Craig W. Davis

Assessment of selective inhibition of rat cerebral cortical calcium-independent and calcium-dependent phosphodiesterases in crude extracts using deoxycyclic AMP and potassium ions

The effects of various inhibitors on the activity of calcium-independent and calcium-dependent phosphodiesterases from rat cerebral cortex were examined. While the agents varied greatly in their relative potency, each was found to be approximately equipotent in inhibiting the calcium-dependent hydrolysis of either cyclic AMP or cyclic GMP. In contrast, the inhibitors displayed a marked substrate specificity for the calcium-independent enzyme with ratios of IC50 values for inhibition of cyclic GMP hydrolysis when compared to cyclic AMP hydrolysis in decreasing order being: ZK 62711 (much greater than 100) greater than Ro 20-1724 (much greater than 25) papaverine (13) greater than 7-benzyl IBMX (4) greater than quercetin and kaempferol (2). The differential selectivity of the inhibitors for the two enzymes was most pronounced for ZK 62711 and Ro 20-1724 which were at least 25-100-times more potent in inhibiting the calcium-independent hydrolysis of cyclic AMP when compared to the calcium-dependent hydrolysis of cyclic AMP. In contrast, 7-benzyl IBMX, kaempferol and quercetin were 8-100-times more effective as inhibitors of cyclic GMP hydrolysis by the calcium-dependent phosphodiesterase while 7-benzyl IBMX and trimazosin displayed a similar enzyme selectivity using cyclic AMP as substrate. With the exception of papaverine, all agents were competitive inhibitors of the calcium-dependent phosphodiesterase. The type of inhibition observed with the calcium-independent enzyme was dependent on the substrate employed. The specificity of potassium ions in inhibiting the activity of the calcium-dependent phosphodiesterase and deoxycyclic AMP in inhibiting the calcium-independent enzyme was found to provide a convenient means to assess the effects of agents on these activities in crude extracts of cerebral cortex.

Effects of Aerosolized Synthetic Surfactant, Atovaquone, and the Combination of These on Murine Pneumocystis carinii Pneumonia

An immunosuppressed rat model was used to determine the pharmacokinetics of aerosolized atovaquone (administered with and without a synthetic surfactant) and to evaluate the efficacy of inhaled atovaquone in the prevention and treatment of Pneumocystis carinii pneumonia (PCP). After a single dose by aerosol, mean peak concentrations of atovaquone averaged 52 microg/mL in plasma and 31 microg/g in lungs of rats infected with P. carinii. When atovaquone was combined with surfactant, mean peak concentrations of 94 microg/mL in plasma and 51 microg/g in lung were achieved. Aerosolized synthetic surfactant alone significantly increased survival of rats with PCP and, when combined with atovaquone, increased plasma and lung concentrations of the drug and eradication of the organism.

1-(4-Aminophenyl)isoquinoline derivatives: Potent inhibitors of calcium-independent and calcium-dependent phosphodiesterases from rat cerebral cortex

The effects of a series of 1-(4-aminophenyl)isoquinoline derivatives on the activity of calcium-independent and calcium-dependent phosphodiesterases purified from rat cerebral cortex were examined. Agents were approximately equipotent (IC50 values, 0.2 to 25 microM) in inhibiting the calcium-dependent hydrolysis of either cyclic AMP or cyclic GMP, while they were 6-35 times more effective as inhibitors of cyclic AMP hydrolysis when compared to cyclic GMP hydrolysis using the calcium-independent enzyme. The diastereomers of 3-(carbomethoxy)propenamido demonstrated a marked difference in specificity. The cis-isomer was very potent in inhibiting cyclic AMP or cyclic GMP hydrolysis by either enzyme (IC50 values, 0.2 to 8 microM) while the trans-isomer was only effective in inhibiting calcium-independent cyclic AMP hydrolysis (IC50 values, 2.5 microM). Kinetic analyses of the type of inhibition of the calcium-dependent enzyme revealed that the various agents were competitive inhibitors of cyclic GMP hydrolysis and noncompetitive inhibitors of cyclic AMP hydrolysis. A reverse pattern of inhibition by the isoquinoline derivatives was found using the calcium-independent phosphodiesterase, i.e. noncompetitive inhibition of cyclic GMP while competitive inhibition of cyclic AMP. Inhibition of phosphodiesterases by these agents was also manifest using intact brain slices prepared from rat cerebral cortex. Thus, the agents were found to potentiate forskolin-elicited accumulations of cyclic AMP by 100-700% and increased the half-time for the decline in cyclic AMP following forskolin stimulation from 3 to 6 min.

Regulation of adenosine 3′:5′-monophosphate-dependent protein kinase in cerebral cortex

Alterations in the cyclic AMP-dependent protein kinase activity ratio in response to putative neurotransmitters and other cyclic AMP-elevating agents in intact cerebral cortical slices and Krebs-Ringer particulate preparations from cerebral cortex were examined. Both norepinephrine (30 microM) and forskolin (20 microM) produced a time-dependent increase in intracellular levels of cyclic AMP in cerebral cortical slices which was paralleled by an increase in both cyclic AMP and the protein kinase activity ratio. The increases were maximal at 5 min. and remained elevated for at least 15 min. Forskolin, norepinephrine, adenosine and isoproterenol produced a concentration-dependent increase in both cyclic AMP and the protein kinase activity ratio, however, the degree of increase observed was dissimilar. Thus, a 5-fold change in intracellular cyclic AMP resulted in only a 2-fold increase in the activity ratio. Of the agents examined, forskolin produced the most marked change in the activity ratio (from 0.23 to 0.78 at 100 microM) while isoproterenol at 100 microM produced only a 50% increase in the activity ratio. The half-time for the decline in forskolin elicited elevations of either the activity ratio or cyclic AMP was about 4-6 min. In the presence of the phosphodiesterase inhibitor, Ro 20-1724, both were significantly prolonged being 60-70% of the maximum observed immediately after forskolin stimulation, at 15 min. Potentiation of forskolin elicited increases in the activity ratio by Ro 20-1724 were also observed but the increase in the activity ratio was maximal at 7.5 min. while cyclic AMP accumulations continued to rise during the entire 15 min. incubation. Particulate preparations from cerebral cortex were found to contain a cyclic AMP-dependent protein kinase which could be activated 2 to 3-fold with either forskolin, norepinephrine, or adenosine. Unlike the intact brain slice the changes in protein kinase activity ratio and intracellular levels of cyclic AMP in cell-free particulate preparations were similar in both time and degree.

Selective alteration of Ca+ -dependent and Ca2+ -independent cyclic nucleotide phosphodiesterase activity in rat cerebral cortex by cyclic nucleotides and their analogs

Abstract The effects of various cyclic nucleotides and cyclic nucleotide analogs on the activity of Ca2+ -independent and Ca2+ -dependent phosphodiesterases purified from rat cerebral cortex were examined. The order of potency for inhibition of the Ca2+ -dependent enzyme by the various agents was the same using either cAMP or cGMP as substrate with 2′-O-monobutyryl cGMP, clMP and 2-deoxy cGMP being the most potent. The inhibition by deoxy cGMP using cAMP or cGMP as substrate was competitive, with Ki values of 11 and 13 μM, respectively. In marked contrast, hydrolysis of cAMP or cGMP by the Ca2+ -independent enzyme was stimulated 50–75% by cIMP, deoxy cGMP and N 2-monobutyryl cGMP with EC50 values of 7, 20 and 30 μM, respectively, cGMP (EC50, 1.5 μ M) produced quantitatively the same degree of stimulation of cAMP hydrolysis by the Ca2+ -independent phosphodiesterase and the activation was not additive with that of deoxy cGMP. Of the other derivatives examined, 2′-O-monobutyryl cAMP and 2′-deoxy cAMP were the most potent inhibitors of cAMP hydrolysis by tbe Ca2+ -independent enzyme and were 30–60-times more effective in inhibiting cAMP hydrolysis as compared to cGMP hydrolysis. The specificity of K+ in inhibiting the activity of the Ca2+ -dependent phosphodiesterase and deoxy cAMP in inhibiting the Ca2+ -independent enzyme may provide convenient means to examine specifically these activities in crude extracts from rat cerebral cortex.