Disulfide-Directed Multicyclic Peptides with N-Terminally Extendable α-Helices for Recognition and Activation of G Protein-Coupled Receptors.

Many peptide hormones adopt long α-helical structures upon interacting with their cognate receptors but often exhibit flexible conformations when unbound. Strategies that can stabilize long α-helices without disrupting their binding to receptors are still lacking, which hinders progress in their biological applications and drug development. Here, we present an approach that combines rational design with library screening to create and identify a unique disulfide-directed multicyclic peptide (DDMP) scaffold, which could effectively stabilize N-terminally extendable α-helices while displaying exceptional efficiency in disulfide pairing and oxidative folding.

Triscysteine disulfide-directing motifs enabling design and discovery of multicyclic peptide binders.

Peptides are valuable for therapeutic development, with multicyclic peptides showing promise in mimicking antigen-binding potency of antibodies. However, our capability to engineer multicyclic peptide scaffolds, particularly for the construction of large combinatorial libraries, is still limited. Here, we study the interplay of disulfide pairing between three biscysteine motifs, and designed a range of triscysteine motifs with unique disulfide-directing capability for regulating the oxidative folding of multicyclic peptides.

De Novo Discovery of Cysteine Frameworks for Developing Multicyclic Peptide Libraries for Ligand Discovery.

Conserved cysteine frameworks are essential components of disulfide-rich peptides (DRPs), which dominantly define the structural diversity of both naturally occurring and de novo-designed DRPs. However, there are only very limited numbers of conserved cysteine frameworks, and general methods enabling de novo discovery of cysteine frameworks with robust foldability are still not available. Here, we devised a "touchstone"-based strategy that relies on chasing oxidative foldability between two individual disulfide-rich folds on the phage surface to discover new cysteine frameworks from random sequences.

Selection and evolution of disulfide-rich peptides cellular protein quality control.

Disulfide-rich peptides (DRPs) are an interesting and promising molecular format for drug discovery and development. However, the engineering and application of DRPs rely on the foldability of the peptides into specific structures with correct disulfide pairing, which strongly hinders the development of designed DRPs with randomly encoded sequences. Design or discovery of new DRPs with robust foldability would provide valuable scaffolds for developing peptide-based probes or therapeutics.

Disulfide-Directed Multicyclic Peptide Libraries for the Discovery of Peptide Ligands and Drugs.

Multicyclic peptides with stable 3D structures are a kind of novel and promising peptide formats for drug design and discovery as they have the potential to combine the best characteristics of small molecules and proteins. However, the development of multicyclic peptides is largely limited to naturally occurring products. It remains a big challenge to develop multicyclic peptides with new structures and functions without recourse to the existing natural scaffolds.

Crystal structure of the polyketide cyclase from .

About 40% of proteins are classified as conserved hypothetical proteins in (TB). Identification and characterization of these proteins are beneficial to understand the pathogenesis of TB and exploiting novel drugs for TB treatments. The polyketide cyclase, a protein from ( PC) has been annotated as a hypothetical protein in Uniprot database.

Rapid and specific detection of with a visualized isothermal amplification method.

is a serious problem for hospitals and can spread from patient to patient. Most of the current detection methods are associated with limitations associated with the need for trained personnel; they are also time-consuming. Thus, it is necessary to develop rapid and accurate detection methods to control the spread of In this study, we developed a rapid and accurate detection method for using recombinase polymerase amplification (RPA) combined with a lateral flow strip (LFS).

Redox-Regulated Conformational Change of Disulfide-Rich Assembling Peptides.

Disulfide bond formation is a common mechanism for regulating conformational changes in proteins during oxidative folding. Despite extensive studies of the use of multiple disulfide bonds to constrain peptide conformation, few studies have explored their usage in developing self-assembling peptides. Herein, we report that a thiol-rich peptide could fold into an amphiphilic β-hairpin conformation through the formation of two hetero-disulfide bonds upon oxidation, subsequently self-assembling into a mechanically rigid hydrogel.

Structure-guided design of CPPC-paired disulfide-rich peptide libraries for ligand and drug discovery.

Peptides constrained through multiple disulfides (or disulfide-rich peptides, DRPs) have been an emerging frontier for ligand and drug discovery. Such peptides have the potential to combine the binding capability of biologics with the stability and bioavailability of smaller molecules. However, DRPs with stable three-dimensional (3D) structures are usually of natural origin or engineered from natural ones.

Fast and sensitive graphene oxide-DNAzyme-based biosensor for Vibrio alginolyticus detection.

DNAzymes have been widely and effectively used for the detection of pathogenic bacteria, which pose a serious public health threat. However, the rapid and cost-effective detection of such bacteria remains a major challenge. In this study, we successfully selected Vibrio alginolyticus-specific DNAzymes.

An evolution-inspired strategy to design disulfide-rich peptides tolerant to extensive sequence manipulation.

Natural disulfide-rich peptides (DRPs) are valuable scaffolds for the development of new bioactive molecules and therapeutics. However, there are only a limited number of topologically distinct DRP folds in nature, and most of them suffer from the problem of oxidative folding. Thus, strategies to design DRPs with new constrained topologies beyond the scope of natural folds are desired.

Fast and Selective Reaction of 2-Benzylacrylaldehyde with 1,2-Aminothiol for Stable N-Terminal Cysteine Modification and Peptide Cyclization.

N-terminal cysteine (Cys)-specific reactions have been exploited for protein and peptide modifications. However, existing reactions for N-terminal Cys suffer from low reaction rate, unavoidable side reactions, or poor stability for reagents or products. Herein we report a fast, efficient, and selective conjugation between 2-benzylacrylaldehyde (BAA) and 1,2-aminothiol, which involves multistep reactions including aldimine condensation, Michael addition, and reduction of imine by NaBHCN.

Rapid detection of using a DNAzyme-based sensor.

In the present study, a DNAzyme was screened in vitro through the use of a DNA library and crude extracellular mixture (CEM) of . Following eight rounds of selection, a DNAzyme termed PAE-1 was obtained, which displayed high rates of cleavage with strong specificity. A fluorescent biosensor was designed for the detection of in combination with the DNAzyme.

H, C, N backbone and side-chain chemical shift assignments of the polyketide cyclase from Mycobacterium tuberculosis.

Polyketide cyclase from Mycobacterium tuberculosis (MtPC) is related to the formation of sterol derivatives, which may play a role in immune escape in the initial stage of macrophage infection by Mycobacterium tuberculosis. However, the structure and specific functions of MtPC are still unknown. Here we report the backbone and side-chain NMR resonance assignments for the MtPC.

Detection of in Seafood With a DNAzyme-Based Biosensor.

is an important pathogenic bacterium that is often associated with seafood-borne illnesses. Therefore, to detect this pathogen in aquatic products, a DNAzyme-based fluorescent sensor was developed for the detection of . After screening and mutation, a DNAzyme that we denominated "RFD-VV-M2" exhibited the highest activity, specificity, and sensitivity.

Rapid Detection of Infection in Shrimp With a Real-Time Isothermal Recombinase Polymerase Amplification Assay.

(EHP) infection has become a significant threat in shrimp farming industry in recent years, causing major economic losses in Asian countries. As there are a lack of effective therapeutics, prevention of the infection with rapid and reliable pathogen detection methods is fundamental. Molecular detection methods based on polymerase chain reaction (PCR) and loop-mediated isothermal amplification (LAMP) have been developed, but improvements on detection speed and convenience are still in demand.

Rapid Detection of by the Naked Eye Using DNA Aptamers.

was first isolated from gastritis patients by Barry J. Marshall and J. Robin Warren in 1982, and more than 90% of duodenal ulcers and about 80% of gastric ulcers are caused by infection.

Biophysical and functional characterizations of recombinant RimI acetyltransferase from Mycobacterium tuberculosis.

Nα-acetylation is a universal protein modification related to a wide range of physiological processes in eukaryotes and prokaryotes. RimI, an Nα-acetyltransferase in Mycobacterium tuberculosis, is responsible for the acetylation of the α-amino group of the N-terminal residue in the ribosomal protein S18. Despite growing evidence that protein acetylation may be correlated with the pathogenesis of tuberculosis, no structural information is yet available for mechanistically understanding the MtRimI acetylation.

Solution structure and backbone dynamics for S1 domain of ribosomal protein S1 from Mycobacterium tuberculosis.

The pro-drug pyrazinamide is hydrolyzed to pyrazinoic acid (POA) in its use for the treatment of tuberculosis. As a molecule with bactericidal activity, POA binds to the C-terminal S1 domain of ribosomal protein S1 from Mycobacterium tuberculosis (MtRpsA_S1) to inhibit trans-translation. Trans-translation is a critical component of protein synthesis quality control, and is mediated by transfer-messenger RNA.

Selection of DNAzymes for Sensing Aquatic Bacteria: Vibrio Anguillarum.

Vibrio anguillarum is a bacterial pathogen that causes serious damage to aquatic fish, and its rapid detection and prevention are critical. DNAzymes are DNA-based catalysts with excellent stability. In this study, in vitro selection of DNAzymes was performed using the crude extracellular matrix (CEM) of V.