大腹园蛛管状腺丝重组蛋白的克隆表达及纺丝

TuSp1蛋白(tubuliform spidroin 1)是管状腺丝(tubuliform silkfiber)的主要组成成分。管状腺丝作为蛛丝卵袋的外层包卵丝,其结构具有很好的耐腐蚀性和良好的力学性能。目前国内外对大腹园蛛TuSp1蛋白的研究很少,仅有一条基因序列的报道。本课题首次构建含大腹园蛛N端非重复结构域、重复单元以及C端非重复结构域的重组管状腺丝蛋白TuSp1 NT-Rp-CT,并经湿法纺丝获得重组蛋白丝纤维。重组蛋白液圆二色谱分析结果显示,pH由7. 0降低到5. 5的过程中,始终保持稳定的α-螺旋构象;重组蛋白丝纤维的傅里叶变换红外光谱结果显示,丝纤维中主要二级结构为β-折叠及β-转角;经扫描电镜观察发现,冻干的絮状重组蛋白能自组装成丝纤维,且表面光滑纤细;湿纺后的重组蛋白丝纤维直径较粗,但表面较平整均匀,具有类似天然管状腺丝的形态特征,这些为TuSp1蛋白的成丝机理及仿生纺丝研究提供了理论依据。     

Prey attraction as a possible function of the silk decoration of the uloborid spider Octonoba sybotides

Both laboratory experiments and field observations were usedto examine the prey-attraction hypothesis for the function ofthe silk decoration on the orb web of Octonoba sybotides. Thereflectance spectrum of the decorative silk showed that thedecorations reflect relatively more ultraviolet (UV) light.Choice experiments were conducted using Drosophila melanogaster,a common prey species of the spider, to determine whether webswith silk decoration attract more flies than undecorated webs.The choice experiment showed that webs with silk decorationattract more flies in light that includes UV rays. However,flies choose their flight direction randomly in light withoutUV rays. This suggests that the silk decoration might attract preyinsects that tend to fly toward UV-reflecting objects. Fieldobservations comparing the prey capture rate between webs withand without a silk decoration showed that more prey are caughtin decorated webs. In this study, no difference between thetwo forms of silk decoration, linear and spiral, was detectedeither in prey attraction in the choice experiment or in theprey capture rate in the field observations.     

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.     

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;     

Silk Spinning Behavior and Domicile Construction in Webspinners

Analysis of spinning and of silk domiciles revealed similarities and differences for three species of embiids: Antipaluria urichi (Saussure), Pararhagadochir trinitatis (Saussure), and Oligotoma saundersii (Westwood). Each exhibited similar routines while spinning; they positioned the silk by touching the substrate with either front tarsus and by moving the leg to the next position, with many silk strands issuing forth at each step. Reinforced pathways developed as they spun while traveling from diurnal retreats and nocturnal foraging zones. Frass from the interior of their domiciles was spun into the silk. O. saundersii was unique in that it plastered its silk with gathered materials. Analysis of field colonies of P. trinitatis and O. saundersii showed that, like A. urichi, adult females share their silk with offspring and, often, with other females.     

Intraspecific variation in Gape–prey size Relationships and Feeding Success During Early Ontogeny in Red Drum, Sciaenops Ocellatus

The relationship between predator gape and prey consumption in laboratory-reared larva and field-caught early juvenile red drum, Sciaenops ocellatus, was investigated in light of the hypothesis that feeding success varies throughout the early life history intervals of marine fishes. We expected the feeding ability of red drum to be more strongly constrained by mouth gape in smaller fish and expected this ability to improve with gape size. To test this hypothesis, field-caught, early juvenile red drum were examined to determine the relationship between gape size and prey size consumed. In field-caught early juveniles, gape (height and width) and prey size consumed (length and width) increased linearly with standard length (SL); however, mean width of prey consumed was only 20–47% of gape width. Furthermore, when regressed on SL, gape width yielded a higher slope than prey width. To further test this hypothesis on less developed, pre-metamorphic fish, age-specific differences in gape, number of prey and size of prey consumed prior to metamorphosis were determined from laboratory-reared red drum larvae. Similar patterns were observed for gape height– and gape width–SL relationships in laboratory-reared red drum larvae. Size of consumed prey increased from three days from hatching (dfh) to 18dfh. The percentage of feeding larvae also increased from 3% at 3dfh to 97% at 18dfh. In both field-caught, early juvenile red drum and laboratory-reared larvae, there was little evidence that the size of prey consumed was constrained by mouth gape. It is hypothesized that besides gape size, the development of other features of the feeding mechanism (e.g., hyoid and opercular series) influences prey-capture performance prior to settlement in marine fishes.     

Food capture kinematics of the suction feeding horn shark, Heterodontus francisci

The goal of this study was to examine the feeding kinematics of the horn shark, Heterodontus francisci, a member of the most basal clade of galeomorph sharks, the Heterodontiformes. The accessibility of the food was manipulated to determine if the horn shark modulated capture. Three different methods of presenting food were used to mimic the different positions of prey items found in the natural diet of the horn shark. Food was presented unattached to the substrate, securely attached, or fitted snugly in a tube. Using high-speed video kinematic analysis, capture events were examined. Heterodontus francisci uses inertial suction facilitated by rapid mandible depression and labial cartilage protrusion to capture food. The horn shark conforms to a capture kinematic profile characteristic of both basal and derived inertial suction feeding sharks. Unusual post-capture behaviors include body leveraging, use of the mouth to form a seal over food, and chisel-like palatoquadrate protrusion. When presented with food of different accessibility, Heterodontus francisci used one consistent kinematic pattern for capture that was not modulated. Only post-capture behaviors varied according to food accessibility.     

Different adaptation to visual hunting in three ground beetle species of the same genus

Compound eyes and hunting behaviour of three species of the genus Asaphidion de Gozis 1886 (Coleoptera, Carabidae) have been investigated. All three have a fovea and binocular overlap in their frontal fields of vision. In the smallest species A. flavipes, the binocular overlap is largest and the foveal interommatidial angles are narrowest. All three species hunt by visual cues; A. flavipes is the most precise during the approach to the prey and during the attack. The mean size of its approach jerks and its critical distance prior to the attack are shorter than those of A. caraboides, and the scatter of these distances is much smaller. This leads to greater success in capturing fast fleeing prey (Collembola) on the soil surface.     

Switched-angle spinning applied to bicelles containing phospholipid-associated peptides

In a model study, the proton NMR spectrum of the opioid pentapeptide leucine-enkephalin associated with bicelles is investigated. The spectral resolution for a static sample is limited due to the large number of anisotropic interactions, in particular strong proton–proton couplings, but resolution is greatly improved by magic-angle sample spinning. Here we present two-dimensional switched-angle spinning NMR experiments, which correlate the high-resolution spectrum of the membrane-bound peptide under magic-angle spinning with its anisotropic spectrum, leading to well-resolved spectra. The two-dimensional spectrum allows the exploitation of the high resolution of the isotropic spectrum, while retaining the structural information imparted by the anisotropic interactions in the static spectrum. Furthermore, switched-angle spinning techniques are demonstrated that allow one to record the proton spectrum of ordered bicellar phases as a function of the angle between the rotor axis and the magnetic field direction, thereby scaling the dipolar interactions by a predefined factor.     

Diurnal Tiger Beetles (Coleoptera: Cicindelidae) Capture Prey Without Sight

Although much research has examined the process of prey capture by tiger beetles, an underlying assumption in this work is that tiger beetles are principally, or even exclusively, visual predators. Because this assumption is untested, we performed a series of experiments on four diurnally active tiger beetles in the Genus Cicindela. Individual beetles were placed in chambers in complete darkness and allowed to forage on apterous Drosophila for 6 h. Contrary to expectations, adults of all tested species captured more than 90% of prey items. These results show that other modalities can be used by tiger beetles during prey capture. Beyond potentially providing an explanation for observed night activity in tiger beetle species, the significance of these findings lies in the need to test underlying assumptions of even well-studied organisms.     

The functional morphology of the praying mantis forelimb (Dictyoptera: Mantodea)

The structure and function of the forelimbs of praying mantids are discussed. A large spine on the femur and the spine on the end of the tibia were shown experimentally to be important in the capture of unrestrained flies. These spines may function to narrow the gap through which a fly may escape while the tibia is closing on the femur. Some of the spines on the femur are hinged at their base; the structure, properties and possible functions of these spines are discussed.
Similar hinged spines are reported on the lorelimbs of Stomatopoda (CrustaceaI but were not found in the Mantispidac (Neuroptera:Insecta). The variation of forelimb structure within the Mantodea is briefly discussed. The theory that the optimum prev size can be predicted from the geometry of the mantid forelimb is critically discussed.