Effect of cyclic nucleotide analogs on intrachain site I of protein kinase isozymes

The effects of numerous cAMP analogs present in the [3H]cAMP binding reaction on subsequent dissociation of [3H]cAMP from the regulatory subunit of cAMP-dependent protein kinase I and II were analyzed. Certain analogs with modification at either C-8 or C-2 showed relative selectivity for one (site 1) of two intrachain cAMP binding sites of both isozymes. Modification at C-6 caused selectivity for the second site (site 2). The combination of a site-1-directed and site-2-directed analog inhibited [3H]cAMP binding much more than did either analog alone. In general, there was a correlation between the site 1 selectivity and the ability of the analog to stimulate the binding of [3H]cIMP, which selects site 2. The site-1-directed analogs stimulated the initial rate of [3H]cIMP binding. The stimulatory effect was enhanced in the presence of a polycationic protein such as histone and was inhibited by high ionic strength. The type I and II isozymes exhibited large differences in analog specificity for this effect. For type I, of the analogs tested the most efficacious for stimulating [3H]cIMP binding were those containing a nitrogen atom attached to C-8, 8-aminobutylamino-cAMP being the most effective. Type II responded best to analogs containing a sulfur atom attached to C-8, 8-SH-cAMP being the most effective of those tested. The stimulatory effect was accentuated in the presence of MgATP when using type I, but this nucleotide had no effect when using type II. It is proposed that in intact tissues cAMP binding to site 1 of either isozyme stimulates the binding to site 2.     

Purification and characterization of an inactive form of cAMP-dependent protein kinase containing bound cAMP

By a new procedure, the holoenzyme of bovine heart type II cAMP-dependent protein kinase was purified to homogeneity as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). A high performance liquid chromatography-DEAE purification step resolved two distinct peaks of protein kinase activity, which were designated Peak 1 and Peak 2 based on their order of elution. The two peaks exhibited similar Stokes radii and sedimentation coefficients. They had similar ratios of regulatory to catalytic subunits both by densitometric scanning of SDS-PAGE bands and by the ratios of equilibrium [3H]cAMP binding to maximal kinase activity. These results suggested that the holoenzyme of each peak contained two regulatory subunits and two catalytic subunits, although a subpopulation of holoenzyme lacking one catalytic subunit also appeared to be present in Peak 2. Assays of cAMP indicated that the Peak 1 holoenzyme was cAMP-free, but half of the Peak 2 holoenzyme cAMP binding sites contained cAMP. Determination of [3H]cAMP dissociation rates showed that the cAMP was equally distributed in binding Site 1 and Site 2 of Peak 2. Although SDS-PAGE analysis ruled out conversions by proteolysis or autophosphorylation-dephosphorylation, Peak 1 could be partially converted to Peak 2 by the addition of subsaturating amounts of cAMP. Interconvertibility of the two holoenzyme peaks strongly suggested that the difference between the two peaks was caused by the presence of cAMP in Peak 2. Peak 2 holoenzyme, as compared to Peak 1, had enhanced binding in nonequilibrium [3H]cIMP and [3H]cAMP binding assays, as was expected due to the presence of cAMP and to the known positive cooperativity in binding of cyclic nucleotides to the kinase. The positive cooperativity in kinase activation, as indicated by the Hill coefficient, was greater for Peak 2 than Peak 1, but the cAMP concentration required for half-maximal activation (Ka) of each of the two peaks was very similar. In conclusion, Peak 2 is an inactive ternary complex of cAMP, regulatory subunit, and catalytic subunit, and Peak 1 is a cAMP-free holoenzyme. The cAMP-bound form may represent a major cellular form of the enzyme which is primed for activation.     

Studies of two different intrachain cGMP-binding sites of cGMP-dependent protein kinase

The binding of [3H]cGMP to purified beef lung cGMP-dependent protein kinase (cG kinase) was examined using two methods of membrane filtration which avoided loss of bound [3H]cGMP. The enzyme bound 1.6-2.0 mol of [3H]cGMP/mol of monomer. If the kinase was saturated with [3H]cGMP and then excess unlabeled cGMP was added, [3H]cGMP dissociated from the enzyme as two approximately equal components (Sites 1 and 2). When 8-bromo-cGMP or cIMP was added to the [3H]cGMP-binding reaction at a concentration sufficient to competitively inhibit binding by greater than 50%, the relative amount of the slower or faster component, respectively, of [3H]cGMP dissociation decreased during the cGMP chase. The data indicated that the cG kinase, like its cAMP-dependent protein kinase homologue, possesses two highly conserved intrachain cyclic nucleotide-binding sites which have different dissociation rates and analog specificity. The Ka of the kinase for cGMP was about 20-fold lower using histone instead of heptapeptide as substrate. Aging of the enzyme caused conversion to a higher Ka form of the kinase and an apparent increase in the Site 1 cGMP dissociation rate. Using fresh enzyme and heptapeptide as substrate, Site 1 occupation occurred at lower concentrations of cGMP than did Site 2 occupation, and was associated with an increase in protein kinase activity. However, kinase activity appeared to correlate better with total cGMP binding than with binding to either of the two sites, and the activation by cGMP exhibited positive cooperativity (n = 1.57). It is suggested that both intrachain sites are involved in protein kinase activation. E2 + 4 cGMP in equilibrium E2 . cGMP4 The cG kinase could be photoaffinity-labeled using 8-azido-[32P]cAMP. When the labeled cG kinase was trypsin-treated followed by sodium dodecyl sulfate-slab gel electrophoresis, a single major peptide of approximate Mr = 12,000 was resolved.     

Characterization of cyclic GMP-binding sites of cyclic GMP-dependent protein kinase by rapid filtration assay.

The kinetics of cyclic [3H]GMP binding to the purified cyclic GMP-dependent protein kinase (cG kinase) were studied by using the rapid filtration assay method with polyethyleneimine-treated glass filters (method A), and the data were compared with those of the (NH4)2SO4 precipitation procedure (method B), which has been used for many previous studies on cyclic GMP binding to cG kinase. Each method gave a similar stoichiometry of approx. 2 mol of cyclic GMP/mol of cG kinase subunit; however, other binding kinetics obtained with these two methods were different. The dissociation of bound cyclic [3H]GMP from the kinase showed a single slow component when method A was used, whereas rapid and slow dissociation components were observed with method B. The Scatchard plot of cyclic [3H]GMP binding with method A was linear with a Kd value of 11 +/- 2 nM, suggesting that the two intrachain binding sites have similar high affinity for cyclic GMP. Results obtained on cyclic nucleotide analogue specificity of the two intrachain cyclic GMP-binding sites were also different between these two methods. These findings suggest that cG kinase has two high-affinity cyclic GMP-binding sites per subunit in the native state, and that when (NH4)2SO4 is added, ostensibly to stop the binding reaction, one low-affinity site is created from one high-affinity site.     

Demonstration of two exchangeable non-catalytic and two cooperative catalytic sites in isolated bovine heart mitochondrial F1, using the photoaffinity labels [2-3H]8-azido-ATP and [2-3H]8-azido-ADP

The photoreactive nucleotides [2-3H]8-azido-ATP and [2-3H]8-azido-ADP could be used to label the nucleotide binding sites on isolated mitochondrial F1-ATPase to a maximum of 4 mol of nucleotide per mol F1, also when the F1 was depleted of tightly bound nucleotides. At a photolabel concentration of 300-1000 microM, label was found on both alpha and beta subunits in a typically 1:3 ratio, independent of the total amount bound. Under these conditions the covalent binding of two nucleotides is needed for full inactivation (Wagenvoord, R.J., Van der Kraan, I. and Kemp, A. (1977) Biochim. Biophys. Acta 460, 17-24). At lower concentrations of [2-3H]8-azido-ATP (20 microM), it was found that covalent binding of only 1 mol of nucleotide per mole F1 was required for complete inactivation to take place indicating catalytic site cooperativity in the mechanism of ATP hydrolysis. Under those conditions, radioactivity was only found on the beta subunits, which would indicate that the catalytic site is located on a beta subunit and that a second site is located on the alpha/beta interface. It is found that four out of the six nucleotide binding sites are exchangeable and can be labelled with 8-azido-AT(D)P, i.e., two catalytic sites and two non-catalytic sites.     

Activation of type I cyclic AMP-dependent protein kinases with defective cyclic AMP-binding sites

Two S49 mouse lymphoma cell variants hemizygous for expression of mutant regulatory (R) subunits of type I cyclic AMP-dependent protein kinase were used to investigate functional consequences of lesions in the putative cAMP-binding sites of R subunit. Kinase activation properties of wild-type and mutant enzymes were compared using cAMP and six site-selective analogs of cAMP. Kinases from both mutant sublines were relatively resistant to cyclic nucleotide-dependent activation, but they were fully activable by at least some effectors. Relative resistances of the mutant kinases varied from about 5-fold for analogs selective for their nonmutated sites to as much as 700-fold for analogs selective for their mutated sites; resistance to cAMP was intermediate. Apparent affinities of wild-type and mutant R subunits for [3H]cAMP were not appreciably different, but competition experiments with site-selective analogs of cAMP suggested that binding of cAMP to mutant R subunits was primarily to their nonmutated sites. Analyses of cooperativity in cyclic nucleotide-dependent activation of mutant kinases, synergism between site I- and site II-selective analogs in activating the mutant enzymes, and dissociation of bound cAMP from mutant R subunits provided additional evidence that the mutations in these strains selectively inactivated single classes of cAMP-binding sites: phenomena attributable in wild-type enzyme to intrachain interactions between sites I and II were always absent or severely diminished in experiments with the mutant enzymes. These results confirm that R subunit sequences implicated in cAMP binding by homology with other cyclic nucleotide-binding proteins actually correspond to functional cAMP-binding sites. Furthermore, occupation of either cAMP-binding site I or II is apparently sufficient for activation of cAMP-dependent protein kinase. The presence of four functional cAMP-binding sites in wild-type kinase enhances the cooperativity and sensitivity of cAMP-mediated activation.     

Characterization of small cAMP-binding fragments of cAMP-dependent protein kinases.

Monomeric cAMP-binding fragments of molecular mass 16,000 and 14,000 daltons were obtained by Sephadex G-75 chromatography of partially trypsin-hydrolyzed regulatory subunits of cAMP-dependent protein kinase isozymes I and II, respectively. The Stokes radii were 19.1 and 16.4 A, the frictional ratios were 1.15 and 1.03, and the sedimentation coefficients were 1.94 and 1.91 S for the 16,000- and 14,000-dalton fragments, respectively. The 16,000-dalton fragment retained specific cyclic nucleotide binding characteristics of the native protein. The specificity of cyclic nucleotide binding to the 14,000-dalton fragment (cAMP greater than cIMP = 8-bromo-cAMP = 8-oxo-cAMP greater than cUMP = cGMP) differed from that of the native subunit (cAMP = 8-oxo-cAMP greater than 8-bromo-cAMP greater than cIMP greater than cUMP = cGMP). The 14,000-dalton fragment bound nearly 1 mol of cAMP/mol of fragment. The binding exchange rate of cAMP was much faster for the 14,000-dalton fragment than for either of the native regulatory subunits or for the 16,000 dalton fragment. Although hemin inhibited cAMP binding to the native regulatory subunits and to the 16,000 dalton fragment, the molecule did not affect cAMP binding to the 14,000-dalton fragment. Both of the native regulatory subunits and the isolated 16,000- and 14,000-dalton fragments could be covalently labeled with the photoaffinity analog, 8-N3-[32P]cAMP. The 14,000-dalton fragment could not be phosphorylated and neither fragment could recombine with the catalytic subunit to inhibit its activity. The results indicate that the functional entities of the regulatory subunit other than cAMP binding are destroyed by trypsin. The properties of the 16,000-dalton fragment suggest that the intact cAMP-binding site is contained in a small trypsin-resistant "core" of the native regulatory subunit. The properties of the 14,000-dalton fragment imply that part of the binding site of the native regulatory subunit was slighlty modified or lost during preparation of this fragment.     

Cyclic 3',5'-adenosine monophosphate-dependent kinase and phosphoproteins in human amnion

3',5'-Cyclic adenosine monophosphate (cAMP) modulates prostaglandin production in human amnion membranes. The major effects of cAMP are presumably mediated through the phosphorylation of specific regulatory phosphoproteins following cAMP activation of cAMP-dependent protein kinase. Cyclic AMP-dependent protein kinase and phosphoproteins have not previously been characterized in human amnion. Total homogenates, cytosol, and membrane fractions from human amnion were examined for [3H]cAMP binding activity and cAMP-dependent kinase activity. cAMP-dependent kinase activity was barely detectable in crude amnion fractions. Cytosol was therefore partially purified by DEAE column chromatography for further examination. Two peaks of coincident [3H]cAMP binding and cAMP-dependent kinase activity were demonstrated at 70 and 140 mM NaCl, characteristic of the Type I and Type II cAMP-dependent protein kinase isozymes. [3H]cAMP binding to the material from both peak fractions was saturable and reversible. Scatchard analysis of [3H]cAMP binding to the peak fractions was linear for peak I and curvilinear for peak II. Assuming a one-site model, [3H]cAMP binding to the Type I isozyme showed a KD = 4.17 x 10(-8) M and Bmax = 73 pmole/mg protein; using a two-site model, [3H]cAMP binding to the high-affinity site for the Type II isozyme had a KD = 3.94 x 10(-8) M and Bmax = 6.3 pmole/mg protein. Other cyclic nucleotides competed for these [3H]cAMP binding sites with a potency order of cAMP much greater than cGMP greater than (BU)2cAMP.cAMP caused a dose-dependent increase in cAMP-dependent kinase activity in the peak fractions; half-maximal activation was observed with 5.0 x 10(-8) M cAMP. The ability of cAMP to increase phosphorylation of endogenous proteins in both crude amnion cytosol and cytosol from cultures of amnion epithelial cells was assessed using [32P]ATP, SDS-polyacrylamide gel electrophoresis and autoradiography. cAMP stimulated 32P incorporation into three proteins having Mr = 80,000, 54,000, and 43,000 (P less than .01). Half-maximal 32P incorporation into these proteins occurred at 1.0 x 10(-7) M cAMP. cAMP-dependent kinase is present in human amnion; specific cAMP-enhanced phosphoproteins are also present. Hormones elevating cAMP levels in amnion may exert their effects by activating cAMP-dependent kinase and phosphorylating these phosphoproteins.     

Identification of a ternary complex between cAMP and a trimeric form of cAMP-dependent protein kinase

One of the intermediates involved in dissociation and reassociation of the subunits of the type II cAMP-dependent protein kinase has been characterized. This intermediate can be generated when the protein kinase is prepared from the isolated catalytic subunit (C) and the isolated regulatory subunit-[3H]cAMP complex (R2-[3H]cAMP4) by dialysis for 18 h followed by gel filtration. The intermediate, which could be separated from the holoenzyme and the isolated subunits by polyacrylamide gel electrophoresis, had an apparent molecular weight of 149,000, consistent with an R2C form. Following electrophoresis, measurements of R and bound nucleotide indicated that R2C was half-saturated with [3H]cAMP. The bound [3H]cAMP exhibited biphasic dissociation kinetics indicating that both types of cAMP binding sites were occupied. These findings suggested that the intermediate is R2C-cAMP2. This intermediate was not seen when the dialysis time was increased to 5 days, but could be observed when cAMP was added to the holoenzyme or when holoenzyme was mixed with R2cAMP4 and cAMP. The presence of two occupied cAMP binding sites on this intermediate suggests that there is minimal cooperativity between the two members of the regulatory subunit dimer, i.e. one member of the dimer binds 2 molecules of cAMP while the other binds C.     

Purification and partial characterization of membrane-associated type II (cGMP-activatable) cyclic nucleotide phosphodiesterase from rabbit brain

Membrane-associated, Type II (cGMP-activatable) cyclic nucleotide phosphodiesterase (PDE) from rabbit brain, representing 75% of the total homogenate Type II PDE activity, was purified to apparent homogeneity. The enzyme was released from 13,000 x g particulate fractions by limited proteolysis with trypsin and fractionated using DE-52 anion-exchange, cGMP-Sepharose affinity and hydroxylapatite chromatographies. The enzyme showed 105 kDa subunits by SDS-PAGE and had a Stokes radius of 62.70 A as determined by gel filtration chromatography. Hydrolysis of cAMP or cGMP showed positive cooperativity, with cAMP kinetic behavior linearized in the presence of 2 microM cGMP. Substrate concentrations required for half maximum velocity were 28 microM for cAMP and 16 microM for cGMP. Maximum velocities were approx. 160 mumol/min per mg for both nucleotides. The apparent Kact for cGMP stimulation of cAMP hydrolysis at 5 microM substrate was 0.35 microM and maximal stimulation (3-5-fold) was achieved with 2 microM cGMP. Cyclic nucleotide hydrolysis was not enhanced by calcium/calmodulin. The purified enzyme can be labeled by cAMP-dependent protein kinase as demonstrated by the incorporation of 32P from [gamma-32P]ATP into the 105 kDa enzyme subunit. Initial experiments showed that phosphorylation of the enzyme did not significantly alter enzyme activity measured at 5 microM [3H]cAMP in the absence or presence of 2 microM cGMP or at 40 microM [3H]cGMP. Monoclonal antibodies produced against Type II PDE immunoprecipitate enzyme activity, 105 kDa protein and 32P-labeled enzyme. The 105 kDa protein was also photoaffinity labeled with [32P]cGMP. The purified Type II PDE described here is physicochemically very similar to the isozyme purified from the cytosolic fraction of several bovine tissues with the exception that it is predominantly a particulate enzyme. This difference may reflect an important regulatory mechanism governing the metabolism of cyclic nucleotides in the central nervous system.     

Activation of protein kinase isoenzymes under near physiological conditions. Evidence that both types (A and B) of cAMP binding sites are involved in the activation of protein kinase by cAMP and 8-N3-cAMP

cAMP-dependent protein kinase I and II (cAKI and cAKII) were incubated under near physiological conditions in the presence of various concentrations of 8-N3-c[3H]AMP or c[3H]AMP. Both types (A and B) of cyclic nucleotide binding sites of cAKI or cAKII were occupied to a similar extent and the degree of their occupation correlated with the degree of kinase activation. cAKI and cAKII bound cAMP in an apparent positively cooperative manner in the presence of Mg2+, ATP. 8-N3-c[3H]AMP dissociated several orders of magnitude faster from site A than site B of the regulatory moiety of cAKII, and was photo-incorporated only when bound to site B.     

Two classes of cAMP analogs which are selective for the two different cAMP-binding sites of type II protein kinase demonstrate synergism when added together to intact adipocytes

Twenty-five cyclic nucleotide analogs were tested individually to act as lipolytic agents and to activate adipocyte protein kinase. The lipolytic potency of individual analogs correlated better with their Ka for protein kinase and their lipophilicity rather than with either parameter alone. Some of the most potent lipolytic analogs had I50 values for the particulate low Km cAMP phosphodiesterase suggesting that their effect was not due to raising endogenous cAMP levels through inhibition of phosphodiesterase. The most potent lipolytic analogs contained a thio moiety at the C-8 or C-6 position. These analogs exhibited concave upward dose-response curves. At high concentrations, some analogs were as effective as optimal concentrations of epinephrine in stimulating glycerol release. The regulatory subunit of protein kinase has two different intrachain cAMP-binding sites and cAMP analogs modified at the C-8 position (C-8 analogs) are generally selective for Site 1 and analogs modified at the C-6 position (C-6 analogs) are generally selective for Site 2 (Rannels, S. R., and Corbin, J. D. (1980) J. Biol. Chem. 255, 7085-7088). Thus, C-8 and C-6 analogs were tested in combination to stimulate lipolysis in intact adipocytes and to activate protein kinase in vitro. Each process was stimulated synergistically by a combination of a C-6 and C-8 analog. Two C-8 analogs or two C-6 analogs added together did not cause synergism of either process. For both lipolysis and protein kinase activation, C-8 thio analogs acted more synergistically than C-8 amino analogs when incubated in combination with C-6 analogs, a characteristic of type II protein kinase. It is concluded that the observed synergism of lipolysis is due to binding of cAMP analogs to both intrachain sites and that it is the type II protein kinase isozyme which is responsible for the lipolytic response.     

A cAMP receptor from mouse liver cytosol whose binding capacity is enhanced by Mg++-ATP.

A receptor with a dissociation constant of 2·10^?6M for cyclic 3′,5′-AMP (cAMP) has been found in mouse liver cytosol. This cAMP binding activity can be differentiated from the cAMP-dependent protein kinase holoenzymes and the free regulatory subunits also found in the cytosol. Mg⁺⁺-ATP increases the number of binding sites for cAMP several fold. This increased capacity for cAMP binding persists after Sephadex G-25 filtration, and incubation for 14 hours in the presence of 5 mM EDTA. Among several adenosine- and guanosine-derivatives tested, only AMP, ADP and ATP compete efficiently with [³H] cAMP for the cAMP binding site.     

Characterization of the interchain and intrachain interactions between the binding sites of the free regulatory moiety of protein kinase I

The interaction between the four binding sites (two A sites and two B sites) of the regulatory subunit dimer of protein kinase I (RI2) was studied. The rate of association of c[3H]AMP to site B was slower when site A had already been occupied. Occupation of site A also retarded the rate of dissociation of c[3H]AMP from site B. This site A-B interaction was intrachain since it was observed also for a monomeric fragment of RI2. Thus, each monomer of RI2 must have one A site and one B site. Quantitative analysis of the rate constants for cAMP binding to variously liganded RI2 suggested little or no thermodynamic coupling between site A and B. This conclusion was supported by equilibrium binding data. Occupation of one A site retarded the dissociation of c[3H]AMP from the A site of the other subunit (interchain interaction). The rate kinetic constants as well as equilibrium binding data indicated a positively cooperative site A-A interaction. The interaction between cAMP and either site was enthalphy-driven (25 degrees C), the process being accompanied by a loss of entropy. The thermodynamic parameters did not support the occurrence of an abrupt conformational change at a certain level of ligandation of RI2. Half-maximal saturation of either site occurred at 1-2 nM cAMP (37 degrees C, pH 7.0, 0.15 M KCl). The concentration of RI2 did not detectably influence any binding parameters. Aging of RI2 produced a form with minimally, if at all, altered Mr, but which showed a more rapid release of c[3H]AMP bound to site B.     

Binding of 5,5'-bis[8-(phenylamino)-1-naphthalenesulfonate] by the regulatory subunits of adenosine cyclic 3',5'-phosphate dependent protein kinase

Binding to the regulatory subunits of types I and II adenosine cyclic 3',5'-phosphate (cAMP) dependent protein kinase (RI and RII, respectively) produces large distinctive increases in fluorescence and optical activity of 5,5'-bis[8-(phenylamino)-1-naphthalenesulfonate] [bis(ANS)]. Both specific and nonspecific interactions are involved. Association of the regulatory subunits with either the catalytic subunit or cAMP results in dissociation of a major portion of the bound bis(ANS) as detected by changes in fluorescence and circular dichroism. The results are consistent with the accepted cAMP binding properties of RI and RII, showing cooperativity in case of RI and two heterologous binding sites for RII. cGMP has the same overall effect on bis(ANS) binding as cAMP. However, very high concentrations are required for complete dissociation of bis(ANS) from RII, consistent with the observation that cGMP is inefficient in bringing about the dissociation of the type II holoenzyme. Magnesium binding to sites having dissociation constants of ca. 12 mM increases the interaction of bis(ANS) with both of the isolated regulatory subunits. Experiments involving the 37 000-dalton fragment of RII indicate that the limited proteolytic cleavage was heterogeneous, with only 24-39% of the resulting population interacting strongly with the catalytic subunit.     

Use of nucleotide photoaffinity probes to study hormone action

It has been clearly shown that the action of several hormones is differentially mediated intracellularly by nucleotides containing either adenosine or guanosine base units. To study the protein-nucleotide interactions involved in several complex biological systems our laboratory has synthesized several 8-azido-adenosine (8-N3 A) and 8-azidoguanosine (8-N3 G) derivatives of naturally occurring nucleotides. Modification of the nucleotides in the 8-position of the purine ring was done because: a) 8-substituted derivatives of cAMP and cGMP activated their respective protein kinases at physiological concentrations and were much less susceptible to hydrolysis by specific phosphodiesterases (PDE's) and b) substitution at the 8-position was much less likely to disturb the preferential and selective binding of adenosine versus guanosine nucleotides by enzymes that are specifically regulated by such interactions. This would allow studies of guanosine nucleotide specific binding in the presence of both adenosine nucleotides and adenosine nucleotide binding proteins, and vice-versa. In general, such has been the case and [32P] 8-N3 cAMP and [32P] 8-N3 cGMP have been used effectively to study their respectively activated protein kinases in several systems. Also, [32P] 8-N3 ATP has been used to study several ATPases and kinases while [gamma 32P] 8-N3 GTP has been shown effective for studies on tubulin and the G-regulatory protein (G/N) of adenylyl cyclase (A.C.). Several observations suggest that there must be important physical and energetic tie-ins between external hormone binding and the loading and unloading of specific internal nucleotide binding sites. These binding sites may be activator signals for protein kinases (e.g., cAMP protein kinase regulatory subunit), or cyclases (e.g., G/N proteins of A.C.) or catalytic sites involved in the production or hydrolysis of cyclic nucleotides. The thrust of this article is to detail the use of 8-azidopurine photoaffinity analogs of ATP, GTP, cAMP and cGMP as they may be used to study hormone-mediated events which may or may not involve cyclic nucleotides as a second messenger.     

Changing pattern of cyclic AMP-binding proteins during germination of Mucor racemosus sporangiospores.

Interation of cyclic AMP with a profoundly changing pattern of specific binding proteins was shown during aerobic germination of sporangiospores from the fungus Mucor racemosus. 32P-labeled 8-azido-cycli AMP, an analogue of cyclic AMP that forms a covalent linkage with the binding proteins under u.v. light, was used as the ligand. Binding proteins carrying this photoaffinity label were separated by polyacrylamide-gel electrophoresis and identified by radioautography. Equibiltrium dissociation constants (Kd) and binding-response curves in the presence of competing nucleotides were identical for both 8-azido-cyclic [32P]AMP and cyclic [3H]AMP. A quantitative binding assay with both 8-azido-cyclic [32P]AMP and cyclic [3H]AMP over the time course of sporangiospore germination indicated a parallel relationship between cyclic AMP-binding capacity and the intracellular concentrations of cyclic AMP reported in a previous study [Paznokas & Sypherd (1975) J. Bacteriol. 124, 134--139]. Both of these parameters attained transient high values at a time of development when addition of exogenous cyclic AMP prevents hyphal-germ-tube emergence. The measured Kd values did not change during sport germination.     

Studies of functional domains of the regulatory subunit from cAMP-dependent protein kinase isozyme I

Homogenous regulatory subunit from rabbit skeletal muscle cAMP-dependent protein kinase (isozyme I) was partially hydrolyzed with low (1 g/1300 g) or high (1 g/6 g) concentrations of trypsin. After treatment with low trypsin two main peptides (Mr = 35,000 and 12,000) were produced. The cAMP-binding activity (2 mol cAMP/mol of subunit monomer) was recovered in the monomeric Mr = 35,000 peptide. The ability of either fragment to inhibit catalytic subunit activity was lost. Treatment of the regulatory subunit with a high concentration of trypsin yielded three main fragments (Mr = 32,000, 16,000, and 6,000) which could be resolved by Sephadex G-75 and purified further on DEAE-cellulose columns. One of the peptides (Mr = 32,000) bound 2 mol cAMP/mol fragment. The Mr = 16,000 fragment was very labile and bound cAMP with an undetermined stoichiometry. Cyclic AMP dissociation curves for the native regulatory subunit and its Mr = 32,000 component were similar and suggested the presence of two nonidentical binding sites in each monomer. Using the same procedure, the Mr = 16,000 fragment or homogenous cGMP-dependent protein kinase appeared to contain a single type of binding site. Purified Mr = 32,000 fragment was readily converted to the Mr = 16,000 fragment using high trypsin as assessed by protein bands on SDS-disc gels or by following transfer of radioactivity from Mr = 32,000 peptide covalently labeled with 8-N3-[32P] cAMP to radiolabeled Mr = 16,000 fragment. The smallest regulatory subunit fragment (Mr = 6,000) did not bind cAMP, but was dimeric and could be part of the dimerization domain in the native protein. A model is presented to explain the possible structural-functional relationships of the regulatory subunit.     

Expression and characterization of mutant forms of the type I regulatory subunit of cAMP-dependent protein kinase. The effect of defective cAMP binding on holoenzyme activation

The mouse wild type and four mutant regulatory type I (RI) subunits were expressed in Escherichia coli and subjected to kinetic analyses. The defective RI subunits had point mutations in either cAMP-binding site A (G200/E), site B (G324/D, R332/H), or in both binding sites. In addition, a truncated form of RI which lacked the entire cAMP-binding site B was generated. All of the mutant RI subunits which bound [3H]cAMP demonstrated more rapid rates of cAMP dissociation compared to the wild type RI subunit. Dissociation profiles showed only a single dissociation component, suggesting that a single nonmutated binding site was functional. The mutant RI subunits associated with purified native catalytic subunit to form chromatographically separable holoenzyme complexes in which catalytic activity was suppressed. Each of these holoenzymes could be activated but showed varying degrees of cAMP responsiveness with apparent Ka values ranging from 40 nM to greater than 5 microM. The extent to which the mutated cAMP-binding sites were defective was also shown by the resistance of the respective holoenzymes to activation by cAMP analogs selective for the mutated binding sites. Kinetic results support the conclusions that 1) Gly-200 of cAMP-binding site A and Gly-324 or Arg-332 of site B are essential to normal conformation and function, 2) activation of type I cAMP-dependent protein kinase requires that only one of the cAMP-binding sites be functional, 3) mutational inactivation of site B (slow exchange) has a much more drastic effect than that of site A on increasing the Ka of the holoenzyme for cAMP, as well as in altering the rate of cAMP dissociation from the remaining site of the free RI subunit. The strong dependence of one cAMP-binding site on the integrity of the other site suggests a tight association between the two sites.     

Probing the cyclic nucleotide binding sites of cAMP-dependent protein kinases I and II with analogs of adenosine 3',5'-cyclic phosphorothioates

A set of cAMP analogs were synthesized that combined exocyclic sulfur substitutions in the equatorial (Rp) or the axial (Sp) position of the cyclophosphate ring with modifications in the adenine base of cAMP. The potency of these compounds to inhibit the binding of [3H]cAMP to sites A and B from type I (rabbit skeletal muscle) and type II (bovine myocardium) cAMP-dependent protein kinase was determined quantitatively. On the average, the Sp isomers had a 5-fold lower affinity for site A and a 30-fold lower affinity for site B of isozyme I than their cyclophosphate homolog. The mean reduction in affinities for the equivalent sites of isozyme II were 20- and 4-fold, respectively. The Rp isomers showed a decrease in affinity of approximately 400-fold and 200-fold for site A and B, respectively, of isozyme I, against 200-fold and 45-fold for site A and B of isozyme II. The Sp substitutions therefore increased the relative preference for site A of isozyme I and site B of isozyme II. The Rp substitution, on the other hand, increased the relative preference for site B of both isozymes. These data show that the Rp and Sp substitutions are tolerated differently by the two intrachain sites of isozymes I and II. They also support the hypothesis that it is the axial, and not the previously proposed equatorial oxygen that contributes the negative charge for the ionic interaction with an invariant arginine in all four binding sites. In addition, they demonstrate that combined modifications in the adenine ring and the cyclic phosphate ring of cAMP can enhance the ability to discriminate between site A and B of one isozyme as well as to discriminate between isozyme I and II. Since Rp analogs of cAMP are known to inhibit activation of cAMP-dependent protein kinases, the findings of the present study have implications for the synthesis of analogs having a very high selectivity for isozyme I or II.