毛尾刺虫无性生殖周期中的形态和形态发生

利用蛋白银染色法研究了毛尾刺虫的形态及无性生殖周期中的形态发生,其过程为：（１）后仔虫口原基出现在左缘棘毛内侧深层,其内的毛基体组装成整齐排列的小膜并分化成新ＡＺＭ１,ＡＺＭ２和口侧膜,（２）前仔虫口原基出现在老仔虫ＡＺＭ２之前方深处,其随后发育成前仔虫的ＡＺＭ２口侧膜及ＡＺＭ１的一部分,并更新老结构的ＡＺＭ１中第７－１１片小膜,（３）额腹横棘毛原基为５列,分别以３：３：２：２：３方式分化最终产出     

尖前口虫的口器发生研究(纤毛门, 膜口目)

研究了咽膜类纤毛虫尖前口虫无性生殖期的核器及口器的演化.其发生特征为;1)新的口原基形成于原前庭动基列与口侧膜间,表观为原口侧膜分裂而致;2)随着形态发生的进行,由口原基依次演化出后仔虫的三片咽膜、口侧膜和三条前庭动基列;3)原口器完全被前仔虫所继承;4)体纤毛器在整个形态发生过程中一直保持双动基列结构.       

悬游双眉虫(原生动物,纤毛门)无性生殖期间的形态发生

应用蛋白银染色技术研究了悬游双眉虫青岛种群无性生殖期间皮层结构和核器的演化过程,其主要特征为:后仔虫口原基独立地出现于紧靠虫体左侧第一根横棘毛的皮层下小龛,其中毛基粒不参与其它棘毛原基的形成;老的口围带发生后半部的局部重建而非整个的由前仔虫简单继承;在前仔虫中,波动膜原基来自老结构的反分化,而在后仔虫中则来自口原基;所有棘毛原基均为独立发生并与老结构没有任何关系;在前仔虫中,口棘毛(即左侧第一根额棘毛)来自于波动膜的反分化,而在后仔虫中则为独立发生;背触毛列于老的结构当中产生,并由最右一列原基演化出3根尾棘毛;两大核片段的改组带从一端向另一端移动 ,并随着两者的融合而消失.文中同时对前人有关该属发生模式的若干存疑问题做了探讨 [动物学报 54(3):517-524,2008].     

尾柱虫(Urostyla cristata)的形态发生研究

U.cristata的表膜“纤毛图式”的构成多而复杂,棘毛大小、基部形状都不相同。在分裂时期产生四个新原基(primordium)区域:(1)口原基(AZM和PM),(2)额部、腹部和臀部棘毛原基(FVT),(3)缘棘毛原基和(4)背触毛原基。 U.cristata在无性分裂时,以口原基的出现为第一迹象,PM和No.O棘毛及腹棘毛中部分棘毛产生新原基居中,而以缘棘毛和背触毛产生原基为最后。分裂过程中,后仔虫上的PM是在新AZM原基的右边产生的,而前仔虫上的老PM则在原位从上往下开始更新的,老AZM是在原位从下往上更新的。左右两边缘棘毛都是在最左一条棘毛排上出现上下两个原基区域的。背面各排触毛的原基是在虫体长1/3和2/3两个位置上出现的。     

腹毛目纤毛虫皮膜演化的一种特殊形式—卵圆急纤虫无性二分裂期间的形态发

对海洋纤毛虫卵圆急纤虫无性分裂过程中的形态发生了做了跟踪观察,结果表明,该种的皮膜演化表现了一系列在腹毛目种类中所罕见的特征;１．新老口围带有一临时性汇联为一的阶段;２．左右缘棘毛原基分步出现,即明显的不同步现象;３．大核的改组在细胞分裂开始前即已完成;４．本种后仔虫之棘毛原基的分化既非独立发生又非来自于老结构的反分化,而是紧靠口原基的一侧向外分衍并极可能是孤立地发展而成;５．老的波动膜在形态发生     

卡龙游仆虫无性生殖期间的形态发生学研究：原生动物,纤毛虫

卡龙游仆虫为海洋中自由生纤毛虫,利用银染法对该种二分裂期间的形态发生学进行了初步的研究,其主要过程为：１．伴随大核改组带的出现和ＤＮＡ复制开始,口原基发生于老口围 方皮膜下一龛腔内,后由前至后组装成围口小膜而演化为后ＡＺＭ。老口围带及口侧膜在原位被被前仔虫继承;２．体棘毛场首先出现两组棘毛原基,其随后各自独立演化成９根前、后仔虫的额－腹－横棘毛;３．缘棘毛原基也为独立发生,初为单一,后断裂为二并分     

腹毛目纤毛虫皮膜演化的一种特殊形式--卵圆急纤虫无性二分裂期间的形态发生学

对海洋纤毛虫卵圆急纤虫无性分裂过程中的形态发生做了跟踪观察,结果表明,该种的皮膜演化表现了一系列在腹毛目种类中所罕见的特征:1)新老口围带有一临时性汇联为一的阶段;2)左右缘棘毛原基分步出现,即明显的不同步现象;3)大核的改组在细胞分裂开始前即已完成;4)本种后仔虫之棘毛原基的分化既非独立发生又非来自于老结构的反分化,而是紧靠口原基的一侧向外分衍并极可能是孤立地发展而成;5)老的波动膜在形态发生过程中亦无反分化现象,而呈独特的半原基模式.     

海洋纤毛虫黄色伪角毛虫无性生殖期间的形态发生

利用蛋白银染色技术研究了海洋纤毛虫———黄色伪角毛虫Pseudokeronopsisflava (Cohn ,186 6 )Wirns berger,Larsen&Uhlig ,1987无性生殖期间的细胞发生学。其主要特征为 :1)前仔虫口原基以独立发生的方式出现并独特地形成于口前庭右侧的皮层深处 ,由其对老口围带进行完全的更新 ;2 )老口器不参与新口器的形成 ,完全被吸收 ;3)前仔虫的额 -腹 -横棘毛原基同样为独立发生 ,老结构可能不参加其随后的发育 ;4 )后仔虫的口原基、波动膜原基及额 -腹 -横棘毛原基均来自最初排列无序的毛基粒发生场 ;5 )背触毛及缘棘毛的更新发生在老的结构中 ,并向前后延伸取代老结构 ;6 )在整个发生过程中 ,无大核融合现象。文中同时对该种所表现的发生学特征及系统学意义做了探讨     

四核舍太虫的细胞发生学与Helix E10-1二级结构分析

利用蛋白银染色技术,观察和研究海洋游仆虫-四核舍太虫Certesia quadrinucleata(纤毛门,游仆目)二分裂期间的形态发生学。其主要特征如下:(1)老口围带完全被前仔虫继承;(2)后仔虫口原基独立产生于皮膜深层;(3)老口侧膜参与前仔虫口侧膜原基形成,前后仔虫的口侧膜原基均发生于细胞表面, 向前贡献出第一根额腹棘毛;(4)额-腹-横棘毛以初级5原基模式产生, 且以"3:3:3:3:3"的方式分化出新的棘毛;(5)背触毛与左缘棘毛原基均来自老结构, 无尾棘毛产生。研究首次给出了背面纤毛器的发生图示,为进一步探讨舍太虫的系统地位提供了一份补足性的发生学基础资料。游仆目纤毛虫的核糖体小亚基基因HelixE10-1区域二级结构一共存在9种模式, 该区域序列长度的变异性揭示了游仆目纤毛虫在进化中可能处于比较特殊的地位。       

杜氏利什曼原虫无鞭毛体形态及分裂过程的电镜观察

无鞭毛体呈椭圆形,后部有深杯样表膜凹陷,虫体一侧有一小突起。膜下微管数为74—90个。细胞核有1—3个核仁,细胞质内充满核糖体,动基体大小不一,多呈腊肠形,由动基体延伸形成长袋状线粒体。靠近鞭毛袋一侧有一组4个游离微管,鞭毛轴丝为9+2结构,并具有基板_1和基板_2结构,基体为9组三联微管。 无鞭毛体分裂从新鞭毛轴丝形成和动基体DNA纤丝伸长开始,以后DNA纤丝带出现裂隙,继之核仁裂碎、消失,形成核内纺锤体,开始细胞核的分裂,随后虫体一侧表膜出现凹陷,新膜下微管和表膜先后形成,并从此处向细胞内伸入,最后完全包绕两个分裂的虫体,完成细胞分裂。随着虫体的发育繁殖,含虫空泡涨大,电子致密度变低。分裂后的无鞭毛体贴附到含虫空泡膜,并向巨噬细胞细胞质内移动,最后离开原来的含虫空泡,形成新的含虫空泡。     

Morphology and morphogenesis of a freshwater ciliate, Epistylis chlorelligerum Shen, 1980 (Ciliophora, Peritrichia)

An oligohalobic peritrichous ciliate, Epistylis chlorelligerum Shen, 1980, was collected from a ditch in Hangzhou, China. The morphology, oral infraciliature, and morphogenesis of the species were studied using living and protargol-impregnated specimens. Zooids of E. chlorelligerum are 160-230 × 50-60 μm in vivo, and characterized by green-colored endoplasm containing symbiotic algae. The oral infraciliature presents a well-developed filamentous reticulum linked to the circular fiber of the cytostome; the outer two rows of P3 extend adstomally over P1 and usually enfold it. During binary fission, one daughter cell inherits most part of the old buccal apparatus and the reorganized haplokinety and germinal kinety (Hk' and G'), and new buccal apparatus of the other daughter cell is mostly developed from the original germinal kinety (G) and haplokinety (Hk): new peniculi 2, 3 (2P2, 2P3), new haplokinety (2Hk), and new germinal kinety (2G) are formed from G, while the new peniculus 1 (2P1) and its peristomial extention (2Pk) originate from Hk. The epistomial membrane can be observed until the two sets of buccal apparatus begin to separate from each other.     

Taxonomic characterization of two marine peritrichous ciliates, Epicarchesium corlissi n. sp. and Pseudovorticella jiangi n. sp. (Ciliophora: Peritrichia), from northern China

Two new marine peritrich ciliates, Epicarchesium corlissi n. sp. and Pseudovorticella jiangi n. sp., were discovered in mariculture waters on the coast of northern China near Qingdao. Their morphology, infraciliature and silverline system were investigated based on both living and silver-impregnated specimens. E. corlissi is characterized as follows: marine Epicarchesium with dichotomously branched stalk; zooids elongate, approximately 60–70×25–35 μm in vivo; peristomial collar double-folded; macronucleus J-shaped; single, small contractile vacuole ventrally positioned; more than 60 striations between peristome and aboral trochal band, 13–18 from aboral trochal band to scopula; abstomal end of row 1 of infundibular polykinety 3 terminating at same level as rows 2 and 3 of infundibular polykinety 3; rows 2 and 3 of infundibular polykinety 3 much longer than row 1 and converging adstomally with infundibular polykinety 1. The new species P. jiangi is diagnosed as follows: marine Pseudovorticella; zooid inverted bell-shaped, approximately 80×60 μm in vivo and with a broad, flat, thin peristomial collar that measures approximately 90 μm across; pellicle with transparent cortical vesicles; macronucleus J-shaped; number of silverlines between peristome and aboral trochal band 20–24, from aboral trochal band to scopula 9–11; abstomal end of row 1 of infundibular polykinety 3 diverges from the other two rows of this polykinety and ends alongside row 3 of infundibular polykinety 2.     

Rediscovery and redescription of the marine peritrichous ciliate Epicarchesium abrae (Precht, 1935) nov. comb. (Protozoa, Ciliophora, Peritrichia)

The morphology, infraciliature and silverline system of the marine peritrichous ciliate, Epicarchesium abrae (Precht, 1935) nov. comb., isolated from an abalone-farming pond off the coast of Qingdao, China, are investigated. E. abrae is characterized by: size of zooid in vivo 68 μm×48 μm on average; macronucleus usually J-shaped; one dorsally-located contractile-vacuole; colony regularly dichotomously branched with 4–16 zooids; total number of transverse silverlines 62–72, from peristome to aboral ciliary wreath 41–47, from aboral ciliary wreath to scopula 21–25; outer kinety of peniculus 3 prolonged and converges with peniculus 1.     

Morphology and Phylogeny of Four New Vorticella Species (Ciliophora: Peritrichia) from Coastal Waters of Southern China

Four new species of Vorticella, V. parachiangi sp. n., V. scapiformis sp. n., V. sphaeroidalis sp. n., and V. paralima sp. n., were isolated from coastal brackish waters of southern China. Their morphology, infraciliature, and silverline system were investigated based on observations of specimens both in vivo and following silver staining. Vorticella parachiangi sp. n. is distinguished by: a J‐shaped macronucleus; a single dorsally located contractile vacuole; a two‐rowed infundibular polykinetid 3, in which row 1 is shorter than row 2; 21–31 silverlines between peristome and aboral trochal band, 6–11 between aboral trochal band and scopula. Vorticella scapiformis sp. n. is characterized by its conspicuously thin and irregularly edged peristomial lip; a J‐shaped macronucleus; a single, ventrally located contractile vacuole; row 1 of the infundibular polykinetid 3 proximally shortened; 18–25 silverlines between peristome and aboral trochal band, 8–12 between aboral trochal band and scopula. Vorticella sphaeroidalis sp. n. can be identified by its small, sub‐spherical zooid; a C‐shaped macronucleus; a ventrally located contractile vacuole; an aboral trochal band adjacent to the scopula; 16–18 silverlines between persitome and aboral trochal band, two between aboral trochal band and scopula. Vorticella paralima sp. n. can be identified by its ovoidal zooid; a J‐shaped macronucleus; a dorsally positioned contractile vacuole; rows 1 and 2 of the infundibular polykinetid 3 proximally shortened; 26–35 silverlines from peristome to aboral trochal band, and 7–13 from aboral trochal band to scopula. The SSU rDNA genes of these four species were sequenced and their phylogeny was analyzed.     

Description of Opisthonecta Matiensis N. Sp. (Protozoa, Ciliophora), A New Peritrich Ciliate From Wastewater

Opisthonecta matiensis n. sp. was isolated from the inlet water of a wastewater treatment plant near Madrid, Spain, and studied in vivo, with silver methods, and using electronic and indirect immunofluorescence microscopy. This new species shows an amphora-like cell shape and has a size of 45-73 microns (x 58.2) x 25-40 microns (x 31.3). The oral infraciliature is formed by one haplokinety, three polykineties, and a short row of kinetosomes (epistomial membrane). The aboral infraciliature is made up of the trochal band and the scopula. From the trochal band arise three fibrillar systems: oral fibers, aboral fibers, and oblique fibers. The myoneme system is composed of a delicate peristomial ring, longitudinal branched fibers that reach the trochal band and of radial fibers extending from the scopula to the trochal band. The silverline system consists of an average of 147 lines. This new species is separated from other known forms by its smaller size, the presence of one single vacuole, and its higher number of silverlines.     

显著车轮虫无性繁殖生物学研究

显著车轮虫无性繁殖过程中,其新齿环在分裂前期发生于旧齿环和辐线环之间;由细线状圆环分节以覆瓦式排列,其数目常为旧环的一倍,少数个体有增多。随着虫体发育,新环依次长出齿钩、锥体、齿棘。旧环则依齿钩、齿棘、锥体、齿钩柄的顺序消失;口沟、伸缩泡均在分裂前期分裂,各自形成两个新的口沟、伸缩泡;新辐线在子体发育初或中期才发生于新齿环外缘,总数为旧辐线的一倍。该虫无性繁殖以24小时为一周期。分裂前期需0.5—1小时;分裂期需1—3分钟。幼虫生长发育期需1.5—3小时。成虫生长成熟期需20—22小时。无论幼虫、童虫和成虫,均能感染鱼苗并影响其生长发育。       

Infraciliature and myoneme system of Campanella umbellaria (Protozoa, Ciliophora, Peritrichida)

The infraciliature and myoneme system of Campanella umbellaria were revealed using the protargol impregnation technique. The main characteristics of the infraciliature are the peristomial ciliary rows (haplokinety and polykineties), which make four and a half turns around the peristomial disc before plunging into the infundibulum, and the aboral infraciliature, which is made up of the aboral ciliary wreath (trochal band) and the scopula. The myoneme system is composed of: 1) longitudinal fibers, which include 60-84 (mean 72.3) short longitudinal fibers, 40-56 (mean 45.8) medium-length longitudinal fibers, and numerous long longitudinal fibers; and 2) circular fibers, which include 8-12 (mean 9.3) peristomial ring fibers, linking fibers, support fibers, and peristomial disc fibers. The various fibers in C. umbellaria are interconnected to form a single myoneme system that may act as a cell skeleton as well as providing the mechanism by which the zooid contracts and relaxes.     

小球藻绿钟虫--中国东北淡水生缘毛类纤毛虫的形态学重述

小球藻绿钟虫 (VorticellachlorellataStiller ,194 0 )采自哈尔滨附近水域。本文在活体观察基础上 ,利用蛋白银染色技术对其形态学进行了研究 ,给出了该种染色后的特征。小球藻绿钟虫因其细胞内充满共生小球藻呈鲜绿色而得名。该种自然伸展时呈稳定的矮钟状 ,体长 5 3- 6 3× 4 1- 6 2 μm ;大核“J”型 ,两端明显盘绕 ,纵贯于体内。细胞表面具横纹 ,蛋白银制片后可见从口围唇到反口纤毛环之间有 33- 36条纹 ,从反口纤毛环到帚胚有条纹 15 - 18条 ;第三咽膜 (P3)由三列毛基列组成 ,最内侧一列长度仅是另外两列的一半 ,并显著分离 ;口围盘纤维斜向并呈轮辐式放射状排列 ,纤维末端分叉。通过对本文描述的绿色钟虫—小球藻绿钟虫的研究 ,发现对绿色钟虫的描述与归属问题仍存在一些混淆。本文认同将小球藻绿钟虫与绿钟虫严格分立的观点