Measurement of autophagy via LC3 western blotting following DNA-damage-induced senescence

Green Tea Mitigates the Hallmarks of Aging and Age-Related Multisystem Deterioration

Aging is characterized by progressive multisystem deterioration driven by molecular and cellular mechanisms encapsulated in the twelve hallmarks of aging. Green tea (GT), derived from Camellia sinensis, has garnered significant scientific interest due to its rich polyphenolic composition, particularly epigallocatechin-3-gallate, and its pleiotropic health benefits. In this narrative review, we explored the multifaceted mechanisms through which GT may mitigate the aging hallmarks. Evidence from in vitro, animal, and human studies has shown that GT polyphenols can enhance DNA repair pathways, preserve telomere length, modulate epigenetic aging markers, improve proteostasis and autophagic flux, regulate nutrient-sensing networks, and rejuvenate mitochondrial function. Additionally, GT exhibits anti-inflammatory properties and may restore a physiological gut microbiota composition. Beyond molecular and cellular effects, GT consumption in humans has been associated with improved cognitive function, cardiovascular health, muscle preservation, and metabolic regulation in aging populations. Collectively, these findings highlight GT's potential as a naturally occurring geroscience intervention capable of addressing the interconnected network of aging processes more comprehensively than single-target pharmaceuticals. Future research should focus on optimizing dosing regimens, exploring synergies with other anti-aging strategies, and investigating personalized responses to GT interventions.

Altered Mitochondrial Bioenergetics and Calcium Kinetics in Young-Onset PLA2G6 Parkinson's Disease iPSCs

Parkinson's disease (PD) has emerged as a multisystem disorder affecting multiple cellular and organellar systems in addition to the dopaminergic neurons. Disease-specific induced pluripotent stem cells (iPSCs) model early developmental changes and cellular perturbations that are otherwise inaccessible from clinical settings. Here, we report the early changes in patient-derived iPSCs carrying a homozygous recessive mutation, R741Q, in the PLA2G6 gene. A gene-edited R747W iPSC line mirrored these phenotypes, thus validating our initial findings. Bioenergetic dysfunction and hyperpolarization of mitochondrial membrane potentials were hallmarks of the PD iPSCs. Further, a concomitant increase in glycolytic activity indicated a possible compensation for mitochondrial respiration. Elevated basal reactive oxygen species (ROS) and decreased catalase expression were also observed in the disease iPSCs. No change in autophagy was detected. These inceptive changes could be potential targets for early intervention of prodromal PD in the absence of disease-modifying therapies. However, additional investigations are crucial to delineate the cause-effect relationships of these observations.

Autophagy Analysis: A Step-by-Step Simple Practical Guide for Immunofluorescence and Western Blotting

Autophagy is a vital cellular process responsible for breaking down faulty cellular components and organelles, ultimately routed through lysosomes for degradation. This intricate mechanism involves the translocation of LC3, a cytoplasmic protein, onto the autophagosome membranes. As a result, it becomes feasible to discern cells engaged in autophagy by employing fluorescent markers designed for LC3 or other indicative autophagy markers. Although a variety of techniques such as immunofluorescence and western blotting serve as indispensable tools for assessing autophagy, the definitive confirmation comes from the visualization of autophagosomes using transmission electron microscopy. While numerous protocols for antibody staining can be found in scientific literature and on antibody suppliers' websites, these procedures often demand significant time and financial resources for setup. This chapter endeavors to provide a user-friendly and cost-effective guide for practitioners seeking proficiency in immunofluorescence staining and western blotting techniques.

Mechanism and role of nuclear laminin B1 in cell senescence and malignant tumors

Nuclear lamin B1 (LMNB1) is a member of the nuclear lamin protein family. LMNB1 can maintain and ensure the stability of nuclear structure and influence the process of cell senescence by regulating chromatin distribution, DNA replication and transcription, gene expression, cell cycle, etc. In recent years, several studies have shown that the abnormal expression of LMNB1, a classical biomarker of cell senescence, is highly correlated with the progression of various malignant tumors; LMNB1 is therefore considered a new potential tumor marker and therapeutic target. However, the mechanism of action of LMNB1 is influenced by many factors, which are difficult to clarify at present. This article focuses on the recent progress in understanding the role of LMNB1 in cell senescence and malignant tumors and offers insights that could contribute to elucidating the mechanism of action of LMNB1 to provide a new direction for further research.

P62/SQSTM1 mediates the autophagy-lysosome degradation of CDK2 protein undergoing PI3Kα/AKT T308 inhibition

CDK2 forms a complex with cyclin A and cyclin E to promote the progress of cell cycle, but when cyclin A and cyclin E are dissociated from the complex and degraded by the ubiquitin proteasome pathway, the fate of the inactive CDK2 is unclear. In this study, we found that the inactive CDK2 protein was degraded by autophagy-lysosome pathway. In the classic model of G0/G1 phase arrest induced by serum starvation, we found that the mRNA level in CDK2 did not change but the protein level decreased. Subsequently, using PI3K and AKT inhibitors and gene knockout methods, it was found that CDK2 degradation was mediated by the inhibition of PI3Kα/AKT^T308. In addition, P62/SQSTM1 was found to bind to the inactivated CDK2 protein to help it enter autophagy-lysosome degradation in a CTSB-dependent manner. Taken together, these results confirm that the PI3Kα/AKT^T308 inhibition leads to degradation of CDK2 protein in the autophagy-lysosome pathway. These data reveal a new molecular mechanism of CDK2 protein degradation and provide a new strategy and method for regulating CDK2 protein.