Dietary and homeostatic controls of Zn isotopes in rats: a controlled feeding experiment and modeling approach.

IF 2.9 3区 生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY
Metallomics Pub Date : 2024-06-04 DOI:10.1093/mtomcs/mfae026
Nicolas Bourgon, Théo Tacail, Klervia Jaouen, Jennifer N Leichliter, Jeremy McCormack, Daniela E Winkler, Marcus Clauss, Thomas Tütken
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引用次数: 0

Abstract

The stable isotope composition of zinc (δ66Zn), which is an essential trace metal for many biological processes in vertebrates, is increasingly used in ecological, archeological, and paleontological studies to assess diet and trophic level discrimination among vertebrates. However, the limited understanding of dietary controls and isotopic fractionation processes on Zn isotope variability in animal tissues and biofluids limits precise dietary reconstructions. The current study systematically investigates the dietary effects on Zn isotope composition in consumers using a combined controlled feeding experiment and box-modeling approach. For this purpose, 21 rats were fed one of seven distinct animal- and plant-based diets and a total of 148 samples including soft and hard tissue, biofluid, and excreta samples of these individuals were measured for δ66Zn. Relatively constant Zn isotope fractionation is observed across the different dietary groups for each tissue type, implying that diet is the main factor controlling consumer tissue δ66Zn values, independent of diet composition. Furthermore, a systematic δ66Zn diet-enamel fractionation is reported for the first time, enabling diet reconstruction based on δ66Zn values from tooth enamel. In addition, we investigated the dynamics of Zn isotope variability in the body using a box-modeling approach, providing a model of Zn isotope homeostasis and inferring residence times, while also further supporting the hypothesis that δ66Zn values of vertebrate tissues are primarily determined by that of the diet. Altogether this provides a solid foundation for refined (paleo)dietary reconstruction using Zn isotopes of vertebrate tissues.

大鼠体内锌同位素的膳食和体内平衡控制:控制进食实验和建模方法。
锌(δ66Zn)是脊椎动物许多生物过程中不可或缺的微量金属,其稳定同位素组成越来越多地用于生态学、考古学和古生物学研究,以评估脊椎动物的膳食和营养级区分。然而,对动物组织和生物流体中锌同位素变异的膳食控制和同位素分馏过程的了解有限,限制了精确的膳食重建。本研究采用控制喂养实验和箱式建模相结合的方法,系统地研究了膳食对消费者体内锌同位素组成的影响。为此,研究人员给 21 只大鼠喂食了七种不同的动物性和植物性膳食中的一种,并对这些大鼠的软组织、硬组织、生物流体和排泄物等共计 148 个样本进行了 δ66Zn 测量。在不同的食物组别中,每种组织类型的锌同位素分馏相对稳定,这意味着食物是控制消费者组织δ66Zn值的主要因素,而与食物组成无关。此外,我们首次报道了系统的δ66Zn膳食-牙釉质分馏,从而能够根据牙釉质中的δ66Zn值重建膳食。此外,我们还利用盒式建模方法研究了体内锌同位素变异的动态变化,提供了一个锌同位素平衡模型,并推断了停留时间,同时也进一步支持了脊椎动物组织的δ66Zn值主要由饮食决定的假说。总之,这为利用脊椎动物组织的锌同位素进行精细的(古)膳食重建奠定了坚实的基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Metallomics
Metallomics 生物-生化与分子生物学
CiteScore
7.00
自引率
5.90%
发文量
87
审稿时长
1 months
期刊介绍: Global approaches to metals in the biosciences
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