Jadavji Laboratory



Deparment Biomedical Sciences, Division of Molecular and Integrative Physiology

Southern Illinois University



Maternal dietary deficiencies in folic acid or choline reduce primary neuron viability after exposure to hypoxia through increased levels of apoptosis


Journal article


Alice Yaldiko, Sarah Coonrod, Purvaja Marella, L. Hurley, N. Jadavji
bioRxiv, 2023

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APA   Click to copy
Yaldiko, A., Coonrod, S., Marella, P., Hurley, L., & Jadavji, N. (2023). Maternal dietary deficiencies in folic acid or choline reduce primary neuron viability after exposure to hypoxia through increased levels of apoptosis. BioRxiv.


Chicago/Turabian   Click to copy
Yaldiko, Alice, Sarah Coonrod, Purvaja Marella, L. Hurley, and N. Jadavji. “Maternal Dietary Deficiencies in Folic Acid or Choline Reduce Primary Neuron Viability after Exposure to Hypoxia through Increased Levels of Apoptosis.” bioRxiv (2023).


MLA   Click to copy
Yaldiko, Alice, et al. “Maternal Dietary Deficiencies in Folic Acid or Choline Reduce Primary Neuron Viability after Exposure to Hypoxia through Increased Levels of Apoptosis.” BioRxiv, 2023.


BibTeX   Click to copy

@article{alice2023a,
  title = {Maternal dietary deficiencies in folic acid or choline reduce primary neuron viability after exposure to hypoxia through increased levels of apoptosis},
  year = {2023},
  journal = {bioRxiv},
  author = {Yaldiko, Alice and Coonrod, Sarah and Marella, Purvaja and Hurley, L. and Jadavji, N.}
}

Abstract

Stoke is the leading cause of death and disability globally. By addressing modifiable risk factors, particularly nutrition, the prevalence of stroke and its dire consequences can be mitigated. One-carbon (1C) metabolism is a critical biosynthetic process that is involved in neural tube closure, neuronal plasticity, and cellular proliferation in the developing embryo. Folic acid and choline are two active components of 1C metabolism, we have previously demonstrated that maternal dietary deficiencies in folic acid or choline worsen stroke outcomes in offspring. However, there is insufficient data to understand the neuronal mechanisms involved. We exposed embryonic neurons of offspring, whom mothers were on folic acid or choline deficient diets, to hypoxia conditions for 6 hours and return to normoxic conditions for 24 hours to model an ischemic stroke and reperfusion injury. To determine whether increased levels of either folic acid or choline can rescue reduced neuronal viability, we supplemented cell media with folic acid and choline prior to and after exposure to hypoxia. Our results suggest that maternal dietary deficiencies in either folic acid or choline during pregnancy negatively impacts offspring neuronal viability after hypoxia. Furthermore, increasing levels of folic acid or choline prior to and after hypoxia have a beneficial impact on neuronal viability. The findings contribute to our understanding of the intricate interplay between maternal dietary factors, 1C metabolism, and the outcome of offspring to hypoxic events, emphasizing the potential for nutritional interventions in mitigating adverse outcomes.