Mismatch Between Between Nuclear and Mitochondrial DNA Modestly Accelerates Aging in Flies

Mitochondrial transplantation is under development as a class of therapy to treat aging. Mitochondrial dysfunction is a feature of aging, and evidence from animal studies suggests that lasting improvements in health result from replacement of a fraction of native mitochondria with new, functional mitochondria delivered via intravenous infusion. Cells readily take up mitochondria from their surroundings if given the chance. The biggest challenge remains scaling up manufacture, being able to harvest from cell cultures the vast numbers of mitochondria needed to produce a reasonable level of replacement in a human patient. Work has progressed to a first in human demonstration conducted recently, but a few other companies are also moving towards human trials at some pace.

One of the most interesting questions is that of how vital it is that mitochondrial DNA haplotype matches nuclear DNA haplotype. Mitochondria are the evolved descendants of ancient symbiotic bacteria, and carry their own genome, the mitochondrial DNA. There are more than 20 distinct groupings of human mitochondrial DNA haplotypes. Over evolutionary time, most mitochondrial genes migrated into nuclear DNA, so some components of the molecular machinery in a mitochondrion come from mitochondrial DNA, some from nuclear DNA. What happens when mitochondria with a different DNA haplotype are introduced into an adult individual? What if researchers construct a much better synthetic mitochondrial DNA haplotype that outperforms all natural haplotype when it comes to producing adenosine triphosphate (ATP) with a low burden of oxidative stress, and increases the efficiency of mitochondrial quality control as well? Are there roadblocks to implementing this goal?

There is some evidence to suggest that mixing and matching between haplotypes, or changing mitochondrial haplotype in an adult individual, is modestly harmful. Today's open access paper provides more data on this front, looking at outcomes on the lifespan of flies resulting from mismatches between mitochondrial genes in nuclear DNA versus mitochondrial DNA. The effect size is around a 10% reduction in median life span, which is not all that large in a species life the fruit fly, where life span is very plastic in response to circumstances. Still, it seems likely that companies developing mitochondrial transplantation therapies will choose to be cautious and match haplotype to patient.

Mitonuclear discordance modulates mitochondrial ageing dynamics in natural Drosophila populations

Mitochondria lie at the center of cellular metabolism and are key determinants of organismal ageing. Because the oxidative phosphorylation (OXPHOS) complexes are encoded by both nuclear and mitochondrial genomes, compatibility between these genomes is essential for efficient energy production and eukaryotic life. Disruption of this intergenomic coordination, via mismatches between mitonuclear genotypes, has been shown to impair metabolism with severe life-history consequences across diverse taxa. Yet, the role of mitonuclear compatibility in shaping ageing trajectories in natural populations remains poorly understood, with evidence largely limited to inbred laboratory lines.

Hormesis describes the process where mild stress can trigger protective adaptations against ensuing perturbations. In this context, mitohormetic interventions can represent a protective strategy to promote metabolic homeostasis and healthy ageing. Here, we leveraged natural genetic variation in wild Drosophila melanogaster populations to test how mitonuclear compatibility interacts with early-life metabolic stress to shape ageing phenotypes. Two mitochondrial haplotypes coexist in D. melanogaster populations along the Australian cline: "t" (most common in the north) and "m" (most common in the south), differing by 15 single-nucleotide polymorphism (SNPs) across protein-coding genes. We generated a panel of outbred populations carrying putatively coevolved ("tT," "mM") and mismatched ("mT," "tM") mitonuclear genomes.

We demonstrate that mitonuclear mismatch accelerates age-related mitochondrial decline, elevates reactive oxygen species production, and shortens lifespan. Strikingly, early-life mitochondrial stress induced by dietary modulation counteracts these effects, promoting mitochondrial homeostasis and longevity. Our findings reveal mitonuclear interactions shaping ageing trajectories in natural populations and provide unique evidence that targeted interventions can act as a buffer against the detrimental impact of genetic discordance.

More on the Mechanisms by Which Reducing Age-Related Peroxisome Loss Extends Life

You might recall that last year researchers demonstrated an age-related decline in peroxisome number in cells. Peroxisomes carry out a range of functions related to oxidative and lipid metabolism, but are relatively poorly researched in the context of aging. The decline in number of peroxisomes modestly accelerates the pace of aging, as researchers found that forcing a normalization of the number of peroxisomes via prx-11 inhibition extended life in nematode worms. Here, the same researchers provide an update on how they think that this all works under the hood, providing evidence for peroxisome counts to affect life span via mitochondrial function.

Peroxisomes execute essential functions in cells, including detoxification and lipid oxidation. Despite their centrality to cell biology, the relevance of peroxisomes to aging remains understudied. We recently reported that peroxisomes are degraded en masse via pexophagy during early aging in the nematode Caenorhabditis elegans, and we found that downregulating the peroxisome-fission protein PRX-11/PEX11 prevents this age-dependent pexophagy and extends lifespan. Here, we further investigated how prx-11 inhibition promotes longevity.

Remarkably, we found that reducing peroxisome degradation with age led to concurrent improvements in another organelle: the mitochondrion. Animals lacking prx-11 function showed tubular, youthful mitochondria in older ages, and these enhancements required multiple factors involved in mitochondrial tubulation and biogenesis, including FZO-1/Mitofusin, UNC-43 protein kinase, and DAF-16/FOXO. Importantly, mutation of each of these factors negated lifespan extension in prx-11-defective animals, indicating that pexophagy inhibition promotes longevity only if mitochondrial health is co-maintained.

We also found that experimental perturbation of mitochondria precipitated faster pexophagy with aging, implying bidirectionality in signaling between these two organelles. Our data support a model in which peroxisomes and mitochondria track together with age and interdependently influence animal lifespan.

Link: https://doi.org/10.18632/aging.206395

The Evolved Balance of Unfolded Protein Response Activity in a Cell is Suboptimal for Longevity

That evolution does not optimize for species longevity is illustrated by the large number of small alterations in gene sequence or protein level that extend life in short-lived laboratory species such as nematode worms. Here, researchers note a trade-off between the activity of the unfolded protein response in various parts of the cell. When errors in protein manufacture and folding occur, unfolded and misfolded proteins emerge to cause harm. The unfolded protein response is triggered and acts to remove the problem proteins. Everything a cell does requires effort, and evolution has led to systems that balance that effort versus all of the other things a cell could instead accomplish. Therefore the unfolded protein response tends to operate at a level that is suboptimal for longevity in an organism. Further, it appears that assignment of that unfolded protein response effort across different parts of the cell is also suboptimal for longevity.

Disruption of proteostasis is a hallmark of aging. Given that cellular resources are limited, this necessitates a coordinated orchestration of different proteostatic subsystems. Yet, the principles governing this process, including the potential role of trade-offs, are not well defined. Here, we report a trade-off between the endoplasmic reticulum unfolded protein response (UPRER) and the cytosolic unfolded protein response (UPRcyto) in C. elegans that influences lifespan.

We find that wild-type animals maintain high UPRER activity but low UPRcyto activity, a balance actively enforced by the transcription factor LET-607 (ortholog of mammalian CREBH). Consequently, LET-607 deficiency releases this trade-off, causing a seesaw-like rebalancing: UPRER activity decreases while UPRcyto increases. Strikingly, this rebalancing contributes to longevity: animals lacking LET-607 exhibited extended lifespan in a UPRcyto dependent manner. Mechanistically, LET-607 deficiency downregulates one-carbon cycle, which provides the methyl donor S-adenosylmethionine. This subsequently alleviates H3K9me-mediated repression at the promoters of UPRcyto genes, a process involving the regulators and readers of this histone mark, leading to UPRcyto activation.

Our study reveals a transcriptional mechanism that enforces a proteostatic trade-off and demonstrates that evolutionarily acquired UPR balance in wild-type animals is suboptimal for longevity, supporting the antagonistic pleiotropic theory of aging.

Link: https://doi.org/10.1111/acel.70620

The Longevity Industry Matures By Stages

Setting aside a few early attempts, the longevity industry started in earnest in the mid-2010s. It had the feel of a hype cycle, a land rush, in the context of a broader bull market. A lot of those companies no longer exist; there are disadvantages in being first into a space. One of those disadvantages is that the first cohort in any venture has the privilege of mapping the novel pitfalls by falling into them. That is done now, and we're into the next stage, which is, quite honestly, a lot more complex, messy, diverse, and hard to explain. We know how this story ends: at some point there will be no distinct longevity industry, because the goal of slowing or reversing the aging process by addressing the underlying causes of aging directly will merge into the ordinary, day to day cut and thrust of pharmaceutical and biotech development. It will be become unremarkable to attempt to treat aging as a medical condition.

We are not there yet! From the extremely conservative point of view of those who steer large pharmaceutical industry companies, treating aging remains a distinct, unproven proposition. That will continue to be the case until novel anti-aging drugs are approved by the FDA and EMA, used by hundreds of thousands of patients, produce undeniable results, and, most importantly, generate a large amount of revenue. The number of such approved drugs is somewhat less important than the collective revenue generated. You might look at the opinion of the powers that be on weight loss drugs and how that has shifted across the advent of GLP-1 receptor agonists as an example of how this shift in will take place for the first very successful anti-aging drugs.

But back to what the longevity industry looks like now, and how that differs from the early days. Today's open access paper offers an opinion on the topic, backed by some analysis. It is an interesting read, albeit very focused on just a few parts of the mainstream of the field, the most popular topics. For my part, I'd have to say that I think matters would be fairly different if the bull market in biotech and pharma had sustained itself across the 2020s rather than vanishing into geopolitics and doldrums. A new industry struggles to forge itself in an environment where funding is tight all round. Much of the present character is the character of an industry in which it is exceptionally challenging to raise funds for clinical development, no matter the promise of the technology in question. But this too shall change.

From lifespan extension to hallmark-informed gerotherapeutic prioritization: A bibliometric-guided, strategy-oriented review of anti-aging drug research

Aging is increasingly understood as a shared upstream biological process that increases vulnerability across cardiovascular, neurodegenerative, metabolic, musculoskeletal, renal, and neoplastic disorders. This view was crystallised by the original hallmarks framework and reinforced by its expanded update, which organise aging into interconnected molecular and cellular processes rather than isolated organ-specific events. The translational implication is substantial because interventions directed at aging biology could, in principle, delay or modify several age-related conditions rather than treating each disease independently. The interdependence of aging hallmarks also provides a rationale for evaluating secondary cross-hallmark effects.

Over the past decade, geroscience has moved from a conceptual proposition to an intervention-oriented discipline aimed at extending healthspan and disability-free survival. This shift has been driven by growing recognition that aging is biologically malleable and clinically consequential at the population level. Mechanisms such as cellular senescence, deregulated nutrient sensing, mitochondrial dysfunction, chronic inflammation, loss of proteostasis, and impaired stress adaptation are now regarded as potentially tractable pharmacological entry points. Accordingly, gerotherapeutic development increasingly requires alignment between molecular or pharmacological design, an aging-related biological vulnerability, measurable target engagement, an appropriate population, and a clinically meaningful endpoint.

The landscape of anti-aging drug research has shifted markedly from exploratory lifespan-extension studies toward a more structured, mechanism-informed, and translationally aware framework. Bibliometric analysis reveals that the field coalesces around three partially overlapping intervention logics - senescence-directed therapeutics, nutrient-sensing and metabolic modulators, and homeostasis-restoring compounds - each anchored in reproducible biological hallmarks. These axes collectively provide a coherent rationale for prioritizing interventions based not solely on historical visibility but on mechanistic plausibility, preclinical evidence, and early human translational signals.

Aspects of Gut Microbiome Composition Correlate with Frailty in Women

The composition of the gut microbiome changes with age in ways that negatively impact health. There is enough variance in this process of change that correlations can be observed between specific species and metrics of overall composition on the one hand and risk or status of disease on the other. Researchers are building a growing body of knowledge regarding such correlations, and in many cases have found mechanisms indicating that a poor composition of the gut microbiome is a contributing factor in the development and progression of age-related disease. This is a matter of which metabolites are produced by the gut microbiome and in what amounts; some metabolites are necessary for health, others are harmful or provoke chronic inflammation. This work is the first step towards the development of therapies that can alter the composition of the gut microbiome in specific, tailored ways in order to improve health and slow the progression of aging.

Although commonly used tools, such as the Fried Frailty Phenotype, the Rockwood Frailty Index and the Clinical Frailty Scale, capture specific aspects of frailty, existing indices often fail to encompass its full functional, psychological, and physiological dimensions. The Charlson Comorbidity Index (CCI), while widely adopted for mortality risk stratification, is disease-centric and lacks sensitivity to the broader construct of frailty. To better capture this multidimensional nature, we developed the Frailty Mortality Index (FMI), a composite measure integrating functional and psychosocial aspects in addition to comorbidities. Specifically, the FMI is defined by anthropometrics (age and weight), physical function (walking speed and chair stand), current smoking, mental quality of life (QoL) survey, hospital stay duration, and the CCI.

The gut microbiome is increasingly recognized as a regulator of host physiology and potential contributor to frailty pathophysiology. It influences systemic inflammation, metabolism, musculoskeletal function, and immune and neuroendocrine signaling. While aging alters gut microbiota composition and function, gut microbiome profiles observed in frailty differ from those associated with healthy aging, reflecting not just chronological age but also deterioration of physiological processes.

In this work, we use metagenomic sequencing to investigate species-level features associated with frailty-related phenotypes captured by the FMI in SUPERB, a large Swedish cohort including 2,081 women aged 75-80 years. We demonstrate that the FMI is more strongly associated with frailty-related clinical outcomes, including injurious falls, hip fractures, and mortality, than the CCI. We further show that higher FMI is associated with reduced microbiota diversity, including lower gene richness and Shannon index. At the species level, FMI is associated with different species in Enterocloster, Clostridium, Dysosmobacter and Faecalibacterium in models accounting for the overall decline in microbiome gene richness associated with ageing, thereby distinguishing FMI-associated microbial features from general microbiota decline.

Link: https://doi.org/10.1038/s41467-026-75176-5

TNF-α Inflammatory Signaling Suppresses Neurogenesis

Neurogenesis is the name given to the creation of new neurons in the central nervous system, arising from neural stem cell populations, maturing, and then merging with existing neural networks. Neurogenesis is essential to memory and to the maintenance of brain tissue, the only way to replace neurons lost to damage or dysfunction. The pace of neurogenesis declines with age and in neurodegenerative conditions. Here, researchers investigate the link between inflammatory signaling and lost neurogenesis. The aged brain, like the aged body, is characterized by continual unresolved inflammatory signaling, a maladaptive reaction to forms of cell and tissue damage that changes cell behavior for the worse. It is disruptive to tissue structure and function. Any comprehensive package of rejuvenation therapies will have to include some way to address unwanted chronic inflammatory signaling without sabotaging the normal function of the immune system; so far, this has proven to be a difficult challenge.

Adult hippocampal neurogenesis is essential for learning, memory, and mood regulation, and its disruption is implicated in ageing, neurodegeneration, and mood disorders. However, the mechanisms linking inflammation to adult hippocampal neurogenesis impairment remain unclear. Here, we identify chronic tumour necrosis factor-alpha (TNF-α) signalling as a key driver of neurogenic dysregulation via a previously unrecognised type I interferon autocrine/paracrine loop in human hippocampal progenitor cells.

Using a female-derived human in vitro neurogenesis model, single-cell RNA sequencing, and functional T cell migration assays, we show that tumour necrosis factor-alpha induces a robust type I interferon response in hippocampal progenitor cells, promoting chemokine-mediated and CXC motif chemokine receptor 3 (CXCR3)-dependent T cell recruitment and suppressing neurogenesis. This inflammatory signalling cascade drives a fate switch in hippocampal progenitor cells from a neurogenic trajectory towards an immune-defensive phenotype, with critical implications for infectious and inflammatory disease pathogenesis.

These findings uncover a key inflammatory checkpoint regulating human adult hippocampal neurogenesis and highlight potential therapeutic targets to restore neurogenesis in chronic inflammatory states.

Link: https://doi.org/10.1038/s41467-026-74104-x

Change Over Time in Epigenetic Clock Measures Correlates with Mortality

Aging clocks can be built from any sufficiently complex set of biological data measured in a sufficiently large number of people across a sufficiently large range of different ages. Machine learning techniques are used to find algorithmic combinations of data points that predict age to some sufficient threshold of accuracy. The algorithm is then applied to people who were not in the original sample populations, and most such clock algorithms do an acceptably good job of hitting the mark when considered over groups of people. Unfortunately they are not all that useful for an individual; in part the variance is a problem, but the main challenge is that it is entirely unclear in most clocks as to what the results actually mean. It is also unclear as to how we should expect any given clock to react to any given intervention used to treat aging.

The best path forward to making aging clocks useful for individuals, and for the assessment of novel therapies to treat aging, is probably to collect as much data as possible and observe the emerging patterns. Classes of therapy will have to be assessed in parallel with clocks. Different populations and different strategies for clock use will have to be assessed against actual outcomes, such as mortality rate and disease incidence years later. This won't be a fast process.

Nonetheless, interesting new findings emerge on a fairly regular basis as the use of clocks spreads. In today's open access paper, for example, research demonstrate that change over time in clock assessments is a useful piece of information, perhaps much more useful than single measures. This is particularly relevant to the use of clocks by an individual rather than in a population study, as many of the unknowns become irrelevant when one person uses the same clock repeatedly over a period of years to measure something that may be closely related to the pace of biological aging.

Longitudinal changes in epigenetic clocks predict survival in the InCHIANTI cohort

Over the past years, several proxy biomarkers of biological aging have been developed and validated, with the most advanced using data from DNA methylation. Broadly termed 'epigenetic clocks,' these methylation-based markers of aging have been shown to predict several adverse health outcomes, including mortality, independently of chronological age.

However, whether longitudinal changes in these phenotypes provide additional information on health outcome prediction over and beyond one single measure has not been demonstrated. Based on cross-sectional studies, we cannot definitively exclude that deviations of DNA methylation age from chronological age are determined early in life and are not modulated by behavioral, environmental exposures or changes in health status. In addition, if biological aging clocks are to be used to track the effectiveness of intervention over time, it is important to demonstrate that deviations of epigenetic clock trajectories reflect meaningful changes in health status.

In this longitudinal study of 699 adults from the InCHIANTI cohort followed for up to 24 years, we evaluated whether temporal acceleration of several epigenetic clocks-including first-, second- and third-generation epigenetic clocks-was associated with mortality. We found that faster increases in several clocks were linked robustly to higher risk of death, independent of baseline epigenetic age and other confounders. These findings suggest that dynamic changes in epigenetic aging reflect evolving health status and may serve as sensitive indicators for interventions aimed at extending healthspan and longevity.

Reviewing the Many Different Ways a Cell Can Enter the Senescent State

When a cell becomes senescent, it ceases replication, grows in size, and devotes its energies to secreting a potent mix of pro-growth, pro-inflammatory signals. Cellular senescence serves useful purposes in embryonic development, wound healing, and suppression of cancer. It also marks the Hayflick limit on replication of somatic cells; a somatic cell either undergoes programmed cell death or becomes senescent on reaching the Hayflick limit. In those scenarios, the senescent cells are destroyed by the immune system shortly after serving their purpose. Unfortunately, the aging immune system becomes ever less capable of efficiently clearing senescent cells, and senescent cells begin to accumulate. Their signaling becomes harmful when sustained over the long term, disruptive to tissue structure and function. This is an important component of degenerative aging.

Senescence is a highly heterogeneous phenotype, and this heterogeneity arises from several layers of biological diversity. Different cell types may vary in their susceptibility to enter senescence and in the molecular pathways they activate upon entering this state, in addition to the core cell-cycle arrest machinery. This context-dependent variability is pronounced, such that senescent cells do not share a universal molecular signature, necessitating the use of multiple markers for their accurate identification. Microenvironmental conditions, including inflammatory cues, extracellular matrix composition, oxygen levels, and immune context, further shape the senescence response and senescence-associated secretory phenotype (SASP). Moreover, distinct senescence-inducing stimuli may engage overlapping but not identical signaling networks, leading to variation in gene-expression profiles, metabolic changes, and secretory programs. Together, these factors can create a spectrum of senescent cell phenotypes that differ in their impact on tissue physiology.

In this review, we focus on the major inducers of cellular senescence. While well-established inducers such as DNA damage and oxidative stress are central drivers of senescence in aging and disease, we also discuss physiological and context-specific triggers to provide a more comprehensive and integrative perspective on senescence induction. Starting from the first-described form of senescence, replicative senescence associated with prolonged cell culture, we provide a comprehensive overview of the major inducers of cellular senescence, including DNA damage, oxidative and mitochondrial stress, telomere attrition, oncogene activation, cell-cell fusion, senescence-induced senescence and developmental stimuli, and summarize the molecular mechanisms through which they trigger the senescence program. Integrating insights into these distinct stimuli, the signaling pathways they engage, and their functional consequences might help to clarify how distinct populations of senescent cells contribute to aging, cancer, and age-related pathologies, and assist in the development of new therapeutic strategies aimed at modulating senescence and its deleterious consequences without deteriorating its beneficial functions.

Link: https://doi.org/10.18632/aging.206391

Unclear Effects of Nutritional Interventions on the Burden of Cellular Senescence

An interesting question with regard to the growth in the age-related burden of senescent cells is the degree to which it is altered by lifestyle choice. Or, to put it another way, we know the degree to which better lifestyle choices affect pace of aging and life expectancy: how much of that effect is due to a reduced burden of senescent cells? Can the existing burden be reduced by better lifestyle choices, and by how much? Here, researchers review the evidence for dietary lifestyle choices to influence cellular senescence and find it lacking, as the existing body of clinical trial data is not large enough and consistent enough to support definitive statements. As the researchers note, the data is supportive of the hypothesis that dietary choice has more of an impact on the behavior rather than number of senescent cells. The burden remains.

Cellular senescence is a fundamental mechanism of ageing, characterised by stable cell cycle arrest and the acquisition of a pro-inflammatory secretory phenotype (SASP). Nutritional interventions are widely proposed to modulate ageing biology, but their effects on cellular senescence in humans remain unclear. We systematically synthesised evidence from interventional human studies assessing the impact of nutritional strategies on biomarkers of cellular senescence.

Twenty-nine articles (27 trials; 3,811 participants) were included. Across studies, nutritional interventions modulated multiple senescence biomarkers to varying extents, with calorie restriction producing the most recurrent reductions in circulating inflammatory and secretory factors commonly included in SASP panels as well as senescence-associated transcriptomic signatures. Classical markers of cell cycle arrest (e.g., CDKN2A/p16, CDKN1A/p21) and telomere length were largely unchanged or highly variable. Calorie restriction mimetics, particularly metformin and rapamycin, showed context-dependent effects, most evident under conditions of metabolic or physiological stress. Among dietary supplements, n-3 polyunsaturated fatty acids may modulate selected inflammatory/SASP-related circulating markers, although the evidence for dietary supplements remains limited and heterogeneous.

In humans, available evidence suggests that nutritional interventions may preferentially affect senescence-associated inflammatory and secretory biomarker profiles, particularly SASP-related mediators, rather than markers more directly related to senescent cell abundance. However, because SASP factors and circulating cytokines are heterogeneous and not specific to senescent cells, these findings should be interpreted as evidence for possible modulation of senescence-associated markers rather than definitive effects on senescence burden. These observations support the use of multi-marker and functionally relevant endpoints in future clinical studies targeting biological ageing and cellular senescence.

Link: https://doi.org/10.1016/j.arr.2026.103224

Proposing the Synergy of Therapeutic Plasma Exchange and Partial Epigenetic Reprogramming

It seems a little early in the development of partial epigenetic reprogramming as a class of therapy to be thinking about which of the other approaches to aging it can best be combined with. Nonetheless, a proposal for therapeutic plasma exchange and partial epigenetic programming to go well together is the topic of today's open access paper. The argument is that these two classes of approach are addressing different layers of the dysfunction of aging, and should this do little to interfere with each other's benefits.

Until such time as someone comes up with a safe, viable small molecule reprogramming therapy, it seems likely that reprogramming will remain quite limited in scope because of the delivery challenges inherent in gene therapy. Very few delivery systems have any potential to deliver a payload well to the whole body (or even most of the body), and none of the established options are capable of this outcome. Even when delivery is good for a given tissue, the many different cell types making up that tissue likely vary widely when it comes to optimal dose and duration of reprogramming agents. It is a challenge.

On the therapeutic plasma exchange front, even the most basic, initial questions around dosing and efficacy remain to be answered. Because there is little profit in this type of therapy, no-one with deep pockets has any incentive to run the extensive trials that would be needed to provide definitive answers. As things stand, it seems likely that forms of therapeutic plasma exchange and plasma dilution will spread throughout the medical tourism space, but no firm data will emerge in the near future. This the case for numerous therapies adopted by clinics outside the US and Europe, but which do not bring in enough revenue for someone to sponsor formal clinical trials.

Systemic recalibration and epigenetic resetting as complementary strategies in ageing biology

Systemic and cellular rejuvenation strategies differ fundamentally in their therapeutic targets and in the biological level at which they intervene. Systemic interventions such as therapeutic plasma exchange or young blood administration primarily modify the extracellular and circulating environment. Through removal of pro-ageing and pro-inflammatory factors, or provision of pro-youthful factors, these approaches may improve intercellular communication and reduce adverse systemic influences such as chronic inflammation. Their principal strength lies in the breadth of action across multiple tissues. Their principal limitation is that they do not directly reverse intracellular age-associated changes. Cells with aged epigenomes, altered transcriptional programmes, and accumulated damage may therefore remain only partially responsive.

Partial reprogramming intervenes at the level of intracellular ageing mechanisms. It directly addresses loss of epigenetic information, which the Information Theory of Ageing proposes as the fundamental cause of mammalian ageing. By resetting elements of the epigenetic landscape, partial reprogramming reverses age-associated states such as mesenchymal drift and metabolic dysfunction at their source. Its principal strength lies in mechanistic depth. Its limitation is contextual dependence, because a persistently aged tissue environment may still impose inflammatory, structural, and extracellular constraints that partial reprogramming alone cannot fully resolve. The most important translational question is not which strategy is generally superior, but which biological constraint dominates in a given disease setting and whether both levels require simultaneous intervention.

The dilution hypothesis is examined together with its limitations and the unresolved complexities of systemic interventions. The challenge of cell-autonomous ageing is also considered, particularly the persistence of cell populations that remain refractory to systemic rejuvenation. A conceptual framework integrating these two axes of ageing is then presented. This framework suggests that combined systemic recalibration and targeted partial reprogramming warrant further investigation as a multimodal approach to ageing intervention. Future research priorities include mechanistic clarification of this systemic-cellular interaction and development of robust biomarkers to evaluate multimodal interventions.

Epigenetic Aging in Intervertebral Disc Degeneration

Every mechanism of aging influences all of the other mechanisms of aging. Our biology is a big tangled ball of interactions. As a follow up to a recent post on the connection between mitochondrial dysfunction and senescent cell accumulation in the context of intervertebal disc degeneration, here find a different viewpoint that focuses on the connection between epigenetic aging and senescent cell accumulation. In the nucleus of the cell, epigenetic decoration of nuclear DNA and supporting molecules control its structure; these decorations include DNA methylation and modifications to the histone proteins that DNA is spooled onto. Structure in turn determines which genes are expressed, which proteins manufactured. Patterns of epigenetic control over nuclear DNA structure change with age in characteristic ways, some mix of adaptive and maladaptive reactions to other mechanisms of aging, possibly mixed in with a fundamental disruption to this system of control deriving from the repeated operation of DNA repair.

Intervertebral disc degeneration (IDD) is the leading pathological cause of low back pain, while current clinical treatments are only palliative and cannot reverse the programmed cellular senescence driven by epigenetic dysregulation. This process is characterized by progressive loss of nucleus pulposus (NP) cell identity and establishment of a self-amplifying senescence-associated microenvironment. In this review, we synthesize recent advances elucidating how heterogeneous senescent cell populations and their secretory phenotype (SASP) orchestrate a destructive vicious cycle in IDD.

We further dissect the synergistic interplay among DNA methylation, histone modifications, and non-coding RNAs that constitutes the "epigenetic aging clock" and drives premature cellular aging within the disc. Notably, we evaluate emerging therapeutic strategies aimed at clock reversal, including senolytic clearance of senescent cells, epigenetic remodeling using small-molecule inhibitors or CRISPR-Cas9 editing, and cellular reprogramming approaches ranging from induced pluripotent stem cell (iPSC) differentiation to direct lineage conversion. We propose a synergistic "clear, prime, then seed" roadmap that sequentially combines these interventions for optimal regeneration. This work provides a systematic theoretical framework for the clinical translation of epigenetic-targeted therapy for IDD, and breaks through the cognitive limitation of traditional mechanical wear theory.

Link: https://doi.org/10.3389/fragi.2026.1842955

Extracellular Vesicles Link Inflammation in the Body to Accelerated Neurodegeneration in the Brain

STING is a master regulator of inflammatory signaling, triggered by a range of different sensor proteins for foreign material or forms of damage within a cell. With age, these sensors become overly active even in the absence of the usual stimuli, such as the presence of infectious agents, and the resulting inflammatory response is maladaptive, spreading harms further rather than helping the situation. Continual, unresolved inflammatory signaling is characteristic of old age, and it is disruptive to tissue structure and function. Here researchers note that inflammatory signaling in the body harms the brain via long-range communication between cells that is mediated via production and uptake of extracellular vesicles. Vesicles are small membrane-wrapped packages of molecules, carrying information from one cell to another. Their contents can change dramatically depending on the state of the originating cell, and this is one of the ways in which harms can spread, particularly in the context of chronic inflammation.

All animals age. However, aging is a heterogeneous process, and individual organisms age differently. Moreover, within the same organism, cells or organs do not age at the same speed. For instance, neurodegeneration, a hallmark of aging, generally manifests later than other peripheral aging signs. The genetic determinants of aging are not completely understood.

Gain-of-function (GoF) mutations in leucine-rich repeat kinase 2 (LRRK2GoF) are major genetic risk factors for Parkinson's disease (PD). By analyzing PD patients and LRRK2GoF mice, we show that PD represents an accelerated aging disorder driven by STING-dependent inflammation. This inflammation begins peripherally, disrupts the blood-brain barrier, and causes dopaminergic neurodegeneration.

Mechanistically, aging or LRRK2GoF causes endolysosomal decline, resulting in cytosolic self-DNA accumulation and the release of DNA-containing extracellular vesicles (EVs) that activate the cGAS-STING pathway within and between cells. Our findings identify LRRK2GoF as a key driver of accelerated aging and systemic inflammaging through DNA-containing EVs, highlighting potential therapeutic targets to counteract inflammaging and neurodegeneration.

Link: https://doi.org/10.1016/j.celrep.2026.117640

Increased SIRT3 Expression Improves Mitochondrial Function to Treat Intervertebral Disc Degeneration in Mice

Intervertebral disc degeneration is a complex dysfunction in the tissue maintenance and tissue properties of the discs between vertebrae. The discs allow flexibility of the spine, cushion impacts, and hold the spine together. Weakening of disc structures leads to tears and other failures that produce a sizable negative impact on the ability of an individual to function. A large subset of the population shows measurable degeneration of intervertebral discs even before reaching age 40, and after that point it becomes a majority. This is a universal aspect of aging, and the question is only how long it will take before something important breaks under stress.

Interestingly, intervertebral disc degeneration is strongly connected to cellular senescence. There are clear lines to be drawn between the burden of senescent cells and the mechanisms leading to loss of disc structural integrity. Senolytic therapies to selectively clear senescent cells have done well in animal models of degenerative disc disorders. Similarly, mitochondrial dysfunction is also strongly linked to intervertebral disc degeneration. Both loss of mitochondrial function and burden of senescence are correlated - the former tends to increase the pace at which the latter grows. It is interesting to note today's open access study, in which improved mitochondrial function also reduces cellular senescence in the course of restoring some lost function to an aged tissue.

Activation of Sirt3 reprograms mitochondrial function to regenerate intervertebral disc degeneration

Intervertebral disc degeneration is the principal pathological basis of low back pain. Currently, there are limited therapeutic strategies to regenerate intervertebral disc. In this study, we found the expression of SIRT3 is significantly negatively correlated with the degree of disc degeneration in humans. In mice, knockout of Sirt3 resulted in pronounced disc degeneration accompanied by increased expression of inflammatory mediators and senescence-associated factors.

Transcriptomic analyses in mice revealed that Sirt3 deficiency was closely associated with dysregulation of calcium signaling pathways and impaired adenosine triphosphate (ATP) synthesis. Bioinformatics analyses identified Ckm and Atp2a1 as hub genes linking Sirt3 deficiency to calcium homeostasis disruption and ATP metabolic dysfunction.

Importantly, the administration of Sirt3 activator 2-APQC in a D-galactose-induced aging mouse model significantly ameliorated intervertebral disc degeneration-associated pathological changes, evidenced by restored mitochondrial function, reduced inflammation and cellular senescence, and rescued expression of hub genes Ckm and Atp2a1.

It is Never Too Late to Make Better Lifestyle Choices

Studies tend to show that even a late life adjustment of lifestyle can meaningfully improve health and reduce mortality risk. It is never too late to gain some benefit from a better diet, more physical activity, greater physical fitness, and loss of excess visceral fat tissue. As an illustration of this point, researchers here show that older people who improve their lifestyle choices exhibit a sizable reduction in the risk of cognitive impairment versus those who retain a poor set of lifestyle choices.

This study included 6,765 older adults from the Chinese Longitudinal Healthy Longevity Survey. Data on lifestyle, including dietary habits, sleep quality, physical, cognitive, and social activity were self-reported from 2008 to 2014. Cognitive function was measured using the Mini-Mental State Examination from 2014 to 2018. Over a mean follow-up period of 5.9 years, 1,659 participants (24.5%) developed cognitive impairment. Three distinct lifestyle behavior trajectory classes were identified: "Low-Declining" (n = 4,342, 64.2%), "Moderate-Improving" (n = 1,777, 26.3%), and "High-Declining" (n = 646, 9.5%).

Compared with the Low-Declining group, the Moderate-Improving group was associated with a lower risk of cognitive impairment (hazard ratio, HR = 0.368), a longer time to cognitive impairment onset (mean = 6.433 years) and a slower rate of annual cognitive decline (0.806 points per year). Similarly, the High-Declining group showed a reduced risk (HR = 0.629, delayed onset (mean = 4.969 years) and a slower decline rate (0.543 points per year) compared with the Low-Declining group. Thus an upward trajectory of moderate lifestyle engagement, as well as a high but declining class, was associated with better cognitive outcomes compared with persistently low or declining engagement.

Link: https://doi.org/10.1186/s13690-026-02007-w

Considering Replacement Based Therapies to Treat Aging

How far can one go, practically speaking, and in the relatively near future, to develop therapies to treat aging based on replacement of worn parts? Some forms of replacement therapy have existed for decades, and have arrived at a fairly sophisticated level of development. These approaches include organ transplantation and replacement of damaged bone with non-biological materials. These therapeutic options have their limitations and drawbacks, the largest of which is the need for major surgery. One view of the present era in biotechnology is that it represents an effort to move from approaches requiring major surgery to approaches that regrow and replace tissues in situ without major surgery, based on either cell therapies or manipulation of native cell populations. This transition is a slow one, clearly.

Recent discoveries and therapeutic developments in longevity science have made it increasingly clear that a vast amount of age-related damage and systemic changes at the level of molecules, organelles, cells, tissues, organs, and organisms must be reversed to yield durable and multi-tissue rejuvenation as well as further extensions in healthy lifespan. Advanced biological and synthetic replacement, maintenance, and multi-targeted damage-removal strategies for cells, tissues, and organ systems represent some of the most promising longevity interventions, with the potential to reverse an unprecedented fraction of age-related changes, and to prevent, slow, or even reverse age-related diseases and dysfunction.

We define replacement-based ageing interventions as strategies that replace cells, tissues, organs, physiological systems, or cellular components (e.g., mitochondria or genes) with biological or synthetic alternatives. Biological replacements include transplantation of stem cells, organs, and bioprinted tissues (e.g., progressive brain replacement using cells and biomaterials), bioengineered cell therapies (e.g., CAR-T and synthetic cells), and therapeutic plasma exchange. Synthetic replacements include prostheses, external medical devices (e.g., dialysis machines), and brain-machine interface systems (e.g., cortical implants).

Replacement-based approaches are predicted to act synergistically with emerging regeneration and synthetic damage-removal technologies capable of targeting and exporting hundreds of molecular and organellar damage types from cells without relying solely on inherently limited and declining endogenous repair, clearance, and export processes.

Link: https://doi.org/10.1111/acel.70516