Abstract
Alzheimer's disease (AD) displays striking sex differences in incidence, progression, and resilience, yet the mechanisms that drive female-biased vulnerability remain incompletely understood. Emerging evidence indicates that gut dysbiosis, increasingly prevalent with ageing, acts as a systemic amplifier of neuroinflammation, vascular instability, and metabolic dysfunction. Here, we synthesize converging findings linking gut microbial alterations to noradrenergic pathology in the locus coeruleus (LC), one of the earliest brain regions affected in AD. We outline how dysbiosis-associated inflammatory signaling, including endotoxin exposure and impaired vagal-neuroimmune regulation, targets LC circuits. In parallel, disruptions in microbial metabolite pathways involving short-chain fatty acids, bile acids, and tryptophan metabolism further promote oxidative stress, tau phosphorylation, and neurodegeneration. We further argue that sex-dependent differences in immune reactivity, autonomic regulation, and hormonal transitions, particularly peri- and post-menopausal estrogen decline, render female LC neurons uniquely vulnerable to microbial and inflammatory perturbation. We propose a mechanistic framework in which gut dysbiosis destabilizes LC integrity through parallel immune-vascular, metabolite, endocrine, and vagal neural pathways, thereby accelerating cognitive decline and AD progression. Understanding how microbial signaling intersects with sex biology and neuromodulatory circuitry may reveal therapeutic windows for early intervention, including microbiome restoration, neuromodulatory tuning, and sex-specific metabolic targeting.