Adenylate cyclase reaction catalyzed

Hayaishi and colleagues, who devised the purification for the Brevibacter-ium liquefaciens enzyme, used it to characterize the reversibility of the adenylate cyclase reaction (Kurashina et ai, 1974) and found that the equilibrium constant for the reaction written in the direction of cyclic AMP formation is 0.12 Mat pH 7.3 at this pH the rates of the forward and reverse reactions are comparable but about the rate of the forward reaction measured at its pH optimum, pH 9. Our plan for determining the stereochemical course of the reaction is shown in Fig. 14. Since we had synthesized the diastereomers of cyclic [, 0]dAMP, we would use the cyclase to catalyze their pyrophosphorolysis and form the diastereomers of [a- 0, 0]dATP. However, the thermodynamics of the cyclase reaction prevents an efficient conversion of cyclic dAMP to dATP, so this reaction was coupled to the glycerol kinase reaction the kinase reaction utilizes the thermodynamic instability of the )J,y-anhydride bond to displace the overall equilibrium to favor the synthesis of the diastereomers of [a- 0, 0]dADP. Both the cyclase and glycerol kinase can utilize deoxyadenosine nucleotides as substrates, but only the cyclase reaction can alter the configuration of the chiral phosphorus atoms. 

The effect of receptor stimulation is thus to catalyze a reaction cycle. This leads to considerable amplification of the initial signal. For example, in the process of visual excitation, the photoisomerization of one rhodopsin molecule leads to the activation of approximately 500 to 1000 transdudn (Gt) molecules, each of which in turn catalyzes the hydrolysis of many hundreds of cyclic guanosine monophosphate (cGMP) molecules by phosphodiesterase. Amplification in the adenylate cyclase cascade is less but still substantial each ligand-bound P-adrenoceptor activates approximately 10 to 20 Gs molecules, each of which in turn catalyzes the production of hundreds of cyclic adenosine monophosphate (cAMP) molecules by adenylate cyclase. 

All of the effects of the catecholamines bound to (3 adrenergic receptors and of glucagon, ACTH, and many other hormones appear to be mediated by adenylate cyclase. This integral membrane protein catalyzes the formation of cAMP from ATP (Eq. 11-8, step a). The reaction, whose mechanism is considered in Chapter 12, also produces inorganic pyrophosphate. The released cAMP acts as the second messenger and diffuses rapidly throughout the cell to activate the cAMP-dependent protein kinases and thereby to stimulate phosphorylation of a selected group of proteins (Fig. 11-4). Subsequent relaxation to a low level of cytosolic cAMP is accomplished by hydrolysis of the cAMP by a phosphodiesterase (Eq. 11-8, step fr).166/167 jn thg absence of phosphodiesterase cAMP is extremely stable kinetically. However, it is thermodynamically unstable with respect to hydrolysis. 

Cyclic-AMP is formed from ATP in a reaction catalyzed by the enzyme adenylate cyclase. Assume that adenylate cyclase acts as a base to remove a proton from the 3 -hydroxyl group of ATP and write a mechanism for the formation of cAMP. 

Adenylate cyclase is a two-component enzyme system. It ultimately catalyzes the cyclase reaction, but only when it is associated with the hormone-bound receptor and a regulatory protein called a stimulatory G-protein (guanylate nucleotide binding protein), which activates adenylate cyclase. The G-protein is the intermediate between the receptor and the synthesis of cyclic AMP. 

Cyclic AMP, or cAMP for short, is produced by he intramolecular eyclization of ATP, a reaction catalyzed by the enzyme adenylate (or adenyl) cyclase. 

Figure 7-4 Reaction catalyzed by adenylate cyclase. The activity of adenylate cyclase is decreased when glucose is present in the growth medium.

Adenylate cyclase is considered as a second messenger that catalyzes the formation of cAMP (cyclic adenosine monophosphate) from ATP this results in alterations in intracellular cAMP levels that change the activity of certain enzymes—that is, enzymes that ultimately mediate many of the changes caused by the neurotransmitter. For example, there are protein kinases in the brain whose activity is dependent upon these cyclic nucleotides the presence or absence of cAMP alters the rate at which these kinases phosphorylate other proteins (using ATP as substrate). The phosphorylated products of these protein kinases are enzymes whose activity to effect certain reactions is thereby altered. One example of a reaction that is altered is the transport of cations (e.g., Na+, K+) by the enzyme adenosine triphosphatase (ATPase). 

Figure 8 Simplified diagram of a signaling cascade that involves NE, BDNF, and CREB after NE acts on the postsynaptic fi-noradrenergic receptor. NE couples to a G protein (Gas), which stimulates the production of cAMP from adenosine triphosphate (ATP). This reaction is catalyzed by adenylate cyclase (AC). cAMP activates protein kinase A (PKA). Inside the cell, PKA phosphorylates (P) the CREB protein, which binds upstream from specific regions of genes and regulates their expression. BDNF is one target of cAMP signaling pathways in the brain. CRE, cyclic AMP regulatory element ER, endoplasmic reticulum, [reprinted from Reference 76 with permission of the author and the publisher, Canadian Medical Association].

Distant relatives. The structure of adenylate cyclase is similar to the structures of some types of DNA polymerases, suggesting that these enzymes derived from a common ancestor. Compare the reactions catalyzed by these two enzymes. In what ways are they similar ... 

In the reaction catalyzed by adenylate cyclase, the 3 -OH group nucleophilically attacks the a-phosphorus atom... 

In the reaction catalyzed by adenylate cyclase, the 3 -OH group nucleophilically attacks the a-phosphorus atom attached to the 5 -OH group, leading to displacement of pyrophosphate. The reaction catalyzed by DNA polymerase is similar except that the 3 -OH group is on a different nucleotide. 

The first application of this 0 effect for determining the configuration of an oxygen chiral phosphate ester was the author s determination of the configuration of diastereomeric samples of cyclic [, 0]dAMP, the chiral substrate for studying the stereochemical consequences of the reverse reaction catalyzed by adenylate cyclase (formation of cyclic AMP from ATP), and of the hydrolysis reaction catalyzed by 3, 5 -cyclic nucleotide phosphodiesterase (25) (see Fig. 

These comparative studies constituted the first example of an enzyme-catalyzed hydrolysis reaction whose stereochemical course was unaffected by sulfur substitution. At the time these experiments were performed, the stereochemical courses of the reactions catalyzed by glycerol kinase (83, 84) and by the bacterial adenylate cyclase (85, 86) had already been compared in the laboratories of Knowles and Gerlt, respectively, and these were also found to be unaffected by the sulfur substitution. A number of other comparisons of this type have been made, and in no case were the stereochemical consequences of the reactions studied with chiral phosphate esters and the chiral thiophosphate analogs found to differ. This agreement suggests that the necessary use of oxygen chiral thiophosphate monoesters to study the stereochemical course of phospho-monoesterases will provide pertinent results for ascertaining whether phosphory-lated intermediates are involved in the reaction mechanism. 

Other enzymes that catalyze decarboxylation and dehydration reactions require Mg2+. As will be seen, the a-adrenergic receptor, which includes the enzyme adenyl cyclase in association with ATP, utilizes Mg2+ to mediate the increased cardiac activity associated with epinephrine. It is therefore apparent that pharmaceutical products that provide these inorganic ions (i.e., mineral supplements), as well as vitamin preparations, should actually be considered drugs whether they are used therapeutically to treat clinical symptoms of deficiency, or as food supplements for the maintenance of good health. 

After being ingested, the V. cholerae organisms attach to the brash border of the intestinal epithelium and secrete an exotoxin that binds irreversibly to a specific chemical receptor (Gmi ganglioside) on the cell surface. This exotoxin catalyzes an ADP-ribosylation reaction that increases adenylate cyclase activity and thus cAMP levels in the enterocyte. As a result, the normal absorption of sodium, anions, and water from the gut lumen into the intestinal cell is markedly diminished. The exotoxin also stimulates the crypt cells to secrete chloride, accompanied by cations... 

Phosphoenolpyruvate carboxykinase is induced. Oxaloacetate produces PEP in a reaction catalyzed by PEPCK. Cytosolic PEPCK is an inducible enzyme, which means that the quantity of the enzyme in the cell increases because of increased transcription of its gene and increased translation of its mRNA. The major inducer is cyclic adenosine monophosphate (cAMP), which is increased by hormones that activate adenylate cyclase. Adenylate cyclase produces cAMP from ATP. Glucagon is the hormone that causes cAMP to rise during fasting, whereas epinephrine acts during exercise or stress. cAMP activates protein kinase A, which phosphorylates a set of specific transcription factors (CREB) that stimulate transcription of the PEPCK gene (see Chapter 16 and Pig. 16.18). Increased synthesis of mRNA for PEPCK results in increased synthesis of the enzyme. Cortisol, the major human glucocorticoid, also induces PEPCK. 

FIGURE 24.14 Epinephrine action. When epinephrine binds to its receptor, the binding activates a stimulatory G protein, which in turn activates adenylate cyclase. The cAMP thus produced activates a cAMP-dependent protein kinase. The phosphorylation reactions catalyzed by the cAMP-dependent kinase suppress the activity of glycogen synthase and enhance that of phosphorylase kinase. Glycogen phosphorylase is activated by phosphorylase kinase, leading to glycogen breakdown. 

The mono(ADP-ribosyl)ation, the transfer of the ADP-ribose moiety of NAD to a macromolecule, was discovered by Hayaishi et al. in 1968 as the mechanism of the cytotoxic effect of diphtheria toxin [1], The substrate of this toxin-catalyzed ADP-ribosylation is elongation factor-2. The same reaction is catal)Azed by Pseudomonas toxin. The second bacterial toxin involved in mono(ADP-ribosyl)ation of mammalian cell proteins is cholera toxin, the substrate of which was identified as the guanine nucleotide-binding regulatory component of membrane adenylate cyclase in 1978 [2].E. coli heat-labile enterotoxin is similar to cholera toxin in many respects. 

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