Gannon Bryan M, Pungarcher India, Mourao Luciana, Davis Christopher R, Simon Philipp, Pixley Kevin V, Tanumihardjo Sherry A
Department of Nutritional Sciences, Interdepartmental Graduate Program in Nutritional Sciences.
Department of Horticulture, Vegetable Crops Research Unit, and.
J Nutr. 2016 Jul;146(7):1290-7. doi: 10.3945/jn.116.230300. Epub 2016 Jun 8.
Crops such as maize, sorghum, and millet are being biofortified with provitamin A carotenoids to ensure adequate vitamin A (VA) intakes. VA assessment can be challenging because serum retinol concentrations are homeostatically controlled and more sensitive techniques are resource-intensive.
We investigated changes in serum retinol relative differences of isotope amount ratios of (13)C/(12)C (δ(13)C) caused by natural (13)C fractionation in C3 compared with C4 plants as a biomarker to detect provitamin A efficacy from biofortified (orange) maize and high-carotene carrots.
The design was a 2 × 2 × 2 maize (orange compared with white) by carrot (orange compared with white) by a VA fortificant (VA+ compared with VA-) in weanling male Mongolian gerbils (n = 55), which included a 14-d VA depletion period and a 62-d treatment period (1 baseline and 8 treatment groups; n = 5-7/group). Liver VA and serum retinol were quantified, purified by HPLC, and analyzed by GC combustion isotope ratio mass spectrometry for (13)C.
Treatments affected liver VA concentrations (0.048 ± 0.039 to 0.79 ± 0.24 μmol/g; P < 0.0001) but not overall serum retinol concentrations (1.38 ± 0.22 μmol/L). Serum retinol and liver VA δ(13)C were significantly correlated (R(2) = 0.92; P < 0.0001). Serum retinol δ(13)C differentiated control groups that consumed white maize and white carrots (-27.1 ± 1.2 δ(13)C‰) from treated groups that consumed orange maize and white carrots (-21.6 ± 1.4 δ(13)C‰ P < 0.0001) and white maize and orange carrots (-30.6 ± 0.7 δ(13)C‰ P < 0.0001). A prediction model demonstrated the relative contribution of orange maize to total dietary VA for groups that consumed VA from mixed sources.
Provitamin A efficacy and quantitative estimation of the relative contribution to dietary VA were demonstrated with the use of serum retinol δ(13)C. This method could be used for maize efficacy or effectiveness studies and with other C4 crops biofortified with provitamin A carotenoids (e.g., millet, sorghum). Advantages include no extrinsic tracer dose, 1 blood sample, and higher sensitivity than serum retinol concentrations alone.
玉米、高粱和小米等作物正在通过添加维生素A原类胡萝卜素进行生物强化,以确保充足的维生素A(VA)摄入量。VA评估可能具有挑战性,因为血清视黄醇浓度受到稳态控制,而更敏感的技术资源密集。
我们研究了C3植物与C4植物中天然(13)C分馏导致的血清视黄醇相对差异以及(13)C/(12)C同位素丰度比(δ(13)C)的变化,以此作为一种生物标志物,来检测生物强化(橙色)玉米和高胡萝卜素胡萝卜中维生素A原的功效。
在断奶雄性蒙古沙鼠(n = 55)中进行了一项2×2×2的实验设计,包括玉米(橙色与白色)×胡萝卜(橙色与白色)×VA强化剂(VA+与VA-),其中包括14天的VA耗竭期和62天的治疗期(1个基线组和8个治疗组;每组n = 5 - 7)。通过高效液相色谱法(HPLC)对肝脏VA和血清视黄醇进行定量、纯化,并通过气相色谱燃烧同位素比率质谱法分析(13)C。
各处理影响肝脏VA浓度(0.048±0.039至0.79±0.24μmol/g;P < 0.0001),但不影响总体血清视黄醇浓度(1.38±0.22μmol/L)。血清视黄醇和肝脏VA的δ(13)C显著相关(R(2) = 0.92;P < 0.0001)。血清视黄醇δ(13)C能够区分食用白色玉米和白色胡萝卜的对照组(-27.1±1.2δ(13)C‰)与食用橙色玉米和白色胡萝卜的处理组(-21.6±1.4δ(13)C‰,P < 0.0001)以及食用白色玉米和橙色胡萝卜的处理组(-30.6±0.7δ(13)C‰,P < 0.0001)。一个预测模型显示了橙色玉米对从混合来源摄入VA的组中总膳食VA的相对贡献。
利用血清视黄醇δ(13)C证明了维生素A原的功效以及对膳食VA相对贡献的定量估计。该方法可用于玉米功效或有效性研究以及其他用维生素A原类胡萝卜素进行生物强化的C4作物(如小米、高粱)。优点包括无需外部示踪剂剂量、只需采集一份血样,且比单独的血清视黄醇浓度具有更高的灵敏度。
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