Synchrotron XRF imaging reveals manganese accumulation in the Golgi and post-synapses of neurons and enhanced uptake in astrocytes
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Abstract
Manganese is an essential trace metal for humans, but excessive exposure can cause neurotoxicity, including parkinsonian syndromes, cognitive deficits, and has also been implicated in the pathogenesis of neurodegenerative diseases. Globally, tens of millions of people are exposed to elevated manganese levels through drinking water, exceeding the WHO recommended guideline. Despite its public health significance, the cellular and subcellular mechanisms underlying manganese neurotoxicity remain poorly defined, particularly its distribution across brain cell types and its specific intracellular targets. In this study, we investigated manganese accumulation in primary cultures of hippocampal neurons and astrocytes. Using a correlative imaging approach that combined cryo-fluorescence light microscopy with synchrotron X-ray fluorescence imaging, we mapped and quantified manganese at subcellular resolution. Our analysis revealed that manganese preferentially accumulates in the Golgi apparatus of both neurons and astrocytes. In neurons, manganese was also detected in dendrites at the postsynaptic density, suggesting a role in synaptic vulnerability. Quantitative elemental analysis showed that astrocytes accumulated 3 times more manganese than neurons. Furthermore, when neurons were co-cultured with astrocytes, their manganese uptake was significantly reduced, indicating a possible protective or buffering role of astrocytes. These findings identify key cellular and subcellular targets of manganese and highlight the Golgi apparatus as a major regulator of manganese neurotoxicity. This work provides a foundation for understanding cell type–specific responses to manganese exposure and may inform the development of targeted neuroprotection strategies. Significance statement Manganese neurotoxicity impact millions of people worldwide. Understanding how manganese distributes within brain cells is critical for addressing its neurotoxic effects. This study identifies the Golgi apparatus and postsynaptic density as key sites of manganese accumulation and reveals astrocytes as major regulators of neuronal manganese uptake. These findings provide a cellular framework for developing targeted strategies to mitigate manganese-induced neurotoxicity.
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- last seen: 2026-05-20T01:45:00.602351+00:00