Identification of Genes Responding to Iron or Choline Treatment for Early-Life Iron Deficiency in the Male Rat Hippocampal Transcriptomes

Developmental iron deficiency (ID) is associated with long-term cognitive and affective behavioral impairments in humans. Preclinical studies have shown that developmental ID has short- and long-term effects on gene regulation. Prenatal choline supplementation partially rescues early-life ID-induced...

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Bibliographic Details
Published in:The Journal of nutrition 2024-04, Vol.154 (4), p.1141-1152
Main Authors: Liu, Shirelle X, Calixto Mancipe, Natalia, Gisslen, Tate, Georgieff, Michael K, Tran, Phu V
Format: Article
Language:English
Subjects:
Biological activity
Choline
Cognitive ability
Dietary supplements
Gene expression
Gene regulation
Gene sequencing
Genes
Hippocampus
Inflammation
Iron
Iron deficiency
Long-term effects
Males
Nutrient deficiency
Offspring
Oxidative phosphorylation
Phosphorylation
Prenatal experience
regulation
Rodents
Supplements
transcriptome
Transcriptomes
Vitamin deficiency
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Summary:Developmental iron deficiency (ID) is associated with long-term cognitive and affective behavioral impairments in humans. Preclinical studies have shown that developmental ID has short- and long-term effects on gene regulation. Prenatal choline supplementation partially rescues early-life ID-induced cognitive deficits in adult male rats. To identify acute and long-term changes in biological processes regulated by developmental ID and modifiable by choline. This study compares the hippocampal transcriptomes of postnatal day (P) 15 iron-deficient (acute) and P65 formerly ID (persistent) rats with or without prenatal choline treatment. Pregnant rats were fed an ID (4 mg/kg Fe) or iron-sufficient (IS) (200 mg/kg Fe) diet from gestational day (G) 2 to P7 with or without choline supplementation (5 g/kg choline) from G11 to G18. Hippocampi were collected from P15 or P65 offspring and analyzed for gene expression by RNA sequencing. Developmental ID-induced changes suggested modified activity of oxidative phosphorylation and fatty acid metabolism. Prenatal choline supplementation induced robust changes in gene expression, particularly in iron-deficient animals, where it partially mitigated the early-life ID-dysregulated genes. Choline supplementation also altered the hippocampal transcriptome in the IS rats, with indications for both beneficial and adverse effects. This study provided global assessments of gene expression regulated by iron and choline. Our new findings highlight genes responding to iron or choline treatments, including a potentially novel choline-regulated transporter (IPO7), with shared effects on neuroinflammation in the male rat hippocampus.
ISSN:0022-3166
1541-6100
1541-6100
DOI:10.1016/j.tjnut.2024.02.021