Spinning Glands Research Articles

Overexpressed Artificial Spidroin Based Microneedle Spinneret for 3D Air Spinning of Hybrid Spider Silk.

Efforts have been devoted to developing strategies for converting spider silk proteins (spidroins) into functional silk materials. However, studies mimicking the exact natural spinning process of spiders encounter arduous challenges. In this paper, consistent with the natural spinning process of spiders, we report a high-efficient spinning strategy that enables the mass preparation of multifunctional artificial spider silk at different scales. By simulating the structural stability mechanism of the cross-β-spine of the amyloid polypeptide by computer dynamics, we designed and obtained an artificial amyloid spidroin with a significantly increased yield (13.5 g/L). Using the obtained artificial amyloid spidroin, we fabricated artificial spiders with artificial spinning glands (hollow MNs). Notably, by combining artificial spiders with 3D printing, we perform patterned air spinning at the macro- and microscales, and the resulting patterned artificial spider silk has excellent pump-free liquid flow and conductive and frictional electrical properties. Based on these findings, we used macroscale artificial spider silk to treat rheumatoid arthritis in mice and micro artificial spider silk to prepare wound dressings for diabetic mice. We believe that artificial spider silk based on an exact spinning strategy will provide a high-efficient way to construct and modulate the next generation of smart materials.

Early lecithotrophic stages of Nymphon grossipes, and the role of larval appendages and glands in different larval types of pycnogonids.

Nymphon grossipes is a common subtidal species belonging to a small and unique group of chelicerates, that is, the sea spiders. These animals have an anamorphic phase during post-embryonic development and often hatch as small, oligomeric and exotrophic larvae (protonymphons) with four postocular segments, cheliphores, and two pairs of larval legs. A common alternative to protonymphons is a large lecithotrophic larval type, where animals hatch at more advanced stages and have a foreshortened anamorphic development. Based on external morphology, N. grossipes was believed to be an intriguing intermediate between these two conditions and its hatchlings were called "lecithotrophic protonymphons." Here, we examine the anatomy and ultrastructure of instars I and II and review the variety of roles of larval appendages and associated glands in other sea spiders in order to correctly place the larva of this species among pycnogonid larval types. Compared to "typical protonymphons," N. grossipes young hatch with an advanced segmental and appendage composition: six postocular segments instead of four, buds of walking legs 1 and hidden buds of walking legs 2. This state corresponds to the instars II/III (rather than larvae) of Nymphon brevirostre and Pycnogonum litorale. Modifications of the larval appendages, chelar, and spinning glands are aligned with ecological needs of different larval types along a few typical dimensions: locomotion and feeding, dispersal, and attachment to the parent. Although the main challenge for N. grossipes young is secure attachment to the egg package while they growth, there are some discrepancies in their anatomy: N. grossipes retains an oyster basket, but an otherwise nonfunctional digestive system, and a strong silken thread for attachment, but no corresponding reduction of the larval legs. Thus, it is likely that the switch to lecithotrophy happened in the recent evolutionary history of this species.

Notopodial “spinning glands” of Sthenelanella (Annelida: Sigalionidae) are modified chaetal sacs

AbstractSthenelanella is an unusual genus of tube‐dwelling scale worms, with fine fibrous threads that appear on either side of the body. These fibers emerge dorsally in long silvery bundles that are then tightly interwoven to construct the felt‐like material of the tube. In the literature, these fibers are described as the products of so‐called “spinning glands.” In this article, we investigated the ultrastructure of these notopodial fibers and show that they are annelid chaetae. Three or four dynamic microvilli of a basal chaetoblast form each of these feltage chaetae, making them the thinnest known annelid bristles. Our results show that the spinning glands of Sthenelanella uniformis are additional, highly modified notopodial chaetal sacs. We also show that the follicle cells, by their secretion of the enamel layer, play an active role in shaping the final chaeta. These findings not only increase the known morphological diversity of chaetae but also demonstrate the apparent plasticity of the machinery that form these chitinous structures. Our results are compared with chaetae in other annelids, with a particular focus on similar fibrous chaetae in Aphroditiformia.

Silk nanofibril self-assembly versus electrospinning.

Natural silk fibers represent one of the most advanced blueprints for (bio)polymer scientists, displaying highly optimized mechanical properties due to their hierarchical structures. Biotechnological production of silk proteins and implementation of advanced processing methods enabled harnessing the potential of these biopolymer not just based on the mechanical properties. In addition to fibers, diverse morphologies can be produced, such as nonwoven meshes, films, hydrogels, foams, capsules and particles. Among them, nanoscale fibrils and fibers are particularly interesting concerning medical and technical applications due to their biocompatibility, environmental and mechanical robustness as well as high surface-to-volume ratio. Therefore, we introduce here self-assembly of silk proteins into hierarchically organized structures such as supramolecular nanofibrils and fabricated materials based thereon. As an alternative to self-assembly, we also present electrospinning a technique to produce nanofibers and nanofibrous mats. Accordingly, we introduce a broad range of silk-based dopes, used in self-assembly and electrospinning: natural silk proteins originating from natural spinning glands, natural silk protein solutions reconstituted from fibers, engineered recombinant silk proteins designed from natural blueprints, genetic fusions of recombinant silk proteins with other structural or functional peptides and moieties, as well as hybrids of recombinant silk proteins chemically conjugated with nonproteinaceous biotic or abiotic molecules. We highlight the advantages but also point out drawbacks of each particular production route. The scope includes studies of the natural self-assembly mechanism during natural silk spinning, production of silk fibrils as new nanostructured non-native scaffolds allowing dynamic morphological switches, as well as studying potential applications. This article is categorized under: Biology-Inspired Nanomaterials > Peptide-Based Structures Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Biology-Inspired Nanomaterials > Protein and Virus-Based Structures.

Spinnerets and silk-producing system of Segestria senoculata (Araneae, Araneomorphae, Segestriidae)

The spinning apparatus and silk of <em>Segestria senoculata</em> were studied with the use of scanning electron microscopy and light microscopy, which confirmed the presence of four categories of spigots connected with four types of spinning glands (<em>i.e</em>., <em>Glandulae ampullaceae major, Glandulae ampullaceae minor, Glandulae piriformes and Glandulae pseudaciniformes</em>). New data about the morphology of spinnerets and spigots were obtained for both the adults and nymphal stages of both sexes. For the first time the silken threads of retreats, signal threads and attachment discs of the members of <em>Segestria</em> were subjected to a detailed SEM study. The data resulting from studying the spinning apparatus of <em>S. senoculata</em> was compared to current knowledge of the silk producing systems of families belonging to the Dysderoidea superfamily. Silks that are emitted from spigots in the course of retreat construction are not (similarly to the other dysderoids) processed by the spider’s legs during the subsequent process of hardening. Apart from the major ampullate glands/spigots, segestriids also possess developed minor ampullate glands. Minor ampullate threads are used by <em>S. senoculata</em> spiders when making their signal threads.

Silk fibers and silk‐producing organs ofHarpactea rubicunda(C. L. Koch 1838) (Araneae, Dysderidae)

Scanning electron microscopy and atomic force microscopy were used to study the silk spinning apparatus and silks of Harpactea rubicunda spiders. Three types of silk secretions that are produced by three kinds of silk spinning glands (ampullate, piriform, and pseudaciniform) and released through three types of spigots, were confirmed for both adult and juvenile spiders. Silk secretions for the construction of spider webs for shelter or retreat are produced by the pseudaciniform silk glands. Silk secretions that are released from spigots in the course of web construction are not processed by the legs during the subsequent process of hardening. Pairs of nanofibril bundles seemed to be part of the basic microarchitecture of the web silk fibers as revealed by AFM. These fiber bundles frequently not only overlap one another, but occasionally also interweave. This structural variability may strengthen the spider web. High-resolution AFM scans of individual nanofibrils show a distinctly segmented nanostructure. Each globular segment is ∼30-40 nm long along the longitudinal axis of the fiber, and resembles a nanosegment of artificial fibroin described by Perez-Rigueiro et al. (2007).

Spinning behaviour and morphology of the spinning glands in male and female Aposthonia ceylonica (Enderlein, 1912) (Embioptera: Oligotomidae)

Embioptera (webspinners) are unique among insects in that juvenile and adults of both sexes spin silk. They possess spinning apparatuses in the basitarsomeres of their prothoracic legs, which they use to build galleries as habitat and protection. Embioptera are primitively social and cooperate in building the galleries. They also show sexual dimorphism that comprises modifications of the mandibles in males, the winglessness of the females and differences in the morphology of the forelegs. In the present investigation we address the correlation of spinning behaviour and sexual dimorphism in the spinning apparatus of Aposthonia ceylonica (Enderlein, 1912). To analyse spinning behaviour we conducted video observations of Ap. ceylonica in artificial habitats. We observed females and males alone as well as female–male pairs to cover possible effects of interactions between sexes. The morphology of the spinning apparatus was analysed and reconstructed using high resolution X-ray computed tomography (SRμCT). The observations show that during trials of 24h adult males and females produce similar amounts of silk per body weight, despite the fact that adult males do not feed, perhaps due to modifications of their mandibles related to courtship that interfere with feeding. Spinning glands in males are distinctly smaller than in females in absolute values, which reflect the general size difference in females and males. Despite their smaller body size, the volumes of reservoirs of spinning glands are larger in males in relative as well as in absolute values. Together with spinning behaviour and the amount of silk production, this indicates that males produce and store gland secretions in the large reservoirs prior to their final moult for later use.

Review Protein families, natural history and biotechnological aspects of spider silk

Spiders are exceptionally diverse and abundant organisms in terrestrial ecosystems and their evolutionary success is certainly related to their capacity to produce different types of silks during their life cycle, making a specialized use on each of them. Presenting particularly tandemly arranged amino acid repeats, silk proteins (spidroins) have mechanical properties superior to most synthetic or natural high-performance fibers, which makes them very promising for biotechnology industry, with putative applications in the production of new biomaterials. During the evolution of spider species, complex behaviors of web production and usage have been coupled with anatomical specialization of spinning glands. Spiders retaining ancestral characters, such as the ones belonging to the Mygalomorph group, present simpler sorts of webs used mainly to build burrows and egg sacs, and their silks are produced by globular undifferentiated spinning glands. In contrast, Araneomorphae spiders have a complex spinning apparatus, presenting up to seven morphologically distinct glands, capable to produce a more complex set of silk polymers with different degrees of rigidness and elasticity associated with distinct behaviors. Aiming to provide a discussion involving a number of spider silks' biological aspects, in this review we present descriptions of members from each family of spidroin identified from five spider species of the Brazilian biodiversity, and an evolutionary study of them in correlation with the anatomical specialization of glands and spider's spinning behaviors. Due to the biotechnological importance of spider silks for the production of new biomaterials, we also discuss about the new possible technical and biomedical applications of spider silks and the current status of it.

Structure of silk by raman spectromicroscopy: From the spinning glands to the fibers

Raman spectroscopy has long been proved to be a useful tool to study the conformation of protein-based materials such as silk. Thanks to recent developments, linearly polarized Raman spectromicroscopy has appeared very efficient to characterize the molecular structure of native single silk fibers and spinning dopes because it can provide information relative to the protein secondary structure, molecular orientation, and amino acid composition. This review will describe recent advances in the study of the structure of silk by Raman spectromicroscopy. A particular emphasis is put on the spider dragline and silkworm cocoon threads, other fibers spun by orb-weaving spiders, the spinning dope contained in their silk glands and the effect of mechanical deformation. Taken together, the results of the literature show that Raman spectromicroscopy is particularly efficient to investigate all aspects of silk structure and production. The data provided can lead to a better understanding of the structure of the silk dope, transformations occurring during the spinning process, and structure and mechanical properties of native fibers.

Spinning gland transcriptomics from two main clades of spiders (order: Araneae)--insights on their molecular, anatomical and behavioral evolution.

Characterized by distinctive evolutionary adaptations, spiders provide a comprehensive system for evolutionary and developmental studies of anatomical organs, including silk and venom production. Here we performed cDNA sequencing using massively parallel sequencers (454 GS-FLX Titanium) to generate ∼80,000 reads from the spinning gland of Actinopus spp. (infraorder: Mygalomorphae) and Gasteracantha cancriformis (infraorder: Araneomorphae, Orbiculariae clade). Actinopus spp. retains primitive characteristics on web usage and presents a single undifferentiated spinning gland while the orbiculariae spiders have seven differentiated spinning glands and complex patterns of web usage. MIRA, Celera Assembler and CAP3 software were used to cluster NGS reads for each spider. CAP3 unigenes passed through a pipeline for automatic annotation, classification by biological function, and comparative transcriptomics. Genes related to spider silks were manually curated and analyzed. Although a single spidroin gene family was found in Actinopus spp., a vast repertoire of specialized spider silk proteins was encountered in orbiculariae. Astacin-like metalloproteases (meprin subfamily) were shown to be some of the most sampled unigenes and duplicated gene families in G. cancriformis since its evolutionary split from mygalomorphs. Our results confirm that the evolution of the molecular repertoire of silk proteins was accompanied by the (i) anatomical differentiation of spinning glands and (ii) behavioral complexification in the web usage. Finally, a phylogenetic tree was constructed to cluster most of the known spidroins in gene clades. This is the first large-scale, multi-organism transcriptome for spider spinning glands and a first step into a broad understanding of spider web systems biology and evolution.

Inżynierowany jedwab pajęczy: inteligentny biomateriał przyszłości. Część II

The development and progress in engineered spider silk manufacturing has enabled its practical application. Recombinant spider silk can assemble in several morphological forms such as films, hydrogels, fibers, scaffolds, microcapsules, and micro- and nanospheres. The in vitro fiber formation takes place by mimicking the natural spinning process in the spider spinning gland: in the presence of phosphate ions and dragging forces. Films are obtained by evaporation of solvent from the silk solution, while the result of evaporation of the solvent in the presence of porogens is a silk scaffold. Hydrogels are formed by spontaneous polymerization of silk particles in solutions at low pH. The silk film assembled at the interface of two immiscible phases forms microcapsules. The smallest of the described forms--silk spheres--are obtained by salting out the silk protein solution after addition of the phosphate ions. Common properties of the silk biomaterials are biocompatibility and biodegradability, which make them suitable for a number of applications in medicine and pharmacy. Moreover, the strategy of hybrid proteins which provides the desired function to biomaterial will further expand their potential use.

Book Review

Book Review

The spinning apparatus of Polenecia producta (Araneae, Uloboridae): Structure and histochemistry

The spinning apparatus of the uloborid spider Polenecia producta was studied to complete previous studies on the same family of spiders. The structure of spinnerets and spigots, under scanning electron microscopy, and the main anatomical and histochemical characteristics of the spinning glands of adult females and males are described. In addition some observations on the spinning apparatus at three successive stages of development are made. There are nine kinds of silk glands in Polenecia, i.e. one more (aciniform — B glands) than found in other uloborids. The spinning apparatus of Polenecia is, therefore, the most complex so far known. It is also more complex than that presently known of Araneoidea. The characteristics of the spinning glands of Polenecia are compared with those of other uloborids. Present knowledge of the spinning apparatus of uloborids leads to a renewed discussion of the origin of the orb web in this family and in araneids. It is concluded that these two types of orb webs emerged from independent evolutionary processes.

Changes in esterase activity in the spinning gland cells of Diacrisia obliqua (lepidoptera) during sequential stages of development.

Esterase activity has been studied for the first time during different phases of cellular activity i.e. growth, prefunctional, functional and post functional (degenerating) ones in the spinning gland cells of the Indian moth D. obliqua. Esterase activity is in keeping with the needs of energy of the growing spinning gland cells which is associated with increased metabolism of the cell rather than the secretion of silk. The enzyme also seems to play a significant role in the termination of larval period.

The chemical fractionation of the orb web of Argiope spiders

The orb webs of Argiope aurantia Lucas and Argiope trifasciata (Forskal) were partitioned into three major fractions: trypsin soluble fibroin, trypsin insoluble fibroin and a water soluble fraction. The gravimetric proportions of these were nearly equal in both species. The water soluble fraction was further fractionated into KH 2PO 4, ninhydrin reactive and ninhydrin negative components. The proportions of these differed widely between the two species. The amino acid composition of the trypsin soluble fibroin and trypsin insoluble fibroin was ascertained, as well as the spinning gland luminal contents in order to assign the probable glandular origin of these fractions. The trypsin insoluble fibroin originates primarily from the large ampullate gland whereas the trypsin soluble fibroin appears to be the product of several glands.

The fate of exotoxin of Bacillus thuringiensis in Galleria mellonella caterpillars

Three hours after parenteral administration of 32P-labeled exotoxin of Bacillus thuringiensis to caterpillars of Galleria mellonella, 80% of the radioactivity was localized in the hemolymph in the form of the original exotoxin. The remaining radioactivity occurred in the organs of the caterpillar, especially in the spinning glands and the intestine. After peroral administration, the exotoxin does not pass the intestinal wall into the hemolymph to a measurable degree. In this case, the exotoxin is split in the intestinal wall and the products of 32P reutilization have been found in the hemolymph. The mechanism of action of the exotoxin in the insect organism is discussed; presumably it depends on different ways of administration of the substance.

The Fate of the Intact Orb Web of the Spider Araneus Diadematus Cl. 1)

When spider webs were left intact in the aluminum-glass boxes in the laboratory, most animals ate old webs daily and built new ones. The new webs were built with a larger amount of thread protein, increasing steadily in weight with increasing length of the non-elimination period, to more than 3 times in 8 days. The increased amount of thread material was first used to build larger webs with a longer thread, and later larger webs with thicker threads. A change in the number of spiral turns always went together with a change in web size and/or the number of radii thus confirming PETER'S segment rule. Experiments with radioactive labeled webs indicated that some material for the new web came probably through ingestion and reexcretion of the old web's protein. But experiments with intact versus destroyed and non-eliminated webs showed that probably not only old web material but also the intact web structure were clues for larger new webs. The deterioration of silk as well as continuous new thread synthesis in the spinning glands are suspected as reasons for the frequent rebuilding of webs.

Étude quantitative de l'acide ribonucléique dans les glandes séricigènes chez Bombyx Mori L

Étude quantitative de l'acide ribonucléique dans les glandes séricigènes chez Bombyx Mori L

MICRURGICAL STUDIES ON PROTOPLASM1

Summary1. Relation between nucleus and cytoplasm. Evidence is reviewed of interrelations between the interkinetic nucleus and the cytoplasm, together with recent findings concerning such interrelations between the female nucleus, the male pronucleus, and the karyocytoplasm of the fertilized starfish egg.2. Structural components of the protoplasm. Relatively stable and unstable structures (sol‐gel transformations) can be distinguished. Illustrations are given of cell nuclei, some of which are liquid (spinning glands) so that the progressive deposition of viscid material in the cytoplasm distorts the nucleus into a highly multilobulated shape. Other nuclei (dipteran salivary glands) react as solids from being packed with chromosomes. The boundaries of these chromosomes can be detected by injecting carbon particles which collect in narrow spaces between them.3. Miscibility of protoplasm with water. Cells can be injected with water which spreads through the cytoplasm. More is tolerated if the water contains monovalent salts, particularly potassium chloride.4. Internal osmotic pressure. The capillarity of spaces within a living cell, e.g. muscle fibre, complicates the evaluation of osmotic pressures when determining the freezing‐point of the living cell interior. The question also arises whether the freezing‐point depression of cellular extracts is valid for determining the osmotic pressure of the living cell. Fundulus eggs, considered impermeable to water and to electrolytes, can be shown to be permeable to water by the fact that they develop high internal pressures when immersed in hypotonic solutions. The lack of swelling is due to the inelastic envelopes of the individual eggs.5. An electrolytic solution compatible with cytoplasm. The preparation of a solution approaching that of the interior of a myxomycete has been done by micro‐injecting solutions of varying constituents and ascertaining those exhibiting least toxicity.6. Extraneous coats. A study of the physical properties of the protoplasmic surface film is complicated by the presence of extraneous coats. The most generalized extraneous coat serves as an intercellular cement, the consistency of which is conditioned by the pH and the proportion of calcium and sodium in the medium. The permeability of multicellular membranes is affected by the condition of this cement.7. Hyaluronidase. A hyaluronidase‐like substance from sea‐urchin sperm dissolves the jelly coats of the eggs, but has no effect on the intercellular cement. In this way it resembles the hyaluronidase of mammals which dissolves the mucinous collagen but not the intercellular cement.8. The ‘plasma membrane’. Removal of extraneous coats leaves behind a bounding film on the protoplasm. This film has flowing characteristics and is liquid in the presence of calcium in the environment.9. The hydrogen‐ion concentration of the cell interior. The determination is valid for the continuous aqueous phase of protoplasm. The pH virage of this is slightly, if at all, affected by the presence of the living protein which is relatively inert. Intracellular vacuoles have their own pH values which are independent of the pH of the protoplasmic aqueous phase. Neutral red, a chloride of a coloured base, accumulates in acidic vacuoles and stains fatty globules, while phenol red, a sodium or potassium salt of coloured acid, colours the cytoplasm diffusely and only later tends to accumulate in alkaline vacuoles and in the nucleus which is alkaline.Therefore, in a consideration of the pH of protoplasm it is essential to take into account various factors. Lack of such consideration and the fact that certain regions in the cell are affected by variations in external pH have given rise to confusion in the literature. The only stable region which is well buffered and which, as long as the cell is alive, maintains a constant pH value, is the continuous aqueous phase of protoplasm, that of the cytoplasm being in the close neighbourhood of pH 6–8 and that of the cell nucleus, 7‐6‐7‐8.10. The action of salts on the interior of protoplasm. Reactions to the micro‐injection of salts indicate that the proteins in protoplasm are predominantly on the alkaline side of their isoelectric points. Calcium induces coagulation, while sodium and potassium have a dispersive action. In some cases, cell inclusions exist which are agglutinated by sodium chloride. This feature may lead to erroneous conclusions in centrifugation experiments in which the degree of sedimentation of visible granules is used as a criterion for viscosity.11. Living and dying protoplasm. Living proteins are relatively inert to chemical interaction. Upon the initiation of cytolysis the interactions become prominent accompanied by denaturation of the proteins. The acid of injury may be explained by the increase of ionizable carboxyl groups resulting from the conversion of protein macromolecules to low molecular weight proteins.12. Relation of structure to ‘one‐way’ permeability. The cells of the renal proximal tubule in tissue culture lose their ‘one‐way’ permeability to phenol red when they grow out as flattened sheets. They regain it on becoming oriented about incipient centres of secretion.

The Post-embryonic Development of Hanseniella agilis (Symphyla)

The Post-embryonic Development of Hanseniella agilis (Symphyla)