Primary structure of rat brain protein carboxyl methyltransferase deduced from cDNA sequence

PROTEIN l-ISOASPARTYL METHYLTRANSFERASE (PIMT) in plants: regulations and functions

Proteins are essential molecules that carry out key functions in a cell. However, as a result of aging or stressful environments, the protein undergoes a range of spontaneous covalent modifications, including the formation of abnormal l-isoaspartyl residues from aspartyl or asparaginyl residues, which can disrupt the protein's inherent structure and function. PROTEIN l-ISOASPARTYL METHYLTRANSFERASE (PIMT: EC 2.1.1.77), an evolutionarily conserved ancient protein repairing enzyme (PRE), converts such abnormal l-isoaspartyl residues to normal l-aspartyl residues and re-establishes the protein's native structure and function. Although originally discovered in animals as a PRE, PIMT emerged as a key PRE in plants, particularly in seeds, in which PIMT plays a predominant role in preserving seed vigor and viability for prolonged periods of time. Interestingly, higher plants encode a second PIMT (PIMT2) protein which possesses a unique N-terminal extension, and exhibits several distinct features and far more complexity than non-plant PIMTs. Recent studies indicate that the role of PIMT is not restricted to preserving seed vigor and longevity but is also implicated in enhancing the growth and survivability of plants under stressful environments. Furthermore, expression studies indicate the tantalizing possibility that PIMT is involved in various physiological processes apart from its role in seed vigor, longevity and plant's survivability under abiotic stress. This review article particularly describes new insights and emerging interest in all facets of this enzyme in plants along with a concise comparative overview on isoAsp formation, and the role and regulation of PIMTs across evolutionary diverse species. Additionally, recent methods and their challenges in identifying isoaspartyl containing proteins (PIMT substrates) are highlighted.

Antibiotics in early life: dysbiosis and the damage done

Antibiotics are the most common type of medication prescribed to children, including infants, in the Western world. While use of antibiotics has transformed previously lethal infections into relatively minor diseases, antibiotic treatments can have adverse effects as well. It has been shown in children, adults and animal models that antibiotics dramatically alter the gut microbial composition. Since the gut microbiota plays crucial roles in immunity, metabolism and endocrinology, the effects of antibiotics on the microbiota may lead to further health complications. In this review, we present an overview of the effects of antibiotics on the microbiome in children, and correlate them to long-lasting complications of obesity, behavior, allergies, autoimmunity and other diseases.

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.

Guanosine 5'-(3-O-Thio)triphosphate stimulates protein carboxyl methylation in cell membranes

Using guanosine 5'-(3-O-thio)triphosphate (GTPgammaS), we previously reported that protein carboxyl methyltransferase activities in kidney brush border membranes were increased by the GTP analog (Arch. Biochem. Biophys. 351, 149-158, 1998). Here, we investigated the distribution and characterized the effect of GTPgammaS on protein carboxyl methylation activity. The analysis of species distribution of carboxyl methylation in kidney brush border membranes showed that the GTPgammaS strongly stimulated this activity in rat (15.9-fold), mouse (14.7-fold), human (2.9-fold), and rabbit (2.7-fold). Analysis of GTPgammaS-dependent carboxyl methylation in rat tissues and cell fractions indicated that the activity was mainly localized in membranes of intestine, lung, and kidney, with the highest activity found in liver. To characterize the methyltransferase activity modulated by GTPgammaS in liver membranes, their sensitivity to the detergent 3-[(3-cholamido)dimethylammonio]-1-propanesulfonic acid (Chaps) was used. Methylation of N-acetyl-S-farnesyl cysteine, a prenylated protein methyltransferase (PPMT) substrate was strongly inhibited (86%) in the presence of Chaps, while the methylation of bovine calmodulin and ovalbumin, both of which are substrates for the protein L-isoaspartyl/d-aspartyl methyltransferase (PIMT), was slightly reduced by the detergent (0-12%). The GTPgammaS-dependent carboxyl methylation of endogenous substrates in liver membranes was decreased by 35% in the presence of Chaps, suggesting that PPMT was not the predominant methyltransferase involved in the methylation stimulated by GTPgammaS in liver membranes. Electrophoretic analysis showed that radioactive methylation of several substrates induced by GTPgammaS in liver membranes was reduced by adding calmodulin. Interestingly, addition of GTPgammaS partially inhibited the methylation of two PIMT substrates, ovalbumin (24%) and bovine calmodulin (19%), when incubated with liver membranes. Immunoprecipitation of PIMT from liver and lung membranes strongly inhibited (88-94%) the methylation stimulated by GTPgammaS. Altogether, these data support the hypothesis that GTPgammaS could regulate PIMT activity and may provide new insights into the function of the methyltransferase.

Immunochemical characterization of L-isoaspartyl-protein carboxyl methyltransferase from mammalian tissues

Polyclonal antibodies were raised against a synthetic peptide corresponding to a sequence of 14 amino acid residues found near the C-terminus of L-isoaspartyl (D-aspartyl)-protein carboxyl methyltransferase (PCMT). The affinity-purified antibodies were used to detect the methyltransferase by Western-blot analysis in cytosolic and membrane fractions from several mammalian tissues. A protein of 27 kDa was detected in the cytosol of most tissues; co-incubation with the peptide used for immunization abolished the detection. The identity of the 27 kDa protein as a PCMT was demonstrated by renaturation of PCMT activity from SDS/polyacrylamide gels. The methyltransferase from brain cytosol was immunoprecipitated by the anti-PCMT antibodies and Protein A-agarose, indicating that the native protein was recognized by the antibodies. PCMT was also immunodetected in crude membranes from brain, testes and heart, and in purified membranes from kidney cortex. The expression of the methyltransferase was higher in bovine and human brain than in rat tissues. The bovine enzyme had a greater electrophoretic mobility, suggesting small structural differences. The membrane-bound methyltransferase could be extracted with detergents above their critical micellar concentration, but not with salt, alkaline or urea solutions suggesting that the binding of the enzyme to membranes is hydrophobic by nature. Anti-PCMT antibodies provide an interesting tool for studies regarding the expression of these enzymes in both soluble and membrane fractions of various cell types.

Protein damage and methylation-mediated repair in the erythrocyte

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Tissue-specific expression of isoaspartyl protein carboxyl methyltransferase gene in rat brain and testis

Isoaspartyl protein carboxyl methyltransferase (PIMT) is widely distributed in mammalian tissues. Using a polymerase chain reaction-generated 124-bp DNA fragment from brain cDNA as a probe, four different sizes (approximately 4.0, 2.5, 1.7, and 1.1 kb) of transcripts were detected with northern blot analysis. They were expressed predominantly in rat brain and testis. The major transcripts were 2.5 and 1.7 kb in the brain and 2.5 and 1.1 kb in the testis. One of the major transcripts specific to the testis (1.1 kb) was determined to study the structural difference of major transcripts in the two tissues. This testicular cDNA had neither the 5' (94 nucleotides) nor the 3' (594 nucleotides) end of previously reported brain cDNA corresponding to 1.7 kb. The mRNA levels and enzyme activities of different regions and developmental changes were examined in the brain. The mRNA levels and enzyme activities were concomitantly high in cerebral cortex and hippocampus. Although they increased rapidly approximately 30 days after birth in the testis and decreased in aged rats, they increased gradually after birth and remained high during the aging of the brain. Both structural and developmental studies show that the expression of the PIMT gene in brain and testis is regulated in a tissue-specific manner.

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

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

Identification of the S-adenosyl-L-methionine binding site of protein-carboxyl O-methyltransferase using 8-azido-S-adenosyl-L-methionine

Protein-carboxyl O-methyltransferase (protein methylase II) transfers the methyl group from S-adenosyl-L-methionine (AdoMet) to the carboxyl side chains of the amino acids in the proteins. We have used the radiolabeled analogue of AdoMet, 8-azido-S-adenosyl-L-[methyl-3H]methionine (8-N3-Ado[methyl-3H]Met), to investigate the AdoMet binding site of protein methylase II. The incorporation of the photoaffinity label in the enzyme upon UV irradiation is highly specific. In the absence of UV irradiation or if the photoprobe is irradiated prior to its addition to the reaction mixture, no photoinsertion of the label occurs. Moreover, the presence of a competitive inhibitor of protein methylase II, S-adenosyl-L-homocysteine (AdoHcy), or the unlabeled AdoMet itself in the reaction mixture diminished labeling of the enzyme. Sequential digestion of the labeled enzyme with trypsin, chymotrypsin, and endoproteinase Glu-C yielded a modified and radiolabeled decapeptide. When compared with the reported primary amino acid sequence of protein methylase II from rat brain, the amino acid composition of the decapeptide matched residues 113-121. This segment forms the midpoint region of the enzyme (234 amino acid residues). An important characteristic of the sequence is the presence of two adjacent aspartic acid residues (Asp117-Asp118) which most likely provide the negative charge environment for the sulfonium moiety of the AdoMet molecule.

Molecular characterization of the enniatin synthetase gene encoding a multifunctional enzyme catalysing N-methyldepsipeptide formation in Fusarium scirpi

The gene encoding the multifunctional enzyme enniatin synthetase from Fusarium scirpi (esyn1) was isolated and characterized by transcriptional mapping and expression studies in Escherichia coli. This is the first example of a gene encoding an N-methyl peptide synthetase. The nucleotide sequence revealed an open reading frame of 9393 bp encoding a protein of 3131 amino acids (M(r) 346,900). Two domains designated EA and EB within the protein were identified which share similarity to each other and to microbial peptide synthetase domains. In contrast to the N-terminal domain EA, the carboxyl terminal domain EB is interrupted by a 434-amino-acid portion which shows local similarity to a motif apparently conserved within adenine and cytosine RNA and DNA methyltransferases and therefore seems to harbour the N-methyl-transferase function of the multienzyme.

Rat guanidinoacetate methyltransferase: mutation of amino acids within a common sequence motif of mammalian methyltransferase does not affect catalytic activity but alters proteolytic susceptibility

1. Manual alignment of amino acid sequences of mammalian S-adenosylmethionine-dependent methyltransferases of known sequence revealed the presence of 2 homologous regions. 2. The sequence of the region at the C-terminal side is unique to mammalian methyltransferases, and in guanidinoacetate methyltransferase this sequence occurs at residues 159-165. 3. Mutagenesis of 5 conserved residues in this sequence did not affect the catalytic activity but altered tryptic susceptibility at Arg20.

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.

Alternative splicing of the human isoaspartyl protein carboxyl methyltransferase RNA leads to the generation of a C-terminal -RDEL sequence in isozyme II

We have isolated two cDNA clones that correspond to the mRNAs for two isozymes of the human L-isoaspartyl/D-aspartyl protein carboxyl methyltransferase (EC 2.1.1.77). The DNA sequence of one of these encodes the amino acid sequence of the C-terminal half of the human erythrocyte isozyme I. The other cDNA clone includes the complete coding region of the more acidic isozyme II. With the exception of potential polymorphic sites at amino acid residues 119 and 205, the deduced amino acid sequences differ only at the C-terminus, where the -RWK sequence of isozyme I is replaced by a -RDEL sequence in isozyme II. The latter sequence is identical to a mammalian endoplasmic reticulum retention signal. With the previous evidence for only a single gene for the L-isoaspartyl/D-aspartyl methyltransferase in humans, and with evidence for consensus sites for alternative splicing in corresponding mouse genomic clones, we suggest that alternative splicing reactions can generate the major isozymes previously identified in human erythrocytes. The presence of alternative splicing leads us to predict the existence of a third isozyme with a -R C-terminus. The calculated isoelectric point of this third form is similar to that of a previously detected but uncharacterized minor methyltransferase activity.

Distinct C-terminal sequences of isozymes I and II of the human erythrocyte L-isoaspartyl/D-aspartyl protein methyltransferase

We have purified the more acidic major isozyme (II) of the human erythrocyte L-isoaspartyl/D-aspartyl methyltransferase and compared its structure to that of the previously sequenced isozyme I. These isozymes are both monomers of 25,000 molecular weight polypeptides and have similar enzymatic properties, but have isoelectric points that differ by one pH unit. Analysis of 16 tryptic peptides of isozyme II accounting for 89% of the sequence of isozyme I revealed no differences between these enzyme forms. However, analysis of a Staphylococcal V8 protease C-terminal fragment revealed that the last two residues of these proteins differed. The Trp-Lys-COOH terminus of isozyme I is replaced by a Asp-Asp-COOH terminus in isozyme II. Southern blot analysis of genomic DNA suggests that the human genome [corrected] may contain only a single gene encoding the enzyme. We propose that the distinct C-termini of isozymes I and II can arise from the generation of multiple mRNA's by alternative splicing.