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In order to clarify whether the planktivorous silver carp and bighead carp can collect phytoplankton as small asCyclotella(<20 μm) in Donghu Lake, studies on phytoplankton in their gut contents and feces were made in 1990. The fish were cultured in both net cage in Donghu Lake and aquaria with the lake water. Past the intestine, the average valve diameter ofCyclotella changed little. The average ratio of empty frustule ofCyclotella to totalCyclotella in the foregut contents of the fishes were 1.8–1.9 times higher than that in the lake water, but changed little from foregut to feces. The aquarium experiment showed that both carps could collect particles as small as 8–10 μm, which was obviously narrower than the distance between their gill rakers. Probably, secretion of mucus plays an important role in collecting such small particles.  相似文献   
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海洋硅藻硅质细胞壁结构的形成机理研究概述   总被引:5,自引:0,他引:5  
硅藻具有形态各异、结构复杂、精美绝伦的硅质细胞壁,是海洋中进行生物硅化最主要的生物体。硅质细胞壁的形成同样是一个错综复杂的过程,它涉及硅藻细胞将硅酸从胞外转运到胞内;硅酸在细胞内的转移;在硅沉积囊泡(SDV)中的浓缩沉积;最后合成具种类特异性的细胞壁。重点介绍硅酸转运基因(SITs)的分子特征与作用机制;与生物硅化相关的三种蛋白即硅体蛋白(frus-tulins)、亲硅蛋白(silaffins)和侧壁蛋白(pleuralins)的结构与功能;硅质结构如何在硅沉积囊泡内最终形成的模式。  相似文献   
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商晓梅  孙军  信业宏  张珊 《海洋科学》2020,44(5):149-155
硅藻是海洋浮游植物主要类群和海洋生态系统的重要初级生产者,其硅质壁的存在使其成为了海洋生物硅的最大贡献者,而且成为海洋碳汇的主要来源。因此,硅质壁形成机制的阐明至关重要。硅酸盐转运是硅藻硅质壁形成中的关键,阐明其转运机制对建立硅藻代谢途径模型和进一步理解硅藻在海洋生态系统及生物地球化学循环中的作用具有重大意义。硅酸盐转运子(silicate transporter,SIT)是硅藻中参与硅吸收或转运的一类膜蛋白,因其重要性及多样性成为讨论及研究的焦点。本文综述了硅藻中SIT的分子特征、分子机制、功能多样性及进化关系,为SIT转运机制的研究提供了理论基础。  相似文献   
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The paper aims to expand the application of natural marine algae.Marine diatoms,which have intricate frustule structures,can serve as bio-template for preparing three-dimensional materials.A simple and effective approach to synthesize the corrugated agaric-like biomorphic TiO 2 templated with frustule of Coscinodiscus sp.is reported.In the sol-gel preparation process,the titania-coating on the frustule is prepared through the deposition and condensation with the aid of acetylacetone(acac) as a controlling agent to make the precursor Ti(BuO) 4 hydrolyze slowly.The as-prepared titania-coated frustule and biomorphic TiO 2 is characterized by scanning electron microscopy(SEM) attached with energy dispersive X-ray spectrometer(EMAX) and X-ray diffraction(XRD).The microstructure of the corresponding titania nanoparticles appears to be sphere with the diameters distributed around 10 20 nm.The templating process is repeated for three cycles.Subsequently,the three-dimensional freestanding corrugated agaric-like biomorphic TiO 2 structure is obtained by a selective removal in the NaOH solution.As far as we known,the 3D freestanding corrugated agaric-like biomorphic TiO 2 with greatly increased surface area is obtained for the first time.  相似文献   
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In order to clarify whether the planktivorous silver carp and bighead carp can collect phytoplanktonas small as Cyclotella(<20μm)in Donghu Lake,studies on phytoplankton in their gut contents and feceswere made in 1990.The fish were cultured in both net cage in Donghu Lake and aquaria with the lakewater.Past the intestine,the average valve diameter of Cyclotella changed little.The average ratio of emptyfrustule of Cyclotella to total Cyclotella in the foregut contents of the fishes were 1.8—1.9 times higherthan that in the lake water,but changed little from foregut to feces.The aquarium experiment showedthat both carps could collect particles as small as 8-10μm, which was obviously narrower than the dis-tance between their gill rakers.Probably,secretion of mucus plays an important role in collecting suchsmall particles  相似文献   
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硅藻具有形态各异、结构复杂、精美绝伦的硅质细胞壁,是海洋中进行生物硅化最主要的生物体。硅质细胞壁的形成同样是一个错综复杂的过程,它涉及硅藻细胞将硅酸从胞外转运到胞内;硅酸在细胞内的转移;在硅沉积囊泡(SDV)中的浓缩沉积;最后合成具种类特异性的细胞壁。重点介绍硅酸转运基因(SITs)的分子特征与作用机制;与生物硅化相关的三种蛋白即硅体蛋白(frustulins)、亲硅蛋白(silaffins)和侧壁蛋白(pleuralins)的结构与功能;硅质结构如何在硅沉积囊泡内最终形成的模式。  相似文献   
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