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 GFP with an F64L mutation and an E222G mutation is provided. This GFP has a bigger Stokes shift compared to other GFPs making it very suitable for high throughput screening due to a better resolution. This GFP also has an excitation maximum between the yellow GFP and the cyan GFP allowing for cleaner band separation when used together with those GFPs.

Abstract: The present invention relates to novel variants of the fluorescent protein GFP having improved fluorescence properties.

Abstract: A method and apparatus for screening an array of test compounds for bioactivity by contacting an array of test compounds with a detector layer capable of detecting bioactivity, and detecting a detector layer response. The detector layer is comprised of physiologically viable cells. The method and apparatus allow a large number of test compounds to be simultaneously assayed in parallel without the need for complex fluidic devices.

Abstract: A method and apparatus for screening an array of test compounds for bioactivity by contacting an array of test compounds with a detector layer capable of detecting bioactivity, and detecting a detector layer response. The detector layer is comprised of physiologically viable cells. The method and apparatus allow a large number of test compounds to be simultaneously assayed in parallel without the need for complex fluidic devices.

Abstract: Cells are genetically modified to expresss a luminophore, e.g., a modified (F64L, S65T, Y66H) Green Fluorescent Protein (GFP, EGFP) coupled to a component of an intracellular signalling pathway such as a transcription factor, a cGMP- or cAMP-dependent protein kinase, a cyclin-, calmodulin- or phospholipid-dependent or mitogen-activated serine/threonin protein kinase, a tyrosine protein kinase, or a protein phosphatase (e.g. PKA, PKC, Erk, Smad, VASP, actin, p38, Jnk1, PKG, IkappaB, CDK2, Grk5, Zap70, p85, protein-tyrosine phosphatase 1C, Stat5, NFAT, NFkappaB, RhoA, PKB). An influence modulates the intracellular signalling pathway in such a way that the luminophore is being redistributed or translocated with the component in living cells in a manner experimentally determined to be correlated to the degree of the influence.

Abstract: Cells are genetically modified to express a luminophore, e.g., a modified (F64L, S65T, Y66H) Green Flourescent Protein (GFP, EGFP) coupled to a component of an intracellular signalling pathway such as a transcription factor, a cGMP- or cAMP-dependent protein kinase, a cyclin-, calmodulin- or phospholipid-dependent or mitogen-activated serine/threonin protein kinase, a tryosine protein kinase, or a protein phosphatase (e.g. PKA, PKC, Erk, Smad, VASP, actin, p38, Jnkl, PKG, IkappaB, CDK2, Grk5, Zap70, p85, protein-tyrosine phosphatase 1C, Stat5, NFAT, NFkappaB, RhoA, PKB). An influence modulates the intracellular signaling pathway in such a way that the luminophore is being redistributed or translocated with the component in living cells in a manner experimentally determined to be correlated to the degree of influence.

Abstract: An electroporation apparatus for introducing exogenous material into cells is described herein. The apparatus comprises first a base member configured for holding a cell support, the cell support having a top surface portion, with the top surface portion configured for carrying adherent cells. The apparatus further comprises an electrode carrier operably associated with the base member, the electrode carrier having a bottom surface portion, a first electrode connected to the electrode carrier, and a second electrode also connected to the electrode carrier. The electrode carrier has a channel formed therein, with the channel positioned between the first electrode and the second electrode, so that exogenous material may be introduced through the channel and into contact with the cells. Methods for introducing exogenous compounds into a cell and for visually detecting the location of binding events within a cell are also disclosed.