We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Inter- and intracellular mitochondrial communication: signaling hubs in aging and age-related diseases
Summary
Researchers reviewed how mitochondria — the cell's energy factories — communicate both within and between cells, and how this communication breaks down as we age. When mitochondrial function and signaling both fail together, it creates a damaging cycle that drives age-related diseases, but targeting these pathways may offer new ways to extend healthy lifespan.
Mitochondria are versatile and complex organelles that can continuously communicate and interact with the cellular milieu. Deregulated communication between mitochondria and host cells/organelles has significant consequences and is an underlying factor of many pathophysiological conditions, including the process of aging. During aging, mitochondria lose function, and mitocellular communication pathways break down; mitochondrial dysfunction interacts with mitochondrial dyscommunication, forming a vicious circle. Therefore, strategies to protect mitochondrial function and promote effective communication of mitochondria can increase healthy lifespan and longevity, which might be a new treatment paradigm for age-related disorders. In this review, we comprehensively discuss the signal transduction mechanisms of inter- and intracellular mitochondrial communication, as well as the interactions between mitochondrial communication and the hallmarks of aging. This review emphasizes the indispensable position of inter- and intracellular mitochondrial communication in the aging process of organisms, which is crucial as the cellular signaling hubs. In addition, we also specifically focus on the status of mitochondria-targeted interventions to provide potential therapeutic targets for age-related diseases.
Sign in to start a discussion.
More Papers Like This
Microplastics/nanoplastics contribute to aging and age-related diseases: Mitochondrial dysfunction as a crucial role
This review examines how microplastics and nanoplastics may contribute to aging and age-related conditions by damaging mitochondria, the energy-producing structures inside cells. Researchers describe how these tiny plastic particles enter the body through food, water, and air, and accumulate in various organs where they can disrupt normal mitochondrial function. The study suggests that microplastic-driven mitochondrial damage could be an underappreciated factor in the aging process and related health decline.
Environmental nanoplastics induce mitochondrial dysfunction: A review of cellular mechanisms and associated diseases
This review summarizes how nanoplastics, which are small enough to enter individual cells, damage mitochondria (the energy-producing structures inside cells) by disrupting their shape, function, and ability to produce energy. This mitochondrial damage has been linked to a range of diseases including neurodegeneration, diabetes, cardiovascular disease, and reproductive problems. The findings help explain why nanoplastic exposure may contribute to multiple chronic health conditions through a common cellular mechanism.
Micro- and nanoplastic-induced mitochondrial dysfunction and organelle miscommunication: A toxicological perspective
This review examined how micro- and nanoplastics disrupt mitochondrial function and inter-organelle communication in cells. The evidence indicates that these particles cause oxidative stress, calcium dysregulation, impaired energy production, and activation of stress responses including autophagy and cell death, with cascading effects on lysosomes, the endoplasmic reticulum, and nuclear function.
Impact of Micro- and Nanoplastics on Mitochondria
This review examines how micro- and nanoplastics can damage mitochondria, the energy-producing structures inside cells that are critical for metabolism and cell survival. Researchers found that plastic particle exposure can trigger oxidative stress, disrupt mitochondrial membrane function, and interfere with energy production pathways. Since mitochondrial dysfunction is linked to numerous health conditions, the study suggests this may be a key mechanism through which plastic pollution affects human health.
Author comment: Mitochondria as a target of micro- and nanoplastic toxicity — R0/PR1
This review examines how microplastics and nanoplastics disrupt the function of mitochondria — the cell's energy-producing organelles — by triggering oxidative stress, altering membrane potential, and interfering with cell signaling. Because mitochondrial dysfunction is linked to neurodegenerative disease, cancer, diabetes, and cardiovascular conditions, this work raises concern that microplastic exposure could contribute to or worsen these diseases. The authors call for more targeted research into how plastic particles interact with cellular energy systems.