Methionine Deficiency Research Articles

The Protective Effects of Methionine on Nickel-Induced Oxidative Stress via NF-κB Pathway in the Kidneys of Mice.

Nickel (Ni) is a human carcinogen that causes oxidative damage to many organs, and methionine has been studied to protect mammals from similar toxic effects by other heavy metals possibly through sulfur metabolism. This study aimed to investigate the protective effects of methionine on Ni-induced injuries to the kidneys. In this study, the mice were randomly divided into BC (normal diet), MD (methionine deficiency diet), MN (methionine plus nickel diet), and MDN (methionine deficiency plus nickel diet) treatment groups. Their renal function, histological changes, cell cycle, apoptosis, oxidative damage, and NF-κB inflammatory cytokines were detected after 21days by HE, immunohistochemistry, TUNEL staining, and biochemical and ELISA methods. The results showed that serum Cr, BUN, and the NAG content increased in MDN (P < 0.01), MN (P < 0.05), and MD (P < 0.05) group mice compared to BC group mice. Glomerulus atrophy and renal tubular atrophy were observed in the MDN, MN, and MD groups but less severe in MN group mice. The PCNA protein content was the highest in BC group mice followed by MD, MN, and MDN. The activities of antioxidant enzymes (SOD, CAT, GSH, GSH-Px, and GSH-ST) were lower significantly in MD, MN, and MDN group mice, and the oxidant products content (MDA, LPO, and ROS) in the BC group were higher than those in other groups with a similar trend. The contents of NF-κB, TNF-α, IFN-γ, IL-1a, and IL-6 in the BC group were found to increase significantly in MD, MN, and MDN groups. In conclusion, Ni-induced kidney injury was indicated by renal tissue and cell damage, increased kidney metabolism products release in the serum, and renal oxidative stress while methionine addition helped alleviate the injury. In addition, the NF-κB signal pathway was involved in the renal inflammatory reaction induced by Ni where methionine helped mitigate it.

403 Impact of lysine, methionine, and histidine deficiencies on gene expression and upstream transcriptional regulators in bovine mammary epithelial cells: An RNA-sequencing analysis

Abstract Essential (E) amino acids (AA) may alter bovine mammary epithelial cell functions by impacting mRNA expression of genes through their upstream transcription factors. The objective of this research was to study the impact of EAA deficiencies on gene expression and to identify upstream transcriptional factors mediating their effects in bovine mammary epithelial cells. Epithelial cells were collected from the mammary glands of lactating dairy cows and cultured in combined media of DMEM/F12 and Medium 170, differentiated for 5 d, and subsequently treated in triplicate for 60 h with a control medium containing all EAA at normal plasma concentrations for cows (CTL), or a medium with 20 μM Lys (LY), 5 μM Met (LM), or 10 μM His (LH), which are each 25% of normal concentration. RNA was isolated from the cells and sequenced on an Illumina NovaSeq 6000 producing 150 base pair paired-end reads with a minimum sequencing depth of 150 million reads. Reads were cleaned with ‘fastp’ (Chen et al., 2018), aligned to the bovine reference genome (ARS-UCD1.2) using ‘STAR’ aligner (Dobin et al., 2013), and genes counted using ‘featureCounts’ (Liao et al., 2014). Differential expression of genes between treatment pairs was determined using the ‘DESeq2’ package (Love et al., 2014) in R. Genes with an absolute log2 fold change ≥ 1 and a false discovery rate of &amp;lt; 0.05 were considered differentially expressed. The number of differentially expressed genes relative to CTL was 780 for LY, 383 for LH, and 536 for LM. QIAGEN Ingenuity Pathway Analysis (IPA) identified four pathways consistently affected across LY, LM, and LH: kinetochore metaphase signaling, mitotic roles of polo-like kinase, cell cycle: G2/M DNA damage checkpoint regulation, and interferon signaling (Figure 1-3). Notably, the kinetochore metaphase signaling pathway was identified as the most significant across all treatments, suggesting a strong link to cell proliferation and apoptosis during EAA deficiency. The interferon signaling might be related to the Janus kinase 2/signal transducer and activator of transcription 5 (Jak2/STAT5) pathway which can promote the expression of genes encoding milk proteins such as β-casein and β-lactoglobulin. Furthermore, the IPA identified upstream transcription factors related to cell proliferation, apoptosis, autophagy, protein translation, endoplasmic reticulum biogenesis, and amino acid metabolism including NUPR1, FOXM1, MYC, CCND1, TP53, DDIT3, and ATF4 across all treatments. The findings suggest that AA deprivation regulates bovine mammary epithelial cell function by instigating amino acid response pathways and altering secretory cell number.

Methionine deficiency inhibited pyroptosis in primary hepatocytes of grass carp (Ctenopharyngodon idella): possibly via activating the ROS-AMPK-autophagy axis

BackgroundMethionine (Met) is the only sulfur-containing amino acid among animal essential amino acids, and methionine deficiency (MD) causes tissue damage and cell death in animals. The common modes of cell death include apoptosis, autophagy, pyroptosis, necroptosis. However, the studies about the major modes of cell death caused by MD have not been reported, which worth further study.MethodsPrimary hepatocytes from grass carp were isolated and treated with different doses of Met (0, 0.5, 1, 1.5, 2, 2.5 mmol/L) to examine the expression of apoptosis, pyroptosis, autophagy and necroptosis-related proteins. Based on this, we subsequently modeled pyroptosis using lipopolysaccharides and nigericin sodium salt, then autophagy inhibitors chloroquine (CQ), AMP-activated protein kinase (AMPK) inhibitors compound C (CC) and reactive oxygen species (ROS) scavengers N-acetyl-L-cysteine (NAC) were further used to examine the expression of proteins related to pyroptosis, autophagy and AMPK pathway in MD-treated cells respectively.ResultsMD up-regulated B-cell lymphoma protein 2 (Bax), microtubule-associated protein 1 light chain 3 II (LC3 II), and down-regulated the protein expression levels of B-cell lymphoma-2 (Bcl-2), sequestosome 1 (p62), cleaved-caspase-1, cleaved-interleukin (IL)-1β, and receptor-interacting protein kinase (RIP) 1 in hepatocytes, while it did not significantly affect RIP3. In addition, MD significantly increased the protein expression of liver kinase B1 (LKB1), p-AMPK, and Unc-51-like kinase 1 (ULK1) without significant effect on p-target of rapamycin. Subsequently, the use of CQ increased the protein expression of NOD-like receptor thermal protein domain associated protein 3 (NLRP3), cleaved-caspase-1, and cleaved-IL-1β inhibited by MD; the use of CC significantly decreased the protein expression of MD-induced LC3 II and increased the protein expression of MD-suppressed p62; then the use of NAC decreased the MD-induced p-AMPK protein expression.ConclusionMD promoted autophagy and apoptosis, but inhibited pyroptosis and necroptosis. MD inhibited pyroptosis may be related regarding the promotion of autophagy. MD activated AMPK by inducing ROS production which in turn promoted autophagy. These results could provide partial theoretical basis for the possible mechanisms of Met in ensuring the normal structure and function of animal organs. Furthermore, ferroptosis is closely related to redox states, it is worth investigating whether MD affects ferroptosis in hepatocytes.

Alleviating effect of methionine on intestinal mucosal injury induced by heat stress

Climate change is an increasing concern of stakeholders worldwide. The intestine is severely impacted by the heat stress. This study aimed to investigate the alleviating effects of methionine on the intestinal damage induced by heat stress in mice. The mice were divided into four groups: control group (C), methionine deficiency group (MD), methionine + heat stress group (MH), and methionine deficiency + heat stress group (MDH). Histopathological techniques, PAS-Alcian blue staining, immunohistochemistry method, biochemical quantification method, ELISA, and micro method were used to study the changes in the intestinal mucosal morphology, the number of goblet cells, the expression of tight junction proteins, the peroxide product contents and antioxidant enzyme activities, the intestinal mucosal damage, the content of immunoglobulins and HSP70, the activity of Na+/K+-ATPase. The results showed that methionine can improve intestinal mucosal morphology (increase the villi height, V/C value, and muscle layer thickness, decrease crypt depth), increase the expression of tight junction proteins (Claudin-1, Occludin, ZO-1) and the content of DAO, decrease the content of intestinal mucosa damage markers (ET, FABP2) and peroxidation products (MDA), increase the activity of antioxidant enzymes (GR, GSH-Px, SOD), the number of goblet cells, the contents of immunoglobulins (sIgA, IgA, IgG, IgM) and stress protein (HSP70), and the activity of Na+/K+-ATPase. It is suggested that methionine can alleviate intestinal damage in heat-stressed mice.

Deprivation of methionine inhibits osteosarcoma growth and metastasis via C1orf112-mediated regulation of mitochondrial functions

Osteosarcoma is a malignant bone tumor that primarily inflicts the youth. It often metastasizes to the lungs after chemotherapy failure, which eventually shortens patients’ lives. Thus, there is a dire clinical need to develop a novel therapy to tackle osteosarcoma metastasis. Methionine dependence is a special metabolic characteristic of most malignant tumor cells that may offer a target pathway for such therapy. Herein, we demonstrated that methionine deficiency restricted the growth and metastasis of cultured human osteosarcoma cells. A genetically engineered Salmonella, SGN1, capable of overexpressing an L-methioninase and hydrolyzing methionine led to significant reduction of methionine and S-adenosyl-methionine (SAM) specifically in tumor tissues, drastically restricted the growth and metastasis in subcutaneous xenograft, orthotopic, and tail vein-injected metastatic models, and prolonged the survival of the model animals. SGN1 also sharply suppressed the growth of patient-derived organoid and xenograft. Methionine restriction in the osteosarcoma cells initiated severe mitochondrial dysfunction, as evident in the dysregulated gene expression of respiratory chains, increased mitochondrial ROS generation, reduced ATP production, decreased basal and maximum respiration, and damaged mitochondrial membrane potential. Transcriptomic and molecular analysis revealed the reduction of C1orf112 expression as a primary mechanism underlies methionine deprivation-initiated suppression on the growth and metastasis as well as mitochondrial functions. Collectively, our findings unraveled a molecular linkage between methionine restriction, mitochondrial function, and osteosarcoma growth and metastasis. A pharmacological agent, such as SGN1, that can achieve tumor specific deprivation of methionine may represent a promising modality against the metastasis of osteosarcoma and potentially other types of sarcomas as well.

Fat and proteolysis due to methionine, tryptophan, and niacin deficiency leads to alterations in gut microbiota and immune modulation in inflammatory bowel disease.

Inflammatory bowel disease (IBD) is one of the intractable diseases. Nutritional components associated with IBD have been identified, and it is known that excessive methionine intake exacerbates inflammation, and that tryptophan metabolism is involved in inflammation. Analysis of the gut microbiota has also progressed, where Lactobacillus regulate immune cells in the intestine and suppress inflammation. However, whether the methionine and tryptophan metabolic pathways affect the growth of intestinal Lactobacillus is unknown. Here we show how transient methionine, tryptophan, and niacin deficiency affects the host and gut microbiota in mouse models of colitis (induced by dextran sodium sulfate) fed a methionine-deficient diet (1K), tryptophan and niacin-deficient diet (2K), or methionine, tryptophan, and niacin-deficient diet (3K). These diets induced body weight decrease and 16S rRNA analysis of mouse feces revealed the alterations in the gut microbiota, leading to a dramatic increase in the proportion of Lactobacillus in mice. Intestinal RNA sequencing data confirmed that the expression of several serine proteases and fat-metabolizing enzymes were elevated in mice fed with methionine, tryptophan, and niacin (MTN) deficient diet. In addition, one-carbon metabolism and peroxisome proliferator-activated receptor (PPAR) pathway activation were also induced with MTN deficiency. Furthermore, changes in the expression of various immune-related cytokines were observed. These results indicate that methionine, tryptophan, and niacin metabolisms are important for the composition of intestinal bacteria and host immunity. Taken together, MTN deficiencies may serve as a Great Reset of gut microbiota and host gene expression to return to good health.

Non-alcoholic fatty liver disease changes the expression and activity of hepatic drug-metabolizing enzymes and transporters in rats

Non-alcoholic fatty liver disease (NAFLD) is one of the most common liver diseases, which can cause serious complications and gradually increase the mortality rate. However, the effects of NAFLD on drug-metabolizing enzymes and transporters remain unclear, which may cause some confusion regarding patient medication. In this study, a NAFLD rat model was constructed by feeding rats with methionine and choline deficiency diets for 6 weeks, and the mRNA and protein levels of drug-metabolizing enzymes and transporter were analyzed by real-time fluorescent quantitative PCR and Western blot, respectively. The activity of drug-metabolizing enzymes was detected by cocktail methods. In the NAFLD rat model, the mRNA expression of phase I enzymes, phase II enzymes, and transporters decreased. At the protein level, only CYP1A1, CYP1B1, CYP2C11, and CYP2J3 presented a decrease. In addition, the activities of CYP1A2, CYP2B1, CYP2C11, CYP2D1, CYP3A2, UGT1A1, UGT1A3, UGT1A6, and UGT1A9 decreased. These changes may be caused by the alteration of FXR, HNF4α, LXRα, LXRβ, PXR, and RXR. In conclusion, NAFLD changes the expression and activity of hepatic drug-metabolizing enzymes and transporters in rats, which may affect drug metabolism and pharmacokinetics. In clinical medication, drug monitoring should be strengthened to avoid potential risks.

Multitissue transcriptomics demonstrates the systemic physiology of methionine deficiency in broiler chickens

Methionine (Met) supplementation is common practice in broilers to support nutrition, yet there are gaps in the understanding of its role in systemic physiology. Furthermore, several different Met sources are available that may have different physiological effects. This study evaluated the mode of action of Met deficiency (no Met-supplementation) and supplementation (0.25% DL- or L-Met, 0.41% liquid methionine hydroxy analog-free acid (MHA-FA)), and of Met source (DL-, L- or MHA-FA) in broiler chickens, via host transcriptomics. Biological pathway activation modeling was performed to predict the likely phenotypic effects of differentially expressed genes (DEGs) in tissue samples from the jejunum, liver and breast obtained at 10, 21 and 34/35 d of age from three experiments in a combined analysis. Animal performance data showed that Met deficiency reduced BW, daily BW gain, daily feed intake, and breast yield, and increased feed conversion ratio in all experiments (P < 0.05). Effects of Met deficiency on gene expression were least evident in the jejunum and most evident in the liver and breast, as evidenced by the number of DEG and activated pathways. Activated pathways suggested Met deficiency was associated with inhibited protein turnover, gut barrier integrity, and adaptive immunity functions in the jejunum, that predicted reduced breast yield. There was an interaction with age; in Met-deficient birds, there were 333 DEGs in the jejunum of starter vs finisher birds suggesting young birds were more sensitive to Met deficiency than older birds. In the liver, Met deficiency activated pathways associated with lipid turnover, amino acid metabolism, oxidative stress, and the immune system, whereas in breast, it activated pathways involved in metabolic regulation, hemostasis, the neuronal system, and oxidative stress, again predicting a negative impact on breast yield. In the starter phase, supplementation with DL-Met compared to MHA-FA inhibited gamma-aminobutyric acid activity and oxidative stress in breast tissue. When data from all tissues were integrated, increased expression of a liver gene (ENSGALG00000042797) was found to be correlated with the expression of several genes that best explained variation due to the Met deficiency in jejunum and breast muscle. Some of these genes were involved in anti-oxidant systems. Overall, the findings indicate that impaired growth performance due to Met deficiency results from an array of tissue-specific molecular mechanisms in which oxidative stress plays a key systemic role. Young birds are more sensitive to Met-deficiency and DL-Met was a preferential source of Met than L- or MHA-FA during the starter phase.

Salmonella-mediated methionine deprivation drives immune activation and enhances immune checkpoint blockade therapy in melanoma

BackgroundAlthough immune checkpoint inhibitor (ICI)-based therapy is advantageous for patients with advanced melanoma, resistance and relapse are frequent. Thus, it is crucial to identify effective drug combinations and develop new...

Unraveling the role of δ‐zeins in methionine bio‐fortification of maize

AbstractBackground and ObjectivesMaize is a major ingredient of animal feed. However, its nutritional quality is poor due to the deficiency of essential amino acid methionine. The animal feed, prepared as a corn–legume mixture to balance the nutritional quality, remains deficient in methionine. Therefore, the bio‐fortification of maize for methionine is the best option to make nutritionally balanced animal and poultry feed. The present study was designed to evaluate the profile of zeins and the expression profile of methionine‐associated target genes in high‐ and low‐methionine maize.FindingsResults of sodium dodecyl sulfate‐polyacrylamide gel electrophoresis revealed that the 10‐kDa zein was accumulated during kernel development, and its accumulation was higher in high methionine lines. Gene expression analysis through real‐time polymerase chain reaction revealed that higher expression of 10‐ and 18‐kDa zeins is associated with higher methionine accumulation.ConclusionsThe above results indicate that 10‐ and 18‐kDa genes are the potential targets for the methionine bio‐fortification in maize, which is required for animal and poultry feed.Significance and NoveltyThe present study suggests that 10‐ and 18‐kDa genes are the major source of methionine, and the regulation of these genes is crucial to enhancing the methionine content in maize. The results indicate that these genes are potential targets for genetic engineering in maize to enhance methionine accumulation.

Homocysteine, hyperhomocysteinemia, and H-type hypertension.

Homocysteine (Hcy) is a sulphur-containing nonessential amino acid derived from the intermediate metabolites of methionine. Methionine is obtained from dietary proteins, such as poultry, meat, eggs, seafood, and dairy products. Abnormalities in Hcy metabolic pathways, deficiencies in dietary methionine, folate, and vitamins B12, B6, and B2 and genetic defects, polymorphisms, or mutations in Hcy metabolism-related enzymes may lead to an increase in plasma Hcy levels. Generally, a plasma Hcy level higher than 10 or 15 μmol/L has been defined as hyperhomocysteinemia (HHcy). An individual with essential hypertension complicated with HHcy is considered to have H-type hypertension (HTH). Currently, HHcy is considered a novel independent risk factor for various cardiovascular diseases. To provide a useful reference for clinicians, the research progress on Hcy, HHcy, and HTH in recent years was systematically reviewed here, with a focus on the source and metabolic pathways of Hcy, plasma Hcy levels and influencing factors, detection methods for plasma Hcy levels, relationship between Hcy concentration and hypertension, pathogenesis of HTH, cardiovascular complications of HTH, and treatment of HTH.

Retraction: Methionine-CBS axis promotes intracellular ROS levels by reprogramming serine metabolism.

Retraction: Chen J, Cui X, Fang N, Wu Y, Yu S, Xiao D. Methionine-CBS axis promotes intracellular ROS levels by reprogramming serine metabolism. FASEB J. 2023;37:e23268. https://doi.org/10.1096/fj.202300804RRRR. The above article, published online on 27 October 2023 in Wiley Online Library (wileyonlinelibrary.com), has been retracted by agreement between the authors, the journal Editor-in-Chief, Loren E. Wold, the Federation of American Societies for Experimental Biology, and Wiley Periodicals LLC. The retraction has been agreed upon per the authors' request to retract the article, as they found that the data presented in Figure3 are insufficient to support one of the key conclusions of the paper, that methionine deficiency alters the flow of serine metabolism. The authors apologize for the oversight.

Effects of methionine deficiency on B7H3-DAP12-CAR-T cells in the treatment of lung squamous cell carcinoma

Lung squamous cell carcinoma (LUSC) is a subtype of lung cancer for which precision therapy is lacking. Chimeric antigen receptor T-cells (CAR-T) have the potential to eliminate cancer cells by targeting specific antigens. However, the tumor microenvironment (TME), characterized by abnormal metabolism could inhibit CAR-T function. Therefore, the aim of this study was to improve CAR-T efficacy in solid TME by investigating the effects of amino acid metabolism. We found that B7H3 was highly expressed in LUSC and developed DAP12-CAR-T targeting B7H3 based on our previous findings. When co-cultured with B7H3-overexpressing LUSC cells, B7H3-DAP12-CAR-T showed significant cell killing effects and released cytokines including IFN-γ and IL-2. However, LUSC cells consumed methionine (Met) in a competitive manner to induce a Met deficiency. CAR-T showed suppressed cell killing capacity, reduced cytokine release and less central memory T phenotype in medium with lower Met, while the exhaustion markers were up-regulated. Furthermore, the gene NKG7, responsible for T cell cytotoxicity, was downregulated in CAR-T cells at low Met concentration due to a decrease in m5C modification. NKG7 overexpression could partially restore the cytotoxicity of CAR-T in low Met. In addition, the anti-tumor efficacy of CAR-T was significantly enhanced when co-cultured with SLC7A5 knockdown LUSC cells at low Met concentration. In conclusion, B7H3 is a prospective target for LUSC, and B7H3-DAP12-CAR-T cells are promising for LUSC treatment. Maintaining Met levels in CAR-T may help overcome TME suppression and improve its clinical application potential.

Effects of Methionine Deficiency on Nutrient Composition, No, Nos Activity and Mrna Expression in Nf-κb Signal Pathway of the Liver and Kidney in Broiler

Effects of Methionine Deficiency on Nutrient Composition, No, Nos Activity and Mrna Expression in Nf-κb Signal Pathway of the Liver and Kidney in Broiler

Methionine sources at different dietary levels alters the growth and expression of genes related to homocysteine remethylation in the jejunum of broilers.

Sulfur amino acids are essential for the proper development of broilers and are required throughout the bird's life to perform important physiological functions. Studies that seek to understand the actions of sulfur amino acids in the body of birds are essential. The present study evaluated the influence of sulfur amino acid supplementation using DL-Methionine (DL-Met) and DL-Methionine hydroxy analogue (DL-HMTBA), on the performance and expression of genes related to methionine metabolism, in the jejunum of broilers. Four hundred and fifty male broilers (Cobb-700 slow feathering) were distributed in a completely randomized design, in a factorial scheme (2x3), with two sources of methionine (DL-Met and DL-HMTBA) and three levels of methionine (deficiency, requirement and excess). The mRNA expression of the MAT1, MTR, BHMT, MTRR, CBG and GSS genes, and performance data such as feed intake, weight gain, and feed conversion were evaluated. DL-HMTBA increased the expression of BHMT (p = 0.0072) and MTRR (p = 0.0003) in the jejunum of the birds. Methionine deficiency increased the expression of BHMT (p = 0.0805) and MTRR (p = 0.0018). Higher expression of GSS was observed in birds that were supplemented with DL-HMTBA (p = 0.0672). Analyzing our results, it is preferable to supplement sulfur amino acids with DL-Met at the requirement level. Birds fed with DL-HMTBA showed worse weight gain (p = 0.0117) and higher feed conversion (p = 0.0170); methionine deficiency resulted in higher feed intake (p = 0.0214), lower weight gain (p<0.0001) and consequently higher feed conversion (p<0.0001). Based on the information found in this work, it is recommended to supplement sulfur amino acids with DL-Met at the level of compliance with the requirement.

Effects of different levels of methionine in pre-starter diets on immunity function and DNA methylation in broilers

The study was carried out to determine the effects of different levels of methionine in Pre-starter diets on PPAR gene expression and immune function of broiler chickens. Methionine (Met) is necessary to achieve a fast growth rate in chickens. A total of 240 Ross 308 broilers were equally assigned to 8 treatments with 3 replicates. The treatments included T1: diet with 20% methionine less than Ross catalog recommendation. T2: Standard diet in accordance with the recommendations of the Ross catalog. T3, T4, T5, T6, T7 and T8: diets with 20, 40, 60, 80, 100 and 120 % methionine more than Ross catalog recommendation. The results showed that there was a significant difference in the expression of PPAR gene with the difference in diet methionine levels in the 8 groups. PPAR controls the expression of several genes involved in the proliferation and differentiation of adipose tissue cells. Gene expression in broiler chickens with methionine deficiency and excess may have compensated for this deficiency and excess in the birds. Also, the results indicated that increasing in the levels of methionine in Pre-starter diets of chickens the antibody production against ND increased significantly (P&lt;0.05). Besides, the antibody production against IBD increased significantly (P&lt;0.05). Furthermore, the antibody production against H9N1 not affected (P&gt;0.05). Studies suggest that dietary protein deficiency reduces the concentration of most amino acids in plasma and compromises the immune system. Totally it is suggested that the high levels of Met in the diet maybe beneficial and it needs more studies.

Safety and Feasibility of the Addition of a Radiosensitizing Methionine-Restricted Diet to Radiation Therapy

Methionine is an amino acid necessary for numerous processes critical for cell growth and survival. While normal cells can tolerate methionine deficiency, most cancer cells are methionine auxotrophs, requiring dietary intake since they cannot synthesize it. In vitro, methionine deficiency causes cancer cells to undergo cell cycle arrest and cell death, and in vivo a methionine restricted diet (MRD) enhances radiosensitization without significant adverse effects. Combining a MRD and radiation therapy (RT) to treat human malignancies has never been evaluated. The hypothesis of this Phase I study was that a MRD would be safe, and feasible to administer concurrently with curative-intent RT. Eligible patients included adults with any non-skin cancer malignancy undergoing standard radiation therapy without concurrent cytotoxic chemotherapy. The MRD consisted of low-protein cereals, grains, and breads; fruits; vegetables; margarines and oils; and simple carbohydrates. A clinical dietician developed a personalized meal plan with each subject to reduce methionine consumption to 5-10 mg/kg body weight/day, while maintaining adequate protein and caloric intake. An unlimited supply of a commercially available methionine-free protein supplement was provided to minimize hunger and weight loss. The MRD extended from 2 weeks before initiation of RT, through 2 weeks beyond completion of RT. The primary endpoint for safety was the rate of grade 3 or higher acute and late toxicities per CTCAE, over 12 months follow-up. Feasibility was assessed with a biweekly quantitative plasma amino acid panel during the MRD. The target accrual was 15 subjects. Over two years, 53 patients were offered enrollment, 9 subjects enrolled, 5 completed the MRD and RT, and 4 withdrew during the MRD. The table summarizes subjects' characteristics and outcomes. There was no grade 3 or higher adverse events attributable to the MRD. Methionine plasma levels varied over the course of treatment, and while no subject achieved the target of 13 μM, two nadired at 14 μM. The trial was closed early due to slow accrual and subjects' difficulty maintaining the diet. This study suggests a MRD is safe with thoracic or abdominopelvic RT, with toxicities comparable to those expected with RT alone. However, the diet was challenging, and unacceptable to most patients with cancer.

Digestible methionine plus cystine requirement in tambaqui (Colossoma macropomum) diets: Growth performance and plasma biochemistry

Most animals require methionine as an indispensable amino acid in their dietary protein, the normal growth of animals being affected by any deficiency or excess of methionine and cystine in the diet. The current study aimed to determine the digestible methionine plus cystine requirement in diets for tambaqui (Colossoma macropomum). A total of 288 tambaqui with an initial body weight of 54.53 ± 0.15 g were used in a dose-response experiment with five levels of digestible methionine plus cystine (0.400; 0.600; 0.800; 1.000; 1.200 %) and four replicates per treatment. The results showed that increasing the dietary digestible methionine plus cystine level influenced all growth performance variables evaluated in the study, except feed intake. Methionine plus cystine intake increased linearly (P < 0.05). Quadratic effects on weight gain, specific growth rate, and feed conversion ratio were observed, with estimated requirements being 0.876 %, 0.883 % and 0.907 % of digestible methionine plus cystine, respectively. The deposition of body protein, body fat, and body ash also showed a quadratic response with requirements estimated at 0.920 %, 1.124 % and 0.879 % of digestible methionine plus cystine, respectively. The methionine plus cystine levels evaluated influenced plasma biochemistry, except glucose. The requirement for digestible methionine plus cystine in the diet for tambaqui was determined as 0.920 % (0.297 g/Mcal of digestible energy), as it allows greater deposition of body protein.

Methionine deficiency affects myogenesis and muscle macronutrient metabolism in juvenile turbot Scophthalmus maximus

The study was aimed to explore the impacts of dietary methionine availability on muscle growth and macronutrient metabolism in turbot. Based the optimal dietary methionine requirement, three isonitrogenous and isolipidic diets with different methionine levels (0.91%, 1.90%, and 2.90%) were formulated. 270 fish (average weight 7.40 ± 0.01 g) were distributed into 9 fiberglass tanks and fed for 10 weeks. Results showed that methionine deprivation significantly depressed fish growth and reduced the crude protein content in the whole body and muscle. Methionine deprivation inhibited the expression of myogenic differentiation antigen D (myoD), myogenin and myosin light chain (mlc) while induced myostatin expression. Methionine deficiency inhibited the mechanistic target of rapamycin (mTOR) pathway and activated the autophagy-lysosomal and ubiquitin–proteasome systems. The AMP-activated protein kinase (AMPK) was activated and uncoupling protein 1 (ucp1) was up-regulated when dietary methionine was deficient. Meanwhile, methionine deficiency reduced total free amino acid content, promoted the catabolism of amino acid, and improved the flux of tricarboxylic acid cycle (acetyl-CoA, fumarate, malate, and oxoglutarate). Methionine deficiency depressed the glycolysis and lipogenesis processes, while elevated fatty acid β-oxidation, which shifted the fuel utilization in muscle. Excess methionine intake did not further modulate the cell signaling and metabolism in muscle. Our results provide new clues on the involvement of dietary methionine on muscle growth and metabolic responses in teleost.

Ingestion of mycoprotein, pea protein, and their blend support comparable postexercise myofibrillar protein synthesis rates in resistance-trained individuals.

Pea protein is an attractive nonanimal-derived protein source to support dietary protein requirements. However, although high in leucine, a low methionine content has been suggested to limit its anabolic potential. Mycoprotein has a complete amino acid profile which, at least in part, may explain its ability to robustly stimulate myofibrillar protein synthesis (MyoPS) rates. We hypothesized that an inferior postexercise MyoPS response would be seen following ingestion of pea protein compared with mycoprotein, which would be (partially) rescued by blending the two sources. Thirty-three healthy, young [age: 21 ± 1 yr, body mass index (BMI): 24 ± 1 kg·m-2] and resistance-trained participants received primed, continuous infusions of l-[ring-2H5]phenylalanine and completed a bout of whole body resistance exercise before ingesting 25 g of protein from mycoprotein (MYC, n = 11), pea protein (PEA, n = 11), or a blend (39% MYC, 61% PEA) of the two (BLEND, n = 11). Blood and muscle samples were taken pre-, 2 h, and 4 h postexercise/protein ingestion to assess postabsorptive and postprandial postexercise myofibrillar protein fractional synthetic rates (FSRs). Protein ingestion increased plasma essential amino acid and leucine concentrations (time effect; P < 0.0001), but more rapidly in BLEND and PEA compared with MYC (time × condition interaction; P < 0.0001). From similar postabsorptive values (MYC, 0.026 ± 0.008%·h-1; PEA, 0.028 ± 0.007%·h-1; BLEND, 0.026 ± 0.006%·h-1), resistance exercise and protein ingestion increased myofibrillar FSRs (time effect; P < 0.0001) over a 4-h postprandial period (MYC, 0.076 ± 0.004%·h-1; PEA, 0.087 ± 0.01%·h-1; BLEND, 0.085 ± 0.01%·h-1), with no differences between groups (all; P > 0.05). These data show that all three nonanimal-derived protein sources have utility in supporting postexercise muscle reconditioning.NEW & NOTEWORTHY This study provides evidence that pea protein (PEA), mycoprotein (MYC), and their blend (BLEND) can support postexercise myofibrillar protein synthesis rates following a bout of whole body resistance exercise. Furthermore, these data suggest that a methionine deficiency in pea may not limit its capacity to stimulate an acute increase in muscle protein synthesis (MPS).