Masami Yoshimura

Ethanol-induced phosphorylation and potentiation of the activity of type 7 adenylyl cyclase: Involvement of protein kinase C δ

Ethanol can enhance Gsα-stimulated adenylyl cyclase (AC) activity. Of the nine isoforms of AC, type 7 (AC7) is the most sensitive to ethanol. The potentiation of AC7 by ethanol is dependent on protein kinase C (PKC). We designed studies to determine which PKC isotype(s) are involved in the potentiation of Gαs-activated AC7 activity by ethanol and to investigate the direct phosphorylation of AC7 by PKC. AC7 was phosphorylated in vitro by the catalytic subunits of PKCs. The addition of ethanol to AC7-transfected HEK 293 cells increased the endogenous phosphorylation of AC7, as indicated by a decreased “back-phosphorylation” of AC7 by PKCin vitro. The potentiation of Gαs-stimulated AC7 activity by either phorbol 12,13-dibutyrate or ethanol, in HEL cells endogenously expressing AC7, was not through the Ca2+-sensitive conventional PKCs. However, the potentiation of AC7 activity by ethanol or phorbol 12,13-dibutyrate was found to be reduced by the selective inhibitor of PKCδ (rottlerin), a PKCδ-specific inhibitory peptide (δV1-1), and the expression of the dominant negative form of PKCδ. Immunoprecipitation data indicated that PKCδ could bind and directly phosphorylate AC7. The results indicate that the potentiation of AC7 activity by ethanol involves phosphorylation of AC7 that is mediated by PKCδ.

Phosphorylation Cascades Control the Actions of Ethanol on Cell cAMP Signalling

Our studies indicate that, in the presence of particular isoforms of adenylyl cyclase (i.e., type 7 AC), moderately intoxicating concentrations of ethanol will significantly potentiate transmitter-mediated activation of the cAMP signaling cascade. Activation of this signaling cascade may have important implications for the mechanisms by which ethanol produces intoxication, and/or for the mechanisms of neuroadaptation leading to tolerance to, and physical dependence on, ethanol. We initiated a series of studies to investigate the phosphorylation of AC7 by PKC, the role of this phosphorylation in modulating the sensitivity of AC7 to activation by Gsalpha, and the PKC isotype(s) involved in the phosphorylation of AC7. The T7 epitope-tagged AC7 expressed in Sf9 and HEK293 cells was found to be phosphorylated in vitro by the catalytic subunit of PKC. Treatment of AC7-transfected HEK293 cells with phorbol dibutyrate (PDBu) or ethanol increased the phosphorylation of AC7 and its responsiveness to Gsalpha. In human erythroleukemia (HEL) cells, which endogeneously express AC7, ethanol and PDBu increased AC activity stimulated by PGE(1). The potentiation by both PDBu and ethanol was found to be sensitive to the PKC delta-selective inhibitor, rottlerin. The potentiation of AC activity by ethanol in HEL cells was also selectively attenuated by the RACK inhibitory peptide specific for PKC delta, and by expression of the dominant negative, catalytically inactive, form of PKC delta. These data demonstrate that AC7 can be phosphorylated by PKC, leading to an increase in functional activity, and ethanol can potentiate AC7 activity through a PKC delta-mediated phosphorylation of AC7.

A Sex-Specific Role of Type VII Adenylyl Cyclase in Depression

Major depression represents a complex mental disorder. The identification of biological markers that define subtypes of major depressive disorder would greatly facilitate appropriate medical treatments, as well as provide insight into etiology. Reduced activity of the cAMP signaling system has been implicated in the etiology of major depression. Previous work has shown low adenylyl cyclase activity in platelets and postmortem brain tissue of depressed individuals. Here, we investigate the role of the brain type VII isoform of adenylyl cyclase (AC7) in the manifestation of depressive symptoms in genetically modified animals, using a combination of in vivo behavioral experiments, gene expression profiling, and bioinformatics. We also completed studies with humans on the association of polymorphisms in the AC7 gene with major depressive illness (unipolar depression) based on Diagnostic and Statistical Manual of Mental Disorders IV criteria. Collectively, our results demonstrate a sex-specific influence of the AC7 gene on a heritable form of depressive illness.

Immunological assessment of the distribution of Type VII adenylyl cyclase in brain

The localization of the nine identified isoforms of adenylyl cyclase in brain has been largely based on determination of patterns of mRNA expression. A polyclonal antibody has now been developed that specifically recognizes Type VII adenylyl cyclase. This antibody was used for immunocytochemical analysis of the distribution of Type VII adenylyl cyclase in rat brain. Labeling of Type VII adenylyl cyclase was observed in several areas, including cerebellum, caudate-putamen, nucleus accumbens, hippocampus and cerebral cortex. In some of these areas, the staining of the adenylyl cyclase protein suggested the possibility of presynaptic localization. For example, in situ hybridization showed Type VII adenylyl cyclase mRNA concentrated in cerebellar granule neurons. The cerebellar granule cell layer, however, showed little immunostaining, while punctate immunostaining was observed in the molecular layer. These results suggested that protein synthesized in the granule neurons may be targeted to the neuron terminals. Punctate staining in the caudate-putamen, globus pallidus and nucleus accumbens also suggested the possibility of axonal and/or dendritic localization of Type VII adenylyl cyclase in these regions. Labeling of the soma of cerebellar Purkinje cells, cortical pyramidal and non-pyramidal cells and interneurons in the cerebellum and hippocampus was also observed. Type VII adenylyl cyclase, like the other adenylyl cyclase isoforms, has distinct regulatory characteristics, including sensitivity to stimulation by Gsalpha and G protein betagamma subunits, modulation by protein kinase C, and high sensitivity to stimulation by ethanol. These characteristics, and the discrete localization of this enzyme, may contribute to its ability to provide signal integration and/or control of neurotransmitter release in particular neurons or brain areas.