Methods, systems, compositions and strategies for the delivery of RNA into cells in vivo, ex vivo, or in vitro via ARMMs are provided. In some aspects, ARMMs containing fusion proteins of ARRDC1 fused to an RNA binding protein or an RNA binding protein fused to a WW domain are provided. In some aspects, ARMMs containing binding RNAs associated with cargo RNAs are provided. In other aspects, cargo RNAs associated with a binding RNA, such as a TAR element, are loaded into ARMMs via ARRDC1 fusion proteins containing an RNA binding protein, such as trans-activator of transcription (Tat) protein.

The present invention concerns a production bacterial cell for producing lytic phage particles or lytic phage-derived delivery vehicles, said production bacterial cell stably comprising at least one phage structural genes and at least one phage DNA packaging genes, said phage structural gene(s) and phage DNA packaging gene(s) being derived from a lytic bacteriophage, wherein the expression of at least one of said phage structural genes and/or at least one of said phage DNA packaging gene(s) in said production bacterial cell is controlled by an induction mechanism.

The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell. More specifically, the present disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of a chimeric receptor binding protein (RBP) composed of a fusion between the N-terminal region of a RBP derived from a lambda-like bacteriophage and the C-terminal region of a different RBP.

Described herein is a fusion protein comprising a bacteriophage protein fused to a cancer antigen. Vaccines are also described, as well as methods of treatment and/or prevention of cancer and methods of immunizing an individual.

The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell. More specifically, the present disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of a chimeric receptor binding protein (RBP) composed of a fusion between the N-terminal region of a RBP derived from a lambda-like bacteriophage and the C-terminal region of a different RBP, and/or the presence of an engineered branched receptor binding multi-subunit polypeptides (branched-RBP).

Methods and compositions are provided for the use of anti-CRISPR (ACR) proteins in plants, including modulation of Cas endonuclease activity, improvement of frequency of homologous recombination, control of Cas endonuclease activity during various cell cycles, spatial and/or temporal regulation of Cas endonuclease activity in plants, usage in gene activation or repression, as well as reduction of off-target polynucleotide cleavage.

The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell. More specifically, the present disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of a chimeric receptor binding protein (RBP) composed of a fusion between the N-terminal region of a RBP derived from a lambda-like bacteriophage and the C-terminal region of a different RBP.

A conductive channel-containing membrane includes a membrane layer, and a SPP1 connector polypeptide variant that is incorporated into the membrane layer to form an aperture through which conductance can occur when an electrical potential is applied across the membrane. A method of sensing a molecule, such as a polypeptide or nucleic acid molecule, makes use of the conductive channel-containing membrane. A method of DNA sequence makes use of the conductive channel-containing membrane.

The present invention refers to lambda integrases comprising at least one amino acid mutation at positions 43, 319 and 336 of the lambda integrase as set forth in SEQ ID NO: 1. The invention further refers to nucleic acid molecules comprising the nucleotide sequence encoding the mutant lambda integrase and to host cells containing these nucleic acid molecules. The invention also refers to methods of recombining a nucleic acid of interest into a target nucleic acid in the presence of the mutant lambda integrase and sequence specific recombination kits.

The present invention relates to an antibacterial protein EFAL-2 derived from bacteriophage Ent-FAP-4 (deposition number KCTC 12854BP), a pharmaceutical composition including the same as an active ingredient, and a method for preventing or treating diseases caused by Enterococcus faecium by using the pharmaceutical composition, the antibacterial protein EFAL-2 being characterized by having the ability capable of killing Enterococcus faecium and having an amino acid sequence represented by SEQ ID NO: 2.