亚历山大藻对海产贝类胚胎和蒙古裸腹溞的影响及致毒机制研究

本文研究了典型有毒赤潮藻——亚历山大藻(Alexandrium)对海湾扇贝(Argopecten irradians Lamarck)、文蛤(Meretrix meretrix Linnaeus)和太平洋牡蛎(Ostrea gigas Thunberg)受精卵孵化的影响和致毒机制以及对蒙古裸腹溞(Moina mongolica Daday)生命活动的影响。此外，还针对我国赤潮发生特点，模拟研究了我国东海大规模赤潮对菲律宾蛤仔（Ruditapes philippinarum (Adams et Reeve)）受精卵孵化和蒙古裸腹溞种群数量的影响。 结果发现：8株产PSP毒素的亚历山大藻：塔玛亚历山大藻( ATHK, AT5-1, AT5-3, ATCI02, ATCI03)，链状亚历山大藻, A. lusitanicum、微小亚历山大藻和2株不产PSP毒素的相关亚历山藻(AC-1, AS-1)对海湾扇贝受精卵的孵化均有显著抑制作用，说明在亚历山大藻属中，这种抑制作用具有一定的普遍性，并与PSP毒素的产生无直接关系，表明存在非PSP毒素的其它毒性物质。一种PSP标准毒素STX也没有这种抑制作用，进一步证明该抑制作用与PSP毒素不直接相关。 相关亚历山大藻AC-1对海湾扇贝、文蛤和太平洋牡蛎受精卵孵化的有显著的毒害作用，其藻液、重悬液、去藻液和内容物均显著影响受精卵的孵化。相关亚历山大藻AC-1对海湾扇贝、文蛤和太平洋牡蛎担轮幼虫细胞的超微结构有显著破坏作用，破坏膜结构和胞内结构，影响细胞内的功能器官如溶酶体的稳定性，使卵黄颗粒萎缩变形；对文蛤和太平洋牡蛎的受精卵显示出极强的毒害作用： 3000cells•ml-1时，使二者胚胎完全溶掉消失；在2000cells•ml-1的藻液中培养2h后，担轮幼虫的外膜发生溶解，整个幼体呈葡萄串样。相关亚历山大藻AC-1产生的这种毒性物质可能对贝类胚胎细胞的结构和功能有影响。 亚历山大藻对蒙古裸腹溞的毒性效应与不同藻种/藻株密切有关：塔玛亚历山大藻（AT-6, ATCI02）、链状亚历山大藻、A. lusitanicum和微小亚历山大藻不影响蒙古裸腹溞的存活，而塔玛亚历山大藻（ATHK、ATCI03和AT5-1）和相关亚历山大藻(AC-1, AS-1)有显著影响。蒙古裸腹溞能摄食塔玛亚历山大藻(AT-6, ATHK, ATCI02, ATCI03, AT5-1)，链状亚历山大藻, A. lusitanicum和微小亚历山大藻，很少或基本不摄食相关亚历山大藻。亚历山大藻影响蒙古裸腹溞的RNA/DNA比值和蛋白质含量以及Na+,K+-ATP酶活性。相关亚历山大藻AC-1对蒙古裸腹溞的存活有极强的毒性作用，藻液、重悬液、内容物和碎片均有显著影响；即使与3×106cells•ml-1小球藻混合，10和50cells•ml-1的相关亚历山大藻AC-1仍能使蒙古裸腹溞的产幼数和存活时间显著下降。亚历山大藻对蒙古裸腹溞生命活动的影响不仅与PSP毒素有关，还与非PSP毒素有关；蒙古裸腹溞可能也是研究有害藻急性和慢性毒性的一种理想生物。 应用菲律宾蛤仔胚胎和蒙古裸腹溞评价我国东海特大规模赤潮对海洋生物资源的潜在危害时发现：单种链状亚历山大藻对菲律宾蛤仔受精卵的孵化和蒙古裸腹溞的种群增长均有显著不利影响；单种东海原甲藻（1~10×104cells•ml-1）对菲律宾蛤仔受精卵的孵化没有影响；较低密度的东海原甲藻能维持蒙古裸腹溞（2~5×104cells•ml-1）的种群增长；较高密度的东海原甲藻对蒙古裸腹溞（10×104cells•ml-1）种群有显著的抑制作用。两种藻以赤潮密度混合后，适当密度的东海原甲藻能在一定程度上减轻链状亚历山大藻对菲律宾蛤仔受精卵和蒙古裸腹溞的毒性。可见，东海连年爆发的大规模赤潮不仅对浮游生态系统有不利影响，若同时爆发亚历山大藻赤潮，则对海洋浮游生态系统和贝类资源的恢复产生更加不利的影响。

牡蛎的比较解剖学及系统分类和演化的研究

本文对我国己发表的牡蛎作了详细的比较解剖学研究。在强蛎亚科（Pycnodonteinae）发现了第三个心耳－－右上心耳和与其相连的第三条回心静脉－－后静脉，这在双壳类中实属首次报道。第一次提出了牡蛎循环系统的两种类型，附心脏型和无附心脏型。两者之间的主要区别是：前者无肌套血管，其外套血液主要来自环外套动脉和附心脏，而后者由于无附心脏和环外套动脉，其外套血液主要来自肌套血管；前者是通过出鳃静脉和外套静脉分别将鳃前部和后部的血液送回心耳，而后者的外套静脉与外入鳃血管不通，鳃中的血液只能通过出鳃静脉回到心耳。根据外套腔的形态特点，本文将中国的牡蛎分为三种类型六个组。第一种类型，左右侧都具侧水腔，包括一个组；第二种类型，仅右侧具有侧水腔，包括四个组；第三种类型；不具侧水腔，包括一个组。在比较解剖学研究的基础上，文章还讨论了消化系统，神经系统，循环系统等一些主要系统的演化过程，并推测了现生牡蛎各属间的演化关系。提出了一些新的分类依据，发现了一个具有重要演化意义的单行属种，爪蛎属（Talonostrea），猫爪牡蛎（T. talonata）。澄清了目前世界上在舌骨蛎属（Hyotissa）、拟舌骨蛎属（Parahyotissa）、小蛎属（Saccostrea）和巨蛎属（Crassostrea）分类中的混乱。解决了我国牡蛎分类中存在己久的疑难问题，将己发表的20种牡蛎重新鉴定为15种，即舌骨牡蛎（Hyotissa hyotis），复瓦牡蛎（Parahyotissa imbricata）。中华牡蛎（P. sinensis），鸡冠牡蛎（Lopha cristagalli）。薄片牡蛎（Dendostren folium），缘齿牡蛎（D. cre-nulifera），褶牡蛎（Alectryonella plicatula），猫爪牡蛎（T. talonata），长牡蛎（Crassostrea gigas），近江牡（C. rivularis），拟近江牡蛎（Crassostrea sp.），僧帽牡蛎（Saccostrea cucullata），棘刺牡蛎（S. echinata），鹅掌牡蛎（Planostrea pestigris）和密鳞牡蛎（Ostrea denselamellosa）。它们分别隶属于二个科，曲蛎科（Grypheidae）和牡蛎科（Ostreidae）；四个亚科，强蛎亚科（Pycnodonteinae）。冠蛎亚科（Pycnodonteinae），巨蛎亚科（Lopheinae）和牡蛎亚科（Crassostreinae）。

Classification of jinjiang oysters Crassostrea rivularis (Gould, 1861) from China, based on morphology and phylogenetic analysis

The jinjiang oyster Crassostrea rivularis [Gould, 1861. Descriptions of Shells collected in the North Pacific Exploring Expedition under Captains Ringgold and Rodgers. Proc. Boston Soc. Nat. Hist. 8 (April) 33-40] is one of the most important and best-known oysters in China. Based on the color of its flesh, two forms of C rivularis are recognized and referred to as the "white meat" and 11 red meat" oysters. The classification of white and red forms of this species has been a subject of confusion and debate in China. To clarify the taxonomic status of the two forms of C. rivularis, we collected and analyzed oysters from five locations along China's coast using both morphological characters and DNA sequences from mitochondrial 16S rRNA and cytochrome oxidase 1, and the nuclear 28S rRNA genes. Oysters were classified as white or red forms according to their morphological characteristics and then subjected to DNA sequencing. Both morphological and DNA sequence data suggest that the red and white oysters are two separate species. Phylogenetic analysis of DNA sequences obtained in this study and existing sequences of reference species show that the red oyster is the same species as C. ariakensis Wakiya [1929. Japanese food oysters. Jpn. J. Zool. 2, 359-367.], albeit the red oysters from north and south China are genetically distinctive. The white oyster is the same species as a newly described species from Hong Kong, C. hongkongensis Lam and Morton [2003. Mitochondrial DNA and identification of a new species of Crassostrea (Bivalvia: Ostreidae) cultured for centuries in the Pearl River Delta, Hong Kong, China. Aqua. 228, 1-13]. Although the name C. rivularis has seniority over C. ariakensis and C. hongkongensis, the original description of Ostrea rivularis by Gould [1861] does not fit shell characteristics of either the red or the white oysters. We propose that the name of C. rivularis Gould [1861] should be suspended, the red oyster should take the name C. ariakensis, and the white oyster should take the name C. hongkongensis. (C) 2004 Elsevier B.V. All rights reserved.

Its length polymorphism in oysters and its use in species identification

In an effort to develop genetic markers for oyster identification, we studied length polymorphism in internal transcribed spacers (ITS) between major ribosomal RNA genes in 12 common species of Ostreidae: Crassostrea virginica, C. rhizophorae, C. gigas, C. angulata, C. sikamea, C. ariakensis, C. hongkongensis, Saccostrea echinata, S. glomerata, Ostrea angasi, O. edulis, and O. conchaphila. We designed two pairs of primers and optimized PCR conditions for simultaneous amplification of ITS 1 and ITS2 in a single PCR. Amplification was successful in all 12 species, and PCR products were visualized on high-resolution agarose gels. ITS2 was longer than ITS 1 in all Crassostrea and Saccostrea species, whereas they were about the same size in the three Ostrea species. No intraspecific variation in ITS length was detected. Among species, the length of ITS I and ITS2 was polymorphic and provided unique identification of 8 species or species pairs: C. ariakensis, C. hongkongensis, C. sikamea, O. conchaphila, C. virginica/C. rhizophorae, C. gigas/C. angulata, S. echinata/S. glonzerata, and O. angasi/O. edulis. The ITS assay provides simple, rapid and effective identification of C. ariakensis and several other oyster species. Because the primer sequences are conserved, the ITS assay may be useful in the identification of other bivalve species.