Monitoring of reversible boronic acid-diol interactions by fluorine NMR spectroscopy in aqueous media.

Recognition and sensing of various biologically relevant species using boronic acid-based chemosensors have become increasingly popular over the last few years. Herein, we describe a new convenient method for monitoring boronic acid-diol interactions in aqueous media based on (19)F NMR spectroscopy with fluorinated boronic acid probes.

Involvement of B-50 (GAP-43) phosphorylation in the modulation of transmitter release by protein kinase C.

1. Protein kinase C (PKC) is a family of enzymes that is activated by diacylglycerol (DAG) following phospholipase (PL) C activation. Protein kinase C may also be activated by metabolites and arachidonic acid generated by breakdown of membrane phospholipids by PLD and PLA2, respectively. Subsequent to PKC activation, key protein substrates are phosphorylated, resulting in the facilitation of transmitter release. 2. Phorbol esters are compounds that mimic the actions of DAG on PKC and have been shown to facilitate stimulation-induced (S-I) transmitter release in rat brain. However, some phorbol esters that have a high affinity for PKC have no effect on transmitter release, whereas others with a lower affinity for PKC markedly elevate S-I transmitter release. 3. The structure and, more importantly, the lipophilicity of the phorbol esters determines their ability to access and activate the intraneuronal pools of PKC that are involved with transmitter release. In studies in which cell membranes were intact, phorbol esters did not display the characteristics expected based on their affinities for PKC in contrast with studies in disrupted synaptosomes. This supports the hypothesis that the membrane plays a critical role in determining the effects of phorbol esters on PKC. 4. B-50, a PKC substrate thought to be involved in transmitter release, also appears to be differentially phosphorylated by various phorbol esters. The effects on B-50 phosphorylation in intact synaptosomes, but not disrupted synaptosomes, are well correlated with the effects of phorbol esters on S-I transmitter release. 5. B-50 is colocalized with actin, which has also been suggested to play an important role in facilitating the movement of reserve pools of transmitter vesicles to the readily releasable state. Therefore, it is possible that the phosphorylation status of B-50 directly influences the organization of actin filaments, thereby allowing transmitter output to be sustained under high levels of stimulation.

Differential abilities of phorbol esters in inducing protein kinase C (PKC) down-regulation in noradrenergic neurones.

1. The ability of several phorbol ester protein kinase C (PKC) activators (phorbol 12, 13-dibutyrate, PDB; phorbol 12, 13-diacetate, PDA; and 12-deoxyphorbol 13-acetate, dPA) to down-regulate PKC was studied by assessing their effects on electrical stimulation-induced (S-I) noradrenaline release from rat brain cortical slices and phosphorylation of the PKC neural substrate B-50 in rat cortical synaptosomal membranes. 2. In cortical slices which were incubated for 20 h with vehicle, acute application of PDB, PDA and dPA (0.1 - 3.0 microM) enhanced the S-I noradrenaline release in a concentration-dependent manner to between 200 - 250% of control in each case. In slices incubated with PDB (1 microM for 20 h), subsequent acute application of PDB (0.1 - 3.0 microM) failed to enhance S-I release, indicating PKC down-regulation. However, in tissues incubated with PDA or dPA (3 microM) for 20 h, there was no reduction in the facilitatory effect of their respective phorbol esters or PDB (0.1 - 3.0 microM) when acutely applied, indicating that PKC was not down-regulated. This was confirmed using Western blot analysis which showed that PDB (1 microM for 20 h) but not PDA (3 microM for 20 h) caused a significant reduction in PKCalpha. 3. Incubation with PDB for 20 h, followed by acute application of PDB (3 microM) failed to increase phosphorylation of B-50 in synaptosomal membranes, indicating down-regulation. In contrast, tissues incubated with PDA or dPA for 20 h, acute application of their respective phorbol ester (10 microM) or PDB (3 microM) induced a significant increase in B-50 phosphorylation. 4. Acutely all three phorbol esters elevate noradrenaline release to about the same extent, yet PDA and dPA have lower affinities for PKC compared to PDB, suggesting unique neural effects for these agents. This inability to cause functional down-regulation of PKC extends their unusual neural properties. Their neural potency and lack of down-regulation may be related to their decreased lipophilicity compared to other phorbol esters. 5. We suggest that PKC down-regulation appears to be related to binding affinity, where agents with high affinity, irreversibly insert PKC into artificial membrane lipid and generate Ca(2+)-independent kinase activity which degrades and deplete PKC. We suggest that this mechanism may also underlie the ability of PDB to down-regulate PKC in nerve terminals, in contrast to PDA and dPA.

No involvement of nicotinic receptors in the facilitation of acetylcholine outflow in mouse cortex in the presence of neostigmine and atropine.

The role of nicotinic and muscarinic receptors in the modulation of acetylcholine release was studied using field stimulated mouse cortex slices incubated with [(3)H]-choline. Both acetylcholine (100 microM) and the cholinesterase inhibitor neostigmine (100 microM) inhibited the stimulation-induced (S-I) outflow of radioactivity but in the presence of atropine (0.3 microM) an enhancement was seen, which may be indicative of facilitatory nicotinic receptors. Mecamylamine (100 microM) was unable to antagonize the enhancement seen in the presence of acetylcholine and atropine. The nicotinic agonist dimethylphenylpiperazinium (30 microM) did not facilitate S-I outflow of radioactivity. A range of nicotinic blockers had no effect on the enhancement seen in the presence of neostigmine and atropine, nor did indomethacin, the 5HT(3) antagonist MDL 7222 nor the NMDA antagonist MK-801. The inability to block this effect suggests that nicotinic receptors are not involved. We postulate, at least for neostigmine, that the facilitation is an artefact because of the use of [(3)H]-choline as a radiotracer whereby the efflux of radioactivity is enhanced because the radiolabelled acetylcholine is not metabolized to choline and therefore flows out of the tissue more readily.

Modulation of acetylcholine release from mouse cortex by protein kinase C: dependence on stimulation intensity.

Activation of protein kinase C (PKC) results in enhanced action-potential evoked release of a variety of transmitters. However, previous studies have suggested that acetylcholine release is poorly modulated by PKC compared to other transmitter types. We investigated the effect of stimulation conditions on PKC modulation of electrical stimulation-induced acetylcholine release in mouse cortex, which were incubated with [3H]choline. The PKC activator phorbol dibutyrate (PDB) enhanced acetylcholine release at low stimulation frequencies (0.1 and 0.5 Hz) and not at 3 or 10 Hz. At 3 Hz stimulation, when release was inhibited by neostigmine, PDB enhanced acetylcholine release, suggesting that at low levels of acetylcholine release, exogenous activation of PKC can elevate acetylcholine release. However, at higher frequencies, PKC may already be endogenously activated since the PKC inhibitor polymyxin B (PXB) inhibited acetylcholine release. The other PKC inhibitors, Ro 318220, Gö 6976, bisindolylmaleimide and calphostin C appeared to have no effect at 3 Hz. It may be that these inhibitors do not effectively block PKC in this functional system. Indeed, polymyxin B completely blocked the facilitatory effect of PDB but Ro 318220 was without effect.

M(2)/M(4)-muscarinic receptors mediate automodulation of acetylcholine outflow from mouse cortex.

Acetylcholine outflow can be modulated through inhibitory presynaptic muscarinic autoreceptors. This study was to identify which subtype is involved in mouse cortex. Five muscarinic antagonists and their ability to elevate stimulation-induced (S-I) acetylcholine outflow were tested in the presence of neostigmine, which decreased S-I outflow. The potency of each antagonist was determined, expressed as a ratio of the potency of each other antagonist and compared with the potency ratios of the antagonists for each of the defined muscarinic receptors (M(1)-M(4)), as recorded in the literature. Linear regression analysis revealed that the data fitted the M(2) (r(2)>0.97) and M(4) (r(2)>0.85) subtypes best, with no correlation for the M(1) and M(3) subtypes.

Structural determinants of phorbol ester binding in synaptosomes: pharmacokinetics and pharmacodynamics.

The present study used structurally distinct phorbol esters to investigate the relationship between their pharmacokinetics of binding to protein kinase C (PKC) in rat brain cortex synaptosomes, their affinity for PKC in synaptosomes and ability to enhance noradrenaline release from rat brain cortex. Affinity binding studies using [3deoxyphorbol 13-tetradecanoate (dPT)=PDB&z. Gt;12-deoxyphorbol 13-acetate (dPA)=phorbol 12,13-diacetate (PDA). In intact synaptosomes PDB, dPA and PDA rapidly displaced bound [3H]PDB whereas PMA and dPT were comparatively slow. However, the displacement rates for all the phorbol esters were equally rapid in synaptosomal membranes or synaptosomes permeabilised with Staphylococcus alpha-toxin. These results suggest that the lipophilic phorbol esters (dPT and PMA) are slower to displace [3H]PDB binding because they are hindered by the plasma membrane. In brain cortex slices it was found that the rate of displacement of [3H]PDB binding was closely correlated with the degree of elevation of transmitter noradrenaline release. Thus kinetic characteristics may determine biological responses and this may be particularly evident in events which occur rapidly or where there is fast counter-regulation.

The structural requirements for phorbol esters to enhance serotonin and acetylcholine release from rat brain cortex.

The effects of various phorbol-based protein kinase C (PKC) activators on the electrical stimulation-induced (S-I) release of serotonin and acetylcholine was studied in rat brain cortical slices pre-incubated with [3H]-serotonin or [3H]-choline to investigate possible structure-activity relationships. 4beta-phorbol 12,13-dibutyrate (4betaPDB, 0.1-3.0 microM), enhanced S-I release of serotonin in a concentration-dependent manner whereas the structurally related inactive isomer 4alpha-phorbol 12, 13-dibutyrate (4alphaPDB) and phorbol 13-acetate (PA) were without effect. Another group of phorbol esters containing a common 13-ester substituent (phorbol 12,13-diacetate, PDA; phorbol 12-myristate 13-acetate, PMA; phorbol 12-methylaminobenzoate 13-acetate, PMBA) also enhanced S-I serotonin release with PMA being least potent. The deoxyphorbol monoesters, 12-deoxyphorbol 13-acetate (dPA), 12-deoxyphorbol 13-angelate (dPAng), 12-deoxyphorbol 13-phenylacetate (dPPhen) and 12-deoxyphorbol 13-isobutyrate (dPiB) enhanced S-I serotonin release but 12-deoxyphorbol 13-tetradecanoate (dPT) was without effect. The 20-acetate derivatives of dPPhen and dPAng were less effective in enhancing S-I serotonin release compared to the parent compounds. With acetylcholine release all phorbol esters tested had a far lesser effect when compared to their facilitatory action on serotonin release with only 4betaPDB, PDA, dPA, dPAng and dPiB having significant effects. The effects of the phorbol esters on serotonin release were not correlated with their reported in vitro affinity and isozyme selectivity for PKC. A comparison across three transmitter systems (noradrenaline, dopamine, serotonin) suggests basic similarities in the structural requirements of phorbol esters to enhance transmitter release with short chain substituted mono- and diesters of phorbol being more potent facilitators of release than the long chain esters. Some compounds notably PDA, PMBA, dPPhen, dPPhenA had different potencies across noradrenaline, dopamine and serotonin.

Protein kinase C: a physiological mediator of enhanced transmitter output.

Protein kinase C (PKC), activated by either diacylglycerol and/or arachidonic acid, through the activation of presynaptic receptors or nerve or nerve depolarization is involved is involved in the enhancement of transmitter release from many neural types. This facilities is most likely mediated by the phosphorylation of proteins involved in vesicle dynamics although a role for ion channels cannot be ruled out. PKC is not fundamental to the release process but rather has a modulatory role of PKC is to help maintain transmitter output during prolonged or elevated levels of activation and this seems to parallel suggestions that PKC is involved in the movement of reserve pools of vesicles into release-study sites. presynaptic facilitatory actions mediated by PKC are also involved in integrated modulatory functions such as long term potentiation, again where it elevates or maintains transmitter output. Although studies have tried to identify specific roles for various PKC isoforms, the actions of phorbol esters in elevators transmitter release do not fit with known potencies on individual isoforms and lit suggests that PKC may be located at an intraneuronal location which is difficult to access for lipophilic phorbol esters and further work is required in this area.

Protein kinase C and transmitter release.

1. Protein kinase C (PKC) is an important second messenger-activated enzyme. In noradrenergic nerves it appears to be tonically activated by diacylglycerol (DAG) to facilitate transmitter release and the steps in this involve activation of phospholipase C, generation of DAG and activation of PKC. It is suggested that the subsequent facilitation of transmitter release is due to the phosphorylation of proteins involved in the release process distal to Ca2+ entry, presumably those involved in vesicle dynamics. 2. There are differences between central noradrenergic neurons and sympathetic nerves. In central neurons PKC appears to be tonically active and its inhibition results in a decrease in noradrenaline release under most, if not all, conditions. 3. In sympathetic nerves PKC inhibitors only decrease transmitter release during high-frequency stimulation and not during low-frequency stimulation. At high frequency there is a gradual increase in the effect of PKC inhibitors on transmitter release during the first 15 s of a stimulation train. It is suggested that this is due to a progressive rise in intracellular Ca2+ and a consequent activation of PKC. 4. Activation of PKC by phorbol esters produces a large enhancement in action potential-evoked noradrenaline release in both the central nervous system and in peripheral tissues. The structural requirements of the phorbol esters for maximal effect suggest that the phorbol esters must access the interior of the nerve terminal to activate PKC and the neural membrane acts as a barrier for highly lipophilic phorbol esters, thereby reducing their activity. Activation of PKC represents one of the most powerful ways to enhance transmitter release and may have therapeutic potential.

Modulation of dopamine release from rat striatum by protein kinase C: interaction with presynaptic D2-dopamine-autoreceptors.

1. Interactions between dopamine receptors and protein kinase C (PKC) have been proposed from biochemical studies. The aim of the present study was to investigate the hypothesis that there is an interaction between protein kinase C and inhibitory D2-dopamine receptors in the modulation of stimulation-induced (S-I) dopamine release from rat striatal slices incubated with [3H]-dopamine. Dopamine release can be modulated by protein kinase C and inhibitory presynaptic D2 receptors since phorbol dibutyrate (PDB) and (-)-sulpiride, respectively, elevated S-I dopamine release. 2. The protein kinase C inhibitors polymyxin B (21 microM) and chelerythrine (3 microM) had no effect on stimulation-induced (S-I) dopamine release. However, when presynaptic dopamine D2 receptors were blocked by sulpiride (1 microM), an inhibitory effect of both PKC inhibitors on S-I dopamine release was revealed. Thus, sulpiride unmasks an endogenous PKC effect on dopamine release which suggests that presynaptic D2 receptors normally suppress endogenous PKC activity. This is supported by results in striatal slices which were pretreated with PDB to down-regulate PKC. In this case the facilitatory effect of sulpiride was completely abolished. 3. The inhibitory effect of the dopamine D2/D3 agonist quinpirole on S-I dopamine release was partially attenuated by PKC down-regulation. Since the effect of sulpiride was completely abolished under the same conditions, this suggests that exogenous agonists may target a PKC-dependent as well as a PKC-independent pathway. The inhibitory effect of apomorphine was not affected by either polymyxin B or PKC down-regulation, suggesting that it operated exclusively through a PKC-independent mechanism. 4. These results suggest that there are at least two pathways involved in the inhibition of dopamine release through dopamine receptors. One pathway involves dopamine receptor suppression of protein kinase C activity, perhaps through inhibition of phospholipase C activity and this is preferentially utilized by neuronally-released dopamine. The other pathway which seems to be utilized by exogenous agonists does not involve PKC.

Muscarinic autoinhibition of acetylcholine release in mouse atria is not transduced through cyclic AMP or protein kinase C.

1. The present study investigated the second messenger pathways that may mediate muscarinic receptor autoinhibition of acetylcholine release in mouse atria. The stimulation-induced (S-I) outflow of radioactivity from mouse isolated atria incubated with [3H]-choline was Ca(2+)-dependent and tetrodotoxin-sensitive and was used as an index of neuronal acetylcholine release. 2. The cell permeable analogue of cyclic AMP, 8-bromocyclic AMP (1 x 10(-3)M) enhanced the S-I outflow of radioactivity (33%), lower concentrations having no effect. Similarly, the adenylate cyclase activator forskolin (1 x 10(-5)M) had a small facilitatory effect on acetylcholine release. On the other hand the phosphodiesterase inhibitor 3-isobutylmethylxanthine (1 x 10(-4)M) had no effect on the S-I outflow of radioactivity. Together these results suggest that the adenylate cyclase/cyclic AMP system does not have an appreciable role in the modulation of acetylcholine release. 3. The protein kinase C activator phorbol dibutyrate (0.1-3 x 10(-6)M) enhanced the S-I acetylcholine release (maximally by 45%). The effects of phorbol dibutyrate were attenuated by the protein kinase inhibitor staurosporine (1 x 10(-7)M), which by itself had no effect on the S-I outflow of radioactivity. This latter result suggests that there is no tonic activation of protein kinase C during acetylcholine release. 4. Atropine (1 x 10(-7)M) markedly enhanced (232%) the S-I outflow of radioactivity, presumably by preventing feedback inhibition on acetylcholine release through prejunctional muscarinic receptors. This effect is unlikely to involve adenylate cyclase or protein kinase C since it was far greater than the effects of activation of either system with forskolin and phorbol dibutyrate, respectively. Furthermore, the facilitatory effect of atropine was not attenuated by staurosporine, which although a protein kinase C inhibitor, is also an effective inhibitor of cyclic AMP dependent protein kinase (protein kinase A).