al. Evolution, weighting and phylogenetic utility of mitochondrial gene sequences and a compilation of conserved polymerase chain reaction primers. Annals of the Entomological Society of America, 1994, 87 (6): 651- 701. doi: 10.1093/aesa/87.6.651
	Soper A L, Macquarrie C, Driesche R V. Introduction, establishment, and impact of Lathrolestes thomsoni (Hymenoptera: Ichneumonidae) for biological control of the ambermarked birch leafminer, Profenusa thomsoni (Hymenoptera: Tenthredinidae), in Alaska . Biological Control, 2015, 83, 13- 19. doi: 10.1016/j.biocontrol.2014.12.018
	Soper A L, Van Driesche R. The parasitoid complex of the ambermarked birch leafminer, Profenusa thomsoni Konow (Hymenoptera: Tenthredinidae), in Anchorage, Alaska and each species’ role in biological control . Biological Control, 2019, 136, 103995. doi: 10.1016/j.biocontrol.2019.05.014
	Spitzer P, Pratt K W. The history and development of a rigorous metrological basis for pH measurements. Journal of Solid State Electrochemistry, 2011, 15 (1): 69- 76. doi: 10.1007/s10008-010-1106-9
	Sulkava P, Huhta V, Laakso J. Impact of soil fauna structure on decomposition and N-mineralisation in relation to temperature and moisture in forest soil. Pedobiologia, 1996, 40 (6): 505- 513.
	Sulkava P, Huhta V. Effects of hard frost and freeze-thaw cycles on decomposer communities and N mineralisation in boreal forest soil. Applied Soil Ecology, 2003, 22 (3): 225- 239. doi: 10.1016/S0929-1393(02)00155-5
	Taeger A, Blank S M, Liston A D. World catalog of Symphyta (Hymenoptera). Zootaxa, 2010, 2580 (1): 1- 1064. doi: 10.11646/zootaxa.2580.1.1
	Taekul C, Valerio A A, Austin A D, et al. Molecular phylogeny of telenomine egg parasitoids (Hymenoptera: Platygastridaesl: Telenominae): Evolution of host shifts and implications for classification. Systematic Entomology, 2014, 39 (1): 24- 35. doi: 10.1111/syen.12032
	Wei M, Nie H, Taeger A. Sawflies (Hymenoptera: Symphyta) of China–Checklist and review of research. Recent sawfly research: synthesis and prospects. Goecke & Evers, 2006, Keltern,16, 505- 574.
	Weigel R, Henry H A, Beil I, et al. Ecosystem processes show uniform sensitivity to winter soil temperature change across a gradient from central to cold marginal stands of a major temperate forest tree. Ecosystems, 2021, 24 (6): 1545- 1560. doi: 10.1007/s10021-021-00600-4
	Wilke B M. 2005. Determination of chemical and physical soil properties. In: Monitoring and assessing soil bioremediation. Springer, Berlin, Heidelberg, 47−95.

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