嫁（虫戚）神经系统结构的初步研究

嫁虫戚神经系统包括一对脑神经节、一对足神经节、一对侧神经节和一个脏神经节.左右脑神经节间有较长的神经联合,脑-足、脑-侧神经节间有较长的连索存在.各神经节均由三部分组成:神经节鞘膜、胞体区和神经纤维网.脑神经节相同类型神经元胞体聚集分布,其余神经节神经元未见有明显分区和分层现象.神经元胞体直径一般不超过20μm,这些特征与已研究的前鳃亚纲种类显著不同,可能与该种螺类处于系统演化中较低等地位有关.     

嫁神经系统结构的初步研究

嫁神经系统包括一对脑神经节、一对足神经节、一对侧神经节和一个脏神经节。左右脑神经节间有较长的神经联合,脑—足、脑—侧神经节间有较长的连索存在。各神经节均由三部分组成：神经节鞘膜、胞体区和神经纤维网。脑神经节相同类型神经元胞体聚集分布,其余神经节神经元未见有明显分区和分层现象。神经元胞体直径一般不超过２０μｍ,这些特征与已研究的前鳃亚纲种类显著不同,可能与该种螺类处于系统演化中较低等地位有关。     

中国蛤蜊神经系统GABA和Glu的HPLC测定和免疫组化定位研究

采用邻苯二甲醛(OPA)和9-芴甲氧羰基(FMOC)联合衍生的HPLC法,测定了中国蛤蜊中枢神经系统中2种氨基酸类神经递质(Glu、GABA)的含量.结果表明:足、脑、脏神经节Glu的含量分别为4.77 μg/神经节、0.54μg/神经节、2.13 μg/神经节,GABA含量分别为11.65 μg/神经节、1.03 μg/神经节、4.89 μg/神经节.同时还运用免疫组织化学方法对2种氨基酸在中国蛤蜊中枢神经系统各神经节的分布进行了定位研究和形态学观察.结果显示:谷氨酸免疫阳性反应细胞分布于脑神经节腹侧和背外侧、脏神经节背外侧及后侧、足神经节偶见大型阳性反应细胞;γ-氨基丁酸阳性反应细胞则分布于脑神经节腹侧、脏神经节小细胞团和足神经节的外侧细胞层中.     

嫁Qi神经系统结构的初步研究

嫁Ｑｉ神经系统包括一对脑神经节,一对足神经节,一对侧神经节和一个脏神经节,左右脑神经节间有较长的神经联合,脑一足,脑一侧神经节间有较长的连索存在,各神经节均由三部分组成：神经节鞘膜,胞体区和神经纤维网。脑神经节相同类型神经元胞体聚集分布,其余神经神经元未见有明显分区和分层现象,神经元胞体直径一般不超过２０μｍ,这些特征与已确定的前鳃亚钢种类显著不同,可能与该种螺类处于系统演化中较低等地位有关。     

两种软体动物神经系统一氧化氮合酶的组织化学定位

运用一氧化氮合酶(NOS)组织化学方法研究了软体动物门双壳纲种类中国蛤蜊和腹足纲种类嫁Qi神经系统中NOS阳性细胞以及阳性纤维的分布。结果表明：在蛤蜊脑神经节腹内侧,每侧约有10-15个细胞呈强NOS阳性反应,其突起也呈强阳性反应,并经脑足神经节进入足神经节的中央纤维网中;足神经节内只有2个细胞呈弱阳性反应,其突起较短,进入足神经节中央纤维网中,但足神经节中,来自脑神经节阳性细胞和外周神经系统的纤维大多呈NOS阳性反应;脏神经节的前内侧部和后外侧部各有一个阳性细胞团,其突起分别进入后闭壳肌水管后外套膜神经和脑脏神经索。脏神经节背侧小细胞层以及联系两侧小细胞层的纤维也呈NOS阳性反应。嫁Qi中枢神经系统各神经节中没有发现NOS阳性胞体存在;脑神经节、足神经节、侧神经节以及脑—侧、脑—足、侧—脏连索中均有反应程度不同的NOS阳性纤维,这些纤维均源于外周神经。与已研究的软体动物比较,嫁Qi和前鳃亚纲其它种类一样,神经系统中NO作为信息分子可能主要存在于感觉神经。而中国蛤蜊的神经系统中一氧化氮作为信息分子则可能参与更广泛的神经调节过程。     

中国蛤蜊神经系统显微结构的初步研究

中国蛤蜊中枢神经包括一对脑神经节,一对足神经节和一对脏神经节,各神经节均由神经节被膜,胞体区和中央纤维网三部分组成,脏神经节较腹足类的要复杂,分区现象较明显,脑和足神经节相对较简单,无明显分区和分层现象,神经元胞体可分为大（４０～５４μｍ）,中（２５～４０μｍ）,小（６～２０μｍ）三种类型。     

扁玉螺体表和消化系统甲硫氨酸脑啡肽免疫组织化学定位

采用免疫组织化学strept avidin-biotin complex(S-ABC)法对甲硫氨酸脑啡肽(methionine-enkephalin,M-ENK)在扁玉螺(Neverita didyma)体表、消化系统各器官中的分布进行了研究.结果表明,扁玉螺的足上皮细胞、外套膜的内外上皮细胞以及食道、胃、肠道的黏膜上皮细胞均呈M-ENK阳性反应,且消化道中的阳性反应多集中于上皮细胞游离端;在食道腺的腺上皮中也有少量阳性细胞分布;肝是M-ENK阳性细胞分布较多的器官,主要分布在肝小叶中腺细胞边缘游离端.M-ENK在扁玉螺体表和消化系统各器官均有分布,且分布密度有所不同,可能与各部位的功能有关.     

基于ISSR标记的扁玉螺(Neverita didyma)自然居群遗传结构

利用ISSR分子标记技术,对采自大连（DL）、烟台（YT）及青岛（QD）近海的扁玉螺3个自然居群的遗传结构和遗传多样性进行了分析。用13个引物对90只个体进行了PCR扩增,共检测到161个位点,3个居群的多态位点比例为74.53%～85.09%,各居群遗传多样性水平的高低依次为YT〉QD〉DL。扁玉螺在物种水平上的Nei’s基因多样性指数和Shannon’s信息指数分别为0.3395和0.5113,在居群水平上分别为0.2811和0.4189,显示出扁玉螺有着较高的遗传多样性。AMOVA分子变异分析表明,扁玉螺的遗传变异有27.16%发生在居群间,72.84%发生在居群内,居群内的遗传变异大于居群间的遗传变异。扁玉螺3个居群间的遗传分化系数（Gst）为0.1720,基因流（Nm）为2.4063,Nei’s遗传距离平均值为0.1228,表明扁玉螺居群间虽然存在着一定程度的遗传分化,但仍属于种内正常分化的范畴。上述结果为保护和利用扁玉螺资源提供了科学依据。     

扁玉螺早期发育的实验观察

在实验室条件下人工孵化扁玉螺(Neverita didyma)的卵块,观察了其胚胎发育和幼虫发育过程.扁玉螺的早期发育属间接发生型,其胚胎发育包括卵裂期、囊胚期、原肠胚、膜内担轮幼虫、膜内面盘幼虫;幼虫发育包括面盘幼虫、后期面盘幼虫和匍匐幼虫;匍匐幼虫经变态后发育为稚螺.在水温25～26℃条件下,受精卵发育至膜内面盘幼虫约需38h,5～6d后面盘幼虫冲破卵膜而孵化.扁玉螺面盘幼虫的显著特点是具有1对眼点和1对平衡囊,面盘呈双叶状;后期面盘幼虫的面盘为4叶,呈蝴蝶状,足发达,幼虫既能浮游,又能爬行.后期面盘幼虫进一步生长发育,逐渐转入匍匐生活.     

绿盲蝽中枢神经系统的解剖结构

【目的】阐述绿盲蝽Apolygus lucorum中枢神经系统的组成,辨识各组成部分的神经节解剖结构及其形态,计算中枢神经系统各神经节结构体积大小、解析其空间分布关系以及连接模式。【方法】采用免疫组织化学方法,使用突触蛋白抗体对绿盲蝽中枢神经系统神经髓进行染色标记,利用共聚焦激光扫描显微镜获取中枢神经系统各结构数码图像,使用三维图像分析软件对绿盲蝽中枢神经系统进行分析,并构建三维模型。【结果】绿盲蝽中枢神经系统从前往后分别由脑神经节、咽下神经节、前胸神经节和后部神经节组成。脑、咽下神经节和前胸神经节3个神经节融合在一块,形成脑-咽下神经节-前胸神经节复合体,并通过长的神经连索与后部神经节相连,从外观上看似由2个大的神经节构成,这种神经节愈合形式尚未在昆虫中发现过。前胸神经节与后部神经节分离,二者由长的神经连索连接起来。除前胸神经节由单独的神经原节构成外,其他3个神经节又由多个神经原节融合而成。脑包括前脑、中脑和后脑3部分。咽下神经节包括上颚神经节、下颚神经节和下唇神经节。后部神经节包括中胸、后胸和腹部神经节3部分。【结论】明确了绿盲蝽中枢神经系统的神经节构成,发现了绿盲蝽中枢神经系统各神经节的高度融合特性。该项研究结果为研究绿盲蝽中枢神经系统的发育、重塑和系统演化奠定了形态学基础,为研究中枢神经元形态、分布以及其对昆虫生理和行为的功能调控机制提供了结构框架。     

Locomotion in the pulmonate snail Melampus--II. Recovery after pedal ganglion excision

1. When one pedal ganglion is removed, snails first crawl using the unoperated side of the foot, but in 4-8 weeks the operated side exhibits an anterior-to-posterior gradient of recovery. 2. A ganglion bud bridges the site of the missing ganglion and axons project from intact central ganglia into the foot. 3. Rhythmic activity in right and left pedal nerve pairs is correlated during locomotion in the regenerated snails. 4. The oscillator in the remaining pedal ganglion drives bilaterally coordinated activity. Regenerated projections from the cerebral ganglia through the bud to the remaining pedal ganglion suffice to initiate locomotion.     

脉红螺（Rapana Venosa）神经系统解剖的初步研究

本文对腹足纲、狭舌目、骨螺科的脉红螺神经系统的大体解剖和组织学进行了初步研究。脉红螺神经系统头向集中程度较高,神经节愈合现象较为明显。切片上观察,中枢神经节均由神经节被膜、胞体区和神经纤维网构成;形态上相似的神经细胞有集中分布的现象。     

Embryonic development and organogenesis in the snail Marisa cornuarietis (Mesogastropoda: Ampullariidae). V. Development of the nervous system.

The nervous system is ectodermal in origin. All nerve ganglia arise separately by proliferation and later delamination from the ectoderm, not by invagination. They become secondarily connected to one another by commissures and connectives developing as extensions from the peripheral layer of ganglionic nerve cells. Rudiments of the cerebral, pedal, pleural and intestinal (parietal) ganglia arise almost simultaneously at a relatively early stage (Stage V). The cerebral ganglia develop from the ectoderm of the head plates. Rudiments of the pedal and pleural ganglia are separate at their inception. They later fuse (Stage VI) to form a pleuro-pedal ganglionic mass on each side. The 2 intestinal ganglia are symmetrical at the beginning, but they soon lose their symmetry as a result of torsion. The right ganglion crosses to the left over the gut and persists as the supraintestinal ganglion. The left or subintestinal ganglion shifts to the right and forward, and fuses with the right pleural ganglion (Stage VIII), thus obscuring the chiastoneury. The paired buccal and single visceral (abdominal) ganglia start differentiating in Stage VII. The former develop from the ectodermal wall of the stomodaeum, while the visceral ganglion delaminates from the right wall of the visceral sac, then shifts to the left during torsion. The statocysts develop early (Stage V) from 2 ectodermal invaginations on either side of the rudimentary foot. They later separate from the overlying ectoderm and statoconi appear in their lumina. Contrary to earlier reports on related ampullariids, the osphradium proved to be ontogenetically older than the mantle and mantle cavity. It starts differentiating as a thickened ectodermal plate in the right wall of the visceral sac (Stage V). During torsion, it becomes engulfed in the mantle cavity and shifts to the left side, then is carried forward as the mantlegrow. The eyes develop late (Stage IX) as ectodermal invaginations which rapidly separate from the ectoderm to form closed vesicles. Their cells start differentiating before hatching to form the retina, in which pigment is deposited, and the inner cornea. The lens is secreted in the lumen of the eye and grows by addition of concentric layers of secretion.     

Localization of ovulation hormone-like neuropeptide in the central nervous system of the snail Lymnaea stagnalis by means of immunocytochemistry and in situ hybridization

Summary The caudo-dorsal cells (CDC) in the cerebral ganglia of the pond snail Lymnaea stagnalis synthesize the 36-amino acid ovulation hormone (CDCH). We have used immuno-cytochemistry and in situ hybridization to reveal the localization of neurons and axons containing CDCH-like material.A monoclonal antibody to a fragment of CDCH and a cDNA probe encoding CDCH reacted with the CDC-system, with specific cell groups in the cerebral and pleural ganglia, and with individually occurring neurons throughout the central nervous system. The cells in the pleural ganglia, which were found in about 50% of the preparations studied, are considered as ectopic CDC. They are morphologically similar to CDC in their somal dimensions and axonal organization. By means of immuno-electron microscopy it was shown that these neurons contain secretory vesicles that are similar to those of the CDC. The neurons of the bilateral groups occurring in the cerebral ganglia in addition to the CDC are smaller and more intensely stained than the CDC. Axons of these small neurons probably have varicosities located on the CDC axons in the neuropil of the cerebral ganglion, indicating synaptic contacts. Two major axon tracts could be followed from (or toward) the neuropil of the cerebral ganglion. One tract runs from the cerebral gangion via the pleural and parietal ganglia to the visceral ganglion, giving off branches to most nerves emanating from these ganglia. The other tract could be traced through the cerebro-pedal connective to the pedal ganglia. Only in the right pedal ganglion was extensive axonal branching observed. The nerves emanating from this ganglion contained many more immunoreactive axons than those from the left pedal ganglion. A polyclonal antibody raised against the synthetic fragment of CDCH stained, in addition to the neurons and axons revealed with the monoclonal antibody and the cDNA probe, three other major groups of neurons. Two are located in the cerebral ganglion, the other in the left pedal ganglion.The present findings suggest the presence of a system of neurons that contain CDCH or CDCH-like peptides. The role this system may play in the control of egg-laying and egg-laying behaviour is discussed.     

Ontogenesis of the snail,Helix aspersa: Embryogenesis timetable and ontogenesis of GABA-like immunoreactive neurons in the central nervous system

Late stages of embryogenesis in the terrestrial snail Helix aspersa L. were studied and a developmental timetable was produced. The distribution of gamma-aminobutyric acid-like immunoreactive (GABA-ir) elements in the CNS of the snail was studied from embryos to adulthood in wholemounts. In adults, approximately 226 GABA-ir neurons were located in the buccal, cerebral and pedal ganglia. The population of GABA-ir cells included four pairs of buccal neurons, three neuronal clusters in the pedal ganglia, two clusters and six single neurons in the cerebral ganglia. GABA-ir fibers were observed in all ganglia and in some nerves. The first detected pair of GABA-ir cells in the embryos appeared in the buccal ganglia at about 63–64% of embryonic development. Five pairs of GABA-ir cell bodies were observed in the cerebral ganglia at about 64–65% of development. During the following 30% of development three more pairs of GABA-ir neurons were detected in the buccal ganglia and over fifteen cells were detected in each cerebral ganglion. At the stage of 70% of development, the first pair of GABA-ir neurons was found in the pedal ganglia. In the suboesophageal ganglion complex, GABA-ir fibers were first detected at about 90% of embryonic development. In the posthatching period, the quantity of GABA-ir neurons reached the adult status in four days in the cerebral ganglia, and in three weeks in the pedal ganglia. In juveniles, transient expression of GABA was found in the pedal ganglia (fourth cluster).     

Urotensin I-like immunoreactivity in the central nervous system of Aplysia californica.

In the present study the occurrence and localization of urotensin I (UI, a corticotropin releasing factor-like peptide) in the CNS of Aplysia californica were investigated by immunocytochemistry and radioimmunoassay. The RIA cross-reactivity pattern indicated that the UI antiserum used recognized an epitope in the C-terminal region of the UI, but it did not cross-react with mammalian corticotropin-releasing factor (CRF) and partially recognized sauvagine (SVG, a frog CRF-like peptide). The use of CRF-specific and sauvagine-specific antisera failed to give positive immunostaining. The application of UI antiserum (which does not cross-react with CRF in RIA) gave a positive staining, which was blocked by synthetic sucker (Catostomus commersoni) UI, but not by rat/human CRF (10 microM). On the basis of immunostaining and RIA parallel to fish UI displacement curves of cerebral ganglia extracts, the unknown UI/CRF-like substance in the Aplysia ganglia is likely to have greater homology with sucker UI than with the known CRF peptides. Urotensin I-immunoreactive (UI-ir) neurons were seen mainly in the F neuron clusters, located in the midline and rostrodorsal portion of the cerebral ganglia. Few UI-ir neurons were also found in the C and D neuron clusters of the cerebral ganglia, as well as in the left pleural and abdominal ganglia. In addition, numerous fine and coarse, and beaded UI-ir fibers were found in the cerebral commissure. UI-ir fibers were also seen in the neuropile of the buccal, pedal and pleural ganglia, and abdominal ganglion. A cuff-like arrangement of UI-ir fibers was seen in the supralabial nerves.(ABSTRACT TRUNCATED AT 250 WORDS)     

Similarities in Form and Developmental Sequence for Three Larval Shell Muscles in Nudibranch Gastropods

Shell-anchored muscles that extend into the cephalopodium of five species of planktotrophic nudibranch larvae were studied by ultrastructural examination of sequential larval developmental stages. All species, regardless of larval shell type (inflated or non-inflated), showed a similar basic pattern of shell muscles. The larval retractor muscle (LRM) differentiates prior to hatching and its fibres insert on epithelia of the velum, apical plate, stomodeal region, or mantle fold. Many fibres also connect with subepithelial intrinsic muscles of the cephalopodium. Most but not all LRM fibres Project to left-sided targets and are innervated from the left cerebral ganglion. Two pedal muscles, which are innervated from the pedal ganglia, differentiate during the post-hatching larval stage and both insert primarily on pedal epithelium attached to the operculum. The left pedal muscle is anchored to the shell immediately adjacent to the attachment plaque of the LRM and consists of basal and distal tiers of muscle cells. The right pedal muscle arises on the ventral rim of the shell aperture and consists of a single tier of muscle cells. Ontogenic changes in larval retraction behaviour correlate with developmental change in the muscle effectors. Although some interspecific differences were noted, the presence of a common ground plan for larval shell muscles in these five species contrasts with previous indications of marked variability for nudibranch larval shell muscles.     

A simple neuronal system characterized by a monoclonal antibody to SCP neuropeptides in embryos and larvae of Tritonia diomedea (Gastropoda, Nudibranchia)

SCP-like antigenicity is first present in Tritonia diomedea in small cells of the cerebral ganglia and a single axon crossing the cerebral commissure of 8-day-old embryos. Other axons and neurons become antigenic as the larva develops. At 4-9 days after larvae hatch from the egg mass, 2 additional pairs of neurons are labeled. Axons extend from one pair to the left cerebral ganglion and from the other to the right. A second labeled axon is present across the cerebral commissure. In metamorphically competent larvae the cerebral and pedal neuropils, as well as two neurons in the buccal ganglia with axon(s?) across the commissure, are antigenic. The change in antigenicity as the larva becomes competent is presumably preparatory for juvenile life. The labeled buccal neurons may be B12, which are known to contain SCPs, extend an axon across the buccal commissure, and function in adult feeding behavior. The two large neurons strongly labeled by rabbit polyclonal antibodies against FMRFamide are clearly different from neurons labeled by monoclonal antibody against SCPs. This result supports the contention that different antigens are labeled by these two immune probes.     

Coexistence of FMRFamide, met-enkephalin and serotonin in molluscan neurons

1. Coexistence of FMRFamide, met-enkephalin and serotonin immunoreactivities was examined in Achatina fulica and Aplysia kurodai. 2. Coexistence of FMRFamide and serotonin was found in some neurons of the visceral, right parietal and pedal ganglia of Achatina fulica, and in the pedal ganglion of Aplysia kurodai. 3. In Achatina fulica, coexistence of FMRFamide and met-enkephalin was found in a neuron of the left parietal ganglion and that of met-enkephalin and serotonin was found in a giant neuron of the right parietal ganglion. 4. Based on these results, the biological significance of coexistence was discussed.