LongeCityNews Last Updated: 28 April 2026 - 03:41 PM

Presently largely irreversible lung disease like idiopathic pulmonary fibrosis and chronic obstructive pulmonary disease were one of the first conditions targeted for the development of senolytic therapies to clear senescent cells. A range of evidence supports a prominent role for an increased burden of senescent cells in airway and lung tissues in these conditions. Here, researchers discuss a more recent approach to senolytic therapy, employing a proteolysis-targeting chimera approach to make the cell break down one of the proteins involved in senescent cell survival. Senescent cells, unlike normal cells, are primed to undergo the programmed cell death of apoptosis. They are only held back from that fate by the activity of a few proteins, including BCLXL, which is the target here. When levels of BCLXL are dramatically reduced, senescent cells undergo apoptosis while normal cells are largely unaffected.

Ageing and cellular senescence significantly contribute to the progression of age-related diseases, particularly chronic obstructive pulmonary disease (COPD). Cellular senescence refers to the cessation of cell division in response to stress and damage. While senescent cells remain metabolically active, they secrete pro-inflammatory factors that drive disease progression. Senolytic therapies aim to selectively target and eliminate these senescent cells by inducing their apoptosis. This study examines the senolytic potential of BCLXL-PROTAC, a novel proteolysis-targeting chimera designed to degrade BCLXL, in small airway epithelial cells and fibroblasts from patients with COPD.

Treatment of COPD small airway epithelial cells and fibroblasts with BCLXL-PROTAC led to their apoptosis through the activation of caspase 3, along with a reduction in senescence markers such as p21CIP1, p16INK4a, and senescence-associated β-galactosidase. The effects of BCLXL-PROTAC were selective for senescent cells and did not affect non-COPD cells. The clearance of COPD small airway epithelial cells and fibroblasts by BCLXL-PROTAC was associated with an increase in the proliferation marker Ki67 and enhanced cell proliferation. Additionally, in precision-cut lung slices obtained from COPD patients, BCLXL-PROTAC significantly reduced p21CIP1 expression in the airway epithelium, validating its effectiveness in a more complex tissue environment.

These findings demonstrate that BCLXL-PROTAC is a potent and selective senolytic agent that may promote lung cell rejuvenation, supporting its potential as a novel therapeutic strategy for age-related diseases, including COPD.

Link: https://doi.org/10.1111/acel.70487

Senescent cells accumulate with age, but not all senescent populations are equal. Evidence suggests that some types of senescent cell cause more harm than others, and the research here is an example of this. Researchers find that a population of senescent macrophages in liver tissue acts as an important driver of chronic inflammation and dysfunction in liver aging and the metabolic liver disease associated with excess fat tissue that leads to cirrhosis and cancer. Senolytic therapies that selectively destroy the senescent macrophages reduce liver inflammation and liver dysfunction in mice, proving the point.

Cellular senescence drives chronic sterile inflammation during aging via the senescence-associated secretory phenotype, yet the senescent cell types responsible are poorly defined. Macrophages share multiple features of senescence, including inflammatory secretion, yet whether macrophages can adopt a senescent state remains unclear. Here we identify p21+Trem2+ senescent macrophages as a major source of inflammaging, using primary mouse and human macrophage models of DNA damage and cholesterol-induced senescence characterized by multi-omic profiling.

We found that senescent macrophages exhibit a distinctive p21-TREM2 expression profile and senescence-associated secretory phenotype, driven in part by type I interferon signaling via cytosolic mitochondrial DNA. We also found that senescent macrophage accumulation occurs in aging, metabolic dysfunction-associated steatotic liver disease mouse livers, and is enriched in human cirrhotic liver tissue. Finally, senolytic treatment targeting senescent macrophages reduced liver inflammation and steatosis in both aged mice and mice with metabolic dysfunction-associated steatotic liver disease. These findings establish macrophage senescence as a central driver of chronic inflammation in aging and metabolic liver disease, and a tractable therapeutic target.

Link: https://doi.org/10.1038/s43587-026-01101-6

It is well established that long term exposure to forms of air pollution increases the risk of mortality and numerous age-related conditions. The mechanisms of interest revolve around increased systemic chronic inflammation that is provoked by the interaction of pollutants, such as fine particles, with airway and lung cells. Is this exposure and its consequences a form of accelerated aging? The question of whether one environmental factor or another accelerates aging forces us to consider how aging is defined and measured. Hitting people with hammers repeatedly will certainly increase mortality, and may even increase common measures of biological age, such as epigenetic clocks, but is it producing accelerated aging? One can debate the question, but clearly more biological data would be needed to actually answer it. Looking only at mortality or loss of function is insufficient, one has to also think about what is going on under the hood in the biochemistry of cells.

In today's open access paper, researchers correlate forms of air pollution, several different measures of biological age, and dementia risk. The greater the exposure to air pollution, the greater the increase in biological age measures and the greater the risk of dementia. Under the hood, there is more inflammation, a greater burden of senescent cells, and likely other features of aging to a greater degree. Biological age measures such as epigenetic clocks tend to obscure all of that, however. Senescent cell burden is perhaps a helpful way to think about the effects of exposure and whether those effects are in fact accelerating aging. Senescent cells accumulate with age, and the more there are the worse the outcome. They are a form of damage that negatively impacts tissue structure and function over time. We might consider any exposure that robustly increases senescent cell burden to be creating accelerated aging; consider obesity, for example, or chemotherapy. There are numerous other forms of aging-associated cell and tissue damage that we can measure, and to the degree that they are increased, we can suggest that this increase reflects an increased biological age.

Accelerated biological aging and brain structural alterations linking air pollution to dementia risk: a prospective cohort study

Air pollution is globally ubiquitous and has been identified as a risk factor for global disease burden. Limited epidemiological studies have linked air pollution to morphological brain alterations, with inconsistent findings, and most of them have focused only on a single type of regional brain region. Furthermore, although air pollution has been established as a risk factor for dementia, the underlying neurobiological mechanisms are poorly understood. Recent evidence suggests that air pollution may accelerate systemic biological aging.

Given that dementia is fundamentally an age-related neurodegenerative disorder, accelerated biological aging is a plausible, upstream mediator in the pathway from air pollution exposure to dementia. Since individuals age at different rates, quantifying biological aging rather than chronological age may reveal a more precise mechanistic link between exposure and health outcomes. Together, we propose a novel mechanistic hypothesis: exposure to air pollution may first accelerate systemic biological aging, which in turn drives the degeneration of specific brain structures, ultimately leading to the onset of dementia.

Therefore, using data from the UK Biobank, we aimed to: (1) examine the associations of long-term exposure to five air pollutants (PM2.5, PM10, PM2.5 absorbance, NO2, and NOx) with global gray/white matter volumes, 80 regional gray matter volumes, and incident dementia; (2) assess the association between biological age acceleration and both air pollution and incident dementia; and (3) investigate the mediating roles of biological aging acceleration and brain structure alterations underlying the air pollution-dementia association.

Cox proportional hazards regression models were used to evaluate the association between air pollution and incident dementia, while linear regression models were used to assess its associations with global and 80 regional brain structures. The mediating roles of biological aging acceleration (measured by Klemera-Doubal method Biological Age [KDM-BA] and PhenoAge) and brain structures in the air pollution-dementia association were evaluated using structural equation modeling (SEM).

Compared to participants with the lowest tertile of air pollution exposure, those in the highest exposure group had higher risks of dementia (Hazard ratio, HR: 1.141 for PM2.5; 1.09 for PM10; 1.09 for PM2.5 absorbance; 1.20 for NO2; and 1.14 for NOX). Air pollution exposure was inversely associated with global and several regional brain structural alterations. SEM revealed a consistent mediating pathway that integrates biological aging and brain structural alterations in the association between air pollution exposure and the risk of dementia.

A team of scientists has examined how younger and older mice heal from wounds and found that more robust senescent cell activation in younger animals helps them heal faster.

A double-edged sword

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Cellular Senescence

As your body ages, more of your cells become senescent. Senescent cells do not divide or support the tissues of which they are part; instead, they emit potentially harmful chemical signals, collectively known as the senescence-associated secretory phenotype (SASP), which encourages nearby cells to enter the same senescent state. Their presence causes many problems: they degrade tissue function, increase chronic inflammation, and can even eventually raise the risk of cancer and other age-related ...
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