Development of a Reagentless Biosensor for Inorganic Phosphate, Applicable over a Wide Concentration Range.

A fluorescent reagentless biosensor for inorganic phosphate (Pi), based on the E. coli PstS phosphate binding protein, was redesigned to allow measurements of higher Pi concentrations and at low, substoichiometric concentrations of biosensor. This was achieved by weakening Pi binding of the previous biosensor, and different approaches are described that could enable this change in properties. The readout, providing response to the Pi concentration, is delivered by tetramethylrhodamine fluorescence. In addition to two cysteine mutations for rhodamine labeling at positions 17 and 197, the final variant had an I76G mutation in the hinge region between the two lobes that make up the protein. Upon Pi binding, the lobes rotate on this hinge and the mutation on the hinge lowers affinity ∼200-fold, with a dissociation constant now in the tens to hundreds micromolar range, depending on solution conditions. The signal change on Pi binding was up to 9-fold, depending on pH. The suitability of the biosensor for steady-state ATPase assays was demonstrated with low biosensor usage and its advantage in ability to cope with Pi contamination.

Fluorescent single-stranded DNA binding protein as a probe for sensitive, real-time assays of helicase activity.

The formation and maintenance of single-stranded DNA (ssDNA) are essential parts of many processes involving DNA. For example, strand separation of double-stranded DNA (dsDNA) is catalyzed by helicases, and this exposure of the bases on the DNA allows further processing, such as replication, recombination, or repair. Assays of helicase activity and probes for their mechanism are essential for understanding related biological processes. Here we describe the development and use of a fluorescent probe to measure ssDNA formation specifically and in real time, with high sensitivity and time resolution. The reagentless biosensor is based on the ssDNA binding protein (SSB) from Escherichia coli, labeled at a specific site with a coumarin fluorophore. Its use in the study of DNA manipulations involving ssDNA intermediates is demonstrated in assays for DNA unwinding, catalyzed by DNA helicases.

A biosensor for inorganic phosphate using a rhodamine-labeled phosphate binding protein.

A novel biosensor for inorganic phosphate (Pi) has been developed based on the phosphate binding protein of Escherichia coli. Two cysteine mutations were introduced and labeled with 6-iodoacetamidotetramethylrhodamine. When physically close to each other and correctly oriented, two rhodamine dyes interact to form a noncovalent dimer. In this state, they have little or no fluorescence, unlike the high fluorescence intensity of monomeric rhodamine. The labeling sites were so placed that the distance and orientation between the rhodamines change as a consequence of the conformational change associated with Pi binding. This movement alters the extent of interaction between the dyes. The best mutant of those tested (A17C, A197C) gives rise on average to approximately 18-fold increase in fluorescence intensity as Pi binds. The kinetics of interaction with Pi were measured at 10 degrees C. Under these conditions, the fluorescence increase associated with Pi binding has a maximum rate of 267 s-1. The Pi dissociation rate is 6.6 s-1, and the dissociation constant is 70 nM. An application of the sensor is demonstrated for measuring ATP hydrolysis in real time as a helicase moves along DNA. Advantages of the new sensor are discussed, both in terms of the use of a rhodamine fluorophore and the potential of this double labeling strategy.

The mechanism of Ras GTPase activation by neurofibromin.

Individual rate constants have been determined for each step of the Ras.GTP hydrolysis mechanism, activated by neurofibromin. Fluorescence intensity and anisotropy stopped-flow measurements used the fluorescent GTP analogue, mantGTP (2'(3')-O-(N-methylanthraniloyl)GTP), to determine rate constants for binding and release of neurofibromin. Quenched flow measurements provided the kinetics of the hydrolytic cleavage step. The fluorescent phosphate sensor, MDCC-PBP was used to measure phosphate release kinetics. Phosphate-water oxygen exchange, using (18)O-substituted GTP and inorganic phosphate (P(i)), was used to determine the extent of reversal of the hydrolysis step and of P(i) binding. The data show that neurofibromin and P(i) dissociate from the NF1.Ras.GDP.P(i) complex with identical kinetics, which are 3-fold slower than the preceding cleavage step. A model is presented in which the P(i) release is associated with the change of Ras from "GTP" to "GDP" conformation. In this model, the conformation change on P(i) release causes the large change in affinity of neurofibromin, which then dissociates rapidly.