Disclosed are a construction method of a recombinant drug-resistant Mycobacterium bovis (M. bovis) Bacillus Calmette-Guerin (BCG) strain and a pharmaceutical composition for treating tuberculosis (TB). The construction method includes: using BCG as an original bacterial strain to construct a drug-resistant BCG strain resistant to at least one selected from the group consisting of STR, LFX, EMB, PRO, PAS, and AMK; and further inserting sequence fragments that can express related antigens Ag85b and Rv2628 causing an immune response into a genome of the strain to construct a recombinant drug-resistant BCG strain. The recombinant drug-resistant BCG strain can compete with Mycobacterium tuberculosis (Mtb) for growth, thereby accelerating the death of Mtb. When used in combination with a drug for treating TB, the recombinant drug-resistant BCG strain can further enhance a therapeutic effect for Mtb, and can also avoid re-infection of a patient.

Provided is a method for predicting sensitivity of a cancer cell to a helicase inhibitor, the method comprising the step of: predicting a cancer cell having at least one mutation detected selected from the first group consisting of TTK mutation and RAD 50 mutation, as having sensitivity to a helicase inhibitor, or predicting a cancer cell having at least one mutation detected selected from the second group consisting of RAD 50 mutation, MRE 11 mutation, NBN mutation, DNA 2 mutation and RBBP 8 mutation, as having sensitivity to a helicase inhibitor.

The present invention provides gene editing systems comprising gene editing dimerization switches comprising a first and second gene editing switch domain that allow for the regulation of a gene editing function by the introduction, e.g., administration, of a gene editing dimerization molecule having the ability to bring together a first gene editing switch domain and a second gene editing switch domain. A regulated gene editing function provides, e.g., less off-target side effects, and increases the therapeutic window.

The present invention also provides improved FKBP/FRB-based dimerization switches wherein the FRB switch domain or the FKBP switch domain, or both the FRB and FKBP switch domains, comprise one or more mutations that optimize performance, e.g., that alter, e.g., enhance the formation of a complex between the first switch domain, the second switch domain, and the dimerization molecule, rapamycin, or a rapalog, e.g., RAD001.

The present invention provides gene editing systems comprising gene editing dimerization switches comprising a first and second gene editing switch domain that allow for the regulation of a gene editing function by the introduction, e.g., administration, of a gene editing dimerization molecule having the ability to bring together a first gene editing switch domain and a second gene editing switch domain. A regulated gene editing function provides, e.g., less off-target side effects, and increases the therapeutic window.

The present invention also provides improved FKBP/FRB-based dimerization switches wherein the FRB switch domain or the FKBP switch domain, or both the FRB and FKBP switch domains, comprise one or more mutations that optimize performance, e.g., that alter, e.g., enhance the formation of a complex between the first switch domain, the second switch domain, and the dimerization molecule, rapamycin, or a rapalog, e.g., RAD001.

The present invention relates to a universal calibration method of use for assaying inhibitors of the same enzyme, for example for assaying inhibitors of an enzyme of blood coagulation. The invention also relates to the use of this universal calibration in a method for assaying a reversible or irreversible inhibitor of the enzyme in a biological sample. The invention also relates to the use of the universal calibration in a method for screening inhibitors of the enzyme.

The present invention relates to a universal calibration method of use for assaying inhibitors of the same enzyme, for example for assaying inhibitors of an enzyme of blood coagulation. The invention also relates to the use of this universal calibration in a method for assaying a reversible or irreversible inhibitor of the enzyme in a biological sample. The invention also relates to the use of the universal calibration in a method for screening inhibitors of the enzyme.

The invention relates to a process for the production of ethanol, the process comprising fermenting of a carbon source composition with a recombinant yeast,

wherein the carbon source composition comprises at least glucose and arabinose; and
wherein the recombinant yeast comprises arabinose isomerase activity, ribulokinase activity, ribulose phosphate epimerase activity, glycerol uptake activity and glycerol conversion capacity; and
wherein the recombinant yeast further comprises a genetic modification leading to the reduction, downregulation, inhibition and/or elimination of the activity of a homologous protein with glycerol-efflux activity; and
wherein each of the glucose and the arabinose is converted into ethanol.

In addition, the invention relates to a recombinant yeast that can be used in such a process.

The present application relates to a fructose-4-epimerase variant exhibiting tagatose conversion activity and a method for preparing tagatose using the same.

The present application relates to a fructose-4-epimerase variant exhibiting tagatose conversion activity and a method for preparing tagatose using the same.

The disclosure relates to enzymes, such as cucurbitadienol synthase (CDS), UDP-glycosyltransferase (UGT), C11 hydroxylase, epoxide hydrolase (EPH), squalene epoxidase (SQE), and/or cytochrome P450 reductase enzymes, recombinant host cells expressing the enzymes, and methods of producing mogrol precursors, mogrol, and/or mogrosides using such recombinant cells.