Conformational analysis of peptide analogues of silkmoth chorion protein segments using CD, NMR and molecular modelling.

Silkmoth proteins secreted from the follicular cells that surround the oocyte form a large extracellular assembly which is important for protecting and sustaining the structure of the oocyte and the developing embryo. These proteins have been classified into two major families (A and B). Sequence analysis showed conservation of a central domain containing long stretches of six amino acid residue repeats in both families, which have been suggested to be organized in beta-sheet structures. In this work NMR and CD spectra, as well as molecular calculations, have been used to investigate the conformational properties of two synthetic peptides (A and B), analogues of parts of the central domain of silkmoth chorion proteins of the A and B families, respectively. These peptides consist of three tandem repeats of the six-residue basic motif. Analysis of CD spectra of the two peptides in aqueous solutions and mixtures with organic solvents revealed beta-sheet and turn structural elements with a percentage higher than 40%. NOESY spectra at low temperatures (263-273 K) show sequential nOe connectivities (i, i + 1), indicative of a relative flexibility. The presence of HNi-HNi+1 cross-peaks and medium Halphai-HNi+1 connectivities, chemical shift deviations and temperature coefficient data provide, for the first time, experimental evidence that local folded structures around Gly residues occur in peptide segments of chorion proteins in solution. Simulated annealing calculations were used to examine the conformational space of the peptides and to probe the initial steps of amyloid fibril formation in the case of chorion proteins.     

Amyloid fibril formation propensity is inherent into the hexapeptide tandemly repeating sequence of the central domain of silkmoth chorion proteins of the A-family

Peptide-analogues of the A and B families of silkmoth chorion proteins form amyloid fibrils under a variety of conditions [Iconomidou, V.A., Vriend, G. Hamodrakas, S.J. 2000. Amyloids protect the silkmoth oocyte and embryo. FEBS Lett. 479, 141-145; Iconomidou,V.A., Chryssikos, G.D.,Gionis, V., Vriend, G., Hoenger, A., Hamodrakas, S.J., 2001. Amyloid-like fibrils from an 18-residue peptide-analogue of a part of the central domain of the B-family of silkmoth chorion protein. FEBS Lett. 499, 268-273; Hamodrakas, S.J. Hoenger, A., Iconomidou, V. A., 2004 . Amyloid fibrillogenesis of silkmoth chorion protein peptide-analogues via a liquid crystalline intermediate phase. J. Struct. Biol. 145, 226-235.], which led us to propose that silkmoth chorion is a natural protective amyloid. In this study, we designed and synthesized two mutant peptide-analogues of the central conservative domain of the A family: (a) one, cA_m1, with a length half of that of the central domain of the A family, which folds and self-assembles, in various conditions, into amyloid fibrils very similar in properties and structure to the fibrils formed by the cA peptide, which corresponds to the entire length of the A family central domain [Iconomidou, V.A., Vriend, G. Hamodrakas, S.J. 2000. Amyloids protect the silkmoth oocyte and embryo. FEBS Lett. 479, 141-145.], in full support of our previous proposal, (b) the second, cA_m2, differing from cA_m1 at three positions, where three glutamates have replaced two valines and one alanine residues, does not form amyloid fibrils in any conditions. It appears that (a) the amyloidogenic properties of silkmoth chorion peptides are encoded into the tandemly repeating hexapeptides comprising the central domain of silkmoth chorion proteins, and, that (b) suitable mutations, properly and carefully designed, greatly affect the strong amyloidogenic properties inherent in certain aminoacid sequences and may inhibit amyloid formation.     

FT-Raman spectroscopy as diagnostic tool of Congo red binding to amyloids

Chorion is the major component of silkmoth eggshell. More than 95% of its dry mass consists of the A and B families of low molecular weight structural proteins, which have remarkable mechanical and chemical properties protecting the oocyte and developing embryo from environmental hazards. We present data from FT-Raman spectroscopy of silkmoth chorion and amyloid-like fibrils formed from peptide analogues of chorion proteins, both unstained and stained by Congo red. The results show that FT-Raman spectroscopy is not a straightforward diagnostic tool for the specific interactions of Congo red with amyloids: a dilute aqueous solution of the Congo red dye at pH 5.5 and a thin solid film of the dye cast from this solution exhibit the same "diagnostic" Raman shifts relative to the neat Congo red dry powder as do amyloid fibrils formed from peptide analogues of chorion proteins stained by Congo red. An important consequence of this finding is that these shifts of the Raman active modes of Congo red are probably due to the formation of supramolecular dye aggregates in the presence of water. Therefore, this is not an appropriate diagnostic test for Congo red binding to amyloids.     

The silkmoth eggshell as a natural amyloid shield for the safe development of insect oocyte and embryo: insights from studies of silkmoth chorion protein peptide-analogues of the B family

Silkmoth chorion is the major component of the silkmoth eggshell. The proteins that constitute more than 95% of its dry mass have remarkable mechanical and physicochemical properties forming a protective natural shield for the oocyte and the developing embryo from a wide range of environmental hazards. Peptide-analogues of the central conservative domain of the two major families of silkmoth chorion proteins, the A's and the B's, form amyloid fibrils under a variety of conditions, which prompted us to propose, 10 years ago, that silkmoth chorion is an amyloid with protective properties. Following our finding, a number of studies verified the existence of several functional amyloids. In this study, we designed, synthesized and studied two peptide-analogues of the central conservative domain of the B family of silkmoth chorion proteins, and we present experimental results, which show: (a) that the amyloidogenic properties of silkmoth chorion peptides are encoded into the tandemly repeating hexapeptides comprising the central domain of silkmoth chorion proteins, confirming our previous findings from peptide analogues of the A family of chorion proteins, and, (b) they suggest how silkmoth chorion proteins of the B family self-assemble in vivo, for the formation of the helicoidal architecture of silkmoth chorion.     

Evolution and higher-order structure of architectural proteins in silkmoth chorion.

Genomic and cDNA clones have been sequenced that encode the E2 silkmoth chorion protein. E2 assembles with E1 [Regier, J.C. and Pacholski, P. (1985) Proc. Natl. Acad. Sci. USA, 82, 6035-6039] to form the 'filler' that helps mold prominent chorion surface structures called aeropyle crowns. E2 has two distinct domains. The amino terminal domain consists of four alternating stretches of hydrophobic and hydrophilic residues, the first three of which are homologous in sequence to about half of the E1 protein. Comparison of predicted secondary structures provides further support for the localized homology of E2 and E1. The carboxy terminal domain of E2 is much longer, is hydrophilic and consists entirely of multiple tandem copies of a single, variant hexapeptide repeat sequence that is absent from E1. Numbers of hexapeptide repeat sequences differed dramatically in two animals. The types of events required for such variation are discussed. Finally, we have elaborated our earlier model for how E proteins may assemble in vivo to form filler.     

Amino acid periodicities and their structural implications for the evolutionarily conservative central domain of some silkmoth chorion proteins

The central domain is an evolutionarily conservative region that is invariant in length in the A and Hc-A families of silkmoth chorion proteins. This domain shows strong sixfold periodicities for various amino acid residues, such as glycine and large non-polar residues. The periodicities and their phase relationships, together with the documented prevalence of beta-sheets and beta-turns in the chorion, strongly support a secondary structure model in which short (4-residue) beta-sheet strands alternate with beta-turns, forming a compact antiparallel, probably twisted beta-sheet. This structure should be important for the establishment of higher order structure in the chorion.     

Amyloid-like fibrils from an 18-residue peptide analogue of a part of the central domain of the B-family of silkmoth chorion proteins.

Chorion is the major component of silkmoth eggshell. More than 95% of its dry mass consists of the A and B families of low molecular weight structural proteins, which have remarkable mechanical and chemical properties, and protect the oocyte and the developing embryo from the environment. We present data from negative staining, Congo red binding, X-ray diffraction, Fourier transform-Raman, attenuated total reflectance infrared spectroscopy and modelling studies of a synthetic peptide analogue of a part of the central domain of the B family of silkmoth chorion proteins, indicating that this peptide folds and self-assembles, forming amyloid-like fibrils. These results support further our proposal, based on experimental data from a synthetic peptide analogue of the central domain of the A family of chorion proteins, that silkmoth chorion is a natural, protective amyloid [Iconomidou et al., FEBS Lett. 479 (2000) 141-145].     

Evolution of two major chorion multigene families as inferred from cloned cDNA and protein sequences

Complete or partial sequences are reported from six chorion cDNA clones of the silkmoth Antheraea polyphemus. The proteins encoded belong to the two major chorion protein classes, A and B, each of which is encoded by a multigene family. The sequence comparisons define some major features of the families and suggest how these genes may be evolving. Deletions and insertions might be involved in expanding or contracting internally repetitive regions. Sequence divergence is localized, thus defining sequence domains of distinct evolutionary properties and presumably distinct functions.     

Structural features of B family chorion sequences in the silkmoth Bombyx mori, and their evolutionary implications.

Partial protein sequences, and DNA sequences of corresponding cDNA and genomic clones were obtained and analyzed to reveal the primary structural features of major, developmentally middle or late components of the B chorion multigene family in Bombyx mori. Comparisons with other types of sequences confirm and clarify the tripartite domain structure of chorion proteins. Glycine-, leucine- and tyrosine-containing, tandemly repetitive peptides form the bulk of the amino-terminal and carboxy-terminal domains ('arms'). Extensive sequence homologies suggest a common evolutionary origin for the amino-terminal arms of some B. mori B sequences and the corresponding portions of members of a different (A) chorion multigene family in Antheraea polyphemus, a distantly related silkmoth.     

Twisted β-pleated sheet: the molecular conformation which possibly dictates the formation of the helicoidal architecture of several proteinaceous eggshells

Evidence from X-ray diffraction, laser-Raman spectroscopy, secondary structure prediction, freeze-fracturing, conventional electron microscopy and Fourier analysis suggests that the helicoidal structure of the silkmoth eggshell (chorion) is created by protein molecules, most probably in a twisted β-pleated sheet conformation. It is proposed that this conformation also dictates the formation of the helicoidal architecture of other proteinaceous eggshells; apparently, it may also play an important role in the formation of the helicoidal architecture in other biological systems with protein components.     

X-ray diffraction studies of a silkmoth chorion

High- and low-angle diffraction studies have been performed on mature chorion (eggshell) of the silkmoth, Antheraea polyphemus. The results confirm the prevalence of β-sheet structure, previously suggested by predictions based on known primary structure and by results of laser Raman spectroscopy. The patterns obtained with different irradiation geometries suggest that a significant proportion of β-sheets are stacked and oriented with respect to the chorion surface and the ultrastructurally evident fibrillar components. Strong similarities are evident with the organization of β-sheets in chicken scale keratin.     

Amyloid fibrillogenesis of silkmoth chorion protein peptide-analogues via a liquid-crystalline intermediate phase

Chorion, the major component of silkmoth eggshell, consists of the A and B classes of low-molecular weight structural proteins. Chorion protects the oocyte and the developing embryo from environmental hazards and this is due to the extraordinary physical and chemical properties of its constituent proteins. We have shown previously [FEBS Lett. 479 (2000) 141; 499 (2001) 268] that peptide-analogues of the A and B classes of chorion proteins form amyloid fibrils under a variety of conditions, which led us to propose that silkmoth chorion is a natural, protective amyloid. In this work, we present data showing conclusively that, the first main step of amyloid-like fibrillogenesis of chorion peptides is the formation of nuclei of liquid crystalline nature, which is reminiscent of spider-silk formation. We show that these liquid-crystalline nuclei (spherulites) 'collapse'/deteriorate to form amyloid fibrils in a spectacular manner, important, it seems, for chorion morphogenesis and amyloid fibrillogenesis in general. The molecular 'switch' causing this spectacular transformation is, most probably, a conformational transition to the structure of chorion peptides, from a left-handed parallel beta-helix to an antiparallel beta-pleated sheet. Apparently, these peptides were suitably designed to play this role, after millions of years of molecular evolution.     

Loss of phylogenetic information in chorion gene families of Bombyx mori gene conversion

The silkmoth chorion has provided a stimulating model for the study of evolution and developmental regulation of gene families. Previous attempts at inferring relationships among chorion sequences have been based on pairwise comparisons of overall similarity, a potentially problematic approach. To remedy this, we identified the alignable regions of low sequence variability and then analyzed this restricted database by parsimony and neighbor-joining methods. At the deepest level, the chorion sequence tree is split into two branches, called "alpha" and "beta." Within each branch, early- and late-expressing genes each constitute monophyletic groups, while the situation with middle-expressing genes remains uncertain. The HcB gene family appears to be the most basal beta-branch group, but this conclusion is qualified because the effect of gene conversion on branching order is unknown. Previous studies by Eickbush and colleagues have strongly suggested that ErA, HcA, and HcB families undergo gene conversion within a gene family, whereas the ErB family does not. The occurrence of conversion correlates with a particular tree structure; namely, branch lengths are much greater at the base of the family than at higher internodes and terminal branches. These observations raise the possibility that chorion gene families are defined by gene conversion events (reticulate evolution) rather than by descent with modification (synapomorphy).      

Selection and sequence analysis of a cDNA clone encoding a known chorion protein of the A family.

Using as criteria the size, abundance and developmental specificity of hybridizing mRNA sequences, we have selected from our chorion cDNA library a clone corresponding to a specific chorion protein, A4--cl. Comparison between the clone sequence and the largely known sequence of A4--cl validates the use of the cDNA library for sequence analysis of the chorion multigene families. The two major chorion protein families, A and B, share certain structural similarities.     

Diversity in a chorion multigene family created by tandem duplications and a putative gene-conversion event

Summary Two families of high-cysteine chorion proteins inBombyx mori are encoded in 15 tandemly arranged nonidentical gene pairs. It is assumed that this locus arose by duplication with subsequent sequence divergence. We have compared DNA sequences from two such neighboring pairs of genes in an attempt to understand the manner in which diversity has been generated and/or removed. A high level of sequence identity (91%–99%) was found between the repeats throughout the transcribed and flanking regions, with two significant exceptions. First, in the DNA segment encoding a conserved region of the chorion proteins, ten substitutions were detected in a 39-base-pair region. This localized region of high variability would suggest an intergene conversion-like event. Second, a length difference of 141 base pairs was detected in a region encoding the carboxy-terminal arm of the protein. This difference can be explained by three separate reiterations of single codons (3 base pairs) separated in time by duplication or triplication events.     

A Cuticle Protein Gene from the Japanese Oak Silkmoth, <Emphasis Type="Italic">Antheraea yamamai</Emphasis>: Gene Structure and mRNA Expression

A cuticle protein gene, AyCP12, from the Japanese oak silkmoth, Antheraea yamamai, was isolated and characterized. The gene spans 1107 bp and consists of one intron and two exons coding for a 112 amino acid polypeptide with a predicted molecular mass of 12,163 Da and a pI of 4.4. The AyCP12 protein contained a type-specific consensus sequence identifiable in other insect cuticle proteins and the deduced amino acid sequence of the AyCP12 cDNA is most homologous to another silkmoth, A. pernyi, cuticle protein ApCP13 (82% protein sequence identity). Northern blot analysis revealed that AyCP12 showed the epidermis-specific expression.     

LepChorionDB,a database of Lepidopteran chorion proteins and a set of tools useful for the identification of chorion proteins in Lepidopteran proteomes

Chorion proteins of Lepidoptera have a tripartite structure, which consists of a central domain and two, more variable, flanking arms. The central domain is highly conserved and it is used for the classification of chorion proteins into two major classes, A and B. Annotated and unreviewed Lepidopteran chorion protein sequences are available in various databases. A database, named LepChorionDB, was constructed by searching 5 different protein databases using class A and B central domain-specific profile Hidden Markov Models (pHMMs), developed in this work. A total of 413 Lepidopteran chorion proteins from 9 moths and 1 butterfly species were retrieved. These data were enriched and organised in order to populate LepChorionDB, the first relational database, available on the web, containing Lepidopteran chorion proteins grouped in A and B classes. LepChorionDB may provide insights in future functional and evolutionary studies of Lepidopteran chorion proteins and thus, it will be a useful tool for the Lepidopteran scientific community and Lepidopteran genome annotators, since it also provides access to the two pHMMs developed in this work, which may be used to discriminate A and B class chorion proteins. LepChorionDB is freely available at http://bioinformatics.biol.uoa.gr/LepChorionDB.