Characterization of the isolated cAMP-binding B domain of cAMP-dependent protein kinase.

A 14.4-kDa cAMP-binding fragment was generated during bacterial expression and purification of recombinant bovine cAMP-dependent protein kinase type I alpha regulatory subunit (RI alpha). The full-length RI alpha from which the fragment was derived contained a point mutation allowing its B domain to bind both cAMP and cGMP with high affinity while leaving its A domain highly cAMP selective. The NH2 terminus of the fragment was Ser-252, indicating that it encompassed the entire predicted B domain. Although the [3H]cAMP and [3H]cGMP exchange rates of the isolated B domain were increased relative to the B domain in intact RI alpha, the [3H]cAMP exchange rate was comparable to that of the B domain of full-length RI alpha containing an unoccupied A domain. A plasmid encoding only the isolated B domain was overexpressed in Escherichia coli, and a monomeric form of the B domain was purified that had identical properties to the proteolytically generated fragment, indicating that all of the elements for the high-affinity cAMP-binding B domain are contained within the 128 amino acid carboxyl terminus of the R subunit. Prolonged induction of the B domain in E. coli or storage of the purified protein resulted in the formation of a dimer that could be reverted to the monomer by incubation in 2-mercaptoethanol. Dimerization caused an approximate fivefold increase in the rate of cyclic nucleotide exchange relative to the monomer. The results show that an isolated cAMP-binding domain can function independently of any other domain structures of the R subunit.     

Evidence for the activation of 6-phosphofructo-1-kinase by cAMP-dependent protein kinase in Aspergillus niger

Abstract The change from pentose phosphate pathway to glycolysis plays a significant role in the physiology of Aspergillus niger during the induction of citric acid accumulation. Evidence is shown for the importance of 6-phophofructo-1-kinase in this process since it is activated by phosphorylation. By incubating a purified active form of enzyme together with commercially available alkaline phosphatase, 6-phosphofructo-1-kinase activity was lost after a certain time suggesting that the enzyme was dephosphorylated. Inactive 6-phosphofructo-1-kinase could be isolated from the cells in the early stage of growth in a high citric acid yielding medium. The enzyme was 'in vitro' activated by isolated protein kinase in the presence of cAMP, ATP and Mg²⁺ ions. Additional evidence for covalent phosphorylation of inactive 6-phosphofructo-1-kinase was obtained by incubating both enzymes together with labelled [ γ −³²P]ATP. The activating enzyme was partially purified from A. niger mycelium.     

Catalytic independent functions of a protein kinase as revealed by a kinase-dead mutant: study of the Lys72His mutant of cAMP-dependent kinase

A highly conserved lysine in subdomain II is required for high catalytic activity among the protein kinases. This lysine interacts directly with ATP and mutation of this residue leads to a classical "kinase-dead" mutant. This study describes the biophysical and functional properties of a kinase-dead mutant of cAMP-dependent kinase where Lys72 was replaced with His. Although the mutant protein is less stable than the wild-type catalytic subunit, it is fully capable of binding ATP. The results highlight the effect of the mutation on stability and overall organization of the protein, especially the small lobe. Phosphorylation of the activation loop by a heterologous kinase, 3-phosphoinositide-dependent protein kinase-1 (PDK-1) also contributes dramatically to the global organization of the entire active site region. Deuterium-exchange mass spectrometry (DXMS) indicates a concerted stabilization of the entire active site following the addition of this single phosphate to the activation loop. Furthermore the mutant C-subunit is capable of binding both the type I and II regulatory subunits, but only after phosphorylation of the activation loop. This highlights the role of the large lobe as a scaffold for the regulatory subunits independent of catalytic competency and suggests that kinase dead members of the protein kinase superfamily may still have other important biological roles although they lack catalytic activity.     

Crystal structure of a cAMP-dependent protein kinase mutant at 1.26A: new insights into the catalytic mechanism

The catalytic subunit of cAMP-dependent protein kinase has served as a paradigm for the entire kinase family. In the course of studying the structure-function relationship of the P+1 loop (Leu198-Leu205) of the kinase, we have solved the crystal structure of the Tyr204 to Ala mutant in complexes with Mg.ATP and an inhibitory peptide at 1.26A, with overall structure very similar to that of the wild-type protein. However, at the nucleotide binding site, ATP was found largely hydrolyzed, with the products ADP-PO(4) retained in the structure. High-resolution refinement suggests that 26% of the molecules contain the intact ATP, whereas 74% have the hydrolyzed products. The observation of the substrate and product states in the same structure adds significant information to our understanding of the phosphoryl transfer process. Structural examination of the mutation site substantiates and extends the emerging concept that the hydrophobic core in the large lobe of the kinase might serve as a stable platform for anchoring key segments involved in catalysis. We propose that Tyr204 is critical for anchoring the P+1 loop to the core. Further analysis has highlighted two major connections between the P+1 loop and the catalytic loop (Arg165-Asn171). One emphasizes the hydrophobic packing of Tyr204 and Leu167 mediated through residues from the alphaF-helix, recently recognized as a signal integration motif, which together with the alphaE-helix forms the center of the hydrophobic core network. The other connection is mediated by the hydrogen bond interaction between Thr201 and Asp166, in a substrate-dependent manner. We speculate that the latter interaction may be important for the kinase to sense the presence of substrate and prepare itself for the catalytic reaction. Thus, the P+1 loop is not merely involved in substrate binding; it mediates the communication between substrate and catalytic residues.     

A conserved deamidation site at Asn 2 in the catalytic subunit of mammalian cAMP-dependent protein kinase detected by capillary LC-MS and tandem mass spectrometry.

The N-terminal sequence myr-Gly-Asn is conserved among the myristoylated cAPK (protein kinase A) catalytic subunit isozymes Calpha, Cbeta, and Cgamma. By capillary LC-MS and tandem MS, we show that, in approximately one third of the Calpha and Cbeta enzyme populations from cattle, pig, rabbit, and rat striated muscle, Asn 2 is deamidated to Asp 2. This deamidation accounts for the major isoelectric variants of the cAPK C-subunits formerly called CA and CB. Deamidation also includes characteristic isoaspartate isomeric peptides from Calpha and Cbeta. Asn 2 deamidation does not occur during C-subunit preparation and is absent in recombinant myristoylated Calpha (rCalpha) from Escherichia coli. Deamidation appears to be the exclusive pathway for introduction of an acidic residue adjacent to the myristoylated N-terminal glycine, verified by the myristoylation negative phenotype of an rCalpha(Asn 2 Asp) mutant. This is the first report thus far of a naturally occurring myr-Gly-Asp sequence. Asp 2 seems to be required for the well-characterized (auto)phosphorylation of the native enzyme at Ser 10. Our results suggest that the myristoylated N terminus of cAPK is a conserved site for deamidation in vivo. Comparable myr-Gly-Asn sequences are found in several signaling proteins. This may be especially significant in view of the recent knowledge that negative charges close to myristic acid in some proteins contribute to regulating their cellular localization.     

Surface-plasmon-resonance-based biosensor with immobilized bisubstrate analog inhibitor for the determination of affinities of ATP- and protein-competitive ligands of cAMP-dependent protein kinase

Interactions between adenosine-oligoarginine conjugates (ARC), bisubstrate analog inhibitors of protein kinases, and catalytic subunits of cAMP-dependent protein kinase (cAPK Calpha) were characterized with surface-plasmon-resonance-based biosensors. ARC-704 bound to the immobilized kinase with subnanomolar affinity. The immobilization of ARC-704 to the chip surface via streptavidin-biotin complex yielded a high-affinity surface (K(D)=16nM). The bisubstrate character of ARC-704 was demonstrated with various ligands targeted to ATP-binding pocket (ATP and inhibitors H89 and H1152P) and protein-substrate-binding domain of Calpha (RIIalpha and GST-PKIalpha) in competition assays. The experiments performed on surfaces with different immobilization levels of ARC-704 produced similar results. The closeness of the obtained affinities of the tested compounds to the inhibitory potencies and affinities of the compounds measured with other methods demonstrates the applicability of the chip with the immobilized biligand inhibitor for the characterization of both ATP- and substrate protein-competitive ligands of basophilic protein kinases.     

Kinase conformations: a computational study of the effect of ligand binding.

Protein function is often controlled by ligand-induced conformational transitions. Yet, in spite of the increasing number of three-dimensional crystal structures of proteins in different conformations, not much is known about the driving forces of these transitions. As an initial step toward exploring the conformational and energetic landscape of protein kinases by computational methods, intramolecular energies and hydration free energies were calculated for different conformations of the catalytic domain of cAMP-dependent protein kinase (cAPK) with a continuum (Poisson) model for the electrostatics. Three protein kinase crystal structures for ternary complexes of cAPK with the peptide inhibitor PKI(5-24) and ATP or AMP-PNP were modeled into idealized intermediate and open conformations. Concordant with experimental observation, we find that the binding of PKI(5-24) is more effective in stabilizing the closed and intermediate forms of cAPK than ATP. PKI(5-24) seems to drive the final closure of the active site cleft from intermediate to closed state because ATP does not distinguish between these two states. Binding of PKI(5-24) and ATP is energetically additive.     

Major 56,000-dalton, soluble phosphoprotein present in bovine sperm is the regulatory subunit of a type II cAMP-dependent protein kinase

It has been shown that cAMP-dependent phosphorylation of a soluble sperm protein is important for the initiation of flagellar motion. The suggestion has been made that this motility initiation protein, named axokinin, is the major 56,000-dalton phosphoprotein present in both dog sperm and in other cells containing axokinin-like activity. Since the regulatory subunit of a type II cAMP-dependent protein kinase is a ubiquitous cAMP-dependent phosphoprotein of similar subunit molecular weight as reported for axokinin, we have addressed the question of how many soluble 56,000-dalton cAMP-dependent phosphoproteins are present in mammalian sperm. We report that in bovine sperm cytosol, the ratio of the type I to type II cAMP-dependent protein kinase is approximately 1:1. The type II regulatory subunit is related to the non-neural form of the enzyme and undergoes a phosphorylation-dependent electrophoretic mobility shift. The apparent subunit molecular weights of the phospho and dephospho forms are 56,000 and 54,000 daltons, respectively. When bovine sperm cytosol or detergent extracts are phosphorylated in the presence of catalytic subunits, two major proteins are phosphorylated and have subunit molecular weights of 56,000 and 40,000 daltons. If, however, the type II regulatory subunit (RII) is quantitatively removed from these extracts using either immobilized cAMP or an anti-RII monoclonal affinity column, the ability to phosphorylate the 56,000- but not 40,000-dalton polypeptide is lost. These data suggest that the major 56,000 dalton cAMP-dependent phosphoprotein present in bovine sperm is the regulatory subunit of a type II cAMP-dependent protein kinase and not the motility initiator protein, axokinin.     

Backbone entropy of loops as a measure of their flexibility: Application to a Ras protein simulated by molecular dynamics

The flexibility of surface loops plays an important role in protein–protein and protein–peptide recognition; it is commonly studied by Molecular Dynamics or Monte Carlo simulations. We propose to measure the relative backbone flexibility of loops by the difference in their backbone conformational entropies, which are calculated here with the local states (LS) method of Meirovitch. Thus, one can compare the entropies of loops of the same protein or, under certain simulation conditions, of different proteins. These loops should be equal in size but can differ in their sequence of amino acids residues. This methodology is applied successfully to three segments of 10 residues of a Ras protein simulated by the stochastic boundary molecular dynamics procedure. For the first time estimates of backbone entropy differences are obtained, and their correlation with B factors is pointed out; for example, the segments which consist of residues 60–65 and 112–117 have average B factors of 67 and 18 Ų, respectively, and entropy difference T ΔS = 5.4 ± 0.1 kcal/mol at T = 300 K. In a large number of recent publications the entropy due to the fast motions (on the ps-ns time scale) of N–H and C–H vectors has been obtained from their order parameter, measured in nuclear magnetic resonance spin relaxation experiments. This enables one to estimate differences in the entropy of protein segments due to folding–unfolding transitions, for example. However, the vectors are assumed to be independent, and the effect of the neglected correlations is unknown; our method is expected to become an important tool for assessing this approximation. The present calculations, obtained with the LS method, suggest that the errors involved in experimental entropy differences might not be large; however, this should be verified in each case. Potential applications of entropy calculations to rational drug design are discussed. Proteins 29:127–140, 1997. © 1997 Wiley-Liss, Inc.     

How does activation loop phosphorylation modulate catalytic activity in the cAMP-dependent protein kinase: a theoretical study

Phosphorylation mediates the function of many proteins and enzymes. In the catalytic subunit of cAMP-dependent protein kinase, phosphorylation of Thr 197 in the activation loop strongly influences its catalytic activity. In order to provide theoretical understanding about this important regulatory process, classical molecular dynamics simulations and ab initio QM/MM calculations have been carried out on the wild-type PKA-Mg(2) ATP-substrate complex and its dephosphorylated mutant, T197A. It was found that pThr 197 not only facilitates the phosphoryl transfer reaction by stabilizing the transition state through electrostatic interactions but also strongly affects its essential protein dynamics as well as the active site conformation.     

Importance of the A-helix of the catalytic subunit of cAMP-dependent protein kinase for stability and for orienting subdomains at the cleft interface.

All eukaryotic protein kinases share a conserved catalytic core. In the catalytic (C) subunit of cAMP-dependent protein kinase (cAPK) this core is preceded by a myristylation motif followed by a long helix with Trp 30 at the end of this A-helix filling a hydrophobic cavity between the two lobes of the core. To understand the importance of the A-helix, the myristylation motif (delta 1-14) as well as the entire N-terminal segment (delta 1 -39) were deleted. In addition, Trp 30 was replaced with both Tyr and Ala. All proteins were overexpressed in E. coli and purified to homogeneity. rC(delta 1-14), rC(W30Y), and rC(W30A) all had reduced thermostability, but were catalytically indistinguishable from wild-type C. Based on Surface Plasmon Resonance, all three also formed stable holoenzyme complexes with the RI-subunit, although the appKds were reduced by more than 10-fold due to decrease in the association rate. Surprisingly, however, the holoenzymes were even more thermostable than wild-type holoenzyme. To obtain active enzyme, it was necessary to purify rC(delta 1-39) as a fusion protein with glutathione-S-transferase (GST-rC(delta 1-39), although its thermostability (Tm) was decreased by 12.5 degrees C, was catalytically similar to wild-type C and was inhibited by both the type I and II R-subunits and the heat-stable protein kinase inhibitor (PKI). The Tm for holoenzyme II formed with GST-rC(delta 1-39) was 16.5 degrees C greater than the Tm for free GST-rC(delta 1-39), and the Ka(cAMP) was increased nearly 10-fold. These mutants point out striking and unanticipated differences in how the RI and RII subunits associate with the C-subunit to form a stable holoenzyme and indicate, furthermore, that this N-terminal segment, far from the active site cleft, influences those interactions. The importance of the A-helix and Trp 30 for stability correlates with its location at the cleft interface where it orients the C-helix in the small lobe and the activation loop in the large so that these subdomains are aligned in a way that allows for correct configuration of residues at the active site. This extensive network of contacts that links the A-helix directly to the active site in cAPK is compared to other kinases whose crystal structures have been solved.     

Molecular cloning and characterization of Ct-PKAR, a gene encoding the regulatory subunit of cAMP-dependent protein kinase in Colletotrichum trifolii

Colletotrichum trifolii is a plant pathogenic fungus causing alfalfa anthracnose. Prepenetration development, including conidial germination and appressorial formation, are requisite for successful infection. Pharmacological data from our laboratory indicated a role for a cAMP-dependent protein kinase (PKA) pathway during these early morphogenic transitions. Thus, the cloning and characterization of the genes for PKA catalytic and regulatory subunits were undertaken to more precisely determine the function of PKA during C. trifolii pathogenic growth and development. In this report, the cloning, sequencing, and partial characterization of the gene encoding the regulatory subunit of cAMP-dependent protein kinase (Ct-PKAR) is described. An open reading frame of 1,212 bp containing 404 predicted amino acid residues was identified. Database analysis revealed that the deduced amino acid sequence of Ct-PKAR shares considerable similarity with that of PKA regulatory subunits in other organisms, particularly in the conserved regions. Furthermore, the Ct-PKAR protein is classified as a type II regulatory subunit based on the presence of the hallmark autophosphorylation site. Southern blot analysis indicated that Ct-PKAR is a single-copy gene. Northern blot analysis showed that the expression of Ct-PKAR is developmentally regulated. Ct-PKAR was shown to be a functional regulatory subunit of PKA by complementating the Neurospora crassa mcb mutant, which has a temperature-sensitive mutation in the regulatory subunit of PKA. Received: 26 August 1998 / Accepted: 30 December 1998     

DNA-binding orientation and domain conformation of the E. coli rep helicase monomer bound to a partial duplex junction: single-molecule studies of fluorescently labeled enzymes

The SF1 DNA helicases are multi-domain proteins that can unwind duplex DNA in reactions that are coupled to ATP binding and hydrolysis. Crystal structures of two such helicases, Escherichia coli Rep and Bacillus stearothermophilus PcrA, show that the 2B sub-domain of these proteins can be found in dramatically different orientations (closed versus open) with respect to the remainder of the protein, suggesting that the 2B domain is highly flexible. By systematically using fluorescence resonance energy transfer at the single-molecule level, we have determined both the orientation of an E.coli Rep monomer bound to a 3'-single-stranded-double-stranded (ss/ds) DNA junction in solution, as well as the relative orientation of its 2B sub-domain. To accomplish this, we developed a highly efficient procedure for site-specific fluorescence labeling of Rep and a bio-friendly immobilization scheme, which preserves its activities. Both ensemble and single-molecule experiments were carried out, although the single-molecule experiments proved to be essential here in providing quantitative distance information that could not be obtained by steady-state ensemble measurements. Using distance-constrained triangulation procedures we demonstrate that in solution the 2B sub-domain of a Rep monomer is primarily in the "closed" conformation when bound to a 3'-ss/ds DNA, similar to the orientation observed in the complex of PcrA bound to a 3'-ss/ds DNA. Previous biochemical studies have shown that a Rep monomer bound to such a 3'-ss/ds DNA substrate is unable to unwind the DNA and that a Rep oligomer is required for helicase activity. Therefore, the closed form of Rep bound to a partial duplex DNA appears to be an inhibited form of the enzyme.     

Catalytic subunit of cAMP-dependent protein kinase from a catch muscle of the bivalve mollusk Mytilus galloprovincialis: purification, characterization, and phosphorylation of muscle proteins

cAMP-dependent protein kinase (PKA) plays a crucial role in the release of the catch state of molluskan muscles, but the nature of the enzyme in such tissues is unknown. In this paper, we report the purification of the catalytic (C) subunit of PKA from the posterior adductor muscle (PAM) of the sea mussel Mytilus galloprovincialis. It is a monomeric protein with an apparent molecular mass of 40.0+/-2.0kDa and Stoke's radius 25.1+/-0.3A. The protein kinase activity of the purified enzyme was inhibited by both isoforms of the PKA regulatory (R) subunit that we had previously characterized in the mollusk, and also by the inhibitor peptide PKI(5-24). On the other hand, the main proteins of the contractile apparatus of PAM were partially purified and their ability to be phosphorylated in vitro by purified PKA C subunit was analyzed. The results showed that twitchin, a high molecular mass protein associated with thick filaments, was the better substrate for endogenous PKA. It was rapidly phosphorylated with a stoichiometry of 3.47+/-0.24mol Pmol(-1) protein. Also, catchin, paramyosin, and actin were phosphorylated, although more slowly and to a lesser extent. On the contrary, myosin heavy chain (MHC) and tropomyosin were not phosphorylated under the conditions used.     

15N backbone dynamics of the S-peptide from ribonuclease A in its free and S-protein bound forms: toward a site-specific analysis of entropy changes upon folding.

Backbone 15N relaxation parameters (R1, R2, 1H-15N NOE) have been measured for a 22-residue recombinant variant of the S-peptide in its free and S-protein bound forms. NMR relaxation data were analyzed using the "model-free" approach (Lipari & Szabo, 1982). Order parameters obtained from "model-free" simulations were used to calculate 1H-15N bond vector entropies using a recently described method (Yang & Kay, 1996), in which the form of the probability density function for bond vector fluctuations is derived from a diffusion-in-a-cone motional model. The average change in 1H-15N bond vector entropies for residues T3-S15, which become ordered upon binding of the S-peptide to the S-protein, is -12.6+/-1.4 J/mol.residue.K. 15N relaxation data suggest a gradient of decreasing entropy values moving from the termini toward the center of the free peptide. The difference between the entropies of the terminal and central residues is about -12 J/mol residue K, a value comparable to that of the average entropy change per residue upon complex formation. Similar entropy gradients are evident in NMR relaxation studies of other denatured proteins. Taken together, these observations suggest denatured proteins may contain entropic contributions from non-local interactions. Consequently, calculations that model the entropy of a residue in a denatured protein as that of a residue in a di- or tri-peptide, might over-estimate the magnitude of entropy changes upon folding.     

Characterization of a fluorescent substrate for the adenosine 3',5'-cyclic monophosphate-dependent protein kinase

A synthetic tetradecapeptide derived from the phosphorylation site of the beta-subunit of phosphorylase kinase (Arg-Thr-Lys-Arg-Ser-Gly-Ser-Val-Tyr-Glu-Pro-Leu-Lys-Ile) is a highly efficient substrate for the cAMP-dependent protein kinase, exhibiting a 36% decrease in the intrinsic tyrosine fluorescence on phosphorylation. The fluorescence changes in continuous assays were monitored to demonstrate the roles of protein kinase effectors (cAMP, the type II regulatory subunit, and the 8000-Da heat-stable inhibitor) in the regulation of the enzyme and to determine Km and Vmax. The phosphorylation reaction requires 1 mol ATP/mol peptide. Amino acid analysis demonstrates the presence of phosphoserine in the phosphorylated peptide. Auxiliary experiments show that tyrosine phosphorylation can also be detected fluorometrically and distinguished from serine or threonine phosphorylation.     

Structural characterization of the membrane-associated regulatory subunit of type I cAMP-dependent protein kinase by mass spectrometry: identification of Ser81 as the in vivo phosphorylation site of RIalpha.

The mechanism by which the type Ialpha regulatory subunit (RIalpha) of cAMP-dependent protein kinase is localized to cell membranes is unknown. To determine if structural modification of RIalpha is important for membrane association, both beef skeletal muscle cytosolic RI and beef heart membrane-associated RI were characterized by electrospray ionization mass spectrometry. Total sequence coverage was 98% for both the membrane-associated and cytosolic forms of RI after digestion with AspN protease or trypsin. Sequence data indicated that membrane-associated and cytosolic forms of RI were the same RIalpha gene product. A single RIalpha phosphorylation site was identified at Ser81 located near the autoinhibitory domain of both membrane-associated and cytosolic RIalpha. Because both R subunit preparations were 30-40% phosphorylated, this post-translational modification could not be responsible for the membrane compartmentation of the majority of RIalpha. Mass spectrometry also indicated that membrane-associated RIalpha had a higher extent of disulfide bond formation in the amino-terminal dimerization domain. No other structural differences between cytosolic and membrane-associated RIalpha were detected. Consistent with these data, masses of the intact proteins were identical by LCQ mass spectrometry. Lack of detectable structural differences between membrane-associated and cytosolic RIalpha strongly suggests an interaction between RIalpha and anchoring proteins or membrane lipids as more likely mechanisms for explaining RIalpha membrane association in the heart.     

Conformationally constrained analogs of protein kinase inhibitor (6-22)amide: effect of turn structures in the center of the peptide on inhibition of cAMP-dependent protein kinase.

The high-affinity interaction between protein kinase inhibitor (PKI)(6-22)amide(Thr6-Tyr-Ala-Asp-Phe-Ile-Ala-Ser-Gly-Arg-Thr-Gly- Arg-Arg-Asn- Ala-Ile22-NH2) and the catalytic subunit of cAMP-dependent protein kinase requires both the N-terminal Thr6 to Ile11 sequence of the inhibitor peptide and its C-terminal pseudosubstrate site comprised of Arg15 to Ile22. Small angle X-ray scattering data indicate that PKI(6-22)amide has a compact, rather than extended, structure in solution (Reed J et al., 1989, Biochem J 264:371-380). CD spectroscopic analysis of the PKI peptide led to the suggestion that a beta-turn structure might be located in the -Ala12-Ser-Gly-Arg15-connecting sequence in the middle of the molecule (Reed J, Kinzel V, Cheng HC, Walsh DA, 1987, Biochemistry 26:7641-7647). To investigate this possibility further, conformationally constrained and flexible analogs of PKI(6-22)amide were synthesized and used to study the structure-function relationships of this central portion of the inhibitor. (Des12-14)PKI(6-22) amide exhibited over a 200-fold loss in inhibitory activity. Replacement of the omitted -Ala12-Ser-Gly14-sequence with aminocaprylic acid yielded an analog that regained more than 90% of the lost binding energy. The D-alanine14 PKI analog was as potent as the parent peptide, whereas the beta-alanine14 and the sarcosine14 analogs were only 10-fold less active. Several peptides that promoted a beta-turn structure at residues 12-15 showed about 200-fold decreases in inhibitory activity. Two constrained analogs that could not assume a beta-turn conformation were only 30-fold less potent than PKI(6-22)amide. Thus, the structure of the central connecting portion of the PKI peptide, encompassing residues 12-15, greatly influences its ability to effectively bind to and inhibit the catalytic subunit. We conclude, however, that a formal beta-turn at this position is not required and is actually detrimental for a high-affinity interaction of PKI(6-22)amide with the enzyme. These results are interpreted in light of the Fourier-transform infrared spectra of the peptide analogs and the crystal structure of the peptide bound at the active site of the protein kinase (Knighton DR et al., 1991b, Science 253:414-420).     

Small-molecule FRET probes for protein kinase activity monitoring in living cells

In this study, the applicability of fluorescently labeled adenosine analogue-oligoarginine conjugates (ARC-Photo probes) for monitoring of protein kinase A (PKA) activity in living cells was demonstrated. ARC-Photo probes possessing subnanomolar affinity towards the catalytic subunit of PKA (PKAc) and competitive with the regulatory subunit (PKAr), penetrate cell plasma membrane and associate with PKAc fused with yellow fluorescent protein (PKAc-YFP). Detection of inter-molecular Förster resonance energy transfer (FRET) efficiency between the fluorophores of the fusion protein and ARC-Photo probe can be used for both the evaluation of non-labeled inhibitors of PKAc and for monitoring of cAMP signaling via detection of changes in the activity of PKA as a cAMP downstream effector.