Stopped-flow fluorescence spectroscopy is a highly sensitive method for measuring rapid enzyme kinetics. A wide range of fluorophores can be employed, and fluorescence and fluorescence polarization can be measured. Thus, binding, conformational changes, and catalysis can, in principle, be measured, making it helpful in probing the entire kinetic landscape of a reaction. In this chapter, we use the bacterial RNA processing enzyme ribonuclease P (RNase P) as a model system to illustrate the determination of the kinetic constants for substrate binding and cleavage, thus allowing mechanistic questions regarding the effects of reaction conditions, mutations, or drug binding to be answered.

A \"naked-eye\" detection of health hazardous bisulfite (HSO3-) and hypochlorite (ClO-) using an indicator dye (Quinaldine Red, QR) in a wide range of pH is demonstrated. The molecule contains a quinoline moiety linked to an N,N-dimethylaniline moiety with a conjugated double bond. Treatment of QR with HSO3- and ClO-, in aqueous solution at near-neutral pH, resulted in a colorless product with high selectivity and sensitivity. The detection limit was 47.8μM and 0.2μM for HSO3- and ClO- respectively. However, ClO- was 50 times more sensitive and with 2 times faster response compared to HSO3-. The detail characterization and related analysis demonstrate the potential of QR for a rapid, robust and highly efficient colorimetric sensor for the practical applications to detect hypochlorite in water samples.

Fluorescently labeled phosphate-binding proteins can be used as biomolecular tools to measure the release of inorganic phosphate (Pi) from enzymes in real time, enabling the detailed kinetic analysis of dephosphorylating enzymes using rapid-kinetics approaches. Previously reported methods to purify fluorescently labeled phosphate-binding proteins (PhoS) from Escherichia coli are laborious, and a simplified approach is needed. Here, we report the characterization of a cytosol-localized variant (A197C) of PhoS that allows a streamlined purification for subsequent covalent conjugation with a fluorescent dye. We show that export of PhoS into the periplasmic space is not required for the fluorescence-based detection of Pi binding. Furthermore, we report the addition of a C-terminal His-tag, simplifying the purification of PhoS from the cytosol via Ni2+-affinity chromatography, yielding a fully functional fusion protein (HC PhoS A197C). We demonstrate the utility of fluorescently labeled HC PhoS A197C for rapid-kinetics applications by measuring, using stopped-flow, the Pi release kinetics from LepA/EF4 following 70S ribosome-stimulated GTP hydrolysis. Altogether, the approach developed here allows for the high-yield and simplified in-house production of a Pi detection system suitable for rapid-kinetics approaches with comparable sensitivity to the commercially available Phosphate Sensor.