The present invention refers to the heterologous production in microorganisms of modified versions of a predicted isoform of the surfactant protein Lv-ranaspumin-1 (Lv-Rsn-1), whose sequence was inferred from analyzes of the protein extract of the nest foam from the Northeastern Pepper Frog (Leptodactylus vastus). More specifically, it refers to two surfactant proteins that consist of modified versions of the predicted isoform of Lv-Rsn-1; to two synthetic genes each encoding one of these modified versions of the predicted isoform of Lv-Rsn-1; to two expression cassettes each containing one of the synthetic genes encoding one of the modified versions of the predicted isoform of Lv-Rsn-1; to two expression vectors each containing one of the synthetic genes encoding modified versions of the predicted isoform of Lv-Rsn-1; and to two transgenic microorganisms, a bacterium and a yeast, each transformed with one of these synthetic genes and heterologously producing one of the modified versions of the predicted isoform of Lv-Rsn-1. Lv-Rsn-1 has surfactancy, emulsification and dispersancy properties, among others, and its heterologous production allows it to be used in various applications and industrial products, without the need to extract it from the frog nest foam.

Computational systems and methods are described for identifying new α-helical antimicrobial peptides using a systemic consensus formula. Newly identified α-helical antimicrobial peptides are tested experimentally and show potent microbiocidal activities.

The present disclosure relates to a synthetic Túngara frog foam composition. The synthetic Túngara frog foam composition comprises six synthetically synthesized ranaspumin proteins (RSN-1 to RSN-6) wherein only the active segments of the RSN proteins are synthesized and six synthetically synthesized polysaccharides comprising four tetrasaccharides, a heptasaccharide and a nonasaccharide. Multiple novel applications of the foam are described.

Provided herein, in some embodiments, are engineered phagemids that comprise at least one synthetic genetic circuit, wherein the at least one synthetic genetic circuit comprises gene sequences encoding at least one non-lytic antimicrobial peptides (AMPs) and/or antibacterial toxin proteins, a stable origin of replication, and a bacteriophage-packaging signal, wherein the engineered phagemid does not comprise some or all gene sequences encoding bacteriophage proteins required for assembly of a bacteriophage particle.

This disclosure features structurally-stabilized oncolytic peptides and related compositions and methods of making same. Also disclosed are methods of using such structurally-stabilized peptides in the treatment of cancer, e.g., a hematological cancer, e.g., a leukemia, a lymphoma, or multiple myeloma, and/or in the inhibition of proliferation of a cancer cell, e.g., a hematological cancer, e.g., a leukemia and/or a lymphoma and/or a multiple myeloma cell. Also disclosed are methods of using such structurally-stabilized peptides for killing cancer cells or dual-killing cancer cell and micro-organisms, and thus providing therapeutics to treat cancer with or without simultaneously preventing or treating infection, while avoiding toxicity to normal, non-cancerous cells.

Peptides endowed with an anti-inflammatory, anti-angiogenic and/or antimicrobial activity, a medicament or a pharmaceutical composition including such peptides, and the use thereof in the prevention or treatment of inflammatory diseases, and more particularly inflammatory diseases due to or associated with microbial infections, or in the prevention or treatment of angiogenesis-related diseases.

Compositions and provided to induce cells of the inner ear to renter the cell cycle and to proliferate. In particular, hair cells are induced to proliferate by administration of a composition which activates the Myc and Notch. Supporting cells are induced to transdifferentiate to hair cells by inhibition of Myc and Notch activity or the activation of Atoh1. Methods of treatment include the intracellular delivery of these molecules to a specific therapeutic target.

The present invention refers to the use of Lixisenatide or/and a pharmaceutically acceptable salt thereof, for the manufacture of a medicament for the treatment of diabetes mellitus type 2, for inducing weight loss in diabetes type 2 patients or/and for preventing weight gain in diabetes type 2 patients.

Antiviral polypeptides and methods of use are provided herein. In particular, these polypeptides can comprise the Yodha amino acid sequence, variants, derivatives, or truncated versions thereof. In certain embodiments, this disclosure relates to uses of the peptides, nucleic acid molecules, and compositions disclosed herein to treat or prevent a viral infection.

Compositions are described for direct protein delivery into multiple cell types in the mammalian inner ear. The compositions are used to deliver protein(s) (such as gene editing factors) editing of genetic mutations associated with deafness or associated disorders thereof. The delivery of genome editing proteins for gene editing and correction of genetic mutations protect or restore hearing from genetic deafness. Methods of treatment include the intracellular delivery of these molecules to a specific therapeutic target.