Methods and formulations for diagnosing metabolic disorders in humans using epimetabolic shifters, multidimensional intracellular molecules or environmental influencers are described.

Disclosed herein are ATP biosensor fusion proteins and their use for assaying ATP levels in cells.

Disclosed herein is a protein-based, genetically-encoded bioluminescent sensor that can report changes in intracellular ATP in live cells. This sensor is built from the NanoLuc luciferase (Promega) and mScarlet red fluorescent protein (DOI: 10.1038/nmeth.4074) in a novel platform that provides a much more quantitative optical signal for measurements. Analytical Chemistry demonstrates its characterization and that it can be used to image ATP differences in live cells under the skin of mice. This new sensor can be very useful for research purposes in cancer biology to measure cell health and chemotherapeutic drug efficacy for example in animal models of tumors or in cell-based screening.

The instant invention provides workflows for the design and characterization of mechanism-based sirtuin modulating compounds, including new or improved sirtuin activating compounds. Workflows for the design of mechanism-based sirtuin activating compounds are provided, based on conditions that must be satisfied by activators if they are to exploit the common catalytic mechanism of all sirtuin enzymes and hence increase catalytic efficiency for any sirtuin and any substrate.

The invention relates to the detection of the cofactor reduced nicotinamide adenine dinucleotide phosphate (NADPH). Provided is a sensor molecule for the resonance energy transfer (RET)-based detection of NADPH, the sensor comprising a segment A connected via a linker to a segment B, wherein each of segment A and segment B comprises a member of a RET pair comprising a donor moiety and an acceptor moiety, further characterized in that (i) segment A comprises a binding protein (BP) for NADPH, the BP being dihydrofolate reductase (DHFR; EC 1.5.1.3) or a functional homolog, fragment, derivative or variant thereof, showing the desired NADPH binding properties, and wherein the BP comprises a heterologous protein domain inserted at or replacing at least part of the region corresponding to positions (20) to (27) of E. coli DHFR, said heterologous protein domain comprising the member of the RET pair; (ii) segment B comprises a ligand (L) capable of intramolecular binding to said BP only in the presence of NADPH; such that the donor moiety and the acceptor moiety are in a suitable juxtaposition to yield a RET signal when L is bound to BP, and wherein NADPH-induced binding of L to BP results in an increase in RET efficiency.

Methods and formulations for treating onocological disorders in humans using Coenzyme Q10 are described.

Methods and formulations for treating oncological disorders in humans using epimetabolic shifters, multidimensional intracellular molecules or environmental influencers are described.

The subject invention provides methods, assays, and products for detecting small-molecule targets in a complex sample in both clinical and field settings. The subject invention provides aptamer-based sensors and methods of use thereof. The subject invention provides exonuclease-based methods for generating structure-switching aptamers from fully folded or pre-folded aptamers and developing aptamer-based sensors for small-molecule detection. The method for detecting one or more small-molecule targets in a sample comprises contacting the sample with one or more aptamer-based sensor selective for each of the small-molecule targets, and detecting the small-molecule target in the sample.

The invention relates to the detection of the cofactor reduced nicotinamide adenine dinucleotide phosphate (NADPH). Provided is a sensor molecule for the resonance energy transfer (RET)-based detection of NADPH, the sensor comprising a segment A connected via a linker to a segment B, wherein each of segment A and segment B comprises a member of a RET pair comprising a donor moiety and an acceptor moiety, further characterized in that (i) segment A comprises a binding protein (BP) for NADPH, the BP being dihydrofolate reductase (DHFR; EC 1.5.1.3) or a functional homolog, fragment, derivative or variant thereof, showing the desired NADPH binding properties, and wherein the BP comprises a heterologous protein domain inserted at or replacing at least part of the region corresponding to positions (20) to (27) of E. coli DHFR, said heterologous protein domain comprising the member of the RET pair; (ii) segment B comprises a ligand (L) capable of intramolecular binding to said BP only in the presence of NADPH; such that the donor moiety and the acceptor moiety are in a suitable juxtaposition to yield a RET signal when L is bound to BP, and wherein NADPH-induced binding of L to BP results in an increase in RET efficiency.

Methods and formulations for treating onocological disorders in humans using Coenzyme Q10 are described.