Abstract: The invention relates to methods for predicting the efficacy and/or resistance to one or more treatment regimens comprising administration of a platinum compound in individuals suffering from colon cancer. The methods comprises providing a colon cancer biopsy from the individual, generating tumoroids thereof, and testing whether growth/viability/metabolism of said tumorids is inhibited by incubation with the platinum compounds.

Abstract: The present invention relates to a method and tools for extracting information on a compounds influence on a cellular phenotype. The method of the invention may be used as a very efficient procedure for testing the efficacy or resistance of single drugs or combinations of drugs on cells from individual patients. Thus, the methods may be useful for predicting efficacy of a drug on a given patient. The methods are also useful for testing of compounds for toxicity, identifying drug targets for known or novel compounds.

Abstract: The present invention relates to a method and tools for extracting information on a compounds influence on a cellular phenotype. The method of the invention may be used as a very efficient procedure for testing the efficacy or resistance of single drugs or combinations of drugs on cells from individual patients. Thus, the methods may be useful for predicting efficacy of a drug on a given patient. The methods are also useful for testing of compounds for toxicity, identifying drug targets for known or novel compounds.

Abstract: The present invention relates to a method and tools for extracting information on a compounds influence on a cellular phenotype. The method of the invention may be used as a very efficient procedure for testing the efficacy or resistance of single drugs or combinations of drugs on cells from individual patients. Thus, the methods may be useful for predicting efficacy of a drug on a given patient. The methods are also useful for testing of compounds for toxicity, identifying drug targets for known or novel compounds.

Abstract: The present invention relates to methods for identifying compounds capable of modulating a cellular response. The methods involve attaching living cells to solid supports comprising a library of test compounds. The test compounds are linked to the solid support via cleavable linkers and may thus be released from the solid supports. Solid supports comprising cells, wherein the cellular response of interest has been modulated are selected and the test compound of the solid support can then be identified. The cellular response may for example be changes in complex formation between proteins.

Abstract: The present invention relates to methods for identifying compounds capable of modulating a cellular response. The methods involve attaching living cells to solid supports comprising a library of test compounds. The test compounds are linked to the solid support via cleavable linkers and may thus be released from the solid supports. Solid supports comprising cells, wherein the cellular response of interest has been modulated are selected and the test compound of the solid support can then be identified. The cellular response may for example be changes in complex formation between proteins.

Abstract: The present invention relates to methods for identifying compounds capable of modulating a cellular response. The methods involve attaching living cells to solid supports comprising a library of test compounds. Test compounds modulating a cellular response, for example via a cell surface molecule may be identified by selecting solid supports comprising cells, wherein the cellular response of interest has been modulated. The cellular response may for example be changes in signal transduction pathways modulated by a cell surface molecule.

Abstract: The present invention relates to methods for identifying compounds capable of modulating a cellular response. The methods involve attaching living cells to solid supports comprising a library of test compounds. The test compounds are linked to the solid support via cleavable linkers and may thus be released from the solid supports. Solid supports comprising cells, wherein the cellular response of interest has been modulated are selected and the test compound of the solid support can then be identified. The cellular response may for example be changes in complex formation between proteins.

Abstract: A method is described to assay for protein interactions in living cells, e.g. by the introduction of two heterologous conjugates into the cell. The method uses the measurement of cellular distribution of a detectable component (e.g. a GFP-labeled˜fluorescent probe) to indicate the presence or absence of an interaction between that component and a second component of interest. The method uses the knowledge that certain components can be stimulated to redistribute within the cell to defined locations. Inducible redistribution systems make it possible to determine if specific interactions occur between components. Inducible systems are described where it is demonstrated that the redistribution stimuli are essentially “null”, in that they affect no other system in the cell during the assay period, other than the component whose redistribution can be induced.

Abstract: The present invention relates to various uses of complementing proteins protein fragments to discover chemical compounds or drugs interfering with protein translocation/redistribution and/or protein interactions. The invention takes advantage of the fact that many interacting proteins reside in separate and distinct locations prior to the activation of the signaling pathways in which they play their part. The invention also takes advantage of interaction domains (FRBP, FKBP12) that can be induced to interact. Specifically disclosed are GFP (EGFP, F64L mutated EYFP) complementation.

Abstract: A method is described to assay for protein interactions in living cells, e.g. by the introduction of two heterologous conjugates into the cell. The method uses the measurement of cellular distribution of a detectable component (e.g. a GFP-labelled fluorescent probe) to indicate the presence or absence of an interaction between that component and a second component of interest. The method uses the knowledge that certain components can be stimulated to redistribute within the cell to defined locations. Inducible redistribution systems make it possible to determine if specific interactions occur between components. Inducible systems are described where it is demonstrated that the redistribution stimuli are essentially “null”, in that they affect no other system in the cell during the assay period, other than the component whose redistribution can be induced.

Abstract: The present invention involves that adding certain dyes to the solution outside cells expressing a GFP-tagged proteins in a redistribution assay, enhance the signal. Examples of such dyes are Trypan Blue and Acid Red. This enables redistribution assays to be measured as a change in light intensity. Redistribution movement from the cytosol to the membrane, or vice versa, are illustrated. The apparatus used for measuring the redistribution is an ordinary plate reader or a FLIPRTM type instrument. It is a common feature among the dyes described that the enhancer compound has an absorption spectrum overlapping the emission spectrum of the GFP.