EPO protects preemies’ brains by modifying genes essential for generating new brain cells

Erythropoietin (EPO) helps to protect and repair vulnerable brains though it remains a mystery how the anemia drug does so. Genetic analyses conducted by a multi-institutional research team finds that EPO may work its neuroprotective magic by modifying genes essential for regulating growth and development of nervous tissue as well as genes that respond to inflammation and hypoxia. Findings from the pilot study will be presented during the Pediatric Academic Societies 2018 annual meeting.

“During the last trimester of pregnancy, the fetal brain undergoes tremendous growth. When infants are born weeks before their due dates, these newborns’ developing brains are vulnerable to many potential insults as they are supported in the neonatal intensive care unit during this critical time,” says An Massaro, M.D., an attending neonatologist at Children’s National Health System and lead author of the research. “EPO, a cytokine that protects and repairs neurons, is a very promising therapeutic approach to support the developing brains of extremely low gestational age neonates.”

The research team investigated whether micro-preemies treated with EPO had distinct DNA methylation profiles and related changes in expression of genes that regulate how the body responds to such environmental stressors as inflammation, hypoxia and oxidative stress. They also investigated changes in genes involved in glial differentiation and myelination, production of an insulating layer essential for a properly functioning nervous system. The genetic analyses are an offshoot of a large, randomized clinical trial of EPO to treat preterm infants born between 24 and 27 gestational weeks.

The DNA of 18 newborns enrolled in the clinical trial was isolated from specimens drawn within 24 hours of birth and at day 14 of life. Eleven newborns were treated with EPO; a seven-infant control group received placebo.

DNA methylation and whole transcriptome analyses identified 240 candidate differentially methylated regions and more than 50 associated genes that were expressed differentially in infants treated with EPO compared with the control group. Gene ontology testing further narrowed the list to five candidate genes that are essential for normal neurodevelopment and for repairing brain injury:

• Neurogenin 1, a transcription factor that governs the progression of neurogenesis
• FOS like 1, implicated in development of cognitive deficits after oxygen depravation (hypoxia)
• Mitogen-activated protein kinase 8 interacting protein 2, encodes a scaffolding protein broadly expressed in the brain. Experimental models that lack this protein display autistic tendencies.
• Resistance to inhibitors of cholinesterase 8 homolog A, an essential player in generating new brain cells
• Major histocompatibility complex, class II, DR alpha, a central player in proper immune system function.

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