Screening of Toxicity Biomarkers for Methionine Excess in Rats

Toue, Sakino; Kodama, Riho; Amao, Michiko; Kinoshita, Yasuko; Kimura, Takeshi; Sakai, Ryosei

doi:10.1093/jn/136.6.1716s

Cited by 51 publications

(49 citation statements)

References 28 publications

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“…The study had several limitations. Although the mean HCY concentration in the methionine group was similar to that reported by others (17 ) (27.3 vs 25.3 mol/L), excessive methionine supplementation in rats is known to have toxic effects, such as hemolytic anemia and growth suppression (18 ). HCY appears to be among the most plausible explanations for these toxic effects (18 ), but it is possible that methionine-induced effects might reflect systemic toxicity.…”

Section: Discussionsupporting

confidence: 85%

“…Although the mean HCY concentration in the methionine group was similar to that reported by others (17 ) (27.3 vs 25.3 mol/L), excessive methionine supplementation in rats is known to have toxic effects, such as hemolytic anemia and growth suppression (18 ). HCY appears to be among the most plausible explanations for these toxic effects (18 ), but it is possible that methionine-induced effects might reflect systemic toxicity. We thus substantiated our observations by another, biochemically different model of HHCY consisting of a homocystine-enriched diet, and achieved mean HCY concentrations similar to those reported by Joseph et al (19 ), who used a 9 g/kg homocystine diet.…”

Section: Discussionsupporting

confidence: 85%

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Experimental Hyperhomocysteinemia Reduces Bone Quality in Rats

et al. 2007

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Results: Compared with controls, 3 months of moderate or intermediate HHCY increased mean (SD) bone fragility at the femoral neck by 18% (6%) in methionine-fed (P ‫؍‬ 0.001) and 36% (13%) in homocystine-fed rats (P <0.001). Mean (SD) BAr/TAr at the distal femur in methionine and homocystine groups was decreased by 45% (21%; P ‫؍‬ 0.001) and 93% (9%; P ‫؍‬ 0.001), respectively. At the femoral neck, BAr/TAr was decreased by 19% (11%; P <0.001) and 55% (19%; P <0.001). At the lumbar spine, the reduction of BAr/TAr was 17% (23%; P ‫؍‬ 0.099) and 44% (19%; P <0.001). Plasma OC (bone formation marker) was decreased by 23% (20%; P ‫؍‬

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Section: Discussionsupporting

confidence: 85%

Section: Discussionsupporting

confidence: 85%

Experimental Hyperhomocysteinemia Reduces Bone Quality in Rats

et al. 2007

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“…KMTB is then oxidatively decarboxylated to 3-methylthiopropionate (MTP) through an irreversible reaction catalyzed by the branched chain 2-oxo acid dehydrogenase complex (BCKDC) (15). MTP is further metabolized to the gaseous methanethiol (16), which has been reported to then be broken down into simpler molecules, including hydrogen sulfide, dimethyl sulfide, and formic acid, with the end products being carbon dioxide and sulfur dioxide (17,18). Although initial reports on methionine transamination suggested that it provides a route for the degradation and clearance of methionine (19), more recently researchers have claimed that transsulfuration serves as the major pathway for the detoxification of excessive methionine (20).…”

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confidence: 99%

The Methionine Transamination Pathway Controls Hepatic Glucose Metabolism through Regulation of the GCN5 Acetyltransferase and the PGC-1α Transcriptional Coactivator

Tavares

Sharabi

Dominy

et al. 2016

Journal of Biological Chemistry

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Methionine is an essential sulfur amino acid that is engaged in key cellular functions such as protein synthesis and is a precursor for critical metabolites involved in maintaining cellular homeostasis. In mammals, in response to nutrient conditions, the liver plays a significant role in regulating methionine concentrations by altering its flux through the transmethylation, transsulfuration, and transamination metabolic pathways. A comprehensive understanding of how hepatic methionine metabolism intersects with other regulatory nutrient signaling and transcriptional events is, however, lacking. Here, we show that methionine and derived-sulfur metabolites in the transamination pathway activate the GCN5 acetyltransferase promoting acetylation of the transcriptional coactivator PGC-1␣ to control hepatic gluconeogenesis. Methionine was the only essential amino acid that rapidly induced PGC-1␣ acetylation through activating the GCN5 acetyltransferase. Experiments employing metabolic pathway intermediates revealed that methionine transamination, and not the transmethylation or transsulfuration pathways, contributed to methionine-induced PGC-1␣ acetylation. Moreover, aminooxyacetic acid, a transaminase inhibitor, was able to potently suppress PGC-1␣ acetylation stimulated by methionine, which was accompanied by predicted alterations in PGC-1␣-mediated gluconeogenic gene expression and glucose production in primary murine hepatocytes. Methionine administration in mice likewise induced hepatic PGC-1␣ acetylation, suppressed the gluconeogenic gene program, and lowered glycemia, indicating that a similar phenomenon occurs in vivo. These results highlight a communication between methionine metabolism and PGC-1␣-mediated hepatic gluconeogenesis, suggesting that influencing methionine metabolic flux has the potential to be therapeutically exploited for diabetes treatment.Amino acid sensing is a critical mechanism that cells employ to maintain homeostasis and enable survival upon fluctuations in the nutritional environment (1, 2). Despite variability in side chain chemical structure, cells are able to distinguish the distinct amino acids through the use of specific tRNAs. The amino acid protein sensor GCN2 detects deficiencies in amino acids in a tRNA-dependent manner and reprograms cellular metabolism to modulate energy consumption and maintain homeostasis (3, 4). Although mTORC1 is not considered to be a direct sensor of amino acid levels, it functions similarly to GCN2 to alter metabolic pathways in response to amino acid deprivation (5). Methionine, a dietary essential amino acid, is among the more toxic of the L-amino acids, and hence its abundance needs to be precisely regulated (6, 7). The liver is the primary organ concerned with the detoxification of methionine, and hence its ability to sense alterations in concentrations of this amino acid is vital (8). The existence of any cross-talk between hepatic methionine metabolism and other nutrient-regulated metabolic processes in the liver, such as glucose production, requi...

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“…On the other hand, diet supplementation with low doses of methionine (0.2%, 0.3%, 0.4% feed weight) favored increased feed intake and animal growth [18][19][20][21].…”

Section: Discussionmentioning

confidence: 99%

Hyperhomocysteinemia Lead to Transmural Inflammation of Colon and Increase Severity of Disease in Acetic Acid-Induced Colitis in Rat

Souad

Naïmi

Cherifa

2017

Int J Pharm Pharm Sci

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Objective: The present study was designed to evaluate the effect of hyperhomocysteinemia (Hhcy) induced by feeding rats high methionine diet on the colon wall. Colonic damages caused by Hhcy were compared with those induced by acetic -acid induced colitis.Methods: Sprague-Dawley rats (200-250g) were divided into four groups: group C (control), group M (received 1 g/kg methionine p. o. during 15 d), group A (colitis was induced by transrectal administration of acetic acid 4% on 8 th day) and group MA (received methionine and acetic acid). At the end of the study, plasma homocysteine, C-reactive protein (CRP) and leukocytes (WBC) count were evaluated, all rats were sacrificed and distal 8 cm of the colon was dissected. Colon was weighed for disease activity index (DAI) and injuries were assessed macroscopically and histologically.Results: High methionine diet induced significant (P<0.001) increase of homocysteine (hcy), CRP levels and WBC count compared to control. Acetic acid rats showed a significant decrease of WBC count. Mixed treatment caused a significant increase of hcy, CRP and a significant decrease of WBC count. Our results showed that Hhcy causes significant damages and immune cells infiltration in all layers of the colonic wall. Conclusion:The present investigation demonstrated that Hhcy increased the major inflammatory markers as CRP and leukocytes count and produced transmural colitis in rats. Effect of Hhcy is more toxic on the colonic wall than acetic acid indeed while acetic acid lesions are localized in mucosa and submucosa the lesions of hcy extend to the all layers (mucosa, submucosa and muscularis propria). Acetic acid induced colitis in hyperhomocysteinemic rats increased the severity of colitis.

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Screening of Toxicity Biomarkers for Methionine Excess in Rats

Cited by 51 publications

References 28 publications

Experimental Hyperhomocysteinemia Reduces Bone Quality in Rats

Experimental Hyperhomocysteinemia Reduces Bone Quality in Rats

The Methionine Transamination Pathway Controls Hepatic Glucose Metabolism through Regulation of the GCN5 Acetyltransferase and the PGC-1α Transcriptional Coactivator

Hyperhomocysteinemia Lead to Transmural Inflammation of Colon and Increase Severity of Disease in Acetic Acid-Induced Colitis in Rat

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