bims-agimec 2025-01-26 papers

bims-agimec

Biomed News

on Aging mechanisms

Issue of 2025–01–26
seven papers selected by
Metin Sökmen, Ankara Üniversitesi

Reversing Decline in Aging Muscles: Expected Trends, Impacts and Remedies.
Anti-Aging Tests for Middle Aged Women.
Mitochondrial transplantation: a promising strategy for the treatment of retinal degenerative diseases.
Beneficial death: A substantial element of evolution?
Brain Plasticity and Cell Competition: Immediate Early Genes Are the Focus.
Aging and tumors: a dynamic interaction.
The potential link between the development of Alzheimer's disease and osteoporosis.

J Funct Morphol Kinesiol. 2025 Jan 11. pii: 29. [Epub ahead of print]10(1):

Reversing Decline in Aging Muscles: Expected Trends, Impacts and Remedies.

Matthew Halma, Paul Marik, Joseph Varon, Jack Tuszynski.

  Background: Age-related decline in musculoskeletal function is a significant concern, particularly in Western countries facing demographic shifts and increased healthcare demands. This review examines the typical trajectories of musculoskeletal deterioration with age and evaluates the effectiveness of various interventions in preventing or reversing these changes. Methods: The review analyzes documented rates of decline across multiple parameters, including muscle mass, Type II muscle fiber reduction, and decreased motor unit firing rates. It examines evidence from studies on targeted interventions aimed at reversing these trends or preventing further decline. Results: The evidence suggests that multimodal interventions, including strength training can effectively maintain or improve physical function in aging adults. These interventions have shown potential in altering the trajectory of age-related decline in musculoskeletal function. Conclusions. The findings of this review have important implications for healthcare providers and policymakers in addressing the challenges of an aging population. By providing a framework for understanding and addressing age-related physical decline through evidence-based interventions, this review offers potential strategies for reducing healthcare costs and improving the quality of life for older adults.

Keywords:  cardiovascular fitness; cognitive function; healthy aging; longevity interventions; metabolic health; musculoskeletal strength; physical performance tests; quality of life in older people

DOI:  https://doi.org/10.3390/jfmk10010029
J Menopausal Med. 2024 Dec;30(3): 164-169

Anti-Aging Tests for Middle Aged Women.

Min-Sun Kim, Tae-Hee Kim.

  The interest in aging and anti-aging research has increased significantly in recent years, leading to rapid expansion in the anti-aging market. Aging is associated with gradual physiological changes and an elevated risk of age-related ailments, and is divided into three categories: usual aging, successful aging, and pathological aging. Each category is associated with distinct implications for health and well-being. Middle-aged women who experience accelerated physiological changes that are intensified by hormonal changes during menopause are particularly vulnerable to chronic diseases. The importance of anti-aging tests is increasing since they enable early identification and intervention. Telomere length, oxidative stress markers, DNA repair markers, RNA profiles, inflammatory markers, hormone levels, and epigenetic changes are some molecular parameters studied to test for aging. In addition, a thorough review of middle-aged women's anti-aging profiles also includes monitoring the vitamin D levels and assessing the effects of endocrine-disrupting substances on ovarian aging. The application of personalized medicine paradigms, utilizing various diagnostic methods, will enable accurate risk prediction and the implementation of focused therapies, ultimately promoting the extension of health span and the improvement of quality of life in middle-aged women.

Keywords:  Aging; Middle aged; Telomere

DOI:  https://doi.org/10.6118/jmm.24012
Neural Regen Res. 2024 Dec 07.

Mitochondrial transplantation: a promising strategy for the treatment of retinal degenerative diseases.

Jing Chi, Bin Fan, Yulin Li, Qing Jiao, Guang-Yu Li.

The retina, a crucial neural tissue, is responsible for transforming light signals into visual information, a process that necessitates a significant amount of energy. Mitochondria, the primary powerhouses of the cell, play an integral role in retinal physiology by fulfilling the high-energy requirements of photoreceptors and secondary neurons through oxidative phosphorylation. In a healthy state, mitochondria ensure proper visual function by facilitating efficient conversion and transduction of visual signals. However, in retinal degenerative diseases, mitochondrial dysfunction significantly contributes to disease progression, involving a decline in membrane potential, the occurrence of DNA mutations, increased oxidative stress, and imbalances in quality-control mechanisms. These abnormalities lead to an inadequate energy supply, the exacerbation of oxidative damage, and the activation of cell death pathways, ultimately resulting in neuronal injury and dysfunction in the retina. Mitochondrial transplantation has emerged as a promising strategy for addressing these challenges. This procedure aims to restore metabolic activity and function in compromised cells through the introduction of healthy mitochondria, thereby enhancing the cellular energy production capacity and offering new strategies for the treatment of retinal degenerative diseases. Although mitochondrial transplantation presents operational and safety challenges that require further investigation, it has demonstrated potential for reviving the vitality of retinal neurons. This review offers a comprehensive examination of the principles and techniques underlying mitochondrial transplantation and its prospects for application in retinal degenerative diseases, while also delving into the associated technical and safety challenges, thereby providing references and insights for future research and treatment.

DOI: https://doi.org/10.4103/NRR.NRR-D-24-00851
Biogerontology. 2025 Jan 18. 26(1): 39

Beneficial death: A substantial element of evolution?

Patrick R Winterhalter, Andreas Simm.

  If a shortened lifespan is evolutionarily advantageous, it becomes more likely that nature will strive to change it accordingly, affecting how we understand aging. Premature mortality because of aging would seem detrimental to the individual, but under what circumstances can it be of value? Based on a relative incremental increase in fitness, simulations were performed to reveal the benefit of death. This modification allows for continuous evolution in the model and establishes an optimal lifespan even under challenging conditions. As a result, shorter-lived individuals achieve faster adaptation through more frequent generational turnover, displacing longer-lived ones and likely providing a competitive advantage between species. Contrary to previous assumptions, this work proposes a mechanism by which early death, e.g., due to aging, may contribute to evolution.

Keywords:  Aging theory; Biogerontology; Death; Evolution simulation; Longevity; Programmed aging

DOI:  https://doi.org/10.1007/s10522-024-10176-w
Cells. 2025 Jan 19. pii: 143. [Epub ahead of print]14(2):

Brain Plasticity and Cell Competition: Immediate Early Genes Are the Focus.

Pavel P Tregub, Yulia K Komleva, Maria V Kukla, Anton S Averchuk, Anna S Vetchinova, Natalia A Rozanova, Sergey N Illarioshkin, Alla B Salmina.

  Brain plasticity is at the basis of many cognitive functions, including learning and memory. It includes several mechanisms of synaptic and extrasynaptic changes, neurogenesis, and the formation and elimination of synapses. The plasticity of synaptic transmission involves the expression of immediate early genes (IEGs) that regulate neuronal activity, thereby supporting learning and memory. In addition, IEGs are involved in the regulation of brain cells' metabolism, proliferation, and survival, in the establishment of multicellular ensembles, and, presumably, in cell competition in the tissue. In this review, we analyze the current understanding of the role of IEGs (c-Fos, c-Myc, Arg3.1/Arc) in controlling brain plasticity in physiological and pathological conditions, including brain aging and neurodegeneration. This work might inspire new gene therapy strategies targeting IEGs to regulate synaptic plasticity, and potentially prevent or mitigate neurodegenerative diseases.

Keywords:  Arg3.1/Arc; brain aging; c-Fos; c-Myc; cell competition; immediate early genes; neurodegeneration; neuroplasticity

DOI:  https://doi.org/10.3390/cells14020143
Discov Oncol. 2025 Jan 21. 16(1): 68

Aging and tumors: a dynamic interaction.

Yudi Zhang, Siqiang Zhu, Zhaodong Liu, Yonghao Hu, Yongjian Zhang, Liang Shang, Leping Li.

  Aging is an inevitable physiological process in organisms, and the development of tumors is closely associated with cellular senescence. This article initially examines the role of cellular senescence in tumorigenesis, emphasizing the correlation between telomere length-a marker of cellular senescence-and tumor risk. Concurrently, the study explores the expression levels of senescence-associated markers, such as p16, p53, and mTOR, in the context of tumor development. Additionally, the study investigates the impact of tumors on cellular and organismal senescence, including the effects on immune system function and metabolic processes. Ultimately, the discussion explores the potential application of anti-aging strategies in tumor therapy and considers the possibility of utilizing senescence mechanisms as a novel therapeutic approach for tumors. This research provides novel insights into the complex interplay between senescence and tumor development, suggesting potential strategies for future preventative measures and therapeutic interventions.

Keywords:  Aging; Anti-aging treatment; Cellular senescence; Telomere length; Tumor

DOI:  https://doi.org/10.1007/s12672-025-01808-9
Biogerontology. 2025 Jan 20. 26(1): 43

The potential link between the development of Alzheimer's disease and osteoporosis.

Fariha Nasme, Jyotirmaya Behera, Prisha Tyagi, Nabendu Debnath, Jeff C Falcone, Neetu Tyagi.

  Alzheimer's disease (AD) and osteoporosis (OP) pose distinct but interconnected health challenges, both significantly impacting the aging population. AD, a neurodegenerative disorder characterized by memory impairment and cognitive decline, is primarily associated with the accumulation of abnormally folded amyloid beta (Aβ) peptides and neurofibrillary tangles in the brain. OP, a skeletal disorder marked by low bone mineral density, involves dysregulation of bone remodeling and is associated with an increased risk of fractures. Recent studies have revealed an intriguing link between AD and OP, highlighting shared pathological features indicative of common regulatory pathophysiological pathways. In this article, we elucidate the signaling mechanisms that regulate the pathology of AD and OP and offer insights into the intricate network of factors contributing to these conditions. We also examine the role of bone-derived factors in the progression of AD, underscoring the plausibility of bidirectional communication between the brain and the skeletal system. The presence of amyloid plaques in the brain of individuals with AD is akin to the accumulation of brain Aβ in vascular dementia, pointing towards the need for further investigation of shared molecular mechanisms. Moreover, we discuss the role of bone-derived microRNAs that may regulate the pathological progression of AD, providing a novel perspective on the role of skeletal factors in neurodegenerative diseases. The insights presented here should help researchers engaged in exploring innovative therapeutic approaches targeting both neurodegenerative and skeletal disorders in aging populations.

Keywords:  Aging population; Amyloid beta (Aβ); Bone mineral density; Bone remodeling; Bone-derived factors; Neurodegenerative disorders; Vascular dementia

DOI:  https://doi.org/10.1007/s10522-024-10181-z