Biochemical characterization and cellular imaging of a novel, membrane permeable fluorescent cAMP analog.

BACKGROUND: A novel fluorescent cAMP analog (8-[Pharos-575]- adenosine-3', 5'-cyclic monophosphate) was characterized with respect to its spectral properties, its ability to bind to and activate three main isoenzymes of the cAMP-dependent protein kinase (PKA-Ialpha, PKA-IIalpha, PKA-IIbeta) in vitro, its stability towards phosphodiesterase and its ability to permeate into cultured eukaryotic cells using resonance energy transfer based indicators, and conventional fluorescence imaging. RESULTS: The Pharos fluorophore is characterized by a Stokes shift of 42 nm with an absorption maximum at 575 nm and the emission peaking at 617 nm. The quantum yield is 30%. Incubation of the compound to RIIalpha and RIIbeta subunits increases the amplitude of excitation and absorption maxima significantly; no major change was observed with RIalpha. In vitro binding of the compound to RIalpha subunit and activation of the PKA-Ialpha holoenzyme was essentially equivalent to cAMP; RII subunits bound the fluorescent analog up to ten times less efficiently, resulting in about two times reduced apparent activation constants of the holoenzymes compared to cAMP. The cellular uptake of the fluorescent analog was investigated by cAMP indicators. It was estimated that about 7 muM of the fluorescent cAMP analog is available to the indicator after one hour of incubation and that about 600 muM of the compound had to be added to intact cells to half-maximally dissociate a PKA type IIalpha sensor. CONCLUSION: The novel analog combines good membrane permeability- comparable to 8-Br-cAMP - with superior spectral properties of a modern, red-shifted fluorophore. GFP-tagged regulatory subunits of PKA and the analog co-localized. Furthermore, it is a potent, PDE-resistant activator of PKA-I and -II, suitable for in vitro applications and spatial distribution evaluations in living cells.

Systematic interpretation of cyclic nucleotide binding studies using KinetXBase.

Functional proteomics aims to describe cellular protein networks in depth based on the quantification of molecular interactions. In order to study the interaction of adenosine-3',5'-cyclic monophosphate (cAMP), a general second messenger involved in several intracellular signalling networks, with one of its respective target proteins, the regulatory (R) subunit of cAMP dependent protein kinase (PKA), a number of different methods was employed. These include fluorescence polarisation (FP), isothermal titration calorimetry (ITC), surface plasmon resonance (SPR), amplified luminescence proximity homogeneous assay (ALPHA-screen), radioligand binding or activity-based assays. Kinetic, thermodynamic and equilibrium binding data of a variety of cAMP derivatives to several cAMP binding domains were integrated in a single database system, we called KinetXBase, allowing for very distinct data formats. KinetXBase is a practical data handling system for molecular interaction data of any kind, providing a synopsis of data derived from different technologies. This supports ongoing efforts in the bioinformatics community to devise formal concepts for a unified representation of interaction data, in order to enable their exchange and easy comparison. KinetXBase was applied here to analyse complex cAMP binding data and highly site-specific cAMP analogues could be identified. The software package is free for download by academic users.

Comparative thermodynamic analysis of cyclic nucleotide binding to protein kinase A.

We have investigated the thermodynamic parameters and binding of a regulatory subunit of cAMP-dependent protein kinase (PKA) to its natural low-molecular-weight ligand, cAMP, and analogues thereof. For analysis of this model system, we compared side-by-side isothermal titration calorimetry (ITC) with surface plasmon resonance (SPR). Both ITC and SPR analyses revealed that binding of the protein to cAMP or its analogues was enthalpically driven and characterised by similar free energy values (DeltaG=-9.4 to -10.7 kcal mol-1) for all interactions. Despite the similar affinities, binding of the cyclic nucleotides used here was characterised by significant differences in the contribution of entropy (-TDeltaS) and enthalpy (DeltaH) to DeltaG. The comparison of ITC and SPR data for one cAMP analogue further revealed deviations caused by the method. These equilibrium parameters could be complemented by thermodynamic data of the transition state (DeltaHnot equal, DeltaGnot equal, DeltaSnot equal) for both association and dissociation measured by SPR. This direct comparison of ITC and SPR highlights method-specific advantages and drawbacks for thermodynamic analyses of protein/ligand interactions.

Rearrangements in a hydrophobic core region mediate cAMP action in the regulatory subunit of PKA.

cAMP-dependent protein kinase (PKA) forms an inactive heterotetramer of two regulatory (R; with two cAMP-binding domains A and B each) and two catalytic (C) subunits. Upon the binding of four cAMP molecules to the R dimer, the monomeric C subunits dissociate. Based on sequence analysis of cyclic nucleotide-binding domains in prokaryotes and eukaryotes and on crystal structures of cAMP-bound R subunit and cyclic nucleotide-free Epac (exchange protein directly activated by cAMP), four amino acids were identified (Leu203, Tyr229, Arg239 and Arg241) and probed for cAMP binding to the R subunits and for R/C interaction. Arg239 and Arg241 (mutated to Ala and Glu) displayed no differences in the parameters investigated. In contrast, Leu203 (mutated to Ala and Trp) and Tyr229 (mutated to Ala and Thr) exhibited up to 30-fold reduced binding affinity for the C subunit and up to 120-fold reduced binding affinity for cAMP. Tyr229Asp showed the most severe effects, with 350-fold reduced affinity for cAMP and no detectable binding to the C subunit. Based on these results and structural data in the cAMP-binding domain, a switch mechanism via a hydrophobic core region is postulated that is comparable to an activation model proposed for Epac.