Development of eggs and nauplii of Euphausia superba

Summary The development of eggs and nauplii was studied over 19 days. At 1.5°C nauplii hatched after 5 days. Abdominal spines changed their appearance successively during nauplius development, but no moulting was observed in the course of naupliar development. Moulting occurred between the nauplius and the metanauplius stage 13 days after spawning. Swimming activity was weak in the nauplius, while it was vigorous in the metanauplius. A model is presented for the depth distribution of eggs and larval stages. It is also suggested that present collection techniques may inadequately sample eggs and nauplii based on experiments that show that eggs are extremely sensitive to sieving.     

双斑蟋的胚胎发育

为了从组织胚胎学角度探究昆虫胚胎发育过程,以双斑蟋Gryllus bimaculatus de Geer的卵为实验材料,通过观察、记录蟋蟀胚胎每一天的形态变化并使用显微摄影方法记录胚胎发育过程,对蟋蟀卵胚胎发育全过程进行系统的观察和研究。根据胚胎形态的发育特点,可将整个胚胎发育过程分为7个阶段:卵裂期、囊胚期、原肠胚、无节幼体期Ⅰ、无节幼体期Ⅱ、无节幼体期Ⅲ、无节幼体期Ⅳ。经历14天,蟋蟀的头部、触角、3对足、尾部、腹部及背部都发育完全,整个胚胎发育随之结束。     

Hatching mechanism and delayed hatching of the eggs of three broadcast spawning euphausiid species under laboratory conditions

Three different egg hatching mechanisms were observed underlaboratory conditions in Euphausia pacifica Hansen, Thysanoessaspinifera Holmes and Thysanoessa inspinata Nemoto: backward,forward and flipping. Like all broadcast spawning euphausiids,these species usually hatch as nauplius 1 (N1). Some hours beforehatching the vitelline membrane breaks and the embryo is freelysuspended within the chorion; later the embryo takes on a slightlyoval shape. When ready to hatch, the N1 pushes against the chorionwith the posterior part of the abdomen producing a protuberance.No spine or egg tooth is present to break the chorion. The pressurebreaks the chorion, and the nauplius pushes itself backwardswith the first and second antennae and mandible to slide fromthe chorion. After about three quarters of the body is outside,the nauplius brings all the appendages together to move backwardswithout becoming stuck in the chorion. This is the backwardhatching mechanism. The vitelline membrane remains within theegg after the nauplius leaves the chorion. Hatching takes 5–20s, and most of the eggs in a clutch hatch during <2 h. Severaleggs of E. pacifica hatched as meta-nauplii (MN) (>200 hafter spawning) or as calyptopis 1 (C1) stage (>232 h), ratherthan as N1. Delayed hatching of embryos also was observed inT. spinifera as nauplius 2 (N2) (>120 h) or as MN stage (>180h), and in T. inspinata as N2 (106 h) after spawning. Eggs withlarvae in stages of development beyond N1 have not been observedfrom preserved zooplankton samples. However, eggs spawned inthe field and incubated in the laboratory also had extendeddevelopment and late hatching but with low frequency (<0.06%).It is proposed that, if the backward hatching mechanism fails,alternate hatching mechanisms can be used by the euphausiid.There is high flexibility in their hatching modes. The N2 andMN break the chorion with the first and second antennae, hatchingforwards, and the C1 breaks it with the telson spines and byflipping of the abdomen, resembling the decapod hatching mechanism.Delayed hatching using the forward and flipping mechanisms wereassociated with low hatching success in comparison with thebackward hatching mechanism.     

锦绣龙虾人工繁殖和胚胎发育的研究

锦绣龙虾(Panulirus ornatus)是世界名贵的经济虾类, 也是我国捕捞和养殖的大型虾类, 但资源匮乏,育苗还没有取得成功, 因此, 需要开展人工繁殖研究以保护和增殖资源。实验用人工养殖26 月龄的锦绣龙虾进行人工繁殖和胚胎发育研究, 结果表明, 锦绣龙虾在5 个月内繁殖2 次。切除锦绣龙虾单侧眼柄能加速其性腺发育, 在第一和第二次繁殖中, 切除眼柄的雌龙虾比对照组的卵巢成熟时间分别缩短17.7d 和11.3d。锦绣龙虾在交配后1—10d 内产卵。锦绣龙虾切除眼柄与否对怀卵量没有显著影响。第一、二次繁殖平均产卵量分别为40.34×104 粒和32.97×104 粒, 平均孵化率分别为77.29%和77.72%, 孵化出叶状幼体平均数量分别为31.38×104/尾和25.62×104/尾。锦绣龙虾的胚胎发育分为11 个时期: 受精卵、卵裂期、囊胚期、原肠期、膜内无节幼体期、七对附肢期、九对附肢期、十一对附肢期、复眼色素形成期、准备孵化期和孵化期。在水温29.2℃, 盐度30, 受精卵经22—23d 孵化出叶状幼体。       

The effect of temperature on the growth,development and survival of Macropetasma africanus (Balss) (Penaeoidea:Penaeidae) larvae reared in the laboratory

Macropetasma africanus (Balss) has been successfully spawned and its larvae reared under controlled laboratory conditions. The relationship between egg number (E) and female total length (L) was E = 18.59 L^2.11. An experiment was designed to test the effect of temperature on larval development, survival and growth. Temperature effected larval development time, from 13–15 days at 25°C, to 25 days at 15°C (nauplius 1 to post-larva). Mortality was low for the naupliar stages at 25, 22 and 18°C, while at 15°C only 52% of the larvae reached nauplius 6. Mortality was highest from nauplius 6 to protozoea 1 (17, 21, and 18% at 25, 22, and 18°C, respectively), but decreased considerably for all temperatures once the mysis stage was reached. Overall survival rates from nauplius 1 to post-larva decreased with decreasing temperature (65, 54, 48, and 39% at 25, 22, 18, and 15°C respectively). Temperature also significantly affected larval growth. At 25°C mean total length was significantly (P < 0.05) larger than at 15°C (protozoea 2 to post-larva), while from protozoea 3 to post-larva total length differences were significantly different (P < 0.05) between 18 and 25°C. M. africanus has a major spawning peak in summer, suggesting that there may be a selective advantage to reproducing during the warmer months.     

Embryo and early larval stages of the Humboldt Current krill Euphausia mucronata (Crustacea: Euphausiacea)

The Humboldt Current krill, Euphausia mucronata (Crustacea: Euphausiacea), is an endemic and keystone species in the food web of this highly productive eastern border current ecosystem. The morphology and ontogeny of E. mucronata is known from calyptopis I to the adult phase, but the embryonic and early‐life stages (nauplius and metanauplius) of this broadcast spawning species are unknown. We describe the morphology and development time of these life stages to complete the knowledge of its life cycle. Embryos were obtained from purple‐gonad gravid females collected off Dichato, central Chile, during November 2012. Eight gravid females (mean=16 mm total length) were incubated in seawater at 12°C under laboratory conditions. The average development time from single‐cell embryos to the metanauplius stage was 2.2 d and hatching occurred between 20 and 25 h. The average growth rate was 0.35 mm d^?1 from the late limb bud to the metanauplius stage (range=0.21–0.48 mm d^?1). Embryos of E. mucronata had a mean chorion diameter of 0.460 mm, embryo diameter of 0.343 mm, and perivitelline space of 0.056 mm. Our biological information reported here constitutes a baseline for future ecological studies on distribution and temporal variability of spawning activity and reproductive strategies of E. mucronata in the highly variable and productive Humboldt Current ecosystem.     

Phylogenetic implications of the Crustacean nauplius

The plesiomorphic mode of crustacean development is widely accepted to be via a larva called the nauplius. Extant taxa like the Cephalocarida, Branchiopoda, Ostracoda, Mystacocarida, Copepoda, Cirripedia, Ascothoracida, Facetotecta, Euphausiacea and Penaeidea hatch from an egg as a free-living nauplius. Other crustaceans show an embryonic phase of development suggestive of a naupliar organization. Several features of the nauplius larva have been proposed as diagnostic characters for the Crustacea: a median (nauplius) eye; at least three pairs of head appendages (antennules, antennae, mandibles); a posteriorly directed fold (the labrum) extending over the mouth and a cephalic (nauplius) shield. The relationship between trilobite protaspis with at least four appendages and the crustacean nauplius remains unclear, but reports of a copepod orthonauplius with four appendages are rejected. Swimming is suggested to represent the underived mode of locomotion for the crustacean nauplius, and that naupliar swimming directly results in naupliar feeding which also is underived.     

The embryonic development of the Mediterranean freshwater crab, Potamon edulis (=P.fluviatile) (Crustacea, Decapoda, Potamonidae)

The mating of the crabs is described. The incubation period of the macrolecithal egg of the freshwater crab, Potamon edulis (Latr.) is 46 ± 1 days long. One of the main features of the development of the egg is its extreme abbreviation. In addition to the nauplius, metanauplius, and zoea, the megalopa stage is also imprisoned in the egg. The extent to which direct development is carried in Potamon is unique among the Brachyura. This is considered to have been a pre-adaptation to the colonization of a freshwater habitat by the Potamonidae.     

The ontogenesis of catabolic abilities and energy metabolism during endogenous nutritional periods of tongue sole,Cynoglossus semilaevis

The ontogenesis of catabolic abilities and energy metabolism during endogenous nutritional periods of tongue sole was investigated. In this work, trypsin-like proteases (TRY) and triglyceride lipase (LIP) activities were measured to assess the capacities to catabolize proteins and lipids, respectively. Meanwhile, specific enzymes including pyruvate kinase (PK), glutamic oxalo acetic transaminase (GOT) and glutamate dehydrogenase (GDH), and hydroxyacyl CoA dehydrogenase (HOAD) as well as their ratios were assayed to evaluate the abilities to use energy substrates of carbohydrates, amino acids and fatty acids, respectively, for energy production. In addition, activities of citrate synthase (CS) and lactate dehydrogenase (LDH) and LDH/CS ratio were calculated to analyse the evolution of aerobic and anaerobic pathways. The study found that hatching occurred at 38.8 h after fertilization (HAF), mouth-opening day of eleuteroembryo appeared at 3 days after hatching (DAH), and the most rapid embryonic growth was observed in blastula stage before hatching. Enzymatic assay revealed that except for PK which appeared in cleavage stage onwards, all the other enzymes functioned after fertilization, preparing well for the coming embryogenesis of tongue sole. By comparing the average specific activity of enzyme in each period, it can be found that the highest value occurred at 3 DAH (for TRY, LIP, PK and LDH), 2 DAH (for GDH), fertilized egg (for GOT) and segmentation stage (for HOAD and CS), and the lowest value occurred at fertilized egg (for HOAD, CS and GDH), cleavage stage (for TRY, PK and LDH), gastrula stage (for GOT) and hatching day (for LIP). Based on the changeable patterns of metabolic enzymatic activities and ratios, it is concluded that metabolic capacities on three energy substrates displayed stage-specific traits, and the dominant energy substrate was fatty acids before segmentation stage, amino acids until hatching day and carbohydrate during eleuteroembryo period. As for energy production mode, aerobic pathway appeared to increase greater in fertilized egg and gastrula stage, whereas anaerobic pathway played a predominant role during cleavage stage, blastula stage, segmentation stage and eleuteroembryo stage. These results are valuable to elucidate the nutritional requirements of embryonic stages in tongue sole and to further understand their energy metabolic mechanisms.     

Embryonic development clarifies polyphyly in ostracod crustaceans

The present study describes the embryonic developmental process of the bioluminescent ostracod crustacean Vargula hilgendorfii . Optical microscopy, scanning electron microscopy, DAPI staining and video recording were used for observations. This study is the first detailed report of the embryonic development of a myodocopid ostracod. Contrary to previous studies, cleavage occurred in the yolk sphere and no evident cleavage furrow was found. No nauplius stage was found, and five pairs of appendages developed simultaneously. A bivalved carapace developed from two independent buds of the carapace valves. The buds of the left and right valves are enlarged, and become combined. The combined 'one-piece' carapace was divided by the formation of a hinge, and the usual bivalved carapace was formed. On the 16th day, embryos hatched as juveniles with six pairs of appendages, a pair of immature appendages, a pair of compound eyes, a median eye and a bivalved carapace. An important suggestion for the classification of Ostracoda is derived from the observed development of appendages and carapace, because the subclass Ostracoda is defined mainly by the similarities of appendages and the bivalved carapace. The present observations clearly show that the developmental process of Myodocopa differs from that of Podocopa, and supports polyphyly of the Ostracoda.     

红螯螯虾胚胎发育的研究:Ⅱ.消化系统的发生

应用组织切片技术 ,研究了红螯螯虾胚胎发育过程中消化系统的发生。红螯螯虾的消化系统由前肠、中肠和后肠 3部分组成 ,前肠和后肠由外胚层形成 ,而中肠源自原肠期由胚胎表面向囊胚内迁移的中内胚层细胞团。前无节幼体期前肠开始发生 ,至后无节幼体期先后形成口道、食道和胃等结构 ;中肠起始于后无节幼体期的次级卵黄锥 ,包括管状中肠和 1对囊状消化腺 -中肠腺 ;后肠端部是前无节幼体期形成的肛道 ,肛道不断向胚胎前端延伸逐渐形成后肠     

Structural and ultrastructural analysis of embryonic development of Prochilodus lineatus (Valenciennes, 1836) (Characiforme; Prochilodontidae)

This survey was performed to characterize the embryogenesis of Prochilodus lineatus. Seven stages of embryo development were identified--zygote, cleavage, blastula, gastrula, segmentation, larval and hatching--after a period of incubation of 22 h (24 degrees C) or 14 h (28 degrees C). The following cleavage pattern was identified: the first plane was vertical (2 blastomeres); the second was vertical and perpendicular to the first (4 blastomeres); the third was vertical and parallel to the first (4 x 2); the fourth cleavage was vertical and parallel to the second (4 x 4); the fifth was vertical and parallel to the first (4 x 8); and the sixth cleavage was horizontal (64 blastomeres). At the blastula stage (3.0-4.0 h (24 degrees C); 1.66-2.0 h (28 degrees C)) irregular spaces were detected and periblast structuring was initiated. At the gastrula stage (4.0-8.0 h (24 degrees C); 3.0-6.0 h (28 degrees C)) the epiboly, convergence and cell movements, as well as the formation of embryonic layers, had begun. The segmentation stage (10.0-15.0 h (24 degrees C); 7.0-10.0 h (28 degrees C)) was characterized by a rudimentary formation of organs and systems (somites, optic vesicle and intestinal delimitation). The embryo at the larval stage (16.0-21.0 h (24 degrees C); 11.0-13.0 h (28 degrees C)) showed a free tail, more than 25 somites, an optic vesicle and a ready-to-hatch larval shape. The blastomeres at cleavage stage had disorganized nuclei indicating high mitotic activity. At gastrula, the blastomeres and the periblast had euchromatic nuclei and a large number of mitochondria and vesicles. The yolk was organized into globose sacs, which were dispersed into small pieces prior to absorption.     

The Spawning and Early Development of the Hawaiian Acorn Worm (Hemichordate), Ptychodera flava

The spawning and early embryogenesis of the hemichordate, Ptychodera flava, in Hawaii are described in detail and illustrated with photographs of living material. Natural spawning in the evenings of early December was induced by a shift of seawater temperature from about 22 degrees C to about 26 degrees C. The fertilized egg divides equally and slowly at first, reaching 8 cells at about 5 hr after insemination at room temperature (20-24 degrees C). Divisions then appear to become slightly unequal and by 9 hr the embryo has divided into about 100 cells. The blastocoel forms during cleavage as an irregular space that, when viewed from the side, tends to appear oblate and ultimately appear crescent-shaped as the vegetal plate thickens into the blastocoel. The archenteron forms at about 18 hr as a cleft beginning at the vegetal pole and extending into the vegetal plate. As development proceeds, the embryo expands and by 24 hr forms a typical deuterostome gastrula with an outer sphere of ectoderm and a inner tube of endoderm connected at the blastopore. An out-pocketing of the gut appears at the tip of the archenteron over the next 4 hr to form the protocoel which will become the proboscis coelom. Approaching 40 hr the gut becomes asymmetric and over the next few hr contacts the ectoderm to form a mouth. Hatching occurs during this time at about 45 hr of development. Morphogenesis continues to produce an early tornaria larva by about 60 hr.     

Embryonic and larval development of the host sea anemones Entacmaea quadricolor and Heteractis crispa

Little information is available on the sexual reproductive biology of anemones that provide essential habitat for anemonefish. Here we provide the first information on the surface ultrastructural and morphological changes during development of the embryos and planula larvae of Entacmaea quadricolor and Heteractis crispa, using light and scanning electron microscopy. Newly spawned eggs of E. quadricolor and H. crispa averaged 794 microm and 589 microm diameter, respectively, and were covered by many spires of microvilli that were evenly distributed over the egg surface, except for a single bare patch. Eggs of both species contained abundant zooxanthellae when spawned, indicating vertical transmission of symbionts. Fertilization was external, and the resulting embryos displayed superficial cleavage. As development continued, individual blastomeres became readily distinguishable and a round-to-ovoid blastula was formed, which flattened with further divisions. The edges of the blastula thickened, creating a concave-convex dish-shaped gastrula. The outer margins of the gastrula appeared to roll inward, leading to the formation of an oral pore and a ciliated planula larva. Larval motility and directional movement were first observed 36 h after spawning. E. quadricolor larval survival remained high during the first 4 d after spawning, then decreased rapidly.     

Hatching mechanism and accelerated hatching of the eggs of a sac-spawning euphausiid Nematoscelis difficilis

Observation of the sac-spawning euphausiid Nematoscelis difficilisHansen during shipboard laboratory incubations showed that itsembryos usually hatch as pseudometanauplius (PMN) or metanauplius(MN). The eggs, which have a minute perivitelline space, arespherical at spawning and become elliptical after the nauplius1 develops. When ready to hatch, the PMN or MN embryos extendand contract their first and second antennae in a swimming movement,breaking the chorion into almost equal halves joined by onesmall section in the anterior part of the chorion. The mandiblesplay a secondary role in cutting the chorion. Then the embryopushes itself backwards with the first and second antennae toescape from the chorion. This is known as ‘push-off’hatching. The embryos always hatch progressively from the distalend towards the proximal end of the ovigerous sac. The timebetween hatching of the first and last embryo may reflect thetime the females require to lay a clutch of eggs (<2.1 h).Development time to the PMN stage at 10°C was     

Developmental Expression of D-Galactoside-Binding Lectin in Sea Urchin (Anthocidaris crassispina) Eggs

The spatial and temporal expression of a sea urchin (Anthocidaris crassispina) egg lectin (SUEL) during early embryogenesis was studied using antiserum raised against SUEL. Western blotting analysis revealed the presence of SUEL in all stages so far examined, from unfertilized eggs to gastrula stage embryos. Immunofluorescence and immunoelectron microscopic observation showed that SUEL was stored in small electron-dense granules which migrated to the cortex within 10 min after fertilization. SUEL was localized in the cortical cytoplasm of the blastomere during cleavage stages and subsequently migrated to the outer surface of the embryo, including the invaginated portion of the gastrula. Immunoelectron microscopic study indicated that SUEL was deposited in the hyaline layer at least at the mid gastrula stage. Migration of SUEL to the cortex was significantly reduced by treatment with cytochalasin B, suggesting that actin filaments play an important role in this translocation. Exogenously added SUEL was adsorbed at the surface of unfertilized eggs and hatched embryos, but not to embryos with fertilization membrane. Lactose inhibited this adsorption, suggesting the presence of an endogenous glycoligand(s) specific for SUEL on the surface of unfertilized eggs and in the hyaline layer. We conclude that SUEL is secreted at a certain stage of embryogenesis and specifically adsorbed to the hyaline layer. Temporal changes in extraembryonic matrices caused by SUEL seem to play an important role in developmental morphogenesis.     

Development of eggs of Antarctic krillEuphausia superba in relation to pressure

Summary This paper focuses upon the influence of increasing hydrostatic pressure on the development of krill eggs at 2°C. This experimental study on the embryology ofEuphausia superba was conducted at the Palmer Station, Antarctica during the 1982–1983 austral summer. The gravid females were captured from Bransfield Strait aboard theR/V Hero. The various embryological stages such as early cleavage, blastula, gastrula and limb-bud nauplius larva were defined and described. The duration for these various developmental stages at 1 atm was also established at +2°C and compared with the timing of this event at negative temperature. Krill embryonic development is inhibited at 4°C. The sinking rate of eggs and embryos was also measured at various pressure. The data suggest that pressure does not significantly influence the sinking rate. There appears to be a wide variation of sinking rates of eggs within the same brood. based on a simulated model of sinking rate, egg development was studied at increasing pressure. Pressure of 5–20 atm accelerates the rate of cleavage and therefore the 32-celled stage is attained within 5–8 h, while at 1 atm it took 13 h to reach the same stage. Pressure thus seems to have some influence on the duration of the development of different developmental stages of krill embryos.     

婆罗囊螺早期发育的初步研究

描述了婆罗囊螺(Retusa borneensis)从受精卵到幼虫孵化后的发育过程,婆罗囊螺为雌雄同体的一年生贝类,在浙江沿海繁殖期是6∽9月,盛期在7∽8月。婆罗囊螺为体内受精种类,胚胎发育过程为变态发育,可以分为卵裂、囊胚、原肠胚、担轮幼虫和面盘幼虫等几个阶段。个体发育从受精卵的卵裂开始,卵裂为螺旋形的全裂。卵裂不断进行,囊胚形成,后以外包和内陷方式共同形成了原肠胚。婆罗囊螺的面盘幼虫在膜内就已经形成,并且具备运动能力,但是其面盘和纤毛远没有膜外面盘幼虫发达。幼虫浮游一段时间后,就营匍匐生活,然后变态发育为稚贝。本文还就婆罗囊螺的繁殖期、繁殖力、交配产卵和繁殖特性等做了进一步的讨论。