TSH control of PKA catalytic subunit activity in thyroid cell cultures.

The protein expression and the enzyme activity of the catalytic subunit (C) of the cAMP-dependent protein kinases were studied in porcine thyroid cell primary cultures stimulated with two doses of TSH (0.1 mU/ml and 1 mU/ml) for 1 to 3 days. In TSH-stimulated cells the desensitization of the catalytic subunit activity was accompanied by a simultaneous and parallel decrease of its immunoreactivity. The loss of catalytic subunit was rapid and reached its maximum after 1 day of culture. It is similar in the two subcellular compartments: cytosol and particulate extracts. Contrary to the observed loss of the C subunit protein molecules in TSH-stimulated cells, the expression of the Cbeta subunit mRNA in these cells was increased fivefold compared to controls, while no significant change was observed on the Calpha subunit mRNA. These results suggest that TSH controls the Cbeta subunits of PKA at two levels: at the transcriptional level it increases Cbeta mRNA expression, and at the translational or posttranslational level TSH decreases the amount and the activity of the Cbeta protein molecules.

Forskolin mimics TSH action on the expression of protein kinase C isozymes in pig thyroid cell cultures.

In porcine thyroid cell cultures, phospholipid-dependent protein kinases (PKCs) have the same characteristics as intact glands. The overall PKC activity, presence of PKC isozymes, chromatographic pattern and endogenous substrates specificity were not modified during the two-day culture period. Three PKC isozymes (cPKC epsilon, nPKC epsilon and aPKC zeta) were identified by immunoblot analysis in the two subcellular fractions: cytosol and particulate extract, both in intact glands and two-day-old cultures. In cells cultured for two days in the presence of TSH (0.1 mU/ml), the overall PKC activity was stimulated (ca. 200%) in the two compartments. This stimulation was parallel to the increase in protein expression of the three PKC isoforms (as demonstrated by immunoblot analysis) and was accompanied by a redistribution of cPKC alpha and nPKC epsilon toward the particulate fraction. In TSH-treated cells, hydroxyapatite chromatography of cytosolic PKC revealed an additional peak of PKC activity eluted at 195 mM potassium phosphate. Its elution molarity did not correspond to the molarity of any known PKC isozyme, and it did not cross-react with antibodies directed against cPKC isozymes--: alpha, beta, or gamma. When TSH was replaced by forskolin (10(-5) M), identical quantitative and qualitative modifications were obtained, suggesting that, in thyroid cells, the cyclic AMP-dependent regulatory cascade could be involved in the control of PKC isoforms expression by TSH.

TSH action on cAMP binding to the regulatory subunits of cAMP-dependent protein kinases in pig thyroid cell cultures.

This study examines the mechanism of TSH action on the cAMP-dependent protein kinases (PKA) by measuring the catalytic activity of the two PKA isozymes (PKA I and PKA II) and their capacity to bind cAMP to the regulatory subunits (RI and RII) in thyroid cell cultures exposed for two days to different doses of TSH. In TSH-treated cell cultures a selective down regulation (up to 60%) of the catalytic activity was found; the PKA I was down regulated at lower TSH doses (0.1 mU/ml and even 0.05 mU/ml) than was the PKA II (1.0 mU/ml TSH). At the dose of 1.0 mU/ml the loss of the catalytic activity in PKA I and PKA II was respectively 60% and 40%. No free catalytic activity was found either in control or in TSH-treated cells. Binding of cAMP to regulatory subunits (R) measured under exchange conditions at 37 degrees C, showed that no change in total regulatory subunit protein content occurs in TSH-treated cells. Binding of cAMP to R subunits at 4 degrees C (when only free cAMP binding sites are measured) revealed an important endogenous occupancy of cAMP binding sites of RI and RII isoreceptors under basal conditions (40%) and a significantly increased occupancy after exposure of cells to TSH (60%). Pools of regulatory subunits with more than 50% of sites occupied, which were devoid of enzyme activity, were found both, in control and TSH-exposed cells. They were identified as RI subunits which represented a mixed population of native and partly degraded molecules.(ABSTRACT TRUNCATED AT 250 WORDS)

Species differences of the thyroid protein kinase C heterogeneity.

Protein kinase C (PKC), the mediator of the phosphoinositide transduction pathway, is a family of at least 11 isozymes and its heterogeneity has been described in many tissues and cells. We studied here the heterogeneity of PKC in thyroid glands from three different species, rat, pig, and dog. By combining immunological and biochemical approaches, we identified in rat thyroids, the PKC alpha, beta II, delta, epsilon, and zeta subspecies, in pig thyroids, the alpha, epsilon, and zeta isozymes, and in dog thyroids, only the alpha and zeta isozymes. The observed species differences of the thyroid gland PKC heterogeneity could be related to the reported species differences in the activation of the phosphoinositide regulatory cascade by TSH and other thyroid cell regulators.

Immunological identification of protein kinase C-alpha and protein kinase C-delta in cultured rat mesangial cells: differential sensitivity of the two isoforms towards the protein kinase inhibitor H7.

Rat mesangial cells contain both calcium-dependent protein kinase C (PKC) activity, which phosphorylates histone H1 and endogenous proteins, and calcium-independent, phospholipid-dependent PKC activity, which phosphorylates only endogenous proteins. The calcium-dependent PKC was identified as PKC alpha by immunoblot analysis and hydroxyapatite chromatography (HPLC). The calcium-insensitive, phospholipid-dependent isoform was identified as PKC delta using similar techniques. The inhibition of these two PKC isoforms by the protein kinase inhibitor H7 [1-(iso-quinolinyl sulphonyl)-2-methyl piperazine] was examined using both histone H1 and endogenous proteins as substrates. Phosphorylations catalyzed by the calcium-dependent PKC isoform alpha were almost 90% inhibited when histone H1 was used, and only 55% when endogenous proteins were the substrate. In contrast, the phosphorylation of endogenous proteins catalysed by the calcium-insensitive, phospholipid-dependent PKC delta was not significantly affected by the inhibitor.

Heterogeneity of protein kinase C in cultured rat mesangial cells.

Two forms of protein kinase C (PKC) activity in cytosol of cultured rat mesangial cells have been characterized in vitro by using histone H1 or endogenous proteins as substrates. Histones H1-phosphorylation was significantly increased only when calcium, phosphatidylserine (PS) and 1,2-diacylglycerol (DAG) or phorbol myristate acetate (PMA) were present together in the incubation medium. EGTA, a calcium chelator, completely inhibited this activity. Upon hydroxyapatite chromatography (HPLC), the PKC activity was eluted as a main peak at 150 mM potassium phosphate with a shoulder at 180 mM. Both peaks corresponded to the type III PKC from rat brain and were identified as PKC alpha isoform by immunoblot analysis. In contrast with what was observed using histone H1, the increased phosphorylation of endogenous proteins in the presence of a mixture of Ca2+/PS, plus either DAG or PMA, was only partly reduced by EGTA. Moreover, the level of the PKC activity detected in the presence of EGTA was comparable to the level of kinase activity, measured in the presence of PS alone or associated with DAG or PMA. This suggests that mesangial cells contain PKC activity which does not absolutely require calcium. Polyacrylamide gel electrophoresis revealed that patterns of phosphorylated mesangial cell proteins are different depending on whether calcium was added or not. In the presence of calcium, PKC strongly phosphorylated the proteins of 53,000 molecular weight, a doublet of 37,000-39,000, the 24,000 and the triplet of 17,000-20,000-22,000 molecular weight. The addition of EGTA to the assays suppressed completely the labelling of most proteins; only the 20,000 molecular weight protein remained strongly labelled, while the 39,000 molecular weight band was only faintly visible. The same patterns of phosphorylations were obtained after omission of calcium in the assays containing only PS and DAG (or PMA). So, the main substrates of calcium-dependent PKC are proteins of 53,000, 39,000, 37,000, 22,000, 24,000 and 17,000 molecular weight while the protein of 20,000 molecular weight appears to be the main substrate of calcium-independent PKC. The existence in mesangial cells of at least two forms of PKC, which phosphorylate specific endogenous proteins, emphasizes the complexity of the phospholipid-dependent regulatory cascade and raises the possibility that actions of different regulators may be transduced through distinct PKC isozymes.

Epidermal growth factor and phorbol ester actions on the TSH induced down regulation of the isoenzyme I (PKA I) of cyclic AMP-dependent protein kinases in dog thyroid cell primary cultures.

In dog thyroid cell primary cultures the prolonged presence (up to 4-6 days) of TSH induced down regulation of the isoenzyme I (PKA I) of cAMP-dependent protein kinases. In the simultaneous presence of TSH and EGF this down regulation of PKA I was maintained, although it was slightly smaller than in assays without EGF. In contrast, the simultaneous presence of TPA, totally inhibited the TSH induced down regulation of PKA I. These results partly explain the previously observed additivity of TSH and EGF, and the non-additivity of TSH and TPA actions on cell proliferation in these cells.

Changes in cAMP-dependent and Ca2(+)-phospholipid-dependent protein kinase activities in suspension cultures of porcine thyroid cells.

The morphological and functional characteristics and the activities of cyclic AMP- (PKA I and PKA II) and calcium and phospholipid-dependent (PKC) protein kinases were studied in 2-day-old suspension cultures of porcine thyroid cells and were compared with those in freshly dissociated cells and intact glands. Thyroid cell morphology changed during the 2-day culture in the absence of specific regulators. This is characterized by a loss of cellular polarity, exo- and endocytotic vesicles and membranes of the rough endoplasmic reticulum, and an increase in the number of lysosomes, pseudomyelinic structures, lipidic inclusions and free ribosomes. Functional changes are characterized by a progressive decrease in protein iodination and its sensitivity to TSH stimulation. The total PKA activity in the cytosols of these cultures was slightly greater than that of freshly prepared tissue, due to the selective and significant accumulation of PKA I in cultured cells. In the particulate fraction the PKA activity was unchanged. PKC is the major kinase activity in porcine thyroids, and remains so in cultured cells. The slight drop in its activity in cytosols was offset by a significant increase in the particulate fraction, suggesting an intracellular redistribution of this kinase in cultured cells. The PKC activity is also partly activated in both the cytosol and particulate fraction, which results in an increased basal activity. The changes in PKA and PKC activities greatly modified the PKC/PKA ratios in the cytosols and the particulate fractions of cultured cells. These modifications could be partly responsible for the changes in sensitivity of cultured cells to the agents which control their activity.

[Modifications of protein kinase C activity and phosphorylation of lipocortin I in cultures of pig thyroid cells]. / Modifications de l'activité de la protéine kinase C et de la phosphorylation de la lipocortine I dans les cultures de cellules thyroïdiennes porcines.

When cultured in the absence of thyreostimulin (TSH), thyroid cells lose some of their differentiated functions such as iodide transport and its incorporation into thyroglobulin. In the presence of TSH (0.1 mU/ml), these differentiated functions are preserved ("TSH cells"). The addition of tetradecanoyl phorbol 13 acetate (TPA) inhibits some differentiated functions of the cells and provokes important modifications of bio-signalling pathways. The protein kinase C (pKC) activity, unchanged in "control" and "TSH cells", was dramatically modified in TPA treated cells. After translocation, the pKC activity was down-regulated and the phosphorylation of its endogenous substrates (35-38 kDa) disappeared. Among these substrates, we identified the lipocortin I (LC I) (35 kDa), a phospholipase A2 inhibitory protein related to the Ca2+ binding protein family. By monodimensional electrophoresis (PAGE-SDS) and western-blot, we evidenced the presence of LCI in cytosols and particulate extracts. By 2 dimensional electrophoresis (PAGE-SDS and IEF) and western-blot we identified a phosphorylated and unphosphorylated LCI protein. The phosphorylation of LCI by pKC decreased its isoelectric point from 6.9-6.6. The modifications of pKC activity and LCI phosphorylation and the changes in the bio-signalling pathways can partly account for the loss of differentiation observed in control or TPA treated cells.

Identification of four lipocortin proteins and phosphorylation of lipocortin I by protein kinase C in cytosols of porcine thyroid cell cultures.

Four proteins of the lipocortin family, lipocortin I (35 kDa), lipocortin II (36 kDa), lipocortin V (32 kDa) and lipocortin VI (67-70 kDa), were identified in the cytosols of 2-day-old cultures of thyroid cells. Only lipocortin I was phosphorylated in vitro in fully differentiated, thyroid stimulating hormone-treated cells (0.1 mU/ml). Protein kinase C was the only kinase activity which phosphorylated lipocortin I. Phosphorylation shifted its pI from 6.9 to 6.6. The in vitro phosphorylation of lipocortin I was impaired in cultures exposed for 2 days to phorbol ester (10(-7) M), although it was present in both the cytosol and the particulate fraction of these cells.

Thyrotropin but not epidermal growth factor down-regulates the isozyme I (PKa I) of cyclic AMP-dependent protein kinases in dog thyroid cells in primary cultures.

The activity of the two cAMP-dependent protein kinases (PKa I and PKa II) was evaluated in dog thyroid cells in primary cultures after a 6-day growth period induced by either thyrotropin (TSH) or epidermal growth factor (EGF). Although the total PKa activity was not affected in cells cultured in the presence of TSH or EGF, their actions on the PKa I and PKa II expressions were significantly different. The activity of PKa I was strongly inhibited by TSH (70-80%) while with EGF it was either stimulated or unaffected with respect to controls. The two mitogens did not have a significant effect on the activity of PKa II. Forskolin (Fk) mimicked the effect of TSH. The expression of the two regulatory subunits (R I and R II), evaluated by the covalent binding of 8-azido-cAMP, was similar to the expression of the corresponding catalytic activities, suggesting a coregulation of the catalytic and regulatory subunits from the same isozyme. After chronic stimulation by TSH, differentiated dog thyroid cells are almost completely deprived of PKa I.

Phorbol ester prevents the thyroid-stimulating-hormone-induced but not the forskolin-induced decrease of cAMP-dependent protein kinase activity in thyroid cell cultures.

The potent tumor promoter 12-O-tetradecanoyl-phorbol 13-acetate (TPA) affects several thyroid cell functions and interacts with thyroid-stimulating hormone (TSH) either by inhibiting or potentiating its action on different cellular parameters. Since phorbol ester acts mainly through the activation of protein kinase C, which is its receptor, we studied this activation and its interaction with TSH and forskolin in suspension cultures of porcine thyroid cells. In thyroid cell cultures, TPA has a dual effect on protein kinase C activity: immediately (2-5 min) after exposure of cells to TPA, it began to be translocated from the cytosol to the particulate fraction. The transfer of the cytosolic enzyme was total and could occur with or without a loss of activity. The translocated enzyme still needed Ca2+ and phospholipids for its activation. The basal activity increased transiently (2-4 h) in both the cytosol and particulate fractions during translocation. The peak activity in the particulate fraction was reached 10-30 min after exposure of cells to TPA, and was followed by down-regulation of protein kinase C and almost complete disappearance of its activity. The residual activity was about 13% of control after a 2-day exposure to TPA. It was unequally distributed between cytosol (4%) and particulate fraction (9%). Prolonged exposure of cells to TPA did not affect either the activity or the subcellular distribution of the cAMP-dependent protein kinase activity. TPA interacted with TSH and prevented the decrease of this activity induced by prolonged exposure of cells to the hormone not only when it was introduced simultaneously with TSH, but also when it was added 24 h after TSH. However, the forskolin-induced decrease in cAMP-dependent protein kinase activity was not prevented by the presence of TPA. TPA also affected the increases in cAMP accumulation mediated by TSH and forskolin. The TSH-induced increase was significantly stimulated by TPA after short contacts (5-15 min), while longer preincubations of cells with TPA provoked a very strong inhibition of the TSH action. However, the forskolin-induced stimulation of the cAMP accumulation was maintained and even further increased in the presence of TPA. Consequently, the actions of TSH and TPA are apparently interdependent, while those of forskolin and TPA seem to be parallel and independent. Neither TSH nor forskolin prevented the TPA-induced down regulation of protein kinase C. The biologically inactive phorbol ester analogue 4 alpha-phorbol 12,13-didecanoate had no effect on protein kinase C activity, and did not interact with either TSH or forskolin.(ABSTRACT TRUNCATED AT 400 WORDS)

Decrease in cAMP-dependent protein kinase activity in suspension cultures of porcine thyroid cells exposed to TSH or forskolin.

Suspension cultures of porcine thyroid cells were used to study the action of TSH and forskolin (Fk) on cAMP-dependent (PKa) and Ca2+-phospholipid-dependent (PKc) protein kinase--enzymes which represent the key step in the transduction of extracellular signals. The PKa activity in cells cultured for 2 days in the presence of TSH was decreased to about 50% of control level with a TSH dose of 0.1 mU/ml. This decrease is dose dependent; only traces of PKa activity remained at very high doses of TSH (50 mU/ml). Similar results were obtained with Fk (10(-5) M), the adenylate cyclase activator. It decreased the PKa activity to the level obtained with 0.1-1.0 mU/ml TSH. The loss of the PKa activity was parallel in cytosol and particulate fractions, suggesting that there is no translocation of enzymes under the action of either TSH or Fk. Neither TSH nor Fk had any effect on PKc, which became the predominant activity in cells exposed to either of the regulators. The cAMP-dependent phosphorylation of endogenous proteins was lower in TSH- or Fk-treated cells than in controls, and was dependent, like the PKa activity, on the dose of TSH. Polyacrylamide gel electrophoresis (PAGE) revealed the specific substrates of PKa in cultured thyroid cells. Proteins of 28, 30 and 33 kDa were regularly found, while 58 kDa protein was not present in all experiments. PAGE patterns showed that the decrease in endogenous phosphorylation in TSH- and Fk-treated cells was due to decreased labelling of PKa-specific substrates. The observed down-regulation of PKa activity could have an influence on the expression of thyroid cell differentiation.

Characteristics of thyroid protein kinase C. Different Ca2 requirement for the phosphorylation of endogenous proteins and of H1 histone.

Thyroid protein kinase C (PKc) from cytosols of porcine and rat thyroid glands has been characterized using histone H1 or endogenous proteins as substrates. As in many other tissues histone H1 is by far the preferred exogenous substrate of thyroid PKc. Kinetic studies with H1 showed that, compared to rat thyroids, porcine glands are particularly rich in PKc, the predominant kinase activity in this tissue. The cAMP-dependent protein kinase (PKa) level, on the contrary, is very similar in both rat and porcine thyroids. Consequently, for the same type of tissue, there may be great species differences in the PKc level and the ratios between PKc and PKa kinase activities. Chromatographic properties of thyroid PKc are similar to those described in other tissues (one major peak followed by a small shoulder) except that elution of the main peak can vary depending on the nature of the salt gradient (approximately 55 mM for NaCl and 15 mM for sodium phosphate). In the first case PKc is completely separated from the PKa activity, in the second it is coeluted with the peak of PKa type I. The one-dimensional PAGE pattern of proteins phosphorylated by porcine PKc is very similar to the pattern obtained by rat enzyme. Protein bands of 18 kDa, 22-25 kDa and 32-36 kDa are specific substrates of the thyroid PKc, after in vitro phosphorylation of cytosol proteins. A great difference in Ca2+ requirement for PKc activation was noted, depending whether histone H1 or endogenous proteins were substrates. As in other tissues, calcium was absolutely necessary for phosphorylation of histone H1 by PKc. The addition of calcium was not absolutely necessary when endogenous proteins were the substrates, either for the activation of the enzyme or for phosphorylation of the PKc-specific substrates. Almost the same rate of phosphorylation was obtained with or without calcium in the incubation medium. However the one-dimensional PAGE pattern of phosphorylated proteins was different in the presence or absence of calcium. While addition of calcium was not absolutely necessary for the phosphorylation of a great number of proteins by the PKc, its presence was indispensable for the phosphorylation of certain endogenous substrates. However, calcium alone, in the absence of phospholipids had no effect on the phosphorylation of these proteins. Endogenous proteins, phosphorylated by the PKc only when calcium was present, were resolved by the two-dimensional PAGE into several distinct spots with molecular masses of 32-35 kDa and pI range of 5-7.5.(ABSTRACT TRUNCATED AT 400 WORDS)

Endogenous substrates of protein kinase C in experimentally induced and regressed rat thyroid goitres.

The presence of endogenous substrates of the protein kinase C (PKc) in rat thyroid glands has been demonstrated in in vitro phosphorylated cytosolic proteins by polyacrylamide gel electrophoresis (PAGE). Rat thyroid PKc specifically catalyzes the phosphorylation of the 35 kDa and 18 kDa proteins. These proteins were not labelled in the presence of Ca2+ alone, but they were phosphorylated when phospholipids alone were added. In hyperplastic glands the total phosphorylation of endogenous proteins is stimulated, due to the increased labelling of the 35 kDa and 18 kDa proteins. No extra phosphorylated bands were revealed by PAGE analysis. After suppression of growth activity the labelling of the two PKc-specific substrates was strongly inhibited.

Protein kinase C activity in experimentally developed and regressed rat thyroid goitres.

The presence of protein kinase C activity in rat thyroid glands was demonstrated by kinetic studies, using lysine-rich histone as substrate. DE 52 cellulose chromatography resolved thyroidal protein kinase C activity into two peaks, the first eluting at 50 mM and the second at 150 mM salt solution. They contained respectively 40% and 60% of the total activity. In cytosols from experimentally induced goitres, which are hyperplastic tissues, protein kinase C activity rose 3-4-fold compared to control glands. In this tissue, protein kinase C seems to be present in reversibly activated form, since its activity was completely inhibited in the absence of calcium and phospholipids. After removal of growth stimulus, rapid involution of goitres occurred, producing a spectacular decrease in protein kinase C activity. In goitres regressed for 5 days, the level of protein kinase C was lower than in untreated control tissue. The protein kinase C activities in control glands and developed and regressed goitres were 1.88, 5.85 and 0.74 pmoles 32P/mg tissue, respectively. These results clearly demonstrate, for the first time, a direct correlation between the protein kinase C level and the thyroid gland growth activity induced by endogenous stimuli.

Modification of protein kinase pattern in human placentae during gestation.

The cAMP-dependent and cAMP-independent histone kinases have been studied in the two subcellular compartments (cytosol and particulate fraction) from placentae of different gestational age. The total protein kinase activity, as well as its distribution between the two compartments, changes during the period of gestation. The total activity is significantly increased in full-term placentae. The increase is much greater for the cAMP-dependent (400 per cent), than for the cAMP-independent (270 per cent) protein kinases. It is much higher (400 per cent) in the cytosol than in the particulate fraction (170 per cent); consequently, the particulate fraction of term placentae shows a relatively lower proportion of protein kinase activity (26 per cent of the total activity) than the corresponding fraction of young placentae (37 per cent). DEAE-cellulose chromatography revealed the presence of two cAMP-dependent protein kinase peaks which correspond to Type I and Type II isoenzymes described in many mammalian tissues (Corbin, Keely and Park, 1975). The Type II isoenzyme is predominant in both first- and third-trimester placentae. The increase in protein kinase activity in term placentae is due to the selective activation of the Type II kinase only. The activity of the Type I isoenzyme remained unchanged throughout the period of gestation. The third peak eluted from the DEAE-cellulose column corresponds to a cAMP-independent sucrose-gradient ultracentrifugation into two distinct peaks similar to those already observed in several rat tissues (Toru-Delbauffe, Ohayon and Pavlovic-Hournac, 1983). The protein kinase patterns of both young and term placentae remain stable during the incubation of the tissues 'in vitro' for three hours.

Protein kinase patterns in hyperplastic rat thyroids and in human non-toxic nodular goitres.

Patterns of cAMP-dependent protein kinases and cAMP-independent histone and casein kinases of hyperplastic rat thyroid glands and of human nodular non-toxic goitres have been analysed in two subcellular compartments, cytosol and particulate fraction. In hyperplastic rat glands the different compartmentalization of the two cAMP-dependent isoenzymes was preserved and the pattern of cAMP-independent protein kinases was not changed qualitatively, but the activities of the three classes of protein kinases were enhanced to different degrees: the highest increase was observed for the cAMP-dependent enzymes and the lowest for the cAMP-independent casein kinases. Analysis of individual peaks of cAMP-dependent kinases showed selective stimulation of the cytosolic Type II form and independent control of the Type I activity in the two subcellular compartments. Among cAMP-independent protein kinases only two histone kinase peaks were selectively enhanced; other kinase entities were changed to a lesser degree. During the involution of hyperplastic glands, a transient but differential enhancement of nearly all kinases was noted at first, which was followed later by a strong decrease, more or less rapid, of almost all kinase activities. In the regressed glands, neither the thyroid weight nor the pattern of different kinase entities corresponded to those of control, untreated glands, indicating that some of the protein kinase alterations in hyperplastic tissues are partly irreversible. In spite of great similarities, human and rat goitre tissues are not identical. The most important difference was the loss of compartmentalization of the cAMP-dependent isoenzymes in human tissue. The different ratios of the light and heavy peaks of cytosolic cAMP-independent histone kinases was the second characteristic which distinguished human and rat glands.

Some characteristics and hormonal control of thyroidal cAMP-independent protein kinases.

Cyclic AMP-independent protein kinases in cytosol from rat thyroid glands were evaluated using histone and casein as exogenous substrates. Compared with other rat tissues, thyroid gland is rich in histone kinases, while its casein kinase activity is lower than that of liver and brain. Thyroidal cAMP-independent protein kinases can be resolved by sucrose gradient ultracentrifugation into two distinct peaks of histone (HKi-1 and HKi-2) and two peaks of casein (CKi-1 and CKi-2) kinases. An intermediate peak of histone kinase activity is only occasionally present. The four main kinase peaks are distinct with respect to several properties: their sedimentation coefficients are significantly different; only one out of the four peaks (CKi-2) can use GTP as substrate; monovalent ions strongly inhibit (50%) light peaks (HKi-1 and CKi-1), while heavy peaks (HKi-2 and CKi-2) are slightly but significantly stimulated (30%); light peaks are very sensitive to thermal inactivation, while heavy peaks are much more resistant. Their reactivity to hormonal action is different: in chronically stimulated glands HKi-2 is selectively and strongly stimulated (240%) while CKi-1 is not changed. In human pathological tissues independent alterations in different kinase entities were observed compared with healthy tissue. In conclusion, the four thyroidal c-AMP-independent protein kinases resolved on sucrose gradient seem to represent distinct entities which are independently and selectively controlled by hormones, and specifically altered in human pathological tissues.