Disclosed are compounds, compositions, and methods involving cyclic peptides that can bind to KRAS (G12D) oncogenic protein. For example, disclosed are cyclic peptides that selectively bind KRAS (G12D) oncogenic protein. Also disclosed are methods of inhibiting KRAS (G12D) oncogenic protein in a cancer cell expressing KRAS (G12D) oncogenic protein. In some forms, the method comprises incubating the cancer cell with any one or more of the disclosed cyclic peptides. In some forms, the method comprises bringing into contact the cancer cell with any one or more of the disclosed cyclic peptides.

Disclosed are compounds, compositions, and methods involving cyclic peptides that can bind to KRAS (G12D) oncogenic protein. For example, disclosed are cyclic peptides that selectively bind KRAS (G12D) oncogenic protein. Also disclosed are methods of inhibiting KRAS (G12D) oncogenic protein in a cancer cell expressing KRAS (G12D) oncogenic protein. In some forms, the method comprises incubating the cancer cell with any one or more of the disclosed cyclic peptides. In some forms, the method comprises bringing into contact the cancer cell with any one or more of the disclosed cyclic peptides.

The invention describes peptide ligands specific for human plasma Kallikrein.

The invention describes peptide ligands specific for human plasma Kallikrein.

The present invention relates to methods for displaying cyclic peptides on the surface of bacteriophage particles and collections thereof.

The present invention relates to methods for displaying cyclic peptides on the surface of bacteriophage particles and collections thereof.

A fluorescent tracer for targeting tumors, comprises: at least one first fluorophore fluorescing in a range of wavelengths of between 700 and 1000 nm, a targeting assembly comprising at least two identical targeting molecules, and a cyclic oligopeptide: configured so as to define a mean plane defining a first upper face and a second lower face, comprising at least one first lysine amino acid residue on the second lower face, the targeting molecules being fixed to the first upper face of the mean plane, the fluorophore being fixed to the second lower face of the mean plane via a spacer arm connecting a carbon of the sequence of the at least three double bonds and the lysine amino acid residue of the oligopeptide.

A fluorescent tracer for targeting tumors, comprises: at least one first fluorophore fluorescing in a range of wavelengths of between 700 and 1000 nm, a targeting assembly comprising at least two identical targeting molecules, and a cyclic oligopeptide: configured so as to define a mean plane defining a first upper face and a second lower face, comprising at least one first lysine amino acid residue on the second lower face, the targeting molecules being fixed to the first upper face of the mean plane, the fluorophore being fixed to the second lower face of the mean plane via a spacer arm connecting a carbon of the sequence of the at least three double bonds and the lysine amino acid residue of the oligopeptide.

The present invention provides a method of presenting a cyclic peptide on a protein having a loop structure. The cyclic peptide has a chemically crosslinked structure for forming an intramolecular cyclic structure. The method includes replacing the chemically crosslinked structure of the cyclic peptide with two amino acid residues constituting the loop structure, thereby fusing the cyclic peptide with the protein having a loop structure.

A method of treatment of inflamed, pre-cancerous or cancerous tissue or polyps in a mammalian subject is disclosed. The treatment involves administration of a composition of at least one peptide agonist of a guanylate cyclase receptor and/or other small molecules that enhance intracellular production of cGMP. The at least one peptide agonist of a guanylate cyclase receptor may be administered either alone or in combination with an inhibitor of cGMP-dependent phosphodiesterase. The inhibitor may be a small molecule, peptide, protein or other compound that inhibits the degradation of cGMP. Without requiring a particular mechanism of action, this treatment may restore a healthy balance between proliferation and apoptosis in the subject's population of epithelial cells, and also suppress carcinogenesis. Thus, the method may be used to treat, inter alia, inflammation, including gastrointestinal inflammatory disorders, general organ inflammation and asthma, and carcinogenesis of the lung, gastrointestinal tract, bladder, testis, prostate and pancreas, or polyps.