密度信号对两种臂尾轮虫种群增长的影响

Abstract

PDF HTML阅读 XML下载 导出引用 引用提醒 密度信号对两种臂尾轮虫种群增长的影响 DOI: 10.5846/stxb201303010331 作者: 作者单位: 生物多样性与生态工程教育部重点实验室,生物多样性与生态工程教育部重点实验室 作者简介: 通讯作者: 中图分类号: 基金项目: 国家自然科学基金资助项目(30970349) Effects of crowding signals on population growth of two Brachionus rotifer species Author: Affiliation: Ministry of Education Key Laboratory for Biodiversity Science and Ecological Engineering,College of Life Sciences,Beijing Normal University,Ministry of Education Key Laboratory for Biodiversity Science and Ecological Engineering,College of Life Sciences,Beijing Normal University Fund Project: 摘要 | 图/表 | 访问统计 | 参考文献 | 相似文献 | 引证文献 | 资源附件 | 文章评论 摘要:为了更好的了解化学干扰对轮虫种间竞争的影响,分别用萼花臂尾轮虫(Brachionus calyciflorus)和角突臂尾轮虫(Brachionus angularis)研究了同种和异种种群密度信号对种群增长的影响。结果表明,密度信号对轮虫种群增长具有一定的影响。萼花臂尾轮虫的密度信号显著降低了本种和角突臂尾轮虫种群的环境容纳量K并提高了它们的种群增长率r(P < 0.05),角突臂尾轮虫的密度信号对本种和萼花臂尾轮虫的种群增长都没有显著影响(P > 0.05)。萼花臂尾轮虫种群增长受同种密度信号抑制十分显著,环境容纳量K降低了50%以上,可能主要受自毒作用的调节,但同种密度信号对高有性生殖的萼花臂尾轮虫种群的混交率影响不明显。角突臂尾轮虫几乎不受自身密度信号的影响。因此,在两种臂尾轮虫的竞争中,由于自身密度信号的抑制作用,萼花臂尾轮虫将更快被角突臂尾轮虫排除。据此可推测密度信号对轮虫的种间竞争具有重要影响。 Abstract:Chemical signal is one of the primary channels of sensory input for zooplankton. Chemicals released by zooplankton individuals can affect their behavior, including migration, feeding, predator defense, growth, reproduction, and so on. Rotifers are adequate model animals for chemical ecology studies in aquatic system, with a rich literature on inducible defense and sexual production. However, studies associated with the effects of chemical signals on population competition have not been reported. Brachionus calyciflorus and Brachionus angularis are both common freshwater rotifer species. B. angularis, who has a lower threshold food concentration because of its smaller body size, would out-compete large body sized B. calyciflorus when the resource is limited. The present work examined the effect of crowding signals on population growth of B. calyciflorus and B. angularis. Culture medium conditioned by rotifers was used as the crowding signals and two crowding levels were set for each rotifer species. Population growth experiments of the two rotifers were carried out at an initial density of 1 ind./mL in 5 ml and 20 ml medium for B. angularis and B. calyciflorus, respectively. Regardless of the treatments, B. angularis reached its maximum population density at 100 ind./mL after 23 days, while it took B. calyciflorus only 3 to 8 days to reach its maximum population density, which was far lower than that of B. angularis. Both B. calyciflorus and B. angularis showed a higher population growth rate (r) and lower maximum population density (K) under the crowding signals of B. calyciflorus. However, neither B. calyciflorus population nor B. angularis population was significantly affected by the crowding signals of B. angularis. The maximum population density of B. calyciflorus was inhibited by its own crowding signal (from 9.124 ind./mL to 4.564 and 3.448 ind./mL under low and high crowding signals, respectively), leading a 50% decreasing of the carrying capacity K of the population. That was probably because of the inhibitory effects of autotoxins. Meanwhile, mixis ratios of B. calyciflorus populations fluctuated between 40% and 80%, and showed no significant differences among groups, because B. calyciflorus was sensitive to population density and mixis ratios were high at all these population densities. Because population growth of B. angularis was obviously affected by its own crowding signals, growing to a higher population density, and its threshold food concentration was lower, as a result, exclusion of B. calyciflorus by B. angularis may become quicker during the competition process. These results indicated that crowding signals may play an important role in the competition outcome between different rotifer species. 参考文献 相似文献 引证文献