Specific protein phosphorylation during cyclic AMP-mediated morphological reversion of transformed cells

Treatment of transformed Chinese hamster ovary cells with dibutyryl cAMP or other agents that elevate cAMP results in the acquisition of growth and morphology characteristic of normal fibroblasts. The role of specific protein phosphorylation in this process of morphological reversion has been examined using metabolic labelling of Chinese hamster ovary (CHO) cells with ³²P-orthophosphate in the presence or absence of N⁶O^2′-dibutyryladenosine 3′:5′-cyclic monophosphoric acid (Bt₂cAMP). Analysis of labelled cultures by SDS gel electrophoresis and radioautography demonstrate dramatic changes in the phosphorylation of only 2 cellular proteins during reverse transformation. A 55,000 dalton protein (pp55) was phosphorylated and a 20,000 dalton protein (pp20) was dephosphorylated. The time course of these events was consistent with the kinetics of morphological reversion. The lower molecular weight species, pp20, was dephosphorylated within 15–30 minutes, prior to all morphological changes except membrane tranquilization. The higher molecular weight protein, pp55, was maximally phosphorylated over 1–2 hours following addition of Bt₂cAMP, paralleling early stages in the establishment of fibroblastic form. The phosphorylated forms of pp20 and pp55 were both extracted from cellular cytoskeletons by 0.5% Triton X-100, but analysis of ³⁵S-methioninelabelled cultures suggested that unphosphorylated pp 20 may be bound to the cytoskeleton. Since pp20 was found to comigrate with the 20,000 dalton myosin light chain, it is possible that dephosphorylation of CHO cell myosin induced by cAMP may alter its interaction with actin microfilaments and modulate the assembly of stress fibers during morphological reversion.     

Regulation of protein phosphorylation in pancreatic acini by cyclic AMP-mediated secretagogues: interaction with carbamylcholine

The effects on protein phosphorylation in mouse pancreatic acini of cyclic AMP-mediated secretagogues and the Ca2+-mediated agonist carbamylcholine were compared. Under the conditions adopted for the study of protein phosphorylation, carbamylcholine (3 microM) stimulated amylase release from pancreatic acini 6-fold, whereas vasoactive intestinal polypeptide (VIP) (100 nM) and the cyclic AMP analogue 8-bromo-cyclic AMP (1 mM) caused little or no increase in secretion. However, VIP and 8-bromo-cyclic AMP, when added in combination with carbamylcholine, potentiated the stimulation of amylase release to 170-180% of that caused by carbamylcholine alone. As assessed by two-dimensional gel electrophoresis, VIP reproduced four of the ten changes in protein phosphorylation elicited by carbamylcholine, these changes being the increased phosphorylation of one soluble protein and the decreased phosphorylation of three soluble proteins. VIP enhanced the carbamylcholine-induced changes in phosphorylation for three proteins. In addition, VIP increased the phosphorylation of a unique protein of Mr 52,000 and pI 5.66 which was not affected by carbamylcholine. All of the effects on protein phosphorylation exerted by VIP in the presence or absence of carbamylcholine were mimicked by 8-bromo-cyclic AMP. Secretin also reproduced most of the changes in protein phosphorylation caused by VIP, although concentrations of secretin of at least 100-fold higher were required to elicit a maximal response. It is concluded that cyclic AMP-mediated secretagogues alter the phosphorylation of a unique protein as well as of several pancreatic proteins affected by carbamylcholine. Moreover, these effects appear to be mediated primarily by VIP-preferring receptors and may be involved in the synergistic action of VIP to promote carbamylcholine-induced amylase release.     

Voltage-dependent modulation of T-type calcium channels by protein tyrosine phosphorylation.

A T-type Ca2+ channel is expressed during differentiation of the male germ lineage in the mouse and is retained in sperm, where is it activated by contact with the the egg's extracellular matrix and controls sperm acrosomal exocytosis. Here, we examine the regulation of this Ca2+ channel in dissociated spermatogenic cells from the mouse using the whole-cell patch-clamp technique. T currents were enhanced, or facilitated, after strong depolarizations or high frequency stimulation. Voltage-dependent facilitation increased the Ca2+ current by an average of 50%. The same facilitation is produced by antagonists of protein tyrosine kinase activity. Conversely, antagonists of tyrosine phosphatase activity block voltage-dependent facilitation of the current. These data are consistent with the presence of a two-state model, in which T channels are maintained in a low (or zero) conductance state by tonic tyrosine phosphorylation and can be activated to a high conductance state by a tyrosine phosphatase activity. The positive and negative modulation of this channel by the tyrosine phosphorylation state provides a plausible mechanism for the control of sperm activity during the early stages of mammalian fertilization.     

Intracellular electrophysiology of mammalian peptidergic neurons in rat hypothalamic slices

The magnocellular neuropeptidergic cells (MNCs) of the paraventricular and supraoptic nuclei have been a model for biochemical and physiological studies of peptidergic neurons in the mammalian brain, but nearly all the electrophysiological studies of these vasopressinergic and oxytocinergic neuroendocrine cells are based on extracellular recordings. This paper reviews recent literature on electrophysiological properties of neurons in the magnocellular nuclei in which the rat in vitro slice preparation and intracellular recording were used. Spontaneously occurring action potentials and synaptic potentials (excitatory and inhibitory) have been observed in hypothalamic slices. The spike patterns have included slow and irregular firing, short rapid bursts of inactivating spikes, and slow phasic discharge with prolonged active and silent periods. Some studies have shown that increased osmolality causes neuronal firing, but this area is controversial. Intracellular injections of lucifer yellow have shown that some MNCs are dye-coupled and electron microscopic observations with the freeze-fracture technique have revealed occasional gap junctions, thus suggesting that some MNCs are electrotonically coupled. Both excitatory and inhibitory postsynaptic potentials have been evoked with extracellular stimulation. Therefore, action potentials, synaptic potentials, burst discharges, and probably electrotonic coupling have been found with intracellular recording in mammalian neuroendocrine cells. Future studies with intracellular recording and staining followed by immunohistochemical identification of cells should provide significant new information on the membrane physiology and synaptic pharmacology of vasopressinergic and oxytocinergic cells.     

Intracellular calcium and extra-retinal photoreception in Aplysia giant neurons

The early or “instantaneous” current-voltage relationship for the light-activated potassium current in Aplysia giant neurons was linear during the first second of illumination. However, the light current was greatly reduced or abolished by prolonged hyperpolarization. It was also greatly reduced by the injection of calcium EGTA buffers having calcium activities of 5.6 × 10^?8 M and simulated by injecting buffers with calcium activities of 2.8–5.6 × 10^?7 M. Removal of calcium from the extracellular fluid had no effect. Both the light-and calcium-activated outward potassium currents were reduced by tetra-ethylammonium (TEA) ions. The light current was not affected by substituting rubidium for potassium nor by substituting either lithium or Tris for sodium. The calcium-activated potassium current persisted when the neuron was cooled to 5°C. However, the light response could no longer be elicited. Light hyperpolarizes Aplysia neurons probably by increasing intracellular calcium activity two-to six-fold which activates a membrane potassium conductance. Calcium levels appear to be restored within the cell and are energy dependent. The light-activated release of calcium is inhibited by cooling. The body wall of Aplysia transmits enough visible or 500-nm light to hyperpolarize some Aplysia giant neurons under ambient conditions. These neurons may be involved in the extraretinal light entrainment that occurs in Aplysia.     

Regional differences in processing of locally translated prohormone in peptidergic neurons of Aplysia californica

Earlier work showed that cell bodies and neurites of the peptidergic bag cell neurons of Aplysia californica contain mRNA for egg-laying hormone. The purpose of the present study was to determine if egg-laying hormone synthesis and prohormone processing is similar in the pleurovisceral connective nerves (containing neurites of bag cell neurons) and the bag cell neuron clusters (containing both cell bodies and neurites of bag cell neurons). Initial experiments confirmed by RT-PCR and sequencing that egg-laying hormone mRNA was present in the pleurovisceral connective nerves. To investigate possible regional differences in translation of mRNA and prohormone processing, clusters were separated from connective nerves and newly synthesized egg-laying hormone-immunoreactive proteins were analyzed. Results showed that synthesis and processing of prohormone occurred in both the clusters and isolated connective nerves; however, the relative abundance of prohormone, processing intermediates, and egg-laying hormone was different. Pulse-chase experiments showed that prohormone was processed more slowly in the connective nerves than in the clusters. These results show that mRNA in isolated neural processes of neuroendocrine cells can be translated, and that the cellular machinery for protein synthesis is present, but processing of the ELH prohormone is significantly compromised.     

Rictor regulates phosphorylation of the novel protein kinase C Apl II in Aplysia sensory neurons

J. Neurochem. (2012) 122, 1108-1117. ABSTRACT: Rapamycin-insensitive companion of TOR (Rictor) is a conserved component of target of rapamycin complex 2 (TORC2), a complex implicated in phosphorylation of a number of signal transduction-related kinases, including protein kinase Cs (PKCs) at their 'hydrophobic' site in the carboxy-terminal extension domain. In the marine mollusk, Aplysia californica, an increase in phosphorylation of the novel PKC, Apl II, at the hydrophobic site is associated with a protein synthesis-dependent increase in synaptic strength seen after continuous application of serotonin. To determine if Rictor plays a role in this increase, we cloned the Aplysia ortholog of Rictor (ApRictor). An siRNA-mediated decrease in ApRictor levels in Aplysia sensory neurons led to a decrease in the phosphorylation of PKC Apl II at the hydrophobic site suggesting a role for ApRictor in hydrophobic site phosphorylation. However, over-expression of ApRictor was not sufficient to increase phosphorylation of PKC Apl II. Continuous application of serotonin increased phosphorylation of PKC Apl II at the hydrophobic site in cultured sensory neurons, and this was blocked by Torin, which inhibits both TORC1 and TORC2. Over-expression of ApRictor did not lead to change in the magnitude of serotonin-mediated phosphorylation, but did lead to a small increase in the membrane localization of phosphorylated PKC Apl II. In conclusion, these studies implicate Rictor in phosphorylation of a novel PKC during synaptic plasticity and suggest an additional role for Rictor in regulating the localization of PKCs.     

Intracellular Ca2+ regulates the sensitivity of cyclic nucleotide-gated channels in olfactory receptor neurons.

In olfactory receptor neurons, odorants stimulate production of cAMP, which directly activates cyclic nucleotide-gated (CNG) channels. Olfactory adaptation is thought to result from a rise in intracellular Ca2+. To determine whether inhibition of CNG channels plays a role in adaptation, we have investigated the action of Ca2+ on these channels in inside-out "macro" patches from the dendrite and cilia of catfish olfactory neurons. Internal Ca2+, with a K1/2 of 3 microM, profoundly inhibits CNG channels by shifting the dose-response relationship to higher cAMP levels without altering the maximal response. The inhibition does not appear to result from a direct interaction of Ca2+ with the CNG channel. Thus, the inhibition washes out after excision of the inside-out patch, and Ca2+ does not inhibit the cloned catfish CNG channel expressed in Xenopus oocytes. Hence we propose that a regulatory Ca(2+)-binding protein, distinct from the CNG channel, controls the gain of signal transduction and contributes to olfactory adaptation by decreasing the sensitivity of the CNG channel to cAMP.     

GABAA receptor phosphorylation and functional modulation in cortical neurons by a protein kinase C-dependent pathway

GABA(A) receptors are critical mediators of fast synaptic inhibition in the brain, and the predominant receptor subtype in the central nervous system is believed to be a pentamer composed of alpha, beta, and gamma subunits. Previous studies on recombinant receptors have shown that protein kinase C (PKC) and PKA directly phosphorylate intracellular serine residues within the receptor beta subunit and modulate receptor function. However, the relevance of this regulation for neuronal receptors remains poorly characterized. To address this critical issue, we have studied phosphorylation and functional modulation of GABA(A) receptors in cultured cortical neurons. Here we show that the neuronal beta3 subunit is basally phosphorylated on serine residues by a PKC-dependent pathway. PKC inhibitors abolish basal phosphorylation, increasing receptor activity, whereas activators of PKC enhance beta3 phosphorylation with a concomitant decrease in receptor activity. PKA activators were shown to increase the phosphorylation of the beta3 subunit only in the presence of PKC inhibitors. We also show that the main sites of phosphorylation within the neuronal beta3 subunit are likely to include Ser-408 and Ser-409, residues that are important for the functional modulation of beta3-containing recombinant receptors. Furthermore, PKC activation did not change the total number of GABA(A) receptors in the plasma membrane, suggesting that the effects of PKC activation are on the gating or conductance of the channel. Together, these results illustrate that cell-signaling pathways that activate PKC may have profound effects on the efficacy of synaptic inhibition by directly modulating GABA(A) receptor function.     

Serotonin induced protein phosphorylation in the Aplysia eye

Serotonin (5-HT) increases the phosphorylation of two low molecular weight phosphoproteins of 23,000 and 15,000 daltons molecular weight and decreases the phosphorylation of a 20,000 dalton phosphoprotein in the isolated Aplysia eye. The cAMP analog 8-benzylthio cAMP increases and decreases the phosphorylation of the 23,000 and 20,000 dalton 5-HT sensitive phosphoproteins, respectively. The effect of 5-HT on protein phosphorylation is not affected by the phase of the circadian rhythm of spontaneous compound action potentials generated in the eye.     

Functional modulation of brain sodium channels by cAMP-dependent phosphorylation.

Voltage-gated Na+ channels, which are responsible for the generation of action potentials in brain, are phosphorylated by cAMP-dependent protein kinase in vitro and in intact neurons. Phosphorylation by cAMP-dependent protein kinase reduces peak Na+ currents 40%--50% in membrane patches excised from rat brain neurons or from CHO cells expressing type IIA Na+ channels. Inhibition of basal cAMP-dependent protein kinase activity by transfection with a plasmid encoding a dominant negative mutant regulatory subunit increases Na+ channel number and activity, indicating that even the basal level of kinase activity is sufficient to reduce Na+ channel activity significantly. Na+ currents in membrane patches from kinase-deficient cells were reduced up to 80% by phosphorylation by cAMP-dependent protein kinase. These effects could be blocked by a specific peptide inhibitor of cAMP-dependent protein kinase and reversed by phosphoprotein phosphatases. Convergent modulation of brain Na+ channels by neurotransmitters acting through the cAMP and protein kinase C signaling pathways may result in associative regulation of electrical activity by different synaptic inputs.     

Charybdotoxin selectively blocks small Ca-activated K channels in Aplysia neurons

The action of charybdotoxin (ChTX), a peptide component isolated from the venom of the scorpion Leiurus quinquestriatus, was investigated on membrane currents of identified neurons from the marine mollusk, Aplysia californica. Macroscopic current recordings showed that the external application of ChTX blocks the Ca-activated K current in a dose- and voltage-dependent manner. The apparent dissociation constant is 30 nM at V = -30 mV and increases e-fold for a +50- to +70-mV change in membrane potential, which indicates that the toxin molecule is sensitive to approximately 35% of the transmembrane electric field. The toxin is bound to the receptor with a 1:1 stoichiometry and its effect is reversible after washout. The toxin also suppresses the membrane leakage conductance and a resting K conductance activated by internal Ca ions. The toxin has no significant effect on the inward Na or Ca currents, the transient K current, or the delayed rectifier K current. Records from Ca-activated K channels revealed a single channel conductance of 35 +/- 5 pS at V = 0 mV in asymmetrical K solution. The channel open probability increased with the internal Ca concentration and with membrane voltage. The K channels were blocked by submillimolar concentrations of tetraethylammonium ions and by nanomolar concentrations of ChTX, but were not blocked by 4-aminopyridine if applied externally on outside-out patches. From the effects of ChTX on K current and on bursting pacemaker activity, it is concluded that the termination of bursts is in part controlled by a Ca-activated K conductance.     

Ionic channels: modulation by G proteins and by phosphorylation.

The gating of ion channels may be modulated by G proteins or by phosphorylation. Direct coupling between G proteins and ion channels has been shown in excised patches of membrane. Steps must now be taken to study the protein domains of G proteins and ion channels involved in the mutual interaction. The concept of channel modulation by protein kinases has recently been extended to include additional types of ion channel.     

Plasma membrane cyclic AMP-dependent protein phosphorylation system in L6 myoblasts.

Plasma membranes can be isolated without disruption of cells by the plasma membrane vesiculation technique (Scott, R.E. (1976) Science 194, 743-745). A major advantage of this technique is that it avoids contamination of plasma membranes with intracellular membrane components. Using this method, we prepared plasma membranes from L6 myoblasts grown in tissue culture and studied the characteristics of the protein phosphorylation system. We found that these plasma membrane preparations contain protein kinase which is tightly bound to the membrane and cannot be removed by washing in EDTA or in high ionic strength salt solutions. This protein kinase activity can catalyze the phosphorylation of several exogenous substrates with decreasing efficiency as acceptors of phosphate: calf thymus histones f2b, protamine and caseine. Cyclic AMP causes a dose-dependent stimulation of protein kinase activity; the highest stimulation (4-fold) is achieved at concentration 10(-5) M cyclic AMP. Cyclic AMP-dependent stimulation can be completely inhibited by heat-stable protein kinase inhibitor isolated from rabbit skeletal muscle. On the other hand, cyclic GMP does not affect the activity of protein kinase. Plasma membrane-bound protein kinase also catalyzes the phosphorylation of endogenous membrane protein substrates and this is also stimulated by addition of cyclic AMP. Analysis of plasma membrane proteins by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis showed that specific polypeptides are phosphorylated by cyclic AMP-independent and by cyclic AMP-dependent protein kinase systems. The results of these studies demonstrate the presence of endogenous cyclic AMP-dependent and -independent protein phosphorylating systems (enzyme activity and substrates) in purified plasma membrane preparations. These data provide a basis for further investigations on the role of plasma membrane phosphorylation as a regulator of membrane functions including those that may control cellular differentiation.     

Ethanol induced alterations in plasma membrane protein phosphorylation of neurons and astrocytes

The endogenous protein phosphorylation patterns in plasma membranes of bulk isolated neurons and astroglia from control and chronic ethanol treated rats have been investigated. Chronic ethanol treatment resulted in increased phosphorylation of specific proteins with molecular weights 116, 63 and 60 kDa in both neurons and astrocytes. These proteins were further resolved by 2-DE and the analysis suggested an increased phosphorylation of 10–15 proteins, of which 116 kDa protein is phosphorylated to a higher extent by ethanol. Further, decreased phosphorylation was noticed in D-95 and D-63 proteins in neurons and D-78 and D-54 proteins in astrocytes. Alkali stability experiments for identifying the phosphoamino acid involved in phosphorylation of 116, 63 and 60 kDa proteins suggested that tyrosine and threonine are not involved and probably serine is the likely site for phosphorylation during chronic ethanol treatment. The phosphorylation of specific membrane proteins during chronic ethanol treatment might contribute to ethanol evoked cellular dysfunction.     

Cholesterol-dependent modulation of tau phosphorylation in cultured neurons

One of the hallmarks of Alzheimer's disease (AD) is the abnormal state of tau. It is both highly phosphorylated and aggregated into paired helical filaments (PHFs) in neurofibrillary tangles (NFTs). However, the mechanism underlying the hyperphosphorylation of tau in NFTs and neuronal degeneration in AD remains to be elucidated. The fact that hyperphosphorylation of tau in NFTs are also found in the patients with Niemann-Pick disease, type C (NPC), which is a cholesterol storage disease associated with defective intracellular trafficking of exogenous cholesterol, implies that perturbation of cholesterol metabolism may be involved in tau phosphorylation and neurodegeneration. Here, we report that cholesterol deficiency induced by inhibition of cholesterol biosynthesis in cultured neurons results in hyperphosphorylation of tau, accompanied by axonal degeneration associated with microtubule depolymerization. These changes were prevented by concurrent treatment with beta-migrating very low-density lipoprotein (beta-VLDL) or cholesterol. We propose that intracellular cholesterol plays an essential role in the modulation of tau phosphorylation and the maintenance of microtubule stability.     

Regulation of ion channels by protein tyrosine phosphorylation

Ion channels are regulated by protein phosphorylation and dephosphorylation of serine, threonine, and tyrosine residues. Evidence for the latter process, tyrosine phosphorylation, has increased substantially since this topic was last reviewed. In this review, we present a comprehensive summary and synthesis of the literature regarding the mechanism and function of ion channel regulation by protein tyrosine kinases and phosphatases. Coverage includes the majority of voltage-gated, ligand-gated, and second messenger-gated channels as well as several types of channels that have not yet been cloned, including store-operated Ca2+ channels, nonselective cation channels, and epithelial Na+ and Cl- channels. Additionally, we discuss the critical roles that channel-associated scaffolding proteins may play in localizing protein tyrosine kinases and phosphatases to the vicinity of ion channels.     

Kv4.2 phosphorylation by cyclic AMP-dependent protein kinase

Recent evidence suggests that K(+) channels composed of Kv4.2 alpha-subunits underlie a transient current in hippocampal CA1 neurons and ventricular myocytes, and activation of the cAMP second messenger cascade has been shown to modulate this transient current. We determined if Kv4.2 alpha-subunits were directly phosphorylated by cAMP-dependent protein kinase (PKA). The intracellular domains of the amino and carboxyl termini of Kv4.2 were expressed as glutathione S-transferase fusion protein constructs; we observed that both of these fusion proteins were substrates for PKA in vitro. By using phosphopeptide mapping and amino acid sequencing, we identified PKA phosphorylation sites on the amino- and carboxyl-terminal fusion proteins corresponding to Thr(38) and Ser(552), respectively, within the Kv4.2 sequence. Kinetic characterization of the PKA sites demonstrated phosphorylation kinetics comparable to Kemptide. To evaluate PKA site phosphorylation in situ, phospho-selective antisera for each of the sites were generated. By using COS-7 cells expressing an EGFP-Kv4.2 fusion protein, we observed that stimulation of the endogenous PKA cascade resulted in an increase in phosphorylation of Thr(38) and Ser(552) within Kv4.2 in the intact cell. We also observed modulation of PKA phosphorylation at these sites within Kv4.2 in hippocampal area CA1. These results provide insight into likely sites of regulation of Kv4.2 by PKA.