Dysregulation of Brain Cholesterol Biosynthetic Pathway following Hypoxia Ischemia in Neonatal Mice.

INTRODUCTION

Brain cholesterol relies on de novo biosynthesis and is crucial for brain development. Cholesterol synthesis is a complex series of reactions that involves more than twenty enzymes to reach the final product and generates a large number of intermediate sterols along two alternate pathways. This is a highly regulated and oxygen-dependent process and thus sensitive to hypoxia.

METHODS

Using the modified Vannucci procedure, a clinically relevant animal model of neonatal hypoxia ischemia (HI), we characterized the profile of cholesterol and its sterol intermediates, along with the key enzymes on the cholesterol synthetic pathway over a time course of 5 days after HI in the postnatal day 10 mouse brain.

RESULTS

Although the total cholesterol levels in the injured cortices appeared to be minimally attenuated at 5 days following HI, there was an overall repression of brain cholesterol biosynthesis. Lanosterol and the downstream sterols in both the Bloch and Kandutsch-Russell (K-R) pathways were consistently reduced for up to 3 days except for desmosterol, which was elevated. Correspondingly, protein expression of the controlling transcription factors sterol regulatory element-binding protein 2 (SREBP-2) and SREBP-1 was decreased at early time points (within 6 h), in parallel with the downregulation of several substrate enzymes for up to 5 days post-HI. HMG-CoA reductase (HMGCR), the first rate-limiting enzyme, was upregulated in the first 24 h after HI. The expression of 24-dehydrocholesterol reductase (DHCR24) that catalyzes the last step to produce cholesterol on the Bloch pathway and bridges the Bloch to K-R pathway was also augmented.

CONCLUSIONS

Our data suggest perturbed brain cholesterol biosynthesis following neonatal HI. As some sterol intermediates and enzymes have diverse functions in brain development and stress responses other than producing cholesterol, assessment of their dynamic changes after HI is important to understand the lipid responses in rodent HI models and to identify lipid-based targeted therapies in future studies.