Scientists Uncover Potential Key to Keeping Your Brain Healthy: Midlife Recycling

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Mitochondrial recycling, or mitophagy, plays a crucial role in brain aging, with midlife identified as a pivotal stage for maintaining brain health. New research reveals a dynamic, region-specific pattern of mitophagy in the brain, offering insights into aging and neurodegenerative diseases.

Mitophagy dynamics change with age, particularly during midlife, influencing brain health and aging. These findings offer insights for developing therapies for neurodegenerative diseases.

The mitochondria, often referred to as the powerhouses of our cells, play a vital role in maintaining cellular health. When damaged, these organelles are removed through a recycling process known as mitophagy, which is essential for the proper function of long-lived cells, particularly in the brain. Impaired mitophagy has been strongly linked to neurodegenerative disorders such as Alzheimer’s and Parkinson’s disease, highlighting its importance as a target for drug discovery and therapeutic advancements.

New research from the McWilliams lab at the University of Helsinki, spearheaded by doctoral researcher Anna Rappe, MSc, reveals a changing and unexpected landscape of mitophagy across in different brain cell types during the aging process.

For example, mitophagy levels increased in a specialized mouse brain region responsible for movement as the animals aged, while in memory-related brain cells, mitophagy first rose and then sharply declined in old age. These findings identify midlife as a key inflection point for healthy brain aging, offering novel insights into the molecular mechanisms that sustain mammalian brain function.

Another key finding of the study was that some lysosomes, the structures responsible for breaking down cellular waste, lose acidity as the brain ages. This exciting observation parallels changes observed in Alzheimer’s disease models, suggesting that the processes seen in normal aging might be exacerbated in the development of neurodegenerative conditions. The results challenge previous assumptions that mitophagy simply decreases with age across all species, showing that in longer-lived mammals, this special recycling process is much more dynamic and complex.

Previous studies, often using short-lived models like yeast and worms, suggested that mitophagy levels decline over a lifetime, marking it as a hallmark of aging. However, studying this process in the aging mammalian brain has been challenging due to the complexity of brain tissue and the limitations of traditional research methods. Only recently have the tools needed to track mitophagy across different tissues and organs in mammals become available. The McWilliams Lab employed cutting-edge tools in mouse genetics, optobiology, neuroscience, and advanced imaging to track mitophagy over time in different brain cell types. Their results highlight the importance of developing new perspectives when studying brain aging in longer-lived species, with midlife emerging as a critical period for preserving brain function.

Implications for understanding brain aging in health and disease

Associate Professor Thomas McWilliams, who supervised the study, contextualized these findings: “There is no doubt that mitophagy decreases in shorter-lived species. While we share important genes and mechanisms, the tissues of longer-lived mammals have evolved under distinct pressures to handle different challenges. Our work reveals that mitophagy is highly dynamic in the aging mouse brain and suggests midlife is a crucial period for mammalian brain health.”

He added that while the field has made progress in understanding neurodegenerative diseases, the high failure rate of current therapies underscores the need for new approaches.

“There is still much to do, but we are excited by these new findings that reshape our understanding of brain aging. Together with our clinical collaborators, we are committed to advancing this research towards more human-centered applications. We hope our current results will give companies and translational researchers a valuable roadmap to help accelerate the development of new therapies for brain disease.”

Reference: “Longitudinal autophagy profiling of the mammalian brain reveals sustained mitophagy throughout healthy aging” by Anna Rappe, Helena A Vihinen, Fumi Suomi, Antti J Hassinen, Homa Ehsan, Eija S Jokitalo and Thomas G Mc Williams, 4 October 2024, The EMBO Journal.
DOI: 10.1038/s44318-024-00241-y

The study has been well received internationally, with Anna Rappe achieving awards at several meetings, including the 2024 Nordic Autophagy Society Conference (the EMBO Journal Best Poster Prize, Iceland), the 2024 Anatomici Fenniae Symposium (Joint best prize – Helsinki, Finland), and previously at the 2022 FENS Forum (Paris, FR) — Europe’s largest neuroscience conference, when this work started during her MSc in the McWilliams lab (best poster prize). Earlier this year, McWilliams was awarded 1.12 million EUR from the Jane and Aatos Erkko Foundation to conduct further groundbreaking research into human-specific autophagy mechanisms.

The study was led by Associate Professor Thomas McWilliams and his team at the University of Helsinki, with important collaborative contributions from Dr. Helena Vihinen and Dr. Eija Jokitalo at the HiLIFE Electron Microscopy Unit and Dr. Antti Hassinen from the FIMM HCA Unit.

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