cAMP-independent casein kinase mediates phosphorylation of many T3-dependent phosphoproteins in rat liver cytosol

Administration of T3 (20 micrograms/100 g BW) for 3 days increases phosphorylation of several proteins in rat liver cytosol in vitro. To help elucidate the mechanism of T3-induced phosphorylation, we studied which protein kinase(s) mediate phosphorylation of endogenous cytosolic proteins. Five different protein kinases were obtained by DEAE+ cellulose column chromatographic fractionation of liver cytosol. When their ability to phosphorylate heat-inactivated cytosol was investigated, casein kinase, a cAMP independent protein kinase, showed the strongest effect. Casein kinase, purified by phosphocellulose chromatography, phosphorylated more than 10 cytosolic proteins. Several T3-dependent (and cAMP independent) phosphoproteins were included among these. One protein with Mr 39 X 10(3), of which phosphorylation is stimulated by T3 within five hours after injection, was the most active substrate for casein kinase. The results suggest that casein kinase is the enzyme responsible for phosphorylation of many rat liver cytosolic proteins and that several phosphoproteins, apparently under T3-regulation, might be phosphorylated by this enzyme.     

Characterization of protein phosphokinase activities in horse thyroid nuclei.

The distribution of protein phosphokinase (EC 2.7.1.37) activities has been established in horse thyroid nuclei. The presence of several enzyme activities has been demonstrated, two of which are clearly distinct. The first one acts on histone as substrate and is activated by cyclic AMP. Physico-chemical properties of this nuclear cyclic AMP-dependent histone kinase and of the cytosol histone kinase are different, demonstrating the absence of a contamination from the cytosol. The second enzyme acts on casein as substrate and is not stimulated by cyclic AMP POR CYCLIC GMP. The findings are consistent with the observation of thyrotropin stimulation of histone phosphorylation in thyroid nuclei.     

Clathrin-coated vesicles contain two protein kinase activities. Phosphorylation of clathrin beta-light chain by casein kinase II

Incubation of clathrin-coated vesicles with Mg2+-[gamma-32P]ATP results in the autophosphorylation of a 50-kDa polypeptide (pp50) (Pauloin, A., Bernier, I., and Jollès, P. (1982) Nature 298, 574-576). We describe here a second protein kinase that is associated with calf brain and liver coated vesicles. This kinase, which phosphorylates casein and phosvitin but not histone and protamine using either ATP or GTP, co-fractionates with coated vesicles as assayed by gel filtration, electrophoresis, and sedimentation. The enzyme can be extracted with 0.5 M Tris-HCl or 1 M NaCl, and can be separated from the pp50 kinase as well as the other major coat proteins. We identified this enzyme as casein kinase II based on physical and catalytic properties and by comparative studies with casein kinase II isolated from brain cytosol. It has a Stokes radius of 4.5 nm, a catalytic moiety of approximately 45 kDa, and labels a polypeptide of 26 kDa when the pure enzyme is assayed for autophosphorylation. Its activity is inhibited by heparin and not affected by cAMP, phospholipids, or calmodulin. This protein kinase preferentially phosphorylates clathrin beta-light chain. The phosphorylation is markedly stimulated by polylysine and inhibited by heparin. Isolated beta-light chain as well as beta-light chain in triskelions or in intact coated vesicles is phosphorylated. All of the phosphate (0.86 mol of Pi/mol of clathrin beta-light chain) is incorporated into phosphoserine.     

A cAMP-binding phosphoprotein in Drosophila heads is similar to the regulatory subunit of the mammalian type II cAMP-dependent protein kinase

Cyclic AMP (cAMP)-dependent regulation of in vitro phosphorylation of several proteins including a cAMP-binding protein was studied with crude membrane and cytosol fractions from Drosophila heads. Phosphorylation of at least seven distinct proteins was enhanced in the presence of cAMP. Interestingly, however, the phosphorylation of a 56 kDa protein was apparently reduced by cAMP in the membrane but not in the cytosol fraction. The following data strongly indicate that the 56 kDa phosphoprotein in both membrane and cytosol fractions is a cAMP-binding protein, very similar to the regulatory subunit (RII) of a mammalian cAMP-dependent protein kinase, and that its binding to cAMP makes this protein very susceptible to the action of phosphatases: (i) cAMP highly stimulated the dephosphorylation of the 56 kDa phosphoprotein by the endogenous phosphatase in the membrane fraction. (ii) The dephosphorylation of a similar 56 kDa phosphoprotein in the cytosol fraction by an exogenous, cAMP-independent, alkaline phosphatase was also highly stimulated by cAMP. (iii) The 56 kDa phosphoprotein was covalently bound to cAMP by u.v. irradiation. (iv) The alkaline-phosphatase treatment reversibly converted this phosphoprotein to a 53 kDa non-phosphorylated protein. (v) The 53 kDa protein was selectively bound to cAMP-agarose and subsequently eluted by cAMP and high salt. (vi) This protein served as a substrate for the catalytic subunit of a mammalian cAMP-dependent protein kinase.     

Mechanism of activation of cyclic GMP-dependent protein kinase from rat liver by multiple modulators

A number of polyanionic compounds, including DNA, RNA and polyglutamate, were shown to exhibit protein kinase stimulatory modulator activity as they were required for cyclic GMP to stimulate the phosphorylation of various cationic substrates by rat liver cyclic GMP-dependent protein kinase. Anionic proteins (casein, phosvitin) were phosphorylated poorly by the enzyme and their phosphorylation was not stimulated by the stimulatory modulators. Studies of the mechanism of action suggest that the modulators interact directly with the substrates to form a complex which is a better substrate than free histone. The observed effect of modulator is complex as it depends on the ratio of modulator to histone and the resultant state of the complex formed (better or poorer substrate than free histone). The observed effect is also dependent on the properties of the histone substrate as Michaelis-Menten kinetics are not observed in the phosphorylation of arginine-rich histone in the absence or presence of cyclic GMP.     

Further characterization of a protein kinase-substrate complex precipitable with Ca2+ from the cytosol fraction of AH-66 hepatoma cells

The properties of a protein kinase-substrate complex precipitated with Ca2+ from the cytosol of AH-66 hepatoma cells were characterized. The endogenous phosphorylation reaction of the complex was little affected by addition of histone, cyclic nucleotides, Ca2+-calmodulin, or Ca2+-phospholipid but was increased about two-fold by addition of casein. The complex contained several phosphate acceptor proteins with molecular weights ranging from 74,000 to 13,000 as analyzed by two-dimensional gel electrophoresis. These phosphate acceptor proteins were specifically concentrated in the complex. The protein kinase in the complex was purified by successive chromatography and proved to be casein kinase 2.     

Mechanism of activation of cyclic GMP-dependent protein kinase from rat liver by multiple modulators

A number of polyanionic compounds, including DNA, RNA and polyglutamate, were shown to exhibit protein kinase stimulatory modulator activity as they were required for cyclic GMP to stimulate the phosphorylation of various cationic substrates by rat liver cyclic GMP-dependent protien kinase. Anionic proteins (casein, phosvitin) were phosphorylated poorly by the enzyme and their phosphorylation was not stimulated by the stimulatory modulators. Studies of the mechanism of action suggest that the modulators interact directly with the substrates to form a complex which is a better substrate than free histone. The observed effect of modulator is complex as it depends on the ratio of modulator to histone and the resultant state of the complex formed (better or poorer substrate than free histone). The observed effect is also dependent on the properties of the histone substrate as Michaelis-Menten kinetics are not observed in the phosphorylation of arginine-rich histone in the absence or presence of cyclic GMP.     

Cyclic adenosine monophosphate-dependent and -independent protein kinase activity of renal brush border membranes.

Kinase(s) in brush border membranes, isolated from rabbit renal proximal tubules, phosphorylated proteins intrinsic to the membrane and exogenous proteins. cAMP stimulated phosphorylation of histone; phosphorylation of protamine was cAMP independent. cAMP-dependent increases in phosphorylation of endogenous membrane protein were small, but highly reproducible. Most of the ³²P incorporated into membranes represented phosphorylation of serine residues, with phosphorylthreonine comprising a minor component. cAMP did not alter the electrophoretic pattern of ³²P-labeled membrane polypeptides. The small cAMP-dependent phosphorylation of brush border membrane proteins was not due to membrane phosphodiesterase or adenylate cyclase activities. Considerable cAMP was found “endogenously” bound to the membranes as prepared. However, this did not result in preactivation of the kinase since activity was not inhibited by a heat-stable protein inhibitor of cAMP-dependent protein kinases. With intrinsic membrane protein as phosphate acceptor, the relationship between rate of phosphorylation and ATP concentration appeared to follow Michaelis-Menton kinetics. With histone the relationship was complex. cAMP did not affect the apparent K_m for histone. One-half maximal stimulation of the rate of histone phosphorylation was obtained with 7 × 10^?8m cAMP. The K_a values for dibutyryl cAMP, cIMP, and cGMP were one to two orders of magnitude greater. Treatment of brush border membranes with detergent greatly increased the dependency of histone phosphorylation on cAMP. Phosphorylations of intrinsic membrane protein and histone were nonlinear with time, due in part to the lability of the protein kinase, the hydrolysis of ATP, and minimally to the presence of phosphoprotein phosphatase in the border membrane. The membrane phosphoprotein phosphatase was unaffected by cyclic nucleotides. Protein kinase activity was also found in cytosolic and crude particulate fractions of the renal cortex. Activity was enriched in the brush border membrane relative to that in the crude membrane preparation. The kinase activities in the different loci were distinct both in relative activities toward different substrates and in responsiveness to cAMP.     

Protein kinases of the human placental microvillous membrane. Their potential role in intrasyncytial communication

Protein phosphorylation has been shown to alter various plasma membrane functions. To investigate the role of phosphorylation in human placental trophoblast, microvillous membrane vesicles were incubated with [gamma-32-P]ATP and the phosphorylation of endogenous and exogenous protein substrates was measured. The microvillous membrane was shown to possess both adenosine 3',5'-cyclic monophosphate (cAMP)-independent and cAMP-dependent kinases. Both endogenous proteins and exogenous proteins were phosphorylated and these processes were enhanced by the presence of Triton or the ionophore alamethicin. The phosphorylation of histone and of endogenous peptides of molecular weights (MW) 147 000, 97 000 and 53 000 was increased by the addition of cAMP. cAMP stimulation required the presence of Triton or alamethicin. The cAMP-dependent kinases are apparently located at the internal (cytoplasmic) surface of the membrane. This location would allow stimulation by cAMP produced by the basal (fetal-facing) plasma membrane. cAMP-stimulated protein phosphorylation may serve as a means of communication between the syncytial plasma membranes facing the fetal and maternal surfaces.     

Characterization of Developmentally Regulated cAMP/Ca2+-Independent Protein Kinases from Dictyostelium discoideum

Cell-free extracts of the slime mold Dictyostelium discoideum were assayed for phosphorylating activity towards endogenous proteins and towards histone H1, casein and myelin basic protein (MBP). During development, protein kinase activity towards all of these substrates steadily increased and peaked between the aggregation and the pseudoplasmodial stages. Particulate-associated kinase activity was solubilized with 1% CHAPS, and separated into 300–400 kDa and ∼ 100 kDa components on Sephacryl S-300. The 300–400 kDa peak exhibited the most pronounced developmental increase in MBP phosphorylating activity. It was further fractionated on DEAE-Sephacel and heparin-Sepharose, and in each case, it coeluted with the histone H1 phosphorylating activity. The activity of this kinase was unaffected by cAMP and calmodulin, but it was reduced to 50% by ∼ 350 mM NaCl, 5 mM NaF and 40 μg polylysine/ml. The ∼ 100 kDa peak exhibited the most pronounced increase in casein kinase activity during development. Most of the casein phosphorylating activity did not bind to DEAE-Sephacel; it was distinct from casein kinase 2, which was not developmentally regulated. In parallel with these elevated kinase activities during development, there was increased in vitro phosphorylation of a number of Dictyostelium proteins, including two major phosphoproteins of 140 and 94 kDa.     

Casein kinase II activity and polyamine-stimulated protein phosphorylation of cytosolic and plasma membrane proteins in bovine sperm

A highly purified preparation of sperm cytosolic protein kinase was obtained by repeated chromatography with phosphocellulose. The preferred substrate of the enzyme was casein and the activity was not stimulated by added Ca2+, calmodulin, or cAMP. With casein as substrate, both ATP and GTP served as phosphate donors and the activity was inhibited by low micromolar heparin and stimulated by low millimolar spermine and spermidine. These properties are characteristic of casein kinase II from other cells. Endogenous protein substrates of the enzyme in sperm cytosolic fractions and in plasma membranes were demonstrated by incubating the preparations with [gamma-32P]GTP, under conditions unfavorable to other protein kinases, and analyzing the products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Spermine greatly enhanced the phosphorylation of three (55, 92, and 106 kDa) proteins in both cytosolic and plasma membrane preparations. Our results indicate that polyamines play a role in modulating the phosphorylation state of proteins in sperm and may further regulate sperm function through this mechanism.     

Protein kinases of the chick oviduct: a study of the cytoplasmic and nuclear enzymes.

Subcellular fractionation of oviduct tissue from estrogen-treated chicks indicated that the bulk of the protein kinase activity of this tissue is located in the cytoplasmic and nuclear fractions, DEAE-cellulose chromatography of cytosol revealed a major peak of cAMP stimulatable activity eluting at 0.2 M KCl. This peak was further characterized and found to exhibit properties consistent with cytoplasmic cAMP dependent protein kinases isolated from other tissues; it had a Km for ATP of 2 X 10(-5) M, preferred basic proteins such as histones, as substrate, and had a M of 165 000. Addition of 10(-6) M cAMP caused the holoenzyme to dissociate into cAMP binding regulatory subunit and a protein kinase catalytic subunit. Extraction of purified oviduct nuclei with 0.3 M KCl released greater than 80% of the kinase activity in this fraction. Upon elution from phospho-cellulose, the nuclear extract was resolved into two equal peaks of kinase activity (designated I and II). Peak I had a sedimentation coefficient of 3S and a Km for ATP of 13 muM. while peak II had a sedimentation coefficient of 6S and a Km for ATP of 9 muM. Both enzymes preferred alpha-casein as a substrate over phosvitin or whole histone, although they exhibited different salt-activity profiles. The cytoplasmic and nuclear enzymes were well separated on phospho-cellulose and this resin was used to quantitate the amount of cAMP dependent histone kinase activity in the nucleus and the amount of casein kinase activity in the cytosol. Protein kinase activity in nuclei from estrogen-stimulated chicks was found to be 40% greater than hormone-withdrawn animals. This increase in activity was not due to translocation of the cytoplasmic protein kinase in response to hormone, but to an increase in nuclear (casein) kinase activity. During the course of this work, we observed small but significant amounts of cAMP binding activity very tightly bound to the nuclear fraction. Solubilization of the binding activity by sonication in high salt allowed comparison studies to be performed which indicated that the nuclear binding protein is identical with the cytoplasmic cAMP binding regulatory subunit. The possible role of the nuclear binding activity is discussed.     

Relationship between RNA polymerase and protein kinase activities in rat mammary gland nuclei.

1. Extracts from rat mammary gland nuclei contain cyclic AMP -independent protein kinases which phosphorylate casein rather than histone. 2. A major increase in nuclear protein kinase activity occurred during late pregnancy and was maintained with the onset of lactation. 3. Two major peaks of activity were resolved by chomatography of nuclear extracts on DEAE-Sephadex; the first (NI) appeared in the void volume and the second (NII) was eluted by 0.05-0.12 M ammonium sulfate. Several other regions of lesser activity were also present. 4. Protein kinases in the cytosol 105,000 times g supernatant, precipitated by 70 percent ammonium sulfate, dialyzed against buffer, and chromatographed on DEAE-Sephadex, yielded a major components phosphorylated histone in preference to casein, and this was stimulated by cyclic AMP if histone was the substrate, but only the first (void volume) fraction was cyclic AMP-dependent when casein was used. 5. Most of RNA polymerases Ib and II, derived from the nucleolus and nucleoplasm, respectively, appeared in column fractions distinct from those containing the major NI and NII protein kinases. 6. Cyclic AMP altered the amount of RNA product synthesized by polymerases Ib and II, but the explanation for this is unknown. Due to their elution profiles and cyclic AMP-independence, protein kinases NI and NII are excluded from playing a catalytic role in these effects; participation of quantitatively minor protein kinases which co-elute with polymerase Ib and II is not yet excluded.     

A hepatic soluble cyclic nucleotide-independent protein kinase. Stimulation by basic polypeptides.

Enzymatic phosphorylation of cytoplasmic proteins by a cyclic nucleotide-independent protein kinase (casein kinase of a classical type) in rat liver is stimulated greatly, sometimes more than 10-fold, by polycations, particularly by basic polypeptides such as polylysine, histone, and protamine. These basic polypeptides themselves do not serve as phosphate acceptors but act as stimulators for the reaction by interacting with cytoplasmic proteins rather than with enzyme. The stimulatory effect varies with substrates employed; with casein and phosvitin the stimulation does not exceed 2- to 3-fold. The cytoplasmic endogenous phosphate acceptor proteins measurable in the presence of basic polypeptides are abundant for this species of protein kinase.     

Phosphorylation of adrenal histone H3 is affected by angiotensin, ACTH, dibutyryl cAMP, and atrial natriuretic peptide

Angiotensin (AII) and atrial natriuretic peptide (ANP) exert opposite effects on phosphorylation of a 17.6 kDa nuclear protein from bovine adrenal glomerulosa cells. The protein was separated by sodium dodecyl sulfate electrophoresis and blotted onto polyvinylidene difluoride, and the N-terminal sequence was obtained. This sequence corresponded to histone H3. Another polyacrylamide gel electrophoresis system was used to confirm that AII stimulated the phosphorylation of histone H3. ACTH[1-24] stimulated phosphorylation of the same protein. Dibutyryl cAMP stimulated phosphorylation of a 17.6-kDa protein, and two gel electrophoresis systems confirmed that the protein affected was histone H3. In situ peptide mapping using papain, of either purified standard histone H3 or of the adrenal 17.6-kDa protein, produced the same major fragment as observed by silver staining. Therefore, the 17.6-kDa protein that is affected by AII, ANP, ACTH, and dibutyryl cAMP is histone H3. This finding suggests that in addition to their mutually antagonistic effects on acute steroidogenesis, AII and ANP may exert opposite effects on adrenal cell functions involving the nucleus.     

Fertilization promoting peptide and adenosine, acting as first messengers, regulate cAMP production and consequent protein tyrosine phosphorylation in a capacitation-dependent manner

Fertilization promoting peptide (FPP) and adenosine have been shown to act as first messengers, regulating availability of the second messenger cAMP by initially stimulating cAMP production in uncapacitated spermatozoa and then inhibiting it in capacitated cells. This study investigated possible capacitation-related changes in protein tyrosine phosphorylation in response to FPP and adenosine. Time-dependent changes in phosphorylation of proteins of approximately 30-140 kDa were observed in both uncapacitated and capacitated suspensions, the general level of phosphorylation being markedly greater in capacitated cells. In the presence of FPP, phosphorylation was stimulated in uncapacitated but inhibited in capacitated spermatozoa, compared with untreated control samples. Adenosine, cholera toxin, and CGS-21680, a stimulatory A(2a) adenosine receptor agonist, also stimulated phosphorylation in uncapacitated spermatozoa, while Gln-FPP, a competitive inhibitor of FPP, blocked responses to FPP. In capacitated cells, FPP's inhibition of phosphorylation was abolished when cells were treated with FPP in the presence of pertussis toxin. Consistent with the capacitation-dependent effects of FPP and adenosine on cAMP production, these results support the hypothesis that FPP and adenosine modulate sperm function by regulating the AC/cAMP signaling pathway and, consequently, protein tyrosine phosphorylation. Of particular significance is the identification of several phosphoproteins showing FPP-induced alterations in phosphorylation. In uncapacitated spermatozoa, proteins of approximately 116, 95, 82, 75, 66, 56, and 42 kDa showed increased phosphorylation, while in capacitated cells, phosphoproteins of approximately 116, 95, 82, 75, 70, 66, 56, and 50 kDa showed decreased phosphorylation. This suggests that these particular proteins may be involved in stimulation and arrest of capacitation, respectively.     

The Role of Pro- and Antioxidant Systems in the Development of Placental Dysfunction in Human Pregnancy

The pro-and antioxidant systems of the human placenta have been studied in its central and peripheral areas in the state of dysfunction. It has been shown that the intensity of free-radical oxidation (FRO) is 24% higher (p < 0.05) in mitochondria isolated from peripheral placental areas in the case of preterm termination of pregnancy than in placental mitochondria of women with normal pregnancy ending in delivery on due dates. The values of total antioxidant activity in mitochondria isolated from the central and peripheral areas of placentae of women with preterm labor exceeded 1.5-and 1.8-fold the respective values for the placental mitochondria of women with the normal duration of pregnancy. The rate of glutathione peroxidase activity in placental mitochondria of women with preterm labor was lower than in patients with normal duration of pregnancy terminated on due dates. Higher values of intensity of both the FRO processes and the active components of thiobarbituric acid (TBA) were recorded (higher by 42% and 62%, respectively) in the postmitochondrial fraction in the peripheral area of placentae of women with spontaneous termination of pregnancy, compared with the placentae of women with uncomplicated duration of pregnancy with labor on due date. No differences have been observed in the intensity of oxidative modification of placental proteins in both the periphery and the center in the placentae of women from the studied groups. The rate of glutathione peroxidase activity in the placenta of women with spontaneous termination of pregnancy was more than twice as high as the activity of this enzyme during the first trimester of normal pregnancy and remained high during the second and third trimesters. The activity of the enzyme did not depend on its localization (center or periphery) in placentae of women participating in the study. The values of glutathione transferase activity in the placentae increased in the course of normal pregnancy but remained at the level of the first trimester in the central and peripheral areas in the case of a miscarriage at different gestational terms. Our findings allow us to suggest that oxidative stress developing in placenta from its center to periphery plays a key role in the pathogenesis of placental dysfunction, mainly, due to the glutathione-dependent component of the placental antioxidant defense.