营养基因学
生物
疾病
微量营养素
清脆的
维生素
基因组学
功能基因组学
遗传学
候选基因
维生素C
基因
维生素D与神经学
脱水酶
代谢组学
计算生物学
生物信息学
转录组
维生素A缺乏
骨化三醇受体
维生素E
斑马鱼
作者
Ankur Garg,Skyler Y. Blume,Helen Huynh,Alec M. Barrios,Onurkan O. Karabulut,Qian Zhao,Ayush D. Midha,Adam W. Turner,B. Vittorio Resnick,Xuewen Chen,Ayushi Agrawal,JaeYeon Kim,Liuji Chen,Qitao Ran,Alison M. Ryan,Reece C Larson,Mina Negahban,Sophia C.K. Nelson,Andrew C. Yang,Michela Traglia
出处
期刊:Cell
[Cell Press]
日期:2026-02-01
被引量:1
标识
DOI:10.1016/j.cell.2026.01.022
摘要
Vitamins are essential metabolites that must be obtained from external sources. In modern times, they have become widely available, leading to their ad hoc consumption. We developed a nutritional genomics framework to systematically identify monogenic diseases responsive to micronutrient modulation. Genome-wide CRISPR screens under varying vitamin B2 and B3 levels revealed dozens of candidate disease genes amenable to rescue by individual vitamins. In the vitamin B3 screen, NAD(P)HX dehydratase (NAXD) was the top hit; this enzyme repairs an aberrant, hydrated form of NADH (6-hydroxy-1,4,5,6-tetrahydronicotinamide-adenine dinucleotide [NADHX]), and its loss causes severe neurodevelopmental disease. In our Naxd knockout (KO) mouse, we observed NADHX accumulation, NAD+ depletion, and impaired serine biosynthesis in neonatal KO brains. Spatial metabolomics, single-nuclei RNA sequencing (snRNA-seq), and histology pinpointed cortical and brain endothelial cell vulnerability. Low-vitamin B3 diets accelerated pathology, whereas vitamin B3 supplementation extended lifespan by more than 40-fold. These findings establish a nutritional genomics framework and demonstrate the therapeutic potential of precision vitamin interventions.
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