The role of immunological signaling in disrupted proteostasis in the gut‐brain axis

Abstract

AbstractBackgroundThe pathophysiological mechanism underlying the progressive neurodegenerative process in Alzheimer’s disease (AD) is not well understood. Hence, there is no disease‐modifying treatment. It is then imperative to identify the triggering molecular factors of the disease and the mechanisms supporting molecular spreading of toxic assemblies. Our search for these key clues in the periphery is founded on the fact that peripheral dysfunction, particularly in the gastrointestinal (GI) system, can arise decades before the onset of the classic symptoms in neurodegenerative disorders. In fact, the risk of AD increases significantly in patients with inflammatory bowel disease (IBD) when compared with the non‐IBD population. Furthermore, Tau accumulates in Crohn’s Disease guts and in sigmoid colon of AD and FTD patients. Thus, we are investigating the physiological and molecular mechanisms that support Tau spreading in the prodromal stages, particularly, along the gut‐brain axis.MethodTo test whether corrupted proteins expressed in the gut will spread their pathology to the brain, we employed the Gal4/UAS system and expressed wild‐type or mutant human Tau in selected populations of gut epithelium cells. We then monitor behavior on aging flies expressing Tau in the gut epithelium using Drosophila activity monitors and analyzed their circadian patterns of activity along with several sleep parameters.ResultWe observed that flies selectively expressing full‐length‐2N4R human Tau in enteroendocrine cells of the gut exhibited a significant impairment in their daily activity pattern that specifically affected their behavior during the light phase (day) but not during the dark period (night). Interestingly, these flies also showed an increased sleepiness during the day without affecting their nocturnal sleep pattern.ConclusionOur results support the presence of spreading mechanisms for Tau from gut epithelial cells to the brain; hence, affecting the neuronal physiology that sustain daily activity patterns. We are now investigating the pathways and mechanisms that pathological Tau in the gut employs to target these brain regions responsible for the behavioral phenotypes: transsynaptic spreading or humoral signaling via the innate immune system. We are dissecting the 3 major pathways of innate immunity in Drosophila (Imd‐Toll‐TNF) for their role in disease progression and the involvement of their target antimicrobial peptides.