Enhanced Permeability and Binding Activity of Isobutylene-Grafted Peptides.

We present a new peptide-macrocyclization strategy with an isobutylene graft. The reaction is mild and proceeds rapidly and efficiently both for linear and cyclic peptides. The resulting isobutylene-grafted peptides possess improved passive membrane permeability due to the shielding of the polar backbone of the amides, as demonstrated by NMR spectroscopy and molecular dynamics simulations. The isobutylene-stapled structures are fully stable in human plasma and in the presence of glutathione. This strategy can be applied to bioactive cyclic peptides such as somatostatin. Importantly, we found that structural preorganization forced by the isobutylene graft leads to a significant improvement in binding. The combined advantages of directness, selectivity, and smallness could allow application to peptide macrocyclization based on this attachment of the isobutylene graft

Quaternization of Vinyl/Alkynyl Pyridine Enables Ultrafast Cysteine-Selective Protein Modification and Charge Modulation.

Quaternized vinyl- and alkynyl-pyridine reagents were shown to react in an ultrafast and selective manner with several cysteine-tagged proteins at near-stoichiometric quantities. We have demonstrated that this method can effectively create a homogenous antibody-drug conjugate that features a precise drug-to-antibody ratio of 2, which was stable in human plasma and retained its specificity towards Her2+ cells. Finally, the developed warhead introduces a +1 charge to the overall net charge of the protein, which enabled us to show that the electrophoretic mobility of the protein may be tuned through the simple attachment of a quaternized vinyl pyridinium reagent at the cysteine residues. We anticipate the generalized use of quaternized vinyl- and alkynyl-pyridine reagents not only for bioconjugation, but also as warheads for covalent inhibition and as tools to profile cysteine reactivity

The use of fluoroproline in MUC1 antigen enables efficient detection of antibodies in patients with prostate cancer

A structure-based design of a new gene22ration tumor-associated glycopeptides with improved affinity against two anti-MUC1 antibodies is described. These unique antigens feature a fluorinated proline residue, such as a (4S)-4-fluoro-L-proline or 4,4-difluoroproline, at the most immunogenic domain. Binding assays using bio-layer interferometry reveal 3-fold to 10-fold affinity improvement with respect to the natural (glyco)peptides. According to X-ray crystallography and MD simulations, the fluorinated residues stabilize the antigen-antibody complex by enhancing key CH/ interactions. Interestingly, a notable improvement in detection of cancer-associated anti-MUC1 antibodies from serum of patients with prostate cancer is achieved with the non-natural antigens, which proves that these derivatives can be considered better diagnostic tools than the natural antigen for this type of cancer.We thank the Ministerio de Economía y Competitividad (projects CTQ2015-67727-R, UNLR13-4E-1931, CTQ2013-44367-C2-2-P, CTQ2015-64597-C2-1P, and BFU2016-75633-P). I. A. B. thanks the Asociación Española Contra el Cancer en La Rioja for a grant. I. S. A. and G. J. L. B. thank FCT Portugal (PhD studentship and FCT Investigator, respectively) and the EPSRC for funding. G. J. L. B. holds a Royal Society URF and an ERC StG (TagIt). F.C. and G. J. L. B thank the EU (Marie-Sklodowska Curie ITN, Protein Conjugates). R.H-G. thanks Agencia Aragonesa para la Investigación y Desarrollo (ARAID) and the Diputación General de Aragón (DGA, B89) for financial support. The research leading to these results has also received funding from the FP7 (2007-2013) under BioStruct-X (grant agreement N°283570 and BIOSTRUCTX_5186). We thank synchrotron radiation source DIAMOND (Oxford) and beamline I04 (number of experiment mx10121-19). Hokkaido University group acknowledges to JSPS KAKENHI Grant Number 25220206 and JSPS Wakate B KAKENHI Grant Number 24710242. We also thank CESGA (Santiago de Compostela) for computer support

Structure-Based Design of Potent Tumor-Associated Antigens: Modulation of Peptide Presentation by Single-Atom O/S or O/Se Substitutions at the Glycosidic Linkage.

GalNAc-glycopeptides derived from mucin MUC1 are an important class of tumor-associated antigens. α- O-glycosylation forces the peptide to adopt an extended conformation in solution, which is far from the structure observed in complexes with a model anti-MUC1 antibody. Herein, we propose a new strategy for designing potent antigen mimics based on modulating peptide/carbohydrate interactions by means of O → S/Se replacement at the glycosidic linkage. These minimal chemical modifications bring about two key structural changes to the glycopeptide. They increase the carbohydrate-peptide distance and change the orientation and dynamics of the glycosidic linkage. As a result, the peptide acquires a preorganized and optimal structure suited for antibody binding. Accordingly, these new glycopeptides display improved binding toward a representative anti-MUC1 antibody relative to the native antigens. To prove the potential of these glycopeptides as tumor-associated MUC1 antigen mimics, the derivative bearing the S-glycosidic linkage was conjugated to gold nanoparticles and tested as an immunogenic formulation in mice without any adjuvant, which resulted in a significant humoral immune response. Importantly, the mice antisera recognize cancer cells in biopsies of breast cancer patients with high selectivity. This finding demonstrates that the antibodies elicited against the mimetic antigen indeed recognize the naturally occurring antigen in its physiological context. Clinically, the exploitation of tumor-associated antigen mimics may contribute to the development of cancer vaccines and to the improvement of cancer diagnosis based on anti-MUC1 antibodies. The methodology presented here is of general interest for applications because it may be extended to modulate the affinity of biologically relevant glycopeptides toward their receptors

Synthesis of Tn Antigen Mimetics and Their Incorporation into the MUC1 Glycoprotein Sequence

Cancer is a disease with one of the highest mortality rates in the first world countries and its treatment today is still invasive and often ineffective. To overcome these limitations, new treatment strategies are being developed, such as immunotherapy; the patient's immune system recognizes and eliminates tumor cells with high specificity and effectiveness. Moreover, the early detection of cancer is essential for effective treatment. However, the development of immunotherapy and these diagnostic tools requires the study of new biomarkers, as in the case of the MUC1 mucin. In cancer cells, unlike in healthy cells, alterations occur in its glycosylation, exposing different antigens that can trigger an immune response, such as the Tn antigen (GalNAc--O-Ser/Thr). Thus, the Tn antigen has been incorporated in peptides and used both to generate therapeutic vaccines against cancer and for its early detection. However, the therapeutic use of O-glycopeptides is sometimes limited since they are easily hydrolyzed in biological systems. Therefore, different mimetics of the Tn antigen are being developed, including those that involve changes in the O-glycosidic bond [1].In this work, the oxygen atom of this bond has been replaced by a sulfur or selenium atom (Figure 1). These Tn antigen mimetics have been incorporated at position 16 of the MUC1 tandem repeat peptide sequence (HGVTSAPDTRPAPGST16APPA) using SPPS (Solid-Phase Peptide Synthesis) methodology, replacing the natural Tn antigen [2]. A SN2-type bimolecular nucleophilic substitution on the corresponding protected -haloamino acid was the key step to obtain S- or Se-mimetics of the Tn antigen, using GalNAc--SH and a base or diselenide (GalNAc--Se)2 and NaBH4 as nucleophiles, respectively. Affinities (KD) of all glycopeptides incorporating unnatural Tn mimetics to different anti-MUC1 antibodies were determined experimentally by ELISA tests and/or Surface Plasmon Resonance (SPR) experiments. The results obtained were explained in base of the conformational preferences deduced from NMR experiments combined to MD simulations. The best surrogates in terms of affinity will be the selected candidates to develop cancer therapy approaches in the future

Efficient and irreversible antibody-cysteine bioconjugation using carbonylacrylic reagents.

There is considerable interest in the development of chemical methods for the precise, site-selective modification of antibodies for therapeutic applications. In this protocol, we describe a strategy for the irreversible and selective modification of cysteine residues on antibodies, using functionalized carbonylacrylic reagents. This protocol is based on a thiol-Michael-type addition of native or engineered cysteine residues to carbonylacrylic reagents equipped with functional compounds such as cytotoxic drugs. This approach is a robust alternative to the conventional maleimide technique; the reaction is irreversible and uses synthetically accessible reagents. Complete conversion to the conjugates, with improved quality and homogeneity, is often achieved using a minimal excess (typically between 5 and 10 equiv.) of the carbonylacrylic reagent. Potential applications of this method cover a broad scope of cysteine-tagged antibodies in various formats (full-length IgGs, nanobodies) for the site-selective incorporation of cytotoxic drugs without loss of antigen-binding affinity. Both the synthesis of the carbonylacrylic reagent armed with a synthetic molecule of interest and the subsequent preparation of the chemically defined, homogeneous antibody conjugate can be achieved within 48 h and can be easily performed by nonspecialists. Importantly, the conjugates formed are stable in human plasma. The use of liquid chromatography-mass spectrometry (LC-MS) analysis is recommended for monitoring the progression of the bioconjugation reactions on protein and antibody substrates with accurate resolution

Oxetane Grafts Installed Site-Selectively on Native Disulfides to Enhance Protein Stability and Activity In Vivo

A four‐membered oxygen ring (oxetane) can be readily grafted into native peptides and proteins through site‐selective bis‐alkylation of cysteine residues present as disulfides under mild and biocompatible conditions. The selective installation of the oxetane graft enhances stability and activity, as demonstrated for a range of biologically relevant cyclic peptides, including somatostatin, proteins, and antibodies, such as a Fab arm of the antibody Herceptin and a designed antibody DesAb‐Aβ against the human Amyloid‐β peptide. Oxetane grafting of the genetically detoxified diphtheria toxin CRM197 improves significantly the immunogenicity of this protein in mice, which illustrates the general utility of this strategy to modulate the stability and biological activity of therapeutic proteins containing disulfides in their structures