营养性微量金属元素的肠道吸收机制及相互作用研究进展

王海娃; 颜崇淮

doi:10.11852/zgetbjzz2021-0476

PDF(25309 KB)

中国儿童保健杂志 ›› 2021, Vol. 29 ›› Issue (10) : 1082-1086. DOI: 10.11852/zgetbjzz2021-0476

综述

营养性微量金属元素的肠道吸收机制及相互作用研究进展

王海娃, 颜崇淮

作者信息 +

Research progress on intestinal absorption mechanism and interaction of nutrient trace metal elements

WANG Hai-wa, YAN Chong-huai

Author information +

文章历史 +

摘要

人体内的营养性微量金属元素,主要依靠肠道吸收,在各种生命活动中起着非常重要的作用。本文总结了近年来铁、锌、铜、锰、钼、铬、钴等常见微量金属元素在肠道内吸收机制的研究进展,并探索元素吸收间的相互作用形式。金属元素在机体内通过吸收、分布、排泄维持稳态,整个过程都依赖机体的代谢调节。因此,影响微量金属元素在肠道吸收的因素,不仅是膳食中金属元素间的相互干扰,还包括金属元素的化学形态、金属元素间的比例、食物中其他与金属元素共存的成分、肠道菌群等,更重要的是机体状态。本文将在此基础上提出临床营养补充策略。

Abstract

The nutritive trace metal elements in the human body are mainly absorbed by the intestine and play a very important role in various life activities.This article summarizes the recent research progress in the intestinal absorption mechanism of common trace elements, such as iron, zinc, copper, manganese, molybdenum, chromium and cobalt, and explores the forms of interaction between element absorption.Metal elements in the body maintain a steady state through absorption, distribution and excretion, and the whole process requires the body′s overall metabolic regulation.Therefore, the factors that affect the absorption of trace metal elements in the intestine are not only the interference between the metal elements in the diet, but also the chemical form of the metal elements, the ratio of metal elements, other coexisting components in the food, and the intestinal flora, etc.More important is the state of the body.This article will propose clinical nutritional supplement strategies on this basis.

导出引用

王海娃, 颜崇淮. 营养性微量金属元素的肠道吸收机制及相互作用研究进展[J]. 中国儿童保健杂志. 2021, 29(10): 1082-1086 https://doi.org/10.11852/zgetbjzz2021-0476

WANG Hai-wa, YAN Chong-huai. Research progress on intestinal absorption mechanism and interaction of nutrient trace metal elements[J]. Chinese Journal of Child Health Care. 2021, 29(10): 1082-1086 https://doi.org/10.11852/zgetbjzz2021-0476

中图分类号： R151

参考文献

[1] Fuqua BK, Vulpe CD, Anderson GJ.Intestinal iron absorption[J].J Trace Elem Med Biol, 2012, 26(2-3):115-119.
[2] Maares M, Haase H.A guide to human zinc absorption:General overview and recent advances of in vitro intestinal models[J].Nutrients, 2020, 12(3):762.
[3] Nishito Y, Kambe T.Zinc transporter 1 (znt1) expression on the cell surface is elaborately controlled by cellular zinc levels[J].J Biol Chem, 2019, 294(43):15686-15697.
[4] Wang X, Flores SR, Ha JH, et al.Intestinal dmt1 is essential for optimal assimilation of dietary copper in male and female mice with iron-deficiency anemia[J].J Nutr, 2018, 148(8):1244-1252.
[5] van den Berghe PV, Klomp LW.New developments in the regulation of intestinal copper absorption[J].Nutr Rev, 2009, 67(11):658-672.
[6] Horning KJ, Caito SW, Tipps KG, et al.Manganese is essential for neuronal health[J].Annu Rev Nutr, 2015, 35:71-108.
[7] Winslow JWW, Limesand KH, Zhao N.The functions of zip8, zip14, and znt10 in the regulation of systemic manganese homeostasis[J].Int J Mol Sci, 2020, 21(9):3304.
[8] Mendel RR, Kruse T.Cell biology of molybdenum in plants and humans[J].Biochim Biophys Acta, 2012, 1823(9):1568-1579.
[9] Panchal SK, Wanyonyi S, Brown L.Selenium, vanadium, and chromium as micronutrients to improve metabolic syndrome[J].Curr Hypertens Rep, 2017, 19(3):10.
[10] Proctor DM, Suh M, Aylward LL, et al.Hexavalent chromium reduction kinetics in rodent stomach contents[J].Chemosphere, 2012, 89(5):487-493.
[11]Vincent JB, Edwards KC.Chapter 4-the absorption and transport of chromium in the body[M]//Vincent JB.The nutritional biochemistry of chromium (iii) (second edition).Elsevier,2019:129-174.
[12] Wang T, Xiang P, Ha JH, et al.Copper supplementation reverses dietary iron overload-induced pathologies in mice[J].J Nutr Biochem, 2018, 59:56-63.
[13] Zolfaghari A, Reza Gheisari H, Omidi A, et al.Zinc and manganese of serum were negatively, but copper positively influenced by iron elevation in diet of male wistar rats[J].Int J Vitam Nutr Res, 2018, 88(1-2):50-57.
[14] Elsenhans B, Janser H, Windisch W, et al.Does lead use the intestinal absorptive pathways of iron? Impact of iron status on murine 210pb and 59fe absorption in duodenum and ileum in vivo[J].Toxicology, 2011, 284(1):7-11.
[15] Iyengar V, Pullakhandam R, Nair KM.Coordinate expression and localization of iron and zinc transporters explain iron-zinc interactions during uptake in caco-2 cells:Implications for iron uptake at the enterocyte[J].J Nutr Biochem, 2012, 23(9):1146-1154.
[16] Huster D.Wilson disease[J].Best Pract Res Clin Gastroenterol, 2010, 24(5):531-539.
[17] Candia V, Ríos-Castillo I, Carrera-Gil F, et al.Effect of various calcium salts on non-heme iron bioavailability in fasted women of childbearing age[J].J Trace Elem Med Biol, 2018, 49:8-12.
[18] Ognik K, Stepniowska A, Cholewińska E, et al.The effect of administration of copper nanoparticles to chickens in drinking water on estimated intestinal absorption of iron, zinc, and calcium[J].Poult Sci, 2016, 95(9):2045-2051.
[19] Collins JF, Prohaska JR, Knutson MD.Metabolic crossroads of iron and copper[J].Nutr Rev, 2010, 68(3):133-147.
[20] Grzeszczak K, Kwiatkowski S, Kosik-Bogacka D.The role of Fe, Zn, and Cu in pregnancy[J].Biomolecules, 2020, 10(8):1176.
[21] Ha JH, Doguer C, Collins JF.Consumption of a high-iron diet disrupts homeostatic regulation of intestinal copper absorption in adolescent mice[J].Am J Physiol Gastrointest Liver Physiol, 2017, 313(4):G360-G535.
[22] Suliburska J, Skrypnik K, Chmurzyńska A.Iron and folic acid supplementation affects mineral status in female rats with a deficiency of these micronutrients[J].Biol Trace Elem Res, 2020.doi:10.1007/s//2001-020-02460-w.
[23] Jayalakshmi S, Platel K.Supplemental levels of iron and calcium interfere with repletion of zinc status in zinc-deficient animals[J].Food Funct, 2016, 7(5):2288-2293.
[24] Sathler DFT, Prados LF, Zanetti D, et al.Reducing mineral usage in feedlot diets for nellore cattle:I.Impacts of calcium, phosphorus, copper, manganese, and zinc contents on microbial efficiency and ruminal, intestinal, and total digestibility of dietary constituents[J].J Anim Sci, 2017, 95(4):1715-1726.
[25] Lönnerdal B.Calcium and iron absorption--mechanisms and public health relevance[J].Int J Vitam Nutr Res, 2010, 80(4-5):293-299.
[26] Hennigar SR, McClung JP.Hepcidin attenuates zinc efflux in caco-2 cells[J].J Nutr, 2016, 146(11):2167-2173.
[27] Bjørklund G, Aaseth J, Skalny AV, et al.Interactions of iron with manganese, zinc, chromium, and selenium as related to prophylaxis and treatment of iron deficiency[J].J Trace Elem Med Biol, 2017, 41:41-53.
[28] Zhao N, Zhang AS, Worthen C, et al.An iron-regulated and glycosylation-dependent proteasomal degradation pathway for the plasma membrane metal transporter zip14[J].Proc Natl Acad Sci USA, 2014, 111(25):9175-9180.
[29] Kondaiah P, Yaduvanshi PS, Sharp PA, et al.Iron and zinc homeostasis and interactions:does enteric zinc excretion cross-talk with intestinal iron absorption?[J].Nutrients, 2019, 11(8):1885.
[30] Ha JH, Doguer C, Collins JF.Knockdown of copper-transporting atpase 1 (atp7a) impairs iron flux in fully-differentiated rat (iec-6) and human (caco-2) intestinal epithelial cells[J].Metallomics, 2016, 8(9):963-972.
[31] Doguer C, Ha JH, Collins JF.Intersection of iron and copper metabolism in the mammalian intestine and liver[J].Compr Physiol, 2018, 8(4):1433-1461.
[32] Olivares M, Pizarro F, Ruz M, et al.Acute inhibition of iron bioavailability by zinc:studies in humans[J].Bio Metals, 2012, 25(4):657-664.