Salt-inducible kinase is involved in the ACTH/cAMP-dependent protein kinase signaling in Y1 mouse adrenocortical tumor cells.

The involvement of salt-inducible kinase, a recently cloned protein serine/threonine kinase, in adrenal steroidogenesis was investigated. When Y1 mouse adrenocortical tumor cells were stimulated by ACTH, the cellular content of salt-inducible kinase mRNA, protein, and enzyme activity changed rapidly. Its level reached the highest point in 1-2 h and returned to the initial level after 8 h. The mRNA levels of cholesterol side-chain cleavage cytochrome P450 and steroidogenic acute regulatory protein, on the other hand, began to rise after a few hours, reaching the highest levels after 8 h. The salt-inducible kinase mRNA level in ACTH-, forskolin-, or 8-bromo-cAMP-treated Kin-7 cells, mutant Y1 with less cAMP-dependent PKA activity, remained low. However, Kin-7 cells, when transfected with a PKA expression vector, expressed salt-inducible kinase mRNA. Y1 cells that overexpressed salt-inducible kinase were isolated, and the mRNA levels of steroidogenic genes in these cells were compared with those in the parent Y1. The level of cholesterol side-chain cleavage cytochrome P450 mRNA in the salt-inducible kinase-overexpressing cells was markedly low compared with that in the parent, while the levels of Ad4BP/steroidogenic factor-1-, ACTH receptor-, and steroidogenic acute regulatory protein-mRNAs in the former were similar to those in the latter. The ACTH-dependent expression of cholesterol side-chain cleavage cytochrome P450- and steroidogenic acute regulatory protein-mRNAs in the salt-inducible kinase-overexpressing cells was significantly repressed. The promoter activity of the cholesterol side-chain cleavage cytochrome P450 gene was assayed by using Y1 cells transfected with a human cholesterol side-chain cleavage cytochrome P450 promoter-linked reporter gene. Addition of forskolin to the culture medium enhanced the cholesterol side-chain cleavage cytochrome P450 promoter activity, but the forskolin-dependently activated promoter activity was inhibited when the cells were transfected with a salt-inducible kinase expression vector. This inhibition did not occur when the cells were transfected with a salt-inducible kinase (K56M) vector that encoded an inactive kinase. The salt-inducible kinase's inhibitory effect was also observed when nonsteroidogenic, nonAd4BP/steroidogenic factor-1 -expressing, NIH3T3 cells were used for the promoter assays. These results suggested that salt-inducible kinase might play an important role(s) in the cAMP-dependent, but Ad4BP/steroidogenic factor-1-independent, gene expression of cholesterol side-chain cleavage cytochrome P450 in adrenocortical cells.     

Role of AMP-activated protein kinase in the regulation of gene transcription

AMP-activated protein kinase (AMPK) is a regulator of cellular metabolism in response to changes in the energy status of the cells. AMPK was known to shut down energy-consuming pathways in response to a fall in the ATP/AMP ratio by phosphorylating key enzymes of intermediate metabolism. Here we will discuss the recent evidence implicating AMPK in the regulation of gene expression in mammals, mainly in the liver and in the pancreatic beta-cells.     

Altered cyclic AMP-dependent protein kinase activity in a mutant adrenocortical tumor cell line

A somatic cell genetic approach has been used to evaluate the role of cyclic AMP-dependent protein kinase in ACTH action on adrenal steroidogenesis. A mutant clone, 8BrcAMP^r-1, previously was isolated from an ACTH-sensitive adrenocortical tumor cell line (clone Y1) following mutagenesis and selective growth in 8-bromoadenosine 3′, 5′-monophosphate. This study demonstrates that the 8BrcAMP⁴-1 cells have an altered cyclic AMP-dependent protein kinase. The protein kinase in the cytosol of the mutant characteristically requires, for half-maximal activity, concentrations of cyclic AMP 7-fold higher than those required by the enzyme in preparations from the parent. The cytosolic cyclic AMP-dependent protein kinases of Y1 and 8BrcAMP^r-1 cells chromatograph similarly on columns of DEAE-cellulose. From each cell line, a major peak of activity (≥ 70% of recovered activity), designated as Peak I, elutes with 0.04–0.06 M NaCl; a second peak of activity, designated as Peak II, elutes with 0.12–0.14 M NaCl. Protein kinase activity in the Peak I fraction of mutant cells has a decreased apparent affinity (4-fold) for cyclic AMP relative to the corresponding fraction of parental Y1 cells. The protein kinase activities present in Peak II fractions from Y1 and mutant cells are indistinguishable. The protein kinase mutant exhibits poor steroidogenic responses to added ACTH and cyclic AMP; and as shown previously does not display the growth arrest and morphological changes produced in Y1 by these agents. These results suggest that cyclic AMP-dependent protein kinase is important in the regulation of adrenal steroidogenesis, morphology and growth by ACTH.     

Involvement of protein kinase C in the regulation of cortisol production by guinea pig adrenocortical cells.

Cytosol of the guinea pig adrenals was found to contain a protein kinase which was dependent on the presence of both calcium and phospholipids (phosphatidylserine and diolein), i.e., calcium/phospholipid-dependent protein kinase (protein kinase C). The peak of protein kinase C was separated from type II cAMP-dependent protein kinase by DE-52 chromatography. 12-0-Tetradecanoylphorbol-13-acetate (TPA) caused dose-dependent increments of cortisol formation without affecting cAMP formation by guinea pig adrenocortical cells as well as angiotensin II did. TPA-activated cortisol production was blocked by the addition of aminoglutethimide and cycloheximide, suggesting that the site of action of TPA might be located at a point before the production of pregnenolone in the mitochondria. Since TPA showed an increase in the cortisol production, protein kinase C may be involved in modulating steroidogenesis in the guinea pig adrenals in addition to the classical cAMP-dependent protein kinase pathway.     

Cloning of DNA from double minutes of Y1 mouse adrenocortical tumor cells: Evidence for gene amplification

We have isolated a metaphase chromosome fraction highly enriched in double minutes (dm) from a mouse adrenocortical tumor cell line (Y1-DM). We have cloned DNA from this dm-enriched fraction in the λ vector Charon 4A, and have characterized two randomly chosen recombinant bacteriophage clones from this dm DNA library. When ³²P-labeled DNA from each recombinant was hybridized to Southern blots of restriction endonuclease-digested DNA from different mouse cell lines, large differences were seen in the intensity of the resulting autoradiographic images, depending on the source of the genomic DNA. A very strong signal was obtained with DNA from the Y1-DM cells and with DNA from a related Y1 subline that lacks dm but contains a marker chromosome bearing a large homogeneously staining region (HSR). Hybridization to DNA from parental inbred mice and from two unrelated mouse cell lines produced a significantly weaker signal than that obtained with DNA from the Y1 cells, but the DNA fragments from these sources were of similar size. Based on results from filter hybridization analysis, we estimate that sequences homologous to the cloned fragments are approximately 100- to 200-fold more abundant in the genome of the Y1-DM cells than in the parental mouse cells. The data are consistent with the hypothesis that dm and HSRs in these cells contain amplified genes.     

The interferon-induced protein kinase PK-i from mouse L cells.

Interferon-treated L cells are characterized by an increased protein kinase activity that can selectively phosphorylate the small subunit of eukaryotic initiation factor 2. This protein kinase, PK-i, has been extensively purified and shown to be a potent inhibitor of mRNA translation. The purified PK-i contains the endogenously phosphorylated 67,000 Mr protein characteristic of interferon-treated cell extracts. PK-i can also phosphorylate arginine-rich histones. Purified PK-i can be activated by preincubation with ATP (but not adenylyl imidodiphosphate) and low concentrations of double-stranded RNA. The activation results in an increase in the first rate of eIF-2 phosphorylation. Activated PK-i becomes resistant to high concentrations of double-stranded RNA and more thermostable. A stimulator of PK-i activity, factor A, was isolated, as well as a specific phosphoprotein phosphatase that dephosphorylates the 67,000 Mr protein and eIF-2. These two factors, which are present in untreated L cells, may regulate the translation inhibitory activity of the interferon-induced and double-stranded RNA-activated protein kinase PK-i.     

Nonphorbol tumor promoters okadaic acid and calyculin-A induce membrane translocation of protein kinase C.

The cell-permeable inhibitors of type 1 and 2A protein phosphatases, okadaic acid and calyculin-A, induced a redistribution of protein kinase C (PKC) activity and immunoreactivity (40 to 60%) from cytosol to membrane in some cell types. Calyculin-A was 100-fold more potent than okadaic acid and required only 5 to 10 nM concentrations to induce this PKC translocation. The concentration of these agents required to induce the redistribution of PKC correlated with the potency of these agents to inhibit both type 1 and 2A protein phosphatases. There was a lag period of 15 to 30 min before the onset of PKC translocation, as this process might have been induced by indirect cellular events triggered by inhibitions of protein phosphatases (1 and 2A). Taken together these results suggest that although the okadaic acid class of tumor promoters and phorbol ester-related agents bind to two different cellular receptors having counteracting enzymic activities, they share a common mechanism of action, namely the induction of cytosol to membrane translocation of PKC.     

Microtubules, organelle transport, and steroidogenesis in cultured adrenocortical tumor cells. 1. An ultrastructural analysis of cells in which basal and ACTH-induced steroidogenesis was inhibited by taxol

In adrenocortical cells, the first step in the enzymatic processing of cholesterol to steroid end products occurs in the mitochondria. ACTH increases mitochondrial cholesterol and steroidogenesis. In cultured mouse adrenocortical tumor cells, microtubule-based organelle motility may increase the proximity of mitochondria to the SER, lipid droplets and endoscome-derived lysosomes, thereby facilitating the transfer of cholesterol from these organelles to the mitochondrial outer membrane. ACTH may increase opportunities for the transfer by promoting organelle motility and by increasing the number of lysosomes. Taxol, a microtubule polymerizer, inhibits basal and ACTH-induced steroidogenesis in these cells, presumably at the step where mitochondria obtain cholesterol. We examined the ultrastructure of taxol-treated, unstimulated and ACTH-stimulated cells, seeking alterations which conceivably could interefer with the proposed organelle transport and encounters, and thus correlate with taxol's inhibition of steroidogenesis. Primary cultured cells were incubated in serum-containing medium for 4 hr with and without ACTH (10 mU/ml), with 10 micrograms/ml and 50 micrograms/ml of taxol, and with ACTH and taxol 10 or taxol 50 simultaneously. Culture media were analyzed for the presence of secreted steroids at the end of 1, 2, and 4 hr of incubation. At the end of the fourth hour, unstimulated cells and cells treated with ACTH, taxol 50, and both agents simultaneously, were fixed and processed for EM. Taxol inhibited basal and ACTH-induced steroidogenesis in a dose-dependent fashion. In both unstimulated and ACTH-stimulated cells, taxol 50 formed numerous microtubule bundles, but did not markedly change the distribution of mitochondria and lipid droplets. SER tubules, and clusters of Golgi fragments, endosomes, and lysosomes appeared to be translocated towards the cell periphery along some of the microtubules. Taxol permitted an ACTH-induced cell rounding and microfilament rearrangement considered to facilitate organelle motility. Our data indicate that taxol disrupts the formation of lysosomes by these adrenal cells, but it seemed unlikely that taxol's ultrastructural effects could prevent organelle transport proposed to cause meetings between mitochondria and the SER or lipid droplets, or prevent ACTH-caused increases in these encounters. Taxol may instead prevent the transfer of lipid droplet or SER-contained cholesterol to adjacent mitochondria, by a means not detectable in our electron micrographs.