三种类型蜘蛛丝的结构及生物学功能

利用付里叶变换红外光谱仪(FFIR)对棒络新妇(Nephila clavata)、悦目金蛛(Argiope amoena)的大壶状腺丝(拖丝)、悦目金蛛的捕丝(粘性螺旋丝)和卵袋丝这3种不同类型蜘蛛丝的二级结构进行了测试研究。结果表明：蜘蛛丝同时包含无规则卷曲、α-螺旋和β-折叠构象;对这3种蛛丝的红外光谱进行比较表明同一蜘蛛的不同类型蛛丝所含的这3种二级结构的比例不同,这种不同组成的二级结构就赋予了蜘蛛丝不同的特性,这种特性又与其不同的功能相适应。此外,还用扫描电镜(SEM)和光学显微镜对悦目金蛛和小悦目金蛛(A．minuta)的拖丝和捕丝做了形态结构观察。蜘蛛丝这种天然动物蛋白纤维所具有的特殊的形态结构、蛋白质二级结构与其特殊的性能和生物学功能是高度一致的。     

蜘蛛丝蛋白的结构及其应用

蜘蛛的拖丝是一种既具有抗张强度又具有高度弹性的奇特蛋白质纤维。近看来,生物学者用现代生物工程技术和其它技术对蛛丝蛋白分子的结构和物理特性,主要是机械特性,进行了广泛深入的研究,取得了很大进展,指出了蛛丝蛋白的工业应用价值。1蛛丝蛋白结构研究进展概述编码一种拖丝蛋白（Spidroiril）的部分cDNA克隆以前已获分离产物,但是所预期的氨基酸顺序并不能解释拖丝蛋白的氨基酸组成。此后又分离出一种编码另一拖丝蛋白（SPidloin2）的部分dD：NA克隆,说明蜘蛛的拖丝是由复合蛋白组成的。Spidroin2的氨基酸顺序是一种与Spidro…     

肌动蛋白结构与生物学功能的研究进展

肌动蛋白是真核生物中表达最丰富的蛋白质之一,分布于整个细胞,肌动蛋白聚合形成微丝,微丝参与细胞众多的生物学过程.随着对肌动蛋白生物学特性研究的不断深入,它在分子生物学等方面的应用受到研究者的广泛关注.该文从分子生物学水平对肌动蛋白的结构、装配动力学以及生物学功能进行系统综述.     

蜘蛛丝蛋白的模块结构性能和重组表达

蜘蛛丝是一类天然蛋白质纤维,具有独特的机械性能（高强度、高弹性和高断裂功等）和卓著的生物学特性（生物可降解性和与生物组织的相容性等）,在生物医学、材料、纺织和军事等领域都有着很高的潜在应用价值。综述了不同蜘蛛丝蛋白的模块结构特征及与其功能的关系,扼要介绍了目前利用各种基因工程方法表达重组蜘蛛丝蛋白的研究进展。     

植物角质膜的结构、组成和生物学功能研究进展

植物角质膜是覆盖在植物最外层的一类有机混合物的总称,它是植物抵抗外界环境刺激的最后一道屏障,在植物生长发育过程中起重要作用。该文总结了近几十年来国内外关于角质膜的研究进展,通过植物角质膜的形态结构、化学组成、生物学功能等几个方面对角质膜的研究状况做系统综述,探讨目前研究中存在的一些问题,展望角质膜研究前景,以期为从事角质膜相关领域的研究提供可借鉴的参考依据。     

CD44的基因结构和生物学功能

ＣＤ４４分子由单基因编码,有１０个变异体外显子,能发生选择性拼接,产生多种ＣＤ４４分子,执行不同的生物学功能。     

蜘蛛丝蛋白的结构

很多蛋白在高浓度时都形成纤维状结构,可溶性变差。但蜘蛛网蛋白（有高度重复片段,侧面为非重复性末端区域）却有不同行为。     

细胞因子受体的组成,结构功能及信号传导机制

细胞因子受体种类繁多,分属于不同受体超家族。活化受体的功能可分为：ＰＴＫ型受体或其结合蛋白具有ＰＴＫ活性、丝／苏氨酸蛋白激酶型受体以及与Ｇ蛋白耦联的受体等。不同受体与其配体结合后,通过对受体后信号传导成分的可逆的磷酸化反应传递信号,最终通过对其终端成分,如酶活力、基因表达、细胞骨架蛋白的功能、膜通透性等的调节,导致细胞的生物效应。     

促性腺激素释放激素的结构及其生物学功能

促性腺激素释放激素(GnRH)是下丘脑分泌的十肽激素,是神经、免疫、内分泌三大调节系统互相联系的重要信号分子,对生殖调控具有重要意义.GnRH类似物是近年来应用最广的多肽类激素新药之一.就GnRH及其受体的结构及分布、GnRH在垂体和性腺水平调控生殖的一系列证据、影响GnRH释放的因素等进行了综述,并展望了GnRH研究的发展趋势及应用前景.     

厌氧氨氧化体的组成、结构与功能

厌氧氨氧化(Anammox)是微生物和环境领域的研究热点之一。厌氧氨氧化菌(AnAOB)是Anammox的功能载体。不同于大部分原核微生物,AnAOB具有独特的细胞器——厌氧氨氧化体,它是进行Anammox代谢的场所。研究厌氧氨氧化体有助于探明厌氧氨氧化菌的代谢特性。本文综述了厌氧氨氧化体的组成、结构与功能,以期为从事Anammox研究的同行提供参考。     

蜘蛛丝的分子结构与力学性能研究

蜘蛛丝尤其是蜘蛛大囊状腺产生的拖丝,具有独特的机械性能,是自然界颇具应用潜力的生物材料。现代分子生物学技术使蜘蛛丝蛋白基因得以克隆,通过高分子物理化学手段方法的利用,有利于揭示蜘蛛丝蛋白质序列、分子结构、以及分子结构和力学性能之间的关系。对不同种类蜘蛛丝蛋白的深入研究,将为基因工程方法人工合成并改造蜘蛛丝成为可能。     

三种蜘蛛丝蛋白组成分析

本文应用高压液相色谱（ＨＰＬＣ）法分析了岳麓山的大腹园蛛Ａｒａｎｅｕｓ ｖｅｎｔｒｉｃｏｓｕｓ（Ｃ．Ｋｏｃｈ,１８７８）,机敏漏头蛛Ａｇｅｌｅｎａ ｄｉｆｆｉｃｌｉｓ （Ｆｏｘ,１９３７）,白额巨蟹蛛Ｈｅｔｅｒｏｐｏｄａ ｖｅｎａｔｏｒｉａ （Ｌｉｎｎａｅｕｓ,１７５７）的丝蛋白的氨基酸组成,以ＳＤＳ－ＰＡＧＥ法测定了大腹园蛛不同丝腺体的未成丝的可溶性丝蛋白的分子量。实验结果表明蛛丝蛋白中占优势的     

悦目金蛛拖牵丝力学性能的变异

蜘蛛丝作为一种具有优良机械性能的天然动物蛋白纤维,其特有的结构和机械性能与其生物学功能密切相关。由大壶状腺纺出的拖牵丝在蜘蛛的行走、建网、捕食、逃生、繁殖等多种生命活动中均发挥了重要的功能,其机械性能会受到多种内外因素相互作用的影响。本文对在不同体重、不同猎物饲养和不同营养状态3种条件下人工抽出的悦目金蛛(Argiope amoena)拖牵丝与其不同单丝间的力学性能进行了比较研究。结果表明,悦目金蛛拖牵丝的力学性能在组间、组内不同个体,以及同一个体不同丝纤维间变异都较大。随着蜘蛛个体的增大,蛛丝横截面直径逐渐增大,这会使得蛛丝的力学性能更好,便于作为救命索的拖牵丝在遇到危险时承受蜘蛛体重;蜘蛛在经过1个月的饥饿后,蛛丝在屈服点附近的力学性能并未发生显著变化,而断裂点应变和断裂能均显著减小,同时也表明无论对于作为救命索还是网丝,拖牵丝的弹性形变性能在与蛛丝相关的微观进化中要优先于塑性形变。这是蜘蛛在能量摄入受到限制时对拖牵丝的投入权衡的结果。     

Fine structural aspects of silk secretion in a spider. II. Conduction in the pyriform glands

The excretory duct of pyriform glands in Araneus diadematus is connected to the secretory sac through an intermediary cell ring. Apices of these cells bear thick, long microvilli and cytoplasmic extensions containing microtubules in bundles, some of which are derived from normal basal bodies. These finger-like extensions lie between the cuticular intima and the secretory product; they are thought to protect the intima and to initiate moulding of the silk thread. Structural features of the duct cells suggest that the latter play a role in the control of the water content of the silk glue which is restricted to the last portion of the duct where numerous nerve endings are inserted between cells. It is evident that duct structure and chemical and physical characteristics of silk are correlated in all spider silk glands.     

Inter-specific sequence conservation and intra-individual sequence variation in a spider silk gene

Currently, studies on major ampullate spidroin 1 (MaSp1) genes of non-orb weaving spiders are few, and it is not clear whether genes of these organisms exhibit the same characteristics as those of orb-weavers. In addition, many studies have proposed that MaSp1 might be a single gene with allelic variants, but supporting evidence is still lacking. In this study, we compared partial DNA and amino acid sequences of MaSp1 cloned from different spider guilds. We also cloned partial MaSp1 sequences from genomic DNA and cDNA of the same individuals of spiders using the same primer combination to see if different molecular forms existed. In the repetitive region of partial MaSp1 sequences obtained, GGX, GA and poly-A motifs were present in all Araneomorphae and Mygalomorpae species examined. An extreme similarity in MaSp1 non-repetitive portions was found in sequences of ecribellate, cribellate and Mygalomorphae web-builders and such a result suggested that this sequence might exhibit an important function. A comparison of sequences amplified from the same individual showed that substitutions in amino acids occurred in both repetitive and non-repetitive regions, with a much higher variation in the former. These results suggest that the MaSp1 of Araneomorphae spiders exhibits several forms in an individual spider and it might be either a multiple gene or a single gene with a multiple exon/intron organization.     

外源丙氨酸提高蜘蛛牵引丝蛋白天然基因在原核系统中的表达

蜘蛛丝蛋白天然基因的体外表达受诸多因素的限制。本研究在获得生长于中国的Nephila clavipes蜘蛛牵引丝蛋白Spidroin2 cDNA（Genbank Accession No. AF441245）的基础上,利用限制性内切酶双酶切反应构建含有Spidroin2 cDNA的重组表达质粒pET-28b(+)-Sp。将该质粒转化至大肠杆菌BL21（DE3）宿主细胞感受态菌中,以不同浓度的IPTG进行诱导,并通过诱导时间、培养温度、加入外源丙氨酸等途径提高Spidroin2 cDNA的表达量,同时利用多克隆抗体对表达产物进行Western blot检测。重组质粒pET-28b(+)-Sp的测序结果表明Spidroin2 cDNA基因以正确的阅读框插入到原核表达载体中;SDS-PAGE结果表明菌体表达蛋白中存在着大小约为31 kDa的目的蛋白带（加入外源丙氨酸条件下）,Western blot检测结果进一步证实,目的基因在大肠杆菌中得到正确表达。本研究证实,蜘蛛牵引丝蛋白Spidroin2 cDNA可在原核细胞内正确表达,外源丙氨酸的加入对于提高天然蜘蛛丝蛋白基因在原核系统的表达作用明显。     

Damping capacity is evolutionarily conserved in the radial silk of orb-weaving spiders

Orb-weaving spiders depend upon their two-dimensional silk traps to stop insects in mid flight. While the silks used to construct orb webs must be extremely tough to absorb the tremendous kinetic energy of insect prey, webs must also minimize the return of that energy to prey to prevent insects from bouncing out of oscillating webs. We therefore predict that the damping capacity of major ampullate spider silk, which forms the supporting frames and radial threads of orb webs, should be evolutionarily conserved among orb-weaving spiders. We test this prediction by comparing silk from six diverse species of orb spiders. Silk was taken directly from the radii of orb webs and a Nano Bionix test system was used either to sequentially extend the silk to 25% strain in 5% increments while relaxing it fully between each cycle, or to pull virgin silk samples to 15% strain. Damping capacity was then calculated as the percent difference in loading and unloading energies. Damping capacity increased after yield for all species and typically ranged from 40 to 50% within each cycle for sequentially pulled silk and from 50 to 70% for virgin samples. Lower damping at smaller strains may allow orb webs to withstand minor perturbations from wind and small prey while still retaining the ability to capture large insects. The similarity in damping capacity of silk from the radii spun by diverse spiders highlights the importance of energy absorption by silk for orb-weaving spiders.     

海南稻田蜘蛛群落的结构和动态

报道海南省琼山县稻田蜘蛛群落的物种组成及其优势种群的动态变化。已鉴定的稻田蜘蛛种类有４９种,分属１１分科。食早 瘤蛛Ｕｍｍｅｌｉａｔａ ｉｎｓｅｃｔｉｃｅｐｓ Ｂｏｅｓ．ｅｔ Ｓｔｒ．、草间钻头蛛Ｈｙｌｙｐｈａｎｔｅｓ ｇｒａｍｉｎｉｃｏｌｕｍ（Ｓｕｎｄｅｖａｌｌ）、拟水狼蛛Ｐｉｒａｔａ ｓｕｂｐｉｒａｔｉｃｕｓ（Ｂｏｅｓ．ｅｔ Ｓｔｒ．）、拟环纹豹蛛Ｐａｒｄｏｓａ ｐｓｅｕｄｏａｎｎｕｌａｔａ（     

Silk as an innovative biomaterial for cancer therapy

Silk has been used for centuries in the textile industry and as surgical sutures. In addition to its unique mechanical properties, silk possesses other properties, such as biocompatibility, biodegradability and ability to self-assemble, which make it an interesting material for biomedical applications. Although silk forms only fibers in nature, synthetic techniques can be used to control the processing of silk into different morphologies, such as scaffolds, films, hydrogels, microcapsules, and micro- and nanospheres. Moreover, the biotechnological production of silk proteins broadens the potential applications of silk. Synthetic silk genes have been designed. Genetic engineering enables modification of silk properties or the construction of a hybrid silk. Bioengineered hybrid silks consist of a silk sequence that self-assembles into the desired morphological structure and the sequence of a polypeptide that confers a function to the silk biomaterial. The functional domains can comprise binding sites for receptors, enzymes, drugs, metals or sugars, among others. Here, we review the current status of potential applications of silk biomaterials in the field of oncology with a focus on the generation of implantable, injectable and targeted drug delivery systems and the three-dimensional cancer models based on silk scaffolds for cancer research. However, the systems described could be applied in many biomedical fields.