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Fight Aging! Newsletter, December 22nd 2025 21 December 2025 - 04:02 PM
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- Making Inroads into the Regulation of Reprogramming Induced Rejuvenation
- Aging and Adult Neurogenesis in the Hippocampus
- OTULIN as a Potential Target for Treatment of Tauopathies
- The Hyaluronidase CEMIP is Involved in Demyelinating Diseases
- Methylglyoxal in Aortic Stiffening in Mice
- Extracellular Matrix Protein Tenascin-C is Important to Muscle Stem Cell Function, But Declines with Age
- Terazosin Reduces Endothelial Cell Senescence to Slow Vascular Aging in Mice
- A Pilot MicroRNA Aging Clock
- Lysosomal Enlargement in Aging is a Compensatory Response
- The Contribution of the Aging Gut Microbiome to Alzheimer's Disease
- Reviewing the Aging of the Oral Microbiome
- Modeling a Theoretical Upper Bound on Lifespan Resulting from Somatic Mutation
- A Novel Form of Mitochondrial DNA Damage
- Female Sterilization and Male Castration Increase Lifespan Across Vertebrate Species
- Mitochondrial Dysfunction as a Contribution to Atrial Fibrillation
Making Inroads into the Regulation of Reprogramming Induced Rejuvenation
https://www.fightaging.org/archives/2025/12/making-inroads-into-the-regulation-of-reprogramming-induced-rejuvenation/
Reprogramming involves exposing cells to expression of one or more of the Yamanaka factors, c-Myc, Oct4, Sox2, and KLF4. This slowly alters cell state in a small fraction of exposed somatic cells, and these cells transform to become induced pluripotent stem cells, essentially the same as embryonic stem cells. This recapitulates some of the processes involved in embryogenesis. More rapidly and reliably than this change of state, a cell exposed to Yamanaka factor expression also exhibits rejuvenation of nuclear DNA structure and patterns of gene expression, leading to a restoration of youthful function. This cannot fix everything in an aged cell, such as mutational DNA damage, but it has a sizable enough effect on cells, and in mice, that partial reprogramming as a basis for rejuvenation therapies has become a popular area of development.
Can reprogramming of cell state be efficiently separated from reprogramming of nuclear structure? If we want reliable rejuvenation therapies, it seems likely that progress must be made on this front. Researchers are investigating the regulation of reprogramming downstream of the Yamanaka factors, but this is a painfully slow process. Still, every incremental advance in tracing the interactions of proteins might be the one that disentangles rejuvenation from state change, unleashing a much more efficient approach than offered by the present options capable of triggering reprogramming.
Most of the longevity industry now consists of reprogramming initiatives if measuring by investment size. Related to that, we might argue that most of the work carried out on reprogramming as a basis for rejuvenation therapies is in fact conducted outside academia at this point. In the long run this work will become just as visible as academic efforts, but for now it is dark matter. Thus to find ongoing indications of progress on picking apart the systems of regulation that produce rejuvenation in response to Yamanaka factor expression, one must keep up with the publication of academic papers - such as today's example.
Conserved Master Regulators Orchestrate Cellular Reprogramming-Induced Rejuvenation
Partial somatic cell reprogramming has been proposed as a rejuvenation strategy, yet the regulatory architecture orchestrating age reversal remains unclear. What molecular systems allow partial relaxation of identity to restore youthful regulatory function while avoiding dedifferentiation? Previous work has identified chromatin regulators as central to this process. DNA methyltransferases Tet1 and Tet2 may be required for reprogramming-induced rejuvenation, and reprogramming-induced rejuvenated cells exhibit restored nucleosome regularity and recalibrated histone modification balance. However, identifying genes that change during rejuvenation does not reveal which factors actively drive the process versus those that respond as downstream consequences. Distinguishing upstream regulators from effector genes requires network-level analysis that can infer causal regulatory relationships.
Here, we performed gene regulatory network reconstruction across several independent systems to identify master regulators that coordinate reprogramming-induced rejuvenation (RIR). In mouse mesenchymal stem cells, mouse adipocytes, and human fibroblasts undergoing partial reprogramming, we identified genes showing opposite expression dynamics during aging and reprogramming. This approach revealed regulators governing rejuvenation rather than developmental programs. Despite divergent overall network architectures, nine transcription factors converged as master regulators across all three systems, including Ezh2, Parp1, and Brca1. These regulators undergo coordinated reorganization during reprogramming, characterized by broader target engagement and enhanced regulatory coherence.
We further demonstrated that direct perturbation of Ezh2 bidirectionally modulates transcriptomic age. Notably, overexpression of a catalytically inactive Ezh2 mutant achieved rejuvenation, suggesting mechanisms distinct from canonical H3K27me3-mediated regulation are involved in RIR. Our findings reveal that cellular rejuvenation is orchestrated by conserved master regulators whose network coordination can be targeted independently of the reprogramming process.
Aging and Adult Neurogenesis in the Hippocampus
https://www.fightaging.org/archives/2025/12/aging-and-adult-neurogenesis-in-the-hippocampus/
Clearly change must occur constantly in the adult brain. However we suppose information to be encoded in physical structures of the brain, the information content of a brain evidently changes over time, as illustrated by the processes of memory and learning, and thus the structure of the brain must also change. Nonetheless, if one backtracks to the early 1990s, the consensus at the time was that new neurons were not created in the adult brain. Any change in the brain's information content was thought to be a matter of rearranging axonal connections between neurons or to involve alterations in other, smaller-scale structures such as dendritic spines. Then it was persuasively demonstrated that the creation of new neurons does in fact occur in adult mice.
In the grand scheme of progress in the life sciences, that something occurred thirty years ago makes it a relatively recent realization. Follow up and debate are still very much in progress. Over the past decade, a debate in the scientific literature occurred over whether the limited human data in fact supported the existence of adult neurogenesis in our own species. Matters appear to have settled to a consensus that human adult neurogenesis does occur. Nonetheless, it remains the case that most of the data for adult neurogenesis is (a) obtained from studies in mice, and (b) focused on the hippocampus, an important region for the function of memory.
Today's open access paper is a brief and readable review on the question of aging and neurogenesis in the hippocampus. Neurogenesis is interesting in this context because, as shown in mice, it declines with age. This is thought to contribute to loss of memory function, and there is a sizable contingent of researchers engaged in trying to boost neurogenesis as a possible basis for future therapies. As this review makes clear, however, after nearly thirty years of work on this topic there are still looming gaps in knowledge everywhere you look.
Extent and activity of adult hippocampal neurogenesis
There is strong evidence for human hippocampal neurogenesis occurring well into adulthood, albeit at a steadily decreasing rate, but we lack a cohesive scientific discourse surrounding its physiological role, particularly the relationship between neurogenic extent and activity. Research emphasis is generally on the former, relying on the assumption that the number of newborn neurons sufficiently explains any functional implications. This approach ignores the reality that individual neurons vary drastically in activity, even in otherwise identical cell populations. This review focuses on the relationship between the extent of neurogenesis and activity of the newborn neurons themselves, with a particular emphasis on how we might use this information to inform future studies.
Adult hippocampal neurogenesis is the process by which new neurons are generated in the dentate gyrus of the hippocampus in the adult brain. The generation of new neurons is a hierarchical, activity-dependent process that starts with radial glia-like precursors that quickly transition to progenitors before eventual differentiation into neuroblasts. This immature neuronal population matures and migrates a short distance from the subgranular zone of the dentate gyrus to the granular layer, where it integrates into pre-existing circuits.
Newly generated neurons progress through dynamic stages important for their normal functioning, finally resulting in behavioral modulation with their integration into hippocampal circuitry. This complex process is regulated by various factors that can increase or decrease neurogenesis, leading to alterations in both the number and function of newly generated neurons. For example, aging is a major physiological factor that contributes to the decline of adult hippocampal neurogenesis by pushing the neural stem cell pool into a quiescent stage and reducing the ability of neural stem cells to proliferate.
Even if the neural stem cells produce new neurons, aging impairs the survival and integration of these newborn neurons into existing circuits. Indeed, aging disrupts the dentate gyrus microenvironment by reducing synaptic density and compromising vascularization, ultimately creating a less supportive niche for neurogenesis. The dentate gyrus plays a critical role in pattern separation and episodic memory, and age-related reductions in hippocampal neurogenesis have been directly linked to cognitive decline; studies show that diminished neurogenesis contributes to impairments in spatial learning, memory precision, and cognitive flexibility, all hallmark features of age-related cognitive decline.
OTULIN as a Potential Target for Treatment of Tauopathies
https://www.fightaging.org/archives/2025/12/otulin-as-a-potential-target-for-treatment-of-tauopathies/
Alzheimer's disease is the most prominent of the tauopathies. This is a class of neurodegenerative conditions in which large enough amounts of tau protein become excessively altered by phosphorylation and aggregate into solid deposits, causing inflammation, loss of function, and cell death in the brain. The various isoforms of tau play an important role in maintaining the structure of axons that connect neurons, but aggregation would be problematic regardless of the normal function of tau.
Just as much of Alzheimer's research and development has long focused on trying to prevent, clear, or disarm misfolded amyloid-β and its toxic aggregates, a similar range of efforts is focused on finding ways to prevent, clear, or disarm hyperphosphorylated tau and its aggregates. Progress to date has been frustrating slow, just as it was for amyloid-β clearance via immunotherapy. Many of the possible paths forward appear challenging to implement well.
Today's research materials present an example of the type, an approach that potentially allows dramatic reduction in overall tau levels. Yet tau is important to axonal function, one can't just get rid of it, which presents developers with the much harder goal of achieving a balancing act with dose and outcome. Even then it tends to be the case that therapies that treat a condition in which a protein becomes altered into a toxic form by reducing overall expression of that protein tend to have unpleasant side-effects.
Novel discovery reveals how brain protein OTULIN controls tau expression and could transform Alzheimer's treatment
The research team initially hypothesized that inhibiting the enzyme activity of the OTULIN protein would enhance tau clearance through cellular garbage disposal systems. However, when they completely knocked out the OTULIN gene in neurons, tau disappeared entirely - not because it was being degraded faster, but because it wasn't being made at all. "This was a paradigm shift in our thinking. We found that OTULIN deficiency causes tau messenger RNA to vanish, along with massive changes in how the cell processes RNA and controls gene expression."
The study used neurons derived from a patient with late-onset sporadic Alzheimer's disease, which showed elevated levels of both OTULIN protein and phosphorylated tau compared to healthy control neurons. This correlation suggested OTULIN might be contributing to disease progression. "OTULIN could serve as a novel drug target, but our findings suggest we need to modulate its activity carefully rather than eliminate it completely. Complete loss causes widespread changes in cellular RNA metabolism that could have unintended consequences."
The deubiquitinase OTULIN regulates tau expression and RNA metabolism in neurons
The degradation of aggregation-prone tau is regulated by the ubiquitin-proteasome system and autophagy, which are impaired in Alzheimer's disease (AD) and related dementias (ADRD), causing tau aggregation. Protein ubiquitination, with its linkage specificity determines the fate of proteins, which can be either protein degradative or stabilizing signals. While the linear M1-linked ubiquitination on protein aggregates serves as a signaling hub that recruits various ubiquitin-binding proteins for the coordinated actions of protein aggregate turnover and inflammatory nuclear factor-kappa B (NF-κB) activation, the deubiquitinase OTULIN counteracts the M1-linked ubiquitin signaling. However, the exact role of OTULIN in neurons and tau aggregates clearance in AD are unknown.
Based on our quantitative bulk RNA sequencing analysis of human induced pluripotent stem cell-derived neurons (iPSNs) from an individual with late-onset sporadic AD (sAD2.1), a downregulation of the ubiquitin ligase activating factors (MAGE-A2/MAGE-A2B/MAGE-H1) and OTULIN long noncoding RNA (OTULIN lncRNA) was observed compared to healthy control iPSNs. The downregulated OTULIN lncRNA is concurrently associated with increased levels of OTULIN protein and phosphorylated tau.
Inhibiting the deubiquitinase activity of OTULIN with a small molecule UC495 reduced the phosphorylated tau in iPSNs and SH-SY5Y cells, whereas the CRISPR-Cas9-mediated OTULIN gene knockout (KO) in sAD2.1 iPSNs decreased both the total and phosphorylated tau levels. CRISPR-Cas9-mediated OTULIN KO in SH-SY5Y resulted in a complete loss of tau at both mRNA and protein levels, and increased levels of polyubiquitinated proteins, which are being degraded by the proteasome. In addition, SH-SY5Y OTULIN KO cells showed downregulation of various genes associated with inflammation, autophagy, ubiquitin-proteasome system, and the linear ubiquitin assembly complex that consequently may prevent development of an autoinflammation in the absence of OTULIN gene in neurons.
Together, our results suggest, for the first time, a noncanonical role for OTULIN in regulating gene expression and RNA metabolism, which may have a significant pathogenic role in exacerbating tau aggregation in neurons. Thus, OTULIN could be a novel potential therapeutic target for AD and ADRD.
The Hyaluronidase CEMIP is Involved in Demyelinating Diseases
https://www.fightaging.org/archives/2025/12/the-hyaluronidase-cemip-is-involved-in-demyelinating-diseases/
The axons that carry nerve impulses between neurons must be sheathed in myelin if they are to function. This structured myelin is built and maintained by a specialized population of cells called oligodendrocytes, which derive from a precursor population. Loss of myelin is a feature of severely disabling and ultimately fatal conditions such as multiple sclerosis. To a lesser degree, however, myelin loss also takes place with advancing age, and evidence suggests that this contributes to cognitive decline at the very least. Anything that disrupts the activity of oligodendrocytes will lead to loss of myelin, and the underlying damage that drives aging disrupts all cell populations in a variety of ways, to an increasing degree as the burden of damage rises over time.
The connection with aging is why it is worth keeping an eye on progress towards the development of therapies for multiple sclerosis. Therapies that treat demyelinating conditions may turn out be useful in older people as well. The details do matter, however. The targeted mechanisms must be applicable in both disease and aging, and it isn't always clear that this is the case. Today's open access paper is an example in which the researchers focus on multiple sclerosis patients and animal models of demyelination that have no relevance to aging. Thus the target they uncover does seem promising, but may or may not turn out to be useful outside the scope of multiple sclerosis.
The CEMIP Hyaluronidase is Elevated in Oligodendrocyte Progenitor Cells and Inhibits Oligodendrocyte Maturation
Central nervous system (CNS) demyelination occurs in numerous conditions including multiple sclerosis (MS). CNS remyelination involves recruitment and maturation of oligodendrocyte progenitor cells (OPCs). Remyelination often fails in part due to the inhibition of OPC maturation into myelinating oligodendrocytes (OLs). Digestion products of the glycosaminoglycan hyaluronan (HA), generated by hyaluronidase activity, block OPC maturation and remyelination. Here, we aimed to identify which hyaluronidases are elevated in demyelinating lesions and to test if they influence OPC maturation and remyelination.
We find that the Cell Migration Inducing and hyaluronan binding Protein (CEMIP) is elevated in demyelinating lesions in mice with experimental autoimmune encephalomyelitis during peak disease when neuroinflammatory mediators, including tumor necrosis factor-α (TNFα), are at high levels. CEMIP expression is also elevated in demyelinated MS patient lesions. CEMIP is expressed by OPCs, and TNFα induces increased CEMIP expression by OPCs. Both increased CEMIP expression and HA fragments generated by CEMIP block OPC maturation into OLs. CEMIP-derived HA fragments also prevent remyelination in vivo.
This data indicates that CEMIP blocks remyelination by generating bioactive HA fragments that inhibit OPC maturation. CEMIP is therefore a potential target for therapies aimed at promoting remyelination.
Methylglyoxal in Aortic Stiffening in Mice
https://www.fightaging.org/archives/2025/12/methylglyoxal-in-aortic-stiffening-in-mice/
In flexible, elastic tissues such as skin and blood vessel walls, large molecules of the extracellular matrix must be able to move relative to one another. When undesirable cross-links form between these molecules, tissue loses its elasticity and flexibility. Much of this undesirable cross-linking is the result of interactions with sugars, particularly via a class of compounds known as advanced glycation end-products, AGEs. In addition to the cross-linking, AGEs also provoke inflammation via interaction with the receptor for AGEs, RAGE. This is a well known harmful feature of the high-sugar, dysfunctional diabetic metabolism.
In the 1990s and early 2000s, alagebrium was developed as a drug candidate on the basis of being able to break forms of AGE-induced cross-links found in arterial tissues, and thus reduce age-related arterial stiffening in preclinical studies in mice. In addition to breaking some forms of cross-link, alagebrium was also found to scavenge methylglyoxal, a particularly obnoxious precursor to AGEs and bad actor in diabetic metabolism. Sadly, the cross-links broken by alagebrium are prevalent in mice, but not in humans. Even more sadly, the failure of alagebrium to improve arterial stiffening in human clinical trials sabotaged any likelihood of further clinical trials in diabetic patients - so we have no idea whether alagebrium may or may not have improved the human diabetic metabolism to a sufficient degree to be useful.
The challenge with AGEs is that there are a lot of them, their chemistry is notably different from one to another, the catalog is incomplete, it is unclear whether the present consensus on which AGEs are important and which are not is correct, and this continues to be a relatively poorly studied part of the field. One of the consequences is a tendency for wheels to be reinvented. One might look at today's paper in which researchers use a novel mix of supplements in mice to try to reduce the aortic stiffening induced by methylglyoxal. That alagebrium improved aortic elasticity in mice, and failed to do so in humans, strongly suggests that the effort here is a dead end (or at least says little about the actual merits of the product undergoing testing), and no amount of skating over that point in the paper's discussion is going to change that reality.
Methylglyoxal-induced glycation stress promotes aortic stiffening: putative mechanistic roles of oxidative stress and cellular senescence
In this study, we investigated the impact of glycation stress on aortic stiffness in young and old mice, induced by advanced glycation end-product (AGE) precursor methylglyoxal (MGO) and its non-crosslinking AGE MGO-derived hydroimidazolone (MGH)-1, explored the potential molecular mechanisms involved, and evaluated the therapeutic potential of the glycation-lowering compound Gly-Low. We used a series of complementary in vivo, ex vivo, and in vitro experimental approaches to determine the causal role of MGO-induced glycation stress in aortic stiffening and the putative underlying mechanisms mediating this response, including excessive oxidative stress and cellular senescence. Additionally, we explored the therapeutic potential of Gly-Low, a cocktail consisting of the natural compounds nicotinamide, pyridoxine, thiamine, piperine, and alpha-lipoic acid, in mitigating aortic stiffening, oxidative stress, and cellular senescence mediated by MGO-induced glycation stress.
While MGO has previously been implicated in endothelial dysfunction, our results demonstrate that chronic MGO exposure significantly increases aortic stiffness in young mice. This effect was particularly pronounced in our pharmacological model of glycation stress, where young adult mice exhibited a marked increase in aortic stiffness after just two months of MGO exposure. Lastly, we also demonstrate the direct influence of glycation stress in mediating age-related aortic stiffening, which underscores the critical role of AGEs in promoting aortic stiffening with aging. Notably, our results also reveal the direct impact of MGO on aortic stiffening, supporting the notion that MGO-induced glycation stress can independently drive this pathology.
Extracellular Matrix Protein Tenascin-C is Important to Muscle Stem Cell Function, But Declines with Age
https://www.fightaging.org/archives/2025/12/extracellular-matrix-protein-tenascin-c-is-important-to-muscle-stem-cell-function-but-declines-with-age/
The aging of the extracellular matrix is not as well studied as is the case for cell biochemistry. There are likely many important changes that take place in the extracellular matrix over a lifetime that meaningfully affect cell function in aged tissues, but have yet to be discovered and understood. One example is outlined here, a matrix protein that declines with age but seems necessary to maintain the normal function of muscle stem cells. Declining muscle stem cell function is one of the important contributions to the characteristic loss of muscle mass and strength that occurs with age.
Skeletal muscle regeneration occurs through the finely timed activation of resident muscle stem cells (MuSC). Following injury, MuSC exit quiescence, undergo myogenic commitment, and regenerate the muscle. This process is coordinated by tissue microenvironment cues, however the underlying mechanisms regulating MuSC function are still poorly understood.
Here, we demonstrate that the extracellular matrix protein Tenascin-C (TnC) promotes MuSC self-renewal and function. Mice lacking TnC exhibit reduced number of MuSC, and defects in MuSC self-renewal, myogenic commitment, and repair. We show that fibro-adipogenic progenitors are the primary cellular source of TnC during regeneration, and that MuSC respond through the surface receptor Annexin A2. We further demonstrate that TnC declines during aging, leading to impaired MuSC function. Aged MuSC exposed to soluble TnC show a rescued ability to both migrate and self-renew in vitro.
Overall, our results highlight the pivotal role of TnC during muscle repair in healthy and aging muscle.
Terazosin Reduces Endothelial Cell Senescence to Slow Vascular Aging in Mice
https://www.fightaging.org/archives/2025/12/terazosin-reduces-endothelial-cell-senescence-to-slow-vascular-aging-in-mice/
Senescent cells grow in number with age, lingering to cause harm via inflammatory secretions. This is a problem in every tissue. Here researchers focus on the endothelial lining of blood vessels, and demonstrate that a strategy to reduce the pace at which endothelial cells enter a senescent state can slow the development of vascular stiffness and atherosclerosis in a mouse model of these cardiovascular issues. There are many different ways in which one might go about making cells more resistant to stress-induced senescence, and here the approach is to improve cell defenses against oxidative molecules.
Terazosin (TZ), a well-known antagonist of the α1-adrenergic receptor (α1-AR), has demonstrated protective effects on vascular endothelial cells (ECs) and reduced vascular stiffness in clinical studies. Endothelial dysfunction and oxidative stress are central drivers of cardiometabolic diseases such as diabetes, where sustained reactive oxygen species burden accelerates EC senescence and barrier failure. These findings suggest its potential role in combating vascular aging and atherosclerosis; however, the underlying mechanisms remain partially understood.
In this study, we investigated whether TZ can prevent atherosclerosis in ApoE-/- mice fed a high-cholesterol diet and aimed to elucidate the mechanisms involved. Our results showed that TZ significantly reduced plaque size, EC senescence, vascular permeability, and reactive oxygen species (ROS) levels, effectively inhibiting atherosclerosis independently of α1-AR signaling.
In cultured primary human umbilical vein ECs (HUVECs), TZ inhibited EC senescence via the Pgk1/Hsp90 pathway. It enhanced the interaction between Hsp90 and the antioxidant enzyme peroxiredoxin 1 (Prdx1), leading to lower reactive oxygen species levels - a key driver of cellular senescence. These findings were confirmed in atherosclerotic ApoE-/- mice.
Furthermore, senescent ECs exhibited increased levels of vascular endothelial growth factor A (VEGFA) and decreased levels of angiostatin, contributing to higher vascular permeability and exacerbating atherosclerosis. TZ effectively reversed these changes.
Overall, our study demonstrates that TZ primarily alleviates EC senescence and atherosclerosis through the Pgk1/Hsp90/Prdx1 pathway, highlighting Pgk1 activation as a strategy that may also mitigate endothelial dysfunction and oxidative stress in broader cardiometabolic contexts (e.g., diabetes), suggesting that TZ is a promising senomorphic agent for treating vascular aging and that Pgk1-targeted interventions could have implications beyond atherosclerosis.
A Pilot MicroRNA Aging Clock
https://www.fightaging.org/archives/2025/12/a-pilot-microrna-aging-clock/
Researchers here build an aging clock based on the expression levels of three microRNAs as a proof of principle that microRNA clocks are viable. This should not be a surprise; if the past twenty years of work on aging clocks have taught us anything, it is that any sufficiently complex body of data that changes with age can be used as the basis for a clock. Clocks are now relatively easily produced. The much harder challenge is to take any given clock and amass sufficient human data to (a) demonstrate that it is usefully measuring biological age or something closely related to biological age, and (b) understand its quirks and limitations to the point at which one can trust the use of that clock in the assessment of potential rejuvenation therapies, in order to guide and accelerate progress in the field.
The extension of human longevity has intensified the search for biomarkers that capture not only chronological age but also biological aging and functional healthspan. Among molecular candidates, microRNAs (miRNAs) have emerged as promising regulators and indicators of aging-related processes. In this pilot study, we explored whether selected circulating miRNAs could serve as potential biomarkers of biological age and lifestyle-associated aging dynamics.
Based on current literature, we focused on three miRNAs - miR-24, miR-21, and miR-155 - previously linked to inflammation, senescence, and metabolic regulation. Capillary blood samples from a heterogeneous adult cohort were analyzed using quantitative PCR. Values were integrated into a composite "miRNA-3Age" model through multivariate regression analysis to estimate biological age. Associations between lifestyle variables (diet, exercise, stress, and smoking) and miRNA-based biological age were examined.
The miRNA-3Age model predicted biological age with moderate correlation to chronological age and revealed variability consistent with individual health profiles. Participants with favorable lifestyle factors (e.g., frequent consumption of fish, whole grains, and green tea; regular exercise) tended to exhibit lower miRNA-3Age estimates, whereas stress and smoking were associated with higher predicted biological age. The miRNA-3Age model provides a preliminary step toward a scalable, lifestyle-sensitive aging metric that warrants validation in diverse populations.
Lysosomal Enlargement in Aging is a Compensatory Response
https://www.fightaging.org/archives/2025/12/lysosomal-enlargement-in-aging-is-a-compensatory-response/
In nematode worms, SKN-1 is a known longevity-related gene, and researchers here explore its role in the lysosomal enlargement that occurs with aging. Lysosomes are necessary for the cellular maintenance processes of autophagy to function. Lysosomes carry out the last step in the recycling of damaged and excess proteins machinery and structures in the cell, which is to break down those materials into components that can be reused. It has been observed that lysosomes become larger in cells in aged tissues, but this is apparently a compensatory behavior rather than a form of dysfunction. It is an attempt to maintain lysosomal function and thus the health of the cell in the face of the damage of aging.
Lysosomes are critical hubs for both cellular degradation and signal transduction, yet their function declines with age. Aging is also associated with significant changes in lysosomal morphology, but the physiological significance of these alterations remains poorly understood. Here, we find that a subset of aged lysosomes undergo enlargement resulting from lysosomal dysfunction in C. elegans. Importantly, this enlargement is not merely a passive consequence of functional decline but represents an active adaptive response to preserve lysosomal degradation capacity. Blocking lysosomal enlargement exacerbates the impaired degradation of dysfunctional lysosomes.
Mechanistically, lysosomal enlargement is a transcriptionally regulated process governed by the longevity transcription factor SKN-1, which responds to lysosomal dysfunction by restricting fission and thereby induces lysosomal enlargement. Furthermore, in long-lived germline-deficient animals, SKN-1 activation induces lysosomal enlargement, thereby promoting lysosomal degradation and contributing to longevity. These findings unveil a morphological adaptation that safeguards lysosomal homeostasis, with potential relevance for lysosomal aging and life span.
The Contribution of the Aging Gut Microbiome to Alzheimer's Disease
https://www.fightaging.org/archives/2025/12/the-contribution-of-the-aging-gut-microbiome-to-alzheimers-disease/
The balance of microbial populations making up the gut microbiome changes with age in ways that are detrimental to health. Microbes generating necessary metabolites diminish in number, while microbes that provoke chronic inflammation grow in number. Further, researchers have established that is a tendency towards a distinctly different gut microbiome composition in some age-related conditions, such as Alzheimer's disease. Whether this difference over and above the more usual age-related changes acts to contribute directly to Alzheimer's disease, or is a side-effect of a dysregulated immune system or other aspect of aged metabolism, remains to be concretely determined. Here, researchers focus on microglia, the innate immune cells of the brain. Dysfunctional, inflammatory microglia are thought to be involved in neurodegenerative conditions, and one can argue for a connection to the gut microbiome.
Alzheimer's disease (AD) is a complex neurodegenerative disorder that can be caused by multiple factors, such as abnormal amyloid-beta (Aβ) deposition, pathological changes in Tau protein, lipid metabolism disorders, and oxidative stress. For decades, research into AD has been dominated by the amyloid cascade hypothesis. However, amyloid-beta (Aβ) clearance alone slows progression by only 35%. This compels increasing attention to peripheral factors in AD pathophysiology, redirecting the field from a brain-centric, amyloid-focused model toward a systemic perspective that emphasizes peripheral-central interactions.
It is now increasingly recognized that chronic, low-grade systemic inflammation, a condition often termed "inflammaging," acts as a critical driver of neuroinflammation and accelerates neurodegenerative processes. Within this framework, the gastrointestinal tract, which harbors the body's largest immune cell population and the vast metabolic capacity of the gut microbiome, emerges as a pivotal hub for originating peripheral signals that shape brain health and disease. This article reviews the direct and indirect effects of gut microbiota and its derivatives on microglia, explores their role in the pathogenesis of AD, and discusses therapeutic strategies based on gut microbiota. Although existing studies have shown the potential of these interventions, further research is needed to completely understand their application in the treatment of AD.
Reviewing the Aging of the Oral Microbiome
https://www.fightaging.org/archives/2025/12/reviewing-the-aging-of-the-oral-microbiome/
Like the gut microbiome, the composition of the oral microbiome changes with age. Some of these changes have been shown to correlate with health status, but research into this part of the commensal microbiome is nowhere near as advanced as is the case for the gut microbiome. It is unclear as to the degree to which the oral microbiome is causing issues in aging, even where mechanisms are known to exist, such as leakage of bacteria and bacterial products associated with gingivitis into the bloodstream. It is also unclear as to whether the classes of strategy shown to rejuvenate the composition of the gut microbiome can work effectively for the oral microbiome.
Evidence indicates that the composition of the oral microbiome changes with age, although findings on diversity are inconsistent, with reports of both increases and decreases in older adults. These shifts are influenced by factors such as diet, oral hygiene, and immune function. Unhealthy aging, including conditions like frailty, neurodegenerative diseases, and sarcopenia, is associated with distinct oral dysbiosis. Potential mechanisms linking the oral microbiome to aging include chronic inflammation and immunosenescence.
Although research on the oral microbiome is still in its early stage compared to that on the gut microbiome, existing studies still indicate a link between the oral microbiome and aging. The purpose of this review is to explore whether the oral microbiome, which serves as a common gateway for the microbiota of the respiratory and digestive systems, should be considered a target for predicting and delaying aging. We focus primarily on the changes in the oral microbiome during healthy aging, the characteristics of the oral microbiome in unhealthy aging states such as frailty and age-related diseases and the possible mechanisms underlying the association between the oral microbiome and aging. Finally, we summarize the current research findings and provide possible directions for microbiome-based aging interventions.
Modeling a Theoretical Upper Bound on Lifespan Resulting from Somatic Mutation
https://www.fightaging.org/archives/2025/12/modeling-a-theoretical-upper-bound-on-lifespan-resulting-from-somatic-mutation/
One can debate aspects of the way in which researchers here model what might happen if all of aging is controlled except random mutational damage to nuclear DNA, but the idea is an interesting one. Will random mutational damage to somatic cells be so much harder to eliminate than other aspects of aging that we should think ahead in this way? In tissues where cells are largely replaced, we might think that stem cell populations can at some point be repaired or replaced, and thus the mutational burden in tissues can be reduced over time via the influx of less damaged somatic cells created by the rejuvenated stem cell population. Most neurons in the central nervous system are long-lived, however, and are never replaced. We would have to postulate some very advanced technology to think that we will be able to address the stochastic mutational burden of vital cells in the brain, that damage different in every cell.
Somatic mutations accumulate with age and can cause cell death, but their quantitative contribution to limiting human lifespan remains unclear. We developed an incremental modeling framework that progressively incorporates factors contributing to aging into a model of population survival dynamics, which we used to estimate lifespan limits if all aging hallmarks were eliminated except somatic mutations.
Our analysis reveals fundamental asymmetry across organs: post-mitotic cells such as neurons and cardiomyocytes act as critical longevity bottlenecks, with somatic mutations reducing median lifespan from a theoretical non-aging baseline of 430 years to 169 years. In contrast, proliferating tissues like liver maintain functionality for thousands of years through cellular replacement, effectively neutralizing mutation-driven decline.
Multi-organ integration predicts median lifespans of 134-170 years - approximately twice current human longevity. This substantial yet incomplete reduction indicates that somatic mutations significantly drive aging but cannot alone account for observed mortality, implying comparable contributions from other hallmarks.
A Novel Form of Mitochondrial DNA Damage
https://www.fightaging.org/archives/2025/12/a-novel-form-of-mitochondrial-dna-damage/
Mitochondria retain a circular genome distinct from the DNA of the cell nucleus, a legacy of their distant evolutionary origins as symbiotic bacteria. Mitochondrial DNA damage is thought to contribute to the characteristic mitochondrial dysfunction of aging, although the relative contributions of mitochondrial DNA damage versus epigenetic changes in the nucleus that disrupt mitochondrial function remain up for debate. Researchers here provide evidence for a novel form of molecular damage to mitochondrial DNA to contribute to mitochondrial dysfunction. Once again, the question of relative contributions arises, always a challenge in everything associated with mechanisms of aging.
Mitochondrial DNA (mtDNA) is crucial for cellular energy production, metabolism, and signaling. Its dysfunction is implicated in various diseases, including mitochondrial disorders, neurodegeneration, and diabetes. mtDNA is susceptible to damage by endogenous and environmental factors; however, unlike nuclear DNA (nDNA), mtDNA lesions do not necessarily lead to an increased mutation load in mtDNA. Instead, mtDNA lesions have been implicated in innate immunity and inflammation.
Here, we report a type of mtDNA damage: glutathionylated DNA (GSH-DNA) adducts. These adducts are formed from abasic (AP) sites, key intermediates in base excision repair, or from alkylation DNA damage. Using mass spectrometry, we quantified the GSH-DNA lesion in both nDNA and mtDNA and found its significant accumulation in mtDNA of two different human cell lines, with levels one or two orders of magnitude higher than in nDNA.
The formation of GSH-DNA adducts is influenced by TFAM and polyamines, and their levels are regulated by repair enzymes AP endonuclease 1 (APE1) and tyrosyl-DNA phosphodiesterase 1 (TDP1). The accumulation of GSH-DNA adducts is associated with the downregulation of several ribosomal and complex I subunit proteins and the upregulation of proteins related to redox balance and mitochondrial dynamics. Molecular dynamics (MD) simulations revealed that the GSH-DNA lesion stabilizes the TFAM-DNA binding, suggesting shielding effects from mtDNA transactions.
Collectively, this study provides critical insights into the formation, regulation, and biological effects of GSH-DNA adducts in mtDNA. Our findings underscore the importance of understanding how these lesions may contribute to innate immunity and inflammation.
Female Sterilization and Male Castration Increase Lifespan Across Vertebrate Species
https://www.fightaging.org/archives/2025/12/female-sterilization-and-male-castration-increase-lifespan-across-vertebrate-species/
Researchers here mine human data and records from zoos to show that male castration and female sterilization increase life span in a very broad range of higher animals. Mechanisms are thought to be similar from species to species, even if the size of the effect on life span varies. In males, it appears largely connected with systemic effects of exposure to androgen hormones over a lifespan, while in females it appears largely connected to stresses resulting from reproduction. Thus in males only hormone level reduction increases life span, while in females any contraceptive approach that prevents reproduction increases life span.
Our results demonstrate that ongoing hormonal contraception and permanent methods of surgical sterilization increase vertebrate survivorship. The analysis of zoo records provides unparalleled insight into the taxonomic breadth of the lifespan response, with male castration, female surgical sterilization and ongoing female hormonal contraception linked to increased life expectancy across a broad range of species within the mammalian kingdom.
Life expectancy is increased by an average of 10-20% depending on the timing of treatment and environment the animal is exposed to, providing strong evidence for the presence of an intraspecific trade-off between adult reproduction and survival in vertebrates. Notably, however, we do not observe the very substantial, often more than 50% increases in lifespan that are observed in some invertebrate species after germ cell removal, particularly in species that are semelparous.
There is a wide species-level heterogeneity in the survival response to sterilization and contraception. What causes this remains to be determined. It has been widely hypothesized that male gonadal-specific hormone production (testosterone) contributes to shorter lifespans in males relative to females. In rodents, castration is associated with improvements in several domains of health in later life, in particular cognition and physical function. Thus, reducing male androgen signalling may broadly target multiple processes involved in the biology of ageing.
In females, increased life expectancy occurred with various contraceptive methods. Contraception reduced the risk of death from multiple causes, including infectious and non-infectious diseases. We hypothesize that the increased life expectancy in females arises from reduced allocation to reproduction and reproductive processes in adulthood, with contraception strongly reducing the direct and indirect costs of offspring production.
Mitochondrial Dysfunction as a Contribution to Atrial Fibrillation
https://www.fightaging.org/archives/2025/12/mitochondrial-dysfunction-as-a-contribution-to-atrial-fibrillation/
This paper is an example of work exploring how exactly mitochondrial dysfunction might contribute to age-related atrial fibrillation, the dysregulation of heart rhythm. It is possibly more helpful as an introduction to the roots of atrial fibrillation, meaning dysfunction in electrical connectivity and remodeling of structure in heart tissue, and how those two issues relate to one another. A perhaps surprisingly large fraction of atrial fibrillation can be at least temporarily corrected via minimally invasive surgical techniques, because in those cases the issue arises from inappropriate electrical signaling originating in small areas of the heart and connecting vessels, but once age-related changes in the heart become more widespread and severe, this stops being the case.
Atrial fibrillation (AF) is a common arrhythmia in clinical practice that often leads to severe complications such as heart failure, myocardial infarction, and stroke. It is associated with increased mortality and a significantly reduced quality of life. Current treatments for AF include risk factor control, medications for rate and rhythm control, and anticoagulation. For refractory cases, interventional procedures like cardiac radiofrequency ablation are used. However, these treatments have limitations, including adverse effects such as bleeding and a significant risk of AF recurrence. Further elucidating the mechanisms of AF development and identifying precise intervention targets are urgently needed.
The pathogenesis of AF has not been fully elucidated, but the core pathological basis for its development and maintenance primarily involves two major mechanisms: atrial electrical remodeling and structural remodeling. Electrical remodeling is mainly manifested as abnormal ion channel function in atrial myocytes, resulting in a shortening of action potential duration and increased dispersion of the effective refractory period. This creates a substrate for reentrant arrhythmias. Structural remodeling, on the other hand, involves morphological changes such as atrial fibrosis, myocardial hypertrophy, and dilation, which further promote the persistence and stabilization of AF.
Recent studies have confirmed that mitochondrial dysfunction is a central hub driving these remodeling processes. As the energy factories of the cell, mitochondria generate adenosine triphosphate (ATP) through oxidative phosphorylation, providing the necessary energy for sustained contraction, ion pump operation, and electrical signaling in cardiomyocytes. In the AF state, atrial myocytes are subjected to rapid, disorganized, high-frequency electrical excitation. The dramatic increase in energy demand leads to mitochondrial overload and accelerates mitochondrial senescence and damage.
Mitochondrial dysfunction affects intracellular ionic homeostasis and membrane excitability through dual disruptions of energy crisis (ATP insufficiency) and oxidative stress (reactive oxygen species burst). These disruptions directly impair cardiomyocyte ion channel function and expression, driving the onset and progression of AF. Mitophagy, a key mechanism for mitochondrial quality control, selectively removes damaged mitochondria to prevent reactive oxygen species accumulation and preserve the healthy mitochondrial network. However, chronic AF-related stress (e.g., calcium overload, sustained reactive oxygen species exposure) can impair mitophagy pathways, resulting in the accumulation of dysfunctional mitochondria.
This study combined bioinformatics analysis and experimental validation to uncover key genes and molecular networks underlying the interaction between mitophagy and ion channels in AF. The objective was to elucidate the molecular mechanisms underlying the "mitophagy defects -> ion channel dysfunction -> electrical remodeling" axis.
View the full article at FightAging
Methylglyoxal in Aortic Stiffening in Mice 19 December 2025 - 07:25 PM
In flexible, elastic tissues such as skin and blood vessel walls, large molecules of the extracellular matrix must be able to move relative to one another. When undesirable cross-links form between these molecules, tissue loses its elasticity and flexibility. Much of this undesirable cross-linking is the result of interactions with sugars, particularly via a class of compounds known as advanced glycation end-products, AGEs. In addition to the cross-linking, AGEs also provoke inflammation via interaction with the receptor for AGEs, RAGE. This is a well known harmful feature of the high-sugar, dysfunctional diabetic metabolism.
In the late 1990s and early 2000s, alagebrium was developed as a drug candidate on the basis of being able to break forms of AGE-induced cross-links found in arterial tissues, and thus reduce age-related arterial stiffening in preclinical studies in mice. In addition to breaking some forms of cross-link, alagebrium was also found to scavenge methylglyoxal, a particularly obnoxious precursor to AGEs and bad actor in diabetic metabolism. Sadly, the cross-links broken by alagebrium are prevalent in mice, but not in humans. Even more sadly, the failure of alagebrium to improve arterial stiffening in human clinical trials sabotaged any likelihood of further clinical trials in diabetic patients - so we have no idea whether alagebrium may or may not have improved the human diabetic metabolism to a sufficient degree to be useful.
The challenge with AGEs is that there are a lot of them, their chemistry is notably different from one to another, the catalog is incomplete, it is unclear whether the present consensus on which AGEs are important and which are not is correct, and this continues to be a relatively poorly studied part of the field. One of the consequences is a tendency for wheels to be reinvented. One might look at today's paper in which researchers use a novel mix of supplements in mice to try to reduce the aortic stiffening induced by methylglyoxal. That alagebrium improved aortic elasticity in mice, and failed to do so in humans, strongly suggests that the effort here is a dead end (or at least says little about the actual merits of the product undergoing testing), and no amount of skating over that point in the paper's discussion is going to change that reality.
In this study, we investigated the impact of glycation stress on aortic stiffness in young and old mice, induced by advanced glycation end-product (AGE) precursor methylglyoxal (MGO) and its non-crosslinking AGE MGO-derived hydroimidazolone (MGH)-1, explored the potential molecular mechanisms involved, and evaluated the therapeutic potential of the glycation-lowering compound Gly-Low. We used a series of complementary in vivo, ex vivo, and in vitro experimental approaches to determine the causal role of MGO-induced glycation stress in aortic stiffening and the putative underlying mechanisms mediating this response, including excessive oxidative stress and cellular senescence. Additionally, we explored the therapeutic potential of Gly-Low, a cocktail consisting of the natural compounds nicotinamide, pyridoxine, thiamine, piperine, and alpha-lipoic acid, in mitigating aortic stiffening, oxidative stress, and cellular senescence mediated by MGO-induced glycation stress.
While MGO has previously been implicated in endothelial dysfunction, our results demonstrate that chronic MGO exposure significantly increases aortic stiffness in young mice. This effect was particularly pronounced in our pharmacological model of glycation stress, where young adult mice exhibited a marked increase in aortic stiffness after just two months of MGO exposure. Lastly, we also demonstrate the direct influence of glycation stress in mediating age-related aortic stiffening, which underscores the critical role of AGEs in promoting aortic stiffening with aging. Notably, our results also reveal the direct impact of MGO on aortic stiffening, supporting the notion that MGO-induced glycation stress can independently drive this pathology.
View the full article at FightAging
Maximina Yun on the Wonders of the Axolotl 19 December 2025 - 05:02 PM
Dr. Maximina Yun, principal investigator at Chinese Institutes for Medical Research in Beijing (CIMR), studies some of the most amazing animals in the world: salamanders, a group of amphibians that includes newts and species such as the universally loved axolotl. On top of being cute, salamanders possess unparalleled regeneration abilities for vertebrates, being able to regrow organs and limbs.
Salamanders are also notoriously long-lived for their body sizes, with axolotls hitting around 20 years while demonstrating negligible senescence and cave olms sporting a mind-boggling maximal lifespan of over 100 years. Studying salamanders is not easy, but the potential rewards are enormous. We talked to Maximina about her interest in these animals and the ways that we can utilize their phenomenal adaptations for ourselves.
How did you become a geroscientist, and what does studying human aging mean to you personally?
I arrived in this area because of my interest in DNA repair. I did my PhD on mechanisms of genome stability and maintenance, and I had a strong interest in cellular plasticity. That is what brought me to do a postdoc in Jeremy Brockes’ lab and begin to understand the mechanisms of cellular plasticity commonly used during salamander regeneration.
Eventually, working with this model, I realized that there is a strong potential for using salamanders to understand the links between regeneration and aging. One of the reasons is that salamanders have long been considered organisms of negligible senescence. This is largely based on mortality studies indicating that the rate of death does not increase with age in salamanders, and actually this is seen in all species studied so far.
Moreover, if you go into the very early literature, you will find reports stating that we are unable to determine a salamander’s age. There is no such thing as differentiating a newt that is one year old or two years old versus one that is twenty years old. That presented a lot of potential, and I became interested from the biological side. Obviously, aging is a pressing challenge – probably the biggest challenge of the 21st century. But for me, as a biologist, what really pulled me into the field was the potential link with cellular plasticity and understanding how these two big processes, regeneration and aging, interplay.
I think salamanders are a phenomenal model. Tell me more about them – their regeneration abilities, the negligible senescence, and all the things they can do that we can’t.
Salamanders are a very special type of organism. They are amphibians, very close to Xenopus (frogs). But while Xenopus loses its regenerative ability through adulthood, salamanders keep it regardless of whether they go through metamorphosis or not. All salamander species reported so far are known to regenerate structures. It is thought that the ancestor of salamanders was able to regenerate. Actually, there is an area in Germany called Pfalz which has fossil records of ancient salamanders at different stages of regeneration. My postdoctoral mentor, Jeremy Brockes, used to have a couple of such fossils in his office and they never failed to leave me in awe.
This ability is remarkable among vertebrates. Particularly, they are the only tetrapods able to regenerate their nearly-full limbs as adults. They can regenerate parts of their brains – in experiments with newts, if you remove half the optic tectum, it will grow back. It takes a long time, over six months, but it will grow back.
They are also able to regenerate their ovaries, and work from my talented student Yuliia Haluza looking at thousands of matings over 15 years in the Dresden axolotl colony indicates that the axolotl retains fertility through lifespan, in keeping with their extreme aging resilience.
Axolotl at Vancouver Aquarium. Photo: Arkadi Mazin
They can also regenerate up to a third of their heart, their tail including the spinal cord, maxillary bones, gills. This is really remarkable. They even regrow structures they don’t necessarily need. For example, the axolotl never undergoes metamorphosis, but it can regrow its lung even though it’s never going to use the lung for breathing on land. It’s not selected for utility, which is interesting. It’s an example of residual regeneration.
They are powerful at regenerating, but there is a catch: in all known cases of regeneration – except for the newt lens, which is a particular example – you always needed the remnant of the structure in order to regrow it. However, our lab has just discovered that the limits of regeneration can be extended further: axolotls are able to regrow their thymus de novo. This means they can regrow their thymus completely from scratch, and it’s the one example of a complex organ that can be fully regrown among vertebrates! This is truly exciting, as it present a completely different regeneration paradigm and further highlights the power of this model for regeneration research.
With regards to ageing, this raises key questions too: does the thymus involute with time in axolotls, as it does in mammals? Is its age-related homeostasis enhanced due to the regenerative abilities? Largely, how does a super regenerator age? Many exciting avenues ahead of us.
When they regenerate their brains, are memory and learning preserved?
We don’t know yet. Until recently, salamanders were not fully experimentally tractable. For example, the axolotl genome only came out in 2018, and the first chromosome assembly for the Spanish ribbed newt – the most tractable newt model – came out just in 2025, an effort led by the labs of Nick Leigh, Andras Simon and mine. Compared with other model organisms, this is all too recent. However, it means we can now truly exploit the wide range of tools existing for more traditional systems. There are memory paradigms currently being developed by a few research groups, both for axolotls and newts, and we are all looking forward to the results.
I think their genome is about ten times larger than the human genome, right?
It is ten times larger. There were a lot of complicatons because most salamanders exhibit genomic gigantism. Largely due to massive expansions of repetitive elements, not genome duplication (actually, the axolotl and the Iberian ribbed newt are both diploid). As they are extremely large and highly repetitive, standard sequencing approaches did not work well. Recent advances in genome sequencing tech, particularly PacBio long-read sequencing, made this possible.
So, for geroscience, it’s a fairly new model, and they also usually have long lifespans, correct?
That’s true. Although different salamanders have very different lifespans. For axolotls, the average is 10 to 13 years of age while their maximum lifespan is about 20 or 21. Newts are significantly longer lived, and then cave olms, such as Proteus anguinus, live well over 100 years! They are all lifespan outliers based on their body size.
But we don’t know for sure, say, from your colonies?
It is in fact from our colonies! We had a 21-year-old, one of the longest-lived axolotls. When the model is so long-lived, it’s difficult to do the studies. With newts for example, there have been a lot of capture-recapture studies in the wild. Critically, whenever a salamander species has been studied in terms of lifespan, one thing is obvious: there is no increase in mortality rate with age.
So, that’s negligible senescence.
Exactly. We classify them as having negligible senescence because this has been tested in several species and none of them exhibit mortality increase with age. But nothing is known at the molecular level, and this is where our lab jumps in: in one huge project, my lab is characterizing how these animals age, and how this is different from senescent species such as us.
I’m wondering if there is a relationship between regeneration and negligible senescence in these species.
That’s exactly what we are working on right now. The first attempt to address this was through building epigenetic clocks, together with Steve Horvath’s team. We found that we can build an epigenetic clock for up to four years of aging in the axolotl, which is the early life. Past that point, it seems to stabilize epigenetically, a phenomenon we have never seen before and could relate to negligible senescence traits.
With the part of the clock that works after four years of age, we used this to ask what happens to limbs or tails which have undergone several regeneration cycles. The answer is that if you compare a forelimb that has regenerated three times versus the contralateral limb that has never regenerated, the one that has regenerated three times is epigenetically younger by DNA methylation age than the contralateral limb.
This suggests there might be some rejuvenation events associated with regeneration, which is exciting because it’s in a natural setting. This organism does it naturally; it’s not reprogramming with Yamanaka factors, and it raises multiple questions which we’re trying to address. The epigenetic and other tools we are currently developing will help providing important answers with regards to the interplay between regeneration and aging.
If I remember correctly, regeneration in forlimbs is linked to cellular senescence.
Cell senescence is elicited every time you regenerate a limb. It appears at particular stages during regeneration, and it contributes to fueling the process, particularly by secreting factors – for example, Wnt signals – that will promote plasticity (in newts) or proliferation of the neighboring cells (in axolotls).
As regeneration progresses, you cannot have these processes turned on forever. We have seen that the number of senescent cells starts to decline as the limb progresses through regeneration. This depends on clearance by the immune system, in particular the macrophages.
We know that senescent cells play a role in wound healing in mammals. Is this some sort of a remnant of this mechanism?
It’s not clear. If you read Marco Demaria’s work – he and the late Judith Campisi uncovered the roles of senescence in wound healing – they are acting by secreting PDGF factors that promote the more rapid migration of the cells to close the wound. This is a different mechanism from what we see in salamanders, which fuels formation and proliferation of the blastema progenitors.
We don’t know exactly if they are related. Whether there are commonalities between this context of “beneficial” senescence that are different from the “negative,” pro-inflammatory senescence you see in aging is a very interesting question. We would love to explore this more with others in the field.
Salamanders also appear to have a superior clearance mechanism for senescent cells, right?
The clearance we see is very effective. Not only do the dynamics of regeneration lead to regenerative limbs that have no senescent cells – you can try to find them, but you won’t – but they never linger. Not even a couple, which is remarkable. We know that macrophages are required for their clearance, but little beyond this. There is a great opportunity here to probe the basis of efficient clearance mechanism, which I am convinced could inform strategies to improve clearance in mammalian systems.
Senescent cells are proposed to play roles in limb development, is it also the case in salamanders?
This is also different from development. If you see a developing limb bud, you won’t see senescent cells, but if you induce regeneration in that developing limb bud, then you will see senescent cells. I sometimes get asked if regeneration is similar to development. I would say it is not a full recapitulation. There are many differences. Senescent cell intervention and usage is different, and there are many other aspects. Of course, some of the patterning programs used to regrow the structure are conserved between development and regeneration, but there are many differences, especially at the beginning of the process.
There’s also dedifferentiation, maybe transdifferentiation of cells during regeneration. It’s a really interesting phenomenon, something like cell reprogramming in vivo.
What we know is that salamanders are masters at regulating cellular identity and plasticity. The cells know very well what they are, and when they go back, they never forget what they are. When a limb regenerates, connective tissue only gives you connective tissue; muscle only gives you muscle.
For example, in the newt, the muscle is generated by dedifferentiation. Even though the muscle comes from dedifferentiation, the resulting regenerative progenitors never fully lose their muscle marks and they only give you muscle.
Experiments with genetic tracing, single-cell analysis, and transplantations tell you the specific tissues overall maintain their identity. Dedifferentiation is also critical for axolotl limb regrow, whereby the connective tissue cells dedifferentiate to give you all CT-derived tissues. This is one of the most important principles when these animals regenerate.
Transdifferentiation is another mechanism these animals use. For example, in the newt lens: you can remove the lens of the eye completely, and the entire lens will come back by a transdifferentiation of the dorsal pigmented epithelial cells from the iris. When you remove the lens, these pigmented epithelial cells undergo transdifferentiation to form crystalline cells that form the lens. This is one example where pure transdifferentiation is used.
But in the context of many other complex structures, we haven’t seen much of this transdifferentiation. There are recent reports, such as an exciting preprint from Wouter Masselink, Elly Tanaka and Prayag Murawala, which indicates that the tail mostly regenerates via specific stem-like progenitors. These stem cell-like cells can give you different tissues in the tail, but it’s a bit different; it’s like playing with the potency of a stem cell, not necessarily direct transdifferentiation as in the lens case.
Your group is also working on thymus regeneration in salamanders. This is exciting since thymus involution clearly plays a role in human aging.
It is really amazing because, first, it’s something you can see with your own eyes. The thymus in the axolotl sits at the base of the gills, formed by three bilateral nodules. You can remove the entire nodules including the connective tissue surrounding them, and, in six to eight weeks, the entire organ will be back. It’s a complex organ because it’s formed by thymic epithelial cells, thymic progenitors, hematopoietic progenitors, dendritic cells, endothelium, macrophages, and obviously the different lymphocytes, and everything just reappears.
We found that when these animals regenerate the thymus, they recapitulate the morphology, cell populations, and function. One can do these very cool experiments where you transplant a regenerated structure from one salamander – a thymus nodule from a salamander that is fluorescently labeled – into a [transparently] white host. Then you can see if this regenerated thymus can support the hematopoiesis and lymphopoiesis of the host.
You can see that it does, because after a year or two, this thymus nodule will still have its original thymic epithelial cells fluorescently labeled, but it will be supporting the entire thymopoiesis of the host. It’s wonderful.
How can we translate insights from these species into humans? What are the main hurdles? I must confess that every time I speak with someone about long-lived or regenerating species, I get envious. I immediately want to have those abilities.
The first thing is to do solid basic science that gets deep into cellular and molecular mechanisms. Understand what really underlies these remarkable traits, and only then you can generate a blueprint for guiding interventions.
Regarding hurdles and timescales, these are intertwined. Primarily, you need to consider the physiology and biological differences between species. Sometimes you may have a target that seems sensible, but it’s actually tied to the particular species’ physiology.
In the case of salamanders, they are ectotherms. They live at different temperatures and control their energy differently. If they’re adapted to live at 20 degrees, can we adapt their mechanisms for an organism that lives at 37 degrees? We have to think about all this. Sometimes you can try to replicate these interventions by playing with the organism’s own proteome. That’s great because you are not subject to these differences.
The biggest hurdle is: do we need one hit or ten hits to reproduce this? But that is just trial and error, leveraging datasets and doing preclinical studies. We have started to take some of our thymus findings into other models to see if we can promote thymus rejuvenation or delay involution by giving them these molecular features that the axolotl has. We’re already doing it, and it’s very exciting.
It’s great to know that you are already looking at the translational angle.
Very much so. This goes hand-in-hand with generating a solid fundamental basis.
What about the evolutionary aspect? Do we know why salamanders have preserved regenerative abilities and mammals lost them almost completely?
It is not necessarily clear in the field of regeneration whether regeneration is a conserved trait of all animals or an acquired trait and an example of convergent evolution. A number of scientists, including my postdoctoral mentor Jeremy Brockes, sustained the latter, supported by the fact that there are salamander-specific proteins involved in regeneration. It is quite possible that regeneration has evolved in salamanders in a different way than in other organisms. For example, if you look at Hydra or planarians, they regenerate in very different ways. It’s not that all organisms that regenerate use the same mechanisms. Different organisms have different solutions.
So, it’s not necessarily settled that we lost the ability to regenerate. There are still many views regarding the evolution of regeneration. Among them is the cancer connection – that organisms that regenerate very well would be more prone to cancer, but that’s not the case in salamanders. They’re actually very resistant to cancer.
They seem to have all the bases covered somehow.
Exactly. And if you think of salamanders as an organism, they occupy almost every niche. They are really evolutionarily successful. For example, you can find salamanders in Siberia. You have newts in the tundra that get frozen and stay dormant in a block of ice for long periods, but when the ice melts they just walk away. There’s a lot of adaptability there.
Obviously, humans are a threat to salamanders worldwide. The axolotl is a good example; in Lake Xochimilco, human activity resulted in water contamination from rapid urbanization and the introduction of carps into the system. They started to wipe out axolotl populations in the natural environment to the point of near extinction in their natural environment (though they exist in high numbers in pet shops and colonies!). Right now, there are efforts towards bringing them back, and we are all rooting for this.
Do you have an opinion on Michael Levin’s bioelectricity-focused research into regeneration?
Bioelectricity is very important. There were early studies in the sixties and seventies showing that reverting currents in the water prevents for example, newt limb regeneration. So, we know that bioelectricity plays an important role. It’s a way in which cells communicate. I think Mike’s work is very interesting. For the field, we want to see this expanded into how the different molecular networks impact bioelectricity and how this is coordinated during regenerative processes. It’s a very interesting angle.
You moved to China recently. How do you see China’s place in the modern geroscience landscape, and how is the research and biotech climate different from Europe?
As in many other sectors, China’s influence is growing at speed. The trend is for science to be heavily influenced by China soon. I think the government has made very right steps in investing in science and deciding China should become the next scientific powerhouse. The environment here is certainly very welcoming, increasingly so towards internationals.
The current international context has led to a significant import of foreign scientists, which are in turn strengthening China’s position worldwide. There are significant funding opportunities here, for both basic research and the biotech sphere, combined with the chance to tap into a pool of talented and super hardworking students and staff.
Things happen at a very fast pace, and the regulatory frameworks for experimentation are much more science-friendly than in Europe. There is still perhaps too much focus placed on high-impact publications, but there is a clear effort towards promoting rigorous science. I’ve been here for four months, so we’ll see how things develop, but what I’m experiencing so far is very exciting.
Do you see the agility that is often invoked with regard to China – things being done faster, more efficiently?
Things are being done much faster than anything I have ever experienced. Sometimes if you have too much speed, that can be counterproductive. But institutes like the one I am in, Chinese Institutes for Medical Research (CIMR), are set up with more than 90% of the faculty coming from Europe and the US, so it’s a bit different.
Personally, I was attracted by the idea conceived by Yi Rao and others to create an HHMI-style institute in Beijing. Here, the support system and evaluation processes are based on the success stories that happen in the West, modeling institutes like the Laboratory of Molecular Biology in Cambridge, where I did my PhD, and Janelia Farm.
One of the features of such places is also the possibility to have resources and time to explore great, bold ideas, and I feel this component is important for doing significant science. Overall, there is a view that this will lead to success here.
View the article at lifespan.io
Aging: Why Does Evolution Kill? 19 December 2025 - 03:00 PM
Why do we age at all, and why do different species age at such dramatically different rates? After decades of longevity research, biologists still disagree on the most basic questions: What is aging? Is it possible to stop or reverse it? And what strategies stand a real chance of working?
Most gerontologists explain aging as the gradual accumulation of cellular and molecular damage, much like rust in a car or the decay of a house. But this viewpoint struggles to explain a series of biological paradoxes. Tiny sparrows can live twenty years. Naked mole-rats survive twice as long. Hydra and planaria appear not to age at all. Queens in eusocial species can live fifty times longer than workers with the same genome. Some animals–jellyfish, comb jellies, and eusocial insects–can rejuvenate, yet they do so only under stress, not under ideal conditions. If youth is mechanistically available, why do they “choose” aging and death?
A new book, titled Aging: Why Does Evolution Kill?, written by Hong Kong–based professor Peter Lidsky, and published with the support of Open Longevity, offers a bold, non-orthodox answer. The book argues that classical evolutionary theories of aging are inconsistent with recent empirical and theoretical results–and develops instead a novel pathogen control theory of aging, in which aging is not just damage, but an evolved, adaptive program.
Early evolutionary thinking, dating back to August Weismann in the late 19th century, proposed that aging is a programmed process that removes maimed individuals from a population. This view fell out of favor because it relied on group selection: individuals supposedly sacrifice their own fitness for the good of the species, a mechanism later considered too weak to explain such costly traits. As a result, for much of the 20th century, theories of programmed adaptive aging were largely abandoned, and non-programmed, damage-based explanations took over.
Lidsky’s pathogen control theory revives the idea of programmed aging but grounds it in kin selection, the same well-accepted evolutionary force that explains parental care. As J.B.S. Haldane quipped, he would give his life “for two brothers or eight cousins”— a vivid illustration of kin selection, in which an individual may sacrifice even its life if this helps relatives, who share its genes, to survive and reproduce.
How, then, could death from aging ever help one’s “two brothers or eight cousins”? The book’s central claim is that the missing piece is chronic, sterilizing infections–pathogens such as syphilis or gonorrhea in humans, which do not kill quickly but prevent reproduction. Individuals carrying such infections become evolutionarily “worthless”: they cannot have offspring, and they can transmit these infections to relatives, harming their genetic interests. In this context, the early death of infected, non-reproductive individuals can be favored by kin selection.
Because the probability of acquiring such infections increases with time, evolution, according to the pathogen control theory, can favor mechanisms that remove older individuals as a function of age. In this view, aging is an immune strategy: a program that sacrifices older individuals to protect their kin from the infections they accumulate over long lives.
This perspective leads to a series of striking, testable predictions. If aging evolved to protect relatives from infection, then the population structure–who interacts and infects whom–becomes a major determinant of lifespan and aging patterns. The book argues that many “outlier” species fit this logic: eusocial insects, naked mole-rats, salmon, flying birds, and bats all have atypical population structures that can explain their unusual aging and death schedules.
In the closing chapters, Aging: Why Does Evolution Kill? explores the implications of the pathogen control theory for modern gerontology. It places aging squarely within the context of the immune system and outlines new research directions that could reshape how we think about interventions to slow or reverse aging. The book presents an ongoing research program: many of its hypotheses remain to be rigorously tested, and readers are invited to evaluate the theory critically.
Whether or not one ultimately accepts the pathogen control theory, this book offers a provocative rethinking of one of biology’s most fundamental problems. It will interest researchers, clinicians, and lay readers concerned with aging and longevity.
https://www.amazon.com/dp/B0G4R3DDH6
View the article at lifespan.io
