Purification, gene cloning, and sequence analysis of an L-isoaspartyl protein carboxyl methyltransferase from Escherichia coli

Biological effects of the loss of homochirality in a multicellular organism

Homochirality is a fundamental feature of all known forms of life, maintaining biomolecules (amino-acids, proteins, sugars, nucleic acids) in one specific chiral form. While this condition is central to biology, the mechanisms by which the adverse accumulation of non-L-α-amino-acids in proteins lead to pathophysiological consequences remain poorly understood. To address how heterochirality build-up impacts organism's health, we use chiral-selective in vivo assays to detect protein-bound non-L-α-amino acids (focusing on aspartate) and assess their functional significance in Drosophila. We find that altering the in vivo chiral balance creates a 'heterochirality syndrome' with impaired caspase activity, increased tumour formation, and premature death. Our work shows that preservation of homochirality is a key component of protein function that is essential to maintain homeostasis across the cell, tissue and organ level.

l-Isoaspartyl Methyltransferase Deficiency in Zebrafish Leads to Impaired Calcium Signaling in the Brain

Isomerization of l-aspartyl and l-asparaginyl residues to l-isoaspartyl residues is one type of protein damage that can occur under physiological conditions and leads to conformational changes, loss of function, and enhanced protein degradation. Protein l-isoaspartyl methyltransferase (PCMT) is a repair enzyme whose action initiates the reconversion of abnormal l-isoaspartyl residues to normal l-aspartyl residues in proteins. Many lines of evidence support a crucial role for PCMT in the brain, but the mechanisms involved remain poorly understood. Here, we investigated PCMT activity and function in zebrafish, a vertebrate model that is particularly well-suited to analyze brain function using a variety of techniques. We characterized the expression products of the zebrafish PCMT homologous genes pcmt and pcmtl. Both zebrafish proteins showed a robust l-isoaspartyl methyltransferase activity and highest mRNA transcript levels were found in brain and testes. Zebrafish morphant larvae with a knockdown in both the pcmt and pcmtl genes showed pronounced morphological abnormalities, decreased survival, and increased isoaspartyl levels. Interestingly, we identified a profound perturbation of brain calcium homeostasis in these morphants. An abnormal calcium response upon ATP stimulation was also observed in mouse hippocampal HT22 cells knocked out for Pcmt1. This work shows that zebrafish is a promising model to unravel further facets of PCMT function and demonstrates, for the first time in vivo, that PCMT plays a pivotal role in the regulation of calcium fluxes.

Effect of amino acids present at the carboxyl end of succinimidyl residue on the rate constants for succinimidyl hydrolysis in small peptides

Structural alterations of aspartyl and asparaginyl residues in various proteins can lead to their malfunction, which may result in severe health disorders. The formation and hydrolysis of succinimidyl intermediates are crucial in specific protein modifications. Nonetheless, only few studies investigating the hydrolysis of succinimidyl intermediates have been published. In this study, we established a method to prepare peptides bearing succinimidyl residues using recombinant protein l-isoaspartyl methyltransferase and ultrafiltration units. Using succinimidyl peptides, we examined the effect of amino acid residues on succinimidyl hydrolysis at the carboxyl end of succinimidyl residues and determined the rate constant of hydrolysis for each peptide. The rate constant of succinimidyl hydrolysis in the peptide bearing a Ser residue at the carboxyl side (0.50 ± 0.02 /h) was 3.0 times higher than that for the peptide bearing an Ala residue (0.17 ± 0.01 /h), whereas it was just 1.2 times higher for the peptide bearing a Gly residue (0.20 ± 0.01 /h). The rate constant of succinimidyl formation in the peptide bearing a Ser residue [(2.44 ± 0.11) × 10^-3 /d] was only 1.2 times higher than that for the peptide bearing an Ala residue ([1.87 ± 0.09) × 10^-3 /d], whereas 5.5 times higher for the peptide bearing a Gly residue [(10.2 ± 0.2) × 10^-3 /d]. These results show that the Gly and Ser residues at the carboxyl end of the succinimidyl residue have opposing roles in succinimidyl formation and hydrolysis. Catalysis of Ser residue's hydroxyl group plays a crucial role in succinimidyl hydrolysis.

PIMT-Mediated Protein Repair: Mechanism and Implications

Amino acids undergo many covalent modifications, but only few amino acid repair enzymes have been identified. Protein-L-isoaspartate (D-aspartate) O-methyltransferase (PIMT), also known as L-isoaspartyl/D-aspartyl protein carboxyl methyltransferase (PCMT), methylates covalently modified isoaspartate (isoAsp) residues accumulated in proteins via Asn deamidation and Asp hydrolysis. This cytoplasmic reaction occurs through the formation of succinimide cyclical intermediate and generates either isoAsp or Asp from succinimide. Succinimide conversion into Asp is spontaneous, while isoAsp is restored by PIMT using S-adenosylmethionine as a methyl donor. PIMT transforms isoAsp into succinimide, thereby creating an opportunity for the later to be converted into Asp. Apart from normal cell physiology, formation of isoAsp in proteins is promoted by various stress conditions. The resulting isoAsp can form a kink or bend in the protein backbone thus making the protein conformationally and functionally distorted. Many PIMT-interacting proteins (proteins with isoAsp residues) have been reported in eukaryotes, but only few of them have been found in prokaryotes. Extensive studies in mice have shown the importance of PIMT in neurodegeneration. Detail elucidation of PIMT function can create a platform for addressing various disorders such as Alzheimer's disease and cancer.

Functional divergence of annotated l-isoaspartate O-methyltransferases in an α-proteobacterium

Spontaneous formation of isoaspartates (isoDs) often causes protein damage. l-Isoaspartate O-methyltransferase (PIMT) repairs isoD residues by catalyzing the formation of an unstable l-isoaspartyl methyl ester that spontaneously converts to an l-aspartyl residue. PIMTs are widely distributed in all three domains of life and have been studied most intensively in connection with their role in protein repair and aging in plants and animals. Studies of bacterial PIMTs have been limited to Escherichia coli, which has one PIMT. The α-proteobacterium Rhodopseudomonas palustris has three annotated PIMT genes, one of which (rpa2580) has been found to be important for cellular longevity in a growth-arrested state. However, the biochemical activities of these three R. palustris PIMTs are unknown. Here, we expressed and characterized all three annotated PIMT proteins, finding that two of them, RPA0376 and RPA2838, had PIMT activity, whereas RPA2580 did not. RPA0376 and RPA2838 single- and double-deletion mutants did not differ in longevity from WT R. palustris and did not exhibit elevated levels of isoD residues in aged cells. Comparative sequence analyses revealed that RPA2580 belongs to a separate phylogenetic group of annotated PIMT proteins present in the α-proteobacteria. Our results suggest that this group of proteins is not involved in repair of protein isoD residues. In addition, the bona fide bacterial PIMT enzymes may play a different or subtler role in bacterial physiology than previously suggested.

Vibrio fischeri DarR Directs Responses to d-Aspartate and Represents a Group of Similar LysR-Type Transcriptional Regulators

Mounting evidence suggests that d-amino acids play previously underappreciated roles in diverse organisms. In bacteria, even d-amino acids that are absent from canonical peptidoglycan (PG) may act as growth substrates, as signals, or in other functions. Given these proposed roles and the ubiquity of d-amino acids, the paucity of known d-amino-acid-responsive transcriptional control mechanisms in bacteria suggests that such regulation awaits discovery. We found that DarR, a LysR-type transcriptional regulator (LTTR), activates transcription in response to d-Asp. The d-Glu auxotrophy of a Vibrio fischerimurI::Tn mutant was suppressed, with the wild-type PG structure maintained, by a point mutation in darR This darR mutation resulted in the overexpression of an adjacent operon encoding a putative aspartate racemase, RacD, which compensated for the loss of the glutamate racemase encoded by murI Using transcriptional reporters, we found that wild-type DarR activated racD transcription in response to exogenous d-Asp but not upon the addition of l-Asp, l-Glu, or d-Glu. A DNA sequence typical of LTTR-binding sites was identified between darR and the divergently oriented racD operon, and scrambling this sequence eliminated activation of the reporter in response to d-Asp. In several proteobacteria, genes encoding LTTRs similar to DarR are linked to genes with predicted roles in d- and/or l-Asp metabolism. To test the functional similarities in another bacterium, darR and racD mutants were also generated in Acinetobacter baylyi In V. fischeri and A. baylyi, growth on d-Asp required the presence of both darR and racD Our results suggest that multiple bacteria have the ability to sense and respond to d-Asp.IMPORTANCE d-Amino acids are prevalent in the environment and are generated by organisms from all domains of life. Although some biological roles for d-amino acids are understood, in other cases, their functions remain uncertain. Given the ubiquity of d-amino acids, it seems likely that bacteria will initiate transcriptional responses to them. Elucidating d-amino acid-responsive regulators along with the genes they control will help uncover bacterial uses of d-amino acids. Here, we report the discovery of DarR, a novel LTTR in V. fischeri that mediates a transcriptional response to environmental d-Asp and underpins the catabolism of d-Asp. DarR represents the founding member of a group of bacterial homologs that we hypothesize control aspects of aspartate metabolism in response to d-Asp and/or to d-Asp-containing peptides.

Molecular Basis of Bacterial Longevity

It is well known that many bacteria can survive in a growth-arrested state for long periods of time, on the order of months or even years, without forming dormant structures like spores or cysts. How is such longevity possible? What is the molecular basis of such longevity? Here we used the Gram-negative phototrophic alphaproteobacterium Rhodopseudomonas palustris to identify molecular determinants of bacterial longevity. R. palustris maintained viability for over a month after growth arrest due to nutrient depletion when it was provided with light as a source of energy. In transposon sequencing (Tn-seq) experiments, we identified 117 genes that were required for long-term viability of nongrowing R. palustris cells. Genes in this longevity gene set are annotated to play roles in a number of cellular processes, including DNA repair, tRNA modification, and the fidelity of protein synthesis. These genes are critically important only when cells are not growing. Three genes annotated to affect translation or posttranslational modifications were validated as bona fide longevity genes by mutagenesis and complementation experiments. These genes and others in the longevity gene set are broadly conserved in bacteria. This raises the possibility that it will be possible to define a core set of longevity genes common to many bacterial species.

Bacteria in nature and during infections often exist in a nongrowing quiescent state. However, it has been difficult to define experimentally the molecular characteristics of this crucial element of the bacterial life cycle because bacteria that are not growing tend to die under laboratory conditions. Here we present and validate the phototrophic bacterium Rhodopseudomonas palustris as a model system for identification of genes required for the longevity of nongrowing bacteria. Growth-arrested R. palustris maintained almost full viability for weeks using light as an energy source. Such cells were subjected to large-scale mutagenesis to identify genes required for this striking longevity trait. The results define conserved determinants of survival under nongrowing conditions and create a foundation for more extensive studies to elucidate general molecular mechanisms of bacterial longevity.

Methionine

This review focuses on the steps unique to methionine biosynthesis, namely the conversion of homoserine to methionine. The past decade has provided a wealth of information concerning the details of methionine metabolism and the review focuses on providing a comprehensive overview of the field, emphasizing more recent findings. Details of methionine biosynthesis are addressed along with key cellular aspects, including regulation, uptake, utilization, AdoMet, the methyl cycle, and growing evidence that inhibition of methionine biosynthesis occurs under stressful cellular conditions. The first unique step in methionine biosynthesis is catalyzed by the metA gene product, homoserine transsuccinylase (HTS, or homoserine O-succinyltransferase). Recent experiments suggest that transcription of these genes is indeed regulated by MetJ, although the repressor-binding sites have not yet been verified. Methionine also serves as the precursor of S-adenosylmethionine, which is an essential molecule employed in numerous biological processes. S-adenosylhomocysteine is produced as a consequence of the numerous AdoMet-dependent methyl transfer reactions that occur within the cell. In E. coli and Salmonella, this molecule is recycled in two discrete steps to complete the methyl cycle. Cultures challenged by oxidative stress appear to experience a growth limitation that depends on methionine levels. E. coli that are deficient for the manganese and iron superoxide dismutases (the sodA and sodB gene products, respectively) require the addition of methionine or cysteine for aerobic growth. Modulation of methionine levels in response to stressful conditions further increases the complexity of its regulation.

The NlpD lipoprotein is a novel Yersinia pestis virulence factor essential for the development of plague

Yersinia pestis is the causative agent of plague. Previously we have isolated an attenuated Y. pestis transposon insertion mutant in which the pcm gene was disrupted. In the present study, we investigated the expression and the role of pcm locus genes in Y. pestis pathogenesis using a set of isogenic surE, pcm, nlpD and rpoS mutants of the fully virulent Kimberley53 strain. We show that in Y. pestis, nlpD expression is controlled from elements residing within the upstream genes surE and pcm. The NlpD lipoprotein is the only factor encoded from the pcm locus that is essential for Y. pestis virulence. A chromosomal deletion of the nlpD gene sequence resulted in a drastic reduction in virulence to an LD(50) of at least 10(7) cfu for subcutaneous and airway routes of infection. The mutant was unable to colonize mouse organs following infection. The filamented morphology of the nlpD mutant indicates that NlpD is involved in cell separation; however, deletion of nlpD did not affect in vitro growth rate. Trans-complementation experiments with the Y. pestis nlpD gene restored virulence and all other phenotypic defects. Finally, we demonstrated that subcutaneous administration of the nlpD mutant could protect animals against bubonic and primary pneumonic plague. Taken together, these results demonstrate that Y. pestis NlpD is a novel virulence factor essential for the development of bubonic and pneumonic plague. Further, the nlpD mutant is superior to the EV76 prototype live vaccine strain in immunogenicity and in conferring effective protective immunity. Thus it could serve as a basis for a very potent live vaccine against bubonic and pneumonic plague.

High-performance liquid chromatographic method to measure protein L-isoaspartyl/D-aspartyl o-methyltransferase activity in cell lysates

Protein L-isoaspartyl/D-aspartyl o-methyltransferase (PIMT) is a widely expressed protein repair enzyme that restores isomerized aspartyl residues to their normal configuration. Current methods for measuring PIMT activity have limited sensitivity or require radioactivity. We have developed a highly sensitive new assay method to measure PIMT activity in cell lysates. As a substrate, we used a fluorescently labeled delta sleep-inducing peptide (DSIP) that contains an isoaspartyl residue: 7-nitro-2,1,3-benzoxadiazole (NBD)-DSIP(isoAsp). The PIMT-catalyzed transfer of a methyl group onto this substrate can be detected with a simple high-performance liquid chromatography (HPLC) procedure. After the enzyme reaction, the methylated form of the peptide is stable and can be reproducibly separated from the unmethylated form in an acidic solvent and fluorometrically detected by HPLC. The limit of detection was estimated to be approximately 1 pmol of NBD-DSIP(isoAsp) (signal/noise ratio [S/N]=3), and the quantitation limit of the activity was approximately 18 microg of total cell lysate from HEK293 cells (10.7 pmol/min/mg protein). This assay method is sensitive enough to detect PIMT activity in biological samples without the use of radioisotopes, offering significant advantages over previously reported methods.

Enhancing enzymatic activity of penicillin G acylase by coexpressing pcm gene

Penicillin G acylase (PGA; E.C. 3.5.1.11) is an important enzyme which has broad applications in industries of beta-lactim antibiotics production. In this study, a promising PGA gene from Alcaligenes faecalis (afpga) and another pcm gene encoding protein isoaspartate methyltransferase (PIMT) were constructed into pET43.1a((+)) and pET28a((+)), respectively. The recombinant plasmids pETAFPGA and pETPCM were transformed into the same host cell Escherichia coli BL21 (DE3). Results suggested that the two plasmids could peacefully exist in the host cell and the two genes could be efficiently expressed after induction. The product of pcm gene could function as a helper molecule for enzyme AFPGA. PIMT increased the enzymatic activities in supernatant of ferment broth (1.6 folds) and cell lysate (1.8 folds), while it did not significantly affect the expression level of penicillin G acylase.

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.

Hydroxytyrosol, a natural antioxidant from olive oil, prevents protein damage induced by long-wave ultraviolet radiation in melanoma cells

Previous studies showed that long-wave ultraviolet (UVA) radiation induces severe skin damage through the generation of reactive oxygen species and the depletion of endogenous antioxidant systems. Recent results from our laboratory indicate a dramatic increase of both lipid peroxidation products (TBARS) and abnormal L-isoaspartyl residues, marker of protein damage, in UVA-irradiated human melanoma cells. In this study, the effects of hydroxytyrosol (DOPET), the major antioxidant compound present in olive oil, on UVA-induced cell damages, have been investigated, using a human melanoma cell line (M14) as a model system. In UVA-irradiated M14 cells, a protective effect of DOPET in preventing the uprise of typical markers of oxidative stress, such as TBARS and 2'7'-dichlorofluorescein (DCF) fluorescence intensity, was observed. In addition, DOPET prevents the increase of altered L-isoAsp residues induced by UVA irradiation. These protective effects are dose dependent, reaching the maximum at 400 microM DOPET. At higher concentrations, DOPET causes an arrest of M14 cell proliferation and acts as a proapoptotic stimulus by activating caspase-3 activity. In the investigated model system, DOPET is quantitatively converted into its methylated derivative, endowed with a radical scavenging ability comparable to that of its parent compound. These findings are in line with the hypothesis that the oxidative stress plays a major role in mediating the UVA-induced protein damage. Results suggest that DOPET may exerts differential effects on melanoma cells according to the dose employed and this must always be taken into account when olive oil-derived large consumer products, including cosmetics and functional foods, are employed.

Protein isoaspartate methyltransferase is a multicopy suppressor of protein aggregation in Escherichia coli

We used preS2-S'-beta-galactosidase, a three-domain fusion protein that aggregates extensively at 43 degrees C in the cytoplasm of Escherichia coli, to search for multicopy suppressors of protein aggregation and inclusion body formation and took advantage of the known differential solubility of preS2-S'-beta-galactosidase at 37 and 43 degrees C to develop a selection procedure for the gene products that would prevent its aggregation in vivo at 43 degrees C. First, we demonstrate that the differential solubility of preS2-S'-beta-galactosidase results in a lactose-positive phenotype at 37 degrees C as opposed to a lactose-negative phenotype at 43 degrees C. We searched for multicopy suppressors of preS2-S'-beta-galactosidase aggregation by selecting pink lactose-positive colonies on a background of white lactose-negative colonies at 43 degrees C after transformation of bacteria with an E. coli gene bank. We discovered that protein isoaspartate methyltransferase (PIMT) is a multicopy suppressor of preS2-S'-beta-galactosidase aggregation at 43 degrees C. Overexpression of PIMT reduces the amount of preS2-S'-beta-galactosidase found in inclusion bodies at 43 degrees C and increases its amount in soluble fractions. It reduces the level of isoaspartate formation in preS2-S'-beta-galactosidase and increases its thermal stability in E. coli crude extracts without increasing the thermostability of a control protein, citrate synthase, in the same extracts. We could not detect any induction of the heat shock response resulting from PIMT overexpression, as judged from amounts of DnaK and GroEL, which were similar in the PIMT-overproducing and control strains. These results suggest that PIMT might be overburdened in some physiological conditions and that its overproduction may be beneficial in conditions in which protein aggregation occurs, for example, during biotechnological protein overproduction or in protein aggregation diseases.

Overexpression of l-Isoaspartate O-Methyltransferase in Escherichia coli Increases Heat Shock Survival by a Mechanism Independent of Methyltransferase Activity

Over time and under stressing conditions proteins are susceptible to a variety of spontaneous covalent modifications. One of the more commonly occurring types of protein damage is deamidation; the conversion of asparagines into aspartyls and isoaspartyls. The physiological significance of isoaspartyl formation is emphasized by the presence of the conserved enzyme L-isoaspartyl O-methyltransferase (PIMT), whose physiological function appears to be in preventing the accumulation of deamidated proteins. Seemingly consistent with a repair function, overexpression of PIMT in Drosophila melanogaster extends lifespan under conditions expected to contribute to protein damage. Based on structural information and sequence homology we have created mutants of residues proposed to be involved in co-factor binding in Escherichia coli PIMT. Both mutants retain S-adenosyl L-methionine binding capabilities but demonstrate dramatically reduced kinetic capabilities, perhaps suggestive of catalytic roles beyond co-factor binding. As anticipated, overexpression of the wild type enzyme in E. coli results in bacteria with increased tolerance to thermal stress. Surprisingly, even greater levels of heat tolerance were observed with overexpression of the inactive PIMT mutants. The increased survival capabilities observed with overexpression of PIMT in E. coli, and possibly in Drosophila, are not due to increased isoaspartyl repair capabilities but rather a temperature-independent induction of the heat shock system as a result of overexpression of a misfolding-prone protein. An alternate hypothesis as to the physiological substrate and function of L-isoaspartyl methyltransferase is proposed.

Molecular cloning and analysis of a region of the Bartonella bacilliformis genome encoding NlpD, L-isoaspartyl methyltransferase and YajC homologs

The NlpD/LppB homolog of the human pathogen, Bartonella bacilliformis, is an immunogenic 43-kDa protein that is encoded by a 1206-bp open reading frame (ORF-401). The regions flanking the nlpD/lppB gene of B. bacilliformis were sequenced to determine if it is located within the rpoS operon, as it is in most bacteria. We report that the B. bacilliformis nlpD/lppB gene is located immediately downstream of pcm, a gene encoding a 25-kDa protein, L-isoaspartyl protein carboxyl methyltransferase, that is a component of the rpoS operon in other bacteria. However, the genomic organization downstream of the B. bacilliformis nlpD/lppB gene appears to be distinct. In other bacteria, the third gene in the operon is rpoS, a gene that codes for an alternative sigma factor of RNA polymerase. In B. bacilliformis, an open reading frame encoding a protein homologous to the immunodominant YajC protein is located directly downstream of the nlpD/lppB gene. We show that Bartonella henselae, a close relative of B. bacilliformis, also shares this unusual organizational feature. Thus, the genomic organization of the nlpD/lppB genes of B. bacilliformis, and B. henselae appears to be unique among all bacteria for which the sequence of this region has been reported.

Protein repair methyltransferase from the hyperthermophilic archaeon Pyrococcus furiosus. Unusual methyl-accepting affinity for D-aspartyl and N-succinyl-containing peptides

Protein l-isoaspartate-(d-aspartate) O-methyltransferases (EC ), present in a wide variety of prokaryotic and eukaryotic organisms, can initiate the conversion of abnormal l-isoaspartyl residues that arise spontaneously with age to normal l-aspartyl residues. In addition, the mammalian enzyme can recognize spontaneously racemized d-aspartyl residues for conversion to l-aspartyl residues, although no such activity has been seen to date for enzymes from lower animals or prokaryotes. In this work, we characterize the enzyme from the hyperthermophilic archaebacterium Pyrococcus furiosus. Remarkably, this methyltransferase catalyzes both l-isoaspartyl and d-aspartyl methylation reactions in synthetic peptides with affinities that can be significantly higher than those of the human enzyme, previously the most catalytically efficient species known. Analysis of the common features of l-isoaspartyl and d-aspartyl residues suggested that the basic substrate recognition element for this enzyme may be mimicked by an N-terminal succinyl peptide. We tested this hypothesis with a number of synthetic peptides using both the P. furiosus and the human enzyme. We found that peptides devoid of aspartyl residues but containing the N-succinyl group were in fact methyl esterified by both enzymes. The recent structure determined for the l-isoaspartyl methyltransferase from P. furiosus complexed with an l-isoaspartyl peptide supports this mode of methyl-acceptor recognition. The combination of the thermophilicity and the high affinity binding of methyl-accepting substrates makes the P. furiosus enzyme useful both as a reagent for detecting isomerized and racemized residues in damaged proteins and for possible human therapeutic use in repairing damaged proteins in extracellular environments where the cytosolic enzyme is not normally found.

Structure of Thermotoga maritima stationary phase survival protein SurE: a novel acid phosphatase

BACKGROUND

The rpoS, nlpD, pcm, and surE genes are among many whose expression is induced during the stationary phase of bacterial growth. rpoS codes for the stationary-phase RNA polymerase sigma subunit, and nlpD codes for a lipoprotein. The pcm gene product repairs damaged proteins by converting the atypical isoaspartyl residues back to L-aspartyls. The physiological and biochemical functions of surE are unknown, but its importance in stress is supported by the duplication of the surE gene in E. coli subjected to high-temperature growth. The pcm and surE genes are highly conserved in bacteria, archaea, and plants.

RESULTS

The structure of SurE from Thermotoga maritima was determined at 2.0 A. The SurE monomer is composed of two domains; a conserved N-terminal domain, a Rossman fold, and a C-terminal oligomerization domain, a new fold. Monomers form a dimer that assembles into a tetramer. Biochemical analysis suggests that SurE is an acid phosphatase, with an optimum pH of 5.5-6.2. The active site was identified in the N-terminal domain through analysis of conserved residues. Structure-based site-directed point mutations abolished phosphatase activity. T. maritima SurE intra- and intersubunit salt bridges were identified that may explain the SurE thermostability.

CONCLUSIONS

The structure of SurE provided information about the protein's fold, oligomeric state, and active site. The protein possessed magnesium-dependent acid phosphatase activity, but the physiologically relevant substrate(s) remains to be identified. The importance of three of the assigned active site residues in catalysis was confirmed by site-directed mutagenesis.

Purification and characterization of protein methylase II from Helicobacter pylori

Protein methylase II (AdoMet:protein-carboxyl O-methyltransferase, EC 2.1.1.24) was identified and purified 115-fold from Helicobacter pylori through Q-Sepharose ion exchange column, AdoHcy-Sepharose 4B column, and Superdex 200 HR column chromatography using FPLC. The purified preparation showed two protein bands of about 78 kDa and 29 kDa molecular mass on SDS-PAGE. On non-denaturing gel electrophoresis, the enzyme migrated as a single band with a molecular mass of 410 kDa. In addition, MALDI-TOF-MS analysis and Superdex 200 HR column chromatography of the purified enzyme showed a major mass signal with molecular mass values of 425 kDa and 430 kDa, respectively. Therefore, the above results led us to suggest that protein methylase II purified from H. pylori is composed of four heterodimers with 425 kDa (4x(78+29)=428 kDa). This magnitude of molecular mass is unusual for protein methylases II so far reported. The enzyme has an optimal pH of 6.0, a K(m) value of 5.0x10(-6) M for S-adenosyl-L-methionine and a V(max) of 205 pmol methyl-(14)C transferred min(-1) mg(-1) protein.

Expression, purification, and characterization of the protein repair l-isoaspartyl methyltransferase from Arabidopsis thaliana

Protein l-isoaspartate (d-aspartate) O-methyltransferase (EC 2.1.1. 77) is a repair enzyme that methylates abnormal l-isoaspartate residues in proteins which arise spontaneously as a result of aging. This enzyme initiates their conversion back into the normal l-aspartate form by a methyl esterification reaction. Previously, partial cDNAs of this enzyme were isolated from the higher plant Arabidopsis thaliana. In this study, we report the cloning and expression of a full-length cDNA of l-isoaspartyl methyltransferase from A. thaliana into Escherichia coli under the P(BAD) promoter, which offers a high level of expression under a tight regulatory control. The enzyme is found largely in the soluble fraction. We purified this recombinant enzyme to homogeneity using a series of steps involving DEAE-cellulose, gel filtration, and hydrophobic interaction chromatographies. The homogeneous enzyme was found to have maximum activity at 45 degrees C and a pH optimum from 7 to 8. The enzyme was found to have a wide range of affinities for l-isoaspartate-containing peptides and displayed relatively poor reactivity toward protein substrates. The best methyl-accepting substrates were KASA-l-isoAsp-LAKY (K(m) = 80 microM) and VYP-l-isoAsp-HA (K(m) = 310 microM). We also expressed the full-length form and a truncated version of this enzyme (lacking the N-terminal 26 amino acid residues) in E. coli under the T7 promoter. Both the full-length and the truncated forms were active, though overexpression of the truncated enzyme led to a complete loss of activity.

Increased methyl esterification of altered aspartyl residues in erythrocyte membrane proteins in response to oxidative stress

Protein-L-isoaspartate (D-aspartate) O-methyltransferase (PCMT; EC 2. 1.1.77) catalyses the methyl esterification of the free alpha-carboxyl group of abnormal L-isoaspartyl residues, which occur spontaneously in protein and peptide substrates as a consequence of molecular ageing. The biological function of this transmethylation reaction is related to the repair or degradation of age-damaged proteins. Methyl ester formation in erythrocyte membrane proteins has also been used as a marker reaction to tag these abnormal residues and to monitor their increase associated with erythrocyte ageing diseases, such as hereditary spherocytosis, or cell stress (thermal or osmotic) conditions. The study shows that levels of L-isoaspartyl residues rise in membrane proteins of human erythrocytes exposed to oxidative stress, induced by t-butyl hydroperoxide or H2O2. The increase in malondialdehyde content confirmed that the cell membrane is a primary target of oxidative alterations. A parallel rise in the methaemoglobin content indicates that proteins are heavily affected by the molecular alterations induced by oxidative treatments in erythrocytes. Antioxidants largely prevented the increase in membrane protein methylation, underscoring the specificity of the effect. Conversely, we found that PCMT activity, consistent with its repair function, remained remarkably stable under oxidative conditions, while damaged membrane protein substrates increased significantly. The latter include ankyrin, band 4.1 and 4.2, and the integral membrane protein band 3 (the anion exchanger). The main target was found to be particularly protein 4.1, a crucial element in the maintenance of membrane-cytoskeleton network stability. We conclude that the increased formation/exposure of L-isoaspartyl residues is one of the major structural alterations occurring in erythrocyte membrane proteins as a result of an oxidative stress event. In the light of these and previous findings, the occurrence of isoaspartyl sites in membrane proteins as a key event in erythrocyte spleen conditioning and hemocatheresis is proposed.

Isoaspartate in ribosomal protein S11 of Escherichia coli

Isoaspartyl sites, in which an aspartic acid residue is linked to its C-flanking neighbor via its beta-carboxyl side chain, are generally assumed to be an abnormal modification arising as proteins age. The enzyme protein L-isoaspartate methyltransferase (PIMT), present in many bacteria, plants, and animals, catalyzes the conversion of isoaspartate to normal alpha-linked aspartyl bonds and is thought to serve an important repair function in cells. Having introduced a plasmid into Escherichia coli that allows high-level expression of rat PIMT, we explored the possibility that the rat enzyme reduces isoaspartate levels in E. coli proteins, a result predicted by the repair hypothesis. The present study demonstrates that this is indeed the case; E. coli cells expressing rat PIMT had significantly lower isoaspartate levels than control cells, especially in stationary phase. Moreover, the distribution of isoaspartate-containing proteins in E. coli differed dramatically between logarithmic- and stationary-phase cultures. In stationary-phase cells, a number of proteins in the molecular mass range of 66 to 14 kDa contained isoaspartate, whereas in logarithmic-phase cells, nearly all of the detectable isoaspartate resided in a single 14-kDa protein which we identified as ribosomal protein S11. The near stoichiometric levels of isoaspartate in S11, estimated at 0.5 mol of isoaspartate per mol of S11, suggests that this unusual modification may be important for S11 function.

A highly active protein repair enzyme from an extreme thermophile: the L-isoaspartyl methyltransferase from Thermotoga maritima

We show that the open reading frame in the Thermotoga maritima genome tentatively identified as the pcm gene (R. V. Swanson et al., J. Bacteriol. 178, 484-489, 1996) does indeed encode a protein L-isoaspartate (D-aspartate) O-methyltransferase (EC 2.1.1.77) and that this protein repair enzyme displays several novel features. We expressed the 317 amino acid pcm gene product of this thermophilic bacterium in Escherichia coli as a fusion protein with an N-terminal 20 residue hexa-histidine-containing sequence. This protein contains a C-terminal domain of approximately 100 residues not previously seen in this enzyme from various prokaryotic or eukaryotic species and which does not have sequence similarity to any other entry in the GenBank databases. The C-terminal region appears to be required for enzymatic function as no activity is detected in two recombinant constructs lacking this domain. Sedimentation equilibrium analysis indicated that the enzyme is monomeric in solution. The Km values for measured for peptide and protein substrates were found to be intermediate between those of the high-affinity human enzyme and those of the lower-affinity wheat, nematode, and E. coli enzymes. The enzyme was extremely heat stable, with no loss of activity after 60 min at 100 degreesC. Enzyme activity was observed at temperatures as high as 93 degreesC with an optimal activity of 164 nmol/min/mg protein at 85 degreesC. This activity is approximately 18-fold higher than the maximal activities of mesophilic homologs at 37 degreesC. These data suggest that the Thermotoga enzyme has unique features for initiating repair in damaged proteins containing L-isoaspartyl residues at elevated temperatures.

Mutations in the Escherichia coli surE gene increase isoaspartyl accumulation in a strain lacking the pcm repair methyltransferase but suppress stress-survival phenotypes

The Escherichia coli surE gene is co-transcribed with pcm, encoding the L-isoaspartyl protein repair methyltransferase, and is highly conserved among both the Eubacteria and the Archaea; however, no biochemical function has yet been identified for this gene. Isoaspartyl accumulation during stationary phase was much higher in a pcm surE double mutant than in either single mutant, suggesting that the two genes may represent two parallel pathways by which E. coli can respond to protein damage. A null mutation in surE also suppressed stress-survival defects previously observed in a pcm mutant strain, providing further evidence for an interaction between the two gene products.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

The L-isoaspartyl protein repair methyltransferase enhances survival of aging Escherichia coli subjected to secondary environmental stresses

Like its homologs throughout the biological world, the L-isoaspartyl protein repair methyltransferase of Escherichia coli, encoded by the pcm gene, can convert abnormal L-isoaspartyl residues in proteins (which form spontaneously from asparaginyl or aspartyl residues) to normal aspartyl residues. Mutations in pcm were reported to greatly reduce survival in stationary phase and when cells were subjected to heat or osmotic stresses (C. Li and S. Clarke, Proc. Natl. Acad. Sci. USA 89:9885-9889, 1992). However, we subsequently demonstrated that those strains had a secondary mutation in rpoS, which encodes a stationary-phase-specific sigma factor (J. E. Visick and S. Clarke, J. Bacteriol. 179:4158-4163, 1997). We now show that the rpoS mutation, resulting in a 90% decrease in HPII catalase activity, can account for the previously observed phenotypes. We further demonstrate that a new pcm mutant lacks these phenotypes. Interestingly, the newly constructed pcm mutant, when maintained in stationary phase for extended periods, is susceptible to environmental stresses, including exposure to methanol, oxygen radical generation by paraquat, high salt concentrations, and repeated heating to 42 degrees C. The pcm mutation also results in a competitive disadvantage in stationary-phase cells. All of these phenotypes can be complemented by a functional pcm gene integrated elsewhere in the chromosome. These data suggest that protein denaturation and isoaspartyl formation may act synergistically to the detriment of aging E. coli and that the repair methyltransferase can play a role in limiting the accumulation of the potentially disruptive isoaspartyl residues in vivo.

Correlation between stationary phase survival and acid trehalase activity in yeast

The levels of two trehalose hydrolysing enzymes, acid trehalase (AT) and neutral trehalase (NT), have been investigated in Candida utilis at different stages of growth; in complete contrast to Saccharomyces cerevisiae, significant AT activity appears to be absent at all stages of growth studied in C. utilis. In addition, presence of only very low amounts of iso-aspartyl methyl transferase (IMT) activity at the onset of stationary phase and lower survival ability in early stationary phase in contrast to that of S. cerevisiae lend support to the ideas that (a) lower degree of survival of C. utilis in the stationary phase may be a direct consequence of inability to mobilise stored trehalose due to absence of intracellular AT and reduced levels of IMT activities and (b) trehalose may have a dual role vis-à-vis stress resistance in yeasts.

Targeted gene disruption of the Caenorhabditis elegans L-isoaspartyl protein repair methyltransferase impairs survival of dauer stage nematodes

The methylation of abnormal L-isoaspartyl residues by protein L-isoaspartate (D-aspartate) O-methyltransferase (EC 2.1.1.77) can lead to their conversion to L-aspartyl residues. For polypeptides damaged by spontaneous reactions that generate L-isoaspartyl residues, these steps represent a protein repair pathway that can limit the accumulation of potentially detrimental proteins in the aging process. We report here the construction and the characterization of an animal model deficient in this methyltransferase. We utilized Tc1-transposon-mediated mutagenesis in the nematode Caenorhabditis elegans to construct a homozygous excision mutant lacking exons 2-5 of the pcm-1 gene encoding this enzyme. Nematodes carrying this deletion exhibited no detectable L-isoaspartyl methyltransferase activity. These worms demonstrated normal morphology and behavior and adult mutant nematodes exhibited a normal lifespan. However, the survival of dauer-phase mutants was diminished by 3.5-fold relative to wild-type dauers after 50 days in the dauer phase. The fitness of the pcm-1 deletion nematodes was reduced by about 16% relative to that of wild-type nematodes as measured by the ability of these mutants to compete reproductively against a wild-type population. We found that the absence of the functional methyltransferase gene leads to a modest accumulation of altered protein substrates in aged dauer worms. However, in the viable fraction of these dauer worms, no differences were seen in the levels of altered substrate proteins in the parent and methyltransferase-deficient worms, suggesting that the enzyme in wild-type cells does not efficiently catalyze the repair of spontaneously damaged proteins.

Growth-phase-dependent transcriptional regulation of the pcm and surE genes required for stationary-phase survival of Escherichia coli

Two neighbouring genes, surE and pcm, at 59 min on the Escherichia coli chromosome are both required for stationary-phase survival. Operon fusions of the putative promoter regions in front of surE (P2) or pcm (P3) with the lacZ reporter gene were constructed to study the transcriptional regulation of pcm and surE. Both promoter regions were able to activate beta-galactosidase activity in a growth-phase-dependent way in either rich or minimal medium. Induction from both promoters reached the highest level in late stationary phase and was independent of the rpoS/katF gene. Spent medium from early as well as late stationary-phase cultures could induce the expression of either promoter even after dialysis or boiling. A high cell density could induce the promoters more rapidly but not to a greater extent. It is proposed that the induction might be correlated with the decline in growth rate of the cells. The induction patterns of either P2 or P3 were very similar. pcm can thus be transcribed from both the P2 and P3 promoters that are regulated in similar ways.

Duplication of the pepF gene and shuffling of DNA fragments on the lactose plasmid of Lactococcus lactis

The gene corresponding to the lactococcal oligopeptidase PepF1 (formerly PepF [V. Monnet, M. Nardi, A. Chopin, M.-C. Chopin, and J.-C. Gripon, J. Biol. Chem. 269:32070-32076, 1994]) is located on the lactose-proteinase plasmid of Lactococcus lactis subsp. cremoris NCDO763. Use of the pepF1 gene as a probe with different strains showed that pepF1 is present on the chromosome of Lactococcus lactis subsp. lactis IL1403, whereas there is a second, homologous gene, pepF2, on the chromosome of strain NCDO763. From hybridization, PCR amplification, and sequencing experiments, we deduced that (i) pepF1 and pepF2 exhibit 80% identity and encode two proteins which are 84% identical and (ii) pepF2 is included in an operon composed of three open reading frames and is transcribed from two promoters. The protein, encoded by the gene located downstream of pepF2, shows significant homology with methyltransferases. Analysis of the sequences flanking pepF1 and pepF2 indicates that only a part of the pepF2 operon is present on the plasmid of strain NCDO763, while the operon is intact on the chromosome of strain IL1403. Traces of several recombination events are visible on the lactose-proteinase plasmid. This suggests that the duplication of pepF occurred by recombination from the chromosome of an L. lactis subsp. lactis strain followed by gene transfer. We discuss the possible functions of PepF and the role of its amplification.

RpoS- and OxyR-independent induction of HPI catalase at stationary phase in Escherichia coli and identification of rpoS mutations in common laboratory strains

A rapid spectrophotometric assay to determine the activities of HPI and HPII catalases in Escherichia coli extracts has been developed. This assay is based upon the differential heat stabilities of the two enzymes and offers significant advantages over previous methods for quantitation of their activities. Measurement of catalase activities in extracts of various mutant strains confirmed the ability of this method to accurately distinguish the two activities. Contrary to previously published results, HPI catalase activity was observed to increase at stationary phase in strains lacking the stationary-phase sigma factor sigma(s) (RpoS). This increase was independent of OxyR and also occurred in a strain lacking the HPII structural gene, katE. These results suggest a potential novel pathway for HPI induction in response to increased oxidative stress in the absence of HPII. Measurement of HPII activity in strains carrying mutations in pcm (encoding the L-isoaspartyl protein methyltransferase) and surE led to the finding that these strains also have an amber mutation in rpoS; sequencing demonstrated the presence of this mutation in several commonly used laboratory strains of E. coli, including AB1157, W1485, and JC7623.

Structural organization and developmental expression of the protein isoaspartyl methyltransferase gene from Drosophila melanogaster

A protein carboxyl methyltransferase activity (PCMT) with a specificity for age-damaged protein D-aspartyl and L-isoaspartyl residues (E.C. 2.1.1.77) has been identified and cloned in Drosophila. The Drosophila gene was localized by chromosome in-situ hybridization to region 83AB of the third chromosome. The methyltransferase coding sequence is distributed among four exons within a 1.4-kb segment of the genome; it predicts a polypeptide of 226 amino acids that is 55% identical to the mouse enzyme. When expressed in bacteria, the Drosophila protein exhibits PCMT activity. A single 1.4-kb Pcmt transcript is detected in RNA preparations from embryos, larvae, pupae and adults. The abundance of the transcript, which is lowest in larvae and highest in adults, parallels the specific activity of the enzyme measured in extracts from the same developmental stages. It has been proposed that the PCMT initiates the repair of structurally damaged cellular proteins. The constitutive expression of PCMT and the relatively high level of expression in postmitotic adult cells suggest that PCMT activity is required through development, but acquires additional significance in aging tissues.

A distinctly regulated protein repair L-isoaspartylmethyltransferase from Arabidopsis thaliana

Protein-L-isoaspartate (D-aspartate) O-methyltransferases (EC 2.1.1.77) that catalyze the transfer of methyl groups from S-adenosylmethionine to abnormal L-isoaspartyl and D-aspartyl residues in a variety of peptides and proteins are widely distributed in procaryotes and eucaryotes. These enzymes participate in the repair of spontaneous protein damage by facilitating the conversion of L-isoaspartyl and D-aspartyl residues to normal L-aspartyl residues. In this work, we have identified an L-isoaspartyl methyltransferase activity in Arabidopsis thaliana, a dicotyledonous plant of the mustard family. The highest levels of activity were detected in seeds. Using degenerate oligonucleotides corresponding to two highly conserved amino acid regions shared among the Escherichia coli, wheat, and human enzymes, we isolated and sequenced a full-length genomic clone encoding the A. thaliana methyltransferase. Several methyltransferase cDNAs were also characterized, including ones that would encode full-length polypeptides of 230 amino acid residues. Messenger RNAs for the A. thaliana enzyme were found in a variety of tissues that did not contain significant amounts of active enzyme suggesting the possibility of translational or posttranslational controls on methyltransferase levels. We have identified a putative abscisic acid-response element (ABRE) in the 5'-untranslated region of the A. thaliana L-isoaspartyl methyltransferase gene and have shown that the expression of the mRNA is responsive to exogenous abscisic acid (ABA), but not to the environmental stresses of salt or drought. The expression of the A. thaliana enzyme appears to be regulated in a distinct fashion from that seen in wheat or in animal tissues.

Repair, refold, recycle: how bacteria can deal with spontaneous and environmental damage to proteins

Proteins, like DNA, are subject to various forms of damage that can render them non-functional. Conformational changes and covalent chemical alterations occur spontaneously, and the rates of these reactions can be increased by environmental stresses such as heat, oxidative agents, or changes in pH or osmotic conditions. Although affected proteins can be replaced by de novo biosynthesis, cells--especially those subjected to stress or nutrient limitation--have developed mechanisms which can either restore damaged polypeptides to an active state or remove them. Such mechanisms can spare the biosynthetic capacity of the cell and ensure that the presence of non-functional molecules does not disrupt cell physiology. Three major mechanisms, which operate in bacteria as well as eukaryotic organisms, have been described. First, chaperones not only assist in proper de novo folding of proteins but also provide an important means of restoring activity to conformationally damaged proteins. Second, enzymatic 'repair' systems exist to directly reverse certain forms of protein damage, including proline isomerization, methionine oxidation and the formation of isoaspartyl residues. Finally, proteolysis provides a 'last-resort' means of dealing with abnormal proteins which cannot be repaired. Protein maintenance and repair may be of special importance for bacteria preparing to survive extended periods in stationary phase: both constitutive and induced mechanisms are utilized to permit survival despite greatly reduced protein synthesis.

Purification and characterization of an isoaspartyl dipeptidase from Escherichia coli

We have identified a gene (iadA) in Escherichia coli encoding a 41-kDa polypeptide that catalyzes the hydrolytic cleavage of L-isoaspartyl, or L-beta-aspartyl, dipeptides. We demonstrate at least a 3000-fold purification of the enzyme to homogeneity from crude cytosol. From the amino-terminal amino acid sequence obtained from this preparation, we designed an oligonucleotide that allowed us to map the gene to the 98-min region of the chromosome and to clone and obtain the DNA sequence of the gene. Examination of the deduced amino acid sequence revealed no similarities to other peptidases or proteases, while a marked similarity was found with several dihydroorotases and imidases, reflecting the similarity in the structures of the substrates for these enzymes. Using an E. coli strain containing a plasmid overexpressing this gene, we were able to purify sufficient amounts of the dipeptidase to characterize its substrate specificity. We also examined the phenotype of two E. coli strains where this isoaspartyl dipeptidase gene was deleted. We inserted a chloramphenicol cassette into the disrupted coding region of iadA in both a parent strain (MC1000) and a derivative strain (CL1010) lacking pcm, the gene encoding the L-isoaspartyl methyltransferase involved in the repair of isomerized proteins. We found that the iadA deletion does not result in reduced stationary phase or heat shock survival. Analysis of isoaspartyl dipeptidase activity in the deletion strain revealed a second activity of lower native molecular weight that accounts for approximately 31% of the total activity in the parent strain MC1000. The presence of this second activity may account for the absence of an observable phenotype in the iadA mutant cells.

Cloning, analysis and expression of an rpoS homologue gene from Pseudomonas aeruginosa PAO1

A homologue of the rpoS gene of Escherichia coli was cloned from Pseudomonas aeruginosa PAO1 by hybridization with an oligodeoxyribonucleotide probe designed from an amino-acid stretch conserved among the principal sigma factors of eubacteria. Two open reading frames, the pcm gene and the orf-297 of unknown function, were found in the upstream region of rpoS, and in the same order as in E. coli. The rpoS gene of P. aeruginosa was expressed in E. coli and complemented the catalase deficiency of the rpoS mutant of E. coli. The RpoS protein of P. aeruginosa was identified by Western blot analysis in both P. aeruginosa (Pa) and the transformed E. coli. Levels of RpoS of Pa increased drastically at the onset of the stationary growth phase.

A new gene involved in stationary-phase survival located at 59 minutes on the Escherichia coli chromosome

We determined the DNA sequence of a 2,232-bp region immediately upstream of the pcm gene at 59 min on the Escherichia coli chromosome that encodes an L-isoaspartyl protein methyltransferase with an important role in stationary-phase survival. Two open reading frames of 477 and 1,524 bp were found oriented in the same direction as that of the pcm gene. The latter open reading frame overlapped the 5' end of the pcm gene by 4 bp. Coupled in vitro transcription-translation analysis of DNA containing the 1,524-bp open reading frame directly demonstrated the production of a 37,000-Da polypeptide corresponding to a RNA species generated from a promoter within the open reading frame. The deduced amino acid sequence showed no similarity to known protein sequences. To test the function of this gene product, we constructed a mutant strain in which a kanamycin resistance element was inserted at a BstEII site in the middle of its coding region in an orientation that does not result in reduction of Pcm methyltransferase activity. These cells were found to survive poorly in stationary phase, at elevated temperatures, and in high-salt media compared with parent cells containing the intact gene, and we thus designate this gene surE (survival). surE appears to be the first gene of a bicistronic operon also containing the pcm gene. The phenotypes of mutations in either gene are very similar and indicate that both gene products are important for the viability of E. coli cells under stressful conditions.

The nlpD gene is located in an operon with rpoS on the Escherichia coli chromosome and encodes a novel lipoprotein with a potential function in cell wall formation

rpoS is the structural gene for sigma s, which is a second vegetative sigma subunit of RNA polymerase in Escherichia coli and is involved in the expression of many stationary phase-induced genes. Upstream of rpoS is an open reading frame (ORF) whose function and regulation have not been studied. Strong overproduction of its gene product using the IPTG-inducible tac promoter leads to the formation of bulges at the cell septum and the cell poles, and in rapidly growing cells brings about cell lysis, indicating that the gene product has a hydrolytic function in cell wall formation or maintenance. This is corroborated by sequence homology to lysostaphin, a cell wall lytic exoenzyme synthesized by two Staphylococcus strains. Using globomycin, a specific inhibitor of signal peptidase II, we demonstrate that the product of the ORF is a novel lipoprotein (NlpD). Two transcriptional start sites for nlpD have been localized. In contrast to rpoS, nlpD is not induced during entry into stationary phase. Growth-phase-regulated transcription of rpoS is initiated at additional sites within the nlpD ORF, but the nlpD promoters contribute substantially to the basal level of rpoS expression in exponentially growing cells, indicating that nlpD and rpoS form an operon.

Functional size of C-terminal protein carboxyl methyltransferase from kidney basolateral plasma membranes

The functional sizes of the C-terminal isoprenylcysteine protein carboxyl methyltransferase (PCMT) from kidney cortex basolateral plasma membranes and yeast membranes have been estimated by the radiation inactivation and fragmentation method. Attempts to solubilize the methyltransferase with detergents were unsuccessful as they resulted in the irreversible denaturation of its enzymatic activity. The radiation inactivation sizes of the methyltransferases were 98 and 24 kDa for kidney and yeast, respectively. Kinetic experiments showed that irradiation affects the Vmax of the reaction but not the apparent Km for either S-adenosyl-L-methionine and N-acetyl farnesylcysteine. The functional size reported here for the kidney membrane is about 4-times larger than the size predicted for the Saccharomyces cerevisiae C-terminal PCMT deduced from the nucleotide sequence of its gene (28 kDa). These results suggest that mammalian methyltransferase has a functional size different from that of the yeast; tetramerization of monomers is one possible hypothesis for this difference.

Structure of the 5' upstream region and the regulation of the rpoS gene of Escherichia coli

The nucleotide sequence of the 5' upstream region of the Escherichia coli rpoS gene was determined and analyzed. At least four promoters responsible for rpoS transcription were identified, and designated P1, P2, P3 and P4, P1 being furthest from the upstream. Using lacZ fusion genes, the P2 promoter was found to be the strongest of the four. All of these promoters are regulated similarly, and their activity is enhanced 2 to 3-fold in stationary phase. P1 and P2 transcription start sites were determined by primer extension analyses. The P2 promoter region shows similarity to the consensus sigma 70-type promoter sequence, and was recognized by both E sigma 70 and E sigma 38 holoenzymes in vitro. The mRNA transcribed from the most distal promoter, P1, appears to include another open reading frame (orf-281), indicating that the two open reading frames comprise an operon. The rpoS gene product (sigma 38) was rapidly degraded after addition of chloramphenicol to cultures in the exponential, but not the stationary phase. This strongly suggests that posttranslational regulation is involved in the control of rpoS expression.

A gene at 59 minutes on the Escherichia coli chromosome encodes a lipoprotein with unusual amino acid repeat sequences

We report a 1.432-kb DNA sequence at 59 min on the Escherichia coli chromosome that connects the published sequences of the pcm gene for the isoaspartyl protein methyltransferase and that of the katF or rpoS (katF/rpoS) gene for a sigma factor involved in stationary-phase gene expression. Analysis of the DNA sequence reveals an open reading frame potentially encoding a polypeptide of 379 amino acids. The polypeptide sequence includes a consensus bacterial lipidation sequence present at residues 23 to 26 (Leu-Ala-Gly-Cys), four octapeptide proline- and glutamine-rich repeats of consensus sequence QQPQIQPV, and four heptapeptide threonine- and serine-rich repeats of consensus sequence PTA(S,T)TTE. The deduced amino acid sequence, especially in the C-terminal region, is similar to that of the Haemophilus somnus LppB lipoprotein outer membrane antigen (40% overall sequence identity; 77% identity in last 95 residues). The LppB lipoprotein binds Congo red dye and has been proposed to be a virulence determinant in H. somnus. Utilizing a plasmid construct with the E. coli gene under the control of a phage T7 promoter, we demonstrate the lipidation of this gene product by the incorporation of [3H]palmitic acid into a 42-kDa polypeptide. We also show that treatment of E. coli cells with globomycin, an inhibitor of the lipoprotein signal peptidase, results in the accumulation of a 46-kDa precursor. We thus designate the protein NlpD (new lipoprotein D). E. coli cells overexpressing NlpD bind Congo red dye, suggesting a common function with the H. somnus LppB protein. Disruption of the chromosomal E. coli nlpD gene by insertional mutagenesis results in decreased stationary-phase survival after 7 days.

Characterization of plant L-isoaspartyl methyltransferases that may be involved in seed survival: purification, cloning, and sequence analysis of the wheat germ enzyme

Protein carboxyl methyltransferases (EC 2.1.1.77) that catalyze the transfer of a methyl group from S-adenosylmethionine to L-isoaspartyl and D-aspartyl residues in a variety of peptides and proteins are widely, but not universally, distributed in nature. These enzymes can participate in the repair of damaged proteins by facilitating the conversion of abnormal L-isoaspartyl residues to normal L-aspartyl residues. In this work, we have identified L-isoaspartyl methyltransferase activity in a variety of higher plant species and a green alga. Interestingly, the highest levels of methyltransferase were located in seeds, where the problem of spontaneous protein degradation may become particularly severe upon aging. The wheat germ methyltransferase was purified as a monomeric 28,000-Da species by DEAE-cellulose chromatography, reverse ammonium sulfate gradient solubilization, and gel filtration chromatography. The purified enzyme recognized a variety of L-isoaspartyl-containing peptides, but did not recognize two D-aspartyl-containing peptides that are substrates for the mammalian enzyme. The partial amino acid sequence was utilized to design oligonucleotides to isolate a full-length cDNA clone, pMBM1. Its nucleotide sequence demonstrated an open reading frame encoding a polypeptide of 230 amino acid residues with a calculated molecular weight of 24,710. This sequence shares 31% identity with the L-isoaspartyl methyltransferase from Escherichia coli and 50% identity with the L-isoaspartyl/D-aspartyl methyltransferase from human erythrocytes. Such conservation in sequence is consistent with a fundamental role of this enzyme in the metabolism of spontaneously damaged polypeptides.

Genomic organization and tissue expression of the murine gene encoding the protein beta-aspartate methyltransferase

Two overlapping clones containing the entire 684-nucleotide (nt) sequence encoding murine protein beta-aspartate methyltransferase (EC 2.1.1.77) were isolated from a genomic library. Partial nt sequence analysis of the two clones revealed that the protein carboxyl methyltransferase (PCMT)-encoding sequence is distributed among seven exons, ranging from 32 to 339 bp in length, within 25 kb of genomic DNA. Three exons correspond to regions of primary structure which are strongly conserved among a number of eukaryotic and prokaryotic enzymes which utilize S-adenosylmethionine (AdoMet) and S-adenosylhomocysteine (AdoHcy). The 5'-flanking region of the PCMT-encoding gene (PCMT) contains an 800-bp G+C-rich region with potential binding sites for transcription factor ETF, but lacks a TATA box and binding sites for other known transcription factors. Multiple PCMT mRNAs were detected on Northern blots of RNA extracted from murine brain, testis, liver and kidney. The overall abundance of PCMT mRNAs in each tissue paralleled the measured specific activity of the PCMT. Comparison of the genomic sequence information with the 3'-untranslated regions (UTRs) of two cDNA clones from a murine testis library indicated that PCMT mRNA precursors undergo alternative splicing. The structure and widespread expression of PCMT are characteristics of vertebrate housekeeping genes.

Distribution of an L-isoaspartyl protein methyltransferase in eubacteria

A protein carboxyl methyltransferase (EC 2.1.1.77) that recognizes age-damaged proteins for potential repair or degradation reactions has been found in all vertebrate tissues and cells examined to date. This enzyme catalyzes the transfer of methyl groups from S-adenosylmethionine to the carboxyl groups of D-aspartyl or L-isoaspartyl residues that are formed spontaneously from normal L-aspartyl and L-asparaginyl residues. A similar methyltransferase has been found in two bacterial species, Escherichia coli and Salmonella typhimurium, suggesting that this enzyme performs an essential function in all cells. In this study, we show that this enzyme is present in cytosolic extracts of six additional members of the alpha and gamma subdivisions of the purple bacteria: Pseudomonas aeruginosa (gamma), Rhodobacter sphaeroides (alpha), and the gamma enteric species Klebsiella pneumoniae, Enterobacter aerogenes, Proteus vulgaris, and Serratia marcescens. DNA probes from the E. coli methyltransferase gene hybridized only to the chromosomal DNA of the enteric species. Interestingly, no activity was found in the plant pathogen Erwinia chrysanthemi, a member of the enteric family, nor in Rhizobium meliloti or Rhodopseudomonas palustris, two members of the alpha subdivision. Additionally, we could not detect activity in the four gram-positive species Bacillus subtilis, B. stearothermophilus, Lactobacillus casei, and Streptomyces griseus. The absence of enzyme activity was not due to the presence of inhibitors in the extracts. These results suggest that many cells may not have the enzymatic machinery to recognize abnormal aspartyl residues by methylation reactions. Since the nonenzymatic degradation reactions that generate these residues occur in all cells, other pathways may be present in nature to ensure that these types of altered proteins do not accumulate and interfere with normal cellular physiology.