Retinoylation of proteins in leukemia, embryonal carcinoma, and normal kidney cell lines: differences associated with differential responses to retinoic acid

[Prevention and Treatment of Cancer with Vitamin A and Its Derivatives: Cell Differentiation and Proliferation]

Normal differentiation and proliferation of cells are essential for maintaining homeostasis. Following the successful completion of whole genome sequencing, protein modification has been attracted increasing attention in order to understand the roles of protein diversification in protein function and to elucidate molecular targets in mechanisms of signal transduction. Vitamin A is an essential nutrient for health maintenance. It is present as β-carotene in green and yellow vegetables and retinyl ester in animal products and absorbed into the body from the intestines. After ingestion, it is converted to retinol and oxidized in target cells to retinal, which plays critical roles in vision. It is then further oxidized to retinoic acid (RA), which exhibits a number of effects prior to being metabolized by cytochrome P450 and excreted from the body. Since RA exhibits cell differentiation-inducing actions, it is used as a therapeutic agent for patients with acute promyelocytic leukemia. The current paper describes: (1) HL60 cell differentiation and cell differentiation induction therapy by RA; (2) roles played by RA and retinal and their mechanisms of action; (3) retinoylation, post-translational protein-modified by RA, a novel non-genomic RA mechanism of action without RA receptor; (4) new actions of β-carotene and retinol in vivo and (5) potent anticancer effects of p-dodecylaminophenol (p-DDAP), a novel vitamin A derivative created from the RA derivative fenretinide. We propose that nutritional management of vitamin A can be effective at preventing and treating diseases, and that p-DDAP is a promising anticancer drug.

A splicing factor phosphorylated by protein kinase A is increased in HL60 cells treated with retinoic acid

Retinoic acid (RA) induces the differentiation of human promyelocytic leukemia HL60 cells into granulocytic cells and inhibits proliferation. Certain of actions of RA are mediated by RA nuclear receptors that regulate gene expression. However, it is also known that direct protein modification by RA (retinoylation) can occur. One such retinoylated protein in HL60 cells is a regulatory subunit of protein kinase A (PKA), which is increased in the nucleus following RA treatment and which then increases phosphorylation of other nuclear proteins. However, a complete understanding of which nuclear proteins are phosphorylated is lacking. In the current study, we employed mass spectrometry to identify one of the PKA-phosphorylated proteins as a serine/arginine-rich splicing factor 1 (SF2, SRSF1). We found that RA treatment increased the level of PKA-phosphorylated SF2 but decreased the level of SF2. While SF2 regulates myelogenous cell leukemia-1 (Mcl-1, anti-apoptotic factor), RA treatment reduced the level of Mcl-1L (full-length Mcl-1 long) and increased the level of Mcl-1S (Mcl-1 short; a short splicing variant of the Mcl-1). Furthermore, treatment with a PKA inhibitor reversed these effects on Mcl-1 and inhibited RA-induced cell differentiation. In contrast, treatment with a Mcl-1L inhibitor enhanced RA-induced cell differentiation. These results indicate that RA activates PKA in the nucleus, increases phosphorylation of SF2, raises levels of Mcl-1S and lowers levels of Mcl-1L, resulting in the induction of differentiation. RA-modified PKA may play an important role in inducing cell differentiation and suppressing cell proliferation.

Vitamin A in health care: Suppression of growth and induction of differentiation in cancer cells by vitamin A and its derivatives and their mechanisms of action

Vitamin A is an important micro-essential nutrient, whose primary dietary source is retinyl esters. In addition, β-carotene (pro-vitamin A) is a precursor of vitamin A contained in green and yellow vegetables that is converted to retinol in the body after ingestion. Retinol is oxidized to produce visual retinal, which is further oxidized to retinoic acid (RA), which is used as a therapeutic agent for patients with promyelocytic leukemia. Thus, the effects of retinal and RA are well known. In this paper, we will introduce (1) vitamin A circulation in the body, (2) the actions and mechanisms of retinal and RA, (3) retinoylation: another RA mechanism not depending on RA receptors, (4) the relationship between cancer and actions of retinol or β-carotene, whose roles in vivo are still unknown, and (5) anti-cancer actions of vitamin A derivatives derived from fenretinide (4-HPR). We propose that vitamin A nutritional management is effective in the prevention of cancer.

Changes in the levels of α-actinin-4 in differentiating human myeloid leukemia cells induced by retinoic acid

Retinoic acid (RA) induces granulocytic differentiation and inhibits the growth of human promyelocytic leukemia HL60 cells. α-Actinin-4 is a member of the α-actinin family, which exhibits unique mechanosensory regulation. Herein, we elucidated the effects of RA on α-actinin-4 expression during cell differentiation. RA increased the levels of α-actinin-4 protein significantly, while mRNA expression remained unchanged. In addition, RA treatment altered the intracellular localization of α-actinin-4 from the nucleus to the cytoplasm. Cells pretreated with RA, maintained α-actinin-4 protein levels after cycloheximide treatment as compared with control cells. The amount of ubiquitylated α-actinin-4 protein in RA-treated cells was less than in control cells. These results indicate that RA may inhibit nuclei transport and proteasomal degradation of α-actinin-4 protein. α-Actinin-4 may play a significant role in RA-induced differentiation, including the promotion of cytomorphology changes.

Retinoic acid receptors: from molecular mechanisms to cancer therapy

Retinoic acid (RA), the major bioactive metabolite of retinol or vitamin A, induces a spectrum of pleiotropic effects in cell growth and differentiation that are relevant for embryonic development and adult physiology. The RA activity is mediated primarily by members of the retinoic acid receptor (RAR) subfamily, namely RARα, RARβ and RARγ, which belong to the nuclear receptor (NR) superfamily of transcription factors. RARs form heterodimers with members of the retinoid X receptor (RXR) subfamily and act as ligand-regulated transcription factors through binding specific RA response elements (RAREs) located in target genes promoters. RARs also have non-genomic effects and activate kinase signaling pathways, which fine-tune the transcription of the RA target genes. The disruption of RA signaling pathways is thought to underlie the etiology of a number of hematological and non-hematological malignancies, including leukemias, skin cancer, head/neck cancer, lung cancer, breast cancer, ovarian cancer, prostate cancer, renal cell carcinoma, pancreatic cancer, liver cancer, glioblastoma and neuroblastoma. Of note, RA and its derivatives (retinoids) are employed as potential chemotherapeutic or chemopreventive agents because of their differentiation, anti-proliferative, pro-apoptotic, and anti-oxidant effects. In humans, retinoids reverse premalignant epithelial lesions, induce the differentiation of myeloid normal and leukemic cells, and prevent lung, liver, and breast cancer. Here, we provide an overview of the biochemical and molecular mechanisms that regulate the RA and retinoid signaling pathways. Moreover, mechanisms through which deregulation of RA signaling pathways ultimately impact on cancer are examined. Finally, the therapeutic effects of retinoids are reported.

Nuclear MEK1 sequesters PPARγ and bisects MEK1/ERK signaling: a non-canonical pathway of retinoic acid inhibition of adipocyte differentiation

Uncontrolled adipogenesis and adipocyte proliferation have been connected to human comorbidities. Retinoic acid (RA) is known to inhibit adipocyte differentiation, however the underlying mechanisms have not been adequately understood. This study reports that RA acting as a ligand to RA receptors (RARs and RXRs) is not a sine qua non to the inhibition of adipogenesis. Our intriguing observation of a negative correlation between increased retinoylation and adipogenesis led us to explore retinoylated proteins in adipocytes. Exportin (CRM1) was found to be retinoylated, which in turn can affect the spatio-temporal regulation of the important signaling molecule mitogen-activated protein kinase kinase 1 (MEK1), likely by disrupting its export from the nucleus. Nuclear enrichment of MEK1 physically sequesters peroxisome proliferator-activated receptor gamma (PPARγ), the master regulator of adipogenesis, from its target genes and thus inhibits adipogenesis while also disrupting the MEK1-extracellular-signal regulated kinase (ERK) signaling cascade. This study is first to report the inhibition of adipocyte differentiation by retinoylation.

Retinoids: Potent regulators of metabolism

Retinoids (vitamin A and its analogs) are highly potent regulators of cell differentiation, cell proliferation, and apoptosis. Because of these activities, retinoids have been most extensively studied in the contexts of embryonic development and of proliferative diseases, especially cancer and skin disease. Recently, there has been considerable new research interest focused on gaining understanding of the roles that retinoids and/or retinoid-related proteins may have in the development of metabolic diseases, primarily obesity, diabetes, and dyslipidemia. This review will summarize recent advances that have been made in these areas, focusing on the role of retinoids in modulating adipogenesis, the roles of retinoids and retinoid-related proteins as signaling molecules linking obesity with the development of type II diabetes, the roles of retinoids in pancreatic β-cell biology/insulin secretion, and the actions of retinoids in hepatic steatosis.

Demonstration of basic proteins that bind retinoic acid in the human myeloid leukemia cell line HL60

Retinoic acid (RA) has a variety of biological effects in mammalian cells and tissues. It is well known that RA is a potent anticancer agent that induces differentiation of leukemia cells as well as inhibiting cell growth. The current study examined HL60 proteins using anti-RA monoclonal antibodies (ARMAs) and found that some RA-binding proteins may be histones. These proteins eluted in the void volume fractions following Mono Q anion exchange chromatography and immunostained with ARMAs. These ARMAs showed specific binding to the proteins in a saturable manner that depended on antibody concentration. Certain of these proteins co-migrated with histones on one-dimensional polyacrylamide gel electrophoresis. It was also found that histones isolated from HL60 cells treated with RA also immunostained with ARMAs. These results indicate that basic proteins, including histones, may be bound to RA covalently in HL60 cells and that RA-binding histones may play significant roles in the transcriptional regulation of genes by RA.

Cytokeratins 16 and 10 bind to retinoic acid covalently in skin tissue of mice

BACKGROUND

Retinoic acid (RA) has various biological effects in mammalian cells and tissues. In epidermal cells, RA is an inhibitor of differentiation to the squamous phenotype. The molecular mechanisms underlying the effects of RA on epidermal cells and other cell types are mediated by RA nuclear receptors and retinoylation (acylation by RA) of proteins.

OBJECTIVES

To understand the components responsible for RA effects via RA nuclear receptors and retinoylation.

METHODS

We examined for the first time RA-binding proteins in mouse skin in vivo by immunoblotting using anti-RA monoclonal antibodies and identified by matrix-assisted laser desorption ionization-time of flight mass spectrometry.

RESULTS

We identified eight RA-binding proteins in the skin of hairless mice that were increased by topical RA treatment. Three of these proteins were identified as cytokeratin 10, cytokeratin 16 and serum albumin.

CONCLUSION

These results raise the possibility that RA binding to cytokeratins in vivo may be involved in the effect of RA on keratinocytes in mouse skin.

Retinoic acid-induced testosterone production and retinoylation reaction are concomitant and exhibit a positive correlation in Leydig (TM-3) cells

Retinoic acid (RA) exerts diverse biological effects in the control of cell growth in embryogenesis and oncogenesis. The effects of RA are thought to be mediated by the nuclear retinoid receptors; however, not all the effects of RA can be explained by the nuclear receptor pathways. Indeed, retinoylation is another mechanism of action elicited by RA. In growing TM-3 Leydig cell cultures, the extent of retinoylation depends in a saturable manner on the initial concentration of 3H-RA, time and cell number. In addition, dose-response curves for RA-induced testosterone production and retinoylation are concomitant and exhibit a positive correlation. In the present study we demonstrate that RA is able to influence a retinoylation reaction on protein(s) probably involved on steroidogenesis.

Formation of retinoylated proteins from retinoyl-CoA in rat tissues

Retinoylation (acylation of proteins by retinoic acid) is considered as one mechanism of retinoic acid (RA) action occurring in cells in vitro and in vivo. Previously, our studies showed that in rat tissues the formation of retinoyl-CoA from RA, the first step of retinoylation, required ATP, CoA and MgCl(2). In the current study, we examined whether the transfer of retinoyl-CoA into proteins, the second step of retinoylation, occurs in rat tissues. [(3)H]-Labeled-retinoyl-CoA bound covalently to proteins in rat liver, kidney, testis, and brain. The levels of incorporation of retinoyl-CoA into proteins were higher in vitamin A-deficient rats than in normal ones. The formation of retinoylated proteins depended on the incubation time, and the concentrations of retinoyl-CoA and homogenate. The reaction was suppressed by fatty acyl-CoAs and palmitic acid, but not by arachidonic acid. The Vmax and Km values for retinoyl-CoA in the formation of retinoylated proteins using a crude liver extract were estimated to be 2,597.3 pmol/min/mg protein and 9.5 x 10(-5) M, respectively. Retinoylated proteins formed from retinoyl-CoA, including a 17 kDa protein exhibiting high radioactivity, disappeared in the presence of 2-mercaptoethanol, indicating that RA was linked to the proteins through a thioester bond. These results demonstrate that retinoylation in rat tissues occurs via retinoyl-CoA formed from RA. This process may play a significant physiological role in cells.

[Induction of cell differentiation and development of new anticancer drugs]

Cell differentiation is essential for normal growth and homeostasis, and drug-induced differentiation of tumor cells into benign or normal cells is an important approach for anticancer chemotherapy. Studies of induction mechanisms for cell differentiation and discovery of differentiation-inducing factors are thus critical components of drug development. The Screening of differentiation-inducing factors, such as purified aldehyde reductase, a xenobiotic metabolite enzyme, that induces differentiation of human acute myeloid leukemia HL60 cells into monocyte/macrophage cells is described. Mechanisms of all-trans-retinoic acid (RA)-induced differentiation are also covered. RA is a potent inducer of HL60 cell differentiation and when used as a sole agent it can induce complete remission in patients with acute promyelocytic leukemia (APL). While one mechanism of the effect of RA involves RA nuclear receptors, retinoylation (a posttranslational modification of proteins by RA) may be a new nongenomic mechanism by which RA acts on cells. An early event in RA-induced differentiation may be retinoylation of RII alpha (regulatory subunits of cAMP-dependent protein kinase), in which RII alpha units are retinoylated and the retinoylated RII alpha is then translocated to the nucleus. Drugs can also be combined with RA in RA-differentiation therapy. Cytodifferation therapy by RA in APL patients exhibits limitations due to the resistance of relapsed patients to further RA treatment. This may occur through the induction of expression of various genes that reduce RA blood concentrations. Treatment with combinations of RA and other agents may be one way to reduce induction of those genes. Good candidates for such agents include cAMP-elevating agents, retinoids, steroids, and fatty acids that synergistically induce differentiation of HL60 cells. Two derivatives of falconensone A, falconensone A p-bromophenylhydrazone, which has a bromophenyl residue, and falconensone A dioxime, which possesses a hydroxy residue, were synthesized to incorporate features of RA and N-[4-hydroxyphenyl] retinamide. Both derivatives have exhibited more potent biological activity than the parent falconensone A in vitro and in vivo.

Retinoylation of proteins in rat hepatocytes following uptake of chylomicron remnant retinyl ester

Several proteins may covalently bind retinoic acid, a process called retinoylation. Recently, we have demonstrated that proteins were retinoylated in vivo in liver, kidney and lung. In order to gain further knowledge about the mechanism of this process, we studied retinoylation in rat hepatocytes administered vitamin A as [3H]retinyl esters in chylomicron remnants. This resembles the normal physiological uptake of vitamin A. After 24 h incubation, about 0.0017 mol [3H]retinoid was covalently bound per mol protein. Citral, an inhibitor of the oxidation of retinol to retinoic acid, reduced retinoylation about 40%, indicating that oxidation of retinol to retinoic acid is necessary for a large fraction of the observed covalent modification of proteins. When cells were incubated with physiological concentrations of [3H]retinol or [3H]retinoic acid dissolved in ethanol, much less retinoid was covalently bound per mol protein compared with cells incubated with chylomicron remnant. Saturation of the retinoylation was apparent with retinoic acid around the physiological concentration. Retinoylated proteins were also analysed by SDS-PAGE. In general, the same protein bands were labelled with both [3H]retinol and [3H]retinoic acid, although the intensity of the bands varied. Major bands had an apparent molecular weight of about 16, 35, 50 and 120 kDa. In a parallel experiment in which liver stellate cells were incubated with [3H]retinol, major retinoylated protein bands were about 35, 60 and 65 kDa. Thus, different proteins appear to be retinoylated in hepatocytes and liver stellate cells, suggesting that protein retinoylation is a cell specific phenomenon. These results demonstrate that retinoids presented to hepatocytes as chylomicron remnant retinyl esters are covalently linked to proteins. We therefore suggest that retinoylation of proteins represents a minor but significant pathway whereby cells metabolize vitamin A.

The effect of aging and dietary restriction on the retinoylation of nuclear matrix proteins in rats

The labeling in vivo of young ad libitum (Y/AL) and old diet restricted (O/DR) rats with [3H]retinoic acid (RA) for 6 hours, and the exposure of electrophoretically separated nuclear matrix proteins from bone marrow tissue on film for 48 days revealed the presence of eleven retinoylated proteins. Dosing with RA (100 mg/kg body weight) for 96 hours and exposure to [3H]RA enhanced the levels of radioactive incorporation of several nuclear matrix proteins, including p51, and p55, similarly in Y/AL and O/DR rats. Dosing of old ad libitum (O/AL) rats with [3H]RA for 6 hours showed the incorporation of six proteins following 48 days of exposure on film. Long-term dosing of RA (96 hours) did not increase [3H]RA incorporation in these proteins, including p51 and p55, in O/AL rats. Increasing the level of RA by two-fold (200 mg/kg body weight) in Y/AL and O/DR rats elicited an increase in the incorporation levels of [3H]RA in five proteins. This dose response following increased levels of RA was not seen in the retinoylated proteins of O/AL animals. Analysis by the Western blotting technique showed p51 and p55 from rat bone marrow cells to have the same immunochemical determinates with proteins of identical molecular masses in HL60 cells. The levels of retinoylation of nuclear matrix proteins in O/DR animals, altered by age- and diet-dependent factors, suggests a condition that is more reminiscent of Y/AL than of O/AL animals.

Unassembled (soluble) vimentin in human myeloid leukemia cell line HL60

The intermediate filament proteins which include vimentin, desmin, and the keratins are one of three major classes of cytoskeletal proteins in eukaryotic cells. In this study we found that most of the vimentin of undifferentiated HL60 and cells induced to differentiate either along the monocytoid pathway by 12-O-tetradecanoylphorbol-13-acetate (TPA) or along the granulocytic pathway by retinoic acid was soluble in a buffer containing 1% Triton X-100/0.6 mol/l KCl in which the intermediate filament proteins usually are not soluble. HL60 vimentin separated on polyacrylamide gel electrophoresis into two proteins of Mr 55,000 and 54,000 that we detected by immunoblotting. The Mr 55,000 species was the major form in undifferentiated HL60 cells and cells induced by retinoic acid. The distribution of both forms of vimentin changed during induction of differentiation by TPA and after 24 h the Mr 54,000 species was predominant. After an additional 24 h exposure to TPA the relative levels of the two forms of vimentin approached equivalence and a high level of vimentin degradation products was seen. These results suggest that TPA may increase vimentin degradation along a pathway that has a Mr 54,000 intermediate. In addition, the high levels of soluble vimentin in HL60 cells suggests that these cells may be a good model for studying components involved in vimentin assembly.

Retinoic acid and cyclic AMP synergistically induce the expression of liver/bone/kidney-type alkaline phosphatase gene in L929 fibroblastic cells

In L929 mouse fibroblastic cells, liver/bone/kidney type alkaline phosphatase (L/B/K-ALP) enzymic activity is induced by all-trans-retinoic acid at concentrations between 10(-6) and 10(-5) M. At lower concentrations, retinoic acid is incapable of inducing this enzymic activity per se, but increases cyclic AMP (cAMP)-mediated induction. This effect is observed after incubation of the retinoid with dibutyryl cAMP, 8-bromo cAMP or forskolin. The synergism is dependent on the order of addition of retinoic acid and the activator of the cAMP pathway. Contemporaneous addition of the two agents, or addition of cAMP prior to retinoic acid (but not addition of retinoic acid before cAMP), is necessary to produce this synergistic interaction. The synergism results in increased steady-state levels of L/B/K-ALP mRNA and it is the consequence of increased transcriptional activity of the gene. The expression of the mouse L/B/K-ALP gene is regulated by the presence of two leader exons, 1A and 1B, resulting in the synthesis of two alternatively spliced mRNAs that are different only in part of their 5' untranslated region [Studer, Terao, Giannì and Garattini (1991) Biochem. Biophys. Res. Commun. 179, 1352-1360]. PCR amplification and nuclear run-on experiments performed using probes specific for each leader exon demonstrate that treatment of these cells with retinoic acid, forskolin or dibutyryl cAMP, and with the combination of the retinoid and one of the cAMP-elevating agents, leads to the accumulation of nascent and mature L/B/K-ALP mRNA containing exon 1B. The synergistic induction of the transcription of the L/B/K-ALP gene is well correlated with quantitative and qualitative changes of retinoic-acid-receptor mRNAs mediated by cAMP.

Vitamin A as a hormone: recent advances in understanding the actions of retinol, retinoic acid, and beta carotene

Within the past few years, much has been learned about the metabolism and actions of vitamin A and the carotenoids. This article reviews the biochemical and cellular events in retinoid metabolism that lead to production of retinoic acid, an active metabolite of vitamin A. Retinoic acid functions in a hormone-like manner to regulate the expression of a number of genes. Beta carotene is now under study as an anticancer agent and for its possible beneficial effects in a number of chronic diseases. Current recommendations for carotene intake exceed the usual daily intake nearly fourfold.

Covalent modification of proteins by ligands of steroid hormone receptors

Retinoylation, acylation with retinoic acid (RA), is a covalent modification of proteins occurring in a variety of eukaryotic cell lines. In this study, we found that proteins in HL-60 cells were labeled by 17 beta-[3H]estradiol (E2), [3H]progesterone (Pg), 1 alpha,25-dihydroxy[3H]vitamin D3 [1,25(OH)2D3], [125I]triiodothyronine (T3), [125I]thyroxine (T4), and [3H]prostaglandin E2 (PGE2). All of these hormones, except PGE2, are ligands of the steroid hormone receptor family. Addition to the growth medium of 5 microM ketoconazole, an inhibitor of cytochrome P450-dependent enzymes, increased about 2-fold the labeling of proteins by T3, T4, 1,25(OH)2D3, and PGE2. In contrast, ketoconazole did not change markedly the extent of labeling by RA, E2, or Pg. Alkaline methanolysis, which cleaves ester bonds, released variable percentages of the radioactive ligands bound to protein. These values were about 80% for RA and PGE2; 50% for T3, T4, and Pg; and 20% for E2 and 1,25(OH)2D3. Treatment with thioether-cleavage reagents, iodomethane or Raney nickel catalyst, released < 2% of the covalently bound ligands. Two-dimensional polyacrylamide gel electrophoresis patterns of labeled proteins were unique for each ligand. Proteins of M(r) 47,000 and 51,000 were labeled by RA, E2, T3, and T4. These proteins had the same mobilities as RI and RII, the cAMP-binding regulatory subunits of type I and type II cAMP-dependent protein kinases. 1,25(OH)2D3 also bound to proteins of M(r) 47,000 and 51,000. However, these proteins had pI values different from those of RI or RII. These results suggest that some activities of ligands of the steroid hormone receptor family and of PGE2 may be mediated by their covalent modification of proteins.

The covalent labeling of proteins by 17 beta-estradiol, retinoic acid, and progesterone in the human breast cancer cell lines MCF-7 and MCF-7/AdrR

In this study we analyzed the covalent binding to proteins of 17 beta-estradiol (E2), retinoic acid (RA), and progesterone in MCF-7 and MCF-7/AdrR cells. MCF-7 cells have receptors for E2 and progesterone. MCF-7/AdrR cells do not have these receptors. After a 1-day incubation period with either [3H]E2, [3H]progesterone, or [3H]RA the levels of covalently bound radioactivity was between 1.4- to 2-fold greater in MCF-7 cells than in MCF-7/AdrR cells. We analyzed the labeled proteins with two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) and fluorography. About 40 proteins were labeled by E2 in MCF-7 cells and about 10 of these proteins were the only proteins labeled by E2 in MCF-7/AdrR cells. We saw that the same 8 proteins were labeled by RA in both cell lines. Progesterone labeled 2 proteins with M(r) values of 37,000 and 20,000 in MCF-7 cells. These 2 proteins had mobilities that were the same as proteins that were labeled by either E2 or RA in both MCF-7 and MCF-7/AdrR cells. Besides these 2 proteins, we saw proteins of M(r) 51,000 (p51) and 55,000 that were covalently labeled by E2 in MCF-7 cells and by RA in both MCF-7 and MCF-7/AdrR cells. The p51 had the same mobility on 2D-PAGE as an 8-azido-[32P]cAMP-labeled protein. This protein is probably RII alpha, the type II cAMP-binding regulatory subunit of type II cAMP-dependent protein kinase. These results suggest that the estrogen receptor, while not obligatory, might still modulate the covalent linkage of E2 to protein. In addition, our results raise the possibility that some effects of some ligands of the thyroid/steroid hormone receptor family may involve the covalent linking of these hormones to proteins, including RII alpha.

Retinoylation of the cAMP-binding regulatory subunits of type I and type II cAMP-dependent protein kinases in HL60 cells

Retinoylation (retinoic acid acylation) is a post-translational modification of proteins occurring in a variety of eukaryotic cell lines. There are at least 20 retinoylated proteins in the human myeloid leukemia cell line HL60 (N. Takahashi and T.R. Breitman (1990) J. Biol. Chem. 265, 19, 158-19, 162). Here we found that some retinoylated proteins may be cAMP-binding proteins. Five proteins, covalently labeled by 8-azido-[32P]cAMP which specifically reacts with the regulatory subunits of cAMP-dependent protein kinase, comigrated on two-dimensional polyacrylamide gel electrophoresis with retinoylated proteins of Mr 37,000 (p37RA), 47,000 (p47RA), and 51,000 (p51RA) labeled by [3H]retinoic acid treatment of intact cells. Furthermore, p47RA coeluted on Mono Q anion exchange chromatography with the type I cAMP-dependent protein kinase holoenzyme and p51RA coeluted on Mono Q anion exchange chromatography with the type II cAMP-dependent protein kinase holoenzyme. An antiserum specific to RI, the cAMP-binding regulatory subunit of type I cAMP-dependent protein kinase, immunoprecipitated p47RA. An antiserum specific to RII, the cAMP-binding regulatory subunit of type II cAMP-dependent protein kinase, immunoprecipitated p51RA. These results indicate that both the RI and the RII regulatory subunits of cAMP-dependent protein kinase are retinoylated. Thus, an early event in RA-induced differentiation of HL60 cells may be the retinoylation of subpopulations of both RI and RII.

Retinoylation of cytokeratins in normal human epidermal keratinocytes

Retinoylation (retinoic acid acylation) is a covalent modification of proteins occurring in a variety of eukaryotic cell lines. In this study, we found that proteins in undifferentiated and squamous-differentiated normal human epidermal keratinocytes were retinoylated after treatment with [3H]retinoic acid. The major retinoylated proteins were identified as cytokeratins based on their profile in two-dimensional gel electrophoresis and their immunoreactivity with anti-keratin monoclonal antibodies. The covalently bound [3H]retinoic acid was not removed by mild hydrolysis with methanolic-KOH indicating that it is not linked to the cytokeratins by a thioester bond. The results raise the possibility that retinoylation of cytokeratins is involved in some of the effects of retinoic acid on keratinocytes.