Abstract: The invention refers to a single-chain circular permuted caspase-2 comprising the following structure from N- to C-terminus: i) a small subunit of a caspase-2, or a functionally active variant thereof; and ii) a large subunit of a caspase-2, or a functionally active variant thereof, wherein said cp caspase-2 comprises one or more amino acid substitutions increasing P1? tolerance of said cp caspase-2 compared to a cp caspase-2 without said amino acid substitutions.

Abstract: A genome-based expression system for production of a protein of interest (POI) in a prokaryotic host, comprising at least an RNA polymerase (RNAP) gene, a gene encoding a POI, comprising a coding sequence, a promoter operably linked to said coding sequence, wherein said promoter is recognized by the RNAP expressed from the RNAP gene, and at least one lac operator (lacO) within the sequence of said promoter; and a lad gene encoding a lac repressor protein (LacI) comprising a coding sequence, a lacI promoter operably linked to the lad coding sequence, wherein the lacI promoter is a wild-type lacI promoter or a lacI promoter which increases LacI expression; wherein the expression rate of the POI is regulated by an inducer binding LacI.

Abstract: The present invention is in the field of recombinant biotechnology, in particular in the field of protein expression. The invention generally relates to methods of increasing the expression level of a protein of interest of a bacterial host cell in a production process. The invention relates particularly to improving the capacity of a bacterial host cell to express a protein of interest by expressing a phage protein during the production process which inhibits growth of the bacterial host cell. Decoupling growth of the bacterial host cell of manufacturing of the protein of interest during the production process reduces (i) the metabolic burden, (ii) oxygen demand, (iii) metabolic heat development, and (iv) avoids stress response caused by heterologous protein expression and thereby increases the capacity of a host cell to produce the protein of interest.

Abstract: A method for producing a protein of interest on a manufacturing scale is based on integration, by homologous recombination, of the DNA encoding the protein of interest into a bacterial cell's genome at a pre-selected site. The manufacturing scale production of recombinant proteins is in the fed-batch mode, semi-continuous or in a chemostat.

Abstract: A method for producing a protein of interest on a manufacturing scale is based on integration, by homologous recombination, of the DNA encoding the protein of interest into a bacterial cell's genome at a pre-selected site. The manufacturing scale production of recombinant proteins is in the fed-batch mode, semi-continuous or in a chemostat.

Abstract: The present invention provides new transcription termination signal sequences, especially a polynucleotide comprising at least two consecutive transcription termination signals, characterized in that consecutive transcription termination signals comprise at least a first and a second transcription termination signal that are at most 1000 nucleotides apart, and at least one of the termination signal has or encodes a RNA hairpin structure.

Abstract: A method for producing a protein of interest on a manufacturing scale is based on integration, by homologous recombination, of the DNA encoding the protein of interest into a bacterial cell genome at a pre-selected site. The manufacturing scale production of recombinant proteins is in the fed-batch mode, semi-continuous or in a chemostat.

Abstract: The present invention provides new transcription termination signal sequences, especially a polynucleotide comprising at least two consecutive transcription termination signals, characterized in that said consecutive transcription termination signals comprise at least a first and a second transcription termination signal that are at most 1000 nucleotides apart, and at least one of the termination signal has or encodes a RNA hairpin structure.

Abstract: A method for producing a protein of interest on a manufacturing scale is based on integration, by homologous recombination, of the DNA encoding the protein of interest into a bacterial cell genome at a pre-selected site. The manufacturing scale production of recombinant proteins is in the fed-batch mode, semi-continuous or in a chemostat.

Abstract: In an expression vector having a ColE1 replication system, the homology of the RNAI and RNAII of the ColE1 origin of replication to uncharged tRNAs is modified mutations in the coding region of the RNAI gene and corresponding mutations in the RNAII gene. The mutation results in one or more base exchanges in loop 1 and/or loop 2 and/or loop 3 of RNAI and RNAII. In methods using this vector for producing recombinant proteins, plasmid copy number is stably maintained. In methods for plasmid production, high plasmid copy numbers can be obtained.

Abstract: In an expression vector having a ColE1 replication system, the homology of the RNAI and RNAII of the ColE1 origin of replication to uncharged tRNAs is modified mutations in the coding region of the RNAI gene and corresponding mutations in the RNAII gene. The mutation results in one or more base exchanges in loop 1 and/or loop 2 and/or loop 3 of RNAI and RNAII. In methods using this vector for producing recombinant proteins, plasmid copy number is stably maintained. In methods for plasmid production, high plasmid copy numbers can be obtained.