lubbocki Lepidurus和Triops cancriformis活化石发出水下声音的第一个证据(鳃足目:notostrae)

IF 1.3 4区 生物学 Q3 MARINE & FRESHWATER BIOLOGY Aquatic Biology Pub Date : 2021-01-01 DOI:10.3354/AB00744
G. Buscaino, Maria Ceraulo, D. Canale, E. Papale, F. Marrone
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引用次数: 5

摘要

声音是海洋和淡水生态系统中最有效的交流手段。然而,目前没有关于非马甲甲壳类动物声发射的数据,因此它们产生声音的能力是未知的。本研究首次对两种蝌蚪虾(Triops cancriformis和Lepidurus lubbocki)的声音进行了研究。lubbocki的个体采集自意大利西西里岛的一个天然临时池塘,而T. cancriformis的个体采集自意大利撒丁岛一个岩石池沉积物中的卵。在实验室里,装有动物的实验水箱(一次一个物种)被声学监测。这两个物种都能产生高频、宽带的脉冲,这可以通过它们的声压级来区分,其中,lubbocki的声压级(146 dB)高于T. cancriformis的声压级(130 dB),以及它们的第一和第二峰频率(65和86 kHz)高于T. cancriformis的声压级(63和71 kHz)。功率密度谱中的能量分布呈现出不同的形状,从3db带宽和中心频率可以看出。脉冲持续时间分别为88 μs和97 μs。卢巴克氏夜蛾的鸣叫频率高于癌形夜蛾,且具有明显的昼夜节律规律,夜间鸣叫丰度更高。本研究报告了非马孔甲壳类动物声发射的第一个证据,并揭示了被动声监测在探测这些临时水体中难以捕捉的关键物种的存在、丰度和生命周期方面的巨大潜力。
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First evidence of underwater sounds emitted by the living fossils Lepidurus lubbocki and Triops cancriformis (Branchiopoda: Notostraca)
Sound is the most effective means of communication in marine and freshwater ecosystems. However, no data about acoustic emissions from non-malacostracan crustaceans are currently available, so their ability to produce sounds is unknown. For the first time, this study investigated the sound produced by 2 tadpole shrimp species, Triops cancriformis and Lepidurus lubbocki. L. lubbocki individuals were collected from a natural temporary pond in Sicily (Italy), whereas T. cancriformis individuals were obtained from eggs contained in sediment from a rock pool in Sardinia (Italy). In the laboratory, experimental tanks with the animals (one species at a time) were acoustically monitored. Both species produced high-frequency, wideband pulses distinguishable by their sound pressure level, which was higher in L. lubbocki (146 dB) than in T. cancriformis (130 dB), and by their first and second peak frequencies, which were higher in L. lubbocki (65 and 86 kHz) than in T. cancriformis (63 and 71 kHz). The energy distributions in the power density spectra showed different shapes, as revealed by the 3 dB bandwidth and centre frequency. The pulse durations were 88 and 97 μs in L. lubbocki and T. cancriformis, respectively. L. lubbocki presented a higher emission rate than T. cancriformis and a marked circadian pattern, with a higher abundance of sounds during the night. This study reports the first evidence of sound emissions from non-malacostracan crustaceans and reveals the high potential of passive acoustic monitoring to detect the presence, abundance, and life cycle of these elusive keystone species of temporary water bodies.
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来源期刊
Aquatic Biology
Aquatic Biology 生物-海洋与淡水生物学
CiteScore
2.70
自引率
0.00%
发文量
7
审稿时长
3 months
期刊介绍: AB publishes rigorously refereed and carefully selected Feature Articles, Research Articles, Reviews and Notes, as well as Comments/Reply Comments (for details see MEPS 228:1), Theme Sections, Opinion Pieces (previously called ''As I See It'') (for details consult the Guidelines for Authors) concerned with the biology, physiology, biochemistry and genetics (including the ’omics‘) of all aquatic organisms under laboratory and field conditions, and at all levels of organisation and investigation. Areas covered include: -Biological aspects of biota: Evolution and speciation; life histories; biodiversity, biogeography and phylogeography; population genetics; biological connectedness between marine and freshwater biota; paleobiology of aquatic environments; invasive species. -Biochemical and physiological aspects of aquatic life; synthesis and conversion of organic matter (mechanisms of auto- and heterotrophy, digestion, respiration, nutrition); thermo-, ion, osmo- and volume-regulation; stress and stress resistance; metabolism and energy budgets; non-genetic and genetic adaptation. -Species interactions: Environment–organism and organism–organism interrelationships; predation: defenses (physical and chemical); symbioses. -Molecular biology of aquatic life. -Behavior: Orientation in space and time; migrations; feeding and reproductive behavior; agonistic behavior. -Toxicology and water-quality effects on organisms; anthropogenic impacts on aquatic biota (e.g. pollution, fisheries); stream regulation and restoration. -Theoretical biology: mathematical modelling of biological processes and species interactions. -Methodology and equipment employed in aquatic biological research; underwater exploration and experimentation. -Exploitation of aquatic biota: Fisheries; cultivation of aquatic organisms: use, management, protection and conservation of living aquatic resources. -Reproduction and development in marine, brackish and freshwater organisms
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