A review of the role played by cilia in medusozoan feeding mechanics

IF 11 1区 生物学 Q1 BIOLOGY Biological Reviews Pub Date : 2024-02-02 DOI:10.1111/brv.13052
Mayara de A. Jordano, Renato M. Nagata, André C. Morandini
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Abstract

Cilia are widely present in metazoans and have various sensory and motor functions, including collection of particles through feeding currents in suspensivorous animals. Suspended particles occur at low densities and are too small to be captured individually, and therefore must be concentrated. Animals that feed on these particles have developed different mechanisms to encounter and capture their food. These mechanisms occur in three phases: (i) encounter; (ii) capture; and (iii) particle handling, which occurs by means of a cilia-generated current or the movement of capturing structures (e.g. tentacles) that transport the particle to the mouth. Cilia may be involved in any of these phases. Some cnidarians, as do other suspensivorous animals, utilise cilia in their feeding mechanisms. However, few studies have considered ciliary flow when examining the biomechanics of cnidarian feeding. Anthozoans (sessile cnidarians) are known to possess flow-promoting cilia, but these are absent in medusae. The traditional view is that jellyfish capture prey only by means of nematocysts (stinging structures) and mucus, and do not possess cilia that collect suspended particles. Herein, we first provide an overview of suspension feeding in invertebrates, and then critically analyse the presence, distribution, and function of cilia in the Cnidaria (mainly Medusozoa), with a focus on particle collection (suspension feeding). We analyse the different mechanisms of suspension feeding and sort them according to our proposed classification framework. We present a scheme for the phases of pelagic jellyfish suspension feeding based on this classification. There is evidence that cilia create currents but act only in phases 1 and 3 of suspension feeding in medusozoans. Research suggests that some scyphomedusae must exploit other nutritional sources besides prey captured by nematocysts and mucus, since the resources provided by this diet alone are insufficient to meet their energy requirements. Therefore, smaller particles and prey may be captured through other phase-2 mechanisms that could involve ciliary currents. We hypothesise that medusae, besides capturing prey by nematocysts (present in the tentacles and oral arms), also capture small particles with their cilia, therefore expanding their trophic niche and suggesting reinterpretation of the trophic role of medusoid cnidarians as exclusively plankton predators. We suggest further study of particle collection by ciliary action and its influence on the biomechanics of jellyfishes, to expand our understanding of the ecology of this group.

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纤毛在介形动物摄食机械中的作用综述
纤毛广泛存在于元虫中,具有各种感觉和运动功能,包括通过悬食动物的摄食流收集颗粒。悬浮颗粒的密度很低,而且太小,无法单独捕获,因此必须集中起来。以这些微粒为食的动物发展出了不同的机制来遇到并捕获食物。这些机制分为三个阶段:(i) 遇到;(ii) 捕获;(iii) 处理微粒,即通过纤毛产生的水流或捕获结构(如触手)的运动将微粒送到口中。纤毛可能参与其中任何一个阶段。一些刺网动物和其他悬食动物一样,在其摄食机制中利用纤毛。然而,在研究刺网动物摄食的生物力学时,很少有研究考虑到纤毛流动。已知安氏动物(无柄刺网动物)具有促进流动的纤毛,但在介壳虫中却没有这种纤毛。传统观点认为,水母仅通过线虫囊(刺吸结构)和粘液捕获猎物,不具备收集悬浮颗粒的纤毛。在本文中,我们首先概述了无脊椎动物的悬浮取食,然后批判性地分析了纤毛虫(主要是 Medusozoa)中纤毛的存在、分布和功能,重点是颗粒收集(悬浮取食)。我们分析了悬浮摄食的不同机制,并根据我们提出的分类框架对它们进行了分类。在此分类基础上,我们提出了浮游水母悬浮摄食的阶段划分方案。有证据表明,纤毛会产生水流,但仅作用于中生代悬浮摄食的第 1 和第 3 阶段。研究表明,除了线囊和粘液捕获的猎物外,一些栉水母必须利用其他营养来源,因为仅靠这种食物提供的资源不足以满足它们的能量需求。因此,较小的颗粒和猎物可能是通过其他第二阶段机制捕获的,其中可能涉及纤毛电流。我们假设,髓网虫除了用线虫囊(存在于触手和口臂中)捕捉猎物外,还用纤毛捕捉小颗粒,从而扩大了它们的营养位,并建议重新解释髓网虫作为浮游生物专职捕食者的营养作用。我们建议进一步研究纤毛作用收集颗粒的情况及其对水母生物力学的影响,以扩大我们对该类生物生态学的了解。
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来源期刊
Biological Reviews
Biological Reviews 生物-生物学
CiteScore
21.30
自引率
2.00%
发文量
99
审稿时长
6-12 weeks
期刊介绍: Biological Reviews is a scientific journal that covers a wide range of topics in the biological sciences. It publishes several review articles per issue, which are aimed at both non-specialist biologists and researchers in the field. The articles are scholarly and include extensive bibliographies. Authors are instructed to be aware of the diverse readership and write their articles accordingly. The reviews in Biological Reviews serve as comprehensive introductions to specific fields, presenting the current state of the art and highlighting gaps in knowledge. Each article can be up to 20,000 words long and includes an abstract, a thorough introduction, and a statement of conclusions. The journal focuses on publishing synthetic reviews, which are based on existing literature and address important biological questions. These reviews are interesting to a broad readership and are timely, often related to fast-moving fields or new discoveries. A key aspect of a synthetic review is that it goes beyond simply compiling information and instead analyzes the collected data to create a new theoretical or conceptual framework that can significantly impact the field. Biological Reviews is abstracted and indexed in various databases, including Abstracts on Hygiene & Communicable Diseases, Academic Search, AgBiotech News & Information, AgBiotechNet, AGRICOLA Database, GeoRef, Global Health, SCOPUS, Weed Abstracts, and Reaction Citation Index, among others.
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