尖形碘泡虫(黏体门: 碘泡虫科)的重描述及其分子系统学研究

研究基于形态和分子信息重描述了寄生于嘉陵江重庆段鲫(Carassius auratus Linnaeus)鳃部和胆囊的尖形碘泡虫(Myxobolus acutus Wu and Chen, 1987), 并获得了该虫体的18S rDNA和ITS1 rDNA序列。尖形碘泡虫成熟孢子壳面观呈梨形, 前端稍尖, 后端钝圆, 缝面观呈宽纺锤形。孢子长(13.6±0.9) μm [(11.4—15.3) μm], 宽(10.2±0.9) μm [(7.5—12.8) μm], 厚(7.6±0.6) μm [(6.9—8.3) μm]。两梨形极囊开口处紧靠并位于孢子前端, 极囊大小不等, 大极囊长(6.2±0.4) μm [(5.1—7.5) μm], 宽(3.8±0.4) μm [(2.8—4.7) μm], 极丝盘绕5—8圈, 小极囊长(2.7±0.4) μm [(1.7—3.7) μm], 宽(1.4±0.2) μm [(0.9—1.9) μm], 极丝盘绕2—3圈。基于18S rDNA为分子标记的系统发育分析显示: 尖形碘泡虫与中华单极虫(Thelohanellus sinensis)有最近的亲缘关系, 两物种形成的进化支与贝壳碘泡虫(M. musseliusae)、苍梧碘泡虫(M. tsangwuensis)和鳃基碘泡虫(M. basilamellaris)形成的进化支呈姐妹群关系。通过系统发育与寄生部位关系的分析结果推测, 尖形碘泡虫的初始寄生部位可能为鳃, 而胆囊则是该物种后来适应的新的寄生部位。     

海城碘泡虫(黏体动物门，黏孢子纲)补充描述及基于18S rDNA系统发育分析

海城碘泡虫原始描述中形态数据较为简单,且存在多个宿主及寄生部位,其有效性有待确定。利用现行主流的黏孢子虫形态特征和基因标记系统分析相结合的分类学方法,对采自太湖棒花鱼鳃丝的海城碘泡虫进行了补充描述。该碘泡虫孢囊呈白色,圆形,大小为(0.6—1.1) mm。成熟孢子正面观近似椭圆形,上端稍尖,侧面观呈纺锤型,孢子长(10.8±0.7) μm (10.1—11.5 μm),孢子宽:(8.1±0.5) μm (7.5—9.0 μm),孢子厚:(5.7±0.4) μm (5.2—9.0 μm);两极囊呈梨形,大小存在细微差别,极囊顶端存在突起,大极囊长:(4.7±0.5) μm (4.8—6.7 μm),宽:(2.5±0.2) μm (3.2—4.3 μm),小极囊长:(4.4±0.2) μm (4.1—4.8 μm),宽:(2.2±0.1) μm (2.0—2.5 μm);极丝盘绕4—5圈。基于18S rDNA序列(GenBank登录号:KY965936)比对分析,该碘泡虫与放射孢子虫Hexactinomyxon type 2相似率最高,为97%。系统发育分析表明,该碘泡虫与Hexactinomyxon type 2、Hexactinomyxon type 1、Hexactinomyxon type SH-2006、Myxobolus pfeifferi、Myxobolus caudatus和Myxobolus squamae聚为独立分支,和其他已报道的黏孢子虫亲缘关系较远。研究在补充了海城碘泡虫形态学、基因标记序列信息基础上,推断了该虫生活史。     

田中碘泡虫的重描述及系统发育分析

基于形态学和分子数据(18S rDNA)重新描述了寄生于重庆江津地区金鱼 (Carassius auratus auratus)鳃丝的田中碘泡虫 (Myxobolus tanakai Kato, et al., 2017), 并结合系统发育分析对其近缘种进行了比较研究。形态学特征: 该虫种孢子为后端钝圆的长梨形, 大小为(14.58±0.54) μm×(6.09±0.37) μm; 两个极囊等大; 极丝与极囊长轴垂直缠绕8—10圈; 囊间突起位于极囊前端呈三角形; 具有嗜碘泡。分子特征: 共获得3个分离样本的18S rDNA序列, 其一级结构序列与日本黑川地区鲤 (Cyprinus carpio) 鳃丝寄生的田中碘泡虫的一致性达99.3%—99.6%, 且在系统发生树中聚为一支。结果表明: 本研究种与日本的田中碘泡虫为同种, 此为中国新记录; 金鱼为田中碘泡虫的宿主新记录。18S rDNA的V2、V4和V7区二级结构的比较结果表明: 田中碘泡虫已发生了明显的种内变异, 推测可能因宿主差异和地理隔离同时所致。此外, GenBank中报道的数个野鲤碘泡虫的序列是否为同种有待进一步厘清。     

鲤肠道寄生岳阳碘泡虫新种的形态特征及系统发育分析

在洞庭湖岳阳地区开展鱼类寄生虫调查中,发现一种寄生于鲤Cyprinus carpio L.肠道的黏孢子虫。该黏孢子虫的孢囊呈白色,椭圆形,大小为(1.0±0.2) mm (0.8—1.2 mm)。成熟孢子具有壳瓣,壳面观近似圆形,后端有4—6个“V”形褶皱;缝面观呈纺锤形,缝脊直而粗;孢质均匀,含有一个嗜碘泡;孢子长(9.8±0.6) μm (9.6—10.0 μm),孢子宽(8.2±0.3) μm (8.0—8.5μm),孢子厚(7.3±0.1) μm (7.0—7.5 μm);2个极囊梨形,位于孢子顶端,大小相等,呈“八”字形;极囊长(4.4±0.4) μm (3.8—5.1 μm),宽(2.7±0.2) μm (2.2—3.2 μm),极丝4—5圈。该黏孢子虫与肠膜碘泡虫、丑陋圆形碘泡形态特征非常相似,但其极囊/孢子小于1/2;与文献已报道的鲤肠道寄生北京碘泡虫和鲤肠碘泡虫相比较,其在孢子形态、孢子和极囊大小方面分别存在明显差异。基于该黏孢子虫18S rDNA基因序列(GenBank登录号KY203795)比对分析,该黏孢子虫与山东碘泡虫相似率最高,仅为96%。系统发育分析发现,该黏孢子虫与山东碘泡虫、倪李碘泡虫、住心碘泡虫、Myxobolus encephalicus、Sphaerospora molnari、多涅茨尾孢虫和Henneguya zikaweiensis聚为独立分支,和其他已报道的黏孢子虫亲缘关系较远。综合形态学和18S rDNA基因序列数据,文章报道的鲤肠道寄生黏孢子虫为碘泡虫属一新物种,将其命名为岳阳碘泡虫。     

萨梅诺娃新佩雷斯虫中国新记录

研究报道了中国首例摇蚊微孢子虫, 结合各发育阶段形态特征、生态学特征及分子特征, 鉴定其为萨梅诺娃新佩雷斯虫Neoperezia semenovaiae Issi, et al. 2012, 系我国新记录。萨梅诺娃新佩雷斯虫寄生于羽摇蚊幼虫脂肪体组织, 导致其体表呈白浊状。成熟孢子呈卵圆形, 孢子长(5.7±0.2) μm (5.3—6.3 μm), 宽(3.7±0.1) μm (3.4—4.0 μm)。透射电镜观察显示各发育阶段均为离核, 发育不同步, 与宿主细胞质直接接触。早期发育阶段为高电子密度的多核裂殖体阶段, 经原生质团分裂形成单核或多核产孢体, 进一步发育为单核孢子母细胞。孢子母细胞形状不规则, 周围被内质网环绕, 并逐渐形成微孢子虫的典型结构如极丝、极质体和三层孢壁等。成熟孢子卵圆形, 离核, 细胞核较大, 位于孢子正中央, 被大量核糖体包围。极质体分为两部分, 前半部分为海绵状, 后半部分薄膜状。锚状盘位于孢子前端, 呈蘑菇状。孢壁三层, 外层为高电子密度层, 厚26.5—62.7 nm, 中间层为电子透明层, 厚151.8—236.1 nm, 里层为质膜层。同型极丝, 30—31圈, 分2—3列排列。扩增获得其小核糖体序列为1356 bp, 序列比较发现其与俄罗斯列宁格勒区羽摇蚊的N. semenovaiae相似性为99.1%。系统发育关系分析表明N. semonovaiae与Neoperezia、Bryonosema、Schroedera属种类聚为一独立进化枝, N. semonovaiae种群出现明显的地理分化。     

海城碘泡虫(黏体动物门,黏孢子纲)补充描述及基于18S rDNA系统发育分析（英文）

海城碘泡虫原始描述中形态数据较为简单,且存在多个宿主及寄生部位,其有效性有待确定。利用现行主流的黏孢子虫形态特征和基因标记系统分析相结合的分类学方法,对采自太湖棒花鱼鳃丝的海城碘泡虫进行了补充描述。该碘泡虫孢囊呈白色,圆形,大小为(0.6—1.1)mm。成熟孢子正面观近似椭圆形,上端稍尖,侧面观呈纺锤型,孢子长(10.8±0.7)μm(10.1—11.5μm),孢子宽:(8.1±0.5)μm(7.5—9.0μm),孢子厚:(5.7±0.4)μm(5.2—9.0μm);两极囊呈梨形,大小存在细微差别,极囊顶端存在突起,大极囊长:(4.7±0.5)μm(4.8—6.7μm),宽:(2.5±0.2)μm(3.2—4.3μm),小极囊长:(4.4±0.2)μm(4.1—4.8μm),宽:(2.2±0.1)μm(2.0—2.5μm);极丝盘绕4—5圈。基于18S r DNA序列(Gen Bank登录号:KY965936)比对分析,该碘泡虫与放射孢子虫Hexactinomyxon type 2相似率最高,为97%。系统发育分析表明,该碘泡虫与Hexac-caudatus和Myxobolus squamae聚为独立分支,和其他已报道的黏孢子虫亲缘关系较远。研究在补充了海城碘泡虫形态学、基因标记序列信息基础上,推断了该虫生活史。     

武汉单极虫(粘体门,双壳目)的重描述及基于18S rDNA序列系统发育分析

通过光镜、扫描电镜和18S rDNA序列对比,对寄生于异育银鲫Carassius auratus gibelio体表的粘孢子虫进行了形态学和分子生物学研究,鉴定其为武汉单极虫Thelohanellus wuhanensis,并发现了形态学新特征:膜状鞘的起始位置不同,且仅包围孢子后部;壳瓣底部内侧具“V”形褶皱;一片壳瓣前端有突起结构;缝脊直,突出明显;测得极丝全长为158.5 ～179.2 (170.7 ±5.7) μm.经18S rDNA序列对比,与T.wuhanensis[HQ613410]的相似率为99.87％.系统发育分析表明,单极虫与碘泡虫具有非常近的亲缘关系,将单极虫属与碘泡虫属二者归属于碘泡科的分类方法更合理.     

南海石斑鱼苗种肠道微孢子虫病病原的鉴定

研究通过组织病理分析、超微结构观察以及分子特征分析对石斑鱼(Epinephelus spp.)苗种肠道微孢子虫病病原进行了鉴定。其为一肠孢虫属新种, 命名为石斑鱼肠孢虫(Enterospora epinepheli sp. n.), 专性寄生于细胞核内, 发育过程与肠孢虫属模式种黄道蟹肠孢虫(Enterospora canceri)一致。早期单核裂殖体通过一层简单的电子薄膜与宿主细胞核质隔离。随后, 单核裂殖体发育形成多核裂殖原质团。此时, 细胞核出现明显肥大, 有的甚至被裂殖子胀破。裂殖原质团进一步发育形成多核产孢体, 并开始出现许多高电子密度的囊泡状结构。这些与极丝及锚状盘有关的囊泡状结构聚集在藕核周围, 并组装形成微孢子虫特征性结构(挤出装置)前体。随后, 产孢体原生质团通过连续分裂形成一个个孢子母细胞。孢子母细胞与细胞核直接接触, 并直接发育形成成熟孢子。成熟孢子椭圆形, 孢子长(1.56±0.31) μm (1.07—1.96 μm), 宽(1.08±0.98) μm (0.93—1.28 μm)。 孢壁分为3层, 外壁电子密度高, 厚(15.51±0.95) nm (9.87—26.18 nm), 内壁为电子透明层, 较外层更厚(81.13±2.71) nm (57.16—110.81 nm), 最里面为孢质膜。极丝为同型极丝, 共5—6圈, 分2排排列。组织病理学分析发现该微孢子虫寄生于肠道上皮杯状细胞核内, 肠壁脱落的内容物中也发现大量的微孢子虫。序列比对发现该种与之前报道的石斑鱼肠道微孢子虫待定种(Microsporidium sp.)序列基本一致, 与其他相似性较高的种类的遗传距离在0.162—0.225。系统发育关系分析显示肠胞虫科的种类明显分为两支, 石斑鱼肠孢虫和肠孢虫属其他种类及毕氏肠胞虫聚为一个独立分支, 但不与该分枝中任何种类形成姊妹支。     

楔形两极虫(黏体门,双壳目)的形态学重描述及其近缘种的分子系统学研究

两极虫属Myxidium和楚克拉虫属Zschokklella在形态上非常相似,形态鉴定界限模糊。为进一步厘清两者的分类学关系,本研究对采自涪江重庆市潼南县江段的楔形两极虫M.cuneiforme Fujita,1924进行了形态学重描述,并对其分子系统学进行了研究。楔形两极虫孢子壳面观呈长条形,中部稍凹陷或孢子一边突出,壳瓣上有6~8条与缝嵴平行的条纹;缝嵴直,缝面观呈梭形。孢子长12.5μm±0.3μm,宽5.4μm±0.3μm(n=20)。极囊2个,呈梨形,分布于孢子两极端;极囊长4.3μm±0.2μm,宽3.1μm±0.2μm(n=20),极丝细长且明显,盘曲5~6圈。以18S rDNA为分子标记,对楔形两极虫及其近缘种进行了保守区变异、遗传距离、序列相似度和分子系统发育分析,结果表明:两极虫属和楚克拉虫属均非单系发生,两属间物种相互交叉聚支;两极虫属与楚克拉虫属物种间具有很近的亲缘关系。本文基于形态和分子数据的研究结果支持将两极虫属和楚克拉虫属合并为一个属的观点。     

吴李碘泡虫的重描述及其长江流域不同江段株系的比较研究

研究在对吴李碘泡虫Myxobolus wulii (Wu & Li) Landsberg & Lom, 1991重描述的基础上, 基于形态和分子数据对长江流域不同江段的吴李碘泡虫(重庆株系、湖北株系及江苏株系)进行了比较研究。结果表明: 吴李碘泡虫重庆株系孢子及极囊量度比湖北株系略小, 重庆株系两极囊等大而湖北株系两极囊大小不等。重庆株系、湖北株系及江苏株系18S rDNA序列相似度为99.2%—99.9%, 遗传距离为0.002—0.007。系统发育分析显示: 吴李碘泡虫并未形成地理种群特有的进化枝, 也并未依宿主种类而聚支, 而是依据寄生部位不同分为鳃寄生和肝胰脏寄生2大支系。这表明, 相同寄生部位的吴李碘泡虫具有更近的亲缘关系。吴李碘泡虫的2大支系中, 鳃寄生种群先分化出来, 这可能与体表寄生和体内寄生的演化有关, 而鳃寄生的吴李碘泡虫可能是较早定居的群体。     

Two species of parasitic copepods (Caligidae) new to Japan

Two species of parasitic copepods (Siphonostomatoida: Caligidae), Caligus sclerotinosus Roubal, Armitage & Rohde, 1983, parasitic on red seabream Pagrus major (Temminck & Schlegel), and Lepeophtheirus longiventralis Yü & Wu, 1932, parasitic on spotted halibut Verasper variegatus (Temminck & Schlegel), are redescribed based on material found on their respective hosts cultured in Japan. Both species are new to Japan. Preliminary observation on the occurrence of L. longiventralis indicates that the larval development takes place on the body surface of the host and only the post-mated female migrates into the host's gill-cavities. Whilst the occurrence of L. longiventralis in Japan can be considered as due to natural causes, the occurrence of C. sclerotinosus is likely due to anthropogenic activities.     

葡萄碘泡虫、似葡萄碘泡虫和茄形碘泡虫的鉴别及系统发育

葡萄碘泡虫Myxobolus acinosus Nie & Li, 1973、似葡萄碘泡虫Myxobolus pseudoacinosus Guo, et al., 2018和茄形碘泡虫Myxobolus toyamai Kudo, 1917形态非常相似, 有着共同的宿主和相同的寄生部位, 是病原鉴定中容易混淆的种。文章基于形态学和18S rRNA基因信息对三者进行了鉴别和分子系统学研究。成熟孢子形态特征的比较分析显示, 三者形态存在显著差异。葡萄碘泡虫与似葡萄碘泡虫18S rDNA序列相似度为98.4—98.8%, 遗传距离为0.013—0.020; 葡萄碘泡虫与茄形碘泡虫18S rDNA序列相似度为96.1—97.2%, 遗传距离为0.038—0.042; 似葡萄碘泡虫和茄形碘泡虫18S rDNA序列相似度为96.4—97.6%, 遗传距离为0.033—0.040。18S rDNA序列比对显示, 葡萄碘泡虫含有15个关键变异位点, 可将该虫与似葡萄碘泡虫和茄形碘泡虫区分; 似葡萄碘泡虫含有5个关键变异位点, 可将该虫与葡萄碘泡虫和茄形碘泡虫区分; 茄形碘泡虫含有33个关键变异位点可将该虫与葡萄碘泡虫和似葡萄碘泡虫区分。18S rRNA二级结构V4区的E23-2构型可将葡萄碘泡虫与似葡萄碘泡虫和茄形碘泡虫区分, 而V7区的H43构型可将茄形碘泡虫与葡萄碘泡虫和似葡萄碘泡虫区分。以上表明, 三者无论在形态上还是在遗传上均具有独立物种的特征。系统发育分析显示, 葡萄碘泡虫、似葡萄碘泡虫和茄形碘泡虫为系统树中分化较晚的一支。     

Ceratomyxa aegyptiaca n. sp. (Myxozoa: Myxosporea) from the gall-bladder of Solea aegyptiaca Chabanaud (Pleuronectiformes: Soleidae) in a Tunisian coastal lagoon

A new marine myxosporean species, Ceratomyxa aegyptiaca n. sp. is described from the gall-bladder of Solea aegyptiaca Chabanaud collected from the Ghar El Melh Lagoon in northeastern Tunisia. Mature spores are elongate and crescent-shaped, measuring 8-11?μm in length and 48-58?μm in width. The polar capsules are spherical, 3.2-4?μm in diameter and equal in size. Trophozoites are polysporous and float free in the bile or are attached on the epithelium of the gall-bladder. Morphological data and molecular analysis based on 18S rDNA sequences are provided. The 18S rDNA of C. aegyptiaca is readily distinguishable from that of other myxozoan species, as the genetically most similar myxozoan parasite, C. seriolae Yokoyama & Fukuda, 2001 (AB530265) collected from Seriola quinqueradiata Temminck & Schlegel in Japanese waters, shares with it only 67.5% identical nucleotides over a 1,680-bp long fragment of 18S rDNA.     

Phylogenetic analysis of ribosomal RNA operons from uncultivated coastal marine bacterioplankton

Analyses of small subunit ribosomal RNA genes (SSU rDNAs) have significantly influenced our understanding of the composition of aquatic microbial assemblages. Unfortunately, SSU rDNA sequences often do not have sufficient resolving power to differentiate closely related species. To address this general problem for uncultivated bacterioplankton taxa, we analysed and compared sequences of polymerase chain reaction (PCR)-generated and bacterial artificial chromosome (BAC)-derived clones that contained most of the SSU rDNAs, the internal transcribed spacer (ITS) and the large subunit ribosomal RNA gene (LSU rDNA). The phylogenetic representation in the rRNA operon PCR library was similar to that reported previously in coastal bacterioplankton SSU rDNA libraries. We observed good concordance between the phylogenetic relationships among coastal bacterioplankton inferred from SSU or LSU rDNA sequences. ITS sequences confirmed the close intragroup relationships among members of the SAR11, SAR116 and SAR86 clades that were predicted by SSU and LSU rDNA sequence analyses. We also found strong support for homologous recombination between the ITS regions of operons from the SAR11 clade.     

Description of two new gill myxozoans from smallmouth (Micropterus dolomieu) and largemouth (Micropterus salmoides) bass

Two previously undescribed species of myxozoan parasites were observed in the gills of bass inhabiting the Potomac and James River basins. They are described using morphological characteristics and small-subunit (SSU) rDNA gene sequences. Both were taxonomically identified as new species of Myxobolus; Myxobolus branchiarum n. sp. was found exclusively in smallmouth bass, and Myxobolus micropterii n. sp. was found in largemouth and smallmouth bass. Small, spherical, white plasmodia of M. branchiarum from smallmouth bass were observed grossly in the gills; these plasmodia had an average length of 320.3 μm and width of 246.1 μm. The development of the plasmodia is intralamellar in the secondary lamellae of the gills. Mature spores were pyriform in shape with a length of 12.8 ± 1.4 (8.1-15.1) μm and width of 6.9 ± 1.1 (4.0-9.0) μm. Analysis of SSU rDNA identified M. branchiarum in a sister-group to 3 species of Henneguya , although morphologically caudal appendages were absent. Myxobolus micropterii observed in the gills of largemouth and smallmouth bass had larger, ovoid, cream-colored plasmodia with an average length of 568.1 μm and width of 148.1 μm. The cysts developed at the distal end of the gill filament within the primary lamellae. The mature spores were ovoid in shape with a length of 10.8 ± 0.7 (9.2-12.2) μm and width of 10.6 ± 0.6 (9.0-11.8) μm. SSU rDNA analysis placed M. micropterii in a sister group with Henneguya lobosa and Myxobolus oliveirai . The highest prevalence of M. branchiarum was observed in the gills of bass collected from the Cowpasture River (50.9%). Prevalence was 44.6% in bass from the Potomac River and only 4.3% in bass collected from the Shenandoah River. A seasonal study of M. branchiarum , which included both infected and uninfected smallmouth bass, determined that a significantly higher intensity was observed in the spring than in the summer (P < 0.001) or fall (P = 0.004). In an analysis excluding uninfected bass, a higher intensity was observed in the spring than in the summer (P = 0.001) or fall (P = 0.008). Prevalence and seasonal differences were not determined for M. micropterii .     

倒刺鲃两极虫的宿主新记录及其分子系统学研究

为弄清倒刺鲃两极虫(Myxidium spinibarba)的宿主多样性和胭脂鱼(Myxocyprinus asiaticus)寄生黏孢子虫的种类组成, 研究基于形态和分子数据, 比较分析了寄生于不同宿主的倒刺鲃两极虫的形态学和形态计量学特征及分子系统发育关系。结果显示: 寄生于胭脂鱼和中华倒刺鲃的倒刺鲃两极虫株系在形态学和形态计量学上未出现显著性差异, 18S rDNA序列相似度为99.9%—100.0%, 遗传距离为0.000—0.001, 符合种内变异; 寄生于不同宿主倒刺鲃两极虫的株系在系统发育树中嵌合聚支, 且寄生于胭脂鱼的倒刺鲃两极虫株系先分化。以上结果表明: 研究中两株系与倒刺鲃两极虫为同一物种, 但在分子水平已经出现分化; 这是首次在胭脂鱼中检获到黏孢子虫, 胭脂鱼是倒刺鲃两极虫的新宿主。     

Phylogenetic position of the copepod-infesting parasite Syndinium turbo (Dinoflagellata, Syndinea)

Sequences were determined for the nuclear-encoded small subunit (SSU) rRNA and 5.8S rRNA genes as well as the internal transcribed spacers ITS1 and ITS2 of the parasitic dinoflagellate genus Syndinium from two different marine copepod hosts. Syndinium developed a multicellular plasmodium inside its host and at maturity free-swimming zoospores were released. Syndinium plasmodia in the copepod Paracalanus parvus produced zoospores of three different morphological types. However, full SSU rDNA sequences for the three morphotypes were 100% identical and also their ITS1-ITS2 sequences were identical except for four base pairs. It was concluded that the three morphotypes belong to a single species that was identified as Syndinium turbo, the type species of the dinoflagellate subdivision Syndinea. The SSU rDNA sequence of another Syndinium species infecting Corycaeus sp. was similar to Syndinium turbo except for three base pairs and the ITS1-ITS2 sequences of the two species differed at 34-35 positions. Phylogenetic analyses placed Syndinium as a sister taxon to the blue crab parasite Hematodinium sp. and both parasites were affiliated with the so-called marine alveolate Group II. This corroborates the hypothesis that marine alveolate Group II is Syndinea.