棒络新妇和悦目金蛛拖丝超微结构与力学行为

采用SEM对棒络新妇Nephila clavata腹部向上和向下在水平纱窗上爬行时纺出的拖丝、悦目金蛛Argiope amoena捕食拖丝与垂直向下缓慢纺出的拖丝及其圆网的铆钉丝进行了超微结构观察,采用电子单纤强力仪对棒络新妇拖丝与悦目金蛛圆网铆钉丝进行了力学拉伸试验.结果 表明棒络新妇和悦目金蛛拖丝均呈现出一至多根细丝纤维的多样化超微结构特征,其中悦目金蛛圆网铆钉丝还呈现出"S"形似弹簧的结构.两种蜘蛛丝的力学行为和性能与各自的功能要求相一致.蜘蛛能调节拖丝的超微结构、纤维组成和直径大小以适应其在不同环境条件下对力学性能和功能的瞬时需要.研究结果有助于拓宽和加深人们对蜘蛛丝超微结构、力学性能与生物学功能之间关系的认识和理解.     

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。     

悦目金蛛和棒络新妇卵袋丝物理化学结构表征及其力学性能研究

蜘蛛丝是一种具有优良机械性能的天然动物蛋白纤维,它特有的结构和性能与其生物学功能密切相关。作者采用氨基酸自动分析仪、傅立叶转换红外光谱仪、扫描电镜和电子单纤强力仪对悦目金蛛（Argiope amoena）和棒络新妇（Nephila clavata）的卵袋丝进行了物理化学结构表征与力学性能的研究,结果表明两种蜘蛛卵袋均由微米级柱状腺丝、大壶状腺丝、亚微米级或纳米级葡萄状腺丝构成。卵袋丝的表面形貌特征、极性氨基酸含量、大侧链与小侧链氨基酸的比值、无定型区、β-折叠结构与结晶结构的含量等氨基酸组成种类与蛋白质二级结构特征,均满足各自生物学功能对断裂强度、延展性、初始模量等力学性能的要求。     

悦目金蛛3种蛛丝超微结构和理化特性的初步研究

利用扫描电镜、氨基酸分析仪、X-衍射仪和单纤维电子强力仪分别对悦目金蛛Argiopeamoena拖丝、网框丝和卵袋丝的超微结构和理化特性进行了测试和观察。结果表明,悦目金蛛卵袋不是由一种结构均一的丝纤维构成,而是由直径相差悬殊的Ⅰ型卵袋丝和Ⅱ型卵袋丝2种丝纤维共同组成,该结果对卵袋丝仅由管状腺产生的观点提出了疑问。在氨基酸组成上悦目金蛛拖丝和网框丝相似,但其卵袋丝的氨基酸组成与拖丝和网框丝相比差别明显。另外还发现卵袋丝的强度、结晶度大于拖丝和网框丝,而它的延伸性能却不及拖丝和网框丝。     

悦目金蛛卵袋的结构与组成

采用SEM和氨基酸自动分析仪对悦目金蛛(Argiope amoena)卵袋的结构、纤维组成和覆盖层的氨基酸组成进行了观察研究.结果表明悦目金蛛卵袋呈封闭的倒三角形,是由多种丝腺纺出的丝纤维形成的多个覆盖层构成的,从外向内分别为:金黄色大壶状腺框架丝,灰绿色、浅棕色、白色外覆盖层和棕色内覆盖层,其中外覆盖层是由6根大直径(约4.8-6.8 μm) 柱状腺丝纤维和一些小直径(约0.26-0.76 μm)纤维混合成的基本纤维束单元所折叠成的片层丝被构成的,小直径丝纤维的数量从灰绿色丝被(外)到白色丝被(内)逐渐增加,而内覆盖层仅仅是由6根大直径(约5.20 μm)柱状腺丝纤维构成的基本纤维束单元折叠而成.卵袋外覆盖层丝(白色绒状纤维除外)的甘氨酸、丙氨酸和丝氨酸等氨基酸的百分含量分别介于卵袋内覆盖层丝和葡萄状腺丝相对应氨基酸的百分含量之间,这一数据支持Foradori等关于卵袋小直径丝纤维是由葡萄状腺纺出的推论.悦目金蛛能调节卵袋层丝的颜色、直径、覆盖层丝纤维和氨基酸的组成,使卵袋获得各方面最优化的功能,为卵或若蛛提供支持和保护.     

两种小型蜘蛛卵袋超微结构与纤维组成

采用SEM和氨基酸自动分析仪对暗蛛科Amaurobiidae白斑隐蛛Nurscia albofasciata和园蛛科Araneidae长脸艾蛛Cyclosa omonaga两种小型蜘蛛卵袋的超微结构、丝纤维和覆盖层的氨基酸组成进行了观察研究,并根据氨基酸的组成和电镜扫描的图片分析了不同直径丝纤维的丝腺来源.结果表明这两种蜘蛛卵袋特征结构与纤维组成有较大差异.白斑隐蛛卵袋呈封闭的圆饼状,由白色框丝层(主要含有大壶状腺丝)、浅棕色外覆盖层(主要含有柱状腺与葡萄状腺丝)和黄色内覆盖层(只含有柱状腺丝)构成,覆盖层较致密.而长脸艾蛛卵袋呈开放的椭球状,由金黄色外覆盖层(主要含有大壶状腺丝)和白色内覆盖层(只含有柱状腺丝)构成,覆盖层较疏松.这些差异可能与它们各自的繁殖策略及若蛛生长发育特点有关.     

棒络新妇卵袋结构与组成

采用SEM和氨基酸自动分析仪对棒络新妇 Nephila clavata 卵袋进行了结构观察和氨基酸组成分析.结果 表明棒络新妇的卵袋呈开放的网筛椭球状,结构简单,分为框架(大壶状腺丝)、金黄色或白色外层(主要含大壶状腺丝)和白色内层(主要含柱状腺丝)三部分,内外层都是由大(approx. 6～13 μm)、中(1.25～3.0 μm)、小(approx. 0.7～0.8 μm)直径的丝纤维构成.卵袋框丝和外层丝的氨基酸组成相似,甘氨酸(分别占22.9%和32.5%)和丙氨酸(占24%左右)的含量最丰富,其次是谷氨酸(占16.5%左右)和丝氨酸(分别占8.3%和3%),苏氨酸含量低(分别占2.12%和0.68%).与外层丝相比,卵袋内层丝纤维丝氨酸和苏氨酸的含量显著增加,分别为19.1%和6.11%左右,同时甘氨酸的含量显著减少,为7.2%左右,谷氨酸和脯氨酸的含量较低.大小侧链氨基酸比值(LC:SC)分析表明卵袋内层丝(1.03)﹥卵袋框丝(0.85)＞卵袋外层丝(0.66)≈拖牵丝(0.64)＞蚕丝(0.34),似乎表明卵袋框丝是不同于同纺自大壶状腺的典型蛛丝(拖牵丝)的新型蛛丝纤维.卵袋内层的主要构成成分是另一种具有截然不同氨基酸组成的柱状腺丝.棒络新妇能调节卵袋层丝的颜色、直径、丝纤维的组成及覆盖层的氨基酸组成,使卵袋获得各方面最优化的功能,为卵或若蛛提供支持和保护.     

3种中型蜘蛛卵袋形态特征与纤维组成结构

采用扫描电镜和氨基酸自动分析仪对球蛛科(Theridiidae)温室拟肥腹蛛(Parasteatodatepidariorum)、肖蛸蛛科(Tetragnathidae)肩斑银鳞蛛(Leucauge blanda)及狼蛛科(Lycosidae)猴马蛛(Hippasa holmerae)3种中型蜘蛛卵袋的超微结构和氨基酸组成进行了观察。形态观察表明,这3种蜘蛛的卵袋形态各异,温室拟肥腹蛛卵袋一头尖,呈梨状;肩斑银鳞蛛卵袋呈扁平状;猴马蛛卵袋呈椭球形。扫描电镜观察表明,温室拟肥腹蛛卵袋外覆盖层仅仅由一种均一直径的柱状腺丝组成,而另外2种蜘蛛卵袋外覆盖层主要由柱状腺丝与少量其他丝腺纺出的丝纤维组成。氨基酸组成分析表明,温室拟肥腹蛛卵袋外覆盖层的丝纤维的氨基酸组成与具有保守性的其他种类蜘蛛柱状腺丝心蛋白的氨基酸组成差异较大,这表明其可能含有新的丝心蛋白家族成员。本文根据氨基酸组成与扫描电镜的结果分析探讨了不同直径丝纤维的丝腺来源。     

4种常见蜘蛛蛛丝光学显微镜观察及机械性能的测定

对4种常见蜘蛛大腹园蛛Araneus ventricosus、迷宫漏斗蛛Agelena labyrinthica、草间钻头蛛Hylyphantes graminicola和棒络新妇Nephila clavata蛛丝的物理特性和机械性能进行了初步研究.结果 表明:捕丝是由2根核心丝构成,4种蛛丝呈现不同的颜色;4种蜘蛛蛛丝的密度略有不同,棒络新妇的蛛丝密度最大,草间钻头蛛的蛛丝密度最小;蛛丝中棒络新妇的断裂伸长率和断裂强度都最大,分别为47.3%和852.6 Nmm-2,草间钻头蛛蛛丝的断裂伸长率和断裂强度都最小,分别为32.1%和652.3 Nmm-2.与其它物理化学材料相比,蛛丝具有优异的综合力学性能,生物学特性与生物学功能具有高度一致性.     

蜘蛛丝的组成结构与生物学功能

蜘蛛是纺丝种类最多的一种节肢动物,目前共发现有8种丝腺,各纺出具有不同生物学功能的丝纤维,可分别用于织网、捕食、逃避、扩散、织制卵袋等行为活动。蜘蛛丝是一种天然的动物蛋白纤维,是随蜘蛛4亿年进化的结果,也是为蜘蛛的生存与繁殖所设计的,蜘蛛丝的适应与进化使蜘蛛丝具有多样化的生物学功能。但蜘蛛不是唯一能纺丝的节肢动物,除蛛形纲以外,还有其它很多节肢动物,如昆虫纲和多足纲的动物都有具有丝腺,能纺出一种或多种丝蛋白纤维。本文将以昆虫作为比较来概述蜘蛛丝腺的起源与种类,蜘蛛丝的化学组成、结构、种类与其生物学功能。     

Microstructure of the silk spigots of the green crab spider Oxytate striatipes (Araneae: Thomisidae)

The genus Oxytate L. Koch, 1878 comprises a homogeneous group of nocturnal crab spiders that have silk apparatuses even though they do not spin webs to trap prey. We examined the microstructure of the silk spinning apparatus of the green crab spider Oxytate striatipes, using field emission scanning electron microscopy. The silk glands of the spider were classified into three types: ampullate, pyriform and aciniform. The spigots of these three types of silk gland occur in both sexes. Two pairs of major ampullate glands send secretory ductules to the anterior spinnerets, and another two pairs of minor ampullate glands supply the median spinnerets. In addition, the pyriform glands send ductules to the anterior spinnerets (45 pairs in females and 40 pairs in males), and the aciniform glands feed silk into the median (9–12 pairs in females and 7–10 pairs in males) and the posterior (30 pairs in both sexes) spinnerets. The spigot system of O. striatipes is simpler and more primitive than other wandering spiders: even the female spiders possess neither tubuliform glands for cocoon production nor triad spigots for web‐building.     

Spinneret Microstructure of the Silk Spinning Apparatus in the Crab Spider, Misumenops tricuspidatus (Araneae: Thomisidae)

The silk spinning apparatus in the crab spider, Misumenops tricuspidatus was studied with the field emission scanning electron microscope (FESEM) and the main microstructural characteristics of the silk glands are presented. In spite of the fact that the crab spiders do not spin webs to trap a prey, they also have silk apparatus even though the functions are not fully defined. The crab spider, Misumenops tricuspidatus possesses only three types of silk glands which connected through the typical spinning tubes on the spinnerets. The spinning apparatus of Misumenops closely corresponds to that of wandering spiders such as jumping spiders or wolf spiders except some local variations. Anterior spinnerets comprise 2 pairs of the ampullates and 48 (±5) pairs of pyriform glands. Another 2 pairs of ampullate glands and nearly 20 (±3) pairs of aciniform glands were connected on the middle spinnerets. Additional 50 (±5) pairs of the aciniform glands were connected on the posterior spinnerets. The aggregate glands and the flagelliform glands which have the function of sticky capture thread production in orb‐web spiders as well as the tubuliform glands for cocoon production in females were not developed at both sexes of this spider, characteristically.     

Microstructure of the silk apparatus of the comb-footed spider, Achaearanea tepidariorum (Araneae: Theridiidae)

The microstructural organization of the silk‐spinning apparatus of the comb‐footed spider, Achaearanea tepidariorum, was observed by using a field emission scanning electron microscope. The silk glands of the spider were classified into six groups: ampullate, tubuliform, flagelliform, aggregate, aciniform and pyriform glands. Among these, three types of silk glands, the ampullate, pyriform and aciniform glands, occur only in female spiders. One (adult) or two (subadult) pairs of major ampullate glands send secretory ductules to the anterior spinnerets, and another pair of minor ampullate glands supply the median spinnerets. Three pairs of tubuliform glands in female spiders send secretory ductules to the median (one pair) and posterior (two pairs) spinnerets. Furthermore, one pair of flagelliform glands and two pairs of aggregate glands together supply the posterior spinnerets, and form a characteristic spinning structure known as a “triad” spigot. In male spiders, this combined apparatus of the flagelliform and the aggregate spigots for capture thread production is not apparent, instead only a non‐functional remnant of this triad spigot is present. In addition, the aciniform glands send ductules to the median (two pairs) and the posterior spinnerets (12–16 pairs), and the pyriform glands feed silk into the anterior spinnerets (90–100 pairs in females and 45–50 pairs in males).     

Microstructure of the silk apparatus in the coelotine spider Paracoelotes spinivulva (Araneae: Amaurobiidae)

The microstructural characteristics of the silk‐spinning apparatus and its ecological significance in the coelotine spider Paracoelotes spinivulva were examined by field emission scanning electron microscopy, with the goal of understanding the properties and the evolutionary origins of these silk constructs. The silk apparatuses of this spider were composed of four basic types of silk‐spinning spigot (ampullate, pyriform, aciniform and tubuliform), which connected with typical silk glands in the abdominal cavity. Of the three pairs of spinnerets, the posterior pairs were highly elongated along the body axis. Anterior spinnerets comprised two pairs of ampullate glands and approximately 70–80 pairs of pyriform glands in both sexes. Middle spinnerets had one to two pairs of ampullate spigots, three pairs of tubuliform spigots in females, and 50–60 (female) or 80–90 (male) pairs of aciniform spigots. An additional two pairs of tubuliform spigots in females and 70–80 (female) or 100–120 (male) pairs of aciniform spigots were counted on the spinning surfaces of the posterior spinnerets in both sexes. Although the coelotine spiders use their silk to catch prey, P. spinivulva characteristically do not have a typical “triad” spigot, including a flagelliform and two aggregate spigots, for capture thread production.     

Fine Structural Analysis of the Silk Apparatus in the Funnel-web Spider, Agelena limbata (Araneae: Agelenidae)

ABSTRACT Silk apparatus of the funnel-web spider, Agelena limbata was located at the ventral end of the abdominal part, and was composed of internal silk glands and external spinnerets. Among the three pairs of spinnerets, the posterior pairs were highly elongated along the body axis. By the light and electron microscopic inspections, it was found that four types of silk glands were connected through the typical spinning tubes of each spinneret. Anterior spinnerets comprise 2 pairs of the ampullate and 125 to 150 pairs (female) or 110 to 114 (male) of pyriform glands. Another 2 pairs of ampullate glands in both sexes, 5 to 8 pairs of tubuliform glands in females, and 20 to 26 pairs (female) or 15 to 17 pairs (male) of aciniform glands were connected on the median spinnerets. Additional 8 to 10 pairs of tubuliforms in female and 41 to 53 pairs (female) or 27 to 32 pairs (male) of aciniform glands were on the posterior spinnerets, respectively. While the ampullate and tubuliform glands were connected with the spigot-type spinning tubes, the pyriform and aciniform glands with that of spool-type tubes. It has been also revealed that the tubuliform glands were only observed in female spiders, however the flagelliform and aggregate glands which had the function of adhesive thread production in orb-web spiders were not observed at both sexes of this spiders.     

2种织圆网蜘蛛个体大小与蛛网粘丝区面积间关系

在不惊扰蜘蛛的情况下对悦目金蛛Argiope amoena和圆尾肖蛸Tetragnatha vermiformis的个体大小与蛛网粘丝区面积问的相关性进行了野外观察。主要测量了蜘蛛体长、蛛网粘丝区直径、蛛网框丝固着点间最大距离、网中枢到地面或水面距离、网平面与水平线的夹角等参数;另外还对蛛网框丝固着点间最大距离作为圆网蛛网址选择行为量化指标的可行性进行了探讨。结果表明,2种蜘蛛体长与蛛网粘丝区面积以及蜘蛛体长与蛛网框丝固着点间最大距离均呈现明显的正相关。悦目金蛛体长与蛛网粘丝区面积的相关性高于圜尾肖蛸,这可能与悦目金蛛在其生境中易于找到框丝固着点、而圆尾肖蛸在其生境中较难找到框丝同着点有关;