The level and source of free-methionine affect body composition and breast muscle traits in growing broilers1

Conde-Aguilera, Jose Alberto; Cholet, Juliette; Lessire, Michel; Mercier, Yves; Tesseraud, Sophie; Milgen, J. van

doi:10.3382/ps/pew105

Cited by 30 publications

(25 citation statements)

References 54 publications

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“…The results from the current study show that there is a relationship between dietary Met and growth and this was consistent with previous studies (Conde‐Aguilera et al., ; Garber & Baker, ; Lepore, ). When birds were fed suboptimal dietary Met levels, growth significantly declined.…”

Section: Discussionsupporting

confidence: 93%

Gene expression differences in the methionine remethylation and transsulphuration pathways under methionine restriction and recovery with D,L‐methionine or D,L‐HMTBA in meat‐type chickens

Aggrey

González-Cerón

Rekaya

et al. 2017

Animal Physiology Nutrition

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SummaryThis study examined the molecular mechanisms of methionine pathways in meat-type chickens where birds were provided with a diet deficient in methionine from 3 to 5 weeks of age. The birds on the deficient diet were then provided with a diet supplemented with either D,L-methionine or D,L-HMTBA from 5 to 7 weeks. The diet of the control birds was supplemented with L-methionine from hatch till 7 weeks of age.We studied the mRNA expression of methionine adenosyltransferase 1, alpha, methionine adenosyltransferase 1, beta, 5-methyltetrahydrofolate-homocysteine methyltransferase, 5-methyltetrahydrofolate-homocysteine methyltransferase reductase, betaine-homocysteine S-methyltransferase, glycine N-methyltransferase, S-adenosyl-L-homocysteine hydrolase and cystathionine beta synthase genes in the liver, duodenum, Pectoralis (P.) major and the gastrocnemius muscle at 5 and 7 weeks. Feeding a diet deficient in dietary methionine affected body composition. Birds that were fed a methionine-deficient diet expressed genes that indicated that remethylation occurred via the one-carbon pathway in the liver and duodenum; however, in the P. major and the gastrocnemius muscles, gene expression levels suggested that homocysteine received methyl from both folate and betaine for remethylation. Birds who were switched from a methionine deficiency diet to one supplemented with either D,Lmethionine or D,L-HMTBA showed a downregulation of all the genes studied in the liver. However, depending on the tissue or methionine form, either folate or betaine was elicited for remethylation. Thus, mRNA expressions show that genes in the remethylation and transsulphuration pathways were regulated according to tissue need, and there were some differences in the methionine form.

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Section: Discussionsupporting

confidence: 93%

Gene expression differences in the methionine remethylation and transsulphuration pathways under methionine restriction and recovery with D,L‐methionine or D,L‐HMTBA in meat‐type chickens

Aggrey

González-Cerón

Rekaya

et al. 2017

Animal Physiology Nutrition

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“…In comparative study between MHA-Ca and MHA-FA in broiler chicks, the former exhibited higher methionine efficacy than the latter (Boebel and Baker 1982), although both forms were inferior to DLM. In contrast, equal bio-efficacy of MHA-FA (Elkin and Hester 1983;Liu et al 2006;Xi et al 2007;Swennen et al 2011;Conde-Aguilera et al 2016) or MHA-Ca (Bishop and Halloran 1977;Baker and Boebel 1980;Dilger and Baker 2008) compared with DLM has been also reported in broiler chicks. Nonetheless, it is common practice in feed industry to add MHA sources in the diets of chickens albeit that the bioavailability relative to DLM is still under controversy.…”

Section: Introductionmentioning

confidence: 98%

Effects of different methionine sources on growth performance, meat yield and blood characteristics in broiler chickens

Kim

et al. 2019

Journal of Applied Animal Research

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Three graded levels of MHA (methionine hydroxyl analogue) added into the broilers' diets were based on the assumption that the relative bioavailability of MHA sources to DL-methionine (DLM) on a molar basis was 100%, 90% or 80% to meet the requirement of total sulphur amino acids. DLM was used as the reference control group. Live body weight at 21 and 35 days was retarded (p < 0.05) in chicks fed a diet containing 100% equivalent MHA-FA (methionine hydroxyl analogue free acid) across dietary treatments. Chicks fed the diet containing MHA-Ca vs. MHA-FA grew faster at 35 days (p < 0.05). Chicks consumed least (p < 0.05) when 100% equivalent MHA-FA was added during 1-21 days. FCR was enhanced in MHA-Ca (methionine hydroxyl analogue calcium salt) vs. MHA-FA at all days measured. MHA effect on mortality, being higher (p < 0.05) in chicks on MHA-FA vs. MHA-Ca, was noted. Serum concentration of total cholesterol was lowest (p < 0.05) in chicks fed on DLM-added diet, but highest (p < 0.05) in those fed 100% equivalent MHA-Ca. Serum concentration of immunoglobulin A was low (p < 0.05) in chicks fed on 100% or 80% equivalent MHA-Ca compared with the rest of treatments. Collectively, MHA-Ca performed better than MHA-FA as to performance traits.

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“…But also feather structure and composition are age-dependent and individual morphological parts of fowl feathers show differences in AA composition [40] [48] [49] [50] [51]. In addition, also effects of diets deficient in branched chain AAs and methionine on AA content of the feather protein were reported [27] [43]. In case of deficient AA supply, feather protein synthesis is of superior priority [27] [52].…”

Section: Discussionmentioning

confidence: 99%

“…In addition, also effects of diets deficient in branched chain AAs and methionine on AA content of the feather protein were reported [27] [43]. In case of deficient AA supply, feather protein synthesis is of superior priority [27] [52].…”

Section: Discussionmentioning

confidence: 99%

“…Specifically, an age-dependent change of the whole body protein AA composition can be expected due to different allometric growth rates of individual body tissues and organs [7] [19] [20] [21]. Additionally, the dietary protein and AA supply can also impact on body AA composition [9] [10] [15] [22]- [27]. An increased accuracy in estimations of the adequate dietary AA supply could be achieved if substantial body protein fractions are initially investigated separately.…”

Section: Introductionmentioning

confidence: 99%

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Age and Gender Dependent Amino Acid Concentrations in the Feather, Feather-Free and Whole Empty Body Protein of Fast Growing Meat-Type Chickens

Wecke¹,

Khan²,

Sünder³

et al. 2018

OJAS

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Two consecutive growth experiments with meat-type chickens (Ross 308) were conducted in order to quantify the age-dependent amino acid (AA) content in the whole body protein of male and female birds based on experimental data of the feather and feather-free body protein fractions. Birds were reared under uniform housing and feeding conditions (floor pens, 15 pens per gender, 5 birds per pen) during the starter (day 1 to 22) and grower period (day 22 to 36). Both the starter and grower diet based on corn, wheat, soybean meal, soybean protein concentrate and feed amino acids was formulated to ensure an equal feed protein quality close to the ideal amino acid ratio by adjusting a constant mixture of the feed proteins. At start of the experiment and further on weekly up to the end of the 5 th week, 15 birds per gender (each 3 pens of 5 birds) were selected and fasted for 24 h, to emptying of gastro-intestinal tract, respectively. Subsequently, birds were euthanized and the feathers were manually removed. Nitrogen (N) and AA content were determined both in the feather and feather-free body fraction. The concentration of individual AAs in both of body protein fraction is varying considerably. Explicitly higher Cys, Ser and Pro but importantly lower Met, Lys and His concentrations were found in the feather protein. Furthermore, significant differences (p < 0.001) for nearly all AAs of the studied body protein fractions and the whole empty body protein dependent on age of birds were observed. Especially high deviations were obtained during the first week of age and at the end of the experiment. According to this observed variation of AA concentrations must be concluded that the body AA composition of meat-type chickens during growth is not constant. The detected gender-specific differ

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The level and source of free-methionine affect body composition and breast muscle traits in growing broilers1

Cited by 30 publications

References 54 publications

Gene expression differences in the methionine remethylation and transsulphuration pathways under methionine restriction and recovery with D,L‐methionine or D,L‐HMTBA in meat‐type chickens

Gene expression differences in the methionine remethylation and transsulphuration pathways under methionine restriction and recovery with D,L‐methionine or D,L‐HMTBA in meat‐type chickens

Effects of different methionine sources on growth performance, meat yield and blood characteristics in broiler chickens

Age and Gender Dependent Amino Acid Concentrations in the Feather, Feather-Free and Whole Empty Body Protein of Fast Growing Meat-Type Chickens

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