Activin A in perinatal brain injury.

Activin A is a multifunctional growth and differentiation factor belonging to the transforming growth factor ß (TGF-ß) family. Growing evidence indicates its role as a neurotrophic factor and regulator of synaptic transmission as well as its functional importance in several types of cerebral injury. We recently described age-dependent expression of activin A and its regulation at the mRNA and protein level under different conditions of global hypoxia in the neonatal mouse brain. This review discusses the current knowledge of the function and regulation of activin A from human studies as well as from experimental models of brain injury focusing on acquired lesions of the developing rodent brain during the early stages of brain maturation.

Activin A regulation under global hypoxia in developing mouse brain.

Activin A is a multifunctional growth and differentiation factor with pronounced neuroprotective properties that is strongly up-regulated in various forms of acute brain disorders and injuries including epilepsy, stroke and trauma. In a pediatric context, activin A has been advanced as a potential marker for the severity of perinatal hypoxic-ischemic brain injury. Here we investigated the regulation of activin A under global hypoxia without ischemia in primary cultures of cortical neurons and in neonatal and adult mice of two strains (C57BL/6 and CD-1). From birth to adulthood, activin ßA subunit, activin receptors, and functional activin antagonists were all expressed at roughly similar mRNA levels in the brain of C57BL/6 mice. Independent of mouse line and age, we found both moderate (11% O2, 2h) and severe hypoxia (8%, 6h) to be consistently associated with normal or even reduced levels of activin ßA (Inhba) mRNA. The surprising unresponsiveness of Inhba expression to hypoxia was confirmed at the protein level. In situ hybridization did not indicate regional, hypoxia-related differences in Inhba expression. Pharmacologic stabilization of hypoxia inducible factors with the prolyl hydroxylase inhibitor FG-4497 did not influence Inhba mRNA levels in neonatal mice. Our data indicate that pure hypoxia differs from other, more complex types of brain damage in that it appears not to recruit activin A as an endogenous neuroprotective agent.

Rapidly progressive phenotype of Lafora disease associated with a novel NHLRC1 mutation.

Lafora disease is a fatal, autosomal recessive form of progressive myoclonus epilepsy. Patients characteristically exhibit myoclonic and tonic-clonic seizures and cognitive impairment, beginning in their second decade. Alterations in two genes were identified as the cause of the disease. Mutations in the NHL repeat containing 1 (NHLRC1) gene were described in association with a more benign clinical course and later age of death, compared with epilepsy progressive myoclonus type 2A (EPM2A) mutations. We describe a rapidly progressive phenotype of Lafora disease in an adolescent patient with a novel NHLRC1 mutation. He developed severe disability and dementia less than 2 years after the onset of signs.