The enzymatic peptide phosphorylation by cAMP-dependent protein kinase A (PKA) was optimized and monitored by means of electrospray ionization mass spectrometry (ESI-MS). The direct detection of phosphorylated peptides by MS renders labeling unnecessary, reduces time and labor, due to less initial sample pretreatment. In this study the phosphorylation of the peptide malantide by PKA was performed in batch and reaction compounds were detected by ESI-MS after the incubation time. The subsequent product quantitation was accomplished by using one-point normalization. Applying this set-up, optimum solvent conditions (such as salt and modifier content), concentrations of essential reaction compounds (such as cAMP, Mg2+ and ATP), and the influence of reaction properties (such as pH and reaction time) were determined. The reaction milieu has to be suitable for both, the enzymatic reaction and the mass spectrometric detection. We found that the modifier content and the pH value had to be changed after the enzymatic reaction occurred. Through the addition of methanol and acetic acid, the reaction stopped immediately and a more sensitive mass spectrometric detection could be obtained simultaneously. Furthermore, an inhibitor study was performed, testing the inhibition potency of three protein kinase A inhibitors (PKIs). IC50 values were determined and used to calculate the Ki values, that were 7.4, 19.0 and 340.0 nmol/L for PKI(6-22)amide, PKI(5-24)amide, and PKI(14-24)amide, respectively. These data vary between factor 4.4 (for PKI(6-22)amide) and 8.3 (for PKI(5-24)amide) compared to the Ki values described in literature. However, the Ki values are in good agreement with the data mainly obtained by fluorescence- or radioactivity-based methods. Nevertheless, our results indicate that ESI-MS is a realistic alternative to radioactivity and fluorescence detection in determining enzymatic activity. Furthermore we were able to illustrate its high potential as a quantitative detection method.
Continuous-Flow, On-Line Monitoring of Biospecific Interactions Using Electrospray Mass Spectrometry
A continuous-flow analytical screening system is presented using electrospray mass spectrometry to measure the interaction of biologically active compounds with soluble affinity proteins. The biochemical detection system is based on a solution-phase, homogeneous assay. In a first step, compounds to be screened (e.g., biotinylated compounds, concentration range 10-1,000 nmol/L) are injected into a continuous-flow reaction system and allowed to react with the affinity protein (e.g., streptavidin, concentration range 3-48 nmol/L). Subsequently, a reporter ligand (fluorescein-labeled biotin 96 nmol/L) is added to saturate the remaining free binding sites of the affinity protein and the concentration of unbound reporter ligand is measured using electrospray MS in the selectedion monitoring mode. The presence of active compounds in the sample results in an increase of the concentration of unbound reporter ligands. The feasibility of a homogeneous MS-based biochemical assay is demonstrated using streptavidin/biotin and anti-digoxigenin/digoxin as model systems. Compared to radioactive or fluorescence-based biochemical assays, the present assay format does not require the synthesis and purification of labels. Various analytical conditions were investigated to determine the ability of MS to measure the biochemical interactions. The availability of a single ligand that can be detected at 10-50 nmol/L concentrations by electrospray MS is sufficient to set up the biochemical assay. For the biospecific interactions studies, detection limits of 10-100 nmol/L were obtained.
Electrospray ionization mass spectrometry was used to investigate complex formation of different metal complexes in a continuous-flow ligand-exchange reactor. A computer program was developed based on normal equilibrium calculations to predict the formation of various metal-ligand complexes. Corresponding to these calculations, infusion electrospray mass spectrometric experiments were performed to investigate the actual complex formation in solution. The data clearly show good correlation between the theoretically calculated formation of metal-ligand complexes and the experimental mass spectrometric data. Moreover, the approach demonstrates that the influence of the pH can be investigated using a similar approach. Indirectly, these infusion experiments provide information on relative binding constants of different ligands towards a metal-ion. To demonstrate this, a continuous-flow ligand-exchange detection system with mass spectrometric detection was developed. Injection of ligands, with different affinity for the metal-ion, into the reactor shows good correlation between binding constants and the response in the ligand-exchange detection system. Additional information on the introduced ligand, and the complexes formed after introduction of the ligand, can be obtained from interpretation of the mass spectra. , novel detection methods are necessary. Conventional techniques to study these interactions and complexes are infrared spectroscopy, X-ray diffraction, and nuclear magnetic resonance spectroscopy (NMR) [4], but these techniques have several drawbacks. The use of electrospray ionization mass spectrometry (ESI-MS) for studying metal-ions, metal-ligand interactions and metal complexes is readily recognized [5]. Using MS as a detection technique offers the advantage of being, in general, more sensitive than NMR and X-ray diffraction and opens up the possibility to screen complex samples. Moreover, MS enables simultaneous monitoring the response of ligand-exchange reactions and additionally obtaining chemical information about the specific compound [6,7].Today, MS is often used in studying host-guest complexes [8 -10], structural elucidation by collisioninduced dissociation (CID) MS [11,12], and studying relative binding constants of ligands to metal-ions [13,14]. Additionally, due to the liquid-based ionization in the ESI process, it is suitable for studying liquid-phase reactions, e.g., ligand-exchange reactions [6,7], which enables the study of complex systems.In general, the assumption is made of a good correlation between complexes formed in solution and what is observed in the mass spectrum [15]. FAB-MS and ESI-MS have been used in the past to evaluate binding selectivities of various compounds, e.g., caged crown ethers to metal-ions [16]. An excellent correlation between obtained ESI mass spectral data and expected binding selectivities has been reported in several papers [13,17,18], although several parameters should be kept in mind. For a good correlation between complex formation in solution and what i...
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