Ultrastructural features of the egg envelope of silver carp, <Emphasis Type="Italic">Hypophthalmichthys molitrix</Emphasis> (Osteichthyes,Cyprinidae)

Synopsis We investigated the ultrastructure of the egg membrane surface (unfertilized egg) of Hypophthalmichthys molitrix using scanning electron microscopy. The eggs of silver carp like most other teleosts are surrounded by a relatively thick egg membrane, and have a type III micropyle at the animal pole. The micropyle is almost circular in shape and the micropyle canal is located in its center. The micropyle region is not flat. Round or oval accessory pores are also observed in the canal. The surface of zona radiata is wavy and uneven with a uniform distribution of almost round pores with lips. Microvilli like structure are found in the pore opening region.     

Envelope surface ultrastructure and specific gravity of artificially fertilized Pacific cod Gadus macrocephalus eggs

The envelope surface ultrastructure and specific gravity of artificially fertilized eggs of the Pacific cod Gadus macrocephalus were examined. The unfertilized, demersal and slightly adhesive eggs of G. macrocephalus were almost spherical and had no oil globules. Wrinkled envelope surface with elaborated hexagonal reticulated patterns and type I micropyle were observed under a scanning electron microscope. The adhesiveness of the eggs was lost at the blastodermal‐cap stage after fertilization. The micropylar canal was sealed by secretion of the perivitelline fluid, and the entire surface became rough. Numerous bacilli were deposited at the micropyle and the outer envelope surface at the late germ‐ring stage and at the embryo five‐eighths around the yolk stage. The micropyle was completely deformed at the embryo seven‐eighths around the yolk stage. The specific gravity of the fertilized G. macrocephalus eggs ranged from c. 1·0316 to 1·0454. These values, however, sharply decreased towards the end stages of egg development to produce pelagic larvae. The ultrastructural changes in the micropyle and envelope surface of the G. macrocephalus eggs protected the embryo from microorganism infections and mechanical stress during the long incubation period. The adhesiveness and specific gravity of the eggs influenced their dispersion potential.     

Fine structures of the micropyles of pelagic eggs of some marine fishes

The micropyles and their surrounding structures of pelagic fish eggs of nine species were examined and compared using a scanning electron microscope (SEM). The surface of the egg membrane possesses uniformly distributed pores. However,Lateolabrax japonicus possesses a number of small knobs. The region of the micropyle of fish eggs examined is characterized by a circular elevation in which the pores are larger than those on the other parts of the egg membrane. In contrast,Kareius bicoloratus egg has no elevation and possesses uniform pores to the edge of the micropylar canal. The funnel-like structure is seen in the opening of the micropyle inSardinops melanostictus, Saurida elongata, Sillago japonica, Parapristipoma trilineatum, Hypodytes rubripinnis andK. bicoloratus. These specific features of the micropyle may be used for the identification of pelagic eggs.     

Micropylar exudates in Douglas fir – timing and volume of production

 In Pseudotsuga menziesii, a secretion fills the micropylar canal about 7 weeks postpollination until fertilization. Micropylar volumes were measured and found to show variation. Dissection of the ovuliferous scales caused excess fluid to be exuded from the micropylar canal, forming a drop at the tip of the micropyle. This drop was collected, and its production quantified in three trees. Volume and percentage of ovules with drops were greatest when the archegonia in the female gametophyte were at central cell and/or egg cell stage. The volume of exuded drops far exceeded that of the micropyle. Production of subsequent drops by the ovules further confirms that the fluid is actively produced upon dissection Received: 19 September 1998 / Revision accepted: 26 October 1998     

澳洲杨(大戟科)胚珠及其种子附属结构的个体发育研究

以澳洲杨的胚珠及其种子为材料,运用光学显微镜和电镜扫描的方法对其从胚珠发生直到种子成熟的个体发育过程和结构进行观察,同时与鸭脚西番莲的种子附属结构的发育过程进行对比研究。结果表明:(1)澳洲杨的珠孔类型为外珠孔类型,种子附属结构起源于珠孔而非珠柄,其为种阜,而非假种皮。(2)鸭脚西番莲的珠孔类型为内珠孔类型,种子附属结构起源于珠柄,并且最终将珠孔包被,其为真正的假种皮结构。通过种阜与假种皮的不同个体发育过程,建立了大戟科种阜与假种皮的不同发育模式,并对种子附属结构的生物学功能及其暗示的不同植物进化路径进行了讨论。     

Biology and Egg Morphology of The Dalmatian Barbelgudgeon Aulopyge Huegeli, An Endangered Endemic Species in Croatia

This paper describes patterns of annual and diurnal activity in the endangered endemic cyprinid Aulopyge huegeli from Croatia. The species is largely nocturnal. Spawning in the laboratory begins at temperatures of 20°C. Aulopyge huegeli is a rock and gravel brood hider. The female deposits eggs in various fissures with a special ovipositor. The eggs are whitish and have a diameter between 1.5 and 2mm. The zona radiata is relatively thin (3.2–5.5m) and provides the eggs with the necessary plasticity. The surface is covered with an attaching substance and with short attachment extension around the vegetal pole. This correlates with features of the spawning microhabitats. Aulopyge huegeli has a very small micropyle which consists of a pit with a diameter of 7.5m and a canal with a diameter of 2.5m (micropyle type I).     

家养鱼类受精生物学的研究 Ⅱ.几种淡水鱼类成熟卵球的精孔器与精子入卵通路的光镜与扫描电镜观察

作者对我国四种淡水养殖鱼类——团头鲂、草鱼、白鲢和花鲢卵球的精孔器作了光学显微镜和扫描电子显微镜的比较描述,在扫描电子显微镜下观察到这几种鱼类的精子均直接经精孔器前庭穿过精孔管进入卵内,并对精孔细胞、受精孔与精子入卵的关系以及精孔的位置进行了讨论。       

泥鳅精子入卵的动力作用

在扫描电镜下,泥鳅成熟卵卵膜孔外围呈现完整的左涡旋状结构,受精时精子是顺着涡旋的流线进入卵膜孔。涡旋纹理接近对数螺线。本文分析了真骨鱼类的受精因素,除已知的化学因素外,还存在物理因素。也讨论了泥鳅成熟卵卵膜孔形态形成的必然性。     

Observations on the seasonal breeding biology and fine structure of the egg surface in the white piranha Serrasalmus brandtii from the São Francisco River basin,Brazil

In the Juramento Reservoir, south‐eastern Brazil, the white piranha Serrasalmus brandtii showed a prolonged reproductive season, with evidence for multiple spawning and a reproductive peak associated with seasonal rains. The egg surface exhibited a honeycomb‐like pore canal arrangement and an adhesive apparatus surrounding the micropyle. Electron microscopic analysis suggests a role for the micropylar cell and neighbouring follicular cells in secretion of substances for egg attachment.     

Ultrastructure of the chorion and its micropyle apparatus in the mature Fundulus heteroclitus (Walbaum) ovum

The ovum 'membranes' and the micropyle apparatus of mature, extruded ova of Fundulus heteroclitus were examined by scanning electron microscopy. The ovum is covered by a thin jelly coat comprised of a dense mat of 0.3-0.5 urn fibrils, except for a 50–100 um fibril-free zone surrounding the micropyle apparatus. The micropyle apparatus consists of a 50–100 um diameter funnel-shaped vestibule, at the bottom of which is a circular aperture 4–5 μ in diameter leading to the micropyle canal which traverses the entire chorion layer. The inner micropyle aperture, 2–3 um diameter, apposes the inner ovoplasm mass.
The chorion is the major protective coating of the ovum. It consists of a thin (0.4 μm) outer zone, a thicker (9–12 μ), lamellated inner zone with 4–10 lamellae, and sometimes an innermost crystalline zone, varying in thickness from 1–13 μm. The extreme variability in the structure of the lamellated and crystalline zones of the chorion suggests that generalizations concerning ovum membranes can be misleading.     

大银鱼卵膜孔结构的电镜观察

扫描电镜下，大银鱼成熟卵卵膜孔区域呈现奇异的放射沟脊状结构。在授精开始的３０秒内，测得卵膜附近约８６％的精子沿着凹沟进入精孔管；还拍摄到了通过卵孔中心的纵切面映象，通过电子计算机模拟，验证了卵膜孔的这种结构，为精子的云集和进入精孔管所提供有利条件，从而，于泥鳅之后又发现了一种真骨鱼，其精子入卵除化学因素外，还存在着不容忽视的机械动力因素。     

Closure of the micropyle during embryonic development of some pelagic fish eggs

The fine structure of the egg envelope and micropyle was studied in unfertilized and developing eggs of the flounder Paralichthys olivaceus (Temminck & Schlegel), the Alaska pollack Theragra chalcogramma (Pallas), the Japanese tilefish Branchiostegus japonicus (Houttuyn) and the porgy Pagrus major (Temminck & Schlegel). The outer envelope surface of the unfertilized egg was wrinkled, while the inner surface was folded. The micropyle of the unfertilized egg consisted of a shallow vestibule and a distinct canal. The micropylar region of the inner surface of the envelope had a conical- or bowl-shaped protrusion. In developing eggs, the thickness of the envelope decreased and showed smooth outer and inner surfaces which indicated that it had been stretched tangentially at the time of the perivitelline space formation. The lumen of the micropylar canal was invariably occupied with envelope material. We postulate that the blockage of the micropylar canal is a result of the stretching of the envelope. The closure of the micropyle inhibits sperm and external pathogens from penetrating into the perivitelline space and seems to be involved in both the permanent prevention of polyspermy and the protection of the developing embryo from bacterial infection.     

Structure,ultrastructure, and histochemistry of the pollen tube pathway in the milkweed Asclepias exaltata L.

The structure of the gynoecium and pollen tube pathway in unpollinated and pollinated carpels of Asclepias exaltata L. has been characterized. Pollen tubes penetrate a dry-type stigma, grow intercellularly in a core of solid tissue in the upper style, and subsequently traverse a hollow stylar canal to the ovary where they grow across the placental epithelium to the ovule micropyles. The fine structural characteristics of transmitting cells of the solid style, stylar canal, and placental epithelium indicate a secretory function. Extracellular secretions staining positively for proteins, insoluble carbohydrates, and arabinogalactans/arabinogalactan proteins are present in the solid style, hollow stylar canal, ovary, and micropyle. Micropylar exudate is present subtending the extended cuticle of the embryo sac adjacent to the filiform apparatus of the synergids, providing ultrastructural evidence for a secretion arising from the angiosperm embryo sac.     

Ultrastructure of the micropyle and its relationship to pollen tube growth and synergid degeneration in sunflower

Summary Ultrastructural studies made on the micropyle of sunflower before and after pollination resulted in the following observations. (1) The micropyle is closed instead of a hole or canal. The inner epidermis of the integument on both sides of the micropyle is in close contact at the apex of the ovule. The boundary between the two sides consists of two layers of epidermal cuticle. (2) The micropyle contains a transmitting tissue. The micropyle is composed of an intercellular matrix produced by the epidermal cells of the integument. (3) The micropyle is asymmetrical, and is much wider on the side proximal to the funicle. On the funicle side the cells adjacent to the micropyle are similar to those of the transmitting tissue: they have large amounts of intercellular matrix and contain abundant dictyosomes, rough ER, and starch grains, and provide an appropriate environment for growth of the pollen tubes. The cells distal to the funicle are rich in rough ER and lipid bodies; they lack large intercellular spaces. (4) The micropyle is variable in the axial direction, i.e., it is much larger and more asymmetric at the level distal to the embryo sac than at a level close to the embryo sac. After pollination, one to four pollen tubes are seen in a micropyle. During their passage through the micropyle, most pollen tubes are restricted to the side proximal to the funicle. There is a greater tendency (81%) for the degenerate synergid to be located toward the funicle, i.e., at the same side as the pollen tube pathway. The data indicate a close relationship between micropyle organization, orientation of pollen tube growth, and synergid degeneration.     

尼罗罗非鱼成熟卵结构及精子入卵早期的电镜观察

用扫描电镜观察尼罗罗非鱼(Tilopia nilotica)成熟卵卵膜孔结构和精子入卵的早期情况,用透射电镜观察成熟卵皮质,可见卵膜孔包括前庭和精孔管两部分,前庭壁及壳膜外表面上有许多小孔洞,精孔管壁呈阶梯状。卵膜孔下的卵皮质是一凹陷区,这一区域存在着皮质小泡。本实验见到5种形态的皮质小泡,其中大的皮质小泡靠近质膜。     

Factors inducing closure of the micropylar canal in the chum salmon egg

The micropylar canal of the chum salmon egg was almost completely closed following egg activation caused by incubation in a hypotonic salt solution (HSS) for I h. The closure occurred in both inseminated and parthenogenetically activated eggs. Incubation of isolated envelopes from non-activated eggs in HSS or perivitelline fluid (PVF) did not induce any modification in micropylar structure, indicating that normal organization of the egg is essential for inducing closure. To reduce the volume of the perivitelline fluid, the eggs were activated in PVF or HSS containing 8 mM Dextran, Although the envelope showed hardening, closure of the micropyle was not observed in these eggs. The wall of the micropylar canal, however, possessed a slightly rough surface. Following activation in a Ca-free hypotonic salt solution with 10 mM EDTA, hardening of the egg envelope was completely inhibited. Although such eggs possessed an apparent perivitelline space, neither closure of the micropylar canal nor roughening of the canal surface were detected. We conclude that the synergistic action of perivitelline turgor pressure and perivitelline material is responsible for the closure of the micropyle.     

Morphology of unfertilized mature and fertilized developing marine pelagic eggs in four types of multiple spawning flounders

Starry flounder Platichthys stellatus, spotted halibut Verasper variegates, turbot Scophthalmus maximus, and Japanese flounder Paralichthys olivaceus are four commercially cultivated multiple spawning flounders that spawn pelagic eggs. Through appropriate light and scanning electron microscope processing, the shape and surface structures (such as micropyle, pores, pore density, and paten) of unfertilized mature and fertilized developing eggs of the four species were observed and measured. First, individual or intraspecific comparisons of the surface structures of eggs at different developmental stages were made. Second, interspecific differences among the four species at the same developmental stage of unfertilized mature eggs were statistically computed and analyzed through one-way analysis of variance and hierarchical cluster analysis. Eggs of the same species collected at different stages of development tend to be different in morphology. Smoothing of the convoluted egg envelope surface and closure of the micropyle to serve as a final step of the polyspermy-preventing reaction are common after fertilization. Based on detailed morphology of micropyle of just-mature fertilizable eggs, turbot, starry flounder, and Japanese flounder each have a micropyle with a long canal but no distinct micropylar vestibule, type III of Riehl and Götting (Arch Hydrobiol 74:393–402, 1974). In contrast, spotted halibut has a micropyle with a distinct flat micropylar vestibule and a long canal, type II. Envelope surface microstructures, especially those in the micropyle region, are useful characters for egg identification among the four species. Cluster analysis using selected egg characters indicated the highest similarity between turbot and Japanese flounder and that starry flounder is obviously more similar to turbot and Japanese flounder than to spotted halibut.     

The surface structure of Antarctic fish eggs and its use in identifying fish eggs from the Southern Ocean

Summary The surface structure of eggs of Notothenia neglecta, Nototheniops larseni, Nototheniops nudifrons (Nototheniidae), Champsocephalus gunnari and Chaenocephalus aceratus (Channichthyidae), collected near Elephant Island (Atlantic sector of the Southern Ocean) and of Notothenia rossii rossii (Nototheniidae) from Kerguelen waters (Indian sector of the Southern Ocean) was studied by scanning electron microscopy (SEM). Eggs of N. larseni differed from the other species by containing a micropyle with two micropyle pits. External morphological characteristics of the egg envelope such as the ultrastructure of the zona radiata, its interpore distances and the diameter of the micropyle were species-specific and could aid in the identification of fish eggs collected from the Southern Ocean.     

Ultrastructural features and formation of the micropylar apparatus in the cherry fly Rhagoletis cerasi

The micropylar apparatus (MA) in Rhagoletis cerasi (Diptera, Tephritidae) is located at the anterior pole of the egg and consists of two parts: an outer chorion and an inner vitelline membrane. Sperm entry takes place through the micropylar canal, 2.0–2.5 μm in diameter, which penetrates the micropylar endochorion and terminates in the thick vitelline membrane, thus forming the “pocket.” The pore of the micropylar canal, i.e., the micropyle, is covered by the exochorionic tuft. The formation of the MA is accomplished by 40 micropylar cells during oogenesis. These cells secrete the successive eggshell layers: the vitelline membrane, the wax layer, the innermost chorionic layer, the micropylar endochorion, and the exochorion. Two among 40 micropylar cells differentiate and form two tightly connected projections. The latter contain a bundle of parallel microtubules and participate in the formation of the micropylar canal and the pocket. At the tip of the projections there are two thin extensions full of microfilaments. In late developmental stages the two projections and the extensions degenerate and leave the canal and the pocket behind. We also discuss the structural features of the MA in relation to its physiology among Diptera.