LABORATORY HYBRIDIZATION BETWEEN CRASSOSTREA ARIAKENSIS AND C. SIKAMEA

TO understand possible reproductive interaction between Crassostrea ariakensis (Fujita, 1913) and C. sikamea (Amemiya, 1928), which coexist ill estuaries of China and Japan, we conducted 2 X 2 factorial crosses between the two species. Asymmetry in fertilization success was observed where C. sikamea eggs can be fertilized be C. ariakensis the receprocal cross resulted in no fertilization. Fertilization Success ill C.sikamea female X C. ariakemvis male (SA) crosses was lower than that in the two intraspecific crosses and produced larvae that had similar growth the rate as their maternal species during the first nine days because of maternal effects. After that, genome incompatibility casted negative effects on the growth and survival of the hybrid larvae. Most hybrid larvae died during metamorphosis. but a small number of spat survived. Genetic analysis revealed that the survived SA spat contained DNA from both species and were the hybried. This study demonstrates that hybridization between C. ariakensis and C. sikamea is possible in one direction.

Mitochondrial DNA sequence analysis from multiple gene fragments reveals genetic heterogeneity of Crassostrea ariakensis in East Asia

The native Asian oyster, Crassostrea ariakensis is one of the most common and important Crassostrea species that occur naturally along the coast of East Asia. Molecular species diagnosis is a prerequisite for population genetic analysis of wild oyster populations because oyster species cannot be discriminated reliably using external morphological characters alone due to character ambiguity. To date there have been few phylogeographic studies of natural edible oyster populations in East Asia, in particular this is true of the common species in Korea C. ariakensis. We therefore assessed the levels and patterns of molecular genetic variation in East Asian wild populations of C. ariakensis from Korea, Japan, and China using DNA sequence analysis of five concatenated mtDNA regions namely; 16S rRNA, cytochrome oxidase I, cytochrome oxidase II, cytochrome oxidase III, and cytochrome b. Two divergent C. ariakensis clades were identified between southern China and remaining sites from the northern region. In addition, hierarchical AMOVA and pairwise UST analyses showed that genetic diversity was discontinuous among wild populations of C. ariakensis in East Asia. Biogeographical and historical sea level changes are discussed as potential factors that may have influenced the genetic heterogeneity of wild C. ariakensis stocks across this region.

Population genetics of Crassostrea ariakensis in Asia inferred from microsatellite markers

Crassostrea ariakensis is an important aquacultured oyster species in Asia, its native region. During the past decade, consideration was given to introducing C. ariakensis into Chesapeake Bay, in the United States, to help revive the declining native oyster industry and bolster the local ecosystem. Little is known about the ecology and biology of this species in Asia due to confusion with nomenclature and difficulty in accurately identifying the species of wild populations in their natural environment. Even less research has been done on the population genetics of native populations of C. ariakensis in Asia. We examined the magnitude and pattern of genetic differentiation among 10 wild populations of C. ariakensis from its confirmed distribution range using eight polymorphic microsatellite markers. Results showed a small but significant global theta (ST) (0.018), indicating genetic heterogeneity among populations. Eight genetically distinct populations were further distinguished based on population pairwise theta (ST) comparisons, including one in Japan, four in China, and three populations along the coast of South Korea. A significant positive association was detected between genetic and geographic distances among populations, suggesting a genetic pattern of isolation by distance. This research represents a novel observation on wild genetic population structuring in a coastal bivalve species along the coast of the northwest Pacific.

Identification of Crassostrea ariakensis and related oysters by multiplex species-specific PCR

Genetic markers are needed for rapid and reliable identification of oysters. In this study, we developed multiplex genus- and species-specific PCR markers for the identification of oysters from China. We used the mitochondrial cytochrome oxidase I (COI) and nuclear 28S ribosomal RNA genes for marker development. DNA sequences from different species were obtained from GenBank or by direct sequencing. Sequences were aligned, and genus- and species-specific nucleotides were identified. Primers were designed for genus/species-specific amplification to generate fragments of different sizes. A multiplex set of genus- and species-specific primers from the 28S gene was able to separate C. ariakensis and C. hongkongensis from other species and assign oysters to four genera. A set of species-specific COI primers provided positive identification of all five Crassostrea species from China, C. ariakensis, C. hongkongensis, C. angulata, C. gigas, and C. sikamea in a single PCR. The multiplex PCR assays do not require fluorescence-labeling or post-PCR enzyme digestion, providing a simple, fast and reliable method for the identification of oysters from China.

Differences in the rDNA-bearing chromosome divide the Asian-Pacific and Atlantic species of Crassostrea (Bivalvia, Mollusca)

Karyotype and chromosomal location of the major ribosomal RNA genes (rDNA) were studied using fluorescence in situ hybridization (FISH) in five species of Crassostrea: three Asian-Pacific species (C. gigas, C. plicatula, and C. ariakensis) and two Atlantic species (C. virginica and C. rhizophorae). FISH probes were made by PCR amplification of the intergenic transcribed spacer between the 18S and 5.8S rRNA genes, and labeled with digoxigenin-11-dUTP. All five species had a haploid number of 10 chromosomes. The Atlantic species had 1-2 submetacentric chromosomes, while the three Pacific species had none. FISH with metaphase chromosomes detected a single telomeric locus for rDNA in all five species without any variation. In all three Pacific species, rDNA was located on the long arm of Chromosome 10 (10q)-the smallest chromosome. In the two Atlantic species, rDNA was located on the short arm of Chromosome 2 (2p)-the second longest chromosome. A review of other studies reveals the same distribution of NOR sites (putative rDNA loci) in three other species: on 10q in C. sikamea and C. angulata from the Pacific Ocean and on 2p in C. gasar from the western Atlantic. All data support the conclusion that differences in size and shape of the rDNA-bearing chromosome represent a major divide between Asian-Pacific and Atlantic species of Crassostrea. This finding suggests that chromosomal divergence can occur under seemingly conserved karyotypes and may play a role in reproductive isolation and speciation.

牡蛎染色体的分子生物学分析

本研究应用显带技术和荧光原位杂交(Fluorescence in situ hybridization，FISH)技术，鉴定了牡蛎的染色体；应用FISH方法定位了一系列的重复序列和大分子的P1克隆DNA；制备了染色体特异性探针。应用FISH特异性探针成功地鉴定了长牡蛎的三体10。结果如下：1．分析了G带和C���在美洲牡蛎染色体上的分布。G带在每一条染色体上的带型不同，某些染色体间(如第1对和第4对染色体，第7对和第9对染色体)的带型差别不是很明显。G带型容易受染色体收缩程度的影响。C���型重复性较好，染色体带型较清楚，分布在染色体的端粒区域和着丝粒区域。G带和C���带型能够用来鉴定牡蛎的染色体，但是重复性低和带型差异不显著，并不适合常规的染色体鉴定。2．早期胚胎和担轮幼虫制备的染色体适合于FISH分析。染色体制备方法重复性好，可适用于其它贝类的染色体制备。3．研究了重复序列基因--rDNA的定位：1)18S-5.8S rDNA在研究的五种巨蛎属Crassostrea牡蛎均只有一个位 点。太平洋种(C.gigas，C. ariakensis和C. plicatula)中，杂交信号位于最短的染色体一第10对染色体长臂的端粒区域，在大西洋种(C. virginica和C. rhizophorae)中，同一序列定位在第2对染色体短臂的端粒区域。2)18S-28S rDNA在两种蛤中有两个位点。rDNA探针定位在侏儒蛤(Mulinis Lateralis)的第15对和第19对染色体的端粒区域，同一序列定位在硬壳蛤(Mercenaria mercenaria)的第10对染色体的长臂和第12对染色体短臂的端粒区域。信号强度在两对染色体之间有差异。 3)5s rDNA位于美洲牡蛎的第5对染色体的短臂上靠近着丝粒区域和第6 对染色体的短臂的中间区域。信号强度在两对染色体之间没有显著差异。5S rDNA探针可以作为鉴定和识别第5对和第6对染色体的特异性探针。4．研究了一些重复序列的定位1)两个短的重复序列1G8，1P2均产生很强的荧光信号分布在美洲牡蛎所有的染色体上。在低严谨条件下，这些序列均产生很强的信号散布在所有的染色体上。在高严谨条件下，信号强度大大减弱，但是信号仍散布在所有的染色体上。这些重复序列散布在美洲牡蛎的整个基因组中。2)高度重复序列Cgl70产生的信号分布在长牡蛎的7对染色体的着丝粒区域，没有发现间区信号。在第1对，第2对，第4对和第7对染色体上的荧光信号强且稳定。在第5对，第8对和第10对染色体上的信号相对弱且不稳定。在剩余的染色体上(第3对，第6对和第9对染色体)没有检测到荧光信号。结果表明此卫星序列是一个着丝粒卫星序列。在美洲牡蛎的染色体上没有检测到荧光信号，表明了这个着丝粒卫星序列在这两种牡蛎中的分布存在着显著的差异。3)脊椎动物端粒序列(TTAGGG)n的FISH信号局限在四种双壳贝类(美洲牡蛎，the mangrove oyster，硬壳蛤，侏儒蛤)所有染色体的端粒区域，没有发现间区信号的存在。研究结果与已报道的研究结果表明脊椎动物端粒序列或许存在于所有双壳贝类的染色体末端。双壳贝类是目前研究过的唯一含有脊椎动物端粒序列DNA的无脊椎动物。4)研究了RAPD探针在美洲牡蛎染色体上的定位。大多数RAPD探针产生了多个信号散布在间期细胞核和所有的染色体上。引物OPX-03，OPX-04，OPX—06，OPG-02，OPM—04，OPM-11，0PS-02制备的探针在适宜的条件下产生特异性荧光 信号，分布在牡蛎的特定的染色体上。PCR特异性带产生的探针OPX—06—310和0PG-02—300产生了特异性的荧光信号：OPX—06—310产生的信号位于第5对染色体的短臂的近端粒区域，0PG—02—300探针定位到第3对染色体的短臂上。这两个探针是鉴定美洲牡蛎单条染色体的特异性探针。5．研究了大分子Pl克隆DNA(插入片断为80～100 kb)在美洲牡蛎染色体上的定位。Pl克隆DNA通过切口平移方法标记digoxigenin—11-dUTP用作FISH的探针。Cot-1 DNA作为竞争剂有效地抑制了Pl克隆序列中的重复序列产生的信号。杂交信号用fluorescein标记的anti—digoxigenin抗体来检测，用两层抗体rabbit-anti-sheep抗体和FITC anti—rabbit抗体来扩增信号。9个P1探针成功地定位在特定的染色体上。46—1探针杂交到第1对染色体的长臂靠近着丝粒区域；47-10探针定位到第2对染色体的长臂近端粒区域；Cvpl和48-13两探针定位到第3对染色体上：Cvpl位于短臂的端粒区域，48-13探针位于长臂的近着丝粒区域；48—10探针杂交到第4对染色体的长臂上；48-1探针杂交到第5对染色体长臂的近着丝粒区域；49-11探针位于第7对染色体长臂上；探针49-10和44-11位于第8对染色体长臂上。同时我们成功地将2个P1探针杂交到同一染色体分裂相中，进一步确定了Pl探针在美洲牡蛎染色体 上的定位。6．应用18S-28S rDNA探针成功地鉴定出长牡蛎非整倍体中的三体10。经鉴定AF-35，AF-39和AF-3三体家系属于三体10家系。rDNA探针分布在三条染色体上，即多出的一条染色体为染色体10。相应地在间期细胞核上有三个信号出现。AF-34和AF-36家系不属于三体10家系。rDNA探针分布在两条染色体上，相应地在间期细胞核上有两个信号出现。FISH和染色体特异性探针为非整倍体的鉴定提供了一个快速准确可靠的方法和途径。

软体动物线粒体基因组学及分子系统发生研究

本研究以双壳纲、翼形亚纲、珍珠贝目、扇贝超科的栉孔扇贝(Chlamys farreri )、海湾扇贝(Argopecten irradians)和牡蛎超科巨蛎属(Crassostrea)的长牡蛎(C. gigas)、葡萄牙牡蛎(C. angulata)、熊本牡蛎(C. sikamea)、香港巨牡蛎(C. hongkongensis)和近江牡蛎(C. ariakensis)5种牡蛎及异齿亚纲、帘蛤目、帘蛤科的紫斑文蛤(Meretrix pethechialis)为研究对象，系统的研究了以上物种的线粒体基因组全序列的特点。并以线粒体12个蛋白质编码基因的序列，在氨基酸和核苷酸水平上构建了软体动物的分子系统发生树。本研究旨在为利用线粒体基因组全序列全面构建软体动物分子系统发生树，为软体动物的系统发生和进化研究提供一种新的思路和前期基础工作，本研究主要内容分为以下三个部分： 一、栉孔扇贝和海湾扇贝线粒体基因组序列分析及分子系统发生研究 采用Long-PCR技术扩增了栉孔扇贝和海湾扇贝线粒体全基因组，利用步移法结合文库构建的测序策略获得了线粒体基因组的序列。海湾扇贝线粒体全基因组长度为16,211 bp，栉孔扇贝接近全序列长度为20,789 bp。两个基因组都编码35个基因，包括12个蛋白质编码基因，2个rRNA和21个tRNA。与典型的动物线粒体基因组相比，两个基因组都缺少一个蛋白质编码基因atp8和2个trnS, 在海湾扇贝基因组中有1个trnF的重复，而在栉孔扇贝基因组中有1个trnM的重复。基因排列比较显示，尽管海湾扇贝、栉孔扇贝和巨扇贝分类学上属于同一扇贝科，但是它们的线粒体基因排列非常不同。在四种扇贝中，虾夷扇贝与栉孔扇贝的基因排列顺序非常相似；即使排除tRNA的比较，栉孔扇贝和海湾扇贝基因组仅仅共享三个小的基因块；而海湾扇贝与巨扇贝仅有一个相同的基因块。在所有的系统发生分析中，四种扇贝稳定的系统发生关系得到强有力的支持，海湾扇贝较其他三种扇贝较早的分化出来；栉孔扇贝比其他两种扇贝与虾夷扇贝亲缘关系更近。贝叶斯法和最大似然法分析都支持扇贝超科的单系发生。 二、巨蛎属牡蛎线粒体基因组全序列分析及分子系统发生研究 采用Long-PCR扩增技术和步移法结合文库构建的技术策略获得了巨蛎属C. gigas、C. angulata、C. sikamea、C. hongkongensis和C. ariakensis 5种牡蛎线粒体全基因组序列，并于GenBank已公布的美洲牡蛎C.virginica序列进行比较研究。C. gigas、C. angulata、C. sikamea、C. hongkongensis和C. ariakensis线粒体全基因组长度分别为18,225 bp、18,225 bp、18,243 bp、18,622 bp和18,414 bp，都长于C. virginica基因组17,244 bp的长度。本研究的5种牡蛎线粒体基因组都编码39个基因，包括12个蛋白质编码基因，2个rRNA和25个tRNA。与典型的线粒体基因组相比，都缺少一个蛋白质编码基因atp8，有trnM、trnK和trnQ 3个tRNA基因的重复，更特别的是基因组中的rrnL分为两段，这在其它线粒体基因组中未见报道，有一个重复的rrnS；而C. virginica基因组编码37个基因，与其他牡蛎相比，没有trnK和trnQ重复，只有一个rrnS。基因排列比较显示，巨蛎属的5种牡蛎C. gigas、C. angulata、C. sikamea、C. hongkongensis和C. ariakensis基因排列完全一致，而与C. virginica的基因排列相比仍然有较大的差别，有多个tRNA发生易位。系统发生分析显示，C. gigas和C. angulata首先聚在一起，然后与C. sikamea聚为一支。C. hongkongensis和C. ariakensis聚成一支。C. virginica为单独的一支。系统树清楚的显示出C. gigas和C. angulata以及C. hongkongensis和C. ariakensis非常近的亲缘关系，这也是长期以来，牡蛎分类学上的经典问题，有学者认为C. gigas和C. angulata为同一物种，线粒体基因组的数据显示C. gigas和C. angulata可能达到不同物种的差异。传统分类上的“近江牡蛎”的“白蚝”和“赤蚝”，线粒体序列差别明显，完全支持两种牡蛎新种名的制定。 三、紫斑文蛤线粒体基因组全序列分析及分子系统发生研究 采用Long-PCR扩增技术和步移法结合文库构建的技术策略获得了紫斑文蛤线粒体基因组全序列。该基因组全长19,567 bp，编码36个基因，包括12个蛋白质编码基因，2个rRNA和22个tRNA。与典型的线粒体基因组相比，缺少一个蛋白质编码基因atp8和1个trnS, 有1个trnQ基因的重复。基因排列比较显示，双壳类的基因排列在低的分类阶元时相对保守。在帘蛤科中，紫斑文蛤M. petechialis和菲律宾蛤仔V. philippinarum共享四个完全一致的基因块，两个大的基因块是cox1-L1-nad1-nad2-nad4L-I 和 cox2-P-cob-rrnL-nad4-H-E-S2-atp6-nad3-nad5，另两个小基因块只包括tRNA基因。在以氨基酸序列构建的分子系统树中，帘蛤科紫斑文蛤与菲律宾蛤仔首先聚在一起，然后，它们与A. tuberculata形成一个进化枝。这一枝与H. arctica结合起来，支持异齿亚纲单系发生。

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.

Classification of common oysters from North China

Oysters are commonly found on rocky shores along China's northern coast, although there is considerable confusion as to what species they are. To determine the taxonomic status of these oysters, we collected specimens from nine locations north of the Yangtze River and conducted genetic identification using DNA sequences. Fragments from three genes, mitochondrial 165 rRNA, mitochondria! cytochrome oxidase I (COI), and nuclear 285 rRNA, were sequenced in six oysters from each of the nine sites. Phylogenetic analysis of all three gene fragments clearly demonstrated that the small oysters commonly found on intertidal rocks in north China are Crassostrea gigas (Thunberg, 1793), not C. plicatula (the zhe oyster) as widely assumed. Their small size and irregular shell characteristics are reflections of the stressful intertidal environment they live in and not reliable characters for classification. Our study confirms that the oysters from Weifang, referred to as Jinjiang oysters or C. rivularis (Gould, 1861), are C. ariakensis (Wakiya, 1929). We found no evidence for the existence of C. talienwhanensis (Crosse, 1862) and other Crassostrea species in north China. Our study highlights the need for reclassifying oysters of China with molecular data.

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.

Identifying programs to reduce road trauma to A.C.T. motorcyclists

A broad range of motorcycle safety programs and systems exist in Australia and New Zealand. These vary from statewide licensing and training systems run by government licensing and transport agencies to safety programs run in small communities and by individual rider groups. While the effectiveness of licensing and training has been reviewed and recommendations for improvement have been developed (e.g. Haworth & Mulvihill, 2005), little is known about many smaller or innovative programs, and their potential to improve motorcycle safety in the ACT.