Relationship among methylation,isoprenylation, and GTP binding in 21-to 23-kDa proteins of neuroblastoma

1. Dimethylsulfoxide-induced differentiated neuroblastoma express high levels of membrane 21 to 23-kDa carboxyl methylated proteins. Relationships among methylation, isoprenylation, and GTP binding in these proteins were investigated. Protein carboxyl methylation, protein isoprenylation, and [alpha-32P]GTP binding were determined in the electrophoretically separated proteins of cells labeled with the methylation precursor [methyl-3H]methionine or with an isoprenoid precursor [3H]mevalonate. 2. A broad band of GTP-binding proteins, which overlaps with the methylated 21 to 23-kDa proteins, was detected in [alpha-32P]GTP blot overlay assays. This band of proteins was separated in two-dimensional gels into nine methylated proteins, of which four bound GTP. 3. The carboxyl-methylated 21 to 23-kDa proteins incorporated [3H]mevalonate metabolites with characteristics of protein isoprenylation. The label was not removed by organic solvents or destroyed by hydroxylamine. Incorporation of radioactivity from [3H]mevalonate was enhanced when endogenous levels of mevalonate were reduced by lovastatin, an inhibitor of mevalonate synthesis. Lovastatin blocked methylation of the 21 to 23-kDa proteins as well (greater than 70%). 4. Methylthioadenosine, a methylation inhibitor, inhibited methylation of these proteins (greater than 80%) but did not affect their labeling by [3H]mevalonate. The results suggest that methylation of the 21 to 23-kDa proteins depends on, and is subsequent to, isoprenylation. The sequence of events may be similar to that known in ras proteins, i.e., carboxyl methylation of a C-terminal cysteine that is isoprenylated. 5. Lovastatin reduced the level of small GTP-binding proteins in the membranes and increased GTP binding in the cytosol. Methylthioadensoine blocked methylation without affecting GTP binding. 6. Thus, isoprenylation appears to precede methylation and to be important for membrane association, while methylation is not required for GTP binding or membrane association. The role of methylation remains to be determined but might be related to specific interactions of the small GTP-binding proteins with other proteins.     

Post-translational modification of low molecular mass GTP-binding proteins by isoprenoid

Several proteins in mammalian cells are modified post-translationally by the isoprenoid, farnesol. Incubation of cultured cells with [3H]mevalonate, an isoprenoid precursor, results in the labeling of multiple polypeptides, the most prominent of which migrate in the range of 21-26 kDa on sodium dodecyl sulfate-polyacrylamide gels. In Rat-6 fibroblasts transformed by H-ras, one of the farnesylated proteins was identified as p21ras by two-dimensional immunoblotting. However, this protein accounted for only a small proportion of the [3H]mevalonate-derived radioactivity incorporated into 21-26-kDa proteins. Murine erythroleukemia cells, which did not express immunodetectable quantities of p21ras, contained several 21-26-kDa farnesylated proteins distributed in both the cytosolic and particulate fractions. At least eight of these proteins were capable of binding [alpha-32P]GTP on nitrocellulose membranes. Pulse-chase studies showed that the isoprenoid modification did not necessarily result in the translocation of the cytosolic proteins to the cell membrane. A prominent group of carboxyl-methylated proteins in murine erythroleukemia cells overlapped with the 21-26-kDa farnesylated proteins on one-dimensional sodium dodecyl sulfate gels. Methylation of this group of proteins was selectively abolished when cells were treated with lovastatin, an inhibitor of isoprenoid synthesis. Addition of exogenous mevalonate to the lovastatin-treated cells fully restored carboxyl methylation. These studies suggest that the 21-26-kDa farnesylated proteins in mammalian cells are members of a recently discovered family of low molecular mass GTP-binding proteins which, although ras-related, appear to be distinct structurally and possibly functionally from the products of the ras genes. The observed isoprenoid-dependent carboxyl methylation of a group of 21-26-kDa proteins suggests that the low molecular mass GTP-binding proteins may undergo a series of post-translational C-terminal cysteine modifications (i.e. farnesylation, carboxyl methylation) analogous to those recently elucidated for p21ras.     

Expression of a 24 kDa GTP-binding protein (Gn24) is increased in lovastatin treated human erythroleukemia cells

A major 27 kDa particulate and a minor 24 kDa cytosolic GTP-binding protein was detected in HEL cells upon incubation with [-³²P]GTP of nitrocellulose blots containing polypeptides separated using SDS-PAGE. Addition of lovastatin (30 M) to HEL cells in culture inhibited protein synthesis by 35%. However, this treatment resulted in a 5-fold increase, as quantitated by [-³²P]GTP binding, in the amount of cytosolic 24 kDa GTP-binding protein. Addition of cycloheximide plus lovastatin to cells in culture abolished the observed increase in 24 kDa GTP-binding protein. Incubation of cells with lovastatin plus [R,S]-[5-³H]mevalonolactone resulted in the incorporation of radioactivity into several polypeptides in both the cytosolic and particulate fractions including a polypeptide of molecular mass of 24 kDa in the cytosol. The mobility of this 24 kDa isoprenylated protein on SDS-PAGE was identical to that of the GTP-binding protein increased in response to lovastatin. However, the 24 kDa protein remained in the cytosol after undergoing isoprenylation. The 24 kDa protein was distinct from the HEL cell, G25K/CDC42Hs GTP-binding protein and the GTP-binding protein that was a substrate for botulinum toxin C3 catalyzed ADP-ribosylation. Results demonstrate that lovastatin specifically increases the expression of a 24 kDa GTP-binding protein in HEL cells and that, isoprenylation of low molecular mass GTP-binding protein(s) may have function(s) in addition to its role in the targetting of these proteins to cell membrane.     

Isoprenoid modification of G25K (Gp), a low molecular mass GTP-binding protein distinct from p21ras

Cultured murine erythroleukemia (MEL) cells synthesize a number of low molecular mass GTP-binding proteins that undergo post-translational modification by isoprenoids. We used two-dimensional electrophoresis and immunoblotting to show that a 23-24-kDa protein labeled by the isoprenoid precursor [3H]mevalonate was specifically recognized by an antibody to G25K (Gp), a low molecular mass GTP-binding protein originally purified from placental, platelet, and brain membranes. Several isoelectric variants of G25K were detected in MEL cells, and all were radiolabeled with [3H]mevalonte. The G25K-immunoreactive protein did not cross-react with pan-ras antibody. Although mature p21ras is known to be localized in the cell membrane, most of the isoprenylated G25K was found in the 100,000 x g supernatant fraction when cells were lysed in buffer without detergent. Blocking isoprenoid synthesis by incubation of MEL cells with lovastatin resulted in a decrease in the concentration of G25K in the particulate fraction and a corresponding increase in immunodetectable protein in the soluble fraction. Lovastatin treatment also produced shifts in the electrophoretic mobilities of the G25K isoforms on two-dimensional gels. These observations are consistent with the idea that isoprenylation plays a permissive role in the association of G25K with the cell membrane or other organelles. However, the high proportion of soluble isoprenylated G25K in MEL cells under normal culture conditions suggests that the role of the isoprenoid modification may be more complex than simply serving as a structural anchor for stable insertion of proteins into the lipid bilayer.     

Isoprenylated Proteins in Myelin

Abstract: Incubation of rat brainstem slices with [³H]- mevalonate ([³H]MVA) in the presence of lovastatin resulted in the incorporation of label into three groups of myelin-associated proteins with molecular masses of 47, 21–27, and 8 kDa, as revealed on sodium dodecyl sulfate- polyacrylamide rod gel electrophoresis. Although the gel patterns of [³H]MVA-derived prenylated proteins were similar, the relative level of ³H incorporated into each protein species differed between myelin and the brainstem homogenate. Immunoprecipitation studies identified the 47-kDa prenylated protein as a 2′-3′-cyclic nucleotide phospho- diesterase, whereas the 8-kDa protein proved to be the γ subunit of membrane-associated guanine nucleotide regulatory protein. The ³H-labeled 21–27-kDa group in myelin corresponds to the molecular mass of the extensive Ras- like family of monomeric GTP-binding proteins known to be prenylated in other tissues. Increase in lovastatin concentration resulted in reduced levels of [³H]MVA-labeled species in myelin and concomitantly increased levels in the cytosol. A cold MVA chase restored to normality the appearance of [³H]MVA-labeled proteins in myelin. Furthermore, a high lovastatin concentration in the brainstem slice incubation mixture altered the appearance of newly synthesized nonprenylated myelin proteins, including proteolipid protein and the 17-kDa subspecies of myelin basic protein. Because other myelin proteins were unaffected by the high lovastatin concentration, restricting the availability of MVA in myelin-forming cells may selectively alter processes required for myelinogenesis. Although the molecular basis for the” different MVA requirements in myelin- forming cells remains undefined, it may involve an alteration in the biological activity of certain proteins that require prenylation to be functionally active, and that are responsible for promoting insertion of specific proteins into the myelin membrane.     

Post-translational isoprenylation of cellular proteins is altered in response to mevalonate availability

Cells incorporate isoprenoid products derived from mevalonate (MVA) into several unique proteins. The aim of this study was to delineate the effects of blocking MVA synthesis on the covalent isoprenylation of these proteins in murine erythroleukemia cells. Inhibition of protein synthesis with cycloheximide prevented the incorporation of [3H]MVA into proteins, suggesting that isoprenylation normally occurs immediately after synthesis of the polypeptides. However, incubation of cells with lovastatin, a competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, for as little as 1 h prior to addition of cycloheximide rendered the isoprenylation step insensitive to cycloheximide. Lovastatin had no apparent effect on the stability of the isoprenylated proteins, but the development of cycloheximide insensitivity during the lovastatin preincubation was dependent on synthesis of new protein during that period. Addition of 50-200 microM MVA to the culture medium eliminated the effects of preincubation with lovastatin. Preincubation of cells with 25-hydroxycholesterol, which suppresses the synthesis and enhances the degradation of HMG-CoA reductase but is not a competitive enzyme inhibitor, did not induce cycloheximide-insensitivity of the isoprenylation reaction. The results suggest that blocking MVA synthesis with lovastatin causes a rapid depletion of isoprenoid groups available for protein modification. Consequently, there is an accumulation of non-isoprenylated substrate proteins. Shifts in the ratio of modified vs. unmodified proteins in response to MVA availability may have implications for the changes in cell morphology, cell proliferation and HMG-CoA reductase gene expression that occur when cells are subjected to MVA deprivation.     

Protein Methylation in Cerebellar Synaptosomes

Abstract: Synaptosomes from five regions of adult rat brain were isolated, analyzed for methyl acceptor proteins, and probed for methyltransferases by photoaffinity labeling. Methylated proteins of 17 and 35 kDa were observed in all regions, but cerebellar synaptosomes were enriched in a 21–26-kDa family of methyl acceptor proteins and contained a unique major methylated protein of 52 kDa and a protein of 50 kDa, which was methylated only in the presence of EGTA. When cerebellar and liver subcellular fractions were compared, the cytosolic fractions of each tissue contained methylated proteins of 17 and 35 kDa; liver membrane fractions contained few methylated proteins, whereas cerebellar microsomes had robust methylation of the 21–26-kDa group. Differential centrifugation of lysed cerebellar synaptosomes localized the 17- and 35-kDa methyl acceptor proteins to the synaptoplasm, the 21–26-kDa family to the synaptic membranes, and the 52-kDa to synaptic vesicles. The 21–26-kDa family was identified as GTP-binding proteins by [α-³²P]GTP overlay assay; these proteins contained a putative methylated carboxyl cysteine, based on the presence of volatile methyl esters and the inhibition of methylation by acetylfarnesylcysteine. The 52-kDa methylated protein also contained volatile methyl esters, but did not bind [α-³²P]GTP. When synaptosomes were screened for putative methyltransferases by S -adenosyl-L-[ methyl -³H]methionine photoaffinity labeling, a protein of 24 kDa was detected only in cerebellum, and this labeled protein was localized to synaptic membranes.     

Identification of highly methylated arginine residues in an endogenous 20-kDa polypeptide in cancer cells.

Enzymatic methylation of endogenous proteins in several cancer cell lines was investigated to understand a possible relationship between protein-arginine methylation and cellular proliferation. Cytosolic extracts prepared from several cancer cells (HeLa, HCT-48, A549, and HepG2) and incubated with S-adenosyl-L-[methyl-3H]methionine revealed an intensely [methyl-3H]-labeled 20-kDa polypeptide. On the other hand, cytosolic extracts prepared from normal colon cells did not show any methylation of the 20-kDa protein under identical conditions. To identify nature of the 20-kDa polypeptide, purified histones were methylated with HCT-48 cytosolic extracts and analyzed by SDS-PAGE. However, none of the histones comigrated with the methylated 20-kDa polypeptide, indicating that it is unlikely to be any of the histone subclasses. The [methyl-3H]group in the 20-kDa polypeptide was stable at pH 10-11 (37 degrees C for 30 min) and methylation was not stimulated by GTPgammaS (4 mM), thus the reaction is neither carboxyl methylesterification on isoaspartyl residues, nor on C-terminal farnesylated cysteine. The present study together with the previous identification of N(G)-methylated arginine residues in the HCT-48 cytosol fraction suggests that this novel endogenous 20-kDa arginine-methylation is a cellular proliferation-related posttranslational modification reaction.     

Selective inhibition of isoprenylation of 21-26-kDa proteins by the anticarcinogen d-limonene and its metabolites

Limonene has chemotherapeutic activity against chemically induced rat mammary carcinomas, many of which contain activated ras genes. Given the recent discovery of the post-translational modification of p21ras and other cell growth-associated proteins by intermediates in the mevalonic acid pathway, and the common biochemical origins of limonene and these isoprene products, we investigated the effect of limonene on protein isoprenylation. NIH3T3 and human mammary epithelial cells were incubated with lovastatin and [2-14C]mevalonolactone in the absence and presence of limonene. Labeled proteins were then subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography. Limonene inhibited isoprenylation of a class of cellular proteins of 21-26 kDa, including p21ras and possibly other small GTP-binding proteins, in a dose-dependent manner in both cell lines. In contrast, limonene did not affect the isoprenylation of several other proteins, including nuclear lamins. Limonene is metabolized extensively in vivo but not in cultured cells. The two major rat serum metabolites of limonene, perillic acid and dihydroperillic acid, were more potent than limonene in the inhibition of isoprenylation. These results demonstrate that limonene selectively inhibits isoprenylation of 21-26-kDa proteins at a point in the mevalonic acid pathway distal to 3-hydroxy-3-methylglutaryl coenzyme A reductase, and they provide a plausible explanation for its chemotherapeutic activity. Inhibition of isoprenylation of proteins such as p21ras and other small GTP-binding proteins would alter their intracellular localization and, hence, disrupt their biological activity.     

rab GTP-binding proteins with three different carboxyl-terminal cysteine motifs are modified in vivo by 20-carbon isoprenoids.

p21ras and several other ras-related GTP-binding proteins are modified post-translationally by addition of 15-carbon farnesyl or 20-carbon geranylgeranyl isoprenoids to cysteines within a conserved carboxyl-terminal sequence motif, Caa(M/S/L), where a is an aliphatic amino acid. Proteins ending with M or S are substrates for farnesyltransferase, whereas those ending with L are modified preferentially by geranylgeranyltransferase. We recently reported that GTP-binding proteins encoded by rab1B (GGCC), rab2 (GGCC), and rab5 (CCSN) are modified by 20-carbon isoprenyl derivatives of [3H]mevalonate when translated in vitro, despite having carboxyl-terminal sequences distinct from the Caa(M/S/L) motif. We now show that these proteins function as specific acceptors for geranylgeranyl in vitro and are modified by 20-carbon isoprenyl groups in COS cells metabolically labeled with [3H]mevalonate. Proteins encoded by rab4 and rab6, with yet another distinct carboxyl-terminal motif (xCxC), are similarly modified by 20-carbon isoprenoids in vitro and in vivo. The geranylgeranyl modification of rab5 protein (CCSN) is catalyzed by an enzyme in brain cytosol but not by a purified geranylgeranyltransferase that modifies GTP-binding proteins with the CaaL motif. Unlike the prenylation of proteins with Caa(M/S/L) termini, the prenylation of rab5 protein is not inhibited by a synthetic peptide based on its carboxyl-terminal sequence (TRNQCCSN). When cellular isoprenoid synthesis is blocked by treatment of cells with lovastatin, rab proteins that are normally localized in membranes of the endoplasmic reticulum, Golgi apparatus, and endosomes accumulate in the cytosol. This change in rab protein localization is reversed by providing cells with mevalonate. These findings suggest that geranylgeranyl modification underlies the ability of rab GTP-binding proteins to associate with intracellular membranes, where they are postulated to function as mediators of vesicular traffic.     

Increased methylation of endogenous 20-kDa protein in HIT beta-cell during insulin secretion

Enzymatic methylation of endogenous proteins in clonal pancreatic beta-cell, HIT-T15, was investigated. When cell extract incubated with S-adenosyl-L-[methyl-3H]methionine was subjected to SDS-PAGE followed by fluorography, endogenous 20-kDa protein was highly [methyl-3H]-labeled. The increase of methylation was correlated with insulin secretion, when the cells were treated with secretagogue; at 5.5mM glucose, insulin secretion increased by 2.5-fold, while the 20-kDa methylation to about 3.2-fold. In the case of forskolin, another secretagogue, at 0.1mM, the methylation increased by approximately 4.5-fold. This increase of 20-kDa methylation was inhibited when the cells were treated with 3mM EGTA to inhibit insulin secretion by depleting extracellular calcium ion, indicating intercausal relation between methylation and insulin secretion. The [methyl-3H]-labeled amino acids were identified by thin layer chromatography as N(G)-methylated arginines. While arginyl residues in Gly-Arg-Gly sequence are known to be posttranslationally methylated, a synthetic nonapeptide, GGRGRGRGG, competed with the 20-kDa methylation; at 1 and 10 micro M nonapeptides, 62% and 78% of 20-kDa methylation were inhibited, respectively. Furthermore, Western immunoblot analysis of HIT cell extract against GGRGRGRGG antibodies strongly immunoreacted with the 20-kDa protein. These results suggested that methylation of the endogenous 20-kDa protein might play some role in insulin secretion.     

Evidence for the carboxyl methylation of nuclear lamin-B in the pancreatic beta cell

Lamins are intermediate filament proteins that constitute the main components of the lamina underlying the inner-nuclear membrane and serve to organize chromatin. Lamins (e.g., lamin-B) undergo posttranslational modifications (e.g., isoprenylation and methylation) at their C-terminal cysteine. Such modifications are thought to render optimal association of lamins with the nuclear envelop. Herein, we examined whether nuclear lamin-B undergoes carboxyl methylation in islet beta cells. A 65- to 70-kDa protein was carboxyl methylated in intact rat islets and clonal beta (HIT or INS) cells or in homogenates which could be immunoprecipitated using lamin-B antiserum. Incubation of purified HIT cell-nuclear fraction with [(3)H]S-adenosyl methionine yielded a single carboxyl methylated protein peak (ca. 65-70 kDa); this protein was immunologically identified as lamin-B. Several methylation inhibitors, including acetyl farnesyl cysteine, a competitive inhibitor of protein prenyl cysteine methylation, inhibited the carboxyl methylation of lamin-B, indicating that the carboxyl-methylated amino acid is cysteine. These findings, together with our recent observations demonstrating that inhibition of protein isoprenylation causes apoptotic death of the pancreatic beta cell, raise an interesting possibility that inhibition of C-terminal cysteine modifications of lamin-B might result in disruption of nuclear assembly, leading to further propagation of apoptotic signals, including DNA fragmentation and chromatin condensation.     

Isoprenoid requirement for intracellular transport and processing of murine leukemia virus envelope protein.

Lovastatin blocks the biosynthesis of the isoprenoid precursor, mevalonate. When Friend murine erythroleukemia (MEL) cells are cultured in medium containing lovastatin, the precursor of murine leukemia virus envelope glycoprotein (gPr90env) fails to undergo proteolytic processing, which normally occurs in the Golgi complex. Consequently, newly synthesized envelope proteins are not incorporated into viral particles that are shed into the culture medium. gPr90env appears to be localized in a pre-Golgi membrane compartment, based on its enrichment in subcellular fractions containing NADPH-cytochrome c reductase activity and the sensitivity of its carbohydrate chains to digestion with endoglycosidase H. Arrest of gPr90env processing occurs at concentrations of lovastatin that are not cytostatic, and the effect of the inhibitor is prevented by addition of mevalonate to the medium. The low molecular mass GTP-binding proteins, rab1p and rab6p, which are believed to function in early steps of the exocytic pathway, are normally modified posttranslationally by geranylgeranyl isoprenoids. However, in MEL cells treated with 1 microM lovastatin, nonisoprenylated forms of these proteins accumulate in the cytosol prior to arrest of gPr90env processing. These observations suggest that lovastatin may prevent viral envelope precursors from reaching the Golgi compartment by blocking the isoprenylation of rab proteins required for ER to Golgi transport.     

Secretory Proteins from Adrenal Medullary Cells Are Carboxyl-Methylated In Vivo and Released Under Their Methylated Form by Acetylcholine

The carboxyl methylation of secretory proteins in vivo was investigated in bovine adrenal medullary cells in culture. Chromogranin A, the major intragranular secretory protein in adrenal medullary cells, and other secretory proteins were found to be carboxyl-methylated within secretory vesicles. The in vivo labeling pattern using [methyl-3H]methionine and the in vitro labeling pattern using S-adenosyl-[methyl-14C]methionine of intravesicular secretory proteins were similar. The detection of methylated chromogranin A in mature secretory vesicles required 3-6 h, a time consistent with the synthesis and storage of secretory proteins in this tissue. Carboxyl-methylated chromogranin A was secreted from medullary cells by exocytosis via activation of nicotinic cholinergic receptor and recovered still under the methylated form in the incubation medium. Since protein-carboxyl-methylase is cytosolic, these results suggest that methylation of secretory proteins is a cotranslational phenomenon.     

Identification of low molecular weight GTP-binding proteins and their sites of interaction in subcellular fractions from skeletal muscle

The presence of low molecular weight GTP-binding proteins was investigated in subcellular fractions from skeletal muscle. Skeletal muscle homogenate, transverse tubules, triads, sarcoplasmic reticulum membranes, and cytosol fractions were separated in sodium dodecyl sulfate-gel electrophoresis and blotted onto nitrocellulose. The presence of GTP-binding proteins was explored by incubation of these blots with [alpha-32P] GTP. GTP labeled two polypeptides of Mr = 23,000 and 29,000 in all the fractions examined. Binding of [alpha-32P]GTP was specific and dependent on Mg2+. The 23-kDa polypeptide was labeled to a higher extent with [alpha-32P]GTP than the 29-kDa polypeptide, although both were enriched in transverse tubule fractions. A GTP-binding polypeptide of 40 kDa was also enriched in transverse tubule preparations and identified as Gi alpha by immunostaining with anti-Gi alpha. Using a blot overlay approach and [alpha-32P]GTP-labeled cytosolic components, several polypeptides were identified that interact with the 23- and 29-kDa GTP-binding proteins. Among these components were polypeptides of Mr = 60,000, 47,000, 44,000, 42,000, and 38,000, which were mainly of cytosolic origin but also associated with triads and transverse tubule membranes. The 47-, 44-, 42-, and 38-kDa polypeptides were found to be structurally related to the glycolytic enzymes enolase, 3-phosphoglyceric phosphokinase, aldolase, and glycoeraldehyde-3-phosphate dehydrogenase, respectively. The purified glycolytic enzymes specifically bound the 23- and 29-kDa GTP-binding proteins under both denaturing and nondenaturing conditions. The association of the GTP-binding proteins with these polypeptides was resistant to detergents such as 3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid (CHAPS), Triton X-100, and Tween. A 23-kDa GTP-binding protein purified from chromaffin cells bound to a 157-kDa polypeptide in triads and chromaffin cell membranes. The 157-kDa polypeptide was a minor component in these membranes and not related to the subunits of the dihydropyridine receptor. In view of the proposed function of low molecular weight GTP-binding proteins in processes such as membrane communication and secretion coupling, the association of these proteins with transverse tubules and triads in skeletal muscle is discussed in terms of a role in signal transmission.     

Isoprenylation of the low molecular mass GTP-binding proteins rac 1 and rac 2: possible role in membrane localization

Ras proteins can be modified at their COOH-terminal cysteine in the motif Cys-Ali-Ali-Xaa by a farnesyl isoprenoid. This modification is essential for membrane association and biological activity of ras proteins. A similar COOH-terminal amino acid sequence, Cys-Xaa-Ali-Xaa, exists in the ras-related GTP-binding proteins rac 1 and rac 2. To determine whether these proteins were similarly modified, COS cells were transfected with rac 1 and rac 2 cDNA and expressed proteins were labeled with [3H]mevalonic acid. We report here that both rac 1 and rac 2 are post-translationally modified by addition of an isoprenoid group, the likely site of which is the COOH-terminal cysteine. Isoprenylation was found only in racs associated with particulate cell fractions, suggesting that this modification may be associated with membrane localization of the proteins. These data specifically identify mammalian low molecular mass GTP-binding proteins other than ras that undergo post-translational modification and further define the COOH-terminal consensus sequence, Cys-Ali-Ali-Xaa, as an isoprenylation signal. This sequence may identify a larger family of low molecular mass GTP-binding proteins which are isoprenylated.     

The membrane-binding domain of a 23-kDa G-protein is carboxyl methylated

We have purified to homogeneity a 23-kDa protein from bovine brain membranes using [35S]guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) binding as an assay. GTP gamma S binding to the purified protein is inhibited by GDP, GTP, and GTP analogs but not by cGMP, GMP, or adenine nucleotides, consistent with the nucleotide-binding behavior of members of the family of GTP-binding regulatory proteins. On addition of the methyl donor S-adenosyl-L-methionine and a methyltransferase present in bovine brain membranes, the purified 23-kDa G-protein is carboxyl methylated. When subjected to limited tryptic proteolysis, the 23-kDa protein is converted to a 22-kDa major fragment with concomitant release of a carboxyl methylated protein fragment of 1 kDa. Furthermore, when the cleaved protein is reconstituted with stripped bovine brain membranes, the small carboxyl-methylated fragment but not the 22-kDa major fragment is found to reassociate with the membranes. These results indicate that the site of carboxyl methylation and the region responsible for membrane anchoring, most likely, are localized to a small region at the carboxyl terminus. It is attractive to speculate that carboxyl methylation and membrane anchoring are interrelated processes and play key roles in the function of this small G-protein.     

Geranylgeraniol Overcomes the Block of Cell Proliferation by Lovastatin in C6 Glioma Cells

Abstract: It is well documented that 3-hydroxy-3-methylglutaryl-CoA reductase inhibitors prevent cultured mammalian cells from progressing through the cell cycle, suggesting a critical role for a mevalonate-derived product. Recently, it has been shown that free geranylgeraniol (GG-OH) and farnesol (F-OH) can be utilized by C6 glioma cells for protein isoprenylation. The ability of GG-OH and F-OH to restore protein geranylgeranylation or farnesylation selectively has enabled us to examine the possibility that mevalonate is essential for cell proliferation because it is a precursor of farnesyl pyrophosphate or geranylgeranyl pyrophosphate, the isoprenyl donors involved in the post-translational modification of key regulatory proteins. In this study we report that GG-OH, as well as mevalonate, overcomes the arrest of cell proliferation of C6 glioma cells treated with lovastatin, as assessed by increased cell numbers and a stimulation in [³H]thymidine incorporation. The increase in cell number and [³H]thymidine incorporation were significantly lower when F-OH was added. Under these conditions [³H]mevalonate and [³H]GG-OH are actively incorporated into a set of isoprenylated proteins in the size range of small, GTP-binding proteins (19–27 kDa) and a polypeptide with the molecular size (46 kDa) of the smaller isoform of 2′,3′-cyclic nucleotide 3′-phosphodiesterase. Analysis of the proteins metabolically labeled by [³H]mevalonate and [³H]GG-OH reveals the presence of labeled proteins containing geranylgeranylated cysteinyl residues. Consistent with geranylgeranylated proteins playing a critical role in the entry of C6 cells into the cell cycle, a (phosphonoacetamido)oxy derivative of GG-OH, a drug previously shown to interfere with protein geranylgeranylation, prevented the increase in cell number when mevalonate or GG-OH was added to lovastatin-treated cells. These results strongly suggest that geranylgeranylated proteins are essential for progression of C6 cells into the S phase of the cell cycle and provide the first evidence that the “salvage” pathway for the utilization of the free isoprenols is physiologically significant in the CNS.     

Methylation of erythrocyte membrane proteins at extracellular and intracellular D-aspartyl sites in vitro. Saturation of intracellular sites in vivo

A cytosolic protein carboxyl methyltransferase (S-adenosyl-L-methionine:protein O-methyltransferase, E.C. 2.1.1.24) purified from human erythrocytes catalyzes the methylation of erythrocyte membrane proteins in vitro using S-adenosyl-L-[methyl-3H]methionine as the methyl group donor. The principal methyl-accepting proteins have been identified by sodium dodecyl sulfate-gel electrophoresis at pH 2.4 and fluorography as the anion transport protein (band 3), ankyrin (band 2.1), and integral membrane proteins with molecular weights of 45,000, 28,000, and 21,000. Many of the methylation sites associated with intrinsic membrane proteins may reside in their extracellular portions, since these same proteins are methylated when intact cells are used as the substrate. The maximal number of methyl groups transferred in these experiments is approximately 30 pmol/mg of membrane protein, a value which represents less than one methyl group/50 polypeptide chains of any methyl-accepting species. The number of methylation sites associated with the membranes is increased, but not to stoichiometric levels, by prior demethylation of the membranes. The additional sites are associated primarily with bands 2.1 and 4.1, the principal methyl acceptors in vivo, suggesting that most methylation sites are fully modified in vivo. Extracellular methylation sites are not increased by demethylation of membranes. The aspartic acid beta-methyl ester which can be isolated from carboxypeptidase Y digests of [3H]methylated membranes is in the unusual D-stereoconfiguration. Similar results have been obtained with [3H]methylated membranes isolated from intact cells (McFadden, P.N., and Clarke, S. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 2460-2464). It is proposed that the methyltransferase recognizes D-aspartyl residues in proteins and is involved with the metabolism of damaged proteins in vivo.     

Lipopolysaccharide-induced NF-kappa B activation in mouse 70Z/3 pre-B lymphocytes is inhibited by mevinolin and 5''-methylthioadenosine: roles of protein isoprenylation and carboxyl methylation reactions.

We show that both the lipopolysaccharide (LPS)-induced activation of NF-kappa DNA binding and kappa gene expression are blocked by treating murine pre-B lymphocyte 70Z/3 cells with 5'-methylthioadenosine (MTA), an inhibitor of several S-adenosylmethionine-dependent methylation reactions. We further show that the LPS-induced incorporation of radioactivity from [methyl-3H]methionine into methyl ester-like linkages on a group of membrane polypeptides is also inhibited by MTA treatment, suggesting the involvement of protein methylation reactions in the LPS signal transduction pathway. We also find that NF-kappa B and kappa gene activation in LPS-treated 70Z/3 cells is blocked by mevinolin, an inhibitor that prevents protein isoprenylation. Interestingly, mevinolin-treated cells also exhibited a marked reduction in the methylation of membrane proteins. Neither MTA nor mevinolin significantly inhibited NF-kappa B activation by phorbol myristate acetate, suggesting that these agents act early in signal transduction. These results provide the first evidence that carboxyl methylated and/or isoprenylated proteins play an essential role in the LPS-signaling pathway.