稀有枝角类盾额隆背溞种群生态学特征

doi:10.13287/j.1001-9332.202501.032

应用生态学报 ›› 2025, Vol. 36 ›› Issue (1): 293-302.doi: 10.13287/j.1001-9332.202501.032

稀有枝角类盾额隆背溞种群生态学特征

陈国柱^1,2,3,4

¹西南林业大学, 云南省高原湿地保护修复与生态服务重点实验室, 昆明 650224;
²西南林业大学, 国家高原湿地研究中心/湿地学院, 昆明 650224;
³西南林业大学, 云南省滇池湿地生态系统国家定位观测研究站, 昆明 650224;
⁴西南林业大学, 滇池湖泊生态系统云南省野外科学观测研究站, 昆明 650224

收稿日期:2024-06-05 修回日期:2024-11-08 出版日期:2025-01-18 发布日期:2025-07-18
通讯作者: *E-mail: chenguozhu79@163.com
作者简介:陈国柱, 男, 1979年生, 博士, 副研究员。主要从事鱼类入侵生态学研究。E-mail: chenguozhu79@163.com
基金资助:
国家自然科学基金项目(31960283,32460330)、云南省高原湿地保护修复与生态服务重点实验室开放基金项目(202105AG070002)和滇池湖泊生态系统云南省野外科学观测研究站项目(202305AM340008)

Population characteristics of a rare cladocerans, Bunops scutifrons

CHEN Guozhu^1,2,3,4

¹Yunnan Key Laboratory of Plateau Wetland Conservation, Restoration and Ecological Services, Southwest Forestry University, Kunming 650224, China;
²National Plateau Wetland Research Center/College of Wetlands, Southwest Forestry University, Kunming 650224, China;
³National Wetland Ecosystem Fixed Research Station of Danchi, Southwest Forestry University, Kunming 650224, China;
⁴Dianchi Lake Ecosystem Observation and Research Station of Yunnan Province, Southwest Forestry University, Kunming 650224, China

Received:2024-06-05 Revised:2024-11-08 Online:2025-01-18 Published:2025-07-18

摘要/Abstract

摘要： 稀有种具有典型的狭域分布和生境利用专化等特点,可能携带着物种致危机制的重要信息,厘清其稀有成因将有力促进生态学理论的进一步发展。盾额隆背溞是一种罕见枝角类,国内仅记述过4个样品。除少量分类学形态描述外,其关键性生物学及生态学特征迄今尚未被揭示。本研究在滇池流域枝角类系统调查中首次采集得到盾额隆背溞活体,通过扩繁取得丰富研究材料,并围绕其种群结构、种群繁殖力、种群动态参数等关键种群生态学特征开展研究,以初步了解其种群稀有成因。2022—2023两年的研究结果显示,盾额隆背溞为微小型枝角类(体长0.30～1.15 mm),初次性成熟体长约为0.52 mm。未在种群中检出雄性个体。2022年室外种群夏卵繁殖力为(2.2±1.4) eggs·ind^-1(n=334, 最大值为8 eggs·ind^-1),2023年为(4.8±2.8) eggs·ind^-1 (n=94, 最大值为13 eggs·ind^-1)。产冬卵时,卵鞍含卵2个。在生命表试验中,以小球藻培养的种群子一代(F₁)、子二代(F₂)最大繁殖龄期数分别为8和7个,总生殖率分别为30.3和9.4 eggs·ind^-1,最长个体寿命分别为21和16 d,种群内禀增长率分别为0.37和0.36;以泥糜培养液培养的种群F₁、F₂最大繁殖龄期数均为8个,其总生殖率分别为40.3和36.1 eggs·ind^-1,最长个体寿命分别为28 和27 d,内禀增长率分别为0.31和0.30。在合适环境下盾额隆背溞种群增长迅速,其瞬时增长率为每天0.39,在第10天种群数量已达起始的50倍,相对密度达510 ind·L^-1,并进入平台期。在自然环境中其种群丰度极低,2022年在水体干枯期种群消失;在2023年的连续观察中,其种群在丰水期突然从观察区域完全消失。分析表明,盾额隆背溞具有相对较长寿命、较高繁殖力及较强的种群增长潜力,与众多常见种相比没有呈现明显的劣势,其在自然界中种群稀少可能并不是由其个体生物学及种群生态学基本特征受限所致,而是对环境选择压力应对具脆弱性所致。

关键词: 盾额隆背溞, 种群结构, 繁殖力, 种群动态, 稀有物种

Abstract: Rare species may exhibit some characteristics, such as a narrow distribution area and a specialization of habitat utilization. These characteristics may provide crucial information about the underlying mechanisms of species endangerment. Bunops scutfrons, a rare cladocera, has received more and more attention due to its rarity. Understanding the causes of its rarity could advance ecological theory. This species has only been recorded in four samples in China, with limited taxonomic descriptions. Its key biological and ecological characteristics remain largely unknown. Live specimens of B. scutfrons were firstly collected from the Dianchi Lake Basin during a systematic clado-ceran survey in 2022. Through successful propagation, sufficient individuals were available, allowing for an investigation into population structure, reproductive capacity, and population dynamics of this species. I carried out observations in 2022 and 2023. B. scutfrons was a small cladoceran (body length: 0.30-1.15 mm), with sexual maturation at a small size (0.52 mm). Notably, no male individuals were detected in the population. In 2022, the fecundity of the outdoor population (summer eggs) was (2.2±1.4) eggs·ind^-1 (n=334, max=8 eggs·ind^-1), which increased to (4.8±2.8) eggs·ind^-1(n=94, max=13 eggs·ind^-1) in 2023. During the reproduction of winter eggs, two eggs were produced per ephippium. In life table experiment, individuals were fed with mixed algal solution (Chlorella spp.). The maximum number of reproductive instars in the first (F₁) and second (F₂) generation was 8 and 7, respectively. The total reproductive rate was 30.3 eggs·ind^-1 and 9.4 eggs·ind^-1, respectively, with maximum lifespans of 21 and 16 days, and intrinsic growth rates of 0.37 and 0.36. When cultured in a mud slurry medium, the maximum reproductive instars for both the F₁ and F₂ generations was 8, with a total reproductive rate of 40.3 and 36.1 eggs·ind^-1, respectively. The lifespan extended to 28 and 27 days, with intrinsic growth rates of 0.31 and 0.30, respectively. Under suitable conditions, the population of B. scutfrons grew rapidly, with an instantaneous growth rate of 0.39 per day. By the 10th day, population size increased 50-fold, reaching a relative density of 510 ind·L^-1, and the population entered a plateau phase. In the natural environment, however, the relative abundance remained extremely low. In 2022, the population disappeared during the dry season, while in 2023, it vanished completely from the observation area during the flood season. These findings suggested that B. scutfrons exhibits a relatively long lifespan, high reproductive capacity, and strong potential for population growth under favorable conditions. Compared to many common species, B. scutfrons does not show significant disadvantages in its fundamental biological or population ecological traits. Its rarity in natural environments is likely due to its susceptibility to environmental pressures rather than intrinsic biological limitations.

Key words: Bunops scutifrons, population structure, fecundity, population dynamics, rare species

陈国柱. 稀有枝角类盾额隆背溞种群生态学特征[J]. 应用生态学报, 2025, 36(1): 293-302.

CHEN Guozhu. Population characteristics of a rare cladocerans, Bunops scutifrons[J]. Chinese Journal of Applied Ecology, 2025, 36(1): 293-302.

参考文献

[1] Enquist BJ, Feng X, Boyle B, et al. The commonness of rarity: Global and future distribution of rarity across land plants. Science Advances, 2019, 5: eaaz0414
[2] Cody ML. Structural niches in plant communities//Diamond J, ed. Community Ecology. New York: Harper & Row Publishers, 1986: 381-405
[3] Betts J, Richard PY, Craig HT, et al. A framework for evaluating the impact of the IUCN Red List of threatened species. Conservation Biology, 2020, 34: 632-643
[4] Everton AM. An index for assessing the rare species of a community. Ecological Indicators, 2021, 124: 107424
[5] Chen Y, Wu Y, Chen W, et al. Application of a negative multinomial model gives insight into rarity-area relationships. Forests, 2020, 11: f11050571
[6] 张世萍, 陈受忠. 中国隆背溞属(甲壳纲: 双甲目)一新记录. 华中农业大学学报, 1996, 15(4): 374-375
[7] Davidson NL, Griffin MC, Kelso WE. A report of Bunops scutifrons from Louisiana. Hydrobiologia, 1997, 356: 183-184
[8] Martinez-Caballero AL, Morales-Gutierrez S, Elias-Gutierrez M. First record of the genus Bunops Birge, 1893 (Cladocera: Macrothricidae) in the Neotropical highlands of Mexico with a detailed study of morphology and DNA barcodes. Zootaxa, 2017, 4300: 589-600
[9] 田家怡, 高霞. 黄河三角洲淡水浮游动物名录. 海洋湖沼通报, 2001, 23(4): 81-90
[10] 田家怡. 山东省淡水枝角类及一属、种新记录和华北区23种新记录. 山东科学, 2004, 17(1): 21-25
[11] Ross LS. Some Manitoba Cladocera, with description of one new species. The American Naturalist, 1897, 31: 293-303
[12] 堵南山, 赖伟, 邓雪怀. 太湖枝角类季节变化的初步研究. 海洋与湖沼, 1964, 6(2): 193-204
[13] Van Damme K, Sinev AY. A new genus of cave-dwelling microcrustaceans from the Dinaric region (south-east Europe): Adaptations of true Stygobitic cladocera (Crustacea: Branchiopoda). Zoological Journal of the Linnean Society, 2011, 161: 31-52
[14] Sarmaja-Korjonen K. Headshields of ephippial Chydorus piger Sars (Cladocera, Chydoridae) females from northern Finnish Lapland: A long period of gamogenesis? Hydrobiologia, 1999, 390: 11-18
[15] 蒋燮治, 堵南山. 中国动物志·节肢动物门·甲壳纲·淡水枝角类. 北京: 科学出版社, 1979: 25-26
[16] 郑重. 淡水枝角类的生殖. 动物学杂志, 1959(1): 22-28
[17] 黄祥飞. 温度对透明溞和隆线溞—亚种发育及生长的影响. 水生生物学报, 1984, 8(2): 207-224
[18] 李双宇, 揣洁, 崔延超, 等. 盐度对圆形盘肠溞存活, 生长和繁殖的影响. 大连海洋大学学报, 2015, 30(1): 26-40
[19] 董成浩, 赵文, 魏杰, 等. 壳纹船卵溞的盐度适应性研究. 大连海洋大学学报, 2021, 36(2): 268-273
[20] 邓道贵, 靳英, 柳明, 等. 温度和食物浓度对老年低额溞生长与生殖的影响. 水生生物学报, 2006, 30(3): 298-303
[21] Huang XN, Shi XL, Xu S, et al. Life history characte-ristics of Macrothrix rosea (Jurine, 1820)(Cladocera, Macrothricidae) in laboratory conditions. Journal of Limnology, 2011, 70: 248-254
[22] 施心路, 齐彩花, 刘桂杰, 等. 温度对喜马拉雅低额溞生长与生殖的影响. 水生生物学报, 2010, 34(4): 794-805
[23] 陈受忠. 近亲尖额溞Alona affinis(Leydig,1860)的若干生物学特征. 西南大学学报: 自然科学版, 1989, 11(5): 502-504
[24] 陈受忠. 奇异尖额溞若干生物学问题的初步探讨. 四川动物, 1987, 9(1): 10-13
[25] 黄祥飞. 三种淡水枝角类生物学的研究. 海洋与湖沼, 1985, 16(3): 188-195
[26] Xi YL, Hagiwara A, Sakakura Y. Combined effects of food level and temperature on life table demography of Moina macrocopa Straus (Cladocera). International Review of Hydrobiology, 2005, 90: 546-554
[27] 王玉善, 赵文, 邵宁宁, 等. 盐度对苏拉威西秀体溞种群内禀增长率的影响. 海洋科学, 2008, 32(6): 17-19
[28] Korpelainen H. The effects of temperature and photope-riod on life history parameters of Daphnia magna (Crustacea: Cladocera). Freshwater Biology, 1986, 16: 615-620
[29] Osorio-Treviño OC, Arzate-Cárdenas MA, Rico-Martínez R. Effect of diet and temperature on the culture of Alona guttata (Sars, 1862)(Cladocera: Chydoridae) under laboratory conditions. Hidrobiológica, 2022, 32: 81-91
[30] Hebert PNN. Ecological difference between genotypes in a natural population of Daphnia magna. Heredity, 1974, 33: 327-337
[31] 王丹丽, 赖伟. 拟老年低额溞的生长与生殖. 水产学报, 1990, 14(4): 304-312
[32] 向贤芬, 虞功亮, 陈受忠. 长江流域的枝角类. 北京: 中国科学技术出版社, 2015: 71-75
[33] De Meester L, Vanoverbeke J, De Gelas K, et al. Genetic structure of cyclic parthenogenetic zooplankton populations: A conceptual framework. Archiv für Hydrobio-logie, 2006, 167: 217-244
[34] Boileau MG, Hebert PDN, Schwartz SS. Non-equilib-rium gene frequency divergence: Persistent founder effects in natural populations. Journal of Evolutionary Biology, 1992, 5: 25-39
[35] 黄琦, 徐少林, 徐磊, 等. 广东流溪河水库盔型溞(Daphnia galeata)休眠种群与现生种群的单倍型多样性和遗传分化. 湖泊科学, 2017, 29(5): 1209-1216
[36] 陈利娟, 肖乔芝, 仇玉萍, 等. 云南滇池入侵虾虎鱼类的共存策略. 应用生态学报, 2021, 32(9): 3357-3369

稀有枝角类盾额隆背溞种群生态学特征

Population characteristics of a rare cladocerans, Bunops scutifrons

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