[Autism spectrum disorders and bisphenol A: Is serotonin the lacking link in the chain?] / Les relations entre le bisphénol A et les troubles du spectre autistique se précisent : la sérotonine est-elle le lien manquant ?

The etiology of autism spectrum disorders (ASD) is believed to be multifactorial and to involve genetic and environmental components. Environmental chemical exposures are increasingly understood to be important in causing neurotoxicity in fetuses and newborns. Recent data from the Centers for Disease Control and Prevention in the United States suggest a substantial increase in ASD prevalence, only partly explicable by factors such as diagnostic substitution. Bisphenol A (BPA) is an ubiquitous xenoestrogen widely employed in a variety of consumer products including plastic and metal food and beverage containers, dental sealants and fillings, medical equipment and thermal receipts. Therefore, most people are exposed almost continuously to BPA in industrialized countries. Sources of BPA exposure are predominantly diet, but also through inhalation or dermal absorption. BPA can be measured in many human fluids and tissues including saliva, serum, urine, amniotic fluid, follicular fluid, placental tissue and breast milk. There is concern that BPA exposure may influence human brain development and may contribute to the increasing prevalence of neurodevelopmental and behavioural problems. Epigenetic mechanisms are suggested by a mouse study that demonstrated that BPA exposure during gestation had long lasting, transgenerational effects on social recognition. Previous epidemiological studies suggested a relationship between maternal BPA exposure and ASD. A recent study of 46 children with ASD and 52 controls found for the first time a direct association between children with ASD and BPA exposure and demonstrated that BPA is not metabolized well in children with ASD. The metabolomic analyses showed a correlation between ASD and essential amino acid metabolism pathways. Essential amino acids are precursors of neurotransmitters, for example tryptophan for serotonin. Fetal and prenatal BPA exposure was suggested to perturb the serotonergic system in rat and mice models. On the other hand, hyperserotonemia was reported in approximately one-third of autistic patients and also in relatives. Moreover, neuroimaging studies revealed two fundamentally different types of serotonin synthesis abnormality in children with autism compared to age-matched nonautistic children, a difference in whole-brain capacity and focal abnormalities. Finally, decreased serotonin transporter and serotonin receptor binding have been reported in both children and adults with autism. So, the link between BPA and autism could be a defect of the normal in utero or perinatal serotonergic system development. In France, BPA was banned in baby bottles in 2010 and in any food or beverage packaging since January 2015. Therefore, there is an urgent need to find safe alternatives in the use of BPA in the manufacture of industrial products.

[Gap junctions: A new therapeutic target in major depressive disorder?]. / Les jonctions gap: une nouvelle cible thérapeutique pour le traitement des troubles dépressifs majeurs?

Major depressive disorder is a multifactorial chronic and debilitating mood disease with high lifetime prevalence and is associated with excess mortality, especially from cardiovascular diseases and through suicide. The treatments of this disease with tricyclic antidepressants and monoamine oxidase inhibitors are poorly tolerated and those that selectively target serotonin and norepinephrine re-uptake are not effective in all patients, showing the need to find new therapeutic targets. Post-mortem studies of brains from patients with major depressive disorders described a reduced expression of the gap junction-forming membrane proteins connexin 30 and connexin 43 in the prefrontal cortex and the locus coeruleus. The use of chronic unpredictable stress, a rodent model of depression, suggests that astrocytic gap junction dysfunction contributes to the pathophysiology of major depressive disorder. Chronic treatments of rats with fluoxetine and of rat cultured cortical astrocytes with amitriptyline support the hypothesis that the upregulation of gap junctional intercellular communication between brain astrocytes could be a novel mechanism for the therapeutic effect of antidepressants. In conclusion, astrocytic gap junctions are emerging as a new potential therapeutic target for the treatment of patients with major depressive disorder.

Serotonin and cancer: what is the link?

Serotonin (5-hydroxytryptamine, 5-HT) is a biogenic monoamine that acts as a neurotransmitter in the central nervous system, local mediator in the gut and vasoactive agent in the blood. Serotonin exerts its multiple, sometimes opposing actions through interaction with a multiplicity of receptors coupled to various signalling pathways. In addition to its well-known functions, serotonin has been shown to be a mitogenic factor for a wide range of normal and tumoral cells. Serotonin exhibits a growth stimulatory effect in aggressive cancers and carcinoids more often through 5- HT1 and 5-HT2 receptors. In contrast, low doses of serotonin can inhibit tumour growth via the decrease of blood supply to the tumour, suggesting that the role of serotonin on tumour growth is concentration-dependent. Data are also available on serotonin involvement in cancer cell migration, metastatic processes and as a mediator of angiogenesis. Moreover, the progression of some tumours is accompanied by a dysregulation of the pattern of serotonin receptor expressions. Serum serotonin level was found to be suitable for prognosis evaluation of urothelial carcinoma in the urinary bladder, adenocarcinoma of the prostate and renal cell carcinoma. In some cases, antagonists of serotonin receptors, inhibitors of selective serotonin transporter and of serotonin synthesis have been successfully used to prevent cancer cell growth. This review revaluates serotonin involvement in several types of cancer and at different stages of their progression.

[Gap junctional intercellular communication: a new mechanism in pathophysiology of migraine with aura. Therapeutic applications]. / La communication intercellulaire par l'intermédiaire des jonctions gap: un nouveau mécanisme dans la physiopathologie de la migraine avec aura. Applications thérapeutiques.

Migraine is a common, recurrent and disabling primary headache disorder, which affects up to 20% of the population. About a third of patients with migraine have attacks with aura, a focal neurological disturbance that manifests itself as visual, sensitive or motor symptoms. Cortical spreading depression, a wave of electrical activity that moves across the cerebral cortex through neuronal-glial cell gap junctions, would be involved in the triggering of migraine aura. Moreover, cortical spreading depression activates perivascular trigeminal afferents in the neocortex, that through central and peripheral reflex, cause inflammatory reaction in the meninges to generate the headache. Tonabersat, a novel benzopyran compound, was selected for clinical trial on the basis of its inhibitory activity on cortical spreading depression and neurogenic inflammation in animal models of migraine. Moreover, tonabersat inhibited trigeminal ganglion neuronal-glial cell gap junctions, suggesting that this compound could prevent peripheral sensitization within the ganglion. In clinical trial, tonabersat showed a preventive effect on attacks of migraine with aura but had no efficacy on non-aura attacks and in the acute treatment of migraine. In conclusion, neuronal-glial cell gap junctional intercellular communication seems to be involved in the pathophysiology of migraine with aura and is emerging as a new promising therapeutic target for prophylactic treatment of patients with chronic attacks.

[Connexins and junctional channels. Roles in the spreading of cardiac electrical excitation and heart development]. / Connexines et canaux jonctionnels. Leurs rôles dans la propagation de l'activité électrique cardiaque et le développement du coeur.

The electrical activity in heart is generated in the sinoatrial node and then propagates to the atrial and ventricular tissues. The junctional channels that couple the cardiomyocytes are responsible for this propagation process. These channels are dodecamers of transmembrane proteins of the connexin (Cx) family. Four Cxs - Cx30.2, -40, -43 and -45--have been demonstrated to be synthesized in the cardiomyocytes. In addition, each of these Cxs has a unique expression pattern in the myocardium. A fruitful approach of the role of these Cxs in the cardiac functions came with the development of transgenic mouse models. It has been shown that Cx43 was mainly involved in influx propagation in the ventricles and that inactivation in the cardiomyocytes of the gene of this Cx predisposed to development of cardiac abnormalities. Cx40 very significantly contributes to the propagation of electrical activity in the atria and the conduction system. Cx45 is essential to coordinate the synchronization of contractile activities of embryonic cardiomyocytes and for the normal progress of cardiogenesis. Finally, Cx30.2 contributes to the slowing of propagation of excitation in the atrioventricular node. These observations enable to better understand the relationships between alteration in Cx expression or gap junction remodelling and arrhythmias in the human heart.

Spinophilin: from partners to functions.

Spinophilin/neurabin 2 has been isolated independently by two laboratories as a protein interacting with protein phosphatase 1 (PP1) and F-actin. Gene analysis and biochemical approaches have contributed to define a number of distinct modular domains in spinophilin that govern protein-protein interactions such as two F-actin-, three potential Src homology 3 (SH3)-, a receptor- and a PP1-binding domains, a PSD95/DLG/zo-1 (PDZ) and three coiled-coil domains, and a potential leucine/isoleucine zipper (LIZ) motif. More than 30 partner proteins of spinophilin have been discovered, including cytoskeletal and cell adhesion molecules, enzymes, guanine nucleotide exchange factors (GEF) and regulator of G-protein signalling protein, membrane receptors, ion channels and others proteins like the tumour suppressor ARF. The physiological relevance of some of these interactions remains to be demonstrated. However, spinophilin structure suggests that the protein is a multifunctional protein scaffold that regulates both membrane and cytoskeletal functions. Spinophilin plays important functions in the nervous system where it is implicated in spine morphology and density regulation, synaptic plasticity and neuronal migration. Spinophilin regulates also seven-transmembrane receptor signalling and may provide a link between some of these receptors and intracellular mitogenic signalling events dependent on p70(S6) kinase and Rac G protein-GEF. Strikingly a role for spinophilin in cell growth was demonstrated and this effect was enhanced by its interaction with ARF. Here we review the current knowledge of the protein partners of spinophilin and present the available data that are contributing to the appreciation of spinophilin functions.

Connexin-made channels as pharmacological targets.

Gap junctions are clusters of intercellular channels that provide morphological support for direct diffusion of ions and low-molecular-weight molecules between adjacent coupled cells. Each gap junction channel is made by docking of two hemichannels or connexons, each formed by assembly of six proteins (connexins). 21 members of the connexin gene family are likely to be expressed in the human genome. These ubiquitous gated channels, allowing rapid intercellular communication and synchronisation of coupled cell activities, play critical roles in many signalling processes, including co-ordinated cardiac and smooth muscle contractions, neuronal excitability, neurotransmitter release, insulin secretion, epithelial electrolyte transport, etc. Mutational alterations in the connexin genes are associated with the occurrence of multiple pathologies, such as peripheral neuropathies, cardiovascular diseases, dermatological diseases, hereditary deafness and cataract. But the neuro- and cardioprotective effects of blocking agents of junctional channels show that closure of these channels may also be beneficial in certain pathological situations. Consequently, modulation of gap junctional intercellular communication is a potential pharmacological target. In contrast to most other membrane channels, no natural toxin or specific inhibitor of junctional channels has been identified yet and most uncoupling agents generally also affect other ionic channels and receptors. Future research, based for example on the recent developments in genetics, may clarify gap junction physiology. This will in turn provide promising perspectives for the development of targeted drugs.

Immunoglobulin D enhances interleukin-6 release from the KU812 human prebasophil cell line.

Despite the role of secreted immunoglobulin D (IgD) remains still largely unknown, previous studies have suggested that secreted IgD could induce basophils degranulation in some allergic asthma patients. In the present study we have searched direct evidence of the action of IgD on KU812 cells, generally classified as an immature basophilic cell line. We analyzed by flow cytometry the capacity of IgD, purified from IgD myeloma sera, to bind KU812 cells. Biotinylated monomeric IgD (mIgD) and biotinylated oligomeric IgD (oIgD) could bind KU812 cells. Blocking experiments with others immunoglobulin isotypes showed that KU812 cells expressed an unspecific receptor for IgD. However, oIgD but not mIgD enhances the release of interleukin-6 (IL-6) from KU812 cells. On the other hand, mIgD and oIgD failed to induce histamine release from KU812 cells or from cord blood derived basophils. Since IL-6 is known to induce basophil differentiation, we proposed that IgD could be implicated in allergic disorders by stimulating IL-6 release by prebasophil cells, then IL-6 could further induce an autocrine maturation of the cells.

Endogenous protein phosphatase 1 runs down gap junctional communication of rat ventricular myocytes.

Gap junctional channels are essential for normal cardiac impulse propagation. In ventricular myocytes of newborn rats, channel opening requires the presence of ATP to allow protein kinase activities; otherwise, channels are rapidly deactivated by the action of endogenous protein phosphatases (PPs). The lack of influence of Mg(2+) and of selective PP2B inhibition is not in favor of the involvements of Mg(2+)-dependent PP2C and PP2B, respectively, in the loss of channel activity. Okadaic acid (1 microM) and calyculin A (100 nM), both inhibitors of PP1 and PP2A activities, significantly retarded the loss of channel activity. However, a better preservation was obtained in the presence of selective PP1 inhibitors heparin (100 microg/ml) or protein phosphatase inhibitor 2 (I2; 100 nM). Conversely, the stimulation of endogenous PP1 activity by p-nitrophenyl phosphate, in the presence of ATP, led to a progressive fading of junctional currents unless I2 was simultaneously added. Together, these results suggest that a basal phosphorylation-dephosphorylation turnover regulates gap junctional communication which is rapidly deactivated by PP1 activity when the phosphorylation pathway is hindered.

Nongenomic steroid action: Inhibiting effects on cell-to-cell communication between rat ventricular myocytes.

Numerous steroids are now believed to possess rapid membrane effects independent of the classical gene activation pathways and are potent modulators of membrane proteins, including voltage-and ligand-operated channels. The effects of steroids on the functional state of the intercellular channels clustered in gap junctions were compared by estimation of either the permeability for a fluorescent dye or the electrical conductance in cardiac myocytes of newborn rat. At 25 muM, the esters of 17beta-estradiol, testosterone and two other androgen hormones rapidly abolished cell-to-cell communication, whereas none of the longer chain steroids, belonging to pregnane (17alpha-hydroxypregnenolone, hydrocortisone), sterol (cholesterol, 25-hydroxycholesterol), bile acid (cholic and lithocholic acids) and vitamin (D3) families, lowered the junctional permeability. Altogether, no correlation with the presence or position of double bonds nor with the trans- or cis-fusion of the A and B rings was recognized. Esterification was a prerequisite for the activity of extracellularly applied steroids but the number, nature and position of ester chain(s) had no influence. 17beta-estradiol or testosterone effects were not prevented when cells were prein-cubated with blockers of the estrogen or androgen nuclear receptors (tamoxifen and cyproterone acetate, respectively). This, together with the rapid time course of the steroid effect (complete within a few minutes), in a rather high active concentration range, suggests a nongenomic mechanism of action. The reversible uncoupling effect of steroids appears to be independent of the shape of the molecules and more probably related to their size and lipo-solubility, which condition their insertion into the lipid bilayer and their subsequent disturbing effects.

Dephosphorylation agents depress gap junctional communication between rat cardiac cells without modifying the Connexin43 phosphorylation degree.

The functional state of gap junctional channels and the phosphorylation status of Connexine43 (Cx43), the major gap junctional protein in rat heart, were evaluated in primary cultures of neonatal rat cardiomyocytes. H7, able to inhibit a range of serine/threonine protein kinases, progressively reduced gap junctional conductance to approximately 13% of its initial value within 10 min except when protein phosphatase inhibitors were also present. The dephosphorylating agent 2,3-Butanedione monoxime (BDM) produced both a quick and reversible interruption of cell-to-cell communication as well as a parallel slow inhibition of junctional currents. The introduction of a non-hydrolysable ATP analogue (ATPgammaS) in the cytosol delayed the second component, suggesting that it was the consequence of protein dephosphorylation. Western blot analysis reveals 2 forms of Cx43 with different electrophoretic mobilities which correspond to its known phosphorylated and dephosphorylated forms. After exposure of the cells to H7 (1 mmol/l, 1h) or BDM (15 mmol/l, 15 min), no modification in the level of Cx43 phosphorylation was observed. The lack of direct correlation between the inhibition of cell-to-cell communication and changes in the phosphorylation status of Cx43 suggest that the functional state of junctional channels might rather be determined by regulatory proteins associated to Cx43.

Development of substituted Benzo[c]quinolizinium compounds as novel activators of the cystic fibrosis chloride channel.

Chloride channels play an important role in the physiology and pathophysiology of epithelia, but their pharmacology is still poorly developed. We have chemically synthesized a series of substituted benzo[c]quinolizinium (MPB) compounds. Among them, 6-hydroxy-7-chlorobenzo[c]quinolizinium (MPB-27) and 6-hydroxy-10-chlorobenzo[c]quinolizinium (MPB-07), which we show to be potent and selective activators of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel. We examined the effect of MPB compounds on the activity of CFTR channels in a variety of established epithelial and nonepithelial cell systems. Using the iodide efflux technique, we show that MPB compounds activate CFTR chloride channels in Chinese hamster ovary (CHO) cells stably expressing CFTR but not in CHO cells lacking CFTR. Single and whole cell patch clamp recordings from CHO cells confirm that CFTR is the only channel activated by the drugs. Ussing chamber experiments reveal that the apical addition of MPB to human nasal epithelial cells produces a large increase of the short circuit current. This current can be totally inhibited by glibenclamide. Whole cell experiments performed on native respiratory cells isolated from wild type and CF null mice also show that MPB compounds specifically activate CFTR channels. The activation of CFTR by MPB compounds was glibenclamide-sensitive and 4, 4'-diisothiocyanostilbene-2,2'-disulfonic acid-insensitive. In the human tracheal gland cell line MM39, MPB drugs activate CFTR channels and stimulate the secretion of the antibacterial secretory leukoproteinase inhibitor. In submandibular acinar cells, MPB compounds slightly stimulate CFTR-mediated submandibular mucin secretion without changing intracellular cAMP and ATP levels. Similarly, in CHO cells MPB compounds have no effect on the intracellular levels of cAMP and ATP or on the activity of various protein phosphatases (PP1, PP2A, PP2C, or alkaline phosphatase). Our results provide evidence that substituted benzo[c]quinolizinium compounds are a novel family of activators of CFTR and of CFTR-mediated protein secretion and therefore represent a new tool to study CFTR-mediated chloride and secretory functions in epithelial tissues.

Dissecting subdomains involved in multiple functions of the CK2beta subunit.

We have characterized several subdomains of the beta subunit of protein kinase CK2. The N-terminal half of the protein exhibits a pseudo-substrate segment in tandem with a polyamine binding domain responsible for the activation of the kinase by these polybasic compounds. Study of the chemical features of this polyamine binding site showed that polyamine analogs exhibiting the highest affinity for CK2 are the best CK2 activators. Mutational analysis disclosed that glutamic residues lying in the polyacidic region of the CK2beta subunit are involved in the interaction with polyamine molecules and allowed the delineation of an autonomous binding domain. Furthermore, this regulatory domain was shown to mediate the association of CK2 with plasma membrane. The C-terminal domain of the CK2beta subunit plays a role in the oligomerization of the kinase since it was observed that a truncated form of this subunit lacking its 33-last amino acids was incompetent for the assembly of polymeric forms of CK2. Altogether, our results support the notion that the beta subunit of CK2 is a modular protein made by the association of interdependent domains that are involved in its multiple functions.

ATP counteracts the rundown of gap junctional channels of rat ventricular myocytes by promoting protein phosphorylation.

1. The degree of cell-to-cell coupling between ventricular myocytes of neonatal rats appeared well preserved when studied in the perforated version of the patch clamp technique or, in double whole-cell conditions, when ATP was present in the patch pipette solution. In contrast, when ATP was omitted, the amplitude of junctional current rapidly declined (rundown). 2. To examine the mechanism(s) of ATP action, an 'internal perfusion technique' was adapted to dual patch clamp conditions, and reintroduction of ATP partially reversed the rundown of junctional channels. 3. Cell-to-cell communication was not preserved by a non-hydrolysable ATP analogue (5'-adenylimidodiphosphate, AMP-PNP), indicating that the effect most probably did not involve direct interaction of ATP with the channel-forming proteins. 4. An ATP analogue supporting protein phosphorylation but not active transport processes (adenosine 5'-O-(3-thiotriphosphate), ATPgammaS) maintained normal intercellular communication, suggesting that the effect was due to kinase activity rather than to altered intracellular Ca2+. 5. A broad spectrum inhibitor of endogenous serine/threonine protein kinases (H7) reversibly reduced the intercellular coupling. A non-specific exogenous protein phosphatase (alkaline phosphatase) mimicked the effects of ATP deprivation. The non-specific inhibition of endogenous protein phosphatases resulted in the preservation of substantial cell-to-cell communication in ATP-free conditions. 6. The activity of gap junctional channels appears to require both the presence of ATP and protein kinase activity to counteract the tonic activity of endogenous phosphatase(s).

The tight association of protein kinase CK2 with plasma membranes is mediated by a specific domain of its regulatory beta-subunit.

Previous immunocytochemical studies have shown that protein kinase CK2 is mostly detected both in the cytoplasm and the nucleus of most cells. In the present study, CK2 was detected in highly purified plasma membrane preparations from rat liver. The protein kinase could be released from the membranes by high salt extraction (>1 M NaCl). Plasma membranes prepared from SF9 insect cells expressing the alpha- and beta-subunits of CK2 also contained a significant amount of oligomeric CK2. Furthermore, it was demonstrated in this cell system as well as in rat liver plasma membranes, that the beta-subunit of the kinase is the targeting subunit which mediates the tight association of the enzyme to plasma membrane components. Binding studies using membranes and recombinant proteins corresponding to different regions of the beta-subunit suggest that a functional domain previously shown to be involved in the binding of polyamines may also participate to the binding of CK2 to membranes. Modification of membranes by trypsin and phospholipases indicated that the binding process may require both membrane protein(s) and phospholipids. Interestingly, it was observed that the amount of membrane-bound CK2 in liver of embryos and new born rats increases dramatically after birth and persists during the postnatal stages of development.

Preincubation of human resting T cell clones with interleukin 10 strongly enhances their ability to produce cytokines after stimulation.

Interleukin 10 (IL-10) has been described as a cytokine inhibitory factor downregulating IL-2 secretion and inducing T cell anergy. The data reported in this study show that preincubation of resting T cells from the human CD4+ clone SP-B21 (and clone TA-23.6) with IL-10 strongly enhances their capacity to further produce IL-2, interferon gamma (IFN-gamma), IL-4 and tumour necrosis factor alpha (TNF-alpha) after subsequent activation. In contrast, when IL-10 was added during the activation step, the previously reported specific inhibition of IL-2 synthesis was observed. Flow cytometric analysis of intracellular IL-2- and IL-4-producing cells revealed that preincubation with IL-10 increased the number of cytokine-producing cells, but did not affect their individual ability to produce these cytokines. We further show that IL-10 plays a dose-dependent role of viability maintenance factor. This effect relates to a direct anti-apoptotic effect of IL-10, which is likely independent of the expression of bcl-2, bcl-x and fas. Such paradoxal properties of IL-10 on T cells should be considered when aiming at using IL-10 as an immunosuppressive molecule in the treatment of diseases.

Inhibitions of protein kinases and protein phosphatases have opposite effects on thyrotropin-stimulated cAMP accumulation in human thyroid cells.

We investigated the effects of inhibitions of protein phosphatases and protein kinases on thyrotropin (TSH) stimulation of cAMP accumulation in human thyroid cells. Okadaic acid (OA) and calyculin-A (CL-A), two potent inhibitors of type-1 (PP-1) and type-2A (PP-2A) protein phosphatases, had a biphasic concentration-dependent response on cAMP formation. An inhibitory effect (41.3% and 47.2% inhibition with OA and CL-A) was first observed at 1 microM OA and 10 nM CL-A, followed by a reduction of this effect with OA (24% inhibition) or by a complete reversal of inhibition with CL-A, at 10-fold higher concentrations of both products. Addition of purified PP-1 and PP-2A to crude membranes from cells preincubated with OA, reversed OA-induced adenylyl cyclase inhibition, confirming that these protein phosphatases regulate TSH-mediated cAMP production. Levels of protein incorporation of 32P were higher with 10 microM OA than with 1 microM OA and did not correlate with the biphasic effect of OA on cAMP production. These results support a dual action of protein phosphorylation in the control of adenylyl cyclase activity stimulated by TSH. H-7, an inhibitor of nucleotide- and calcium/phospholipid-dependent protein kinase (PKC), increased by 197% the stimulation of cAMP accumulation by TSH in thyroid cells. Phorbol 12-myristate 13-acetate (PMA) counteracted the effect of H-7 on cAMP levels, which suggests that PKC is involved in the action of H-7. Moreover, KT5926, an inhibitor of calcium/calmodulin-dependent protein kinase II and myosin light chain kinase, increased basal cAMP levels rather than cAMP levels stimulated by TSH. In light of these results, we suggest that phosphorylation/dephosphorylation cycles regulate basal and TSH-stimulated adenylyl cyclase activities in human thyroid.

Evidence of true protein kinase CKII activity in mitochondria and its spermine-mediated translocation to inner membrane.

A true protein kinase CKII (CKII) activity was characterized in liver mitochondria by its phosphorylating activity on the specific peptide substrate of CKII, the binding and elution profile of the enzyme on a phosphocellulose column and immunostaining of a 36 kDa polypeptide with antibodies against the alpha-subunit of human CKII. This CKII activity was located predominantly in the intermembrane space of quiescent mitochondria. A translocation of the enzyme to inner membrane of energized mitochondria occurred in the presence of spermine. Translocated CKII activity was tightly bound to inner membrane, and high salt concentrations were necessary to release the activity. The inner face of the inner membrane could constitute the in vivo localization of mitochondrial CKII since the potential substrates of the enzyme are 4 matrix proteins.

Specificity of rat liver plasma membrane serine/threonine protein kinases and phosphatases over endogenous proteins.

The specificity of rat liver plasma membrane protein kinases and phosphatases was examined over endogenous substrates, using specific effectors of these enzymes. cAMP-dependent protein kinase was shown to phosphorylate the 77, 60 and 51 kDa phosphoproteins and type II casein kinase, a specific 24 kDa one. On the contrary, types 1 and 2A protein phosphatases seemed to have a broad specificity in plasma membranes. An analysis of the phosphoprotein pattern based on the endogenous substrates of plasma membrane enzymes was deduced from these and other results from our laboratory. The specificity of some enzymes might arise from the anchorage in plasma membrane which might restrict their activity to their immediate environment.

Stabilization of phospho-intermediates of rat liver plasma membrane alkaline phosphatase by uncompetitive inhibition. Relation with phosphate uptake into hepatocytes.

Rat liver plasma membrane alkaline phosphatase (ALP) phospho-intermediates, which have molecular masses of 151 and 135 kDa bands, were labelled at physiological pH with either (gamma-32P) ATP or 32Pi. This labeling was stabilized by a potent enzyme inhibitor, bromolevamisole (BL), and not by bromodexamisole (BD). BL augmented the rate and extent of autophosphorylation and slowed down the rate of autodephosphorylation of ALP. The phospho-intermediates labeling presented nearly the same kinetic behaviour with either (gamma-32P) ATP or 32Pi. In the presence of BL a marked decrease of the phosphorylation state of many proteins was observed in hepatocytes. BL also produced a decrease of the 32Pi uptake into hepatocytes and a decrease of the specific radioactivity of cellular ATP. BD had nearly the same effect as BL on protein phosphorylation and 32Pi uptake. These results argued against a direct involvement of ALP in Pi transport across hepatocyte plasma membrane.