海蜇四触手螅状体两种发生方式的观察

通过对海蜇(Rhopilema esculentum)胚胎发育和足囊萌发进行连续观察,发现海蜇四触手螅状体存在2种形成方式:第一种方式为海蜇受精卵在水温(26±1)℃条件下经6 h发育到浮浪幼虫期,浮浪幼虫25 h后经过杯状体阶段,变态发育成四触手螅状体,进入附着生活阶段;第二种方式为足囊在适宜条件下萌发,首先形成杯状...     

桃花水母生活史的实验观察

记录了中国产信阳桃花水母(Craspedacusta xinyangensis)的生活史及各阶段主要发育特征。25～28℃条件下,卵受精23h后发育成长0.14～0.21mm的圆棍状浮浪幼虫,养殖环境下,浮浪幼虫在水中漂浮3～5d后固定到人工玻璃底质上,3～4d后发育成长度0.3～0.6mm的螅状体。水螅体产生无纤毛的类浮浪幼虫形成新的螅状体。一个螅状体成熟后产生一个水母芽,新释放的幼水母具有16只触手。     

盐度对沙蜇有性繁殖阶段早期发育的影响

近几十年来,沙蜇的频繁暴发给东亚海域的海洋生态系统带来了广泛影响。在秋季,沙蜇成熟的雌雄水母体在沿岸水域聚集产卵,有性繁殖产生的受精卵发育成新的底栖螅状体,为螅状体种群数量进行补充。河口浅滩海域为沙蜇的繁育地,沿岸盐度较低,在秋季降雨期盐度多变,较低、多变的盐度可能对沙蜇有性繁殖阶段的早期发育产生重要作用,从而影响螅状体种群数量的补充。实验设置了4种不同盐度(15、20、25、30)试验组,在不同盐度下对沙蜇受精卵进行培养,探讨盐度对沙蜇早期发育过程中受精卵、浮浪幼虫发育以及早期螅状体生长及存活的影响。试验结果:沙蜇受精卵胚胎发育的适宜盐度为20,发育基本与盐度25、30同步,盐度15受精卵细胞发育迟缓,发育率显著降低;浮浪幼虫发育适宜盐度为20和25,两组浮浪幼虫附着变态率高于盐度15、30,盐度15时浮浪幼虫活力明显降低、发育迟缓,浮浪幼虫在盐度15时水中存活时间较长可达8 d,但附着时间集中在培养后的3、4天,与其他组相同;早期螅状体幼体适宜盐度为20、25、30,早期螅状体存活率、相对增长率及特定生长率均显著高于盐度15,三组间差异不显著。结果表明,盐度显著影响沙蜇有性繁殖阶段的早期发育,随着受精卵至螅状体的发育生长,其对盐度的适应范围逐步扩大。     

盐度对海蛰各发育阶段幼体的影响——兼论辽东湾海蜇资源锐减的原因

在室内控制条件下,盐度为2—31.42‰范围内,本文就盐度对海蜇(Rhopilema esculenta Kishinouye)浮浪幼虫、螅状幼体、碟状幼体和幼水母的生长、发育、变态及成活的影响进行实验研究,发现浮浪幼虫生存的盐度下限为12‰;螅状幼体生存的盐度下限为10‰;最适盐度范围为14—20‰;碟状幼体生存的盐度下限为8‰,最适盐度范围为14—20‰;幼水母生存的盐度下限为8‰。 作者根据近15年辽东湾北部主要河流的淡水注入量,海蜇产量及本实验数据,结合辽东湾曾出现过三次大减产现象分析,认为前一年夏、秋季海蜇生殖季节河流淡水注入量过多,使河口附近海蜇浮浪幼虫和螅状幼体的栖息水域盐度聚降,导致浮浪幼虫和螅状幼体毁灭性死亡,是造成海蜇资源锐减的主要原因。作者并提出采取人工培育螅状幼体,选择合适水域进行放流以补充海蜇资源,是海蜇渔业稳定和增产的主要途径。     

温度和食物水平对海月水母螅状体无性繁殖的影响

水母暴发给近岸人类的生活、渔业资源以及海洋生态系统带来影响。这些近岸海域暴发的水母可以通过有性繁殖和无性繁殖来维持或扩大水母种群数量。在水母生活史中,螅状体的无性繁殖是决定水母体数量的关键阶段,因此对此阶段进行研究。设置了4个温度水平(9、12、15、18℃)、3个食物水平(5个卤虫/螅状体、20个卤虫/螅状体、40个卤虫/螅状体),在12个组合条件下研究温度和食物水平对海月水母螅状体无性繁殖能力和方式的影响。研究结果表明,在海月水母螅状体繁殖子体的各种方式中,匍匐茎生殖是主要的繁殖方式,出芽生殖次之,纵向分裂以及足囊出现几率极低。食物对海月水母螅状体产生总子体数影响显著,温度的影响不显著,食物水平越高,海月水母螅状体繁殖子体的能力越强。食物和温度对螅状体发生横裂均有影响,但温度对螅状体横裂的影响更大。温度对螅状体的横裂率影响显著,食物影响不显著。碟状体的释放发生在12、15、18℃的条件下,温度是影响海月水母螅状体通过横裂生殖释放碟状体数量的最重要因素。可见在螅状体无性繁殖阶段,温度和食物对繁殖方式的影响各不相同。     

水螅异常极性体轴的形成及矫正进程的观察

目的:如何建立和维持体轴是一个基本的发育生物学问题,而淡水水螅是适合进行形态发生和个体发育调控机制研究的重要模式生物。本文观察了大乳头水螅异常极性体轴的形成及矫正进程,初步探讨水螅极性体轴的维持和调控机制。方法:先切取水螅的整个头部,再获得带二根触手的口区组织。通过ABTS细胞化学染色法检测水螅基盘分子标志物过氧化物酶的表达,判别水螅基盘组织(水螅足区的末端)是否形成。结果:从40块口区组织再生得到的水螅个体中有1例极性体轴发育异常的个体,其身体两端均发育成头区,且两端的头区均具有捕食能力。随后水螅其中一端头区的触手逐渐萎缩、退化,最终该端头区转化成具有吸附能力的基盘组织。结论:水螅组织的再生涉及极性体轴的重建,而一些特殊因素可能造成临时性的水螅极性体轴调控紊乱。本研究表明水螅具备自我矫正异常极性体轴的能力。另外,本研究结果显示水螅触手可以萎缩直至退化,该现象涉及的细胞学过程可能是非常复杂的,有可能涉及到触手细胞的凋亡转化过程,也可能是触手的高度分化细胞仍然具备去分化能力、去分化后再转移到身体其他地方,其具体机制值得进一步探究。     

白色霞水母生活史的实验室观察

本文首次描述了白色霞水母从受精卵至碟状体的生活史。(1)包括受精卵、卵裂、囊胚以及浮浪幼虫等在内的胚胎发育各期均在开放的水体中,在20·8 -21·4℃浮浪幼虫于受精后14 h出现; (2)浮浪幼虫在定置前形成一种凸面的圆形浮浪幼体囊,除了浮浪体囊外,螅状体还可产生足囊和通过产生匍匐茎形成囊胞进而发育成新的螅状体; (3)尽管偶而产生2个碟状体但仍为典型的单碟型横裂; (4)新释放的碟状幼体绝大多数为8个缘叶, 8个感觉棍和8对钝圆的缘瓣,但畸形个体最多12个,最少6个缘叶; (5)雌雄个体间的交互作用对产卵和受精是非常重要的因子[动物学报52 (2) : 389 -395 , 2006]。     

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。     

环境因子对海月水母生长发育影响的研究进展

海月水母是一种广泛分布的世界性近岸种,也是我国近海海域大型水母优势种之一.近年来海月水母在世界各地频繁暴发,对海洋生态系统和沿岸经济、社会发展带来了很大危害.海月水母有复杂的生活史(营附着生活的螅状体世代和营浮游生活的水母体世代)和多种无性生殖(出芽生殖、横裂生殖、足囊生殖等)及有性生殖方式.环境因子影响海月水母生活史的各个阶段,如浮浪幼虫阶段、螅状体阶段、碟状体阶段等.这些生长阶段尤其是早期生长阶段的状态(如附着、分布、扩散等)会进一步影响海月水母的种群动态.本文以海月水母生活史为主线,系统总结分析了国内外关于环境因子对其生活史各阶段的影响,提出了一些值得进一步深入研究的问题,以期为我国近海海域水母暴发关键因子的研究提供借鉴.     

河川沙塘鳢视觉器官的发育及其与摄食的关系

利用光学显微镜观察了河川沙塘鳢(Odontobutis potamophila)视觉器官的发育,并对其发育与摄食的关系进行了研究。河川沙塘鳢的眼囊起源于神经外胚层。当胚胎发育至心跳期时,眼囊内陷形成视杯;之后,视杯内表面的外胚层形成晶状体而与视杯分离,视杯进一步发育形成视网膜。随着胚胎的进一步发育,晶状体的直径增加,结构逐步发育完善。胚胎发育至眼黑色素出现期时,视网膜分化为6层,其中,外核层、内核层和神经节细胞层3个核层明显;胚胎发育至孵化前期时,视网膜已分化为10层。孵出后1d的仔鱼,其视网膜已能行使功能,仔鱼逐渐开口摄食。随着稚、幼鱼的发育,视网膜厚度进一步增加,结构发育完善。视网膜的结构和视觉特性显示河川沙塘鳢是要求光照条件好、白昼活动并具有较好视觉功能的鱼类。     

Embryonic development and metamorphosis of the scyphozoan <Emphasis Type="Italic">Aurelia</Emphasis>

We investigated the development of Aurelia (Cnidaria, Scyphozoa) during embryogenesis and metamorphosis into a polyp, using antibody markers combined with confocal and transmission electron microscopy. Early embryos form actively proliferating coeloblastulae. Invagination is observed during gastrulation. In the planula, (1) the ectoderm is pseudostratified with densely packed nuclei arranged in a superficial and a deep stratum, (2) the aboral pole consists of elongated ectodermal cells with basally located nuclei forming an apical organ, which is previously only known from anthozoan planulae, (3) endodermal cells are large and highly vacuolated, and (4) FMRFamide-immunoreactive nerve cells are found exclusively in the ectoderm of the aboral region. During metamorphosis into a polyp, cells in the planula endoderm, but not in the ectoderm, become strongly caspase 3 immunoreactive, suggesting that the planula endoderm, in part or in its entirety, undergoes apoptosis during metamorphosis. The polyp endoderm seems to be derived from the planula ectoderm in Aurelia, implicating the occurrence of “secondary” gastrulation during early metamorphosis.     

On some features of embryonic development and metamorphosis of Aurelia aurita (Cnidaria, Scyphozoa)

Aurelia aurita is a cosmopolite species of scyphomedusae. Its anatomy and life cycle are well investigated. This work provides a detailed study on development and structure of A. aurita planula before and during its metamorphosis. Intravital observations and histology study during the settlement and metamorphosis of the planulae demonstrated that the inner manubrium lining of primary polyp (gastroderm) develops from the ectoderm of the planula posterior end. The spatial and temporal dynamics of serotonergic cells from the early embryonic stages until the formation of the primary polyp were studied for the first time. In addition, the distribution of tyrosinated tubulin and neuropeptide RF-amide at different stages of A. aurita development was traced.     

Post-embryonic larval development and metamorphosis of the hydroidEudendrium racemosum (Cavolini) (Hydrozoa,Cnidaria)

The morphology and histology of the planula larva ofEudendrium racemosum (Cavolini) and its metamorphosis into the primary polyp are described from light microscopic observations. The planula hatches as a differentiated gastrula. During the lecithotrophic larval period, large ectodermal mucous cells, embedded between epitheliomuscular cells, secrete a sticky slime. Two granulated cell types occur in the ectoderm that are interpreted as secretory and sensorynervous cells, but might also be representatives of only one cell type with a multiple function. The entoderm consists of yolk-storing gastrodermal cells, digestive gland cells, interstitial cells, cnidoblasts, and premature cnidocytes. The larva starts metamorphosis by affixing its blunt aboral pole to a substratum. While the planula flattens down, the mucous cells penetrate the mesolamella and migrate through the entoderm into the gastral cavity where they are lysed. Subsequently, interstitial cells, cnidoblasts, and premature cnidocytes migrate in the opposite direction, i.e. from entoderm to ectoderm. Then, the polypoid body organization, comprising head (hydranth), stem and foot, all covered by peridermal secretion, becomes recognisable. An oral constriction divides the hypostomal portion of the gastral cavity from the stomachic portion. Within the hypostomal entoderm, cells containing secretory granules differentiate. Following growth and the multiplication of tentacles, the head periderm disappears. A ring of gland cells differentiates at the hydranth's base. The positioning of cnidae in the tentacle ectoderm, penetration of the mouth opening and the multiplication of digestive gland cells enable the polyp to change from lecithotrophic to planktotrophic nutrition.     

Early development, pattern, and reorganization of the planula nervous system in Aurelia (Cnidaria, Scyphozoa)

We examined the development of the nervous system in Aurelia (Cnidaria, Scyphozoa) from the early planula to the polyp stage using confocal and transmission electron microscopy. Fluorescently labeled anti-FMRFamide, antitaurine, and antityrosinated tubulin antibodies were used to visualize the nervous system. The first detectable FMRFamide-like immunoreactivity occurs in a narrow circumferential belt toward the anterior/aboral end of the ectoderm in the early planula. As the planula matures, the FMRFamide-immunoreactive cells send horizontal processes (i.e., neurites) basally along the longitudinal axis. Neurites extend both anteriorly/aborally and posteriorly/orally, but the preference is for anterior neurite extension, and neurites converge to form a plexus at the aboral/anterior end at the base of the ectoderm. In the mature planula, a subset of cells in the apical organ at the anterior/aboral pole begins to show FMRFamide-like and taurine-like immunoreactivity, suggesting a sensory function of the apical organ. During metamorphosis, FMRFamide-like immunoreactivity diminishes in the ectoderm but begins to occur in the degenerating primary endoderm, indicating that degenerating FMRFamide-immunoreactive neurons are taken up by the primary endoderm. FMRFamide-like expression reappears in the ectoderm of the oral disc and the tentacle anlagen of the growing polyp, indicating metamorphosis-associated restructuring of the nervous system. These observations are discussed in the context of metazoan nervous system evolution.     

Nervous systems of the sea anemone Nematostella vectensis are generated by ectoderm and endoderm and shaped by distinct mechanisms

As a sister group to Bilateria, Cnidaria is important for understanding early nervous system evolution. Here we examine neural development in the anthozoan cnidarian Nematostella vectensis in order to better understand whether similar developmental mechanisms are utilized to establish the strikingly different overall organization of bilaterian and cnidarian nervous systems. We generated a neuron-specific transgenic NvElav1 reporter line of N. vectensis and used it in combination with immunohistochemistry against neuropeptides, in situ hybridization and confocal microscopy to analyze nervous system formation in this cnidarian model organism in detail. We show that the development of neurons commences in the ectoderm during gastrulation and involves interkinetic nuclear migration. Transplantation experiments reveal that sensory and ganglion cells are autonomously generated by the ectoderm. In contrast to bilaterians, neurons are also generated throughout the endoderm during planula stages. Morpholino-mediated gene knockdown shows that the development of a subset of ectodermal neurons requires NvElav1, the ortholog to bilaterian neural elav1 genes. The orientation of ectodermal neurites changes during planula development from longitudinal (in early-born neurons) to transverse (in late-born neurons), whereas endodermal neurites can grow in both orientations at any stage. Our findings imply that elav1-dependent ectodermal neurogenesis evolved prior to the divergence of Cnidaria and Bilateria. Moreover, they suggest that, in contrast to bilaterians, almost the entire ectoderm and endoderm of the body column of Nematostella planulae have neurogenic potential and that the establishment of connectivity in its seemingly simple nervous system involves multiple neurite guidance systems.     

Reorganization of the nervous system during metamorphosis of a hydrozoan planula

Abstract. Laser scanning confocal microscopy is used to reveal the changes that occur in the RFamide-positive nerve net as a free-swimming, solid hydrozoan planula larva is transformed into a sessile, hollow, young polyp. Seven stages of development in Pennaria tiarella are described: planula competent to metamorphose, attaching planula, disc, pawn, crown, developing polyp, and developed primary polyp. The RFamide-positive nervous system undergoes dramatic reorganization during metamorphosis: (1) larval neurons degenerate; (2) new neurons differentiate and reform a nerve net; and (3) the overall distribution pattern of the nervous system changes. This study confirms earlier observations on RFamide-positive neurons of Hydractinia which also show the loss of these cells after the onset of metamorphosis.     

The effect of larval age on developmental changes in the polyp prepattern of a hydrozoan planula

The larvae of many marine organisms including hydrozoans are lecithotrophic and will not feed until after metamorphosis. In hydrozoans the aboral region of the planula becomes the holdfast and stolon, while the oral region becomes the stalk and hydranth that grows out of the holdfast following metamorphosis. If metamorphosis is delayed, the portion of the planula allocated to form holdfast and stolon shrinks and the region that forms the hydranth increases in size. Planulae also have the ability to regenerate their polyp prepattern. When the aboral region of the planula that does not normally form a hydranth is isolated and metamorphosis is delayed, it acquires the capacity to form a hydranth from the holdfast. A relatively high proportion of entodermal cells of young planulae engage in DNA synthesis (BrdU labeling index); as planulae age, the labeling index falls close to zero. When the polyp prepattern is modified during planula regeneration, entodermal cells are induced to engage in DNA synthesis. If DNA synthesis is inhibited in planulae, the polyp prepattern changes during regeneration and age-related developmental changes in planula are inhibited, suggesting that DNA synthesis is a necessary part of the pattern respecification process.     

Pattern of cell proliferation in embryogenesis and planula development ofHydractinia echinata predicts the postmetamorphic body pattern

Summary During embryogenesis and planula development of the colonial hydroidHydractinia echinata cell proliferation decreases in a distinct spatio-temporal pattern. Arrest in S-phase activity appears first in cells localized at the posterior and then subsequently at the anterior pole of the elongating embryo. These areas do not resume S-phase activity, even during the metamorphosis of the planula larva into the primary polyp. Tissue containing the quiescent cells gives rise to the terminal structures of the polyp. The posterior area of the larva becomes the hypostome and tentacles, while the anterior part of the larva develops into the basal plate and stolon tips. In mature planulae only a very few cells continue to proliferate. These cells are found in the middle part of the larva. Labelling experiments indicate that the prospective material of the postmetamorphic tentacles and stolon tips originates from cells which have exited from the cell cycle in embryogenesis or early in planula development. Precursor cells of the nematocytes which appear in the tentacles of the polyp following metamorphosis appear to have ceased cycling before the 38th hour of embryonic development. The vast majority of the cells that constitute the stolon tips of the primary polyp leave the cell cycle not later than 58 h after the beginning of development. We also report the identification of a cell type which differentiates in the polyp without passing through a post-metamorphic S-phase. The cell type appears to be neural in origin, based upon the identification of a neuropeptide of the FMRFamide type.     

Neural system reorganization during metamorphosis in the planula larva of Clava multicornis (Hydrozoa, Cnidaria)

The planula larva of the hydroid Clava multicornis (Forskål, 1775) has a complex nervous system, characterized by the presence of distinct, anteriorly concentrated peptidergic populations of amidated neurons, presumably involved in the detection of environmental stimuli and metamorphic signals. Differently from other hydrozoan larvae in C. multicornis planulae GLW-positive cells with putative sensory role have a peculiar dome-shaped forefront organization, followed by a belt of RF-positive nerve cells. By immunohistochemistry, we investigated the transformation of the peptidergic (GLW-amide and RF-amide) larval neuroanatomy at different stages of metamorphosis and the subsequent development of the primary polyp nervous system. By terminal transferase-mediated dUTP nick end-labeling assay, apoptotic nuclei were first identified in the anterior pole of the settled larva, in the same region occupied by GLW-amide positive putative sensory cells. In primary polyps, GLW-amide positive signals first encircled the hypostome area, later extending downwards along the polyp column or upwards over the hypostome dome, whereas RF-amide positive sensory cells initially appeared at the tentacles base to later extend in the tentacles and the polyp column. In spite of the possession of distinct neuroanatomies, different cnidarian planulae may share common developmental mechanisms underlying metamorphosis, including apoptosis and de novo differentiation. Our data confirm the hypothesis that the developmental dynamics of tissue rearrangements may be not uniform across different taxa.