The present invention provides clinical evidence for a method of stem cell transplantation that facilitates engraftment and reconstitutes immunocompetence of the recipient without requiring myeloablative conditioning.

The present disclosure relates to methods for producing lentiviral vectors using mammalian cells. Specifically, the methods utilize three plasmids, rather than four, to provide the required packaging elements and transfer vector to a cell, allowing for the production of a large number of lentiviral vectors in mammalian cells, including suspension-based cells. These methods allow for the production of lentiviral vectors that can be tailored to include a specific gene of interest.

Methods and constructs for engineering circular RNA are disclosed. In some embodiments, the methods and constructs comprise a vector for making circular RNA, the vector comprising the following elements operably connected to each other and arranged in the following sequence: a.) a 5′ homology arm, b.) a 3′ group I intron fragment containing a 3′ splice site dinucleotide, c.) optionally, a 5′ spacer sequence, d.) a protein coding or noncoding region, e.) optionally, a 3′ spacer sequence, f) a 5′ Group I intron fragment containing a 5′ splice site dinucleotide, and g.) a 3′ homology arm, the vector allowing production of a circular RNA that is translatable or biologically active inside eukaryotic cells. Methods for purifying the circular RNA produced by the vector and the use of nucleoside modifications in circular RNA produced by the vector are also disclosed.

A non-naturally occurring cell comprising an inoperative genomic asparaginase (Aspg) gene and an inoperative glutamine synthetase (Gs) gene, wherein the cell has been transfected with a controllably expressed gene encoding an enzyme having asparaginase activity, a controllably expressed gene encoding an enzyme having glutamine synthetase activity, and a controllably expressed gene encoding a heterologous protein of interest.

The present invention generally relates to a process for designing a recombinant poxvirus for a therapeutic vaccine, i.e. personalized cancer vaccine, said recombinant poxvirus comprising one or more expression cassettes, each for expression of a fusion of a plurality of peptides, i.e. neopeptides, characterized in that it comprises performing by processing means (11) of a server (1) the steps of : (a) selecting a first subset of candidate peptides, wherein said peptides present transmembrane scores below a TMS threshold; b) determining an optimal distribution of the candidate peptides from said first subset to the expression cassette(s) among a plurality of possible distributions, wherein said optimal distribution presents, if there are at least two expression cassettes, the lowest range between the hydropathy scores of at least two expression cassettes; (c) for each expression cassette, determining an optimal slot allocation of the candidate peptides as function of cassette slot occupancy rule so as to select the peptide fusion with the lowest TM score; (d) determining a DNA transfer sequence comprising the nucleotide sequence of the one or more expression cassette(s) for generation of said recombinant poxvirus.

The present invention provides clinical evidence for a method of stem cell transplantation that facilitates engraftment and reconstitutes immunocompetence of the recipient without requiring myeloablative conditioning.

A circular mRNA molecule possessing features resembling native mammalian mRNA demonstrates improved translation, while retaining the properties of an extremely long half-life inside cells. This circular mRNA is functional inside mammalian cells, being able to compete against native cellular mRNAs for the eukaryotic translation initiation machinery. The invention possesses additional RNA elements compared to a previous invention containing only an IRES element for successful in vitro or in vivo translation.

Provided is application of ECM1 in the prevention and/or treatment of liver fibrosis-related diseases, specifically provided is the use of ECM1 gene, or protein or a promoter thereof for preparing a composition or a formulation, the composition or formulation being used for (a) preventing and/or treating of liver fibrosis-related diseases; and/or for (b) maintaining liver homeostasis. The ECM1 gene, or the protein or promoter thereof can significantly (i) prevent and/or treat cirrhosis-related diseases; and/or (ii) maintain the liver homeostasis. In addition, the ECM1 gene, or the protein or promoter thereof can also significantly (i) inhibit the occurrence of liver fibrosis-related diseases; and/or (ii) inhibit the activation of hepatic stellate cells (HSCs).

Described herein are methods and compositions for producing a gene of interest (GOD, which, in certain embodiments, can reduce the metabolic burden on cells and reduce decoupling of GOI production from marker production, as compared to prior art methods. The methods relate to positive selection and negative selection approaches to establishing high GOI-producing cell lines, e.g., CHO lines. In certain embodiments, the methods comprise transfecting a cell with (a) an oligonucleotide comprising a GOI and a non-coding RNA, and (b) an oligonucleotide encoding a selection protein; wherein the non-coding RNA promotes or inhibits production of the selection protein. The cell producing the can be identified and/or selected as a result of or by detecting the absence or the presence of the selection protein.

Described herein are methods and compositions for producing a gene of interest (GOI) which, in certain embodiments, can reduce the metabolic burden on cells and reduce decoupling of GOI production from marker production, as compared to prior art methods. The methods relate to positive selection and negative selection approaches to establishing high GOI-producing cell lines, e.g., CHO lines. In certain embodiments, the methods comprise transfecting a cell with (a) an oligonucleotide comprising a GOI and a non-coding RNA, and (b) an oligonucleotide encoding a selection protein; wherein the non-coding RNA promotes or inhibits production of the selection protein. The cell producing the GOI can be identified and/or selected as a result of or by detecting the absence or the presence of the selection protein.