Abstract
Blood-borne factors regulate adult hippocampal neurogenesis (AHN) and cognition in mammals, albeit via mechanisms that are poorly understood. We report that elevating circulating unacylated-ghrelin (UAG), using both pharmacological and genetic methods, reduced hippocampal neurogenesis and plasticity in mice. Spatial memory impairments observed in GOAT-/- mice that lack acyl-ghrelin (AG) but have high levels of UAG, were rescued by treatment with AG. This unexpected finding suggests that the post-translational acylation of ghrelin is an important modulator of neurogenesis and memory in adult mammals. To determine whether this paradigm is relevant to humans we analysed circulating AG:UAG levels in Parkinsons disease (PD) patients diagnosed with dementia (PDD), cognitively intact PD patients and healthy controls. Uniquely, the ratio of plasma AG:UAG was reduced in the PDD cohort and correlated with cognitive performance. Our results identify UAG as a novel regulator of neurogenesis and cognition, and AG:UAG as a circulating diagnostic biomarker of dementia. The findings extend our understanding of adult brain plasticity regulation by circulating factors and suggest that manipulating the post-translational acylation of plasma ghrelin may offer therapeutic opportunities to ameliorate cognitive decline.
Circulating UAG impairs markers of neurogenesis and plasticity
GOAT-/-mice have impaired neurogenesis and spatial memory
Circulating acyl-ghrelin (AG) rescues spatial memory deficit in GOAT-/-mice
Circulating AG:UAG ratio is reduced in Parkinson’s disease dementia