MICOS in the Age-Related Decline of Mitochondrial Function
Here find a tour of an aspect of mitochondrial structure that might be unfamiliar, the boundary between the inner and outer mitochondrial membranes and their features called the mitochondrial contact site and cristae organizing system (MICOS). It is of interest to the researchers here because their data shows that MICOS becomes particularly disarrayed in neurons exposed to Alzheimer's disease pathology, and mitochondrial dysfunction is a feature of Alzheimer's disease and aging more generally. Further research with a broader focus remains needed determine how this fits in to the present consensus on the age-related mitochondrial dysfunction that occurs throughout the body.
Mitochondrial contact site and cristae organizing system (MICOS) complexes are critical for maintaining the mitochondrial architecture, cristae integrity, and organelle communication in neurons. MICOS disruption has been implicated in neurodegenerative disorders, including Alzheimer's disease (AD), yet the spatiotemporal dynamics of MICOS-associated neuronal alterations during aging remain unclear. Using three-dimensional reconstructions of hypothalamic and cortical neurons, we observed age-dependent fragmentation of mitochondrial cristae, reduced intermitochondrial connectivity, and compartment-specific changes in mitochondrial size and morphology. Notably, these structural deficits were most pronounced in neurons vulnerable to AD-related pathology, suggesting a mechanistic link between MICOS disruption and the early mitochondrial dysfunction observed in patients with AD.
Our findings indicate that the loss of MICOS integrity is a progressive feature of neuronal aging, contributing to impaired bioenergetics and reduced resilience to metabolic stress and potentially facilitating neurodegenerative processes. MICOS disruption reduced neuronal firing and synaptic responsiveness, with miclxin treatment decreasing mitochondrial connectivity and inducing cristae disorganization. These changes link MICOS structural deficits directly to impaired neuronal excitability, highlighting vulnerability to AD-related neurodegeneration. These results underscore the importance of MICOS as a critical determinant of neuronal mitochondrial health and as a potential target for interventions aimed at mitigating AD-related mitochondrial dysfunction.