Isoaspartate in Ribosomal Protein S11 of Escherichia coli

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Journal of Bacteriology, May 1999, p. 2872-2877, Vol. 181, No. 9
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Isoaspartate in Ribosomal Protein S11 of Escherichia coli

Cynthia L. David,¹ John Keener,² and Dana W. Aswad¹^,^*

Department of Molecular Biology and Biochemistry¹ and Department of Biological Chemistry,² University of California, Irvine, Irvine, California 92697-3900

Received 7 December 1998/Accepted 31 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Isoaspartyl sites, in which an aspartic acid residue is linked to its C-flanking neighbor via its $beta$ -carboxyl side chain, aregenerally assumed to be an abnormal modification arising as proteinsage. The enzyme protein L-isoaspartate methyltransferase (PIMT),present in many bacteria, plants, and animals, catalyzes the conversionof isoaspartate to normal $alpha$ -linked aspartyl bonds and is thoughtto serve an important repair function in cells. Having introduceda plasmid into Escherichia coli that allows high-level expressionof rat PIMT, we explored the possibility that the rat enzyme reducesisoaspartate levels in E. coli proteins, a result predicted bythe repair hypothesis. The present study demonstrates that thisis indeed the case; E. coli cells expressing rat PIMT had significantlylower isoaspartate levels than control cells, especially in stationaryphase. Moreover, the distribution of isoaspartate-containing proteinsin E. coli differed dramatically between logarithmic- and stationary-phasecultures. In stationary-phase cells, a number of proteins in themolecular mass range of 66 to 14 kDa contained isoaspartate, whereasin logarithmic-phase cells, nearly all of the detectable isoaspartateresided in a single 14-kDa protein which we identified as ribosomalprotein S11. The near stoichiometric levels of isoaspartate inS11, estimated at 0.5 mol of isoaspartate per mol of S11, suggeststhat this unusual modification may be important for S11function.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Isoaspartyl residues are generated within labile amino acid sequences by deamidation of asparagine or isomerization of aspartate(10, 13) (Fig. 1) and may result in diminished enzyme activityor other deleterious functional effects (3, 15). ProteinL-isoaspartate methyltransferase (PIMT) (EC 2.1.1.77) utilizesthe active methyl group of S-adenosyl-L-methionine (AdoMet) tomethylate the $alpha$ -carboxyl group on isoaspartate residues, producingmethyl esters. Spontaneous breakdown of the methyl esters resultsin a mixture of isoaspartate and aspartate in approximately a3:1 ratio (reference 4 and references therein). Isoaspartaterecycling through this pathway converts most of the original isoaspartateto aspartate (16, 26).

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FIG. 1. Formation of isoaspartate by the deamidation of asparagine or the isomerization of aspartate.

Several lines of evidence indicate a role for PIMT in protein repair. In vitro incubation of isoaspartate-containing peptides(9, 16, 26) or proteins (3, 15) with mammalian PIMTand AdoMet results in significant conversion of the damaged sitesto normal peptide linkages containing aspartate. Experiments usingrat PC12 cells grown in the presence of a methylation inhibitorshow a pronounced increase in protein isoaspartate levels (17).Moreover, recent reports have shown that when the mouse gene encodingPIMT is disrupted, cytosolic proteins from the knockout mice havefour to eight times more isoaspartyl sites than proteins fromthe control mice (20, 41). The PIMT-deficient mice grow ata slower rate than the control mice and die from epileptic seizureswhen they are 26 to 60 days old. PIMT activity has been detectedin procaryotic cells (12, 23, 30) and in animal and planttissues (references 27 and 31 and referencestherein).

We previously transformed Escherichia coli with a recombinant plasmid (prIM) encoding rat PIMT and demonstrated that the cultureproduced active rat PIMT at a high level during stationary phase(6). In light of the presumed repair function of mammalianPIMT, we hypothesized that proteins in E. coli transformed withprIM have lower levels of isoaspartate than proteins from controlcells. We were also interested in determining whether isoaspartylsites accumulate in bacterial proteins during stationary phaseas previously suggested (24) and whether isoaspartyl sites inE. coli are distributed at low levels among many proteins, asexpected, or are present in only a fewproteins.

In this study, we show that high-level expression of rat PIMT did indeed result in a significant lowering of isoaspartatein E. coli proteins and that stationary phase was associated withthe accumulation of isoaspartate in a number of proteins. In thecourse of this investigation, we made the unexpected discoverythat most of the isoaspartate in logarithmic-phase E. coli apparentlyresided in a single low-molecular-mass protein which we identifiedas ribosomal proteinS11.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Materials. Ampicillin (AMP) (sodium salt), bovine serum albumin, S-adenosyl homocysteine, DNase I, protein A-Sepharose, and bovine gammaglobulins were purchased from Sigma. Radiolabeled S-adenosyl-L-[methyl-³H]methionine ([³H]AdoMet) was purchased from DuPont NEN. Unlabeled AdoMet waspurchased from Sigma and purified on carboxymethyl cellulose (5)before using it to dilute the [³H]AdoMet to the desired specific activity. Rat recombinant PIMTwas purified as previously described (6) and had a specificactivity of 8,000 to 15,000 U/mg, where 1 U is defined as 1 pmolof methyl transferred to bovine gamma globulins per min at 30°C.Isoaspartyl $delta$ -sleep-inducing peptide (Trp-Ala-Gly-Gly-isoaspartate-Ala-Ser-Gly-Glu)was purchased from BACHEM. Purified E. coli MRE600 30S and 50Sribosomal subunits were donated by Harry Noller, University ofCalifornia, Santa Cruz. Rabbit polyclonal antibodies to E. coliribosomal proteins (r-proteins) were donated by Masayasu Nomura,University of California,Irvine.

Transformation of E. coli JM109. Competent E. coli JM109 cells (Stratagene) were transformed with plasmid DNA, either p $Delta$ blue (2) or prIM (6), accordingto the supplier's directions. Colonies were picked and grown overnightin Luria-Bertani broth (LB) (34) containing 100 µg of AMP perml. Cultures were stored in 50% glycerol at $-$ 70°C.

Extract preparation with lysozyme. Cultures of E. coli JM109/p $Delta$ blue and JM109/prIM grown overnight (16 h) (optical density at 600 nm [OD₆₀₀] of 1.98 ± 0.50)were grown in LB containing 100 µg of AMP per ml at 37°C. Thestarter cultures were centrifuged at 4,350 × g for 10 min andresuspended in LB, and 0.5-ml samples of starter cultures wereused to inoculate 500-ml portions of LB containing 200 µg of AMPper ml in 2-liter triple-baffled flasks (Bellco, Vineland, N.J.)to a cell density of approximately 10⁷ cells/ml. Cultures were incubated at 37°C, with shaking at 250rpm. Samples were removed and centrifuged at 5,500 × g for 10min at 4°C. The pellets were washed twice in buffer A (50 mM TrisCl [pH 7.5], 1 mM EDTA, 100 mM NaCl, 10% glycerol, 15 mM 2-mercaptoethanol,100 µM phenylmethylsulfonyl fluoride [PMSF], and stored at $-$ 20°Cuntil used. Pellets were thawed on ice and resuspended in 3.2ml of buffer A per g of pellet. Cells were lysed by using lysozymeas described previously (6) except RNase was omitted. Lysateswere centrifuged at 15,800 × g for 20 min at 4°C. The supernatantswere removed and centrifuged at 100,000 × g for 60 min at 4°C.Supernatants were stored at $-$ 20°C until used. Lysis yields rangedfrom 6 to 17 mg of protein/ml.

Methyl-accepting capacity reactions. Briefly, a 50-µl reaction mixture containing 100 mM sodium phosphate (pH 6.8), 25 to 100 µg of extract protein, 100 µM [³H]AdoMet (specific activity, 500 dpm pmol¹), and 2.7 µM PIMT in a 1.5-ml microcentrifuge tube was incubatedat 30°C for 30 min. Reactions were stopped and processed in amethanol diffusion assay as previously described (33).

To determine whether the enzymes used to produce the lysozyme lysis extracts contributed artifactually to the observed isoaspartylcontent of the extracts, we assayed samples of lysis buffer containingthe same amounts of lysozyme and DNase I used for extract preparation.We detected no significant amounts of isoaspartate in thesesamples.

Methyltransferase assays. PIMT activity was measured as previously described (1) by using bovine gamma globulins as the methyl acceptor and [³H]AdoMet as the methyldonor.

Gel electrophoresis. Samples were methylated for 10 min at 30°C in 100 mM potassium (2-[N-morpholino]ethanesulfonic acid) (potassium MES) (pH 6.2)containing 38 µM [³H]AdoMet (specific activity, 30,000 dpm/pmol) and 2 to 3 µM PIMT.The final volume was 6 µl. Reactions were processed as describedpreviously (32). The acidic pH sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) gel system of Fairbanks and Avruchwas used (7) (10% acrylamide, 0.75-mm-thick gels) followedby fluorography as described previously (17).

Ribosome preparation. E. coli JM109/p $Delta$ blue cells were grown in LB containing 200 µg of AMP per ml at 37°C in 2-liter triple-baffled flasks (500ml of LB per culture) on a shaker table set at 250 rpm. Logarithmic-phasecells (OD₆₀₀ of 1.1) were harvested by centrifugation at 4,640× g for 10 min. The pellets were washed two times in buffer B(10 mM Tris Cl [pH 7.6], 15 mM MgCl₂, 500 mM NH₄Cl, 1 mM dithiothreitol)and stored at $-$ 70°C. After the pellets were resuspended in bufferB, the cells were lysed with a French pressure cell (AmericanInstrument Co.) at 6,000 to 8,000 lb/in². The lysate was centrifuged at 39,200 × g for 45 min. Ribosomeswere pelleted by centrifuging the supernatant at 226,000 × g for3 h. The pellet was resuspended in a small volume of buffer Band stirred overnight at 4°C. The suspension was centrifuged at39,200 × g for 45 min, and the pellet was discarded. The supernatantwas then subjected to another round of ultracentrifugation andresuspension under the same conditions as described above. Thefinal resuspended material was clarified by centrifugation at12,100 × g for 15 min, and the supernatant was stored at $-$ 70°Cuntilused.

Immunoprecipitation. 70S ribosomes in buffer B were applied to a Pharmacia Micro Spin S-200 HR column equilibrated in a solution containing 50mM potassium MES (pH 6.2), 200 mM KCl, 1 mM dithiothreitol, 100µM PMSF. This column was used for buffer exchange by followingthe manufacturer's instructions. Next the 70S ribosomes (390 µgof protein) were methylated with 50 µM [³H]AdoMet (specific activity, 29,000 dpm/pmol) and 2 µM PIMT for15 min at 30°C in a final concentration of 100 mM potassium MES,pH 6.2. The reaction was stopped by the addition of 10 µl of 5mM S-adenosyl homocysteine, and the reaction mixture was placedon ice. To remove potassium ions, S-adenosyl homocysteine, andunreacted [³H]AdoMet, the reaction mixture was applied to another Micro Spincolumn equilibrated in a solution of 50 mM sodium MES (pH 6.2),200 mM NH₄Cl, and 100 µM PMSF. To dissociate r-proteins, the mixturewas heated at 50°C for 10 min in the presence of 0.5% sodium dodecylsulfate (SDS). After cooling, modified radioimmunoprecipitation(RIPA) buffer (11) was added to achieve final concentrationsof 50 mM sodium MES (pH 6.2), 150 mM NH₄Cl, 1% Nonidet P-40, 0.5%sodium deoxycholate, 0.1% SDS, and 100 µM PMSF. Twenty-microliterportions of the methylated, dissociated 70S mixture along with20 µl of modified RIPA buffer were incubated for 1 h at 4°C with5 µl of polyclonal serum raised against purified r-proteins. Next,100 µl of protein A-Sepharose (10% suspension in modified RIPAbuffer) was added, and the tubes were gently rotated at 4°C for1 h. After centrifugation at 11,600 × g for 20 s at 4°C, the supernatantswere aspirated and discarded, and the pellets were washed twotimes in modified RIPA buffer, followed by one wash in 50 mM sodiumMES (pH 6.2)-200 mM NH₄Cl. The pellets were resuspended in 38mM sodium MES (pH 6.2)-2% SDS-700 mM 2-mercaptoethanol. Sampleswere heated at 50°C for 10 min and then acidified by the additionof 4 µl of a solution containing 0.5 M sodium phosphate (pH 2.4),50% glycerol, and 1.5 mg of pyronin Y per ml. After centrifugation,10-µl portions of the supernatants were loaded onto an acidicpH SDS-PAGE gel as describedabove.

Other methods. Protein concentrations were determined by the method of Lowry et al. (25) following precipitation in a final concentrationof 5% (wt/vol) trichloroacetic acid. Bovine serum albumin wasused as thestandard.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Methyltransferase activity and isoaspartate levels in E. coli expressing rat PIMT. To investigate a possible relationship between PIMT activity and protein isoaspartyl content, we grew E. coli JM109 cellstransformed with the rat PIMT-expressing plasmid prIM (prIM cells),and as a control, JM109 cells transformed with the expressionvector p $Delta$ blue, which lacks the PIMT cDNA. The growth curves ofthe two cultures were nearly identical as monitored by opticaldensity (Fig. 2A, upper panel). Hence, bacterial expression ofthe foreign gene was not detrimental to culture growth. As expected,PIMT activity in the overexpressing cells was always higher thanin control cells, and the difference was greatest during stationaryphase (25.5 h) when PIMT activity in prIM cell extracts was 70times that in control cells (15.3 ± 3.4 compared to 0.216 ± 0.032pmol of methyl/min/mg) (Fig. 2A, lower panel).

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FIG. 2. Methyltransferase activity and methyl-accepting capacity of E. coli JM109/p $Delta$ blue (control) and JM109/prIM extracts with respect to culture growth phase. (A) Growth curve (with optical density of culture represented by log OD₆₀₀) (top) and methyltransferase activity of extracts (bottom). Datum points are averages from three separate experiments, and error bars represent standard deviations from the mean. (B) Acidic pH SDS-PAGE analysis of [³H]AdoMet-methylated JM109/p $Delta$ blue (control) and JM109/prIM extracts from the same cultures as shown in panel A. Fluorograms of gels are shown for lanes 1 to 12. Purified PIMT was included (+) or was not included ( $-$ ) in the methylation reaction mixtures. Methylation conditions were as described in Materials and Methods. A 1-week exposure is shown. Lanes 13 and 14 show Coomassie brilliant blue (CBB) staining pattern of JM109/p $Delta$ blue (control) extracts. The extract in lane 13 was prepared from cells harvested 4.5 h postinoculation (logarithmic phase), and the extract in lane 14 was prepared from cells harvested 8 h postinoculation (late logarithmic/early stationary phase). All lanes contained 9 µg of extract protein. The figure was prepared with Adobe Photoshop version 5.0 for the Macintosh computer.

We examined the molecular mass distribution of isoaspartate-containing proteins in the extracts by methylating the extractswith [³H]AdoMet and PIMT followed by acidic pH SDS- PAGE and fluorography.We used the pH 2.4 gel system of Fairbanks and Avruch (7) topreserve base-labile methyl esters typically generated by PIMT.Surprisingly, analysis of logarithmic-phase cell extracts revealedonly one major methyl-accepting protein band which migrated atabout 14 kDa (Fig. 2B, lanes 1, 3, and 4). Methylation was PIMTdependent; no bands were seen in lanes containing control cellextracts subjected to the methylation conditions lacking exogenousPIMT (Fig. 2B, lanes 2, 6, and 10). As the control cell cultureaged in stationary phase, several additional bands of higher molecularmass appeared (Fig. 2B, lane 9). The major methyl-accepting 14-kDaband in prIM cell extracts almost disappeared from samples harvestedin stationary phase at 16 h postinoculation (Fig. 2B, lane 7),and a diffuse, light pattern of methyl incorporation was seenin the 25.5-h sample (Fig. 2B, lane 11). At the 4.5- and 25.5-htime points, prIM cell extracts had fainter bands migrating at14 kDa in lanes that had no exogenous PIMT included in the methylationreaction mixtures (Fig. 2B, lanes 4 and 12). These bands weredue to methylation catalyzed by the rat PIMT expressed by thecells. In both the prIM and control cell extracts, the heavilymethylated 14-kDa protein and the more lightly methylated higher-massproteins appeared to constitute two distinct classes of methylacceptors. The overall lower levels of isoaspartate in prIM cellproteins suggested that the highly expressed rat PIMT was retardingthe accumulation of isoaspartylsites.

The Coomassie blue staining patterns of the extracts after SDS-PAGE varied with respect to the sample's growth phase but notwith respect to the culture identity (Fig. 2B, lanes 13 and 14).At the earliest sampling point, 4.5 h postinoculation, there wasa darkly stained band that migrated at around 14 kDa, and itsposition matched that of the major methyl-accepting band seenin the fluorograms. In extracts made from cells in late logarithmicor stationary phase, protein migrating at around 14 kDa did notstain as darkly (Fig. 2B, lane 14), suggesting that the concentrationof the methyl acceptor in these extracts was lower than in thelogarithmic-phaseextracts.

We repeated the methylation reactions, electrophoresis, and fluorography on extracts made from logarithmic- and late stationary-phaseE. coli JM109 and DH1 cells to see whether the major methyl-acceptingprotein(s) was encoded on the plasmid or chromosome. Both JM109and DH1 extracts showed methylation patterns very similar to thatseen with control cell extracts (JM109/p $Delta$ blue) (data not shown).These results indicated that the major methyl-accepting protein(s)was encoded by the E. coli chromosome and was not strainspecific.

Identity of the 14-kDa isoaspartate-rich protein. The 14-kDa methyl acceptor appeared to have an overall positive charge. After methylation with PIMT and [³H]AdoMet, extracts made from logarithmic-phase control and prIMcultures were subjected to electrophoresis in a Triton-aceticacid-urea polyacrylamide gel system designed to separate highlybasic proteins (39). Fluorography showed a single band in eachextract that migrated near calf thymus histone H2B, which is highlybasic and has a molecular mass of 13.8 kDa (data not shown). Theintensities of the bands on the fluorogram from the Triton-aceticacid-urea-polyacrylamide gel were comparable to those on SDS-PAGEgel fluorograms, suggesting that most of the 14-kDa methyl acceptorseen in Fig. 2B was associated with a highly basicprotein.

The low-molecular-mass, positive charge, and enrichment in logarithmic-phase cultures led us to suspect that the 14-kDa methylacceptor may be a r-protein. Most E. coli r-proteins have molecularmasses between 7 to 25 kDa, are most abundant in logarithmic phase(28a), and are very basic. To explore the idea that the majormethyl acceptor was an r-protein, we prepared crude 70S ribosomesfrom a logarithmic-phase JM109/p $Delta$ blue culture (these cells hadpreviously been used as the control cells in experiments involvingcells that overexpress PIMT [see above]). The final fraction containing70S ribosomes had a methyl-accepting capacity 3.3-fold higherthan that of the crude extract. As shown in the Fig. 3A fluorogram,the crude extract contained one major band at around 14 kDa, andthis band was enhanced in the 70S ribosome fraction. There wasalso a faint band in the 70S fraction migrating near the 21.5-kDamolecular mass marker. From these results, we concluded that the14-kDa substrate was indeed one or more r-proteins.

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FIG. 3. Identification of r-protein S11 as the major methyl acceptor. (A) Major methyl acceptor copurified with 70S ribosomes. Ribosomes were isolated from logarithmic-phase E. coli JM109/p $Delta$ blue cultures as described in Materials and Methods. Samples (3.6 µg of protein) were methylated with PIMT and [³H]AdoMet and subjected to acidic pH SDS-PAGE followed by fluorography. Prior to methylation, the extracts were diluted in buffer such that the final magnesium and ammonium ion concentrations were 0.2 and 25 mM, respectively. A 48-h fluorogram is shown. Abbreviations: CE, crude extract; SU, supernatant after centrifugation of CE at 226,000 × g for 3 h; 70S, 70S ribosomal fraction. (B) The major methyl acceptor was in the 30S subunit, and its methylation was blocked by magnesium. Purified 30S (8.5 pmol of subunit, 3.1 µg of protein) and 50S (8.5 pmol of subunit, 4.4 µg of protein) subunits and 70S ribosomes (1.7 pmol of ribosome, 3 µg of protein) were methylated with PIMT and [³H]AdoMet and subjected to acidic pH SDS-PAGE followed by fluorography. The presence (+) or absence ( $-$ ) of EDTA is indicated above the lanes. EDTA, when present in the reaction mixtures (lanes 2, 4, and 6), was at a final concentration of 15 mM. A 7-h fluorogram is shown. (C) Immunoprecipitation of the major methyl acceptor by antibodies (Ab) raised against E. coli r-protein S11. Experimental details are described in Materials and Methods. Antibodies directed against r-protein L16 (lane 8) were included in this experiment as a negative control. A 47-h fluorogram is shown. The brightness and contrast of each fluorogram were optimized, and the figure was prepared with Adobe Photoshop version 5.0 for the Macintosh computer.

In the course of our experiments with 70S ribosomes and ribosomal subunits (see below), we found that the 14-kDa substratecould not be methylated when magnesium and ammonium ions (componentsof the buffer used in ribosome purification) were present at concentrationsof 5.0 mM and 170 mM, respectively, but could be methylated whenthe concentrations of these ions in the reaction mixtures werelowered to 0.26 and 27 mM, respectively. To see whether the effectwas substrate or enzyme specific, we tested the ability of PIMTto methylate a synthetic isoaspartyl-containing peptide at variousconcentrations of magnesium and ammonium ions (Table 1). Methylationof the peptide was not inhibited even at the highest concentrationof magnesium tested, 22.5 mM, a concentration 4.5-fold higherthan was present during methylation of extracts and r-proteinsprior to SDS-PAGE analysis. Ammonium ion had a slight inhibitoryeffect on PIMT methylation when it was present at 200 mM, andno inhibition was seen when it was present at 25 mM. When thehighest tested concentrations of magnesium and ammonium ions wereincluded together in the reaction mixture, PIMT methylation ofthe peptide was inhibited by 34% compared to the control. We concludethat the inability of PIMT to methylate the 14-kDa substrate inthe presence of magnesium and ammonium ions was due to an interactionof these cations with the ribosome or with the individual substrateitself and not with the methyltransferase.

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TABLE 1. Effects of magnesium and ammonium ions on the ability of PIMT to methylate isoaspartyl $delta$ -sleep-inducing peptide^a

To determine whether the 14-kDa substrate was in the 30S, 50S, or both of the ribosomal subunits, we methylated purified subunitswith [³H]AdoMet and PIMT and subjected them to SDS-PAGE followed by fluorography.Figure 3B shows that the 14-kDa substrate was solely a componentof the 30S subunit. No methylation occurred in the absence ofEDTA due to the presence of 5 mM magnesium in the subunit storagebuffer (compare lanes 1 and 2 in Fig. 3B). The ammonium ion concentrationin the methylation reaction mixtures was 50 mM. The results inFig. 3B also demonstrate that the 14-kDa substrate was presentin another strain of E. coli, namely,MRE600.

We next used an immunoprecipitation technique to identify which r-protein in the 30S subunit was the 14-kDa substrate. Wetested antibodies made against purified r-proteins that were basicand that had molecular masses which fell within 15% of 14 kDa.Our screening included antibodies directed towards S5, S8, S9,S10, S11, S12, S13, and S14. The results shown in Fig. 3C arefrom a typical experiment and indicate that r-protein S11 wasthe only significant methyl acceptor. Radiolabel precipitatedby antibodies other than anti-S11 was no greater than in the control(lane 1). S11 has a molecular mass of 13,728 Da (40), and itsisoelectric point is greater than 12 (19).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Isoaspartate in E. coli. It appears that isoaspartate in E. coli has two sources. One source, dominant in logarithmic-phase cells, resides almost exclusivelyin the 14-kDa protein we identified as r-protein S11. The secondsource is a group of higher-mass proteins that slowly accumulateisoaspartate during stationary phase. A rise in isoaspartate duringstationary phase was anticipated previously by Li and Clarke,who suggested that isoaspartate accumulation might contributeto the loss of viability that occurs in stationary phase (24).More recently, Visick et al. provided the first direct evidencethat isoaspartate does indeed accumulate during stationary phase(38). In that study, however, no comparisons were made betweenisoaspartate levels in early logarithmic and stationary phasesand no information on the nature of the methyl-accepting specieswasreported.

PIMT from a mammalian source is likely to be better than a bacterial PIMT in detecting isoaspartate in proteins because ithas a higher specific activity and recognizes isoaspartate ina wide variety of proteins and peptides. PIMT from E. coli haslow activity toward proteins (23) and moderate activity towardan isoaspartyl-containing nonapeptide (8).

Isoaspartate in r-protein S11. Twenty-one years ago, well before it was known that PIMT is selective for isoaspartate, Kim et al. (21) reported base-labilemethylation of 30S E. coli r-proteins S3 and S9, and, possibly,S6 and S11. r-protein S3 has a molecular mass of 25,852 Da (40),which makes it an unlikely candidate for the 14-kDa methyl acceptorwe have observed; however, S3 could be the less-pronounced methylacceptor that migrated above the 21.5-kDa marker (Fig. 3A, lane3). r-protein S6 has a molecular mass of 15,704 Da, but it isacidic (isoelectric point of 4.9). It would not have migratedinto the Triton-acetic acid-urea-polyacrylamide gels, so althoughS6 may have a small amount of isoaspartate, we eliminated it asa candidate for the major methylacceptor.

Our immunological results indicate that r-protein S11 was the major methyl-accepting protein in E. coli extracts. S11 is locatedon the platform region in the small (30S) subunit (29, 35).This platform region faces the large (50S) subunit (22) andis believed to be involved with codon-anticodon recognition (seereference 29 and referencestherein).

Both magnesium and ammonium ions appeared to inhibit the in vitro methylation of S11 catalyzed by PIMT. Magnesium has beenshown to stabilize 70S ribosomes and subunits in vitro (36).At low (<2 mM) concentrations of magnesium, the 30S subunit becomesinactive with regard to the binding of Phe-tRNA (42). This inactivityhas been attributed to a magnesium-dependent conformational change.A decrease in the ammonium ion concentration also leads to theinactivation of the 30S subunit. Additionally, incubation temperatureaffects the activity state of subunits. 30S subunits that havebeen inactivated by decreasing the concentration of magnesiumor ammonium ions can be reactivated by replenishing the missingcation and heating the mixture. Perhaps these changes in 30S subunitconformation are intimately involved in changes in the tertiarystructure of S11, leading to different states of the protein whichhave various degrees of accessibility to PIMT. Our observationthat E. coli cultures overproducing PIMT had significantly loweramounts of isoaspartate in S11 argues that the PIMT-accessibleform of S11 does exist invivo.

The mole fraction of isoaspartate in S11 is at least 30-fold higher than in the average mammalian or E. coli cytosolic protein.By measuring the picomoles of [³H]methyl incorporated per microgram of ribosome protein and accountingfor the known stoichiometry of S11 within the ribosome, we calculatedthat S11 contains approximately 0.5 mol of isoaspartate per molof protein. The unusually high level of isoaspartate in S11 suggeststhat isoaspartate may be involved in the function ofS11.

Do the E. coli and rat forms of PIMT have similar functions? One of the original goals of this study was to test the putative repair function of mammalian PIMT by observing the relationshipbetween isoaspartate and PIMT levels in E. coli transformed withprIM or a control plasmid. The high PIMT activity afforded byexpression of the rat enzyme in prIM cells led to a significantreduction in isoaspartate in S11 as well as in the higher-massproteins that accumulated isoaspartate during stationary phase.The rat PIMT apparently recognizes and methylates the S11 isoaspartylsite even though the E. coli homologue may not. These findingslend strong support to the idea that mammalian PIMT converts atypicalisoaspartyl peptide bonds back to normallinkages.

It is unclear at present whether the E. coli enzyme serves a similar repair function. Although inactivation of the PIMT genein mice leads to premature death in conjunction with high isoaspartatelevels (20, 41), disruption of the E. coli PIMT gene alonehas no marked effect on prolonged stationary-phase survival (37)nor does it lead to an increase in isoaspartate levels (38).As noted by Visick et al. (38), this unexpected result doesnot rule out a repair function for E. coli PIMT because otherenzymes, such as proteases, may compensate for the loss of PIMTby rapidly degrading the abnormal isoaspartate-containing proteins.On the other hand, there is additional evidence that PIMT in E.coli differs functionally from its mammalian counterpart. First,as shown by Fu et al. (8), the E. coli and mammalian formsof PIMT differ dramatically in their abilities to methylate ovalbuminrelative to a synthetic isoaspartate-containing peptide, suggestingthat the E. coli enzyme recognizes a more restricted range ofsequences than does the mammalian enzyme. Second, PIMT is apparentlynot required for all life forms, since it appears to be absentfrom several bacteria, including all gram-positive species tested(23), and from the yeasts Schizosaccharomyces pombe and Saccharomycescerevisiae (18). Because isoaspartate repair enzymes are apparentlynot essential for all bacteria, it follows that the presence ofthe isoaspartate-modifying methyltransferase in E. coli could,in principle, have a function other than protein repair. Isoaspartylsites are characterized by an atypical $alpha$ -carboxyl group that resemblesthe $alpha$ -carboxyl normally found only at the C terminus of a polypeptide(14, 28). It seems possible that the E. coli PIMT is designedto modify isoaspartate-like carboxyl groups in a context unrelatedto protein damage. Further studies on the substrate specificityof E. coli PIMT may provide important new insights as to its functionand mechanism ofaction.

	ACKNOWLEDGMENTS

This work was supported in part by NIH grantNS17269.

We thank Harry Noller and Masayasu Nomura for providing materials and Lynn Young for technical assistance in figurepreparation.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Molecular Biology and Biochemistry, University of California, Irvine,Irvine, CA 92697-3900. Phone: (949) 824-6866. Fax: (949) 824-8551.E-mail: dwaswad{at}uci.edu.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Aswad, D. W., and E. A. Deight. 1983. Purification and characterization of two distinct isozymes of protein carboxymethylase from bovine brain. J. Neurochem. 40:1718-1726[Medline].

2. Brandt, M. E., and L. E. Vickery. 1992. Expression and characterization of human mitochondrial ferredoxin reductase in Escherichia coli. Arch. Biochem. Biophys. 294:735-740[Medline].

3. Brennan, T. V., J. W. Anderson, Z. Jia, E. B. Waygood, and S. Clarke. 1994. Repair of spontaneously deamidated HPr phosphocarrier protein catalyzed by the L-isoaspartate-(D-aspartate) O-methyltransferase. J. Biol. Chem. 269:24586-24595[Abstract/Free Full Text].

4. Brennan, T. V., and S. Clarke. 1995. Deamidation and isoaspartate formation in model synthetic peptides: the effects of sequence and solution environment, p. 65-90. In D. W. Aswad (ed.), Deamidation and isoaspartate formation in peptides and proteins. CRC Press, Boca Raton, Fla.

5. Chirpich, T. P. 1968. Ph.D. dissertation. University of California, Berkeley.

6. David, C. L., and D. W. Aswad. 1995. Cloning, expression, and purification of rat brain protein L-isoaspartyl methyltransferase. Protein Expr. Purif. 6:312-318[Medline].

7. Fairbanks, G., and J. Avruch. 1972. Four gel systems for electrophoretic fractionation of membrane proteins using ionic detergents. J. Supramol. Struct. 1:66-75[Medline].

8. Fu, J. C., L. Ding, and S. Clarke. 1991. Purification, gene cloning, and sequence analysis of L-isoaspartyl protein carboxyl methyltransferase from Escherichia coli. J. Biol. Chem. 266:14562-14572[Abstract/Free Full Text].

9. Galletti, P., A. Ciardiello, D. Ingrosso, and A. Di Donato. 1988. Repair of isopeptide bonds by protein carboxyl O-methyltransferase: seminal ribonuclease as a model system. Biochemistry 27:1752-1757[Medline].

10. Geiger, T., and S. Clarke. 1987. Deamidation, isomerization, and racemization at asparaginyl and aspartyl residues in peptides. J. Biol. Chem. 262:785-794[Abstract/Free Full Text].

11. Harlow, E., and D. Lane. 1988. Antibodies: a laboratory manual. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

12. Ichikawa, J. K., and S. Clarke. 1998. A highly active protein repair enzyme from an extreme thermophile: the L-isoaspartyl methyltransferase from Thermotoga maritima. Arch. Biochem. Biophys. 358:222-231[Medline].

13. Johnson, B. A., and D. W. Aswad. 1985. Enzymatic protein carboxyl methylation at physiological pH: cyclic imide formation explains rapid methyl turnover. Biochemistry 24:2581-2586[Medline].

14. Johnson, B. A., and D. W. Aswad. 1990. Fragmentation of isoaspartyl peptides and proteins by carboxypeptidase Y: release of isoaspartyl dipeptides as a result of internal and external cleavage. Biochemistry 29:4373-4380[Medline].

15. Johnson, B. A., E. L. Langmack, and D. W. Aswad. 1987. Partial repair of deamidation-damaged calmodulin by protein carboxyl methyltransferase. J. Biol. Chem. 262:12283-12287[Abstract/Free Full Text].

16. Johnson, B. A., E. D. Murray, Jr., S. Clarke, D. B. Glass, and D. W. Aswad. 1987. Protein carboxyl methyltransferase facilitates conversion of atypical L-isoaspartyl peptides to normal L-aspartyl peptides. J. Biol. Chem. 262:5622-5629[Abstract/Free Full Text].

17. Johnson, B. A., J. Najbauer, and D. W. Aswad. 1993. Accumulation of substrates for protein-L-isoaspartyl methyltransferase in adenosine dialdehyde-treated PC12 cells. J. Biol. Chem. 268:6174-6181[Abstract/Free Full Text].

18. Kagan, R. M., H. J. McFadden, P. N. McFadden, C. O'Connor, and S. Clarke. 1997. Molecular phylogenetics of a protein repair methyltransferase. Comp. Biochem. Physiol. B 117:379-385[Medline].

19. Kaltschmidt, E. 1971. Ribosomal proteins. XIV. Isoelectric points of ribosomal proteins of E. coli as determined by two-dimensional polyacrylamide gel electrophoresis. Anal. Biochem. 43:25-31[Medline].

20. Kim, E., J. D. Lowenson, D. C. MacLaren, S. Clarke, and S. G. Young. 1997. Deficiency of a protein-repair enzyme results in the accumulation of altered proteins, retardation of growth, and fatal seizures in mice. Proc. Natl. Acad. Sci. USA 94:6132-6137[Abstract/Free Full Text].

21. Kim, S., B. Lew, and F. N. Chang. 1977. Enzymatic methyl esterification of Escherichia coli ribosomal proteins. J. Bacteriol. 130:839-845[Abstract/Free Full Text].

22. Lake, J. A. 1982. Ribosomal subunit orientations determined in the monomeric ribosome by single and by double-labeling immune electron microscopy. J. Mol. Biol. 161:89-106[Medline].

23. Li, C., and S. Clarke. 1992. Distribution of an L-isoaspartyl protein methyltransferase in eubacteria. J. Bacteriol. 174:355-361[Abstract/Free Full Text].

24. Li, C., and S. Clarke. 1992. A protein methyltransferase specific for altered aspartyl residues is important in Escherichia coli stationary-phase survival and heat-shock resistance. Proc. Natl. Acad. Sci. USA 89:9885-9889[Abstract/Free Full Text].

25. Lowry, O. H., N. J. Rosebrough, A. L. Farr, and R. J. Randall. 1951. Protein measurement with the Folin phenol reagent. J. Biol. Chem. 193:265-275[Free Full Text].

26. McFadden, P. N., and S. Clarke. 1987. Conversion of isoaspartyl peptides to normal peptides: implications for the cellular repair of damaged proteins. Proc. Natl. Acad. Sci. USA 84:2595-2599[Abstract/Free Full Text].

27. Mudgett, M. B., J. D. Lowenson, and S. Clarke. 1997. Protein repair L-isoaspartyl methyltransferase in plants. Plant Physiol. 115:1481-1489[Abstract].

28. Murray, E. D., Jr., and S. Clarke. 1984. Synthetic peptide substrates for the erythrocyte protein carboxyl methyltransferase. J. Biol. Chem. 259:10722-10732[Abstract/Free Full Text].

28a. Neidhardt, F. C., J. L. Ingraham, and M. Schaechter. 1990. Physiology of the bacterial cell: a molecular approach, p. 420-434. Sinaver Associates, Inc., Sunderland, Mass.

29. Oakes, M., E. Henderson, A. Scheinman, M. Clarke, and J. A. Lake. 1985. Ribosome structure, function, and evolution: mapping ribosomal RNA, proteins, and functional sites in three dimensions, p. 47-67. In B. Hardesty, and G. Kramer (ed.), Structure, function, and genetics of ribosomes. Springer-Verlag, New York, N.Y.

30. O'Connor, C. M., and S. Clarke. 1985. Specific recognition of altered polypeptides by widely distributed methyltransferases. Biochem. Biophys. Res. Commun. 132:1144-1150[Medline].

31. O'Connor, M. B., A. Galus, M. Hartenstine, M. Magee, F. R. Jackson, and C. M. O'Connor. 1997. Structural organization and developmental expression of the protein isoaspartyl methyltransferase gene from Drosophila melanogaster. Insect Biochem. Mol. Biol. 27:49-54[Medline].

32. Orpiszewski, J., and D. W. Aswad. 1996. High mass methyl-accepting protein (HMAP), a highly effective endogenous substrate for protein L-isoaspartyl methyltransferase in mammalian brain. J. Biol. Chem. 271:22965-22968[Abstract/Free Full Text].

33. Potter, S. M., W. J. Henzel, and D. W. Aswad. 1993. In vitro aging of calmodulin generates isoaspartate at multiple Asn-Gly and Asp-Gly sites in calcium-binding domains II, III, and IV. Protein Sci. 2:1648-1663[Abstract].

34. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

35. Stöffler, G., and M. Stöffler-Meilicke. 1985. Immuno electron microscopy on Escherichia coli ribosomes, p. 28-46. In B. Hardesty, and G. Kramer (ed.), Structure, function, and genetics of ribosomes. Springer-Verlag, New York, N.Y.

36. Tissiéres, A., J. D. Watson, D. Schlessinger, and B. R. Hollingworth. 1959. Ribonucleoprotein particles from Escherichia coli. J. Mol. Biol. 1:221-233.

37. Visick, J. E., H. Cai, and S. Clarke. 1998. The L-isoaspartyl protein repair methyltransferase enhances survival of aging Escherichia coli subjected to secondary environmental stresses. J. Bacteriol. 180:2623-2629[Abstract/Free Full Text].

38. Visick, J. E., J. K. Ichikawa, and S. Clarke. 1998. Mutations in the Escherichia coli surE gene increase isoaspartyl accumulation in a strain lacking the pcm repair methyltransferase but suppress stress-survival phenotypes. FEMS Microbiol. Lett. 167:19-25[Medline].

39. Wiekowski, M., and M. L. DePamphilis. 1993. Gel analysis of histone synthesis. Methods Enzymol. 225:489-501[Medline].

40. Wittmann, H. G. 1982. Components of bacteria ribosomes. Annu. Rev. Biochem. 51:155-183[Medline].

41. Yamamoto, A., H. Takagi, D. Kitamura, H. Tatsuoka, H. Nakano, H. Kawano, H. Kuroyanagi, Y. Yahagi, S. Kobayashi, K. Koizumi, T. Sakai, K. Saito, T. Chiba, K. Kawamura, K. Suzuki, T. Watanabe, H. Mori, and T. Shirasawa. 1998. Deficiency in protein L-isoaspartyl methyltransferase results in a fatal progressive epilepsy. J. Neurosci. 18:2063-2074[Abstract/Free Full Text].

42. Zamir, A., R. Miskin, and D. Elson. 1971. Inactivation and reactivation of ribosomal subunits: amino acyl-transfer RNA binding activity of the 30 s subunit of Escherichia coli. J. Mol. Biol. 60:347-364[Medline].

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	ALL ASM JOURNALS

1.	Aswad, D. W., and E. A. Deight. 1983. Purification and characterization of two distinct isozymes of protein carboxymethylase from bovine brain. J. Neurochem. 40:1718-1726[Medline].
2.	Brandt, M. E., and L. E. Vickery. 1992. Expression and characterization of human mitochondrial ferredoxin reductase in Escherichia coli. Arch. Biochem. Biophys. 294:735-740[Medline].
3.	Brennan, T. V., J. W. Anderson, Z. Jia, E. B. Waygood, and S. Clarke. 1994. Repair of spontaneously deamidated HPr phosphocarrier protein catalyzed by the L-isoaspartate-(D-aspartate) O-methyltransferase. J. Biol. Chem. 269:24586-24595[Abstract/Free Full Text].
4.	Brennan, T. V., and S. Clarke. 1995. Deamidation and isoaspartate formation in model synthetic peptides: the effects of sequence and solution environment, p. 65-90. In D. W. Aswad (ed.), Deamidation and isoaspartate formation in peptides and proteins. CRC Press, Boca Raton, Fla.
5.	Chirpich, T. P. 1968. Ph.D. dissertation. University of California, Berkeley.
6.	David, C. L., and D. W. Aswad. 1995. Cloning, expression, and purification of rat brain protein L-isoaspartyl methyltransferase. Protein Expr. Purif. 6:312-318[Medline].
7.	Fairbanks, G., and J. Avruch. 1972. Four gel systems for electrophoretic fractionation of membrane proteins using ionic detergents. J. Supramol. Struct. 1:66-75[Medline].
8.	Fu, J. C., L. Ding, and S. Clarke. 1991. Purification, gene cloning, and sequence analysis of L-isoaspartyl protein carboxyl methyltransferase from Escherichia coli. J. Biol. Chem. 266:14562-14572[Abstract/Free Full Text].
9.	Galletti, P., A. Ciardiello, D. Ingrosso, and A. Di Donato. 1988. Repair of isopeptide bonds by protein carboxyl O-methyltransferase: seminal ribonuclease as a model system. Biochemistry 27:1752-1757[Medline].
10.	Geiger, T., and S. Clarke. 1987. Deamidation, isomerization, and racemization at asparaginyl and aspartyl residues in peptides. J. Biol. Chem. 262:785-794[Abstract/Free Full Text].
11.	Harlow, E., and D. Lane. 1988. Antibodies: a laboratory manual. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
12.	Ichikawa, J. K., and S. Clarke. 1998. A highly active protein repair enzyme from an extreme thermophile: the L-isoaspartyl methyltransferase from Thermotoga maritima. Arch. Biochem. Biophys. 358:222-231[Medline].
13.	Johnson, B. A., and D. W. Aswad. 1985. Enzymatic protein carboxyl methylation at physiological pH: cyclic imide formation explains rapid methyl turnover. Biochemistry 24:2581-2586[Medline].
14.	Johnson, B. A., and D. W. Aswad. 1990. Fragmentation of isoaspartyl peptides and proteins by carboxypeptidase Y: release of isoaspartyl dipeptides as a result of internal and external cleavage. Biochemistry 29:4373-4380[Medline].
15.	Johnson, B. A., E. L. Langmack, and D. W. Aswad. 1987. Partial repair of deamidation-damaged calmodulin by protein carboxyl methyltransferase. J. Biol. Chem. 262:12283-12287[Abstract/Free Full Text].
16.	Johnson, B. A., E. D. Murray, Jr., S. Clarke, D. B. Glass, and D. W. Aswad. 1987. Protein carboxyl methyltransferase facilitates conversion of atypical L-isoaspartyl peptides to normal L-aspartyl peptides. J. Biol. Chem. 262:5622-5629[Abstract/Free Full Text].
17.	Johnson, B. A., J. Najbauer, and D. W. Aswad. 1993. Accumulation of substrates for protein-L-isoaspartyl methyltransferase in adenosine dialdehyde-treated PC12 cells. J. Biol. Chem. 268:6174-6181[Abstract/Free Full Text].
18.	Kagan, R. M., H. J. McFadden, P. N. McFadden, C. O'Connor, and S. Clarke. 1997. Molecular phylogenetics of a protein repair methyltransferase. Comp. Biochem. Physiol. B 117:379-385[Medline].
19.	Kaltschmidt, E. 1971. Ribosomal proteins. XIV. Isoelectric points of ribosomal proteins of E. coli as determined by two-dimensional polyacrylamide gel electrophoresis. Anal. Biochem. 43:25-31[Medline].
20.	Kim, E., J. D. Lowenson, D. C. MacLaren, S. Clarke, and S. G. Young. 1997. Deficiency of a protein-repair enzyme results in the accumulation of altered proteins, retardation of growth, and fatal seizures in mice. Proc. Natl. Acad. Sci. USA 94:6132-6137[Abstract/Free Full Text].
21.	Kim, S., B. Lew, and F. N. Chang. 1977. Enzymatic methyl esterification of Escherichia coli ribosomal proteins. J. Bacteriol. 130:839-845[Abstract/Free Full Text].
22.	Lake, J. A. 1982. Ribosomal subunit orientations determined in the monomeric ribosome by single and by double-labeling immune electron microscopy. J. Mol. Biol. 161:89-106[Medline].
23.	Li, C., and S. Clarke. 1992. Distribution of an L-isoaspartyl protein methyltransferase in eubacteria. J. Bacteriol. 174:355-361[Abstract/Free Full Text].
24.	Li, C., and S. Clarke. 1992. A protein methyltransferase specific for altered aspartyl residues is important in Escherichia coli stationary-phase survival and heat-shock resistance. Proc. Natl. Acad. Sci. USA 89:9885-9889[Abstract/Free Full Text].
25.	Lowry, O. H., N. J. Rosebrough, A. L. Farr, and R. J. Randall. 1951. Protein measurement with the Folin phenol reagent. J. Biol. Chem. 193:265-275[Free Full Text].
26.	McFadden, P. N., and S. Clarke. 1987. Conversion of isoaspartyl peptides to normal peptides: implications for the cellular repair of damaged proteins. Proc. Natl. Acad. Sci. USA 84:2595-2599[Abstract/Free Full Text].
27.	Mudgett, M. B., J. D. Lowenson, and S. Clarke. 1997. Protein repair L-isoaspartyl methyltransferase in plants. Plant Physiol. 115:1481-1489[Abstract].
28.	Murray, E. D., Jr., and S. Clarke. 1984. Synthetic peptide substrates for the erythrocyte protein carboxyl methyltransferase. J. Biol. Chem. 259:10722-10732[Abstract/Free Full Text].
28a.	Neidhardt, F. C., J. L. Ingraham, and M. Schaechter. 1990. Physiology of the bacterial cell: a molecular approach, p. 420-434. Sinaver Associates, Inc., Sunderland, Mass.
29.	Oakes, M., E. Henderson, A. Scheinman, M. Clarke, and J. A. Lake. 1985. Ribosome structure, function, and evolution: mapping ribosomal RNA, proteins, and functional sites in three dimensions, p. 47-67. In B. Hardesty, and G. Kramer (ed.), Structure, function, and genetics of ribosomes. Springer-Verlag, New York, N.Y.
30.	O'Connor, C. M., and S. Clarke. 1985. Specific recognition of altered polypeptides by widely distributed methyltransferases. Biochem. Biophys. Res. Commun. 132:1144-1150[Medline].
31.	O'Connor, M. B., A. Galus, M. Hartenstine, M. Magee, F. R. Jackson, and C. M. O'Connor. 1997. Structural organization and developmental expression of the protein isoaspartyl methyltransferase gene from Drosophila melanogaster. Insect Biochem. Mol. Biol. 27:49-54[Medline].
32.	Orpiszewski, J., and D. W. Aswad. 1996. High mass methyl-accepting protein (HMAP), a highly effective endogenous substrate for protein L-isoaspartyl methyltransferase in mammalian brain. J. Biol. Chem. 271:22965-22968[Abstract/Free Full Text].
33.	Potter, S. M., W. J. Henzel, and D. W. Aswad. 1993. In vitro aging of calmodulin generates isoaspartate at multiple Asn-Gly and Asp-Gly sites in calcium-binding domains II, III, and IV. Protein Sci. 2:1648-1663[Abstract].
34.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
35.	Stöffler, G., and M. Stöffler-Meilicke. 1985. Immuno electron microscopy on Escherichia coli ribosomes, p. 28-46. In B. Hardesty, and G. Kramer (ed.), Structure, function, and genetics of ribosomes. Springer-Verlag, New York, N.Y.
36.	Tissiéres, A., J. D. Watson, D. Schlessinger, and B. R. Hollingworth. 1959. Ribonucleoprotein particles from Escherichia coli. J. Mol. Biol. 1:221-233.
37.	Visick, J. E., H. Cai, and S. Clarke. 1998. The L-isoaspartyl protein repair methyltransferase enhances survival of aging Escherichia coli subjected to secondary environmental stresses. J. Bacteriol. 180:2623-2629[Abstract/Free Full Text].
38.	Visick, J. E., J. K. Ichikawa, and S. Clarke. 1998. Mutations in the Escherichia coli surE gene increase isoaspartyl accumulation in a strain lacking the pcm repair methyltransferase but suppress stress-survival phenotypes. FEMS Microbiol. Lett. 167:19-25[Medline].
39.	Wiekowski, M., and M. L. DePamphilis. 1993. Gel analysis of histone synthesis. Methods Enzymol. 225:489-501[Medline].
40.	Wittmann, H. G. 1982. Components of bacteria ribosomes. Annu. Rev. Biochem. 51:155-183[Medline].
41.	Yamamoto, A., H. Takagi, D. Kitamura, H. Tatsuoka, H. Nakano, H. Kawano, H. Kuroyanagi, Y. Yahagi, S. Kobayashi, K. Koizumi, T. Sakai, K. Saito, T. Chiba, K. Kawamura, K. Suzuki, T. Watanabe, H. Mori, and T. Shirasawa. 1998. Deficiency in protein L-isoaspartyl methyltransferase results in a fatal progressive epilepsy. J. Neurosci. 18:2063-2074[Abstract/Free Full Text].
42.	Zamir, A., R. Miskin, and D. Elson. 1971. Inactivation and reactivation of ribosomal subunits: amino acyl-transfer RNA binding activity of the 30 s subunit of Escherichia coli. J. Mol. Biol. 60:347-364[Medline].