Isolation and characterization of microsatellite DNA markers in the Pacific abalone,Haliotis discus hannai

We developed 17 new microsatellite markers in Haliotis discus hannai. All loci were found to be polymorphic with an average of 13.1 alleles per locus (range 3–28). The mean observed and expected heterozygosities were 0.77 (range 0.17–1.00) and 0.79 (range 0.42–0.96), respectively. Six loci deviated significantly from Hardy–Weinberg proportions, and thus should be used with caution. The high variabilities revealed in this study suggest that these microsatellite loci should provide useful markers for studies of trait mapping, kinship and population genetics.     

对二甲苯对皱纹盘鲍肝胰腺细胞DNA的损伤

为研究对二甲苯对皱纹盘鲍肝胰腺的毒性作用,设置4个浓度(0.5、1.0、1.5和2.0 mg·L^-1)和对照组,开展为期21 d的对二甲苯对皱纹盘鲍的亚慢性毒性试验,采用彗星试验技术进行皱纹盘鲍肝胰腺细胞DNA损伤分析,采用CASP分析软件对拖尾率、彗星尾长、彗尾DNA相对含量、Olive矩等损伤指标进行统计。结果表明: 与对照组相比,各染毒组皱纹盘鲍肝胰腺细胞DNA均受到损伤,且损伤程度存在显著性差异。随着染毒浓度的增加,肝胰腺细胞DNA受损程度加重,高浓度甚至可以引发细胞凋亡,呈现一定的剂量-损伤效应。中浓度对二甲苯短时间暴露即可对皱纹盘鲍肝胰腺细胞造成DNA损伤,随着暴露时间延长,细胞DNA受损程度加重,呈现一定的时间-损伤效应。但长时间暴露细胞DNA各损伤指标有所减小,这可能与细胞自身的DNA修复机制和生物体解毒系统的代谢机制有关。研究表明,对二甲苯可对皱纹盘鲍肝胰腺细胞产生氧化损伤,导致DNA断裂,高浓度的对二甲苯长时间暴露可导致其细胞凋亡。     

幼龄皱纹盘鲍唾液腺和消化腺的超微结构与组织化学

以透射电镜观察和组织化学方法研究了45日龄皱纹盘鲍的唾液腺和消化腺。唾液腺由粘液细胞和纤毛细胞组成,粘液细胞含发达的粗面内质网和大量的粘原颗粒,分泌中性和酸性混合粘多糖。消化腺由消化细胞和嗜碱性细胞组成,消化细胞呈现活跃的内吞和细胞内消化,并具蛋白酶和非特异性酯酶活性。嗜碱性细胞含发达的粗面内质网和大量含铁的折光小体,折光小体的电子密度较低。     

皱纹盘鲍肠粘膜上皮的结构和功能

以透射电镜和扫描电镜观察、组织化学及酶活性测定等方法研究了皱纹盘鲍的肠和直肠,肠和直肠粘膜上皮由5种细胞组成。具微绒的柱状细胞呈现吸收细胞的超微结构特征,纤毛柱状细胞参与运输食物颗粒和粪便,Ⅰ型腺细胞具蛋白酶、非特异性酯酶和脂酶活性,以顶浆分泌形式分泌消化酶,Ⅱ型腺细胞分泌物可能与包裹粪便有关,状细胞分泌酸性粘多糖。体外酶活性分析表明肠和直肠粘膜上皮分别具有4种和3种植物多糖酶。     

皱纹盘鲍消化腺的超微结构

在电镜下研究了大连地区皱纹盘鲍消化腺的超微结构。结果表明,皱纹盘鲍同其它腹足纲软体动物一样,消化腺由消化细胞、排泄细胞和钙细胞三种细胞类型组成。消化细胞呈柱状或锥体形,数量最多,细胞表面具微绒毛,顶端胞质内具顶颗粒,细胞中央区域具有许多“具电子致密核心池”结构,细胞基部胞质内含成簇的脂滴,线粒体球形或不规则,游离核糖体丰富。胞核椭圆形或不规则,位于细胞的基部,染色质多呈块状散布于核内,亦有少量贴核膜分布,核仁一个,十分明显。排泄细胞形状和结构与消化细胞相似,其主要特征是在细胞的在部区域内具有许多含高电子致密物的大液泡。钙细胞呈锥体形,大多分布在消化细胞和排泄细胞的基部,其主要特征是细胞内具有许多呈同心环状的钙粒子。     

皱纹盘鲍外套膜、鳃和足粘液细胞的类型与分布

以阿新兰和过碘酸雪夫氏反应(AB．PAS)染色法显微观察皱纹盘鲍(1taliotis discus hannai)的外套膜、鳃和足的粘液细胞。根据所显示颜色的不同,可将粘液细胞分为Ⅰ～Ⅳ4种类型：分别呈红色、蓝色、紫红色和蓝紫色。外套触手和外套膜上皮的粘液细胞以Ⅱ型为主,Ⅳ型较少,密度不均,多为近圆形细胞,大型和小型细胞均有分布。鳃轴和鳃叶上皮的粘液细胞密度较大,以Ⅱ型和Ⅰ型为主,Ⅲ型和Ⅳ型较少,形态有杯形、近圆形或棒状等,多为中型及小型细胞。足的上皮粘液细胞较少,均为Ⅱ型,但局部上皮的细胞含有许多棕色颗粒。     

皱纹盘鲍的染色体研究

本文报道皱纹盘鲍的染色体制备方法及核型分析结果。皱纹盘鲍的2n=36,可配为18对,中央着丝点(M)的11对,即1,3,6,7,9,11,12,13,14,16,17号染色体。亚中央着丝粒(Sm)的7对,即2,4,5 8,15,18号染色体,NF=72。染色体的长度呈连续递变。其中相对长度最长的1号染色体为7.09,最短的18号染色体4.11,单倍体总长687.05。     

Isolation and characterization of microsatellite markers for the ornamental discus fish Symphysodon discus and cross-species amplification in other Heroini cichlid species

The discus fishes (Symphysodon spp.) are economically important ornamental species. Thirteen microsatellite markers were developed from a CT(12) - and CA(12) -enriched whole genomic DNA library of Symphysodon discus. Allelic variability was tested on 44 individuals of two species (S. discus and S. aequifasciatus). Allelic richness ranged from two to 11 alleles per locus and observed heterozygosities from 0.083 to 0.998. All loci were at Hardy-Weinberg equilibrium, and no pair of loci showed linkage disequilibrium within a species. Cross-species amplification was also successfully performed in the Neotropical cichlids Uaru amphiacanthoides, Hoplarchus psittacus, Hypselecara coryphaenoides, Pterophyllum sp., Mesonauta sp. and Heros sp.     

A novel oligoalginate lyase from abalone, Haliotis discus hannai, that releases disaccharide from alginate polymer in an exolytic manner

We previously reported the isolation and cDNA cloning of an endolytic alginate lyase, HdAly, from abalone Haliotis discus hannai [Carbohydr. Res.2003, 338, 2841-2852]. Although HdAly preferentially degraded mannuronate-rich substrates, it was incapable of degrading unsaturated oligomannuronates smaller than tetrasaccharide. In the present study, we used conventional chromatographic techniques to isolate a novel unsaturated-trisaccharide-degrading enzyme, named HdAlex, from the digestive fluid of the abalone. The HdAlex showed a molecular weight of 32,000 on SDS-PAGE and could degrade not only unsaturated trisaccharide but also alginate and mannuronate-rich polymers at an optimal pH and temperature of 7.1 and 42 degrees C, respectively. Upon digestion of alginate polymer, HdAlex decreased the viscosity of the alginate at a slower rate than did HdAly, producing only unsaturated disaccharide without any intermediate oligosaccharides. These results indicate that HdAlex degrades the alginate polymer in an exolytic manner. Because HdAlex split saturated trisaccharide producing unsaturated disaccharide, we considered that this enzyme cleaved the alginate at the second glycoside linkage from the reducing terminus. The primary structure of HdAlex was deduced with cDNAs amplified from an abalone hepatopancreas cDNA library by the polymerase chain reaction. The translational region of 822 bp in the total 887-bp sequence of HdAlex cDNA encoded an amino-acid sequence of 273 residues. The N-terminal sequence of 16 residues, excluding the initiation methionine, was regarded as the signal peptide of this enzyme. The amino-acid sequence of the remaining 256 residues shared 62-67% identities with those of the polysaccharide lyase family-14 (PL14) enzymes such as HdAly and turban-shell alginate lyase SP2. To our knowledge, HdAlex is the first exolytic oligoalginate lyase belonging to PL14.     

Molecular cloning and characterization of Mn-superoxide dismutase from disk abalone (Haliotis discus discus)

The mitochondrial enzyme manganese superoxide dismutase (mitMn-SOD) is one of the antioxidant enzymes involved in cellular defense against oxidative stress and catalyzes the conversion of O₂⁻ into the stabler H₂O₂. In this study, a putative gene encoding Mn-SOD from disk abalone (Haliotis discus discus, aMn-SOD) was cloned, sequenced, expressed in Escherichia coli K12(TB1) and the protein was purified using pMAL protein purification system. Sequencing resulted ORF of 681 bp, which corresponded to 226 amino acids. The protein was expressed in soluble form with molecular weight of 68 kDa including maltose binding protein and pI value of 6.5. The fusion protein had 2781 U/mg activity. The optimum temperature of the enzyme was 37 °C and it was active in a range of acidic pH (from 3.5 to 6.5). The enzyme activity was reduced to 50% at 50 °C and completely heat inactivated at 80 °C. The alignment of aMn-SOD amino acid sequence with Mn-SODs available in NCBI revealed that the enzyme is conserved among animals with higher than 30% identity. In comparison with human mitMn-SOD, all manganese-binding sites are also conserved in aMn-SOD (H28, H100, D185 and H189). aMn-SOD amino acid sequence was closer to that of Biomphalaria glabrata in phylogenetic analysis.