中华绒螯蟹胚胎附着系统的结构和形成机制

利用透射电镜和扫描电镜技术研究了中华绒螯蟹(Eriocheir sinensis)胚胎附着系统的结构及形成机制。中华绒螯蟹受精卵附着在雌性腹肢内肢的携卵刚毛上。该附着系统由三个连续部分组成:卵膜、卵柄和被膜,后者覆盖在携卵刚毛的绒毛上。研究结果显示:中华绒螯蟹的成熟胚胎由三层明显的卵膜组成,即E1、E2和E3层,但胚胎附着系统的卵柄及被膜仅为外层(E1)。卵巢中成熟卵的卵膜仅由E1层组成,E1分为两个亚层(E1a′、E1b′)。胚胎附着系统的形成与雌蟹的行为、腹肢粘液腺分泌的粘液、卵膜的超微结构及各层的变化有关。受精卵刚从生殖孔中排出时,卵膜(E1a′、E1b′)并不能直接粘附在携卵绒毛上。产卵后不久,雌蟹腹肢粘液腺分泌粘液的量增多,E1a′、E1b′的结构发生变化,表现为边界模糊,卵膜出现很强的粘性。在产卵后约60min E1层又明显分为两个亚层(E1a、E1b),同时排卵后雌蟹腹部的携卵绒毛不断地运动,这种运动促使携卵绒毛外的被膜形成。随着E1层亚结构的变化,E2层也开始形成,当E1新的两个亚层出现时,部分区域的E1层与E2层发生分离,卵柄开始形成,并牢固地附着在携卵绒毛上。被膜、卵柄与卵膜最外层的结构相同,均由E1层构成[动物学报51(5):852-861,2005]。     

中华绒螯蟹不同发育时期胚胎及流产胚胎的同工酶变化

采用聚丙烯酰胺凝胶电泳技术,对中华绒螯蟹(Erlocheir sinensis)不同发育时期胚胎及流产胚胎的6种同工酶(乳酸脱氢酶、醇脱氢酶、苹果酸脱氢酶、酯酶、淀粉酶和过氧化物酶)进行了研究。结果表明,不同发育时期胚胎的乳酸脱氢酶、醇脱氢酶、苹果酸脱氢酶、酯酶及淀粉酶酶谱表现出一定差异。受精卵中未检测到乳酸脱氢酶同工酶活性,卵裂期和囊胚期出现4条酶带,无节幼体及溞状幼体期只有2条酶带;醇脱氢酶同工酶在中华绒螯蟹胚胎发育的各阶段均有表达,但表达的酶带数和活性有区别;在受精卵和溞状幼体期无苹果酸脱氢酶酶带显示,卵裂期酶带数最多,酶活性相对也最强,以后随着发育的进行,酶带数和酶活性都有减弱的现象;酯酶同工酶的变化较为复杂,特别是囊胚期,酯酶酶带突然全部消失;淀粉酶有两种类型：α-淀粉酶和R-淀粉酶。从受精卵发育到幼体其酶带数不增反减。不同发育阶段均检测不到过氧化物酶的活性。第二次抱卵胚胎的酶活性和酶带数低于或有别于第一次抱卵的卵裂期胚胎。流产胚胎中醇脱氢酶、乳酸脱氢酶、淀粉酶与第一次抱卵胚胎不同发育时期的酶谱相比略有变化,而苹果酸脱氢酶、酯酶酶带数迅速减少。     

中华绒螯蟹正常附着胚胎与流产胚胎的结构特点

用扫描电镜技术观察了中华绒螯蟹正常附着胚胎及流产胚胎的结构特点。结果表明,受精卵从生殖孔排出15min后,孵化室中的孵化液体积增大,使胚胎浸没在孵化液中,胚胎表面具有粘性;产卵后30min．卵柄初步形成;80～140min后卵柄完全形成,胚胎牢固地粘附在携卵绒毛上。正常胚胎的卵柄高度扭曲,上有很多毛状物,同时携卵刚毛上有很多粘液;流产胚胎的卵柄上无毛状物,但卵柄及胚胎表面有许多寄生物附着。携卵刚毛上的粘液及卵柄上的毛状物可能和胚胎附着有关;而胚胎表面寄生物的活动,可能使胚胎外被、卵柄以及卵索的结构发生变化,增加了胚胎之间的摩擦,进而胚胎呼吸困难,以致死亡和流产。     

莱氏拟乌贼缠卵腺的显微与超微结构

为了解莱氏拟乌贼(Sepioteuthis lessoniana)缠卵腺的结构和功能,本研究采用组织切片技术和透射电镜技术对该腺体进行显微与超微结构观察.结果显示,缠卵腺由腺壁组织、分泌叶瓣和结缔组织组成.其中,腺壁组织由外膜层和肌肉层组成,位于腺体外部;分泌叶瓣是腺体的主要部分,由分泌细胞和支持细胞组成,分泌细胞具有...     

腺体是如何形成的?

答:凡具有分泌机能的上皮组织称腺上皮,腺上皮的细胞称腺细胞。以腺上皮为主要成分构成的器官称为腺体。腺体是由上皮深陷或外突发育分化而形成的。在胚胎时期,由原始的上皮组织形成上皮细胞索,向深层结缔组织生长分化而形成的。根据腺体有无导管和分泌物运输的途径,腺体分为两大类:外分泌腺和内分泌腺。如果腺体有导管,腺体的分泌物可经导管排到身体表面或器官内腔,这种腺体称为外分泌腺,也称有管腺,如唾液腺、汗腺、皮脂腺、胰腺     

泥螺生殖系统的组织学

泥螺为雌雄同体。生殖系统包括交媾器和生殖器本部。交媾器包括刺激器、阴茎和摄护腺;生殖器本部主要包括两性腺、缠卵腺和蛋白腺。刺激器和阴茎都具有非常发达的肌肉组织,腔壁游离面具纤毛。阴茎腔壁为单层柱状细胞;摄护腺被膜为一层薄的肌纤维,里面具有许多分泌细胞;缠卵腺被膜为单层扁平上皮,下层为环肌,腺体组织由分泌小管构成。蛋白腺主要由皮质层和导管层组成,皮质层内充满了分泌细胞,导管层由许多分泌小管构成,管壁为柱状腺细胞。     

两种吹绵蚧蜡泌物超微结构的研究

采用扫描电镜技术研究了澳洲吹绵蚧lcerya purchase Maskell和埃及吹绵蚧Icerya aegyptiaca(Douglas)不同龄期主要泌蜡腺体和蜡泌物的超微结构.结果发现:成虫期背面的丝状蜡是由多格腺和皮毛共同分泌产生的.卵囊是由雌成虫成熟时腹部腹面的半圆形卵囊带所分泌的,也是实心丝状蜡结构.若虫期吹绵蚧背面覆盖着由多格腺分泌的丝状蜡,实心结构;腹面有长丝状的蜡质缠绕,紧贴腹面体壁的还有一层小蜡圈.     

多疣狭口蛙不同繁殖时期皮肤显微结构观察

采用常规石蜡切片及HE染色,对多疣狭口蛙不同繁殖时期背腹皮肤结构进行显微观察.结果发现:多疣狭口蛙3个不同繁殖时期皮肤结构无明显变化,其背部腺体要比腹部发达.尤其是颗粒腺,比腹部丰富.背部皮肤的色素层也比腹部发达.繁殖前期、繁殖中期粘液腺含量比繁殖后期略微多.     

康氏粉蚧蜡泌物的扫描电镜观察

采用制作玻片标本和扫描电镜技术研究了康氏粉蚧Pseudococcus comstocki(Kuwana)在不同发育阶段的显微形态特征及蜡泌物的超微形态。结果表明:三格腺是康氏粉蚧最主要的腺体,随着虫体的发育,数量增多,分布变广,每个腺孔分泌一根蜡丝,覆盖体表;管腺只在特定的时期分泌长的空心蜡管构成卵囊;多格腺分泌多棱形卷曲的小蜡丝粘附在卵粒上,防止其相互粘连。     

超声波遥测在中华绒螯蟹产卵场研究中的应用

利用一种超声波标志的体外固定方法,采用超声波遥测法,分析了抱卵中华绒螯蟹(Eriocheir sinensis)在产卵场附近水域的水平和垂直活动规律。结果表明:超声波标志的体外固定对中华绒螯蟹死亡率无显著影响(P0.05);移动追踪系统对超声波标志的最大追踪距离为532±16 m;2014年12月共放流14只超声波标志的抱卵中华绒螯蟹,12月下旬至翌年5月上旬10次追踪分别追踪到10、12、13、9、9、9、9、6、4、2只标志蟹;标志蟹主要分布在深水航道的南北两侧的堤坝附近水域,1月标志蟹出现在中游区域的频次显著大于下游区域(P0.05),随后呈逐步东移的趋势,4月出现在下游区域的频次显著大于中游区域(P0.05);标志蟹的栖息水深在不同时间之间差异极显著(P0.01),1月上旬至2月上旬标志蟹逐步由水深8.25±3.35 m的水域移至水深11.10±2.64 m的水域栖息,2月下旬至4月上旬标志蟹偏好水深6.35 m左右的水域,4月下旬标志蟹的栖息水深为9.89±2.59 m。本文成果将为水生动物的生态习性、栖息地定位等研究提供技术支持。     

中华绒螯蟹蜕皮过程中体壁结构和主要成分的变化

采用组织化学和原子吸收分析等方法, 研究了中华绒螯蟹蜕皮过程中体壁结构和主要成分的变化。结果显示: 中华绒螯蟹体壁分为上表皮、外表皮、内表皮和膜层, 糖类物质各层均有分布, 胶原纤维分布在除上表皮外的其他各层。在蜕皮前, 糖类、胶原纤维都被重吸收, 体壁上表皮和外表皮在蜕皮前形成, 内表皮和膜层在蜕皮后形成。体壁粗蛋白含量在蜕皮前期(D1-D3-4期)降低(P0.05), 蜕皮后A-B期含量极高(P0.05)。几丁质含量在蜕皮过程中变化不显著(P0.05), 只是在蜕皮前稍有上升。Ca2+和Mg2+含量在蜕皮前D1期显著低于蜕皮间期和蜕皮前其他时期(P0.05), 而蜕皮后A-B期降到最低(P0.05), 蜕下的甲壳中则含有较多的Ca2+和Mg2+ (P0.05)。Cu2+和Zn2+含量除蜕皮后A-B期升高外(P0.05), 其余时期变化不明显(P0.05)。这些研究结果表明, 中华绒螯蟹体壁结构和成分变化与蜕皮周期密切相关。       

Histochemistry of the cuticle of the crab Menippe rumphii (Fabricius) (Crustacea: Brachyura) in relation to moulting

Histological and histochemical methods have been employed to study the formation and growth of the exoskeleton in relation to the moulting cycle of the crab Menippe rumphii (Fabricius). In the premoult condition the epidermal cells secrete a two-layered cuticle. Later these layers are widened by the secretions coming from the reserve cells, tegumental glands, and the Leydig cells. The fully formed cuticle of the intermoult crab is divisible into four layers, epicuticle, exocuticle, mesocuticle, and endocuticle.Histochemical observations on different cells have revealed that the tegumental glands secrete both neutral and acid mucopolysaccharides. The reserve cells are positive to PAS, BPB, Sudan Black B and Alizarin Red S techniques indicating the presence of carbohydrates, proteins, lipids, and mineral calcium. The Leydig cells are loaded with enzymes, including alkaline phosphatase, acid phosphatase, lipase, and phenoloxidase. Other histochemical tests have been employed to investigate the formation of different layers of the cuticle.     

Structure,molting, and mineralization of the dorsal ossicle complex in the gastric mill of the blue crab,Callinectes sapidus

This study examined the mesocardiac and urocardiac ossicles in the gastric mill of the blue crab to describe its structure, mineralization, and dynamics throughout the molt cycle, and to assess its possible utility in age determination. Morphologically, the mineralized ossicles are similar to the calcified dorsal carapace having a lamellate structure comprised of sheets of chitin/protein fibrils. Staining with acridine orange showed the same arrangement of an epicuticle, exocuticle, and endocuticle. In much of the mesocardiac and urocardiac ossicles, the endocuticle is very reduced, with the exocuticle predominating; the reverse of the dimensions of the exoskeleton. The lamellate structure of the ossicles was confirmed with scanning electron microscopy; however, elemental mapping by energy‐dispersive analysis of X‐rays revealed that the ossicles are mineralized with calcium phosphate, in contrast to the calcium carbonate biomineral of the exoskeleton. The medial tooth of the urocardiac ossicle is not calcified, but the epicuticle is highly elaborated and impregnated with silica. Histological examination of the ossicles demonstrated that they are molted during ecdysis, so despite the appearance of bands in the mesocardiac ossicle, it is difficult to hypothesize how the bands could represent a record of chronological age. J. Morphol. 276:1358–1367, 2015. © 2015 Wiley Periodicals, Inc.     

Structure of the cuticle of the common house cricket with reference to the location of lipids

Cuticle segments from the thorax, abdomen, and jumping legs of the house cricket. Acheta domesticus, were examined using histological techniques for light microscopy, scanning and transmission electron microscopy, and direct examination of frozen-fractured cuticle. The surface of untreated cuticle is covered by a lipid film which obscures fine surface detail. Standard EM preparative procedures, as well as washing the cuticle with ethanol before examination, remove this film exposing previously covered openings to dermal gland ducts and wax canals. An epicuticle, exocuticle, mesocuticle, endocuticle, and a deposition layer were present in all transverse sections of cuticle. Light microscopy showed that the exocuticle and mesocuticle are heavily impregnated with lipids, whereas there is little lipid associated with the endocuticle. Frozen-fractured cuticle clearly shows the ‘plywood’ structure of the meso- and endocuticle, while the exocuticle fractures as if it were a solid sheet. The epicuticle is composed of a dense homogeneous layer, cuticulin, outer epicuticle, and the outer membrane. Superficial wax was detected only in cuticle samples prepared using vinylcyclohexane dioxide as a polar dehydrant. The results were used to construct a comprehensive model of the cuticle of A. domesticus.     

The structure and modification of integumental tissues in Pagurus bernhardus (L.) (Decapoda: Anomura)

The histological structure of cephalothoracic and abdominal integuments has been studied in the hermit crab Pagurus bernhardus (L.). In the branchial region of the carapace, the integument shows a similar structure as described hitherto in a number of other decapod species; there are a thin epicuticle, an exocuticle, and a relatively thick endocuticle, followed by a layer of columnar epithelium and underlying connective tissue. This pattern is repeated on the inner surface of the carapace fold but with generally thinner cuticular layers. Within the connective tissue there are tegumental glands, haemocytes, and some reserve inclusions. The abdominal integument shows a modified cuticle structure which is probably related to its specific function as an adhesive organ attaching the hermit crab to the inner surface of the gastropod shell. The cuticle is uncalcified and it shows deep wrinkles and grooves. Endocuticle and exocuticle are thick and layered whereas the epicuticle is very thin. Large funnel-shaped ducts with secretions occur frequently in the abdominal integument. The cells that are responsible for these secretions are described. The chemical nature of integumental structures has been studied with histochemical tests.     

Immunocytochemical localization of actin and tubulin in the integument of land crab (Gecarcinus lateralis) and lobster (Homarus americanus)

The crustacean integument consists of the exoskeleton and underlying epithelium and associated tissues. The epithelium, which is composed of a single layer of cells, is responsible for the cyclical breakdown and synthesis of the exoskeleton associated with molting (ecdysis). During premolt (proecdysis) the epithelial cells lengthen and secrete the two outermost layers (epicuticle and exocuticle) of the new exoskeleton while partially degrading the two innermost layers (endocuticle and membranous layer) of the overlying old exoskeleton. This increased cellular activity is associated with increased protein synthesis and a change in cell shape from cuboidal to columnar. The cytoskeleton, composed of microfilaments (actin) and microtubules (tubulin), plays important roles in the intracellular organization and motility of eukaryotic cells. Immunoblot analysis shows that the land crab exoskeleton contains actin, tubulin, and actin-related proteins (Varadaraj et al. 1996. Gene 171:177-184). In the present study, immunocytochemistry of land crab and lobster integument showed that both proteins were localized in various cell types, including epithelia, connective tissue, tendinal cells, and blood vessels. Muscle immunostained for actin and myosin, but not for tubulin. The membranous layer of land crab (the other layers of the exoskeleton were not examined) and membranous layer and endocuticle of lobster also reacted specifically with anti-beta-actin and anti-alpha-tubulin monoclonal antibodies, but not with an anti-myosin heavy chain antibody. During proecdysis immunolabeling of the membranous layer decreased probably due to protein degradation. The staining intensity for actin and tubulin in the proecdysial epithelium was similar to that in the intermolt (anecdysial) epithelium, suggesting that there was a net accumulation of both proteins proportional to the increase in cellular volume. These results support the previous biochemical analyses and, more specifically, localize actin and tubulin in exoskeletal structures, suggesting that they may serve both intracellular and extracellular functions in crustaceans. J. Exp. Zool. 286:329-342, 2000.     

Structure of the cuticle of the alpine weta,Hemideina maori (Saussure) (Orthoptera: Stenopelmatidae)

Sclerotized cuticle segments from the thorax, dorsal abdomen, and ventral abdomen of the alpine, weta Hemideina maori (Saussure) (Orthoptera: Stenopelmatidae) were examined by light microscopy and by scanning and transmission electron microscopy. An epicuticle, exocuticle (outer and inner), mesocuticle, endocuticle, and deposition layer are present in transverse sections. The epicuticle is further composed of a cuticulin layer and inner epicuticle, the latter being finely laminated and containing narrow wax canals that terminate below the cuticle surface. Openings to dermal gland ducts are visible on the surface as are large setae and smaller sensory pegs. Frozen fractured cuticle reveals the presence of horizontal ducts or channels that run laterally within the cuticle. The structure of weta cuticle is compared with that of the common house cricket and arthropods in general.     

Silicification of the medial tooth in the blue crab Callinectes sapidus

Observations of cuticular structures mineralized with silica within the Crustacea have been limited to the opal teeth of copepods, mandibles of amphipods, and recently the teeth of the gastric mill in the blue crab Callinectes sapidus. Copepod teeth are deposited during premolt, with sequential elaboration of organic materials followed by secretion of silica into the tooth mold. The timing of mineralization is in stark contrast to that of the general integument of crustaceans in which calcification is completely restricted to the postmolt period. To determine the timing of molt‐related deposition and silicification of the teeth of the gastric mill, the medial tooth of the blue crab C. sapidus was examined histologically and ultrastructurally across the molt cycle. Histological data revealed deposition of the organic matrix of the epicuticle and exocuticle during premolt. No evidence of postmolt changes in the thickness of the epicuticle and exocuticle, or any deposition of endocuticle, was observed. Scanning electron microscopy revealed degradation of the outer surface of the old tooth during premolt. During premolt, epithelial structures resembling papilla appeared to secrete a fibrous web that coalesces to become the matrix of the new tooth. Semi‐quantitative elemental analyses indicated simultaneous deposition of silica and organic matrix, and demonstrated a homogeneous distribution of silicon throughout the epicuticle of the tooth at all stages. However, there is evidence of deposition (presumably silicification) during postmolt as spaces between the papillae become filled in. Thus, the pattern and timing of deposition and silicification of the tooth are different from both teeth of copepods and the general exoskeleton of decapods, and may facilitate rapid resumption of feeding and consumption of the exuvia in early postmolt. J. Morphol. 277:1648–1660, 2016. © 2016 Wiley Periodicals, Inc.     

Histology and histochemistry of the intermoult integument in the ghost crab Ocypoda platytarsis (Milne-Edwards) (Crustacea: Brachyura).

The histological and histochemical aspects of the integument have been described and discussed during the intermoult period of Ocypoda platytarsis. Histological observations revealed that the cuticle comprises of four layers namely epicuticle, exocuticle, endocuticle and membranous layers. Various types of cells in the subepidermal tissue have also been elucidated.