Early-life Conditioning Strategies to Reduce Dietary Phosphorus in Broilers: Underlying Mechanisms

Overview

Journal J Nutr Sci

Publisher Cambridge University Press

Specialty Nutritional Sciences

Date 2020 Aug 4

PMID 32742645

Citations 5

Authors

A S Valable

M P Letourneau-Montminy

S Klein

L Lardic

F Lecompte

S Metayer-Coustard

N Meme

G Page

M J Duclos

A Narcy

Affiliations

Soon will be listed here.

Abstract

Chickens adapt to P and Ca restriction during the very first days of life by improving P utilisation efficiency. The present study was built to identify the mechanisms underlying this adaptive capacity, and to identify the optimal window of application of the restriction (depletion). A total of 1600 Cobb 500 male broilers were used. During each phase (from age 0 to 4 d, 5 to 8 d, 9 to 18 d and 19 to 33 d), the animals received either a control diet (H) or a restricted diet (L) with reduced levels of non-phytate P (nPP) and Ca (between -14 and -25 % for both) with four dietary sequences: HHHH, HLHL, LHHL and LLHL. None of the feeding strategies affected growth. Tibia ash content at day 4 and 8 was impaired when the L diet was fed from 0 to 4 and 5 to 8 d, respectively ( = 0⋅038 and = 0⋅005). Whatever the early restriction period or length between 0 and 8 d of age, the mineralisation delay was compensated by day 18. This was accompanied by an increased mRNA expression of the Ca transporter, , and an increased apparent ileal digestibility of Ca at day 8 ( < 0⋅001). This adaptation was limited to the starter phase in restricted birds. No effect was seen on P transporters mRNA or protein expression. In conclusion, birds adapted to mineral restriction by increasing Ca and nPP utilisation efficiencies. Depletion-repletion strategies are promising in improving the sustainability of broiler production but need to be validated in phytase-supplemented diets.

Citing Articles

Long-Term Effects of Early Low-Phosphorous Nutritional Conditioning on Broiler Chicken Performance, Bone Mineralization, and Gut Health Under Adequate or Phosphorous-Deficient Diets.

Tous N, Francesch M, Tarradas J, Badiola I, Perez de Rozas A, Fabrega E Animals (Basel). 2024; 14(22).

PMID: 39595271 PMC: 11591060. DOI: 10.3390/ani14223218.

and Gene Expression in Kidneys and Their Involvement in Calcium and Phosphate Metabolism in Laying Hens.

Salmoria L, Ibelli A, Tavernari F, Peixoto J, Mores M, Marcelino D Animals (Basel). 2024; 14(10).

PMID: 38791624 PMC: 11117318. DOI: 10.3390/ani14101407.

SLC34A2 Targets in Calcium/Phosphorus Homeostasis of Mammary Gland and Involvement in Development of Clinical Mastitis in Dairy Cows.

Wang X, Zhang B, Dong W, Zhao Y, Zhao X, Zhang Y Animals (Basel). 2024; 14(9).

PMID: 38731279 PMC: 11083581. DOI: 10.3390/ani14091275.

Heat stress exposure cause alterations in intestinal microbiota, transcriptome, and metabolome of broilers.

Liu X, Ma Z, Wang Y, Jia H, Wang Z, Zhang L Front Microbiol. 2023; 14:1244004.

PMID: 37795292 PMC: 10547010. DOI: 10.3389/fmicb.2023.1244004.

Dietary Phosphorus and Calcium Utilization in Growing Pigs: Requirements and Improvements.

Lautrou M, Narcy A, Dourmad J, Pomar C, Schmidely P, Letourneau Montminy M Front Vet Sci. 2021; 8:734365.

PMID: 34901241 PMC: 8654138. DOI: 10.3389/fvets.2021.734365.

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