Selection of Peptide-Bismuth Bicycles Using Phage Display.

Cysteine conjugation is widely used to constrain phage displayed peptides for the selection of cyclic peptides against specific targets. In this study, the nontoxic Bi3+ ion was used as a cysteine conjugation reagent to cross-link peptide libraries without compromising phage infectivity. We constructed a randomized 3-cysteine peptide library and cyclized it with Bi3+, followed by a selection against the maltose-binding protein as a model target. Next-generation sequencing of selection samples revealed the enrichment of peptides containing clear consensus sequences. Chemically synthesized linear and Bi3+ cyclized peptides were used for affinity validation. The cyclized peptide showed a hundred-fold better affinity (0.31 ± 0.04 µM) than the linear form (39 ± 6 µM). Overall, our study proved the feasibility of developing Bi3+ constrained bicyclic peptides against a specific target using phage display, which would potentially accelerate the development of new peptide-bismuth bicycles for therapeutic or diagnostic applications.

Generation of a 100-billion cyclic peptide phage display library having a high skeletal diversity.

Phage display is a powerful technique routinely used for the generation of peptide- or protein-based ligands. The success of phage display selections critically depends on the size and structural diversity of the libraries, but the generation of large libraries remains challenging. In this work, we have succeeded in developing a phage display library comprising around 100 billion different (bi)cyclic peptides and thus more structures than any previously reported cyclic peptide phage display library. Building such a high diversity was achieved by combining a recently reported library cloning technique, based on whole plasmid PCR, with a small plasmid that facilitated bacterial transformation. The library cloned is based on 273 different peptide backbones and thus has a large skeletal diversity. Panning of the peptide repertoire against the important thrombosis target coagulation factor XI enriched high-affinity peptides with long consensus sequences that can only be found if the library diversity is large.

Towards the Development of Orally Available Peptide Therapeutics.

Peptides have a number of attractive properties that make them an interesting modality for drug development, including their ability to bind challenging targets, their high target specificity, and their non-toxic metabolic products. However, a major limitation of peptides as drugs is their typically poor oral availability, hindering their convenient and flexible application as pills. Of the more than 60 approved peptide drugs, the large majority is not orally applicable. The oral delivery of peptides is hampered by their metabolic instability and/or limited intestinal uptake. In this article, we review the barriers peptides need to overcome after their oral administration to reach disease targets, we highlight two recent successes of pharma companies in developing orally applicable peptide drugs, and we discuss efforts of our laboratory towards the generation of bioavailable cyclic peptides.

Generation of a Large Peptide Phage Display Library by Self-Ligation of Whole-Plasmid PCR Product.

The success of phage display, used for developing target-specific binders based on peptides and proteins, depends on the size and diversity of the library screened, but generating large libraries of phage-encoded polypeptides remains challenging. New peptide phage display libraries developed in recent years rarely contained more than 1 billion clones, which appears to have become the upper size limit for libraries generated with reasonable effort. Here, we established a strategy based on whole-plasmid PCR and self-ligation to clone a library with more than 2 × 1010 members. The enormous library size could be obtained through amplifying the entire vector DNA by PCR, which omitted the step of vector isolation from bacterial cells, and through appending DNA coding for the peptide library via a PCR primer, which enabled efficient DNA circularization by end-ligation to facilitate the difficult step of vector-insertion of DNA fragments. Panning the peptide repertoires against a target yielded high-affinity ligands and validated the quality of the library and thus the new library cloning strategy. This simple and efficient strategy places larger libraries within reach for nonspecialist researchers to hopefully expand the possible targets of phage display applications.

De novo development of proteolytically resistant therapeutic peptides for oral administration.

The oral administration of peptide drugs is hampered by their metabolic instability and limited intestinal uptake. Here, we describe a method for the generation of small target-specific peptides (less than 1,600 Da in size) that resist gastrointestinal proteases. By using phage display to screen large libraries of genetically encoded double-bridged peptides on protease-resistant fd bacteriophages, we generated a peptide inhibitor of the coagulation Factor XIa with nanomolar affinity that resisted gastrointestinal proteases in all regions of the gastrointestinal tract of mice after oral administration, enabling more than 30% of the peptide to remain intact, and small quantities of it to reach the blood circulation. We also developed a gastrointestinal-protease-resistant peptide antagonist for the interleukin-23 receptor, which has a role in the pathogenesis of Crohn's disease and ulcerative colitis. The de novo generation of targeted peptides that resist proteolytic degradation in the gastrointestinal tract should help the development of effective peptides for oral delivery.

Interlaboratory analysis of teicoplanin plasma concentration assays among Chinese laboratories.

WHAT IS KNOWN AND OBJECTIVE: Teicoplanin is widely used for the treatment of infections caused by drug-resistant Gram-positive bacteria. Since there is a good correlation between trough levels and clinical outcome, therapeutic drug monitoring (TDM) is recommended to achieve better clinical curative effects. However, TDM of teicoplanin is not routine in China. So, a programme was initiated in 2017, including both HPLC method establishment and interlaboratory quality assessment, for the measurement of teicoplanin. METHODS: A main centre and a quality control centre were set up in the study. An HPLC-based method of teicoplanin determination in plasma was developed by the main centre. Analysis was performed using a Waters Symmetry C18 column (250 mm × 4.6 mm, 5 µm). The mobile phase was NaH2 PO4 (0.01 mol/L) and acetonitrile (75:25 v/v; pH 3.3), with a flow rate of 1.0 mL/min and a detection wavelength of 215 nm. Piperacillin sodium was selected as an internal standard (IS). Twenty-six additional TDM centres were then recruited to adopt this method. Then, all the centres were asked to take part in a quality control assessment evaluated by the quality control centre. RESULTS: For all TDM centres, linearity of teicoplanin concentration ranges was between 3.125 and 100 µg/mL. Intraday and interday accuracies ranged from 87.1% to 118.4%. Intraday and interday precision ranged from 0.3% to 13.8%. Therapeutic drug monitoring centres all passed inter-room quality assessment. All samples tested met the acceptance criteria. Then, 542 samples were collected. Patients with sub-optimal (≤10 mg/L) plasma teicoplanin concentrations constituted 42% of the total study population. WHAT IS NEW AND CONCLUSIONS: For the first time, a simple, rapid and accurate HPLC method for determining teicoplanin levels was successfully applied to therapeutic drug monitoring in clinical practice for twenty-seven TDM centres in China. The results demonstrated excellent interlaboratory agreement for teicoplanin testing and provide support for clinical laboratory quality management and results inter-accreditation.

Engineered Peptide Macrocycles Can Inhibit Matrix Metalloproteinases with High Selectivity.

Matrix metalloproteinases (MMPs) are zinc-dependent endopeptidases at the intersection of health and disease due to their involvement in processes such as tissue repair and immunity as well as cancer and inflammation. Because of the high structural conservation in the catalytic domains and shallow substrate binding sites, selective, small-molecule inhibitors of MMPs have remained elusive. In a tour-de-force peptide engineering approach combining phage-display selections, rational design of enhanced zinc chelation, and d-amino acid screening, we succeeded in developing a first synthetic MMP-2 inhibitor that combines high potency (Ki =1.9±0.5 nm), high target selectivity, and proteolytic stability, and thus fulfills all the required qualities for in cell culture and in vivo application. Our work suggests that selective MMP inhibition is achievable with peptide macrocycles and paves the way for developing specific inhibitors for application as chemical probes and potentially therapeutics.

Cyclization of peptides with two chemical bridges affords large scaffold diversities.

Successful screening campaigns depend on large and structurally diverse collections of compounds. In macrocycle screening, variation of the molecular scaffold is important for structural diversity, but so far it has been challenging to diversify this aspect in large combinatorial libraries. Here, we report the cyclization of peptides with two chemical bridges to provide rapid access to thousands of different macrocyclic scaffolds in libraries that are easy to synthesize, screen and decode. Application of this strategy to phage-encoded libraries allowed for the screening of an unprecedented structural diversity of macrocycles against plasma kallikrein, which is important in the swelling disorder hereditary angioedema. These libraries yielded inhibitors with remarkable binding properties (subnanomolar Ki, >1,000-fold selectivity) despite the small molecular mass (~1,200 Da). An interlaced bridge format characteristic of this strategy provided high proteolytic stability (t1/2 in plasma of >3 days), making double-bridged peptides potentially amenable to topical or oral delivery.