The mitochondria are often referred to as the powerhouse of the cell due to their role in producing energy in the form of Adenosine 5′-triphosphate or ATP. The more energy it can produce, the more energy the cell will have to work properly across all tissues and organs. Additionally, it plays a role in cellular metabolism. A dysfunctional mitochondrion has been found to lead to an increase in reactive oxygen species that fuel inflammation and oxidative stress, triggering a cascade of maladaptations and accelerating aging. Studies have found mitochondrial dysfunction to be associated with a wide range of human pathologies, such as cancer and metabolic and cardiovascular diseases.

Proper cellular functioning requires a state of homeostasis, the process that regulates proteins within the cell. A balance between protein synthesis, folding, and degradation is essential for maintaining cellular function and preventing the accumulation of damaged or misfolded proteins. The loss of proteostasis refers to the gradual decline in the ability of cells to maintain that protein homeostasis or proteostasis. The efficiency of cells to maintain proteostasis declines over time, leading to a build-up of damaged or misfolded proteins, which have been found to contribute to aging and disease. Scientists have identified that a common pathological hallmark among different neurodegenerative diseases is the accumulation of aggregated proteins that might cause cellular dysfunction and, eventually, lead to cell death.

Nothing within an organism, like the human body, occurs in a vacuum or in isolation. Cells constantly communicate with each other through a variety of mechanisms. When this communication gets altered, however, the signaling between cells can be lost, misinterpreted, or even ignored, interrupting normal tissue function and repair, and may contribute to the development of age-related diseases.

Epigenetic alterations are characterized by changes in the regulation of gene expression. While these changes do not impact the DNA sequence itself, they may trigger modifications in whether a gene switch is turned on or off. Factors such as your environment, diet, lifestyle choices, and stress management can all contribute to how certain genes are expressed over the course of your life. However, as we age, the patterns of these epigenetic alterations can become more pronounced, leading to undesirable changes in gene expression that can contribute to age-related diseases and conditions. A review published in the International Journal of Molecular Sciences concluded that epigenetic alterations may result in the development or progression of several human pathologies, including cancer, diabetes, osteoporosis, and neurodegenerative disorders. Since epigenetics refers to all things external that impact gene expression, these are largely reversible, and we can control what we do and surround ourselves with to protect our genes from developing diseases.

Telomeres are small protective caps on the ends of chromosomes that help to maintain the stability and integrity of your genes. However, each time a cell divides, its telomeres become shorter due to the incomplete replication of the telomere sequence during DNA synthesis. The shorter they get, the less protection there is for the chromosomes, which eventually will result in cellular senescence or programmed cell death (more on this below). The shortening of telomeres has been found to accelerate aging due to limiting the ability of cells to divide and replenish damaged tissues. Additionally, telomere attrition has been linked to chronic inflammation. According to a study in Nature Cell Biology, “senescent cells secrete a complex set of proinflammatory cytokines, known as the senescence-associated secretory phenotype (SASP). This alters the composition of the extracellular matrix, impairs stem cell functions, promotes cell transdifferentiation, and can spread the senescence phenotype to surrounding cells, thereby causing chronic systemic inflammation.” A variety of factors impact telomere attrition, including oxidative stress, inflammation, and exposure to toxins. However, studies have found that exercise, particularly aerobic activity, may help to improve telomere length. The explanation lies in the telomerase enzyme that adds telomere sequence to the ends of chromosomes. Such physical activity has been found to increase telomerase activity and reduce the rate of telomere attrition. Telomere attrition has been linked to a number of age-related diseases, such as cardiovascular disease, cancer, and neurodegenerative disorders.

Deregulated nutrient sensing is defined by the decline of the cell’s ability to sense what nutrients are at hand and communicate to the other inner systems for further mechanisms to occur. Nutrient sensing pathways play a critical role in regulating cellular metabolism, energy balance, and growth and are essential for supporting the proper functioning of cells and tissues. One of the most profound nutrient-sensing pathways relates to how our cells behave in the presence of insulin and insulin-like growth factor (IGF-1).

Macroautophagy, or autophagy, is the body’s natural process through which cells get rid of damaged or dysfunctional organelles and proteins to help to maintain cellular homeostasis. Age, oxidative stress, epigenetic factors, and mitochondrial dysfunction may decrease our cells’ ability to perform autophagy, leading to the accumulation of damaged cells and proteins and accelerating aging. Additionally, the inhibition of this inner “healing” mechanism has been linked to Alzheimer’s disease, type 2 diabetes, and cardiovascular disease.

Chronic inflammation refers to a constant, lingering, and low-grade inflammatory response that, over time, wrecks havoc on the body. Think of being poked by a small needle for a very long time. You might not even notice it for the first few hours, but as days, weeks, months, and years go by, it will cause great damage beneath your skin. Going beyond molecular inflammation and inflammaging, a group of researchers has identified multiphase inflammatory networks and proinflammatory pathways that may contribute to aging and, as a systemic response, may exacerbate age-related chronic diseases.