R Is for Arginine
2013; Lippincott Williams & Wilkins; Volume: 128; Issue: 13 Linguagem: Inglês
10.1161/circulationaha.113.005924
ISSN1524-4539
Autores Tópico(s)Metabolism and Genetic Disorders
ResumoHomeCirculationVol. 128, No. 13R Is for Arginine Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBR Is for ArginineMetabolism of Arginine Takes off Again, in New Directions Thomas Michel, MD, PhD Thomas MichelThomas Michel From the Cardiovascular Division, Department of Medicine, Brigham and Women's Hospital, Harvard Medical School, Boston, MA. Originally published4 Sep 2013https://doi.org/10.1161/CIRCULATIONAHA.113.005924Circulation. 2013;128:1400–1404Other version(s) of this articleYou are viewing the most recent version of this article. Previous versions: September 24, 2013: Previous Version 1 First published in 1962, Ray Bradbury's short story collection R is for Rocket provided a view of space travel with a prescience and sophistication that transformed the simpler notions of the time. In a simpler era dating back only to the mid-1980s, l-arginine (abbreviated R in the single-letter amino acid code) seemed to be just another amino acid, notable principally for its guanido group, which conferred arginine with a high pKa and provided its distinction as 1 of the 3 basic amino acids. Abundant in many types of food, synthesized from simple precursors, or recycled in different tissues in the body, arginine is classified as a nonessential amino acid; except under extreme conditions, nutritional states of arginine deficiency are rare. Yet how much more complicated and interesting has arginine become in the past 3 decades! The role of arginine as a humdrum amino acid was forever transformed by the discovery that this amino acid is a substrate for the formation of nitric oxide by all mammalian nitric oxide synthases.1,2 The metabolic transformations of arginine and their roles in cardiovascular (patho)physiology have since been explored in many hundreds of articles.2–7 The current issue of Circulation reports a new and intriguing aspect of arginine metabolism involving the compound homoarginine,8 with even broader implications for our understanding of the roles of metabolic systems in vascular biology and disease.Article see p 1451Homoarginine looks a lot like arginine except that it has an extra carbon (methylene group) in its side chain (Table 1). Because of the involvement of other arginine and arginine metabolites in vascular homeostasis,2–7 this structural similarity has recently inspired numerous clinical studies exploring the relationship between plasma homoarginine levels and human disease states.8–12 Unlike the methylated arginine metabolites, which are competitive inhibitors of nitric oxide (NO) synthases (NOS),6 homoarginine can serve as an NOS substrate (albeit not a very good one).13,14 Because NO is generally viewed as a biologically salutary molecule, it seemed like a plausible hypothesis that low plasma homoarginine levels would be associated with cardiovascular disease states and that higher homoarginine levels might be good for you. This hypothesis appears to be largely correct; however, in 1 clinical study with somewhat contrary findings,10 low plasma homoarginine levels have been found to be associated with increased morbidity or mortality in patients with coronary artery disease, cerebrovascular disease, diabetes mellitus, chronic kidney disease, and other diseases.8,11,12 What is less clear is the molecular mechanism for these associations.Table 1. Properties of selected arginine metabolitesCompoundStructureeNOS Km or (IC50)Plasma/intracellular levels (µM)Source or synthetic pathwayMajor catabolic pathwaysRelation of plasma levels to CV diseaseL-Arginine1,2,5,13,14~3 µM~60-100/>>200 µMProteolysis> diet, recycling via ASS/ASL, de novo synthesisNOS, Arginases, AGATNo clear relation. Acute infusion improves vascular function, but long-term supplementation may be harmful.L-Homoarginine8–14~70 µM~1 µM/ ?Diet, recycling, OTC/ASS/ASL or via AGATNOS, Arginases?, others?↓ levels seen in stroke, CV disease; ↑ levels are protective. Supplements ↓ stroke in mice.L-Citrulline1,2Not a NOS inhibitor/ substrate~20-100/ ~20-30 µMNOS product, product of DDAHs, diet"citrulline cycle" via ASS/ASLNo clear relation to CV disease.ADMA2–7(~1 µM)0.4/~4 µMPRMTs → proteolysisDDAH-1 and DDAH-2, arginases↑ levels seen in CV diseaseSMA2–6Not a NOS inhibitor/ substrate~1 µM/ ?PRMTs → proteolysisRenal excretionNo clear relation to CV disease.NMMA2–6(~1 µM)~0.4/~3 µMPRMTs → proteolysisDDAH-1 and DDAH-2, arginases↑ levels seen in CV diseaseThis table summarizes basic features of several major arginine metabolites relevant to cardiovascular (CV) disease states. The first column lists principal arginine metabolites and provides key references (mostly review articles) that support the information provided in this table and in the text; because of space limitations, the numerous relevant original research articles cannot be listed here. The structure of l-arginine (second column) differs from l-homoarginine by the additional methylene group present in the homoarginine side chain. The third column shows the concentration of the compound that yields half-maximal enzyme activity (Km) for active substrates or (in parentheses) the concentration that yields half-maximal suppression of enzyme activity for inhibitor compounds (IC50). The Km has been extensively validated for l-arginine in studies of the purified enzyme. In contrast, the endothelial nitric oxide synthase (eNOS) Km value for l-homoarginine is based either on analyses of crude cell lysates or on studies of other nitric oxide synthase (NOS) isoforms. The concentrations of NOS inhibitors yielding IC50 are determined mostly in studies in which asymmetrically Nω-dimethylated arginine (ADMA) or monomethylated arginine (NMMA) is added to cultured endothelial cells and eNOS activity is estimated, and the IC50 values for inhibitors depend on the extracellular arginine concentration. ADMA and NMMA appear to be competitive inhibitors of eNOS, whereas symmetrically dimethylated arginine (SMA) serves as neither a substrate nor an inhibitor of NOS isoforms. Plasma levels for these compounds have been reported in many studies, but the intracellular concentrations have been less extensively characterized. The relative roles of different synthetic and catabolic pathways are best known for arginine and less so for the other arginine metabolites. The text and Figure provide further discussion. AGAT indicates arginine:glycine amidinotransferase; ASL, arginosuccinate lyase; ASS, arginosuccinate synthase; DDAH, dimethyl diaminoarginine hydrolase; OTC, ornithine transcarbamoylase; and PRMT, protein arginine methyltransferases.The study reported by Choe et al8 provides important new clues about homoarginine while raising interesting new questions. Consistent with previous papers reporting an association between higher plasma homoarginine levels and reduced cardiovascular morbidity or mortality, Choe et al show that higher homoarginine was independently associated with a reduction in mortality in stroke patients. The authors speculate that their data "suggest that homoarginine may positively influence the beneficial pathways of NO,"8 although no direct measurements of the activity of the NO pathway were reported in this study. This still seems like a plausible hypothesis, yet a direct effect of homoarginine on endothelial NOS catalysis may be less likely; homoarginine appears to be a relatively poor NOS substrate in vivo13 and in vitro14 and may even lead to NOS uncoupling.14 But the Cho et al article goes well beyond prior clinical reports on homoarginine by performing genome-wide association studies analyzing single-nucleotide polymorphisms in stroke patients stratified by plasma homoarginine levels. These analyses led to an intriguing and novel discovery that low plasma homoarginine levels are significantly associated with polymorphisms in the gene encoding arginine:glycine amidinotransferase (AGAT; Figure). AGAT encodes an enzyme known to be expressed in the kidney and is mostly studied for its role in creatine metabolism, but more recently, AGAT was shown to be involved in the synthesis of homoarginine.15 Another significant genome-wide association study finding in the Choe et al study8 was in the ornithine transcarbamoylase gene, but this was a weaker association and was not followed up in detail. It is interesting to note that polymorphisms in ornithine transcarbamoylase (a key enzyme in the urea cycle) have previously been implicated in genome-wide association studies of hypertension and stroke.16 Focusing in detail on the AGAT polymorphisms that they had discovered, the authors8 found that most of these polymorphisms were located in intronic regions of the AGAT gene, documenting just 1 missense mutation (exchange of a glutamine residue for histidine). The effect of this amino acid change on AGAT enzyme activity was not explored in this study, nor were levels of AGAT protein measured. Yet the authors still provide several clear and compelling lines of evidence suggesting that AGAT has a key role in homoarginine metabolism. They showed that overexpression of AGAT increased homoarginine levels in a cell model and analyzed AGATnull knockout mice. They found that AGATnull knockout mice had low plasma homoarginine levels and showed that these mice had increased morbidity in an experimental stroke model that could be ameliorated by homoarginine feeding. Conversely, in a distinct knockout mouse model in which the gene for a different arginine-metabolizing enzyme called guanidinoacetate methyltransferase (GAMT) was deleted, the mice had higher homoarginine levels and smaller experimental strokes. The authors conclude, "These results provide evidence that higher homoarginine levels attenuate stroke severity and improve outcome in mice and suggest that homoarginine is causally involved in the (patho)physiology of ischemic stroke." This seems like a reasonable inference, yet the molecular mechanisms remain incompletely defined. Moreover, this study did not show that plasma homoarginine levels improved risk prediction over conventional risk factors. So before we start crop-dusting the population with homoarginine, let us take a closer look at how homoarginine fits into a complicated network that involves not only AGAT and GAMT but also many other complexly modulated enzymes and pathways that regulate arginine and its metabolites.Download figureDownload PowerPointFigure. Principal pathways of arginine and homoarginine metabolism. ADMA indicates asymmetrically Nω-dimethylated arginine; AGAT, arginine:glycine amidinotransferase; ASL, arginosuccinate lyase; ASS, arginosuccinate synthase; DDAH, dimethyl diaminoarginine hydrolase; NMMA, monomethylated arginine; NO, nitric oxide; NOS, nitric oxide synthase; OTC, ornithine transcarbamoylase; PRMT, protein arginine methyltransferases; and SAM, symmetrically dimethylated arginine. See the text for details.Let us start with arginine, which has been the most extensively studied of these compounds. The Figure presents a simplified (but still complicated) scheme showing many of the intersecting cycles of arginine metabolism that appear to be most clearly related to cardiovascular (patho)physiology. Table 1 gives the molecular structures and the references supporting the summary presented below. l-Arginine levels in the plasma are in the ≈100-µmol/L range, and intracellular arginine levels appear to be even higher. The NOS half-maximal enzyme activity (Km) for l-arginine is much lower than its overall intracellular concentration, but it appears that arginine and arginine-metabolizing enzymes may have differential subcellular distributions, raising the possibility that arginine concentrations may be limiting for NOS in specific subcellular locales. Moreover, the presence of endogenous competitive inhibitors of NOS (discussed below) may raise the effective intracellular arginine concentration needed for full enzyme activity. In any event, the action of NOS on l-arginine yields NO plus l-citrulline, which can be recycled back to l-arginine by the sequential reactions catalyzed by arginosuccinate synthase and arginosuccinate lyase. But it appears that most of the plasma l-arginine comes either from the diet or from recycling/proteolysis of cellular proteins, with a smaller fraction synthesized from other amino acids or recycled from l-arginine (at least in most cell types). The traffic of extracellular l-arginine (and other cationic amino acids, including l-lysine) into cells occurs via specific cell surface amino acid transporters, of which CAT-1 and related transporters are the best characterized. Arginine may also be catabolized by l-AGAT, the enzyme recently implicated in homoarginine metabolism,15 as discussed above. However, in most cell types, arginine catabolism is catalyzed principally by a family of arginase enzymes, which yield ornithine and urea; the ornithine that is formed by arginase can by metabolized back to l-arginine in multiple enzymatic steps. Arginases are central to arginine flux in the cell because these enzymes may represent the quantitatively most important pathway for arginine catabolism, and arginase activity appears to be inhibited by homoarginine.Let us now move on to the methylated arginine compounds, which have been definitively linked to cardiovascular disease and might represent another potential pathway whereby homoarginine may have a role. Monomethylated arginine (NMMA) and asymmetrically Nω-dimethylated arginine (ADMA) are potent NOS inhibitors, whereas symmetrically dimethylated arginine is neither an NOS substrate or inhibitor. To form these arginine homologs, the terminal guanido nitrogens of arginine residues in proteins are methylated by a family of protein arginine methyltransferases. Methylarginines play a broad role in cellular regulation well beyond their effects on NOS. These compounds are implicated in transcriptional regulation and in the metabolism of DNA and RNA.7 As is the case for arginine, methylated arginine compounds are released from cellular proteins by proteolysis, possibly in the context of cellular autophagy or apoptosis; increased levels of ADMA and NMMA are clearly implicated in vascular pathology and in the inhibition of NOS activity. ADMA and NMMA can be catalyzed either by arginases or by a family of dimethyl diaminoarginine hydrolase enzymes, yielding citrulline, which can then be recycled back to arginine. It is possible that homoarginine might inhibit the actions of protein arginine methyltransferases, thereby reducing the levels of NMMA and ADMA and thus enhancing NOS activity. Arguing against this notion is the fact that plasma levels of ADMA and NMMA were unchanged in the AGATnull knockout mouse studied by Choe et al,8 although intracellular levels of these compounds were not measured.Compared with the large body of clinical and biochemical data on the roles of arginine and methylated arginine compounds, much less is known about the metabolic transformations and biochemical roles of homoarginine (the Figure and Table 1). In mammals, homoarginine can come either from the diet or by synthesis from endogenous precursors; plasma homoarginine levels are ≈100-fold lower than those of l-arginine. Homoarginine can serve as an NOS substrate, yielding NO plus homocitrulline as coproducts. Yet the NOS Km for homoarginine is ≈20-fold higher than for arginine. Moreover, homoarginine is not a very effective substrate for NOS, and it is not clear than higher homoarginine levels would necessarily lead directly to significant increases in NO synthesis. There are even some reports that homocitrulline, the enzymatic product of NOS action on homoarginine, might be associated with atherogenesis.17 Although homoarginine can serve as an arginase substrate with a low Km, it is not a very good arginase substrate, and it is plausible that homoarginine could actually function as an arginase inhibitor and thereby lead to an increase in intracellular arginine. But because intracellular arginine levels are already well in excess of the NOS Km for its substrate, the direct consequences of homoarginine-dependent arginase inhibition on NOS activity are less obvious. Clinical studies have reported that long-term arginine supplementation may have deleterious effects, raising caveats about the possible long-term consequences of homoarginine supplementation despite the clearly beneficial effects of short-term homoarginine supplementation in mouse stroke models, as reported by Choe et al.8The AGATnull and GAMTnull mouse knockout models that were carefully studied by Choe et al provide additional intriguing clues to possible mechanisms whereby homoarginine may modulate vascular (patho)physiology. Homoarginine can be formed from l-arginine and the amino acid l-lysine by the actions of our now-familiar AGAT enzyme, as shown in the Figure. AGAT is a mitochondrial enzyme that is expressed most abundantly in the kidney and is critically involved in the synthesis of creatine, a vital metabolite in energy metabolism. Marked decreases in both homoarginine and creatine were documented in plasma from AGATnull mice, associated with significant increases in the size of experimental stroke.8 Yet previous studies of AGATnull mice documented multiple other metabolic changes in these knockout mice.18 The metabolic phenotype of AGATnull mice is quite complex, and the link between homoarginine and stroke needs to be viewed in the context of numerous biochemical derangements in this knockout mouse model. However, the fact that homoarginine but not creatine supplementation improved the stroke phenotype provides strong suggestive evidence for a central role for homoarginine in attenuating the severity of stroke in this mouse model. But despite the intriguing associations between homoarginine levels and stroke protection in these informative mouse models, the links between AGAT polymorphisms, homoarginine, and vascular disease in humans likely reflect a greater complexity.In humans, AGAT expression appears to be highest in kidney and liver. Yet AGAT is also expressed in the myocardium, where levels of AGAT appear to be dynamically regulated in heart failure.19 Although arginine is clearly required for AGAT catalysis, the enzyme is somewhat promiscuous in its choice of cosubstrates: AGAT generates homoarginine when lysine is used as the cosubstrate or instead promotes creatine synthesis when glycine is used (Figure). This enzymatic promiscuity may also depend on the specific tissue in which AGAT is expressed and the relative availability of lysine versus glycine for catalysis. Because creatine synthesis can lead to the generation of the proatherogenic metabolite homocysteine,20 subtle changes in the expression and activity of AGAT may have a marked effect on vascular pathobiology. Perhaps increased levels of plasma homoarginine are associated with decreased levels of homocysteine, reflecting a change in the balance of AGAT activity between using lysine as a cosubstrate (leading to homoarginine synthesis) instead of glycine (yielding creatine and homocysteine). Might lysine be the link? We do not know, but it is important to note that all but one of the AGAT polymorphisms identified in the Choe et al study are located in intronic regions, which might possibly lead to differences in AGAT expression or tissue distribution.Clearly, more remains to be learned about the molecular mechanisms whereby differences in plasma homoarginine levels modulate stroke severity. It should now be clear that arginine metabolism cannot be viewed as a single pathway or even as the confluence of multiple pathways. Rather, arginine metabolism must be viewed as a biochemical system, allowing multiple points of connection and regulation within any particular cell type and differing patterns of tissue-specific enzyme expression and modulation.One of the best-known short stories in Bradbury's R is for Rocket is called "A Sound of Thunder," which relates the tale of a time traveler who interferes with the thread of time by accidentally treading on a butterfly during his journey into the past. When the time traveler returns to the present after his mishap with the butterfly, he finds subtle but irrevocable changes in the world that he left behind to travel into the past. So it is for arginine metabolism: Subtle changes in levels of one metabolite may lead to profound changes in the levels or biological activities of distantly related metabolites. No matter what molecular mechanisms are ultimately identified in unraveling the association between homoarginine and disease, the Choe et al study serves as an exemplar of the need to view levels of specific metabolites as reflecting the products of interrelated and dynamic metabolic systems.Sources of FundingThis work was supported in part by National Institutes of Health grants HL46457 and HL48743.DisclosuresNone.FootnotesThe opinions expressed in this article are not necessarily those of the editors or of the American Heart Association.Correspondence to Thomas Michel, MD, PhD, Brigham and Women's Hospital, Cardiovascular Division, 75 Francis St, Thorn Bldg, Room 1210A, Boston, MA 02115. E-mail [email protected]References1. Marletta MA. Nitric oxide: biosynthesis and biological significance.Trends Biochem Sci. 1989; 14:488–492.CrossrefMedlineGoogle Scholar2. Böger RH, Bode-Böger SM. The clinical pharmacology of l-arginine.Annu Rev Pharmacol Toxicol. 2001; 41:79–99.CrossrefMedlineGoogle Scholar3. Vallance P, Leiper J. Cardiovascular biology of the asymmetric dimethylarginine:dimethylarginine dimethylaminohydrolase pathway.Arterioscler Thromb Vasc Biol. 2004; 24:1023–1030.LinkGoogle Scholar4. Caplin B, Leiper J. Endogenous nitric oxide synthase inhibitors in the biology of disease: markers, mediators, and regulators?Arterioscler Thromb Vasc Biol. 2012; 32:1343–1353.LinkGoogle Scholar5. Morris SM. Arginine metabolism in vascular biology and disease.Vasc Med. 2005; 10(suppl 1):S83–S87.CrossrefMedlineGoogle Scholar6. Cardounel AJ, Cui H, Samouilov A, Johnson W, Kearns P, Tsai AL, Berka V, Zweier JL. Evidence for the pathophysiological role of endogenous methylarginines in regulation of endothelial NO production and vascular function.J Biol Chem. 2007; 282:879–887.CrossrefMedlineGoogle Scholar7. Bedford MT. Arginine methylation at a glance.J Cell Sci. 2007; 120(pt 24):4243–4246.CrossrefMedlineGoogle Scholar8. Choe C, Atzler D, Wild PS, Carter AM, Boger RH, Ojeda F, Simova O, Stockbrand M, Lackner K, Nabuurs C, Marescau B, Streichert T, Müller C, Lüneburg N, De Deyn PP, Benndorf RA, Baldus S, Gerloff C, Blankenberg S, Heerschap A, Grant PJ, Magnus T, Zeller T, Isbrandt D, Schwedhelm E. Homoarginine levels are regulated by l-arginine:glycine amidinotransferase and affect stroke outcome: results from human and murine studies.Circulation. 2013; 128:1451–1461.LinkGoogle Scholar9. Wilson AM, Harada R, Nair N, Balasubramanian N, Cooke JP. l-Arginine supplementation in peripheral arterial disease: no benefit and possible harm.Circulation. 2007; 116:188–195.LinkGoogle Scholar10. van der Zwan LP, Davids M, Scheffer PG, Dekker JM, Stehouwer CD, Teerlink T. l-Homoarginine and l-arginine are antagonistically related to blood pressure in an elderly population: the Hoorn study.J Hypertens. 2013; 31:1114–1123.CrossrefMedlineGoogle Scholar11. März W, Meinitzer A, Drechsler C, Pilz S, Krane V, Kleber ME, Fischer J, Winkelmann BR, Böhm BO, Ritz E, Wanner C. Homoarginine, cardiovascular risk, and mortality.Circulation. 2010; 122:967–975.LinkGoogle Scholar12. Dreschler C, Kollerits B, Meinitzer A, Marz W, Ritz E, Konig P, Neyer U, Pilz S, Wanner C, Kronenberg F; MMKD Study Group. Homoarginine and progression of chronic kidney disease: results from the Mild to Moderate Kidney Disease Study.PLoS One. 2013; 8:e63560.CrossrefMedlineGoogle Scholar13. Schini VB, Vanhoutte PM. l-arginine evokes both endothelium-dependent and -independent relaxations in l-arginine-depleted aortas of the rat.Circ Res. 1991; 68:209–216.LinkGoogle Scholar14. Moali C, Boucher J-L, Sari M-A, Steuhr DJ, Mansuy D. Substrate specificity of NO synthases: detailed comparison of l-arginine, homo-l-arginine, their Nω-hydroxy derivatives, and Nω-hydroxynor-l-rginine.Biochemistry. 1998; 37:10453–10460.CrossrefMedlineGoogle Scholar15. Davids M, Ndika JD, Salomons GS, Blom HJ, Teerlink T. Promiscuous activity of arginine:glycine amidinotransferase is responsible for the synthesis of the novel cardiovascular risk factor homoarginine.FEBS Lett. 2012; 586:3653–3657.CrossrefMedlineGoogle Scholar16. Dumont J, Meroufel D, Bauters C, Hansmannel F, Bensemain F, Cottel D, Hamon M, Lambert JC, Ducimetière P, Amouyel P, Zureik M, Brousseau T. Association of ornithine transcarbamylase gene polymorphisms with hypertension and coronary artery vasomotion.Am J Hypertens. 2009; 22:993–1000.CrossrefMedlineGoogle Scholar17. Wang Z, Nicholls SJ, Rodriguez ER, Kummu O, Hörkkö S, Barnard J, Reynolds WF, Topol EJ, DiDonato JA, Hazen SL. Protein carbamylation links inflammation, smoking, uremia and atherogenesis.Nat Med. 2007; 13:1176–1184.CrossrefMedlineGoogle Scholar18. Stockebrand M, Sauter K, Neu A, Isbrandt D, Choe CU. Differential regulation of AMPK activation in leptin- and creatine-deficient mice.FASEB J. June 28, 2013. http://www.fasebj.org/content/early/2013/06/28/fj.12-225136.long. doi:10.1096/fj.12-225136.Google Scholar19. Jahangir E, Vita JA, Handy D, Holbrook M, Palmisano J, Beal R, Loscalzo J, Eberhardt RT. The effect of l-arginine and creatine on vascular function and homocysteine metabolism.Vasc Med. 2009; 14:239–248.CrossrefMedlineGoogle Scholar20. Cullen ME, Yuen AHY, Felkin LE, Smolenski RT, Hall JL, Grindle S, Miller LW, Birks EJ, Yacoub MH, Barton PJR. Myocardial expression of the arginine:glycine amidinotransferase gene is elevated in heart failure and normalized after recovery; potential implications for local creatine synthesis.Circulation. 2006; 114(suppl I):I-16–I-20.LinkGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited ByNitz K, Lacy M, Bianchini M, Wichapong K, Kücükgöze I, Bonfiglio C, Migheli R, Wu Y, Burger C, Li Y, Forné I, Ammar C, Janjic A, Mohanta S, Duchene J, Heemskerk J, Megens R, Schwedhelm E, Huveneers S, Lygate C, Santovito D, Zimmer R, Imhof A, Weber C, Lutgens E and Atzler D (2022) The Amino Acid Homoarginine Inhibits Atherogenesis by Modulating T-Cell Function, Circulation Research, 131:8, (701-712), Online publication date: 30-Sep-2022. Şengül V, Güney Z, Kurgan Ş, Önder C, Serdar M and Günhan M (2022) Evaluation of salivary and serum methylated arginine metabolites and nitric oxide synthase in advanced periodontitis patients, Clinical Oral Investigations, 10.1007/s00784-022-04479-w Chia T, Zolp A and Miska J (2022) Polyamine Immunometabolism: Central Regulators of Inflammation, Cancer and Autoimmunity, Cells, 10.3390/cells11050896, 11:5, (896) Weng A, Köstler H, Bley T and Ritter C (2021) Effect of short-term smoking & L-arginine on coronary endothelial function assessed by cardiac magnetic resonance cold pressor testing: a pilot study, BMC Cardiovascular Disorders, 10.1186/s12872-021-02050-1, 21:1, Online publication date: 1-Dec-2021. Ming Z, Zou Z, Cai K, Xu Y, Chen X, Yi W, Luo J and Luo Z (2020) ARG1 functions as a tumor suppressor in breast cancer, Acta Biochimica et Biophysica Sinica, 10.1093/abbs/gmaa116, 52:11, (1257-1264), Online publication date: 11-Dec-2020. Malle O, Trummer C, Theiler-Schwetz V, Meinitzer A, Keppel M, Grübler M, Tomaschitz A, Voelkl J, März W and Pilz S (2020) NO Synthesis Markers Are Not Significantly Associated with Blood Pressure and Endothelial Dysfunction in Patients with Arterial Hypertension: A Cross-Sectional Study, Journal of Clinical Medicine, 10.3390/jcm9123895, 9:12, (3895) Mokhaneli M, Fourie C, Botha-Le Roux S, Böger R, Schwedhelm E and Mels C (2020) Asymmetric dimethylarginine and l-homoarginine prospectively relate to carotid wall thickness in a South African cohort, Amino Acids, 10.1007/s00726-020-02866-9, 52:6-7, (965-973), Online publication date: 1-Jul-2020. Pawlak-Chaouch M, Boissière J, Munyaneza D, Tagougui S, Gamelin F, Cuvelier G, Heyman E, Goossens J, Descat A, Berthoin S and Aucouturier J (2018) Plasma asymmetric dimethylarginine concentrations are not related to differences in maximal oxygen uptake in endurance trained and untrained men, Experimental Physiology, 10.1113/EP087398, 104:2, (254-263), Online publication date: 1-Feb-2019. McDonald J, Mah E, Dey P, Olmstead B, Sasaki G, Villamena F and Bruno R (2019) Dairy milk, regardless of fat content, protects against postprandial hyperglycemia-mediated impairments in vascular endothelial function in adults with prediabetes by limiting oxidative stress responses that reduce nitric oxide bioavailability, The Journal of Nutritional Biochemistry, 10.1016/j.jnutbio.2018.10.002, 63, (129-139), Online publication date: 1-Jan-2019. McDonald J, Mah E, Chitchumroonchokchai C, Dey P, Labyk A, Villamena F, Volek J and Bruno R (2019) Dairy milk proteins attenuate hyperglycemia-induced impairments in vascular endothelial function in adults with prediabetes by limiting increases in glycemia and oxidative stress that reduce nitric oxide bioavailability, The Journal of Nutritional Biochemistry, 10.1016/j.jnutbio.2018.09.018, 63, (165-176), Online publication date: 1-Jan-2019. Jud P, Hafner F, Verheyen N, Meinitzer A, Gary T, Brodmann M, Seinost G and Hackl G (2018) Homoarginine/ADMA ratio and homoarginine/SDMA ratio as independent predictors of cardiovascular mortality and cardiovascular events in lower extremity arterial disease, Scientific Reports, 10.1038/s41598-018-32607-8, 8:1, Online publication date: 1-Dec-2018. Tommasi S, Elliot D, Da Boit M, Gray S, Lewis B and Mangoni A (2018) Homoarginine and inhibition of human arginase activity: kinetic characterization and biological relevance, Scientific Reports, 10.1038/s41598-018-22099-x, 8:1, Online publication date: 1-Dec-2018. Jud P, Hafner F, Verheyen N, Gary T, Meinitzer A, Brodmann M, Seinost G and Hackl G (2018) Age-dependent effects of homocysteine and dimethylarginines on cardiovascular mortality in claudicant patients with lower extremity arterial disease, Heart and Vessels, 10.1007/s00380-018-1210-9, 33:12, (1453-1462), Online publication date: 1-Dec-2018. McDonald J, Mah E, Chitchumroonchokchai C, Reverri E, Li J, Volek J, Villamena F and Bruno R (2018) Co-ingestion of whole eggs or egg whites with glucose protects against postprandial hyperglycaemia-induced oxidative stress and dysregulated arginine metabolism in association with improved vascular endothelial function in prediabetic men, British Journal of Nutrition, 10.1017/S0007114518002192, 120:8, (901-913), Online publication date: 28-Oct-2018. Zinellu A, Paliogiannis P, Carru C and Mangoni A (2018) Homoarginine and all-cause mortality: A systematic review and meta-analysis, European Journal of Clinical Investigation, 10.1111/eci.12960, 48:8, (e12960), Online publication date: 1-Aug-2018. da Boit M, Tommasi S, Elliot D, Zinellu A, Sotgia S, Sibson R, Meakin J, Aspden R, Carru C, Mangoni A and Gray S (2017) Sex Differences in the Associations between L-Arginine Pathway Metabolites, Skeletal Muscle Mass and Function, and their Responses to Resistance Exercise, in Old Age, The journal of nutrition, health & aging, 10.1007/s12603-017-0964-6, 22:4, (534-540), Online publication date: 1-Apr-2018. Radhakutty A, Mangelsdorf B, Drake S, Rowland A, Smith M, Mangoni A, Thompson C and Burt M (2017) Opposing effects of rheumatoid arthritis and low dose prednisolone on arginine metabolomics, Atherosclerosis, 10.1016/j.atherosclerosis.2017.10.004, 266, (190-195), Online publication date: 1-Nov-2017. Papageorgiou N, Androulakis E, Papaioannou S, Antoniades C and Tousoulis D (2015) Homoarginine in the shadow of asymmetric dimethylarginine: from nitric oxide to cardiovascular disease, Amino Acids, 10.1007/s00726-015-2017-y, 47:9, (1741-1750), Online publication date: 1-Sep-2015. Yang Y, Wu Z, Jia S, Dahanayaka S, Feng S, Meininger C, McNeal C and Wu G (2015) Safety of long-term dietary supplementation with l-arginine in rats, Amino Acids, 10.1007/s00726-015-1992-3, 47:9, (1909-1920), Online publication date: 1-Sep-2015. Hou Y, Jia S, Nawaratna G, Hu S, Dahanayaka S, Bazer F and Wu G (2015) Analysis of l-homoarginine in biological samples by HPLC involving precolumn derivatization with o-phthalaldehyde and N-acetyl-l-cysteine, Amino Acids, 10.1007/s00726-015-1962-9, 47:9, (2005-2014), Online publication date: 1-Sep-2015. Hov G, Aasarød K, Sagen E and Åsberg A (2015) Arginine, dimethylated arginine and homoarginine in relation to cardiovascular risk in patients with moderate chronic kidney disease, Clinical Biochemistry, 10.1016/j.clinbiochem.2015.03.012, 48:10-11, (646-651), Online publication date: 1-Jul-2015. Vogl L, Pohlhammer J, Meinitzer A, Rantner B, Stadler M, Peric S, Hammerer-Lercher A, Klein-Weigel P, Fraedrich G, Kronenberg F and Kollerits B (2015) Serum concentrations of l-arginine and l-homoarginine in male patients with intermittent claudication: A cross-sectional and prospective investigation in the CAVASIC Study, Atherosclerosis, 10.1016/j.atherosclerosis.2015.02.019, 239:2, (607-614), Online publication date: 1-Apr-2015. Bogdan C (2015) Nitric oxide synthase in innate and adaptive immunity: an update, Trends in Immunology, 10.1016/j.it.2015.01.003, 36:3, (161-178), Online publication date: 1-Mar-2015. Melsom T, Fuskevåg O, Mathisen U, Strand H, Schei J, Jenssen T, Solbu M and Eriksen B (2015) Estimated GFR Is Biased by Non-Traditional Cardiovascular Risk Factors, American Journal of Nephrology, 10.1159/000371557, 41:1, (7-15), . Feliers D, Lee D, Gorin Y and Kasinath B (2015) Symmetric dimethylarginine alters endothelial nitric oxide activity in glomerular endothelial cells, Cellular Signalling, 10.1016/j.cellsig.2014.09.024, 27:1, (1-5), Online publication date: 1-Jan-2015. Cheon D, Walts A, Beach J, Lester J, Bomalaski J, Walsh C, Ruprecht Wiedemeyer W, Karlan B and Orsulic S (2014) Differential expression of argininosuccinate synthetase in serous and non‐serous ovarian carcinomas, The Journal of Pathology: Clinical Research, 10.1002/cjp2.4, 1:1, (41-53), Online publication date: 1-Jan-2015. Atzler D, Gore M, Ayers C, Choe C, Böger R, de Lemos J, McGuire D and Schwedhelm E (2014) Homoarginine and Cardiovascular Outcome in the Population-Based Dallas Heart Study, Arteriosclerosis, Thrombosis, and Vascular Biology, 34:11, (2501-2507), Online publication date: 1-Nov-2014. September 24, 2013Vol 128, Issue 13 Advertisement Article InformationMetrics © 2013 American Heart Association, Inc.https://doi.org/10.1161/CIRCULATIONAHA.113.005924PMID: 24004503 Originally publishedSeptember 4, 2013 Keywordsarginineamino acidsstrokeEditorialsnitric oxidePDF download Advertisement
Referência(s)