The Redox-Active Conopeptide Derived from the Venom Duct Transcriptome of Conus lividus Assists in the Oxidative Folding of Conotoxin

Exploring Diversity of Conopeptides and Revealing Novel Conoinsulins from Conus betulinus by Proteomic Analyses

The venom of cone snails, a potent weapon for predation and defense, contains diverse bioactive peptides (known as conopeptides, or conotoxins) that target various ion channels and receptors, offering potential as pharmacological tools or therapeutics. While transcriptomic studies have expanded conopeptide databases, proteomic validation remains limited. Here, we integrated two high-resolution mass spectrometry platforms to explore conopeptide diversity in Conus betulinus. A total of 283 conopeptides were identified, with 268 classifiable into known gene superfamilies or homology classes, while 15 unclassified conopeptides represent novel superfamilies. There were 46 newly discovered sequences and five new cysteine frameworks. Notably, we report the first proteomic identification of two novel conoinsulins in C. betulinus, Con-ins Be1 and Con-ins Be2. Both of them were predicted to retain insulin's canonical A/B-chain architecture. Structure modeling using the AlphaFold2 multimer suggested that Con-ins Be1 has a four-disulfide-bond arrangement, differing from the three disulfide bonds found in vertebrate insulin. In contrast, Con-ins Be2 was predicted to have three disulfide bonds, consistent with the structure of the vertebrate insulin. In summary, our study not only expanded the conopeptide repository but also provided two novel conoinsulins that may serve as pharmacological tools for insulin system research and merit further investigation.

Structure-aided function assignment to the transcriptomic conopeptide Am931

Implementation of the next-generation technologies for gene sequencing of venom duct transcriptome has provided a large number of peptide sequences of marine cone snails. Emerging technologies on computational platforms are now rapidly evolving for the accurate predictions of the 3D structure of the polypeptide using the primary sequence. The current report aims to integrate the information derived from these two technologies to develop the concept of structure-aided function assignment of Conus peptides. The proof of the concept was demonstrated using the transcriptomic peptide Am931 of C. amadis. The 3D structure of Am931 was computed using Density Functional Theory (DFT) and the quality of the predicted structure was confirmed using 2D NMR spectroscopy of the corresponding synthetic peptide. The computed structure of Am931 aligns with the active site motif of thioredoxins, possess catalytic disulfide conformation of (+, -)AntiRHHook and selectively modulate the N-terminal Cys3 thiol. These structural features indicate that Am931 may act as a disulfide isomerase and modulate the oxidative folding of conotoxins. Synthetic peptide Am931 provides proof-of-function by exhibiting catalytic activity on the oxidative folding of α-conotoxin ImI and improving the yield of native globular fold. The approach of integration of new technologies in the Conus peptide research may help to accelerate the discovery pipeline of new/improved conotoxin functional.

Redox-Active Conopeptide Li520 Has Evolved to Catalyze Oxidative Folding of Conotoxins

The evolution of miniature conopeptide Li520 (COWC*, *: C-terminal amidation) to exhibit the disulfide isomerase activity was probed using structure, function, disulfide conformation, and the precursor gene sequence. The peptides Li520, Li504, [O2A]Li520, [W3A]Li520, and Grx506, homologues active-site motif of glutaredoxin, were chemically synthesized and assessed for their disulfide reduction potential, intrinsic folding of disulfides, and disulfide isomerization activity on α-conotoxin ImI. The reduction potential of the disulfide of peptides varies from -189 to -344 mV, which is within the range observed for the redox family of proteins that modulates the folding of protein disulfides. The oxidative folding studies confirm the significance of the tryptophan residue in engaging Li520 in disulfide-exchange reactions and the role of proline hydroxylation in extending the lifetime of Li520 in a reduced free thiol state. Studies of quenching of tryptophan fluorescence by the disulfide in situ folding reaction in conjunction with the optimized structures by density functional theory (DFT) confirm the difference in conformation of disulfides between the native and mutant peptides. Interestingly, the native peptide Li520/Li504 shares a similar disulfide conformation of (-,-)AntiRHHook with the redox family of proteins known to modulate disulfides, particularly in lieu of the tetrapeptide of glutaredoxin, deviating from its disulfide conformation compared to its naive protein. Analysis of the precursor gene sequences of M-superfamily conotoxins revealed the presence of Li520 in different cone snail species with distinct food habits and possible modes of evolution through the diversification of cysteine motifs. The results of the report suggest that the short redox conopeptide Li520 has evolved to facilitate the oxidative folding of conotoxins and may be useful to develop as reagents for the synthesis of therapeutically important cysteine-rich peptides.

Oxidative Folding Catalysts of Conotoxins Derived from the Venom Duct Transcriptome of C. frigidus and C. amadis

Two novel redox conopeptides with proline residues outside and within the active site disulfide loop were derived from the venom duct transcriptome of the marine cone snails Conus frigidus and Conus amadis. Mature peptides with possible post-translational modification of 4-trans-hydroxylation of proline, namely, Fr874, Fr890[P1O], Fr890[P2O], Fr906, Am1038, and Am1054, have been chemically synthesized and characterized using mass spectrometry. The estimated reduction potential of cysteine disulfides of synthetic peptides varied from -298 to -328 mV, similar to the active site cysteine disulfide motifs of the redox family of proteins. Fr906/Am1054 exhibited pronounced catalytic activity and assisted in improving the yields of natively folded globular form α-conotoxin ImI. Three-dimensional (3D) structures of the redox conopeptides were optimized using computational methods and verified by 2D-ROESY NMR spectroscopy: C. frigidus peptides adopt an N-terminal helical fold and C. amadis peptides adopt distinct structures based on the Phe4-Pro/Hyp5 peptide bond configuration. The shift in the cis-trans configuration of the Phe4-Pro/Hyp5 peptide bond of Am1038/Am1054 was observed between reduced free thiol and oxidized disulfide forms of the optimized peptides. The report confirms the position-specific effect of hydroxyproline on the oxidative folding of conotoxins and sequence diversity of redox conopeptides in the venom duct of cone snails.

Marine natural products

Covering: January to December 2021This review covers the literature published in 2021 for marine natural products (MNPs), with 736 citations (724 for the period January to December 2021) referring to compounds isolated from marine microorganisms and phytoplankton, green, brown and red algae, sponges, cnidarians, bryozoans, molluscs, tunicates, echinoderms, mangroves and other intertidal plants and microorganisms. The emphasis is on new compounds (1425 in 416 papers for 2021), together with the relevant biological activities, source organisms and country of origin. Pertinent reviews, biosynthetic studies, first syntheses, and syntheses that led to the revision of structures or stereochemistries, have been included. An analysis of the number of authors, their affiliations, domestic and international collection locations, focus of MNP studies, citation metrics and journal choices is discussed.

Significance of D- tryptophan in Contryphan-Ar1131 Conus peptide: Oxidative folding, trypsin binding, and photostabilization activity

Distinct differences have been observed between L-tryptophan and D-tryptophan containing contryphan-Ar1131 in oxidative folding, trypsin binding, and photostabilization activity on avobenzone. [W⁵] contryphan-Ar1131 and [w⁵] contryphan-Ar1131 were chemically synthesized and characterized using RP-HPLC and mass spectrometry. Structural differences due to the change of configuration of tryptophan were evident from the optimized structures of contryphan-Ar1131 using density functional theory (DFT). The comparison of early events of oxidative folding has revealed the role of D-tryptophan in accelerating the formation of a disulfide bond. The optimized structures of the reduced form of peptides revealed the occurrence of aromatic-aromatic and aromatic-proline interactions in [w⁵] contryphan-Ar1131 which may be critical in aiding the oxidative folding reaction. The presence of the Lys6-Pro7 peptide bond indicates that contryphan-Ar1131 is resistant but may bind to trypsin allowing to assign the binding affinity of peptides to the protein surface. Competitive binding studies and molecular docking along with molecular dynamic (MD) simulations have revealed that [w⁵] contryphan-Ar1131 has more affinity for the active site of trypsin. Given tryptophan is a photostabilizer of FDA-approved chemical UV-A filter avobenzone, the report has compared the photostabilization activity of [W⁵]/ [w⁵] contryphan-Ar1131 on avobenzone under natural sunlight. [w⁵] contryphan-Ar1131 has better photostabilization activity than that of [W⁵] contryphan-Ar1131 and also individual D-tryptophan and L-tryptophan amino acids. These biochemical studies have highlighted the significance of D-tryptophan in contryphan-Ar1131 and its photostabilization activity on avobenzone may find applications in cosmetics.