An unlikely silk: the composite material of green lacewing cocoons

Spiders routinely produce multiple types of silk; however, common wisdom has held that insect species produce one type of silk each. This work reports that the green lacewing ( Mallada signata, Neuroptera) produces two distinct classes of silk. We identified and sequenced the gene that encodes the major protein component of the larval lacewing cocoon silk and demonstrated that it is unrelated to the adult lacewing egg-stalk silk. The cocoon silk protein is 49 kDa in size and is alanine rich (>40%), and it contains an alpha-helical secondary structure. The final instar lacewing larvae spin protein fibers of approximately 2 microm diameter to construct a loosely woven cocoon. In a second stage of cocoon construction, the insects lay down an inner wall of lipids that uses the fibers as a scaffold. We propose that the silk protein fibers provide the mechanical strength of the composite lacewing cocoon whereas the lipid layer provides a barrier to water loss during pupation.     

Tissue-type plasminogen activator is a multiligand cross-beta structure receptor

Tissue-type plasminogen activator (tPA) regulates fibrin clot lysis by stimulating the conversion of plasminogen into the active protease plasmin. Fibrin is required for efficient tPA-mediated plasmin generation and thereby stimulates its own proteolysis. Several fibrin regions can bind to tPA, but the structural basis for this interaction is unknown. Amyloid beta (Abeta) is a peptide aggregate that is associated with neurotoxicity in brains afflicted with Alzheimer's disease. Like fibrin, it stimulates tPA-mediated plasmin formation. Intermolecular stacking of peptide backbones in beta sheet conformation underlies cross-beta structure in amyloid peptides. We show here that fibrin-derived peptides adopt cross-beta structure and form amyloid fibers. This correlates with tPA binding and stimulation of tPA-mediated plasminogen activation. Prototype amyloid peptides, including Abeta and islet amyloid polypeptide (IAPP) (associated with pancreatic beta cell toxicity in type II diabetes), have no sequence similarity to the fibrin peptides but also bind to tPA and can substitute for fibrin in plasminogen activation by tPA. Moreover, the induction of cross-beta structure in an otherwise globular protein (endostatin) endows it with tPA-activating potential. Our results classify tPA as a multiligand receptor and show that cross-beta structure is the common denominator in tPA binding ligands.     

Betabellins 15D and 16D, de Novo designed beta-sandwich proteins that have amyloidogenic properties

The betabellin structure is a de novo designed beta-sandwich protein consisting of two 32-residue beta-sheets packed against one another by hydrophobic interactions. d-Amino acid residues are used to energetically favor formation of type-I' beta turns. Air oxidation of betabellin 15S (B15S) (HSLTAKIpkLTFSIAphTYTCAVpkYTAKVSH, where p denotes d-Pro, h denotes d-His, and k denotes d-Lys) yields betabellin 15D (B15D), a 64-residue disulfide-bridged protein. The amino acid sequence of B15D contains a conformationally constrained d-Pro residue at the i + 1 position of each type-I' beta turn. To test whether d-Pro residues are necessary for folding at these positions, the six d-Pro residues of B15D are replaced by d-Ala residues in betabellin 16D (B16D). Previously, transmission electron microscopy showed that B15D forms unbranched, 35-A wide fibrils that associate into bundles in 5.0 mM 3-(N-morpholino)propanesulfonate and 250 mM NaCl at pH 7; under these conditions, B16D forms ribbon-like assemblies. The B15D fibrils resemble the protofilaments that constitute amyloid fibrils. The present studies show that both B15D and B16D have characteristics of amyloidogenic proteins: the unbranched fibrils and ribbons stained with Congo red and displayed a green birefringence, exhibited a cross-beta structure, and bound 1-anilino-8-naphthalenesulfonate. Thus, these de novo designed beta-sandwich proteins should provide useful models for studying the mechanism of amyloid protofilament formation and assembly into amyloid fibrils and for designing potential inhibitors of amyloidogenesis.     

The natural silk spinning process. A nucleation-dependent aggregation mechanism?

The spinning mechanism of natural silk has been an open issue. In this study, both the conformation transition from random coil to beta sheet and the beta sheet aggregation growth of silk fibroin are identified in the B. mori regenerated silk fibroin aqueous solution by circular dichroism (CD) spectroscopy. A nucleation-dependent aggregation mechanism, similar to that found in prion protein, amyloid beta (Abeta) protein, and alpha-synuclein protein with the conformation transition from a soluble protein to a neurotoxic, insoluble beta sheet containing aggregate, is a novel suggestion for the silk spinning process. We present evidence that two steps are involved in this mechanism: (a) nucleation, a rate-limiting step involving the conversion of the soluble random coil to insoluble beta sheet and subsequently a series of thermodynamically unfavorable association of beta sheet unit, i.e. the formation of a nucleus or seed; (b) once the nucleus forms, further growth of the beta sheet unit becomes thermodynamically favorable, resulting a rapid extension of beta sheet aggregation. The aggregation growth follows a first order kinetic process with respect to the random coil fibroin concentration. The increase of temperature accelerates the beta sheet aggregation growth if the beta sheet seed is introduced into the random coil fibroin solution. This work enhances our understanding of the natural silk spinning process in vivo.     

Egg case protein-1. A new class of silk proteins with fibroin-like properties from the spider Latrodectus hesperus

Spiders produce multiple types of silk that exhibit diverse mechanical properties and biological functions. Most molecular studies of spider silk have focused on fibroins from dragline silk and capture silk, two important silk types involved in the survival of the spider. In our studies we have focused on the characterization of egg case silk, a third silk fiber produced by the black widow spider, Latrodectus hesperus. Analysis of the physical structure of egg case silk using scanning electron microscopy demonstrates the presence of small and large diameter fibers. By using the strong protein denaturant 8 M guanidine hydrochloride to solubilize the fibers, we demonstrated by SDS-PAGE and protein silver staining that an abundant component of egg case silk is a 100-kDa protein doublet. Combining matrix-assisted laser desorption ionization tandem time-of-flight mass spectrometry and reverse genetics, we have isolated a novel gene called ecp-1, which encodes for one of the protein components of the 100-kDa species. BLAST searches of the NCBInr protein data base using the primary sequence of ECP-1 revealed similarity to fibroins from spiders and silkworms, which mapped to two distinct regions within the ECP-1. These regions contained the conserved repetitive fibroin motifs poly(Ala) and poly(Gly-Ala), but surprisingly, no larger ensemble repeats could be identified within the primary sequence of ECP-1. Consistent with silk gland-restricted patterns of expression for fibroins, ECP-1 was demonstrated to be predominantly produced in the tubuliform gland, with lower levels detected in the major and minor ampullate glands. ECP-1 monomeric units were also shown to assemble into higher aggregate structures through the formation of disulfide bonds via a unique cysteine-rich N-terminal region. Collectively, our findings provide new insight into the components of egg case silk and identify a new class of silk proteins with distinctive molecular features relative to traditional members of the spider silk gene family.     

Isolation of a clone encoding a second dragline silk fibroin. Nephila clavipes dragline silk is a two-protein fiber.

Spider dragline silk is a unique protein fiber possessing both high tensile strength and high elasticity. A partial cDNA clone for one dragline silk protein (Spidroin 1) was previously isolated. However, the predicted amino acid sequence could not account for the amino acid composition of dragline silk. We have isolated a partial cDNA clone for another dragline silk protein (Spidroin 2), demonstrating that dragline silk is composed of multiple proteins. The amino acid sequence exhibits an entirely different repetitive motif than Spidroin 1. Spidroin 2 is predicted to consist of linked beta-turns in proline-rich regions which alternate with beta-sheet regions composed of polyalanine segments. This structure for Spidroin 2 provides a model for dragline silk structure and function.     

A twisted four-sheeted model for an amyloid fibril

The formation of amyloid fibers and their deposition in the body is a characteristic of a number of devastating human diseases. Here, we propose a structural model, based on X-ray diffraction data, for the basic structure of an amyloid fibril formed by using the variants of the B1 domain of IgG binding protein G of Streptococcus. The model for the fibril incorporates four beta sheets in a bundle with a diameter of 45 A. Its cross-section, or layer, consists of four strands, one strand from each sheet. Layers stack on top of each other to form the fibril, which has an overall helical twist with a periodicity of about 154 A. Each strand interacts in a parallel fashion with the strands in the layers above and below it, in an infinite beta sheet. Some geometric features of this model and the logic behind it may be applicable for constructing other related cross-beta amyloid fibrils.     

Silk from crickets: a new twist on spinning

Raspy crickets (Orthoptera: Gryllacrididae) are unique among the orthopterans in producing silk, which is used to build shelters. This work studied the material composition and the fabrication of cricket silk for the first time. We examined silk-webs produced in captivity, which comprised cylindrical fibers and flat films. Spectra obtained from micro-Raman experiments indicated that the silk is composed of protein, primarily in a beta-sheet conformation, and that fibers and films are almost identical in terms of amino acid composition and secondary structure. The primary sequences of four silk proteins were identified through a mass spectrometry/cDNA library approach. The most abundant silk protein was large in size (300 and 220 kDa variants), rich in alanine, glycine and serine, and contained repetitive sequence motifs; these are features which are shared with several known beta-sheet forming silk proteins. Convergent evolution at the molecular level contrasts with development by crickets of a novel mechanism for silk fabrication. After secretion of cricket silk proteins by the labial glands they are fabricated into mature silk by the labium-hypopharynx, which is modified to allow the controlled formation of either fibers or films. Protein folding into beta-sheet structure during silk fabrication is not driven by shear forces, as is reported for other silks.     

A Simple Lattice Model That Captures Protein Folding,Aggregation and Amyloid Formation

The ability of many proteins to convert from their functional soluble state to amyloid fibrils can be attributed to inter-molecular beta strand formation. Such amyloid formation is associated with neurodegenerative disorders like Alzheimer''s and Parkinson''s. Molecular modelling can play a key role in providing insight into the factors that make proteins prone to fibril formation. However, fully atomistic models are computationally too expensive to capture the length and time scales associated with fibril formation. As the ability to form fibrils is the rule rather than the exception, much insight can be gained from the study of coarse-grained models that capture the key generic features associated with amyloid formation. Here we present a simple lattice model that can capture both protein folding and beta strand formation. Unlike standard lattice models, this model explicitly incorporates the formation of hydrogen bonds and the directionality of side chains. The simplicity of our model makes it computationally feasible to investigate the interplay between folding, amorphous aggregation and fibril formation, and maintains the capability of classic lattice models to simulate protein folding with high specificity. In our model, the folded proteins contain structures that resemble naturally occurring beta-sheets, with alternating polar and hydrophobic amino acids. Moreover, fibrils with intermolecular cross-beta strand conformations can be formed spontaneously out of multiple short hydrophobic peptide sequences. Both the formation of hydrogen bonds in folded structures and in fibrils is strongly dependent on the amino acid sequence, indicating that hydrogen-bonding interactions alone are not strong enough to initiate the formation of beta sheets. This result agrees with experimental observations that beta sheet and amyloid formation is strongly sequence dependent, with hydrophobic sequences being more prone to form such structures. Our model should open the way to a systematic study of the interplay between the factors that lead to amyloid formation.     

Glycation induces formation of amyloid cross-beta structure in albumin

Amyloid fibrils are components of proteinaceous plaques that are associated with conformational diseases such as Alzheimer's disease, transmissible spongiform encephalopathies, and familial amyloidosis. Amyloid polypeptides share a specific quarternary structure element known as cross-beta structure. Commonly, fibrillar aggregates are modified by advanced glycation end products (AGE). In addition, AGE formation itself induces protein aggregation. Both amyloid proteins and protein-AGE adducts bind multiligand receptors, such as receptor for AGE, CD36, and scavenger receptors A and B type I, and the serine protease tissue-type plasminogen activator (tPA). Based on these observations, we hypothesized that glycation induces refolding of globular proteins, accompanied by formation of cross-beta structure. Using transmission electron microscopy, we demonstrate here that glycated albumin condensates into fibrous or amorphous aggregates. These aggregates bind to amyloid-specific dyes Congo red and thioflavin T and to tPA. In contrast to globular albumin, glycated albumin contains amino acid residues in beta-sheet conformation, as measured with circular dichroism spectropolarimetry. Moreover, it displays cross-beta structure, as determined with x-ray fiber diffraction. We conclude that glycation induces refolding of initially globular albumin into amyloid fibrils comprising cross-beta structure. This would explain how glycated ligands and amyloid ligands can bind to the same multiligand "cross-beta structure" receptors and to tPA.     

Molecular and mechanical properties of major ampullate silk of the black widow spider, Latrodectus hesperus

Molecular and material properties of major ampullate silk were studied for the cobweb-building black widow spider Latrodectus hesperus. Material properties were measured by stretching the silk to breaking. The strength was 1.0 +/- 0.2 GPa, and the extensibility was 34 +/- 8%. The secondary structure of the major ampullate silk protein was studied using carbon-13 NMR spectroscopy. Alanine undergoes a transition from a coiled structure in pre-spun silk to a beta sheet structure in post-spun silk. We have also isolated two distinct cDNAs (both about 500 bp) which encode proteins similar to major ampullate spidroin 1 and 2 (MaSp1 and MaSp2). The MaSp1-like silk contains polyalanine runs of 5-10 residues as well as GA and GGX motifs. The MaSp2-like silk contains polyalanine runs of varying length as well as GPG(X)(n) motifs. L. hesperus major ampullate silk is more like major ampullate silk from other species than other L. hesperus silks.     

A synthetic peptide forms voltage-gated porin-like ion channels in lipid bilayer membranes

Design of simple protein structures represents the essential first step toward novel macromolecules and understanding the basic principles of protein folding. Our work focuses on the ion channel formation and structure of peptides having a repeated pattern of glycine residues. Investigation of the ion channel properties of a glycine repeat peptide, VSLGLSIGFSVGVSIGWSFGRSRG revealed the formation of porin-like high conductance, multimeric, non-selective voltage-gated channels in phospholipid bilayer membranes. ATR-IR and CD spectroscopic studies showed an anti-parallel beta sheet structure in membranes. The formation of porin-like ion channels by a beta sheet peptide suggests spontaneous assembly into a beta barrel structure through oligomerization as in pore forming bacterial toxins. The present work is the first example of a short synthetic peptide mimicking the pore characteristics of a complex beta barrel protein and demonstrates that smaller peptides are capable of mimicking the complex functional properties of natural ion channels. This will have implications in understanding the folding of beta sheet proteins in membranes, the mechanism of two state voltage gating, and the role of glycine residues in beta barrel proteins.     

On (GGLGY) synthetic repeating sequences of lamprin and analogous sequences.

The repetitive sequence GGLGY was found in lamprin, the most important matrix protein of lamprey annular cartilage by Keeley and co-workers. Similar sequences appear also in other proteins, i.e. elastin, spidroin, spider minor ampullate silk proteins, in matrix proteins of the chorion or egg shell membrane of insects and others. We synthesized (GGLGY)n, n=1, 2, 6, because the sequence is repeated six times in the aggregated protein. The peptides were studied both in solution and in the solid state. Because the CD spectra were dominated by aromatic contribution, we synthesized GGLGF and GGLGA in order to carefully interpret the CD spectra. The conformational analysis suggests that all synthetic peptides do adopt the same secondary structure. In solution the peptides present a flexible conformation with a significant amount of PPII structure. In the solid state PPII, beta-pleated-sheets and beta-turns possibly co-exist.     

Bioactive silk protein biomaterial systems for optical devices

Silk-based biomaterial systems have been previously explored for a variety of medical and nonmedical materials needs. The unique biophysical features of silks provide options to generate highly tailored structures and morphologies with this unique family of fibrous proteins. To exploit these features, we have optimized the all aqueous processing of silk fibroin into novel surface nanopatterned protein materials. We have exploited control of this nanomorphology to optimize the optical features of these silk protein systems. We demonstrate control of surface morphology down to 125 nm, with fidelity over large length scales. This surface nanopatterning allows the silk protein to be formed into diffractive optics such as diffraction gratings, pattern generators, and lenses due to novel aqueous processing into optically clear materials via control of beta sheet crystallinity. Further, we incorporate biological components, such as hemoglobin and the enzyme peroxidase, during the process of forming the silk diffraction gratings. The ambient processing of the silk protein in water, in combination with these bioactive components, allows these entrained molecules to retain activity and provide added functions and selectivity to the optically active silk films. Thus, combinations of biochemical and optical readout is feasible and provides in a single, disposable/all degradable element with both spectral discrimination and biological function. These new surface nanopatterned, bioactive silk protein-based material systems offer a unique combination of features potentially useful for a range of biosensor needs, particularly when considered in concert with the remarkable mechanical properties of these proteins, their biocompatibility, and controllable biodegradation.     

Novel assembly properties of recombinant spider dragline silk proteins

Spider dragline silk, which exhibits extraordinary strength and toughness, is primarily composed of two related proteins that largely consist of repetitive sequences. In most spiders, the repetitive region of one of these proteins is rich in prolines, which are not present in the repetitive region of the other. The absence of prolines in one component was previously speculated to be essential for the thread structure. Here, we analyzed dragline proteins of the garden spider Araneus diadematus, ADF-3 and ADF-4, which are both proline rich, by employing the baculovirus expression system. Whereas ADF-3 represented an intrinsically soluble protein, ADF-4 was insoluble in vitro and self-assembled into filaments in the cytosol of the host insect cells. These ADF-4 filaments displayed the exceptional chemical stability of authentic silk threads. We provide evidence that the observed properties of ADF-3 and ADF-4 strongly depend on intrinsic characteristics such as hydropathicity, which differs dramatically between the two proteins, as in most other pairs of dragline silk proteins from other Araneoidea species, but not on their proline content. Our findings shed new light on the structural components of spider dragline silk, allowing further elucidation of their assembly properties, which may open the door for commercial applications.     

Structure and aggregation mechanism of beta(2)-microglobulin (83-99) peptides studied by molecular dynamics simulations

Many human neurodegenerative diseases are associated with amyloid fibril formation. The human 99-residue beta(2)-microglobulin (beta2m) is one of the most intensively studied amyloid-forming proteins. Recent studies show that the C-terminal fragments 72-99, 83-89, and 91-96 form by themselves amyloid fibrils in vitro and play a significant role in fibrillization of the full-length beta2m protein under acidic pH conditions. In this work, we have studied the equilibrium structures of the 17-residue fragment 83-99 in solution, and investigated its dimerization process by multiple molecular dynamics simulations. We find that an intertwined dimer, with the positions of the beta-strands consistent with the results for the monomer, is a possible structure for two beta2m(83-89) peptides. Based on our molecular-dynamics-generated dimeric structure, a protofibril model is proposed for the full-length beta2m protein.     

The FMO protein is related to PscA in the reaction center of green sulfur bacteria

The Fenna–Matthews–Olson protein is a water-soluble protein found only in green sulfur bacteria. Each subunit contains seven bacteriochlorophyll (BChl) a molecules wrapped in a string bag of protein consisting of mostly β sheet. Most other chlorophyll-binding proteins are water-insoluble proteins containing membrane-spanning α helices. We compared an FMO consensus sequence to well-characterized, membrane-bound chlorophyll-binding proteins: L & M (reaction center proteins of proteobacteria), D1 & D2 (reaction center proteins of PS II), CP43 & CP47 (core proteins of PS II), PsaA & PsaB (reaction center proteins of PS I), PscA (reaction center protein of green sulfur bacteria), and PshA (reaction center protein of heliobacteria). We aligned the FMO sequence with the other sequences using the PAM250 matrix modified for His binding-site identities and found a signature sequence (LxHHxxxGxFxxF) common to FMO and PscA. (The two His residues are BChl a. binding sites in FMO.) This signature sequence is part of a 220-residue C-terminal segment with an identity score of 13%. PRSS (Probability of Random Shuffle) analysis showed that the 220-residue alignment is better than 96% of randomized alignments. This evidence supports the hypothesis that FMO protein is related to PscA. This revised version was published online in June 2006 with corrections to the Cover Date.     

A comprehensive examination of protein sequences for evidence of internal gene duplication

Summary We have implemented a routine procedure for screening protein sequences for evidence of intragenic duplications. We tested 163 protein sequences representing 116 superfamilies of unrelated proteins. Twenty superfamilies contain proteins with internal gene duplications. The intragenic duplications detected can be divided into two major types. (1) One or more duplications of all or part of a gene produce a protein with two or several detectable regions of sequence homology. Sequences from 18 superfamilies contained this type of duplication. (2) Repeated reduplication of a small DNA segment can produce a protein that is repetitive over most of its length. Three superfamilies contain such repetitive sequences. We also investigated the limits of detection of ancient duplications using sequences derived by random mutation of a model sequence consisting of ten 10-residue repeats. The original repetitive nature of the sequence was usually detected after 250 point mutations even though the ancestral segment could not be accurately reconstructed.     

A proposed model for dragline spider silk self‐assembly: Insights from the effect of the repetitive domain size on fiber properties

Dragline spider silk has been intensively studied for its superior qualities as a biomaterial. In previous studies, we made use of the baculovirus mediated expression system for the production of a recombinant Araneus diadematus spider silk dragline ADF4 protein and its self‐assembly into intricate fibers in host insect cells. In this study, our aim was to explore the function of the major repetitive domain of the dragline spider silk. Thus, we generated an array of synthetic proteins, each containing a different number of identical repeats up to the largest recombinantly expressed spider silk to date. Study of the self‐assembly properties of these proteins showed that depending on the increasing number of repeats they give rise to different assembly phenotypes, from a fully soluble protein to bona fide fibers with superior qualities. The different assembly forms, the corresponding chemical resistance properties obtained as well as ultrastructural studies, revealed novel insights concerning the structure and intermolecular interactions of the repetitive and nonrepetitive domains. Based on these observations and current knowledge in the field, we hereby present a comprehensive hypothetical model for the mechanism of dragline silk self‐assembly and fiber formation. © 2009 Wiley Periodicals, Inc. Biopolymers 93: 458–468, 2010. This article was originally published online as an accepted preprint. The “Published Online” date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com