Distinct Mechanisms of Regulation by Ca2+/Calmodulin of Type 1 and 8 Adenylyl Cyclases Support Their Different Physiological Roles

Nine membrane-bound mammalian adenylyl cyclases (ACs) have been identified. Type 1 and 8 ACs (AC1 and AC8), which are both expressed in the brain and are stimulated by Ca²⁺/calmodulin (CaM), have discrete neuronal functions. Although the Ca²⁺ sensitivity of AC1 is higher than that of AC8, precisely how these two ACs are regulated by Ca²⁺/CaM remains elusive, and the basis for their diverse physiological roles is quite unknown. Distinct localization of the CaM binding domains within the two enzymes may be essential to differential regulation of the ACs by Ca²⁺/CaM. In this study we compare in detail the regulation of AC1 and AC8 by Ca²⁺/CaM both in vivo and in vitro and explore the different role of each Ca²⁺-binding lobe of CaM in regulating the two enzymes. We also assess the relative dependence of AC1 and AC8 on capacitative Ca²⁺ entry. Finally, in real-time fluorescence resonance energy transfer-based imaging experiments, we examine the effects of dynamic Ca²⁺ events on the production of cAMP in cells expressing AC1 and AC8. Our data demonstrate distinct patterns of regulation and Ca²⁺ dependence of AC1 and AC8, which seems to emanate from their mode of regulation by CaM. Such distinctive properties may contribute significantly to the divergent physiological roles in which these ACs have been implicated.Nine membrane-bound mammalian adenylyl cyclases (ACs),² AC1–AC9, have been identified (1). They possess a common predicted structure (2)³ and are stimulated by forskolin (FSK; except AC9) and G_sα, although they are distributed and regulated differently (1, 3, 4). Four ACs are regulated by physiological concentrations of Ca²⁺ and thereby provide a critical link between the Ca²⁺- and cAMP-signaling pathways (3, 5); AC5 and AC6 are directly inhibited by Ca²⁺, whereas AC1 and AC8 are stimulated by Ca²⁺ in a calmodulin (CaM)-dependent manner (5). AC3 is also regulated by CaM in vitro, although this requires supramicromolar concentration of Ca²⁺ (6), and in vivo AC3 is inhibited by Ca²⁺ via CaM kinase II (7), unlike AC1 and AC8.AC1 is closely related in sequence to the Ca²⁺/CaM-stimulable rutabaga AC from Drosophila, which is important in Drosophila learning tasks (8–10). AC1 and the other Ca²⁺/CaM-stimulable mammalian AC, AC8, have also been implicated in learning and memory (11). As a means of establishing their proposed roles, single and/or double AC1 and AC8 knockout mice have been generated. Mouse models have demonstrated that Ca²⁺/CaM-stimulable ACs are involved in long-term potentiation and long-term memory (12). However, despite the general view that AC1 and AC8 can behave similarly, discrete physiological actions of each isoform are becoming apparent. Recent studies by Zhuo''s group demonstrated that AC1 specifically participates in N-methyl-d-aspartic acid receptor-induced neuronal excitotoxicity (13) and an increase in GluR1 synthesis induced by blocking AMPA receptors (14). Furthermore, Nicol and colleagues (15, 16) showed a contribution of AC1, but not AC8, in axon terminal refinement in the retina. On the other hand, AC8 specifically was seen to be responsible for retrieval from adaptive presynaptic silencing (17) and the acquiring of new spatial information (18). These differences in physiological roles must reflect not only differences in their distributions but also presumably in their regulatory properties. Both enzymes are expressed in brain; AC1 is neuro-specific, whereas the expression of AC8 is more widespread (1, 12). Within the central nervous system, AC1 is abundant in the hippocampus, the cerebral cortex, and the granule cells of the cerebellum, whereas AC8 has a high expression level in the thalamus and the cerebral cortex (19). Studies of mouse brain revealed that AC1 is distributed pre-synaptically and AC8 post-synaptically (18, 20).Although physiological differences in the roles of these two enzymes are suggested from the studies outlined above, the regulatory mechanisms that might underlie these differences are not. AC1 is more sensitive to Ca²⁺ than is AC8 in vitro (21, 22), yet details on how these two enzymes are regulated by Ca²⁺/CaM are sparse. In non-excitable cells, a Ca²⁺ elevation caused by capacitative Ca²⁺ entry (CCE), the mode of Ca²⁺ entry triggered by emptying Ca²⁺ from internal stores (23), preferentially stimulates AC1 and AC8 (21). Although stimulation of AC8 by CCE has been shown to be at least partially dependent on its localization at lipid rafts (24), whether AC1 is also targeted to this region of plasma membranes has never been addressed. In addition, CaM regulation of AC1 and AC8 has not been compared in detail, although CaM appears to bind to different domains of the two enzymes. AC8 utilizes two CaM binding domains: a classic amphipathic “1-5-8-14” motif at the N terminus and an IQ-like motif in the C2b domain (25). A recent study indicates that CaM pre-associates with the N terminus of AC8, where it becomes fully saturated upon a Ca²⁺ rise, and activates the enzyme via a C-terminally mediated relief of auto-inhibitory mechanisms (26). By contrast, only residues 495–522 of the C1b region of AC1 have been shown to bind CaM in a Ca²⁺-dependent manner (27, 28). With the presence of only one CaM binding domain in AC1, a simpler mechanism of CaM regulation might be expected.CaM mediates the regulation of numerous Ca²⁺-dependent processes in eukaryotic cells (29). The protein possesses N- and C-terminal lobes, both of which contain two Ca²⁺ binding EF hands (EF1 and EF2 in the N lobe, and EF3 and EF4 in the C lobe (30)). Mutations in the EF hands have been valuable for investigating the interaction of CaM with its targets. Alanine substitutions in the EF12 pair or EF34 pair have generated CaM₁₂ and CaM₃₄ to investigate the independent function of the C and N lobes of CaM, respectively (31, 32).Against the background of the distinct physiological roles carried out by AC1 and AC8, we performed a detailed comparison of the two enzymes expressed in HEK 293 cells. Their sensitivity to Ca²⁺/CaM was compared both in vitro and in vivo; the possibility that they might be expressed in different domains of the plasma membrane was addressed; and putative lobe-specific CaM regulation was assessed using Ca²⁺-binding mutants of CaM. Single cell measurements using a FRET-based cAMP sensor were performed to compare the kinetic responses of the enzymes to physiological elevations of [Ca²⁺]_i. The results demonstrate superficial similarities in the regulation of AC1 and AC8 but critical disparities in their mechanism of activation by the lobes of CaM and in the speed and pattern of their responsiveness to [Ca²⁺]_i. These discrete behaviors provide a physiological opportunity for different outcomes to elevation of [Ca²⁺]_i, depending on the AC that is expressed in particular contexts.     

Calmodulin and Ca2+/calmodulin-binding proteins are involved in Tetrahymena thermophila phagocytosis

The ciliated protist, Tetrahymena thermophila, possesses one oral apparatus for phagocytosis, one of the most important cell functions, in the anterior cell cortex. The apparatus comprises four membrane structures which consist of ciliated and unciliated basal bodies, a cytostome where food is collected by oral ciliary motility, and a cytopharynx where food vacuoles are formed. The food vacuole is thought to be transported into the cytoplasm by a deep fiber which connects with the oral apparatus. Although a large number of studies have been done on the structure of the oral apparatus, the molecular mechanisms of phagocytosis in Tetrahymena thermophila are not well understood. In this study, using indirect immunofluorescence, we demonstrated that the deep fiber consisted of actin, CaM, and Ca2+/CaM-binding proteins, p85 and EF-1alpha, which are closely involved in cytokinesis. Moreover, we showed that CaM, p85, and EF-1alpha are colocalized in the cytostome and the cytopharynx of the oral apparatus. Next, we examined whether Ca2+/CaM signal regulates Tetrahymena thermophila phagocytosis, using Ca2+/CaM inhibitors chlorpromazine, trifluoperazine, N-(6-aminohexyl)-1-naphthalenesulfonamide, and N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide HCI. In Tetrahymena, it is known that Ca2+/CaM signal is closely involved in ciliary motility and cytokinesis. The results showed that one of the inhibitors, N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide HCl, inhibited the food vacuole formation rather than the ciliary motility, while the other three inhibitors effectively prevented the ciliary motility. Considering the colocalization of CaM, p85, and EF-1alpha to the cytopharynx, these results suggest that the Ca2+/CaM signal plays a pivotal role in Tetrahymena thermophila food vacuole formation.     

Evidence for a G-Protein Regulated Adenylate Cyclase and a Ca2/Calmodulin Controlled Phosphodiesterase in the Phytoflagellate Chlorogonium

In the green flagellate Chlorogonium elongatum the cAMP concentration of the cells depends on the culture conditions of the alga. Autotrophically cultured cells possess three times more cAMP than cells cultured heterotrophically (in the dark with acetate). The activity of adenylate cyclase in a membrane fraction of Chlorogonium is distinctly stimulated by GTPγS. Such a stimulation is generally regarded as an indication of the participation of heterotrimeric G-proteins in this regulatory process. The activity of phosphodiesterase is stimulated in vitro by calmodulin and inhibited by trifluoperazin and EGTA.     

CaMKII Autonomy Is Substrate-dependent and Further Stimulated by Ca2+/Calmodulin

A hallmark feature of Ca²⁺/calmodulin (CaM)-dependent protein kinase II (CaMKII) regulation is the generation of Ca²⁺-independent autonomous activity by Thr-286 autophosphorylation. CaMKII autonomy has been regarded a form of molecular memory and is indeed important in neuronal plasticity and learning/memory. Thr-286-phosphorylated CaMKII is thought to be essentially fully active (∼70–100%), implicating that it is no longer regulated and that its dramatically increased Ca²⁺/CaM affinity is of minor functional importance. However, this study shows that autonomy greater than 15–25% was the exception, not the rule, and required a special mechanism (T-site binding; by the T-substrates AC2 or NR2B). Autonomous activity toward regular R-substrates (including tyrosine hydroxylase and GluR1) was significantly further stimulated by Ca²⁺/CaM, both in vitro and within cells. Altered K_m and V_max made autonomy also substrate- (and ATP) concentration-dependent, but only over a narrow range, with remarkable stability at physiological concentrations. Such regulation still allows molecular memory of previous Ca²⁺ signals, but prevents complete uncoupling from subsequent cellular stimulation.     

Demonstration of a Ca2+/Calmodulin Dependent Protein Kinase Cascade in the Hog Heart

Members of the Ca²⁺/calmodulin dependent protein kinase (CaMK) family and a CaMK cascade have been identified and well characterized in the brain, but little is known about their equivalents in the heart. Thus only CaMKII and its function have been reported so far. Therefore, we purified and characterized CaMKI and CaMK kinase (CaMKK) as an associated activator from the hog heart for the first time. The heart CaMKI was revealed to be the α isoform of brain CaMKI with a molecular weight of 41 kDa to phosphorylate cardiac phospholamban peptide, and to exhibit autophosphorylation requiring CaMKK. Heart CaMKK was found as a 67 kDa band and proved to be a different kinase from that in brain. These data indicate the existence of a heart specific CaMK cascade, consisting of CaMKI and CaMKK, along with CaMKII, which should be taken into account in any consideration of Ca²⁺signal transduction.     

A Quantitative Study of the Ca2+/Calmodulin Sensitivity of Adenylyl Cyclase in Aplysia, Drosophila, and Rat

Studies in Aplysia and Drosophila have suggested that Ca2+/calmodulin-sensitive adenylyl cyclase may act as a site of convergence for the cellular representations of the conditioned stimulus (Ca2+ influx) and unconditioned stimulus (facilitatory transmitter) during elementary associative learning. This hypothesis predicts that the rise in intracellular free Ca2+ concentration produced by spike activity during the conditioned stimulus will cause an increase in the activity of adenylyl cyclase. However, published values for the Ca2+ sensitivity of Ca2+/calmodulin-sensitive adenylyl cyclase in mammals and in Drosophila vary widely. The difficulty in evaluating whether adenylyl cyclase would be activated by physiological elevations in intracellular Ca2+ levels is in part a consequence of the use of Ca2+/EGTA buffers, which are prone to several types of errors. Using a procedure that minimizes these errors, we have quantified the Ca2+ sensitivity of adenylyl cyclase in membranes from Aplysia, Drosophila, and rat brain with purified species-specific calmodulins. In all three species, adenylyl cyclase was activated by an increase in free Ca2+ concentration in the range caused by spike activity. Ca2+ sensitivity was dependent on both calmodulin concentration and Mg2+ concentration. Mg2+ raised the threshold for adenylyl cyclase activation by Ca2+ but also acted synergistically with Ca2+ to activate maximally adenylyl cyclase.     

The Pseudo Signal Peptide of the Corticotropin-releasing Factor Receptor Type 2a Decreases Receptor Expression and Prevents Gi-mediated Inhibition of Adenylyl Cyclase Activity

The corticotropin-releasing factor receptor type 2a (CRF_2(a)R) belongs to the family of G protein-coupled receptors. The receptor possesses an N-terminal pseudo signal peptide that is unable to mediate targeting of the nascent chain to the endoplasmic reticulum membrane during early receptor biogenesis. The pseudo signal peptide remains uncleaved and consequently forms an additional hydrophobic receptor domain with unknown function that is unique within the large G protein-coupled receptor protein family. Here, we have analyzed the functional significance of this domain in comparison with the conventional signal peptide of the homologous corticotropin-releasing factor receptor type 1 (CRF₁R). We show that the presence of the pseudo signal peptide leads to a very low cell surface receptor expression of the CRF_2(a)R in comparison with the CRF₁R. Moreover, whereas the presence of the pseudo signal peptide did not affect coupling to the G_s protein, G_i-mediated inhibition of adenylyl cyclase activity was abolished. The properties mediated by the pseudo signal peptide were entirely transferable to the CRF₁R in signal peptide exchange experiments. Taken together, our results show that signal peptides do not only influence early protein biogenesis. In the case of the corticotropin-releasing factor receptor subtypes, the use of conventional and pseudo signal peptides have an unexpected influence on signal transduction.     

A Joint 2D NMR and Theoretical Investigation of Ca2+ Binding Loops III and IV of Calmodulin

Abstract

A 2D NMR NOESY spectrum of integral CaM in water(148 residues) reveals a series of downfield-shifted crosspeaks stemming from the NH protons of the Ca²⁺ -binding loops III and IV. Their attribution, with the help of already assigned proton resonances of isolated tryptic fragments, was complemented by means of energy-minimizations on the Ca²⁺ complexes of loops III and IV. From these calculations, a set of two alternative, related conformations was obtained for each loop. The first type of conformation provides a coordination pattern for Ca²⁺ that is similar to that found in loop EF of parvalbumin. The computed interproton distances in both loops are fully compatible with the inferences from the sets of NOESY cross-peaks. Evidence is also provided for interloop interactions.     

Calmodulin and Ca2+ in normal and transformed cells

Numerous lines of evidence implicate calcium and calmodulin (CaM) as regulators of cell growth and functional differentiation. In light of this evidence, several studies of the possible involvement of the CaM system in cellular transformation by RNA and DNA tumor viruses have been carried out. This paper summarizes the evidence linking calcium and CaM to the regulation of cell growth and critically examines the evidence that increases in CaM levels occur in transformed versus normal cells. A nontraumatic method for synchronizing both normal and transformed chick fibroblasts is presented. This method is utilized in a comparison of CaM level throughout the cell cycle of Rous sarcoma virus transformed and normal chick embryo fibroblasts. These studies best support the hypothesis that the observed differences in CaM levels between transformed and normal cultures under optimal growth conditions may largely reflect differences in the proportion of cells in a dividing versus a nondividing state.     

Similarly Potent Inhibition of Adenylyl Cyclase by P-Site Inhibitors in Hearts from Wild Type and AC5 Knockout Mice

Adenylyl cyclase type 5 (AC5) was described as major cardiac AC isoform. The knockout of AC5 (AC5KO) exerted cardioprotective effects in heart failure. Our study explored the impact of AC5KO on mouse heart AC activities and evaluated putative AC5-selective inhibitors. In cardiac membranes from AC5KO mice, basal AC activity was decreased, while AC stimulation was intact. The putative AC5-selective P-site inhibitors SQ22,536 [9-(tetra-hydro-2-furanyl)-9H-purin-6-amine], vidarabine (9-β-D-arabinosyladenine) and NKY80 [2-amino-7-(2-furanyl)-7,8-dihydro-5(6H)-quinazolinone] inhibited recombinant AC5 more potently than AC2 and AC1, but selectivity was only modest (∼4-40-fold). These compounds inhibited cardiac AC from WT and AC5KO mice with similar potencies. In conclusion, AC regulation in AC5KO hearts was unimpaired, questioning the supposed dominant role of AC5 in the heart. Moreover, the AC inhibitors SQ22,536, NKY80 and vidarabine lack adequate selectivity for AC5 and, therefore, do not present suitable tools to study AC5-specific functions.     

Type II Ca2+/calmodulin-dependent protein kinase binds to actin filaments in a calmodulin-sensitive manner

Multifunctional type II Ca2+/calmodulin-dependent protein kinase purified from rat brain cytosol was found to bind to actin filaments in vitro. The binding was saturable, and the dissociation constant for the binding was determined to be about 4 X 10(-8)M. Electron microscopic observation indicated that the kinase binds to the side of actin filaments. Calmodulin inhibited the binding of the kinase to actin filaments in a Ca2+-dependent manner. The Ca2+/calmodulin-regulated binding of the kinase to actin filaments revealed here may be important for the substrate recognition of the kinase.     

The A-kinase Anchoring Protein Yotiao Facilitates Complex Formation between Adenylyl Cyclase Type 9 and the IKs Potassium Channel in Heart

The scaffolding protein Yotiao is a member of a large family of protein A-kinase anchoring proteins with important roles in the organization of spatial and temporal signaling. In heart, Yotiao directly associates with the slow outward potassium ion current (I(Ks)) and recruits both PKA and PP1 to regulate I(Ks) phosphorylation and gating. Human mutations that disrupt I(Ks)-Yotiao interaction result in reduced PKA-dependent phosphorylation of the I(Ks) subunit KCNQ1 and inhibition of sympathetic stimulation of I(Ks), which can give rise to long-QT syndrome. We have previously identified a subset of adenylyl cyclase (AC) isoforms that interact with Yotiao, including AC1-3 and AC9, but surprisingly, this group did not include the major cardiac isoforms AC5 and AC6. We now show that either AC2 or AC9 can associate with KCNQ1 in a complex mediated by Yotiao. In transgenic mouse heart expressing KCNQ1-KCNE1, AC activity was specifically associated with the I(Ks)-Yotiao complex and could be disrupted by addition of the AC9 N terminus. A survey of all AC isoforms by RT-PCR indicated expression of AC4-6 and AC9 in adult mouse cardiac myocytes. Of these, the only Yotiao-interacting isoform was AC9. Furthermore, the endogenous I(Ks)-Yotiao complex from guinea pig also contained AC9. Finally, AC9 association with the KCNQ1-Yotiao complex sensitized PKA phosphorylation of KCNQ1 to β-adrenergic stimulation. Thus, in heart, Yotiao brings together PKA, PP1, PDE4D3, AC9, and the I(Ks) channel to achieve localized temporal regulation of β-adrenergic stimulation.     

Ca2+/H+ exchange,lumenal Ca2+ release and Ca2+/ATP coupling ratios in the sarcoplasmic reticulum ATPase

The Ca²⁺ transport ATPase (SERCA) of sarcoplasmic reticulum (SR) plays an important role in muscle cytosolic signaling, as it stores Ca²⁺ in intracellular membrane bound compartments, thereby lowering cytosolic Ca²⁺ to induce relaxation. The stored Ca²⁺ is in turn released upon membrane excitation to trigger muscle contraction. SERCA is activated by high affinity binding of cytosolic Ca²⁺, whereupon ATP is utilized by formation of a phosphoenzyme intermediate, which undergoes protein conformational transitions yielding reduced affinity and vectorial translocation of bound Ca²⁺. We review here biochemical and biophysical evidence demonstrating that release of bound Ca²⁺ into the lumen of SR requires Ca²⁺/H⁺ exchange at the low affinity Ca²⁺ sites. Rise of lumenal Ca²⁺ above its dissociation constant from low affinity sites, or reduction of the H⁺ concentration by high pH, prevent Ca²⁺/H⁺ exchange. Under these conditions Ca²⁺ release into the lumen of SR is bypassed, and hydrolytic cleavage of phosphoenzyme may yield uncoupled ATPase cycles. We clarify how such Ca²⁺pump slippage does not occur within the time length of muscle twitches, but under special conditions and in special cells may contribute to thermogenesis.     

The Effect of Moderate Hypocapnic Ventilation on Nuclear Ca2+-ATPase Activity, Nuclear Ca2+ Flux, and Ca2+/Calmodulin Kinase IV Activity in the Cerebral Cortex of Newborn Piglets

Previous studies have shown that hypocapnia results in fragmentation of nuclear DNA in the cerebral cortex of newborn piglets. We tested the hypothesis that hypocapnia results in decreased ATP and phosphocreatine (PCr) levels and increased nuclear high-affinity Ca++-ATPase activity, intranuclear Ca++ flux, and CaM kinase IV activity in neuronal nuclei of piglets. Three groups of piglets were ventilated as either hypocapnic (a PaCO2 of 20 mm Hg), normocapnic (a PaCO2 of 40 mm Hg), or corrected hypocapnic (ventilated as hypocapnic but with CO2 added to maintain normocapnia) for 1 h. Tissue ATP levels were lower in the hypocapnic than in the normocapnic group. PCr levels were lower and 45Ca++-influx, Ca++-ATPase activity and CaM kinase IV activity were higher in hypocapnic than in normocapnic or corrected hypocapnic piglets. We conclude that hypocapnia alters nuclear membrane Ca++ flux mechanisms and may alter neuronal phosphorylation mechanisms in the cerebral cortex of piglets.     

Autoinhibition and Signaling by the Switch II Motif in the G-protein Chaperone of a Radical B12 Enzyme

MeaB is an accessory GTPase protein involved in the assembly, protection, and reactivation of 5′-deoxyadenosyl cobalamin-dependent methylmalonyl-CoA mutase (MCM). Mutations in the human ortholog of MeaB result in methylmalonic aciduria, an inborn error of metabolism. G-proteins typically utilize conserved switch I and II motifs for signaling to effector proteins via conformational changes elicited by nucleotide binding and hydrolysis. Our recent discovery that MeaB utilizes an unusual switch III region for bidirectional signaling with MCM raised questions about the roles of the switch I and II motifs in MeaB. In this study, we addressed the functions of conserved switch II residues by performing alanine-scanning mutagenesis. Our results demonstrate that the GTPase activity of MeaB is autoinhibited by switch II and that this loop is important for coupling nucleotide-sensitive conformational changes in switch III to elicit the multiple chaperone functions of MeaB. Furthermore, we report the structure of MeaB·GDP crystallized in the presence of AlF_x⁻ to form the putative transition state analog, GDP·AlF₄⁻. The resulting crystal structure and its comparison with related G-proteins support the conclusion that the catalytic site of MeaB is incomplete in the absence of the GTPase-activating protein MCM and therefore unable to stabilize the transition state analog. Favoring an inactive conformation in the absence of the client MCM protein might represent a strategy for suppressing the intrinsic GTPase activity of MeaB in which the switch II loop plays an important role.     

Existence of endogenous substrate proteins for Ca2+/calmodulin-dependent and Ca2+/phospholipid-dependent protein kinases in rat adrenal glomerulosa cells

In rat adrenal glomerulosa cells, endogenous substrate proteins for Ca2+/calmodulin (CaM)-dependent protein kinase (glomerulosa CaM kinase) and Ca2+/phospholipid-dependent protein kinase (protein kinase C) were investigated. In a 105,000 g-supernatant fraction (cytosol), the Mr 100,000 protein was phosphorylated in the presence of calcium (calculated free Ca2+ concentration, 460 microM) alone or calcium and CaM, and the phosphorylation of this protein was completely inhibited by the CaM antagonists pimozide (500 microM) and melittin (5 microM) in the presence of calcium alone, respectively. These results indicate that the Mr 100,000 protein is a major substrate for glomerulosa CaM kinase, and considerable amounts of endogenous CaM might be present in the cytosol. In the presence of phospholipids (the micelles of 8 micrograms of phosphatidyl serine and 1 microgram of diacylglycerol), at least twelve proteins of Mr 127,000, 80,000, 70,000, 36,000, 35,000, 33,000, 32,000, 30,000, 27,000, 22,000, 19,000 and 17,000 were phosphorylated, and the phosphorylation of these proteins was enhanced by the addition of calcium, indicating that these proteins are substrates for protein kinase C. No endogenous protein phosphorylation was found in a 105,000 g-particulate fraction. Thus, these findings demonstrate that adrenal glomerulosa cells have specific substrate proteins for glomerulosa CaM kinase and protein kinase C, respectively.