巴布亚硝水母无性生殖过程及形态变化北大核心CSCD

以巴布亚硝水母(Mastigias papua)为研究对象,观察了水螅体无性生殖产生类浮浪幼虫胞芽、类浮浪幼虫胞芽变态发育为水螅体、水螅体横裂产生碟状体以及碟状体发育为水母体的过程和形态变化。25℃时类浮浪幼虫胞芽经过93 h后变态发育为水螅体。换用带有虫黄藻的天然海水并将培养温度从25℃升至27℃后,水螅体开始横裂,萼部触手环下方产生缢痕。水螅体横裂开始47 h后,缢痕更加明显,其上方部分发育为碟状幼体,后期碟状体搏动越来越频繁,最后释放。释放后的碟状体在实验室培养条件下21 d后可发育为水母幼体。巴布亚硝水母虽然只有产生类浮浪幼虫胞芽一种无性生殖方式,但繁殖速度较快,27℃时1个水螅体平均1 d可产生1.7个类浮浪幼虫胞芽,类浮浪幼虫胞芽可在3或4 d的短时间内附着变态。     

大型水母幼体生长的影响因子研究进展

21世纪以来,中国东、黄海,韩国西海岸以及日本海连年发生大型水母暴发现象,对海洋渔业的生产活动以及海洋生态系统带来巨大的影响。水母暴发形成机制非常复杂,解释其发生机理并有效预报是目前急待解决的问题。大型水母的生活史中有明显的世代交替现象,受精卵,浮浪幼虫,螅状体,足囊,横裂体到碟状体的幼体发育阶段属无性世代,幼蜇发育到成蜇阶段属有性世代。在早期生活史中,螅状体的足囊繁殖与横裂生殖是大型水母无性繁殖的重要方式,对其成体的数量形成至关重要。综述了国内外有关温度、盐度、光以及营养条件对大型水母早期发育阶段的影响研究进展,研究表明温度是影响螅状体发育以及足囊繁殖和横裂生殖的最主要的环境因子;盐度、光和营养条件在适温范围内,均对螅状体和横裂生殖有一定的影响,其上下限随水母种类和发育阶段有所变化。展望了大型水母早期幼体研究的发展趋势,如环境因子对不同种类的大型水母幼体生长机理的影响、多个环境因子对幼体的综合作用、动态的环境因子与大型水母幼体之间的关系等。     

海蜇横裂生殖

正海蜇(Rhopilema esculentum)属于钵水母纲(Scyphozoa),根口水母目(Rhizostomeae),根口水母科(Rhizostomatidae),海蜇属(Rhopilema),主要分布于西北太平洋沿岸,是我国重要的海水增养殖品种,同时是我国钵水母研究的代表种类。海蜇、沙海蜇(Nemopilema namurai)、海月水母(Aurelia auria)等大多数钵水母具有复杂的生活史,包括营栖息生活的无性阶段(水螅体)和营浮游生活的有性阶段(水母体),从水螅体到水母体的转变是通过一个有序变态过程实现的,叫作"横裂生殖"。"横裂生殖"是钵水母特有的一种无性繁殖方式,也是钵水母水螅体产生水母体的唯一途径,是影响水母体种群数量的重要环节,亟需加深对其调控机制的认识。     

温度、投饵频次对白色霞水母无性繁殖与螅状体生长的影响

白色霞水母是我国近海主要大型灾害水母种类之一,其暴发性增殖严重破坏了海洋生态系统平衡.在室内控制条件下,研究了温度(7.5、11、14.5、18、21.5和25℃)和投饵频次(1次/2d、1次/8d和1次/16d)对白色霞水母无性繁殖与螅状体生长的影响.结果显示,白色霞水母足囊繁殖的适宜温度为18-25℃,足囊繁殖随温度和投饵频次的增加而增加.温度对白色霞水母横裂率和横裂次数的影响显著,温度越高,白色霞水母发生横裂生殖的时间越早,横裂生殖速度越快,重复横裂次数越多,释放的碟状体数量也越多.横裂率和横裂次数随投饵频次的增加而递增.白色霞水母螅状体在7.5-25℃范围的成活率均为100％,其生长速度随温度和投饵频次的增加而增加.温度和投饵频次对白色霞水母螅状体足囊繁殖、横裂率和螅状体生长具有明显的交互效应.螅状体的横裂次数和初生碟状幼体伞径随螅状体柄径增大而递增,呈线性相关.研究表明,温度、投饵频次即营养条件显著影响着白色霞水母的种群数量,说明海水水温上升、富营养化或渔业资源锐减导致的浮游动物量增加均可能诱发白色霞水母暴发性增殖.结论为进一步探索大型水母暴发的生态环境机理提供重要科学依据.     

高通量测序解析大青叶有效成分的生物合成途径

中药大青叶是菘蓝的干燥叶片,主要活性物质为吲哚类化合物,包括靛蓝、靛玉红、色胺酮等,以上吲哚类化合物的生物合成起始于色氨酸途径,目前在植物中的合成机制还未完全阐明.本研究以成熟菘蓝叶片为研究对象,对茉莉酸甲酯诱导的叶片进行了转录组分析,对已知途径进行了转录组注释,并对未解析途径进行了预测分析.分别获得了色氨酸代谢途径中色氨酸、吲哚乙酸、吲哚苷和萜类吲哚生物碱合成几个代谢支路中16个催化步骤的38个编码基因.通过共表达网络分析,预测转录因子bHLH125可能对吲哚途径具有核心调控作用;CYP2A6-1和CYP735A2等蛋白可能催化生成靛蓝、靛玉红、色胺酮前体的羟基化反应,对这两个蛋白与底物分子的结合进行分子对接建模,均显示对吲哚分子具有较好的结合力.本研究为后续开展菘蓝代谢调控和育种,以及开展吲哚类物质合成生物学研究提供候选基因.     

温度对海蜇横裂生殖的影响

横裂生殖(strobilafion)是大多数钵水母(Scyphomedusac)特有的一种无性繁殖方式,指螅状幼体经分节(segmentation)和变态(metamorphosis)两个紧密联系的发育阶段产生碟状幼体的全过程(Spangenberg,1965)。海蜇(Rhopilema esculenta Kishinouye)生活史多次变态过程中,横裂生殖是一个重要环节(丁耕芜、陈介康,1981);就经济意义而言,人类食用的是海蜇水母型成体,只有通过横裂生殖才能产生实质为幼水母的碟状幼体。因此,阐明海蜇横裂生殖的诱导和抑制条件,无论对发育生物学研究,或以人工手段培育出大量海蜇幼水母用于水产增殖实践都具有重要意义。     

短期低温条件对海蜇横裂生殖的影响

刺胞动物是一类仅具有两个胚层的低等动物, 一般认为海绵动物为侧生动物,刺胞动物为真正的后生动物起源1。刺胞动物在淡水中的种类主要为淡水水螅类以及著名而珍稀的桃花水母类2-3, 在海水中常见的刺胞动物主要为各种珊瑚类以及水母类, 其中有些大型钵水母类可以食用并具有较高的经济价值, 并成为海洋渔业捕捞的对象4。       

吲哚——种间及跨界信号分子新成员

吲哚作为一种典型的氮杂环芳烃化合物,在自然界中广泛存在。近年来,越来越多的研究表明吲哚具有一定的生物活性,是一种新型种间及跨界的信号分子。研究发现,吲哚不仅可以调节微生物的毒性、耐药性、生物膜形成以及群感效应等生理生化行为,调控植物生长发育和防御系统的形成过程,还能够影响动物的肠道炎症、细胞氧化压力及荷尔蒙分泌等生理健康。因此吲哚在微生物代谢、动物健康和植物生长等多个方面扮演了重要角色,具有重要的生物学及生态学双重意义。文中综述了吲哚从生物代谢到信号传递的研究历史,及其在微生物种内或种间以及微生物-动植物之间跨界的信号传导与调控作用的研究进展,旨在为揭示复杂环境中吲哚生物代谢及信号调控的生物学意义与生态学机制提供重要的理论指导。     

海蜇(Rhopilema esculentum)even-skipped基因的克隆及生物信息学分析

Even-skipped(eve)是一个含有同源框结构域的转录调控因子,在体节形成、神经分化、尾芽发育等过程中发挥着重要作用.为探究eve在钵水母变态发育中的作用,本研究以海蜇转录组测序获得的eve基因类似序列为基础,通过RACE技术获得了海蜇eve基因(ReEve)的cDNA全长,并已提交GenBank数据库,登录号为MN836581.结果显示ReEve基因全长1 566 bp,开放阅读框(ORF)为630 bp,所编码蛋白质含209个氨基酸,其分子量(MW)为24.29 kD,理论等电点(pI)为8.90.在二级结构上,无规则卷曲为ReEve蛋白最主要的结构形式.ReEve蛋白是一个亲水性蛋白质,不存在跨膜区域,不含信号肽.在第76～135位氨基酸之间具有eve相关基因家族特有的同源框结构域(homeodomain),与其他物种具有较高同源性.基于氨基酸序列获得的系统进化关系显示与传统分类结果一致.研究结果为进一步揭示其在海蜇等钵水母横裂生殖中的具体作用提供了一定基础.     

拟柄突和平水母在中国的首次发现及其生活史观察

报道青岛海洋科技馆培养的和平水母属(软水母亚纲,和平水母科)一种我国的新纪录--拟柄突和平水母西 Eirene lacteoides Kubota and Horita,1992.首次提供该种水母水螅体的形态,并对各期水母体的特征进行描述,为编写水螅水母动物志提供参考.     

Indomethacin induction of metamorphosis from the asexual stage to sexual stage in the moon jellyfish, Aurelia aurita

We found while screening a chemical library that indomethacin, an inhibitor of prostaglandin biosynthesis, induced strobilation (metamorphosis from the asexual to sexual stage) in the moon jellyfish, Aurelia aurita. Indomethacin initiated strobilation in a dose-dependent manner, but was not involved in the progression of strobilation. Pharmacological experiments suggested that indomethacin could induce strobilation independently of prostaglandin biosynthesis.     

Evolution and development of scyphozoan jellyfish

Scyphozoan jellyfish, or scyphomedusae, are conspicuous members of many ocean ecosystems, and have large impacts on human health and industry. Most scyphomedusae are the final stage in a complex life cycle that also includes two intermediate stages: the larval planula and benthic polyp. In species with all three life‐cycle stages, the metamorphosis of a polyp into a juvenile scyphomedusa (ephyra) is termed strobilation, and polyps can produce one ephyra (termed monodisc strobilation) or many ephyrae (termed polydisc strobilation). In contrast to species with planula, polyp and medusa stages, a handful of scyphozoan species possess modified life cycles with reduced or absent stages. The evolutionary patterns associated with strobilation and life‐cycle type have not been thoroughly investigated, and many studies of ephyra development and strobilation induction are not yet synthesized. Herein, I place the development of scyphomedusae in an evolutionary context. I first review the current evolutionary hypotheses for Scyphozoa. Next, I review what is known about scyphomedusa development across a broad diversity of species, including the first signs of strobilation, the formation of strobila segments, and the morphogenesis of ephyrae. I then review cases where the canonical scyphozoan life cycle has been modified, and take advantage of phylogenetic hypotheses to place these observations in an evolutionary context. I show that the evolution of monodisc strobilation occurred at least twice, and that the loss of intermediate life‐cycle stages occurred several times independently; by contrast, the reduction of the medusa stage appears to have occurred within a single clade. I then briefly review the major natural cues of strobilation induction. Finally, I summarize what is currently known about the molecular mechanisms of strobilation induction and ephyra development. I conclude with suggestions for future directions in the field.     

Molecular characterization of aspartylglucosaminidase,a lysosomal hydrolase upregulated during strobilation in the moon jellyfish,Aurelia aurita

The life cycle of the moon jellyfish, Aurelia aurita, alternates between a benthic asexual polyp stage and a planktonic sexual medusa (jellyfish) stage. Transition from polyp to medusa is called strobilation. To investigate the molecular mechanisms of strobilation, we screened for genes that are upregulated during strobilation using the differential display method and we identified aspartylglucosaminidase (AGA), which encodes a lysosomal hydrolase. Similar to AGAs from other species, Aurelia AGA possessed an N-terminal signal peptide and potential N-glycosylation sites. The genomic region of Aurelia AGA was approximately 9.8 kb in length and contained 12 exons and 11 introns. Quantitative RT-PCR analysis revealed that AGA expression increased during strobilation, and was then decreased in medusae. To inhibit AGA function, we administered the lysosomal acidification inhibitors, chloroquine or bafilomycin A1, to animals during strobilation. Both inhibitors disturbed medusa morphogenesis at the oral end, suggesting involvement of lysosomal hydrolases in strobilation.     

Artificial warming increases size at metamorphosis in plateau frogs (Rana kukunoris) in the presence of predators

Global warming may induce significant changes in species life history traits particularly in amphibians, which are characterized by complex and plastic life cycles. Because both warming and predators are often suggested to reduce size at metamorphosis in amphibians, we hypothesized that the size at metamorphosis was further reduced by experimental warming in the presence of predators. We conducted a factorial-designed experiment involving two factors and two levels (warmed vs. ambient, lethal predator absence vs. presence, resulting in four treatments) using Rana kukunoris tadpoles in the eastern Tibetan Plateau, and we examined its behavioral, growth, and developmental responses to warming in the presence and absence of predatory beetles (Agabus sp.) for 13 weeks. During the course of the experiment, a similar level of tadpole mortality due to the diving beetles was found between ambient and warmed treatments, but the warming effect on size at metamorphosis depended on whether the predators were present or absent. In the absence of predators, warming did not significantly increase tadpole growth but advanced the timing of metamorphosis, such that size at metamorphosis of forelimb emergence and tail resorption was much reduced in terms of body fresh weight. In the presence of predators, warming increased tadpole growth rate much more than the development rate (as reflected by duration of the tadpole stage), and therefore the size at metamorphosis was significantly increased. The significant effect of the interaction between predator and warming on the size at metamorphosis could be attributed to the tadpole response in the frequencies of feeding, resting, and swimming to the predator activity level, which was in turn increased by warming. We suggest that warming-induced changes in life history traits should be studied in relation to species interaction so as to accurately predict ecological response of amphibians to the future warmed world.     

Ontogenetic changes in the ecological function of the association behavior between jack mackerel <Emphasis Type="Italic">Trachurus japonicus</Emphasis> and jellyfish

Commensal behavior of jack mackerel Trachurus japonicus (Temminck & Schlegel) with jellyfishes has been widely observed but its ecological function is still unclear. The goal of the present research is to examine the function of association behavior with jellyfish in the laboratory and in field observations with an emphasis on ontogenetic changes. In the laboratory, jack mackerel juveniles (mean standard length (SL) = 11, 19, 38, and 55 mm) were placed in 500-l polycarbonate tanks with two live moon jellyfish, Aurelia aurita (Linné), and one artificial jellyfish made of silicon. Association behavior with either live or artificial jellyfish was visually observed under the following conditions: control, presence of a predator model, before and after feeding live Artemia, 1 h and 3 h after feeding, and at night. Jack mackerel at 11 mm SL associated with both the moon jellyfish and artificial jellyfish, unrelated to the presence of a predator model or feeding. Juveniles at 19 mm associated with moon jellyfish only in the presence of a predator model. Larger juveniles associated with moon jellyfish at 1 h and 3 h after feeding. Thus the ecological function of association was proposed to develop first from school formation, next as a hiding place from predators, and then as a food source. Underwater observations of jack mackerel associating with giant jellyfish Nemopilema nomurai (Kishinouye) in two different areas in the Sea of Japan supported this hypothesis. High predation pressure from benthic piscivorous fishes in the southern area (Tsushima) may encourage association with jellyfish, whereas pressure from pelagic predators in the northern area (Maizuru) may encourage settlement to rocky reef habitats in temperate waters. Thus the jellyfish may also function as a vehicle for the northward migration of this species. Guest editors: K. A. Pitt & J. E. Purcell Jellyfish Blooms: Causes, Consequences, and Recent Advances     

Structural and Developmental Disparity in the Tentacles of the Moon Jellyfish Aurelia sp.1

Tentacles armed with stinging cells (cnidocytes) are a defining trait of the cnidarians, a phylum that includes sea anemones, corals, jellyfish, and hydras. While cnidarian tentacles are generally characterized as structures evolved for feeding and defense, significant variation exists between the tentacles of different species, and within the same species across different life stages and/or body regions. Such diversity suggests cryptic distinctions exist in tentacle function. In this paper, we use confocal and transmission electron microscopy to contrast the structure and development of tentacles in the moon jellyfish, Aurelia species 1. We show that polyp oral tentacles and medusa marginal tentacles display markedly different cellular and muscular architecture, as well as distinct patterns of cellular proliferation during growth. Many structural differences between these tentacle types may reflect biomechanical solutions to different feeding strategies, although further work would be required for a precise mechanistic understanding. However, differences in cell proliferation dynamics suggests that the two tentacle forms lack a conserved mechanism of development, challenging the textbook-notion that cnidarian tentacles can be homologized into a conserved bauplan.     

Metamorphosis of the amphibian eye

For many metamorphosing amphibians, the visual system must remain functional as the animal changes from an aquatic to a terrestrial habitat. Thyroid hormone, the trigger for metamorphosis, brings about changes at all levels of the animal, and profoundly alters the visual system, from cellular changes within the eye to new central connections subserving the binocular vision that develops during metamorphosis in some species. I will survey the alterations in the visual system in the metamorphosis of several Amphibian groups, and consider the role of thyroid hormone in bringing about these transformations through action at the molecular level.     

Environmental control of phase transition and polyp survival of a massive-outbreaker jellyfish

A number of causes have been proposed to account for the occurrence of gelatinous zooplankton (both jellyfish and ctenophore) blooms. Jellyfish species have a complex life history involving a benthic asexual phase (polyp) and a pelagic sexual phase (medusa). Strong environmental control of jellyfish life cycles is suspected, but not fully understood. This study presents a comprehensive analysis on the physicochemical conditions that control the survival and phase transition of Cotylorhiza tuberculata; a scyphozoan that generates large outbreaks in the Mediterranean Sea. Laboratory experiments indicated that the influence of temperature on strobilation and polyp survival was the critical factor controlling the capacity of this species to proliferate. Early life stages were less sensitive to other factors such as salinity variations or the competitive advantage provided by zooxanthellae in a context of coastal eutrophication. Coherently with laboratory results, the presence/absence of outbreaks of this jellyfish in a particular year seems to be driven by temperature. This is the first time the environmental forcing of the mechanism driving the life cycle of a jellyfish has been disentangled via laboratory experimentation. Projecting this understanding to a field population under climatological variability results in a pattern coherent with in situ records.