Methylation of membrane proteins in human erythrocytes. Identification and characterization of polypeptides methylated in lysed cells

Synapsin I is a major endogenous substrate for protein L-isoaspartyl methyltransferase in mammalian brain

The accumulation of potentially deleterious L-isoaspartyl linkages in proteins is prevented by the action of protein L-isoaspartyl O-methyltransferase, a widely distributed enzyme that is particularly active in mammalian brain. Methyltransferase-deficient (knock-out) mice exhibit greatly increased levels of isoaspartate and typically succumb to fatal epileptic seizures at 4-10 weeks of age. The link between isoaspartate accumulation and the neurological abnormalities of these mice is poorly understood. Here, we demonstrate that synapsin I from knock-out mice contains 0.9 +/- 0.3 mol of isoaspartate/mol of synapsin, whereas the levels in wild-type and heterozygous mice are undetectable. Transgenic mice that selectively express methyltransferase only in neurons show reduced levels of synapsin damage, and the degree of reduction correlates with the phenotype of these mice. Isoaspartate levels in synapsin from the knock-out mice are five to seven times greater than those in the average protein from brain cytosol or from a synaptic vesicle-enriched fraction. The isoaspartyl sites in synapsin from knock-out mice are efficiently repaired in vitro by incubation with purified methyltransferase and S-adenosyl-L-methionine. These findings demonstrate that synapsin I is a major substrate for the isoaspartyl methyltransferase in neurons and suggest that isoaspartate-related alterations in the function of presynaptic proteins may contribute to the neurological abnormalities of mice deficient in this enzyme.

13 Protein L-isoaspartyl, D-aspartyl O-methyltransferases: Catalysts for protein repair

Protein L-isoaspartyl, D-aspartyl O-methyltransferases (PIMTs) are ancient enzymes distributed through all phylogenetic domains. PIMTs catalyze the methylation of L-isoaspartyl, and to a lesser extent D-aspartyl, residues arising from the spontaneous deamidation and isomerization of protein asparaginyl and aspartyl residues. PIMTs catalyze the methylation of isoaspartyl residues in a large number of primary sequence configurations, which accounts for the broad specificity of the enzyme for protein substrates both in vitro and in vivo. PIMT-catalyzed methylation of isoaspartyl substrates initiates the repair of the polypeptide backbone in its damaged substrates by a spontaneous mechanism that involves a succinimidyl intermediate. The repair process catalyzed by PEVITs is not completely efficient, however, leaving open the possibility that unidentified enzymatic activities cooperate with PIMT in the repair process. Structurally, PIMTs are members of the class I family of AdoMet-dependent methyltransferases. PIMTs have a unique topological arrangement of strands in the central β sheet that provides a signature for this class of enzymes. The regulation and physiological significance of PIMT has been studied in several model organisms. PIMTs are constitutively synthesized by cells, but they can be upregulated in response to conditions that are potentially damaging to protein structures, or when proteins are stored for prolonged periods of time. Disruption of PIMT genes in bacteria and simple eukaryotes produces subtle phenotypes that are apparent only under stress. Loss of PIMT function in transgenic mice leads to fatalepilepsy, suggesting that PIMT function is particularly important to neurons in mammals.

Protein carboxylmethylation in porcine spleen is mainly mediated by class I protein carboxyl O-methyltransferase

The functional role of protein carboxylmethylation (PCM) has not yet been clearly elucidated in the tissue level. The biochemical feature of PCM in porcine spleen was therefore studied by investigating the methyl accepting capacity (MAC) of natural endogenous substrate proteins for protein carboxyl O-methyltransferase (PCMT) in various conditions. Strong acidic and alkaline-conditioned (at pH 11.0) analyses of the MAC indicated that approximately 65% of total protein methylation seemed to be mediated by spleen PCMT. The hydrolytic kinetics of the PCM products, such as carboxylmethylesters (CMEs), under mild alkaline conditions revealed that there may be three different kinds of CMEs [displaying half-times (T1/2) of 1.1 min (82.7% of total CMEs), 13.9 min (4.6%), and 478.0 min (12.7%)], assuming that the majority of CME is base-labile and may be catalyzed by class I PCMT. In agreement with these results, several natural endogenous substrate proteins (14, 31 and 86 kDa) were identified strikingly by acidic-conditioned electrophoresis, and their MAC was lost upon alkaline conditions. On the other hand, other proteins (23 and 62 kDa) weakly appeared under alkaline conditions, indicating that PCM mediated by class II or III PCMT may be a minor reaction. The MAC of an isolated endogenous substrate protein (23-kDa) was also detected upon acidic-conditioned electrophoresis. Therefore, our data suggest that most spleen PCM may be catalyzed by class I PCMT, which participates in repairing aged proteins.

Inhibition of GTPgammaS-dependent L-isoaspartyl protein methylation by tyrosine kinase inhibitors in kidney

Protein carboxyl methylation in rat kidney cytosol is increased by the addition of guanosine 5'-O-[gamma-thio]triphosphate (GTPgammaS), a non-hydrolysable analogue of GTP. GTPgammaS-stimulated methyl ester group incorporation takes place on isoaspartyl residues, as attested by the alkaline sensitivity of the labelling and its competitive inhibition by L-isoaspartyl-containing peptides. GTPgammaS was the most potent nucleotide tested, whereas GDPbetaS and ATPgammaS also stimulated methylation but to a lesser extent. Maximal stimulation (5-fold) of protein L-isoaspartyl methytransferase (PIMT) activity by GTPgammaS was reached at a physiological pH in the presence of 10 mM MgCl2. Other divalent cations, such as Cu2+, Zn2+ and Co2+ (100 microM), totally inhibited GTPgammaS-dependent carboxyl methylation. The phosphotyrosine phosphatase inhibitor vanadate potentiated the GTPgammaS stimulation of PIMT activity in the kidney cytosol at a concentration lower than 40 microM, but increasing the vanadate concentration to more than 40 microM resulted in a dose-dependent inhibition of the GTPgammaS effect. The tyrosine kinase inhibitors genistein (IC50 = 4 microM) and tyrphostin (IC50 = 1 microM) abolished GTPgammaS-dependent PIMT activity by different mechanisms, as was revealed by acidic gel analysis of methylated proteins. Whereas tyrphostin stabilised the methyl ester groups, genistein acted by blocking a crucial step required for the activation of PIMT activity by GTPgammaS. The results obtained with vanadate and genistein suggest that tyrosine phosphorylation regulates GTPgammaS-stimulated PIMT activity in the kidney cytosol.

Regulation by GTPgammaS of protein carboxylmethyltransferase activity in kidney brush border membranes

The increase in carboxyl methylation induced by guanosine 5',3-O-(thio)triphosphate (GTPgammaS) in brush border membranes from rat kidney cortex was studied, and the methyltransferase activities affected by this nucleotide analog were identified. Addition of GTPgammaS to brush border membranes stimulated the carboxyl methylation in a time-dependent manner while adenosine and guanine nucleotides were ineffective. The GTPgammaS-dependent carboxyl methylation was inhibited by the chelating agents EDTA (63%) and 1,10-phenanthroline (68%), suggesting that this activity required divalent cations. The methyl ester groups induced by the addition of GTPgammaS to brush border membranes were unstable, with about 80% of them hydrolyzed following 1 h incubation at 37 degrees C. The GTPgammaS stimulation of the carboxyl methylation in brush border membranes was unaffected by the detergent 3-[(3cholamido)-dimethylammonio]-1-propanesulfonic acid up to a concentration of 0.4% (w/v). At this latter detergent concentration, the activity of prenylated protein methyltransferase (PPMT) was strongly inhibited and that of l-isoaspartyl/d-aspartylmethyltransferase (PIMT) was increased twofold, as measured with their respective exogenous substrates, N-acetyl-S-farnesyl cysteine and ovalbumin. GTPgammaS increased the methylation of several substrates in brush border membranes. The induced methylation in substrates migrating between 20 and 36 kDa was strongly decreased by the competitive inhibitor farnesylthioacetic acid, a synthetic farnesylated substrate for PPMT, while a delta-sleep-inducing peptide containing an L-isoaspartyl residue inhibited that of substrates with molecular weights above 36 kDa, suggesting that PIMT activity was also involved. This interpretation was strengthened by the observation that the increased methylation induced by GTPgammaS in these membrane substrates was completely lost following their analysis by gel electrophoresis under alkaline conditions. Taken together, these results indicate that both PPMT and PIMT activities are regulated by guanine nucleotides in brush border membranes of rat kidney.

Calcium binding to the subunit c of E. coli ATP-synthase and possible functional implications in energy coupling

The 8-kDa subunit c of the E. coli F0 ATP-synthase proton channel was tested for Ca++ binding activity using a 45Ca++ ligand blot assay after transferring the protein from SDS-PAGE gels onto polyvinyl difluoride membranes. The purified subunit c binds 45Ca++ strongly with Ca++ binding properties very similar to those of the 8-kDa CF0 subunit III of choloroplast thylakoid membranes. The N-terminal f-Met carbonyl group seems necessary for Ca++ binding capacity, shown by loss of Ca++ binding following removal of the formyl group by mild acid treatment. The dicyclohexylcarbodiimide-reactive Asp-61 is not involved in the Ca++ binding, shown by Ca++ binding being retained in two E. coli mutants, Asp61-->Asn and Asp61-->Gly. The Ca++ binding is pH dependent in both the E. coli and thylakoid 8-kDa proteins, being absent at pH 5.0 and rising to a maximum near pH 9.0. A treatment predicted to increase the Ca++ binding affinity to its F0 binding site (chlorpromazine photoaffinity attachment) caused an inhibition of ATP formation driven by a base-to-acid pH jump in whole cells. Inhibition was not observed when the Ca++ chelator EGTA was present with the cells during the chlorpromazine photoaffinity treatment. An apparent Ca++ binding constant on the site responsible for the UV plus chlorpromazine effect of near 80-100 nM was obtained using an EGTA-Ca++ buffer system to control free Ca++ concentration during the UV plus chlorpromazine treatment. The data are consistent with the notion that Ca++ bound to the periplasimic side of the E. coli F0 proton channel can block H+ entry into the channel. A similar effect occurs in thylakoid membranes, but the Ca++ binding site is on the lumen side of the thylakoid, where Ca+2 binding can modulate acid-base jump ATP formation. The Ca+2 binding to the F0 and CF0 complexes is consistent with a pH-dependent gating mechanism for control of H+ ion flux across the opening of the H+ channel.

Trapping succinimides in aged polypeptides by chemical reduction

Cyclization of aspartic acid and asparagine to succinimides is thought to be a common spontaneous aging reaction in proteins, but the instability of the succinimide ring has made it difficult to directly measure this structure. Chemical reduction has now been tested as a means of trapping succinimides as stable derivatives, homoserine and isohomoserine. Two succinimide-containing compounds were tested in this manner. First, polysuccinimide was reduced by sodium borohydride to a derivative that contained homoserine and isohomoserine in amounts that were consistent with the content of succinimide determined independently by quantitative hydrolysis. The identity of isohomoserine was confirmed by its resistance to degradation by L-amino acid oxidase, and through its synthesis by an alternate route involving borane reduction of asparagine. Second, in a test of this approach on a peptide mixture with only a trace-content of succinimide, isohomoserine and homoserine were formed as reduction products in amounts equivalent to the trace content of succinimide in the mixture. Detection of the products of the chemical reduction of polypeptides is therefore diagnostic of succinimides, and can be successfully applied at the trace sensitivity necessary for studies of naturally aging proteins. A related study of the reduction of aspartyl and beta-aspartyl residues to, respectively, homoserine and isohomoserine, is described in the accompanying manuscript (Carter and McFadden, 1994).

Automethylation of protein (D-aspartyl/L-isoaspartyl) carboxyl methyltransferase, a response to enzyme aging

A question that is central to understanding the mechanisms of aging and cellular deterioration is whether enzymes involved in recognition and metabolism of spontaneously damaged proteins are themselves damaged, either becoming substrates for their own activity; or being unable to act upon themselves, initiating cascades of cellular damage. We show here by in vitro experiments that protein (D-aspartyl/L-isoaspartyl) carboxyl methyltransferase (PCM) from bovine erythrocytes does methylate age-dependent amino acid damage in its own sequence. The subpopulation that is methylated, termed the alpha PCM fraction, appears to be formed through age-dependent deamidation of an asparaginly site to either an L-isoaspartyl or D-aspartyl site because (a) the stoichiometry of automethylation of purified PCM is less than 1%, a value typical of the substoichiometric methylation of many other aged protein substrates, (b) alpha PCM is slightly more acidic than the bulk of PCM, and (c) the methyl esterified site in alpha PCM has the characteristic base-lability of this type of methyl ester. Also, the methyl group is not incorporated into the enzyme as an active site intermediate because the incorporated methyl group is not chased onto substrate protein. The effect of enzyme dilution on the rate of the automethylation reaction is consistent with methylation occurring between protein molecules, showing that the pool of PCM is autocatalytic even though individual molecules may not be. The automethylation and possible self-repair of the PCM pool has implications for maintaining the in vivo efficiency of methylation-dependent protein repair.

Protein methylation in cerebellar synaptosomes

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 [alpha-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 [alpha-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 a site for carboxyl methylation in human alpha-globin

The human erythrocyte protein carboxyl methyltransferase modifies unusual protein D-aspartyl and L-isoaspartyl residues which arise spontaneously from internal rearrangements accompanying asparaginyl deamidation and aspartyl isomerization. A site of methylation associated with alpha-globin in intact cells has been identified by peptide mapping of radiolabeled globin isolated from human erythrocytes previously incubated with L-[methyl-3H]methionine. The site is located in a Staphylococcus V8 peptide containing residues 1-30 of alpha-globin. Two potential sources of methylation sites are present in this sequence at Asp-t and Asn-9.

Amplification and detection of substrates for protein carboxyl methyltransferases in PC12 cells

A strategy that facilitates the identification of substrates for protein carboxyl methyltransferases that form "stable" methyl esters, i.e., those that remain largely intact during conventional polyacrylamide gel electrophoresis is described. Rat PC12 cells were cultured in the presence of adenosine dialdehyde (a methylation inhibitor) to promote the accumulation of hypomethylated proteins. Nonidet P-40 cell extracts were then incubated in the presence of S-[methyl-3H]adenosyl-L-methionine to label methyl-accepting sites via endogenous methyltransferases. After labeled proteins were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, gel slices were incubated in 4 N methanesulfonic acid or 6 N HCl to hydrolyze methyl esters. The resulting [3H]methanol was detected by trapping in liquid scintillation fluid. Seven carboxyl methylated proteins were observed with masses ranging from 18 to 96 kDa. Detection of five of these proteins required prior treatment of cells with adenosine dialdehyde, while methyl incorporation into one protein at 18 kDa was substantially enhanced by the treatment. The use of acidic conditions for methyl ester hydrolysis has an important advantage over assays that utilize alkaline hydrolysis conditions. In PC12 cells, and possibly other cell types where there are significant levels of arginine methylation, the methanol signal becomes obscured by high levels of volatile methylamines generated under the alkaline conditions. Carrying out diffusion assays under acidic conditions eliminates this interference. Adenosine dialdehyde, by virtue of increasing the methyl-accepting capacity of substrates for protein carboxyl methyltransferases, in combination with a more selective assay for carboxyl methylation, should prove useful in the isolation and characterization of new protein carboxyl methyltransferases and their substrates.

Protein carboxyl methylation in kidney brush-border membranes

Protein carboxyl methylation activity was detected in the cytosol and in purified brush-border membranes (BBM) from the kidney cortex. The protein carboxyl methyltransferase (PCMT) activity associated with the BBM was specific for endogenous membrane-bound protein substrates, while the cytosolic PCMT methylated exogenous substrates (ovalbumin and gelatin) as well as endogenous proteins. The apparent Km for S-adenosyl-L-methionine with endogenous proteins as substrates were 30 microM and 4 microM for the cytosolic and BBM enzymes, respectively. These activities were sensitive to S-adenosyl-L-homocysteine, a well known competitor of methyltransferase-catalyzed reactions, but were not affected by the presence of chymostatin and E-64, two protein methylesterase inhibitors. The activity of both cytosolic and BBM PCMT was maximal at pH 7.5, while BBM-phospholipid methylation was predominant at pH 10.0. Separation of the = methylated proteins by acidic gel electrophoresis in the presence of the cationic detergent benzyldimethyl-n-hexadecylammonium chloride revealed distinct methyl accepting proteins in the cytosol (14, 17, 21, 27, 31, 48, 61 and 168 kDa) and in the BBM (14, 60, 66, 82, and 105 kDa). Most of the labelling was lost following electrophoresis under moderately alkaline conditions, except for a 21 kDa protein in the cytosol and a 23 kDa protein in the BBM fraction. These results suggest the existence of two distinct PCMT in the kidney cortex: a cytosolic enzyme with low selectivity and affinity, methylating endogenous and exogenous protein substrates, and a high-affinity BBM-associated methylating activity.

Protein carboxyl methylation and methyl ester turnover in density-fractionated human erythrocytes

A widely distributed methyltransferase modifies protein D-aspartyl and L-isoaspartyl residues which arise spontaneously as proteins age. Protein carboxyl methylation reactions were analyzed in human erythrocytes which had been separated on density gradients, a procedure which provides fractions enriched in older cells in the denser areas of the gradient. The total flux of methyl groups through the carboxyl methylation pathway was monitored by incubating cells from each fraction with L-[methyl-3H]methionine and measuring the formation of both protein [3H]methyl esters and [3H]methanol, derived from the hydrolysis of protein [3H]methyl esters in vivo. Cells isolated from denser areas of the gradient showed progressively higher rates of both protein carboxyl methylation and methanol production. In all cases, only 10-20% of the total methyl groups transferred were still present as intact protein [3H]methyl esters, consistent with the rapid hydrolysis of protein methyl esters in erythrocytes of all ages. The total flux of methyl groups through the carboxyl methylation pathway was approximately 3-fold higher in cells isolated from densest areas of the gradient compared to cells isolated from least dense areas of the gradient. Increases of a similar magnitude were observed in the numbers of both membrane protein carboxyl methyl esters and cytosolic protein carboxyl methyl esters. The only protein whose methylation was unchanged in denser cells was a 35,000 Da cytosolic protein. It has been proposed that protein carboxyl methyl esters are intermediates in either the repair or metabolism of structurally damaged proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

The function of protein carboxylmethyltransferase in eucaryotic cells

Protein carboxylmethyltransferase (PCM) is an enzyme whose function in eucaryotic cells remains controversial. Early studies suggested that protein carboxylmethylation subserved a regulatory, post-translational role in such diverse processes as secretion, neuronal receptor function, chemotaxis, and cellular differentiation. Later work strongly supported a totally unrelated role for this enzyme, i.e., the repair of spontaneously altered aspartate residues in cellular proteins. More recent evidence, however, suggests that a distinct, membrane-associated PCM catalyzes the methylation of alpha-carboxyl groups of C-terminal cysteines on discrete proteins. In view of these recent investigations, the data supporting a regulatory role for PCM are critically discussed and re-evaluated. There now appears to be compelling evidence that PCM(s) subserves both repair and regulatory functions in eucaryotic cells, catalyzing post-translational modifications of proteins involved in cell division, hormonal secretion, calmodulin-associated events and the interaction of guanyl nucleotide-linked proteins with the cell membrane.

Protein carboxyl methylation in synaptic membrane of rat brain: the possible presence of adenosine-bound S-adenosyl-L-homocysteine hydrolase in the membrane

The effects of some neurotransmitters, adenosine (Ad), and homocysteine (Hcys) on protein carboxyl methylation in synaptic plasma membranes from rat cerebral cortex were examined. Neither any of the neurotransmitters nor Ad had a detectable effect. Incubation of membrane with DL-Hcys alone (5 X 10(-5) M), the combination of both Ad (5 X 10(-5)) and DL-Hcys (5 X 10(-5)), or S-adenosyl-L-homocysteine (SAH) (1 X 10(-6)) strongly decreased the methyl ester formation. The inhibitory effect of the combination of both compounds may be interpreted in terms of the increased SAH concentration due to the presence of SAH hydrolase in the membrane. The inhibitory effect of Hcys alone was blocked by preincubation with Ad deaminase or Neplanocin A, a potent inhibitor of SAH hydrolase, suggesting the presence of Ad-bound SAH hydrolase in the synaptic membrane. Ad-bound SAH hydrolase activity estimated by the inhibition of methylation in the presence of Hcys was located in the membrane fractions including synaptosomes, myelin, and microsomes (about 70%), but the SAH hydrolase activity estimated on the basis of the inhibitory effect of the combination of both Ad and Hcys was localized exclusively in the soluble fraction (about 90%). The distribution of the latter activity is coincident with that of SAH hydrolase reported to date. Incubation of the synaptic membrane with Hcys markedly increased the SAH concentration. The stimulatory effect of Hcys alone was blocked by Ad deaminase.

Protein methylase II in five taxa from three phyla

Protein methylase II (protein O-methyltransferase, EC 2.1.1.24) was found in Dictyostelium discoideum amoebae, Astacus leptodactylus axonal, Locusta migratoroides neuronal, Torpedo marmorata electroplaque and Bos bovis stratial tissue and compared in both the soluble and particulate fractions. The intrinsic decay data of the methyl groups transferred onto proteins from Dictyostelium and Torpedo tissues were virtually identical. The short term kinetics of the methyl group transfer of all fractions and of all taxa investigated were non-linear and multiphasic. The particulate fractions displayed transient peaks at 1 min, 3 min, or both after the start of the reaction. The methyl group transfer was stimulated by the neurotoxins veratridine (VTx) and inhibited by veratridine plus tetrodotoxin (TTx) (axonal membrane vesicles of Astacus), stimulated transiently and in a biphasic manner by carbamoylcholine and phospholipase A2 (AChR-rich membrane vesicles of Torpedo), and stimulated transiently and biphasically by the adequate chemotactic stimulus cAMP (aggregation competent amoebae of Dictyostelium).

Metabolism of S-adenosyl-L-methionine in intact human erythrocytes

Freshly isolated human erythrocytes contain S-adenosyl-L-methionine (AdoMet) at a concentration of about 3.5 mumol/l cells. When such cells are incubated in a medium containing 30 microM L-methionine, 18 mM D-glucose and 118 mM sodium phosphate (pH 7.4), intracellular AdoMet levels continuously decrease to a value of about 0.1 microM after 24 h. This occurs in spite of the fact that the cellular concentrations of the substrates for the AdoMet synthetase reaction, ATP and L-methionine, remain relatively constant. In a search for incubation conditions that lead to stable levels of AdoMet in incubated cells, we have developed a sodium-Hepes-buffered medium which includes 1 mM adenine and a stoichiometric excess of MgCl2 over its ligand, phosphate. The inclusion of magnesium ion (and a reduction in phosphate) appears to increase intracellular free Mg2+, which is required for full activity of the erythrocyte AdoMet synthetase. Even in the presence of MgCl2, however, the AdoMet pool level can drop 4-6-fold within the first 2 h of incubation. We present evidence that suggests that this initial fall in the cellular AdoMet level may be due to the activation of AdoMet-dependent protein carboxyl methyltransferase, an enzyme which accounts for a large fraction of the total cellular AdoMet utilization. Adenine, or related compounds in the medium may prevent this activation, although the mechanism of this action is not clear at present.

Protein carboxyl methyltransferase and methyl acceptor proteins in aging and cataractous tissue of the human eye lens

We have studied the enzymatic modification of proteins in human eye lens tissue where these molecules can be long-lived and can be exposed to non-enzymatic degradation processes for periods of time up to the age of the individual. We have detected a protein carboxyl methyltransferase that is similar to enzymes from other mammalian tissues which appear to catalyze the methyl esterification of altered aspartyl residues, including D-aspartyl and beta-isomerized L-aspartyl residues, but which have no activity on normal L-aspartyl sites. Upon gel filtration of human lens extracts, we find protein substrates for the lens methyltransferase in each of the major soluble classes of protein. In comparing individual lenses of various ages, protein carboxyl methyltransferase activity was present in tissue from all normal and yellow cataractous lenses tested, but was present only at very low apparent levels in brunescent lens tissue. We find that the methyltransferase is much more highly saturated by endogenous methyl acceptor substrates in lens extracts from older individuals, suggesting that the prolonged in vivo aging of lens protein leads to the accumulation and perhaps metabolism of altered aspartyl residues.

Stimulation of protein methylase II from Torpedo marmorata by cholinergic effectors

The enzymatic transfer of methyl groups mediated by protein methylase II onto proteins of the electroplaque tissue of Torpedo marmorata is described. The protein methylase II resides to the extent of 80% in the cytosol and 20% in the acetylcholine receptor-rich membrane. The kinetics of the methyl-group transfer are characteristically different in the cytosol and membrane fractions. The reaction is inhibited by phosphate with IC50 = 450 microM. The cholinergic effectors carbamoylcholine, flaxedil and alpha-bungarotoxin applied to the outside of the acetylcholine receptor-rich membrane vesicles stimulated the protein methylase II which is exclusively located inside the vesicles. The stimulation is biphasic and transient, yielding an increased initial velocity and a peak of activity at 2 min after the addition of the effector. The stimulation by carbamoylcholine is qualitatively similar to that elicited by the antagonist. In addition, the protein methylase II is stimulated transiently by phospholipase A2 with a time-course clearly different from that of the cholinergic effectors. We conclude that the conformational change in the receptor-protein elicited by cholinergic effectors is efficiently transduced to the cytoplasmic methylation sites.

Effects of carboxymethylation by a purified Torpedo californica methylase on the functional properties of the acetylcholine receptor in reconstituted membranes

The functional effects of carboxymethylation of Torpedo californica acetylcholine receptor by an endogenous Torpedo methylase were examined. Both the receptor and the methylase were purified to increase the level of methylation and the sensitivity of the functional assays. The methylase catalyzed the carboxymethylation of all four receptor subunits (alpha, beta, gamma, delta) with preferential labeling of the alpha and gamma subunits. For all the reactions, S-adenosylmethionine was used as the methyl donor. Functional effects of methylation were assessed by measuring ligand binding and ligand-activated ion permeability responses in reconstituted membranes containing purified acetylcholine receptors. Methylation of receptor to a level of 20 mol% had no significant effect on agonist or antagonist binding nor did methylation affect the transition from low-to-high affinity binding triggered by agonists. In contrast, 20% methylation led to a 20% reduction in the agonist-stimulated flux of cations across the receptor-containing membranes. The results suggest that methylation inhibits the ion permeability control properties of acetylcholine receptors.

Demethylation of protein carboxyl methyl esters: a nonenzymatic process in human erythrocytes?

We have compared the demethylation rate of protein carboxyl methyl esters from isolated human erythrocyte membranes with the corresponding rate of metabolic turnover of these same methyl groups in the intact erythrocyte. Surprisingly, the apparent spontaneous demethylation of these membrane protein methyl esters was significantly faster at physiological pH than the corresponding rate determined by pulse-chase analysis of intact cells incubated with L-[methyl-3H]methionine. Readdition of erythrocyte lysate to purified membranes did not increase the rate of demethylation, as might be expected if there were cytosolic or membrane-bound protein methylesterase activity, but resulted instead in an apparent stabilization of these methyl esters. Thus, the metabolic lability of these protein methyl esters in intact cells may be quantitatively explained by spontaneous, rather than enzymatic, demethylation reactions. A model is presented in which a rapid but nonenzymatic intramolecular demethylation reaction results in the formation of a polypeptide imide or anhydride intermediate. The metabolic fate of these hypothetical intermediates is unknown but may lead to the repair or degradation of protein D-aspartyl and L-isoaspartyl residues, which appear to be the substrates for the initial transmethylation reaction.

Analysis of erythrocyte protein methyl esters by two-dimensional gel electrophoresis under acidic separating conditions

A two-dimensional polyacrylamide gel electrophoresis system which is suitable for the analysis of protein methylation reactions in cells incubated with L-[methyl-3H]methionine is described. The procedure separates proteins under primarily acidic conditions by isoelectric focusing in the first dimension and by sodium dodecyl sulfate electrophoresis at pH 2.4 in the second dimension. The low pH is essential for preserving protein [3H]methyl esters, but it limits the effective separating range of this system to proteins with isoelectric points between 4 and 8. With this system, we have shown that most, if not all, erythrocyte membrane and cytosolic proteins can act as substoichiometric methyl acceptors for an intracellular S-adenosylmethionine-dependent carboxyl methyltransferase and that protein carboxyl methylation reactions may be the major methyl transfer reaction in erythrocytes. These results are most consistent with the generation of protein substrate sites for the carboxyl methyltransferase by spontaneous deamidation and racemization reactions.

Is Ca2+-calmodulin-dependent protein phosphorylation in rat brain modulated by carboxylmethylation?

Calmodulin stimulation of protein kinase activity in calmodulin-depleted preparations of rat brain cytosol or synaptosomal membranes was attenuated by prior carboxylmethylation of the enzyme source with purified protein-O-carboxylmethyltransferase. Similarly, calmodulin stimulation of highly purified Ca2+-calmodulin-dependent protein kinase was reduced if the kinase was exposed to methylating conditions prior to addition of calmodulin. Biochemical and acidic sodium dodecyl sulfate-gel electrophoretic analyses indicated that all sources of protein kinase activity were substrates for methylation. The specific activity of methyl group incorporation into protein kinase increased with increasing purity of the preparation, reaching values of 1.72 pmol CH3/micrograms protein or 0.15-1.12 mol CH3/mol of holoenzyme. Analysis of ATP binding in cytosol with the use of the photoaffinity probe [32P]8-azido-ATP indicated that carboxylmethylation reduced ATP binding. These results suggest that carboxylmethylation of Ca2+-calmodulin protein kinase may modulate the activity of this enzyme in rat brain.

Protein O-carboxylmethylation in relation to male gamete production and function

Protein O-carboxylmethyltransferase (PCM) activity of differentiating male germ cells in the testis and of spermatozoa is strikingly high. PCM catalyzes the methylesterification by S-adenosylmethionine of dicarboxylic amino acid residues in proteins. PCM appears to be the only type of protein methyltransferase present in mature spermatozoa. Mammalian sperms contain considerable amounts of S-adenosylmethionine and can apparently synthesize this nucleoside from L-methionine and ATP. Spermatozoa are rich in S-adenosylhomocysteine hydrolase. The characteristics of this enzyme in testicular germ cells and in sperms are very similar to those in other mammalian tissues; the very sub-stoichiometric extent of methylation of various pure protein substrates, and the rapid spontaneous hydrolysis of the protein methyl ester products at physiological and especially higher pH values, are particularly remarkable. From studies on processes related to protein O-carboxylmethylation in rat spermatozoa from different regions of the epididymis, and in ejaculated spermatozoa from normal and infertile men, unequivocal evidence could not be obtained for hypotheses of other investigators that PCM-catalyzed reactions are of regulatory importance for the acquisition of a potentiality for motility in sperms during their transit and maturation in the epididymis, or for the locomotion of ejaculated sperms. The findings are discussed in the light of the recent hypothesis of S. Clarke that PCM catalyzes methylesterification of D-aspartyl residues that accumulate in certain proteins as a result of slow spontaneous racemization of L-aspartyl residues, and that the methyl esterification of D-aspartyl residues may be related to disposal or repair of proteins damaged in this fashion.