A safety band prevents falling of the suspended pupa of the butterfly Inachis io (Nymphalidae) during moult. A comparison with the girdled pupa of Pieris brassicae (Pieridae, Lepidoptera)

 During the pupal moult the suspended prepupa of the butterfly Inachis io completely removes its larval skin (exuvia) from the body. In doing this, the attachment to a silken pad has to be transferred from the anal prolegs of the prepupa to the cremaster of the pupa without losing the hold at any time. Falling is prevented by a short safety band which is drawn off from the innermost layer of the exuvia as it adheres to two prominent, pupal projections when the exuvia is slipped backwards. The projections which lie on the ventral side of the last abdominal segment are covered with numerous, minute spines each orientated in the opposite direction to the removal of the exuvia. The transparent safety band has a gelatinous consistency and is strong enough to withstand the fivefold load of a pupa. By contrast, the prepupa of Pieris brassicae is additionally held in place during moult by a girdle around the back. It usually rests in an upright position. Nevertheless, the pupa also shows the prominent projections covered with spines. The exuvia is held fast by the projections, but only a fold is formed. The formation of a safety band is never observed. The connection of the exuvia to the projections is sufficient to hold the tip of the abdomen within reach of the pad for hooking the cremaster therein. However, the pupae of those species in Satyrinae which pupate lying in cocoons or cells lack any kind of projections as well as spines. Accepted: 21 January 1998     

Rhythmic leaf movements in biloxi soybean and their relation to flowering

The rhythmic leaf movement of Biloxi soybean (Glycine max) and its relationship to the rhythmic flowering response were studied. The movements of fully expanded trifoliate leaves were recorded with kymographs and time lapse photography in growth chambers. A comparison between the leaf movement rhythm and the rhythmic flowering response indicates that a high degree of similarity exists between the two rhythms. A definite relationship was shown to exist between the direction of the leaf movement and the photophil-photophobe phases of the rhythmic flowering response.     

The effect of lunisolar tidal acceleration on stem elongation growth,nutations and leaf movements in peppermint (Mentha × piperita L.)

• Orbital movement of the Moon generates a system of gravitational fields that periodically alter the gravitational force on Earth. This lunar tidal acceleration (Etide) is known to act as an external environmental factor affecting many growth and developmental phenomena in plants. Our study focused on the lunar tidal influence on stem elongation growth, nutations and leaf movements of peppermint.
• Plants were continuously recorded with time‐lapse photography under constant illumination as well in constant illumination following 5 days of alternating dark–light cycles. Time courses of shoot movements were correlated with contemporaneous time courses of the Etide estimates. Optical microscopy and SEM were used in anatomical studies.
• All plant shoot movements were synchronised with changes in the lunisolar acceleration. Using a periodogram, wavelet analysis and local correlation index, a convergence was found between the rhythms of lunisolar acceleration and the rhythms of shoot growth. Also observed were cyclical changes in the direction of rotation of stem apices when gravitational dynamics were at their greatest. After contrasting dark–light cycle experiments, nutational rhythms converged to an identical phase relationship with the Etide and almost immediately their renewed movements commenced. Amplitudes of leaf movements decreased during leaf growth up to the stage when the leaf was fully developed; the periodicity of leaf movements correlated with the Etide rhythms.
• For the fist time, it was documented that lunisolar acceleration is an independent rhythmic environmental signal capable of influencing the dynamics of plant stem elongation. This phenomenon is synchronised with the known effects of Etide on nutations and leaf movements.

     

Silks produced by insect labial glands

Insect silks are secreted from diverse gland types; this chapter deals with the silks produced by labial glands of Holometabola (insects with pupa in their life cycle). Labial silk glands are composed of a few tens or hundreds of large polyploid cells that secrete polymerizing proteins which are stored in the gland lumen as a semi?liquid gel. Polymerization is based on weak molecular interactions between repetitive amino acid motifs present in one or more silk proteins; cross?linking by disulfide bonds may be important in the silks spun under water. The mechanism of long?term storage of the silk dope inside the glands and its conversion into the silk fiber during spinning is not fully understood. The conversion occurs within seconds at ambient temperature and pressure, under minimal drawing force and in some cases under water. The silk filament is largely built of proteins called fibroins and in Lepidoptera and Trichoptera coated by glue?type proteins known as sericins. Silks often contain small amounts of additional proteins of poorly known function. The silk components controlling dope storage and filament formation seem to be conserved at the level of orders, while the nature of polymerizing motifs in the fibroins, which determine the physical properties of silk, differ at the level of family and even genus. Most silks are based on fibroin β?sheets interrupted with other structures such as α?helices but the silk proteins of certain sawflies have predominantly a collagen?like or polyglycine II arrangement and the silks of social Hymenoptera are formed from proteins in a coiled coil arrangement.     

Fine structural analysis of the fibrillar adhesion apparatus in ladybird beetle

The attachment system on the ladybird beetle Harmonia axyridis is composed of a pair of pretarsal claws and adhesive pads at the tarsal segments. The claws, which are connected to the pretarsal segment, are mainly used to hold the rough substrates by their apical diverged hooks. In contrast, the adhesive pads have an adhesive function when landing on smooth surfaces. They are interspersed at the ventral adhesive pad of each tarsomere, and are composed of two kinds of hairy setae. The discoid tip seta (DtS) is located at the central region of each adhesive pad. The DtS has a spoon‐shaped endplate with a long and narrow shaft. In contrast, the pointed tip seta (PtS) is interspersed along the marginal regions of each adhesive pad, and has a hook‐shaped spine near the tip. In the present study, we found numerous fine cuticular pores beneath the setae, which seem to be related to the secretion of some adhesive fluids. It may be deduced that ladybird beetles can attach to smooth surfaces more effectively by employing adhesive fluids filling in surface crevices to overcome problems cause by their larger size endplates.     

Properties of synthetic spider silk fibers based on Argiope aurantia MaSp2

Spiders have evolved a complex system of silk producing glands. Each of the glands produces silk with strength and elasticity tailored to its biological purpose. Sequence analysis of the major ampullate silk reveals four highly conserved concatenated blocks of amino acids: (GA) n , A n , GPGXX, and GGX. While the GPGXX motif, which has been hypothesized to be responsible for the extensibility of the fiber, displays natural variation in its precise sequence arrangement and content, correlating these differences with particular fiber properties has been difficult. Three genetic constructs based on the Argiope aurantia sequence were engineered to progressively increase the number of GPGXX repeats in a head-to-tail assembly prior to interruption by another motif. Circular dichroism and Fourier transform infrared spectroscopy of synthetic spider silk spin dopes show secondary structures that correspond to an increase in the repeat number of GPGXX regions and an increase in the extensibility of synthetically spun recombinant fibers.     

Synthetic spider silk fibers spun from Pyriform Spidroin 2, a glue silk protein discovered in orb-weaving spider attachment discs

Spider attachment disc silk fibers are spun into a viscous liquid that rapidly solidifies, gluing dragline silk fibers to substrates for locomotion or web construction. Here we report the identification and artificial spinning of a novel attachment disc glue silk fibroin, Pyriform Spidroin 2 (PySp2), from the golden orb weaver Nephila clavipes . MS studies support PySp2 is a constituent of the pyriform gland that is spun into attachment discs. Analysis of the PySp2 protein architecture reveals sequence divergence relative to the other silk family members, including the cob weaver glue silk fibroin PySp1. PySp2 contains internal block repeats that consist of two subrepeat units: one dominated by Ser, Gln, and Ala and the other Pro-rich. Artificial spinning of recombinant PySp2 truncations shows that the Ser-Gln-Ala-rich subrepeat is sufficient for the assembly of polymeric subunits and subsequent fiber formation. These studies support that both orb- and cob-weaving spiders have evolved highly polar block-repeat sequences with the ability to self-assemble into fibers, suggesting a strategy to allow fiber fabrication in the liquid environment of the attachment discs.     

Les rythmes endogènes des mouvements foliaires chez Mimosa pudica L.

Abstract

Endogenous Rhythms in Mimosa pudica L. Leaf Movements.

The rhythmic movements performed by the leaves of the “Sensitive plant”, Mimosa pudica L., observed by time lapse photography, result of periodical turgor variations taking place in the parenchymatous cells of specialized motor organs. These turgor variations are associated with membrane permeability changes and ionic movements. These leaf movements allow to specify the temporal organization of this plant. Statistical analysis of observed periodicities in leaf movement shows that, in alternating conditions of light and dark (L/D:14/10) three distinct rhythms exist: a circadian rhythm synchronized by the photoperiodic cycle (τ = 24 hrs), and two ultradian rhythms with mean period values 3.8 hrs and 0.5 hrs respectively. In constant conditions from germination (L/L), the leaf behavior is strongly modified, but the three period values are found again (mean period values of 25.1 hrs, 3.5 hrs and 0.6 hrs respectively). The occurence of many rhythms with various periods taking place in the same organ is discussed in reference to observations effected on other biological subjects. Then, it appears that the period value within 2 and 4 hrs may be considered as a characteristic one in plants.     

The pupa of Calamoceras illiesi Malicky & Kumanski, 1974 (Trichoptera Calamoceratidae)

The previously unknown pupa of Calamoceras illiesi Malicky & Kumanski, 1974 is described and illustrated, based on material collected from northwestern Turkey. It is compared with Calamoceras marsupus Brauer, 1865, the second species of the genus Calamoceras found in western Europe. The pupa of C. illiesi is very different from that of C. marsupus, in particular in having a flattened abdomen, the arrangement of the transversal fringes of the abdominal segments, the shape of the sclerotised hook plate of abdominal segment I, and the shape of the anal processes.     

Enhanced stiffness of silk‐like fibers by loop formation in the corona leads to stronger gels

We study the self‐assembly of protein polymers consisting of a silk‐like block flanked by two hydrophilic blocks, with a cysteine residue attached to the C‐terminal end. The silk blocks self‐assemble to form fibers while the hydrophilic blocks form a stabilizing corona. Entanglement of the fibers leads to the formation of hydrogels. Under oxidizing conditions the cysteine residues form disulfide bridges, effectively connecting two corona chains at their ends to form a loop. We find that this leads to a significant increase in the elastic modulus of the gels. Using atomic force microscopy, we show that this stiffening is due to an increase of the persistence length of the fibers. Self‐consistent‐field calculations indicate a slight decrease of the lateral pressure in the corona upon loop formation. We argue that this small decrease in the repulsive interactions affects the stacking of the silk‐like blocks in the core, resulting in a more rigid fiber.     

Investing in attachment: evolution of anchoring structures in acanthocephalan parasites

Secure attachment to host tissues is essential for survival and reproduction in parasitic organisms. The production of elaborate attachment structures must be costly, however, and investments in attachment should be approximately proportional to the likelihood that a parasite will be dislodged. In the present study, relative investments in attachment as a function of body size and the type of host used were examined across 138 species of acanthocephalans. These worms live anchored to the intestinal wall of a vertebrate host by inserting their hooked proboscis into host tissues. Taking proboscis volume into account, there is a negative interspecific relationship between the number of hooks borne on the proboscis and their mean length, reflecting a trade‐off between hook number and hook length. This supports the assumption that hooks are costly to produce, because any given species cannot simultaneously maximize both the relative number and relative length of the hooks it produces. There is a positive relationship between total worm size and total hook length, but it is weak, with a slope indicating that, as total body volume increases, total hook length also increases but at a slower rate. Indeed, relative investments in attachment, measured as hook length per unit body volume, decrease as worm size increases. Independently of total body size, investments in hook production are higher in species exploiting endothermic hosts, especially birds, than in those living in ectothermic hosts. Given the greater amounts of food passing through the gut of endotherms, and the richer and denser communities of intestinal parasites that they harbour, they are likely to select for greater investments in attachment. These results support the prediction that investments in attachment are influenced by the probability of being dislodged, and allow comparisons with other groups of intestinal parasites such as cestodes or trematodes. © 2007 The Linnean Society of London, Biological Journal of the Linnean Society, 2007, 90 , 637–645.     

Spinning activity of the spider Trogloneta granulum (Araneae, Mysmenidae): web, cocoon, cocoon handling behaviour, draglines and attachment discs

The spider species Trogloneta granulum, which in the wild lives inside scree slopes, builds three-dimensional orb webs. During egg-laying and egg sac building, the females stay with their dorsa down at the central part of the web. In this process, the hub is used as a platform. The threads of the hub are not incorporated into the silk cover of the egg sac. The silk wall of the egg sac is very thin, with all the silken threads constituting it having a uniform ultrastructure. The silk wall of the egg sac and the spinnerets are permanently linked by a dragline. Draglines produced by T. granulum affect the direction of movements of the female carrying its cocoon. Egg sacs are handled using draglines. The low number of piriform glands leads to the formation of very simple attachment discs, which fix the individual threads to the substratum. Thread bundles are attached to the substratum by means of accumulated attachment discs.     

Silk produced by hornets: thermophotovoltaic properties-a review

This article deals with the silk weave produced by pupating larvae of the Oriental hornet and its electric properties. Larvae of this hornet commence pupation at approximately 2 weeks of age. Creation of the cocoonal silk weave requires a number of hours and the encased pupa remains in the cocoon for approximately 2 more weeks before ecloding as an adult. The silk weave is initially of a creamish white color, but gradually becomes brown-gray owing to the activity of certain bacteria secreted in the silk. The silk weave is composed of fibers arranged in multiple layers with interposed surfaces occupying a considerable part of the area and containing pockets of bacteria. The spun silk contains both metallic and non-metallic elements, mostly K and Cl but also Mg, P, S, Ca, Ti and V. Shaped as a dome, the silk projects considerably beyond the cell proper, contributing importantly to its total volume and providing a shield for the contained pupa against predators, parasites, or extreme changes in temperature, as well as affording a 'sterile and clean room' in which the pupa can form its new cuticle without the interference of contaminating dust particles or the turbulence of air currents. The silk is endowed with electric properties. Inter alia, a thermoelectric phenomenon was observed in the dark, namely, upon increase in temperature the current rose to several hundred nano Amperes (nA); in light, a photovoltaic effect was observed involving voltages of several dozen millivolts (mV), with a sharp transition between the current and voltage during transition from darkness to light. Also recorded was a very high electric capacitance, amounting to scores of milli farads (mF). In all, the pupal silk behaves like an organic semiconductor, in that its electric properties are temperature-dependent, and it also displays ferroelectric properties. Additionally, a luminescence phenomenon was recorded on the silk, wherein excitation at wavelengths within the UV(i.e. 249, 290 and 312 nm) range yielded an emission spectrum at a wavelength of 450 and of 530 nm. The silk caps are anisotropic in that the emission from the outside is lower than that from the inside. By way of recap, the various mentioned properties of the pupal silk are discussed from their biological and physical aspects.     

A structural view on spider silk proteins and their role in fiber assembly

Spider silk is the toughest known biomaterial and even outrivals modern synthetic high‐performance materials. The question of understanding fiber formation is how the spider can prevent premature and fatal aggregation processes inside its own body and how the chemical and mechanical stimuli used to induce the fiber formation process translate into structural changes of the silk material, finally leading to controlled and irreversible aggregation. Here, the focus will be on the structure and function of the highly conserved N‐domains and C‐terminal domains of spider dragline silk which, unlike the very long repetitive sequence elements, adopt a folded conformation in solution and are therefore able to control intermolecular interactions and aggregation between other spider silk molecules. The structures of these domains add valuable details for the construction of a molecular picture of the complicated and highly optimized silk assembly process that might be beneficial for large‐scale in vitro fiber formation attempts with recombinant silk material. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.     

Mechanical Response of Silk Crystalline Units from Force-Distribution Analysis

The outstanding mechanical toughness of silk fibers is thought to be caused by embedded crystalline units acting as cross links of silk proteins in the fiber. Here, we examine the robustness of these highly ordered β-sheet structures by molecular dynamics simulations and finite element analysis. Structural parameters and stress-strain relationships of four different models, from spider and Bombyx mori silk peptides, in antiparallel and parallel arrangement, were determined and found to be in good agreement with x-ray diffraction data. Rupture forces exceed those of any previously examined globular protein many times over, with spider silk (poly-alanine) slightly outperforming Bombyx mori silk ((Gly-Ala)_n). All-atom force distribution analysis reveals both intrasheet hydrogen-bonding and intersheet side-chain interactions to contribute to stability to similar extent. In combination with finite element analysis of simplified β-sheet skeletons, we could ascribe the distinct force distribution pattern of the antiparallel and parallel silk crystalline units to the difference in hydrogen-bond geometry, featuring an in-line or zigzag arrangement, respectively. Hydrogen-bond strength was higher in antiparallel models, and ultimately resulted in higher stiffness of the crystal, compensating the effect of the mechanically disadvantageous in-line hydrogen-bond geometry. Atomistic and coarse-grained force distribution patterns can thus explain differences in mechanical response of silk crystals, opening up the road to predict full fiber mechanics.     

Use of time‐lapse photography and digital image analysis to estimate breeding success of a cliff‐nesting seabird

Development of new methods for obtaining basic demographic data from difficult‐to‐access breeding colonies and easily disturbed species is an important challenge in studies of seabirds. We describe a method that can generate data concerning annual breeding success of cliff‐nesting seabirds or other colonial birds with open nests. Our method requires only a single visit to a colony every second or third year, and is based on the use of automated time‐lapse photography. To test our method, we used time‐lapse photos to examine the breeding success of Thick‐billed Murres (Uria lomvia) in two breeding colonies in Greenland during the years 2011, 2012, and 2014. Based on the analysis of time‐lapse photos, we found that hatching success during the 3 yr of our study ranged from 60% to 81%, fledging success from 89% to 95%, and breeding success from 53% to 74% (Table 1). Use of digital image analysis made it possible to differentiate between breeding and non‐breeding birds and determine if and when breeding attempts failed or succeeded. The key to making our method a realistic long‐term monitoring technique is the use of an automated, formal image analysis to process the thousands of photos from the time‐lapse cameras and, more specifically, to reduce a large number of photos to a manageable number. Using our method, we needed 12–22 h per study plot, depending on the number of breeding sites per plot (range = 47–127) and whether it was the first or the second time the plot was analyzed, to obtain our estimates of hatching, fledging, and breeding success. This included time for data preparation, image analyses, visual inspections, and summarizing data in a spreadsheet. We found that our estimates of breeding success were comparable to those obtained by direct observation in the field. An important aspect of using time‐lapse technology is to foresee potential reasons why time‐lapse cameras might stop taking pictures, for example, equipment failure (camera, timer, or battery) or interference by visitors (e.g., vandalism or theft). As such, thorough testing of time‐lapse systems and selecting camera locations less likely to be disturbed are most important. We believe that use of time‐lapse photography in combination with digital image analysis to estimate breeding success can be useful for determining the breeding success of other cliff‐nesting seabirds and, more generally, other birds that breed in colonies, especially those located in remote areas and where direct observation may disturb birds.     

Synthetic spider silk: a modular fiber

Spiders make their webs and perform a wide range of tasks with up to seven different types of silk fiber. These different fibers allow a comparison of structure with function, because each silk has distinct mechanical properties and is composed of peptide modules that confer those properties. By using genetic engineering to mix the modules in specific proportions, proteins with defined strength and elasticity can be designed, which have many potential medical and engineering uses.     

Silk tape nanostructure and silk gland anatomy of trichoptera

Caddisflys (order Trichoptera) construct elaborate protective shelters and food harvesting nets with underwater adhesive silk. The silk fiber resembles a nanostructured tape composed of thousands of nanofibrils (～ 120 nm) oriented with the major axis of the fiber, which in turn are composed of spherical subunits. Weaker lateral interactions between nanofibrils allow the fiber to conform to surface topography and increase contact area. Highly phosphorylated (pSX)(4) motifs in H-fibroin blocks of positively charged basic residues are conserved across all three suborders of Trichoptera. Electrostatic interactions between the oppositely charged motifs could drive liquid-liquid phase separation of silk fiber precursors into a complex coacervates mesophase. Accessibility of phosphoserine to an anti-phosphoserine antibody is lower in the lumen of the silk gland storage region compared to the nascent fiber formed in the anterior conducting channel. The phosphorylated motifs may serve as a marker for the structural reorganization of the silk precursor mesophase into strongly refringent fibers. The structural change occurring at the transition into the conducting channel makes this region of special interest. Fiber formation from polyampholytic silk proteins in Trichoptera may suggest a new approach to create synthetic silk analogs from water-soluble precursors.     

Silk fiber mechanics from multiscale force distribution analysis

Here we decipher the molecular determinants for the extreme toughness of spider silk fibers. Our bottom-up computational approach incorporates molecular dynamics and finite element simulations. Therefore, the approach allows the analysis of the internal strain distribution and load-carrying motifs in silk fibers on scales of both molecular and continuum mechanics. We thereby dissect the contributions from the nanoscale building blocks, the soft amorphous and the strong crystalline subunits, to silk fiber mechanics. We identify the amorphous subunits not only to give rise to high elasticity, but to also ensure efficient stress homogenization through the friction between entangled chains, which also allows the crystals to withstand stresses as high as 2 GPa in the context of the amorphous matrix. We show that the maximal toughness of silk is achieved at 10–40% crystallinity depending on the distribution of crystals in the fiber. We also determined a serial arrangement of the crystalline and amorphous subunits in lamellae to outperform a random or a parallel arrangement, putting forward what we believe to be a new structural model for silk and other semicrystalline materials. The multiscale approach, not requiring any empirical parameters, is applicable to other partially ordered polymeric systems. Hence, it is an efficient tool for the design of artificial silk fibers.