LongeCityNews Last Updated: 21 April 2026 - 12:42 PM

The aging and longevity of flies is very dependent on intestinal function. The noted longevity-associated gene INDY acts on intestinal function, for example. Here, researchers report on their investigation of the role of the gut microbiome in INDY-related longevity in flies. As might be expected given the present state of knowledge of the role of the gut microbe in long-term health and aging, there are signs of a contribution. These results are only a first step, however; the gut microbiome is a complex array of different microbial species, and there is a great deal more that might be catalogued in terms of its relationship to genetic associations with longevity in this species.

Reduction in the Indy (I'm not dead yet) gene, a plasma membrane citrate transporter, in Drosophila and its homolog in worms extends lifespan by promoting metabolic homeostasis. Indy reduction delays the onset of aging-associated pathology in the fly midgut, including preservation of intestinal barrier integrity and intestinal stem cell homeostasis. Gut microbiota has broad impacts on host metabolism, health, and aging. Age-related dysbiosis impairs intestinal barrier function and drives mortality. However, the underlying mechanisms that link increased microbial load to frailty and negative effects on health remain mostly unclear.

Here we show that Indy heterozygote flies have significantly lower bacterial load and increased diversity during aging compared to controls. However, the presence of the microbiome was not required for Indy lifespan extension, though removal of microbes did enhance the effects of Indy reduction on longevity, suggesting potential interactions between the microbiome and Indy. Indy down-regulation was linked to reduced expression of the JAK/STAT signaling ligands Upd3 and Upd2 in the midgut of young flies, which likely contributes to preserved intestinal stem cell homeostasis. Altogether, our results suggest that Indy reduction impacts microbiome load and composition, which preserves gut homeostasis and extends lifespan through impacts on JAK/STAT signaling pathway.

Link: https://doi.org/10.64898/2026.03.25.714291

PEPITEM is a circulating peptide involved in resolution of inflammation and reduction of chronic inflammation. Levels of PEPITEM decline with age, which is one of the reasons why inflammatory athritis becomes worse with age, in that this inhibitory mechanism declines in effectiveness. Studies in animal models have shown that injection of synthetic PEPITEM can improve symptoms; an example of this sort of work is noted here.

Inflammatory arthritis is a group of diseases, including rheumatoid arthritis (RA) and psoriatic arthritis (PsA), where the immune system attacks the joints, causing severe joint damage, pain, and disability. Under normal conditions, adiponectin in the bloodstream stimulates white blood cells to produce PEPITEM, which in turn reduces white blood cell migration in the tissues, preventing an unregulated inflammatory response. However, in inflammatory arthritis, white blood cells fail to respond to adiponectin, and secrete less PEPITEM in the joint. The natural 'break' that prevents white cell migration into the joint cavity is lost, and the inflammatory response becomes unregulated.

The initial study of peripheral blood mononuclear cells (PBMCs, white blood cells) harvested from treatment-naïve human donors with suspected inflammatory arthritis showed a reduced capacity to respond to adiponectin, which could be restored by the addition of PEPITEM. Further examination of whole blood indicated a lower bioavailability of PEPITEM in patients with early RA, leading the researchers to hypothesise that supplementation with PEPITEM could restore immune regulation and reduce the inflammatory changes seen in early-stage disease.

Their work in mouse models of inflammatory arthritis and gouty arthritis showed that injection of synthetic PEPITEM could prevent the onset of inflammatory arthritis, with significant reductions in disease incidence. In addition, joint swelling was reduced by PEPITEM when compared with infliximab - the current standard of care. Tissue studies confirmed that these changes were mirrored in synovial tissue (tissue inside the joints), with significantly less joint inflammation, cartilage damage, and bone erosion observed in PEPITEM treated mice, and significantly fewer white blood cells infiltrating the joints. Molecular studies showed significant down regulation of inflammatory mediators (NF-kB and COX2 protein) within the synovial tissue in PEPITEM-treated mice compared to controls, and a significant increase in the foxp3 transcript, which is crucial for the development of a type of white blood cell that suppresses the immune response, to prevent excessive inflammation and autoimmune disease.

Link: https://www.birmingham.ac.uk/news/2026/pepitem-replacement-therapy-shows-potential-for-early-stage-inflammatory-arthritis

The World Health Organization (WHO) launched intrinsic capacity into the space of ideas relating to the study of aging a decade ago; it is defined as "the composite of all the physical and mental capacities that an individual can draw on." At a more detailed level, intrinsic capacity is envisaged as the sum of motor capacity, sensory capacity, general vitality, psychological wellness, and cognition capacity. What the WHO authors did not specify is how to measure any of this, specifically and in detail.

Putting a fuzzy definition in front of the scientific community is like dangling catnip in front of a bunch of cats, and so now there exist a fair number of proposed approaches for measuring intrinsic capacity that are accompanied by published epidemiological data, but there is little to no consensus as to which of these approaches is the one to move ahead with, and no great ability to compare the data produced via one scientist's intrinsic capacity to data produced via another scientist's intrinsic capacity.

This hasn't stopped a continued flow of new publications in which researchers compare someone's definition of intrinsic capacity to other health data, such as epigenetic age. This may all settle into a consensus at some point, but postponing anything to await that outcome seems unwise. Free-form debates of this nature can last decades. Today's open access paper is another that seeks to build upon the concept of intrinsic capacity and efforts to define it precisely, this time in the direction of animal models of aging. Given that no-one can agree on how intrinsic capacity should be measured in human patients, why not expand that discussion to the animal models that inform the development of new therapies with the potential to slow or reverse aspects of aging?

Could animal models be used to longitudinally track intrinsic capacity during aging?

The World Health Organization (WHO) recently highlighted the importance of promoting healthy aging worldwide, a process characterized by the maximization of functional ability, enabling well-being in older adulthood. This concept inspired the development of the Integrated Care for Older People (ICOPE) program and the Intrinsic Capacity (IC) construct, with the latter serving as core element of ICOPE for clinical use. IC represents the composite of all mental and physical internal attributes of an individual. It is often operationalized through five key domains: cognition, locomotion, vitality, sensory function, and psychological capacity.

Research on IC during aging in humans is growing, being marked by high IC variability. Longitudinal monitoring must be prioritized to capture aging trajectories and identify modifiable risk factors. However, the need for a long-time window spanning decades of human life poses a significant challenge to investigating IC decline over time. In contrast, animal models offer a strategic alternative due to their shorter lifespans compared to humans. For example, the typical lifespan of a mouse is 2-3 years, whereas specific fish models (e.g., killifish) may live only 4-6 months. Thus, leveraging these models for longitudinal IC tracking offers a viable pathway that may expedite the elucidation of IC dynamics and mechanisms during aging.

Preserved functional ability can be objectively assessed through behavioral paradigms in animal studies. By using these measurements in observational or experimental settings, animal models can recapitulate the longitudinal trajectories of IC during aging. To facilitate crosstalk with humans and accurately capture age-related changes in IC, assessment tools should meet specific criteria: they should target the corresponding IC domains in humans, show a decline over time with aging, and exhibit sufficient amplitude to distinguish meaningful functional loss. Here, we discuss how longitudinal IC investigations in mice and fish may advance human research and care during aging. Particular attention will be given to assessing, in experimental models, all IC domains longitudinally, interactions across IC domains, and the definition of a set of potentially informative IC assessments in both mice and fish.

A paper in Cell Genomics has described how age-related systemic inflammation (inflammaging) is related to epigenetic aging as measured by four established clocks.

Tying together two well-known aspects of aging

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Chronic Inflammation

Chronic inflammation refers to a persistent, low-grade buzz of immune activity that settles into the body without the drama of an infection or obvious injury. In the world of aging, this slow, smoldering fire is often called inflammaging, a term coined by Claudio Franceschi to capture the systemic, hard-to-detect inflammation that creeps in with advancing years.
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