3种贝类糖胺聚糖的粗提及含量比较

以企鹅珍珠贝、菲律宾蛤仔和锯齿巴非蛤全脏器为原料，经酶解、离心去蛋白、醇沉、分离、洗涤、干燥，得糖胺聚糖（GAG）粗制品．分别测定并比较3种贝类的GAG的含量和得率。结果表明，企鹅珍珠贝的GAG质量分数为22．35％．菲律宾蛤仔为18．69％．锯齿巴非蛤为20．36％，由此得出企鹅珍珠贝的GAG的含量比其他两种贝类高．是较好的GAG来源。     

深圳海域麻痹性贝类毒素含量特征

根据 1996～ 1997年间深圳海域 (大亚湾和大鹏湾 ) 13种贝类 (华贵栉孔扇贝、马氏珍珠贝、翡翠贻贝、波纹巴非蛤、毛蚶、栉江瑶、联珠蚶、文蛤、棕带仙女蛤、僧帽牡蛎、菲律宾蛤仔、习见蛙螺和近江牡蛎 )体中的麻痹性毒素的检测数据 ,阐述了贝类麻痹性毒素的含量水平、年际变化、PSP中毒事件以及与其它海区贝类 PSP的比较     

深圳海域麻痹性贝类毒素含量特征

根据1996－1997年间深圳海域（大亚湾和大鹏湾）13种贝类（华贵栉孔扇贝、马氏珍珠贝、翡翠贻贝、波纹巴非蛤、毛蚶、栉江瑶、联珠蚶、文蛤、棕带仙女蛤、僧帽牡蛎、菲律宾蛤仔、习见蛙螺和近江牡蛎）体中的麻痹性毒素的检测数据，阐述了贝类麻痹性毒素的含量水平、年际变化、PSP中毒事件以及与其它海区贝类PSP的比较。     

企鹅珍珠贝主要污损生物的初步研究

企鹅珍珠贝[Pteria(Magnavicula)penguin(R ding)]分布于热带亚热带海域,在台湾、两广沿海和海南岛有野生种群栖息,它是珍珠贝属的一种可生产大规格附壳珠和正圆珠的大型贝类。近年来企鹅珍珠贝的种苗生产、养殖和大型珍珠培育以及生化遗传的研究受到关注。在养殖中,其他海洋生物的附着或寄生成为影响企鹅珍珠贝生长与存活的重要因素,目前相关研究仅见其他贝类的多毛虫寄生病[1-4]、附着敌害生物和网笼污损生物类群等[5-7]的报道,而企鹅珍珠贝的污损生物的研究仅见污损苔虫的文献记录[8]。本文对企鹅珍珠贝的附着生物进行了初步鉴别,并分…     

企鹅珍珠贝主要污损生物的初步研究

企鹅珍珠贝[Pteria（Magnavicula）penguin（Roeding）]分布于热带亚热带海域，在台湾、两广沿海和海南岛有野生种群栖息，它是珍珠贝属的一种可生产大规格附壳珠和正圆珠的大型贝类。近年来企鹅珍珠贝的种苗生产、养殖和大型珍珠培育以及生化遗传的研究受到关注。在养殖中，其他海洋生物的附着或寄生成为影响企鹅珍珠贝生长与存活的重要因素，目前相关研究仅见其他贝类的多毛虫寄生病、附着敌害生物和网笼污损生物类群等的报道，而企鹅珍珠贝的污损生物的研究仅见污损苔虫的文献记录。本文对企鹅珍珠贝的附着生物进行了初步鉴别，并分析它们的附着或寄生状态。     

企鹅珍珠贝附壳珍珠的培育

以7种聚乙烯塑料核型为珠核,正常壳形与二壳隆起的畸形企鹅珍珠贝为手术贝,培育附壳珍珠。养殖6个月,结果表明:壳形正常的育珠贝成活率为73.3%～93.8%,成珠率55.0%～82.0%;畸形贝成活率为60%,成珠率53.3%。统计分析表明:珠核高度是影响育珠贝成活率和成珠率的主要因素,珠核越高,育珠贝成活率和成珠率越低。畸形贝与正常壳形贝成活率和成珠率存在极显著差异(P<0.01),畸形贝不宜用作手术贝。     

3种珍珠贝精子发生及其超微结构的比较研究

在透射电子显微镜下观察合浦珠母贝（Ｐｉｎｃｔａｄａｆｕｃａｔａ）、大珠母贝（Ｐｉｎｃｔａｄａｍａｘｉｍａ）和企鹅珍珠贝（Ｐｔｅｒｉａｐｅｎｇｕｉｎ）的精子发生及精子形态．结果表明．大珠母贝从精原细胞到精子，核内都有数量不等的板层小体（ｎｕｃｌｅａｒｌａｍｅｌｌａｒｂｏｄｙ）；企鹦珍珠贝从精原细胞的晚期直到精子细胞早期，大多数细胞出现核内包含体（ｎｕｃｌｅａｒｉｎｃｌｕｓｉｏｎ）；而合浦珠母贝的生精细胞核无特殊结构．合浦珠母贝在初级精母细胞时由高尔基体分泌形成前顶体粒；企鹅珍珠贝的前顶体粒主要在次级精母细胞和早期精子细胞阶段形成。虽然大珠母贝的各级生精细胞中都没有出现典型的高尔基体，但前顶体粒仍在精母细胞时期形成。三种贝的精子结构均为典型的原生型，由头部、中段和尾部构成．合浦珠母贝精子的顶体最长，中段的线粒体数有变异；大珠母贝的精子核最高，其中含有板层小体；而企鹅珍珠贝精子中段的体积是最大的．     

企鹅珍珠贝同工酶表达多态性的初步研究

采用垂直板状聚丙烯酰胺梯度凝胶电泳,对企鹅珍珠贝鳃组织的酯酶(EST)、葡萄糖-6磷酸脱氢酶(G6PD)、乳酸脱氢酶(LDH)、苹果酸脱氢酶(MDH)和超氧化物歧化酶(SOD)5种同工酶进行了检测,并对酶谱特征进行了生化遗传分析.酶谱表型显示企鹅珍珠贝的同工酶呈现多态现象,同工酶表达上的多态性表明企鹅珍珠贝具有较丰富的遗传多样性.     

企鹅珍珠贝同工酶表达多态性的初步研究

采用垂直板状聚丙烯酰胺梯度凝胶电泳，对企鹅珍珠贝鳃组织的酯酶(EST)、葡萄糖-6磷酸脱氢酶(G6PD)、乳酸脱氢酶(LDH)、苹果酸脱氢酶(MDH)和超氧化物歧化酶(SOD)5种同工酶进行了检测，并对酶谱特征进行了生化遗传分析。酶谱表型显示企鹅珍珠贝的同工酶呈现多态现象，同工酶表达上的多态性表明企鹅珍珠贝具有较丰富的遗传多样性。     

湄洲湾海域贝类重金属污染状况及健康风险评价

【目的】研究湄洲湾海域贝类重金属污染状况,评价其健康风险。【方法】测定湄洲湾海域长牡蛎(Crassostrea gigas)、缢蛏(Sinonovacula constricta)、菲律宾蛤仔(Ruditapes philippinarum)、毛蚶(Scapharca subcrenata)、文蛤(Meretrix meretrix)等5种贝类中的Pb、Cd、无机As、Cr、Hg、Cu含量,对其进行Pearson相关性分析。采用单项污染指数法和综合污染指数法评价5种贝类的健康风险。【结果】Hg与Cu之间存在有统计学意义的正相关(P0.05),相关系数为0.923,其他各元素间相关性则无统计学意义;Pb、Cd、无机As、Cr、Hg、Cu的平均含量均未超过食品中污染物限量,5种贝类的综合污染指数为0.28~0.35;5种贝类的复合目标危害系数TTHQ值为0.370~0.532,均小于1。【结论】湄洲湾海域5种贝类均未受重金属污染,重金属暴露的健康风险较低。     

4种海洋贝类多糖提取和保湿性研究

以马氏珠母贝(Pinctada martensii)、企鹅珍珠贝(Pteria penguin)、翡翠贻贝(Perna viridis)和近江牡蛎(oyster)的内脏团为原料提取、纯化多糖,与甘油、聚乙二醇400(PEG-400)、丙二醇和1,3-丁二醇四种常规保湿剂进行比较.结果表明,在相对湿度为44%时,前12h 吸湿率顺序为:马氏珠母贝<近江牡蛎<企鹅珍珠贝<翡翠贻贝< PEG-400<1,3-丁二醇<甘油<丙二醇;在相对湿度为80%时,前12 h 吸湿率顺序为:近江牡蛎<马氏珠母贝<企鹅珍珠贝<1,3-丁二醇<翡翠贻贝< PEG-400<甘油<丙二醇.前12 h 的保湿率顺序为:近江牡蛎>翡翠贻贝>马氏珠母贝>企鹅珍珠贝>甘油>1,3-丁二醇>丙二醇> PEG-400.翡翠贻贝吸湿性多糖优于其他贝类多糖,稍低于常规保湿剂.在相对湿度为80%时,前12 h 翡翠贻贝多糖的吸湿率大于常规保湿剂1,3-丁二醇,翡翠贻贝多糖保湿性稍弱于近江牡蛎,但强于其他贝类多糖和常规保湿剂要强一些     

企鹅珍珠贝人工苗生长的初步观察

为了解企鹅珍珠贝生长规律，观察了壳高2.5～5.0mm的出池幼苗，按月测量其生长参数和成活率，以及环境因子。结果表明，企鹅珍珠贝生长最快的月份为7～11月和次年4～6月，壳长，壳高和壳宽月均增加量分别为3.8～13.0mm、4.7～11.2mm、2.3～3.8mm，月成活率97.8%～98.6%。企鹅珍珠贝生长最慢月份是11月至次年3月。     

企鹅珍珠贝人工养殖及育珠的研究

在幼贝中间养成中采用柱形笼养殖法,母贝的养成中采用穿耳开放式养殖法,与全程采用锥形笼的传统式养殖方法相比较,进行企鹅珍珠贝人工养殖。结果表明:采用本技术养殖企鹅珍珠贝,在幼贝中间养成阶段,比传统养殖的壳高生长速率提高32·1%(P<0·05),壳长生长速率提高30·3%(P<0·01),成活率提高36%(P<0·01);母贝养成阶段,比传统养殖的壳高生长速率提高28·1%(P<0·05),壳长生长速率提高26·7%(P<0·01),成活率提高18·3%(P<0·01)。同时进行企鹅珍珠贝人工培育游离珠实验,植核贝在休养期和育珠期存活率分别为71·2%和54·3%,留核率分别为29·6·6%和21·0%,成珠率58·6%,优质珠比例为26·7%。     

一种提取高质量贝类基因组DNA的简易方法

以企鹅珍珠贝(Pteria penguin)闭壳肌为样品,利用高盐+十二烷基硫酸钠(SDS)除去蛋白和多糖,用低盐+十六烷基三甲基溴化铵(CTAB)进一步纯化DNA,建立一种贝类基因组DNA简便、安全、经济的提取方法。改进后的SDS-CTAB法提取的DNA纯度较高,无蛋白质和RNA污染;酶切和AFLP实验验证表明,所提取DNA可满足酶切分析和分子标记等实验的要求。     

基于近缘EST-SSR引物的企鹅珍珠贝养殖和野生群体的遗传标记

利用近源物种马氏珠母贝的EST-SSR引物对企鹅珍珠贝DNA进行扩增,获得7对可扩增出目标条带的近缘分子标记,分析野生群体(YS)和养殖群体(YZ)企鹅珍珠贝的遗传多样性。结果显示,7个位点共获得26个等位基因;野生和养殖群体的等位基因数分别为3~5和3~4,平均期望杂合度(He)分别为0.623 5、0.496 8;平均观测杂合度(Ho)分别为0.431 8、0.302 8;HNUPM047位点的多态信息含量较低,为0.446 7,其他位点均在0.5以上,说明该遗传标记可提供比较丰富的遗传信息。表明养殖群体遗传多样性水平低于野生群体。     

Sodium and potassium in the bones of penguin and skua revealed by EPR and SR-XRF technique

Penguin and skua in the maritime Antarctic have high salt loadings in the body due to almost exclusive diet consumption of marine invertebrates. However, the storage and turnover of sodium and potassium in these animals are poorly investigated. Here we determined the concentration and microscopic distribution of the two elements in the bones of penguin and skua. The average concentrations of sodium and potassium in penguin bone were comparable with that in skua bone (0.18% and 0.82% for penguin bone; 0.19% and 0.76% for skua bone in dry weight). The ratios of sodium to calcium and potassium to calcium (0.0330 and 0.0075 for penguin, 0.0335 and 0.0082 for skua in average by weight) were somewhat higher than the reported ratios for terrestrial animals, indicating these marine animals' bone enrichment of salt. The ratios of sodium to potassium in average by weight were 6.75 and 4.65 for penguin and skua, respectively. This value is much lower compared with the bulk sea water ratio of about 27.0, implying that potassium is favorable to reside in the bone rather than sodium. Both sodium and potassium were found to significant correlation with the content of organic materials in bone based upon the intensity of native signal determined by electron paramagnetic resonance (EPR). It was estimated that almost all of potassium is kept within the organic phases, while about 30% of sodium is stored in organic phases and the other 70% within mineral phase. The microscopic distributions of potassium in the cross-section and/or surface were revealed by synchrotron radiation X-ray fluorescence (SR-XRF) technique. The ratio of potassium to calcium based upon the SR-XRF intensity counter varied considerably from the surface to the interior, and on the surface the highest concentration of potassium was observed in the middle section with decreasing amounts toward the edge. This indirectly documented that exchange of potassium between fluid and bone organic phase maybe occur.     

低盐度海水对企鹅珍珠贝存活的影响

对企鹅珍珠贝稚贝、中贝和成贝在降低盐度的海水中存活状态进行了观察和研究。在水温20~23℃,以不同盐度梯度(8、12、16、20、242、8、30和33)的海水暂养稚贝并定时检查,在广东的四个海区,对盐度变化时中贝及成贝的养殖成活率进行了观察。结果表明:盐度低于16的3个组,稚贝在60h内全部死亡,盐度20~24海水中,稚贝虽只有部分死亡,但活力较差;稚贝在14的海水中4h后转入正常海水,可全部存活,而超过8h后再移入正常海水的稚贝会陆续死亡;在盐度18海水中,稚贝一直未分泌足丝附着,而移入正常海水,6h就有小苗附着;大万山岛附近海域在雨季盐度可降至20以下,6~9月不适合养殖,而其它实验点可以通过深吊避免海水盐度变化造成企鹅珍珠贝死亡。     

Distribution and reproductive behavior of penguins on Ardley Island and their environmental impact factors

During the 2006/07 Antarctic summer, the species population, distribution and reproductive behavior of penguins in areas near the Great Wall Station were investigated. Five species of penguin were recorded: gentoo penguin (Pygoscelis papua), adelie penguin (P. adeliae), chinstrap penguin (P. antarctica), King penguin (Aptenodytes patagonicus) and Emperor penguin (A. forsteri). The first three species bred locally, while the other two species were observed occasionally. Ardley Island is one of the most important breeding areas for penguins. After the breeding season of 2006/07, there were a total of about 17 234 penguins and the breeding success rate was 0.40-141. Comparing with historical data, changes in penguin species populations and distribution were analyzed, and their relationships with the environment, climate change and human activity were investigated.     

The identification and comparison of the bio-elements of the penguin ornithogenic sediments sample from Davis Station and Great Wall Station

During CHINARE-22 in austral summer of 2005-2006, a lake sediment core named DG4, which is impacted by penguin droppings, was retrieved from a lake catchment in Gardner Island of Vestfold Hills, East Antarctica. In this study, the concentrations of characteristic elements in the core, local bedrocks and fresh penguin guanos were determined. P, Se, F, S, As, Sr and Cu in DG4 were identified as the bio-element assemblage by R-clustering analysis and compared with those in the local bedrocks and fresh guanos, the results are similar to Y2 in Ardley Island, Antarctic Peninsula. On this basis, P and Se were identified as the optimum bio-elements in DG4 and F, P and S were identified in Y2, respectively. This work will provides the foundation for reconstructing the past penguin populations in Gardner Island of Vest- fold Hills, East Antarctica and comparing the penguin population dynamics between East Antarctica and Antarctic Peninsula.