Urinary excretion of homocysteine thiolactone and the risk of acute myocardial infarction in coronary artery disease patients: the WENBIT trial.

OBJECTIVES: No individual homocysteine (Hcy) metabolite has been studied as a risk marker for coronary artery disease (CAD). Our objective was to examine Hcy-thiolactone, a chemically reactive metabolite generated by methionyl-tRNA synthetase and cleared by the kidney, as a risk predictor of incident acute myocardial infarction (AMI) in the Western Norway B-Vitamin Intervention Trial. DESIGN: Single centre, prospective double-blind clinical intervention study, randomized in a 2 × 2 factorial design. SUBJECTS AND METHODS: Patients with suspected CAD (n = 2049, 69.8% men; 61.2-year-old) were randomized to groups receiving daily (i) folic acid (0.8 mg)/vitamin B12 (0.4 mg)/vitamin B6 (40 mg); (ii) folic acid/vitamin B12 ; (iii) vitamin B6 or (iv) placebo. Urinary Hcy-thiolactone was quantified at baseline, 12 and 38 months. RESULTS: Baseline urinary Hcy-thiolactone/creatinine was significantly associated with plasma tHcy, ApoA1, glomerular filtration rate, potassium and pyridoxal 5'-phosphate (positively) and with age, hypertension, smoking, urinary creatinine, plasma bilirubin and kynurenine (negatively). During median 4.7-years, 183 patients (8.9%) suffered an AMI. In Cox regression analysis, Hcy-thiolactone/creatinine was associated with AMI risk (hazard ratio = 1.58, 95% confidence interval = 1.10-2.26, P = 0.012 for trend; adjusted for age, gender, tHcy). This association was confined to patients with pyridoxic acid below median (adjusted HR = 2.72, 95% CI = 1.47-5.03, P = 0.0001; Pinteraction = 0.020). B-vitamin/folate treatments did not affect Hcy-thiolactone/creatinine and its AMI risk association. CONCLUSIONS: Hcy-thiolactone/creatinine ratio is a novel AMI risk predictor in patients with suspected CAD, independent of traditional risk factors and tHcy, but modified by vitamin B6 catabolism. These findings lend a support to the hypothesis that Hcy-thiolactone is mechanistically involved in cardiovascular disease.

Plasma homocysteine is a determinant of tissue necrosis factor-alpha in hypertensive patients.

Chronic sub-clinical inflammation observed in hypertension plays a prominent role in the progression of atherosclerosis. Accumulating evidence suggests that homocysteine (Hcy) can cause inflammation. The aim of this study was to compare the predictive utility of Hcy and lipid measures as determinants of inflammation in hypertensive patients. We studied a group of 100 patients (45.0+/-12.2 years old) with essential hypertension and a control group of 40 healthy volunteers (44.0+/-8.7 years old). We found that plasma total Hcy (tHcy), tumor necrosis factor alpha (TNF-alpha), interleukin 6 (IL-6), and C-reactive protein (CRP) were significantly higher in hypertensive patients compared with the control group. The subgroup of hypertensive patients with obesity had higher levels of TNF-alpha (p<0.001), IL-6 (p<0.01), and tHcy (p=0.063), compared with the subgroup of hypertensive patients without obesity. The subgroup of patients with a history of myocardial infarction or stroke had significantly higher levels of tHcy, TNF-alpha, IL-6, and CRP compared to patients with a negative history of vascular events. In the group of hypertensive patients, a strong positive correlation between tHcy and TNF-alpha was observed (r=0.48; p<0.001). In contrast, no correlation was observed between TNF-alpha and any of the lipid measures. In multivariate regression analysis tHcy, but not lipids, was an independent predictor of TNF-alpha. In conclusion, our findings show that plasma tHcy is a determinant of TNF-alpha in hypertension and that obesity or a history of vascular events aggravates inflammation in patients with hypertension. A positive correlation between Hcy and TNF-alpha suggests a mechanism underlying the pro-atherogenic properties of Hcy.

The pathophysiological hypothesis of homocysteine thiolactone-mediated vascular disease.

Accumulating evidence suggests that homocysteine (Hcy) metabolite, the thioester Hcy-thiolactone, plays an important role in atherothrombosis. Hcy-thiolactone is a product of an error-editing reaction in protein biosynthesis which forms when Hcy is mistakenly selected by methionyl-tRNA synthetase. The thioester chemistry of Hcy-thiolactone underlies its ability to from isopeptide bonds with protein lysine residues, which impairs or alters protein's function. Protein targets for the modification by Hcy-thiolactone include fibrinogen, low-density lipoprotein, high-density lipoprotein, albumin, hemoglobin, and ferritin. Pathophysiological consequences of protein N-homocysteinylation include protein and cell damage, activation of an adaptive immune response and synthesis of auto-antibodies against N-Hcy-proteins, and enhanced thrombosis caused by N-Hcy-fibrinogen. Recent development of highly sensitive chemical and immunohistochemical assays has allowed verification of the hypothesis that the Hcy-thiolactone pathway contributes to pathophysiology of the vascular system, in particular of the prediction that conditions predisposing to atherosclerosis, such as genetic or dietary hyperhomocysteinemia, lead to elevation of Hcy-thiolactone and N-Hcy-protein. This prediction has been confirmed in vivo both in humans and in mice. For example, plasma Hcy-thiolactone was found to be elevated 59-72-fold in human patients with hyperhomocysteinemia secondary to mutations in methylenetetrahydrofolate reductase (MTHFR) or cystathionine beta-synthase (CBS) genes. Plasma N-Hcy-protein levels are elevated 24-30-fold in MTHFR- or CBS-deficiency, both in human patients and in mice. Plasma and urinary Hcy-thiolactone and plasma N-Hcy-protein levels are also elevated up to 30-fold in mice fed a hyperhomocysteinemic (1.5% methionine) diet. Furthermore, plasma levels of prothromobogenic N-Hcy-fibrinogen were elevated in human CBS deficiency, which explains increased atherothrombosis observed in CBS-deficient patients. We also observed increased immunohistochemical staining for N-Hcy-protein in aortic lesions from ApoE-deficient mice with hyperhomocysteinemia induced by a high methionine diet, relative to the mice fed a normal chow diet. We conclude that genetic or dietary hyperhomocysteinemia significantly elevates proatherothrombotic metabolites Hcy-thiolactone and N-Hcy-proteins in humans and mice.

Mechanisms of homocysteine toxicity in humans.

Homocysteine, a non-protein amino acid, is an important risk factor for ischemic heart disease and stroke in humans. This review provides an overview of homocysteine influence on endothelium function as well as on protein metabolism with a special respect to posttranslational modification of protein with homocysteine thiolactone. Homocysteine is a pro-thrombotic factor, vasodilation impairing agent, pro-inflammatory factor and endoplasmatic reticulum-stress inducer. Incorporation of Hcy into protein via disulfide or amide linkages (S-homocysteinylation or N-homocysteinylation) affects protein structure and function. Protein N-homocysteinylation causes cellular toxicity and elicits autoimmune response, which may contribute to atherogenesis.

The correlation of homocysteine-thiolactonase activity of the paraoxonase (PON1) protein with coronary heart disease status.

Homocysteine (Hcy)-thiolactonase (HTase) activity of the paraoxonase-1 (PON1) protein detoxifies Hcythiolactone in human blood and could thus delay the development of atherosclerosis. We investigated a hypothesis that HTase activity is associated with coronary heart disease. We studied HTase activities and PON1 genotypes in a group of 475 subjects, 42.5% of whom were healthy and 57.5% had coronary heart disease (CHD). We found that HTase activity was positively correlated with total cholesterol (r=0.254, P<0.0001), LDL cholesterol (0.149, P=0.016), ApoB (r=0.167, P=0.006), ApoA1 (0.140, P=0.023), and HDL cholesterol (0.184, P=0.002) in a group of CHD cases (n=270) but not in controls (n=202). Mean HTase activity was significantly higher in CHD cases than in controls (4.57 units vs. 3.30 units, P <10(-5)). The frequencies of the PON1-192 genotypes in CHD cases were similar to those in controls. HTase activity was not different between patients receiving statins and those not treated with statins. Multiple regression analysis shows that CHD status, PON1 genotype, and total cholesterol are determinants of HTase activity in humans. Our results suggest that HTase activity of the PON 1 protein is a predictor of CHD.

Molecular basis of homocysteine toxicity in humans.

Because of its similarity to the protein amino acid methionine, homocysteine (Hcy) can enter the protein biosynthetic apparatus. However, Hcy cannot complete the protein biosynthetic pathway and is edited by the conversion to Hcy-thiolactone, a reaction catalyzed by methionyl-transfer RNA synthetase in all organisms investigated, including human. Nitrosylation converts Hcy into a methionine analogue, S-nitroso-Hcy, which can substitute for methionine in protein synthesis in biological systems, including cultured human endothelial cells. In humans, Hcy-thiolactone modifies proteins posttranslationally by forming adducts in which Hcy is linked by amide bonds to epsilon-amino group of protein lysine residues (Hcy-epsilonN-Lys-protein). Levels of Hcy bound by amide or peptide linkages (Hcy-N-protein) in human plasma proteins are directly related to plasma 'total Hcy' levels. Hcy-N-hemoglobin and Hcy-N-albumin constitute a major pool of Hcy in human blood, larger than 'total Hcy' pool. Hcy-thiolactone and Hcy-thiolactone-hydrolyzing enzyme, a product of the PON1 gene, are present in human plasma. Modification with Hcy-thiolactone leads to protein damage and induces immune response. Autoantibodies that specifically recognize the Hcy-epsilonN-Lys-epitope on Hcy-thiolactone-modified proteins occur in humans. The ability of Hcy to interfere with protein biosynthesis, which causes protein damage, induces cell death and elicits immune response, is likely to contribute to the pathology of human disease.

Determinants of homocysteine-thiolactonase activity of the paraoxonase-1 (PON1) protein in humans.

Homocysteine (Hcy)-thiolactonase (HTase) activity of the paraoxonase-1 (PON1) protein detoxifies Hcy-thiolactone in human blood and could thus delay the development of atherosclerosis. To gain insight into physiological role(s) of the PON1 protein, we studied HTase activities and PON1 genotypes in a group of 184 subjects, 32.6% of whom were healthy, 27.7% had angiographically proven coronary artery disease but did not have myocardial infarction (CAD), and 39.7% had myocardial infarction (MI). We found that the hydrolytic activities of the serum PON1 protein towards Hcy-thiolactone and the organophosphate paraoxon substrates were strongly correlated. PON1-192-RR and PON1-55-LL genotypes were associated with high HTase activity. HTase activity was negatively correlated with age (beta = -0.135, p =0.002), plasma total Hcy (in 192-QR subjects only; r = -0.46, p = 0.001), and positively correlated with total cholesterol (beta = 0.169, p<0.001), but not with HDL cholesterol. Mean HTase activities were similar in CAD subjects, MI subjects, and in healthy controls. However, the frequency of the PON1-192-RR genotype tended to be lower in CAD subjects than in controls (2% vs 10.0%, p = 0.057) and higher in MI subjects that in CAD subjects (10.9% vs 2.0%, p = 0.001). The R-allele was marginally associated with CAD (26.7% in controls vs 17.6% in CAD, p = 0.146) and significantly associated with MI (17.6% in CAD vs 31.5% in MI, p = 0.018). Multiple regression analysis suggests that PON1 genotype, total Hcy, total cholesterol, and age are major determinants of HTase activity in humans.

[Retroperitoneal giant angiomyolipoma diagnosed post-partum with lymph node involvement]. / Postpartal diagnostiziertes retroperitoneales Riesenangiomyolipom mit Lymphknotenbefall.

HISTORY AND PRESENTING COMPLAINT: A 30-year-old primipara after a normal pregnancy had delivered a 3340 g child. After an uneventful post-partum period she had noticed her abdomen failing to reduce in size. INVESTIGATIONS, DIAGNOSIS AND TREATMENT: The abdominal sonography discovered a large retroperitoneal tumor. CT and MRI showed a giant tumor which originated from the right kidney. Suspecting the diagnosis of renal liposarcoma the kidney and tumor were excised with removal of enlarged precaval and preaortal lymph nodes. Gross inspection revealed a ca. 3,2 kg myxoid tumor, measuring 27 x 19 x 10 cm. The histological examination of the surgical preparation revealed a retroperitoneal angiomyolipoma. CONCLUSION: This is the first case of a giant retroperitoneal angiomyolipoma with lymph node involvement diagnosed post partum.

Protein N-homocysteinylation: implications for atherosclerosis.

Elevated levels of homocysteine (Hcy) are associated with various human pathologies, including cardiovascular disease. However, it is not exactly known why Hcy is harmful. A plausible hypothesis is that the indirect incorporation of Hcy into protein, referred to as protein N-homocysteinylation, leads to cell damage. A translational pathway involves: 1) reversible S-nitrosylation of Hcy with nitric oxide produced by nitric oxide synthase; 2) aminoacylation of tRNAMet with S-nitroso-Hcy catalyzed by MetRS; and 3) transfer of S-nitroso-Hcy from S-nitroso-Hcy-tRNAMet into growing polypeptide chains at positions normally occupied by methionine. Subsequent transnitrosylation leaves Hcy in the protein chain. A post-translational pathway involves: 1) metabolic conversion of Hcy to thiolactone by methionyl-tRNAsynthetase (MetRS), and 2) acylation of protein lysine residues by Hcy thiolactone. The levels of Hcy thiolactone and N-homocysteinylated protein in human vascular endothelial cells depend on the ratio of Hcy/Met, levels of folic acid, and HDL, factors linked to cardiovascular disease. HDL-associated human serum Hcy thiolactonase/paraoxonase hydrolyzes thiolactone to Hcy, thereby minimizing protein N-homocysteinylation. Variations in Hcy thiolactonase may play an important role in Hcy-associated human cardiovascular disease.

Translational accuracy of aminoacyl-tRNA synthetases: implications for atherosclerosis.

Aminoacyl-tRNA synthetases establish the rules of the genetic code by matching amino acids (AA) with their cognate tRNA. When differences in binding energies of AA to an aminoacyl-tRNA synthetase are inadequate, editing is used as a major determinant of the enzyme selectivity. Metabolic conversion of the nonprotein AA homocysteine (Hcy) to the thioester Hcy thiolactone by methionyl-, isoleucyl-, and leucyl-tRNA synthetases in vivo shows that continuous editing of incorrect AA is part of the process of tRNA aminoacylation in living organisms, including humans. Reversible S-nitrosylation of Hcy prevents its editing by methionyl-tRNA synthetase and allows incorporation of Hcy into proteins at positions specified by methionine codons. This illustrates how the genetic code can be expanded by invasion of the methionine-coding pathway by Hcy. Translational (nitric oxide-mediated) and post-translational (thiolactone-mediated) incorporation of Hcy into protein provide plausible chemical mechanisms by which elevated levels of Hcy may contribute to the pathology of human cardiovascular diseases.

Yeast cytoplasmic and mitochondrial methionyl-tRNA synthetases: two structural frameworks for identical functions.

The yeast Saccharomyces cerevisiae possesses two methionyl-tRNA synthetases (MetRS), one in the cytoplasm and the other in mitochondria. The cytoplasmic MetRS has a zinc-finger motif of the type Cys-X(2)-Cys-X(9)-Cys-X(2)-Cys in an insertion domain that divides the nucleotide-binding fold into two halves, whereas no such motif is present in the mitochondrial MetRS. Here, we show that tightly bound zinc atom is present in the cytoplasmic MetRS but not in the mitochondrial MetRS. To test whether the presence of a zinc-binding site is required for cytoplasmic functions of MetRS, we constructed a yeast strain in which cytoplasmic MetRS gene was inactivated and the mitochondrial MetRS gene was expressed in the cytoplasm. Provided that methionine-accepting tRNA is overexpressed, this strain was viable, indicating that mitochondrial MetRS was able to aminoacylate tRNA(Met) in the cytoplasm. Site-directed mutagenesis demonstrated that the zinc domain was required for the stability and consequently for the activity of cytoplasmic MetRS. Mitochondrial MetRS, like cytoplasmic MetRS, supported homocysteine editing in vivo in the yeast cytoplasm. Both MetRSs catalyzed homocysteine editing and aminoacylation of coenzyme A in vitro. Thus, identical synthetic and editing functions can be carried out in different structural frameworks of cytoplasmic and mitochondrial MetRSs.

Genetic determinants of homocysteine thiolactonase activity in humans: implications for atherosclerosis.

A metabolite of homocysteine (Hcy), the thioester Hcy thiolactone, damages proteins by modifying their lysine residues which may underlie Hcy-associated cardiovascular disease in humans. A protein component of high density lipoprotein, Hcy thiolactonase (HTase) hydrolyzes thiolactone to Hcy. Thiolactonase is a product of the polymorphic PON1 gene, also involved in detoxification of organophospates and implicated in cardiovascular disease. Polymorphism in PON1 affects the detoxifying activity of PON1 in a substrate-dependent manner. However, how PON1 polymorphism affects HTase activity is unknown. Here we report a strong association between the thiolactonase activity and PON1 genotype in human populations. High thiolactonase activity was associated with L55 and R192 alleles, more frequent in blacks than in whites. Low thiolactonase activity was associated with M55 and Q192 alleles, more frequent in whites than in blacks. High thiolactonase activity afforded better protection against protein homocysteinylation than low thiolactonase activity. These results suggest that variations in HTase may play a role in Hcy-associated cardiovascular disease.

Amino acid selectivity in the aminoacylation of coenzyme A and RNA minihelices by aminoacyl-tRNA synthetases.

Coenzyme A (CoA-SH), a cofactor in carboxyl group activation reactions, carries out a function in nonribosomal peptide synthesis that is analogous to the function of tRNA in ribosomal protein synthesis. The amino acid selectivity in the synthesis of aminoacyl-thioesters by nonribosomal peptide synthetases is relaxed, whereas the amino acid selectivity in the synthesis of aminoacyl-tRNA by aminoacyl-tRNA synthetases is restricted. Here I show that isoleucyl-tRNA synthetase aminoacylates CoA-SH with valine, leucine, threonine, alanine, and serine in addition to isoleucine. Valyl-tRNA synthetase catalyzes aminoacylations of CoA-SH with valine, threonine, alanine, serine, and isoleucine. Lysyl-tRNA synthetase aminoacylates CoA-SH with lysine, leucine, threonine, alanine, valine, and isoleucine. Thus, isoleucyl-, valyl-, and lysyl-tRNA synthetases behave as aminoacyl-S-CoA synthetases with relaxed amino acid selectivity. In contrast, RNA minihelices comprised of the acceptor-TpsiC helix of tRNA(Ile) or tRNA(Val) were aminoacylated by cognate synthetases selectively with isoleucine or valine, respectively. These and other data support a hypothesis that the present day aminoacyl-tRNA synthetases originated from ancestral forms that were involved in noncoded thioester-dependent peptide synthesis, functionally similar to the present day nonribosomal peptide synthetases.

Homocysteine thiolactone and protein homocysteinylation in human endothelial cells: implications for atherosclerosis.

Editing of the nonprotein amino acid homocysteine by certain aminoacyl-tRNA synthetases results in the formation of the thioester homocysteine thiolactone. Here we show that in the presence of physiological concentrations of homocysteine, methionine, and folic acid, human umbilical vein endothelial cells efficiently convert homocysteine to thiolactone. The extent of this conversion is directly proportional to homocysteine concentration and inversely proportional to methionine concentration, suggesting involvement of methionyl-tRNA synthetase. Folic acid inhibits the synthesis of thiolactone by lowering homocysteine and increasing methionine concentrations in endothelial cells. We also show that the extent of post-translational protein homocysteinylation increases with increasing homocysteine levels but decreases with increasing folic acid and HDL levels in endothelial cell cultures. These data support a hypothesis that metabolic conversion of homocysteine to thiolactone and protein homocysteinylation by thiolactone may play a role in homocysteine-induced vascular damage.

Translational incorporation of S-nitrosohomocysteine into protein.

The non-protein amino acid homocysteine (Hcy), owing to its structural similarity to the protein amino acids methionine, isoleucine, and leucine, enters first steps of protein synthesis and is activated by methionyl-, isoleucyl-, and leucyl-tRNA synthetases in vivo. However, translational incorporation of Hcy into protein is prevented by editing mechanisms of these synthetases, which convert misactivated Hcy into thiolactone. The lack of efficient interactions of the side chain of Hcy with the specificity subsite of the synthetic/editing active site is a prerequisite for editing of Hcy. Thus, if the side chain thiol of Hcy were reversibly modified with a small molecule that would enhance its binding to the specificity subsite and prevent editing, such modified Hcy is predicted to be transferred to tRNA and incorporated translationally into protein. Here I show that S-nitroso-Hcy is in fact transferred to tRNA by methionyl-tRNA synthetase and incorporated into protein by the bacterium Escherichia coli. S-Nitroso-Hcy-tRNA also supports translation of mRNAs in a rabbit reticulocyte system. Removal of the nitroso group yields Hcy-tRNA and protein containing Hcy in peptide bonds. S-Nitrosylation-mediated translational incorporation of Hcy into protein may occur under natural conditions in cells and contribute to Hcy-induced pathogenesis in atherosclerosis.

Homocysteine thiolactone: metabolic origin and protein homocysteinylation in humans.

Homocysteine thiolactone, an intramolecular thioester of homocysteine, is synthesized by methionyl-tRNA synthetase in an error-editing reaction that prevents translational incorporation of homocysteine into proteins. The synthesis of thiolactone occurs in all human cell types investigated. An increase in homocysteine levels leads to elevation of thiolactone levels in human cells. In cultured human cells and in human serum, homocysteine thiolactone reacts with proteins by a mechanism involving homocysteinylation of protein lysine residues. The homocysteinylation leads to protein damage. A calcium-dependent homocysteine thiolactonase, tightly associated with HDL in human serum, may prevent protein damage by detoxifying thiolactone.

Calcium-dependent human serum homocysteine thiolactone hydrolase. A protective mechanism against protein N-homocysteinylation.

Homocysteine thiolactone is formed in all cell types studied thus far as a result of editing reactions of some aminoacyl-tRNA synthetases. Because inadvertent reactions of thiolactone with proteins are potentially harmful, the ability to detoxify homocysteine thiolactone is essential for biological integrity. This work shows that a single specific enzyme, present in mammalian but not in avian sera, hydrolyzes thiolactone to homocysteine. Human serum thiolactonase, a 45-kDa protein component of high density lipoprotein, requires calcium for activity and stability and is inhibited by isoleucine and penicillamine. Substrate specificity studies suggest that homocysteine thiolactone is a likely natural substrate of this enzyme. However, thiolactonase also hydrolyzes non-natural substrates, such as phenyl acetate, p-nitrophenyl acetate, and the organophospate paraoxon. N-terminal amino acid sequence of pure thiolactonase is identical with that of human paraoxonase. These and other data indicate that paraoxonase, an organophosphate-detoxifying enzyme whose natural substrate and function remained unknown up to now, is in fact homocysteine thiolactonase. By detoxifying homocysteine thiolactone, the thiolactonase/paraoxonase would protect proteins against homocysteinylation, a potential contributing factor to atherosclerosis.

Protein homocysteinylation: possible mechanism underlying pathological consequences of elevated homocysteine levels.

Homocysteine thiolactone, a cyclic thioester, is synthesized by certain aminoacyl-tRNA synthetases in editing or proofreading reactions that prevent translational incorporation of homocysteine into proteins. Although homocysteine thiolactone is expected to acylate amino groups in proteins, virtually nothing is known regarding reactivity of the thiolactone. Here it is shown that reactions of the thiolactone with protein lysine residues were robust under physiological conditions. In human serum incubated with homocysteine thiolactone, protein homocysteinylation was a major reaction that could be observed with as little as 10 nM thiolactone. Individual proteins were homocysteinylated at rates proportional to their lysine contents. Homocysteinylation led to protein damage, manifested as multimerization and precipitation of extensively modified proteins. Model enzymes, such as methionyl-tRNA synthetase and trypsin, were inactivated by homocysteinylation. Metabolic conversion of homocysteine to the thiolactone, protein homocysteinylation, and resulting protein damage may underlie involvement of Hcy in the pathology of vascular disease.-Jakubowski, H. Protein homocysteinylation: possible mechanism underlying pathological consequences of elevated homocysteine levels.

Misacylation of tRNALys with noncognate amino acids by lysyl-tRNA synthetase.

Lysyl-tRNA synthetase (LysRS), a class II enzyme whose major function is to provide Lys-tRNALys for protein synthesis, also catalyzes aminoacylation of tRNALys with arginine, threonine, methionine, leucine, alanine, serine, and cysteine. The limited selectivity in the tRNA aminoacylation reaction appears to be due to inefficient editing of some amino acids (Met, Leu, Cys, Ala, Thr) by a pre-transfer mechanism or the absence of editing of other amino acids (Arg and Ser). Purified Arg-tRNALys, Thr-tRNALys, and Met-tRNALys were essentially not deacylated by LysRS, indicating that the enzyme does not possess a post-transfer editing mechanism. However, LysRS possesses an efficient pre-transfer editing mechanism which prevents misacylation of tRNALys with ornithine. A novel feature of this editing reaction is that ornithine lactam is formed by the facile cyclization of ornithyl adenylate.