An isolated nucleic acid that includes an open reading frame encoding a lanthipeptide protease polypeptide for scarless tag removal from a polypeptide is presented. Reagents, expression constructs and methods are also provided for preparing a scarless tag polypeptide product from a tagged polypeptide precursor containing a lanthipeptide protease cleavage site. The reagents are directed to novel lanthipeptide proteases and expression constructs and polypeptide precursors that include highly specific lanthipeptide protease substrate recognition sequence. Methods are provided that enable scarless tag removal from a cognate lanthipeptide, a non-cognate lanthipeptide or a heterologous polypeptide that includes extraneous amino acid sequences, such as leader peptides and tags.

The invention relates to bifunctional stapled or stitched peptides comprising a targeting domain, a linker moiety, and an effector domain, that can be used to tether, or to bring into close proximity, at least two cellular entities (e.g., proteins). Certain aspects relate to bifunctional stapled or stitched peptides that bind to an effector biomolecule through the effector domain and bind to a target biomolecule through the targeting domain. Polypeptides and/or polypeptide complexes that are tethered by the bifunctional stapled or stitched peptides of the invention, where the effector polypeptide bound to the effector domain of the bifunctional stapled or stitched peptide modifies or alters the target polypeptide bound to the targeting domain of the bifunctional peptide. Uses of the inventive bifunctional stapled or stitched peptides including methods for treatment of disease (e.g., cancer, inflammatory diseases) are also provided.

The present description relates to synthetic peptides useful for increasing the transduction efficiency of polypeptide cargos to the cytosol of target eukaryotic cells. More specifically, the present description relates to synthetic peptides and polypeptide-based shuttle agents comprising an endosome leakage domain (ELD) operably linked to a cell penetrating domain (CPD), or an ELD operably linked to a histidine-rich domain and a CPD. Compositions, kits, methods and uses relating to same are also described.

Embodied herein are engineered fusion proteins that bind and target nociceptor neurons, compositions comprising these engineered fusion proteins, and methods for treatment of pain using these engineered fusion proteins or compositions containing the engineered fusion proteins. The engineered fusion proteins contain domains derived from protein toxins such as the anthrax toxin, clostridial botulinum family of toxins, disulphide-containing toxins, and AB component type toxins.

The invention relates to a method of controlling the level of a polypeptide sequence comprising administering a polypeptide sequence fused to a ubiquitin targeting protein which comprises a minimal degron structural motif. In particular, the polypeptide sequence comprises a chimeric antigen receptor therefore the present invention is useful in methods of cell and gene therapy where the activity of the chimeric antigen receptor needs to be controlled.

Provided herein are cytokines or functional fragments thereof that, in some embodiments, are engineered to be masked by a masking moiety at one or more receptor binding site(s) of the cytokine or functional fragment thereof. In some embodiments, the cytokines are engineered to be activatable by a protease at a target site, such as in a tumor microenvironment, by including a proteolytically cleavable linker. In some embodiments, the proteolytically cleavable linker links the cytokine to the masking moiety, links the cytokine to a half-life extension domain, and/or links the masking moiety to a half-life extension domain. The masking moiety blocks, occludes, inhibits (e.g., decreases) or otherwise prevents (e.g., masks) the activity or binding of the cytokine to its cognate receptor or protein. Upon proteolytic cleavage of the cleavable linker at the target site, the cytokine becomes activated, which renders it capable of binding to its cognate receptor or protein with increased affinity.

Resonance energy transfer (RET)- or protein-fragment complement assay (PCA)-based biosensors useful for assessing the activity of G-proteins are described. These biosensors are based on the competition between the Got subunit and a Gβγ interacting protein (βγ IP) for the binding to the Gβγ dimer. These biosensors comprises (1) a βγ IP and (2) a Gβ or Gγ protein; a GPCR; or a plasma membrane targeting domain, fused to suitable RET or PCA tags. Methods using such biosensors for different applications, including the identification of agents that modulates G-protein activity or for the characterization of GPCR signaling/regulation, such as G-protein preferences and activation profiles of GPCRs, are also described.

The present disclosure provides compositions and methods for targeting various tumor associated antigens (including human 5T4 epitopes), cells expressing high affinity antigen specific binding proteins such as TCRs, nucleic acids encoding the same, and compositions for use in treating diseases or disorders in which cells overexpress one or more of these antigens, such as in cancer.

[Problem] To provide a production method capable of simply and efficiently producing a fructose-added carbohydrate using β-fructofuranosidase. [Solution] A method for producing a fructose-added carbohydrate, said method having a step in which a receptor substrate and a hydrate containing terminal fructose residue are brought into contact with: Escherichia coli expressing an anchor protein for expression on a cell surface and β-fructofuranosidase as one polypeptide, a composition including dead cells of the expressing Escherichia coli, or a polypeptide obtained from the expressing Escherichia coli and including an amino acid sequence of β-fructofuranosidase.

A fusion protein including granzyme B, a cell penetrating peptide, a cleavage site, and a targeting moiety, a composition for cell membrane penetration comprising the fusion protein, and an anticancer composition comprising the fusion protein.