Abstract
Aging is the most important risk factor for multiple pathologies including cardiovascular, neoplastic, metabolic and neurodegenerative diseases. Potential geroprotective strategies involve lifestyle-related, nutritional and pharmacological interventions. Recently, chalcones, a subgroup of secondary plant metabolites, have gained attention. 4,4’-dimethoxychalcone was the first chalcone to be shown to mediate geroprotection and lifespan extension across different species. Several other chalcones also exert anti-aging effects at the cellular and organismal levels. Defined mechanistic routes that are causally involved in these protective effects have been delineated. Here, we summarize current evidence supporting the potential of 4,4’-dimethoxychalcone and other chalcones as geroprotective agents.
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Introduction
Caloric restriction and caloric restriction mimetics
Aging is a complex biological process characterized by a progressive decline in physiological function, which encompasses the manifestation of a number of hallmarks1 and the accompanying loss of organismal health2. Biological aging increases the risk of developing age-associated chronic pathologies such as type 2 diabetes, cardiovascular events, neurodegenerative disorders like Alzheimer’s and Parkinson’s disease, and cancer. In recent decades, advancements in healthcare and technology have led to a remarkable rise in life expectancy. This confers individual advantages but menaces the global economy by overloading healthcare and social systems. This negative impact of population aging is explained by the fact that the increase in healthspan, the period of life free from age-related morbidities and disabilities, has not kept pace with the extension of lifespan. As a result, the incidence of age-related diseases has increased to pandemic proportions.
Crucially, the aging process involves regulatory molecular networks and is thus potentially pliable. In fact, a number of nutritional and pharmacological interventions have been proposed as anti-aging strategies, which may be able to harness this pliability, and hence postpone, decelerate or halt the aging process. Among these interventions, caloric restriction (CR), a dietary regimen that reduces calorie intake without malnutrition, has long been recognized for its ability to extend lifespan and improve healthspan across various organisms. Significantly, numerous age-related disorders that are improved by CR in model organisms have also shown effects in human studies3, for example, regarding obesity, type 2 diabetes, cardiovascular disease or the incidence of cancers4.
Mechanistically, CR activates a range of cellular pathways associated with nutritional stress, including pathways involved in stress resistance, DNA repair and metabolism. These pathways are regulated by master transcription factors (e.g., FOXO1, NRF2, PPAR-α, PGC-1α, etc.) and ultimately promote longevity3,4. One of the key antiaging mechanisms is autophagy (from ancient Greek, “self-eating”), a catabolic process responsible for the lysosomal degradation of subcellular components that serves as a recycling mechanism to meet nutritional demands upon nutrient deprivation. Thereby, it removes old, superficial, damaged and dysfunctional components, facilitating ‘cellular renewal’ at the molecular level. Consequently, experimental enhancement of autophagy promotes longevity, while disabled autophagy is involved in numerous diseases, including cancer, neurodegenerative disorders and metabolic syndrome5. The regulation of autophagy is highly conserved and governed by a number of negative and positive key regulators6 as well as by several autophagy-related genes (ATGs), which are crucial for the successive stages of autophagy7.
While CR is an established strategy to robustly promote healthspan (and possibly lifespan), achieving and maintaining CR in the long-term is challenging for humans. This is linked to the fact that classical CR strategies consist in reducing the calorie content of each meal without reducing the frequency or timing of breakfast, lunch and dinner. Periodic fasting is a more attainable strategy in which calorie intake is restricted to a specific time window4. Similar to CR, time-restricted, intermittent and long-term fasting can improve various health-related parameters, with autophagy serving as the key underlying mechanism4. Still, CR and fasting can be problematic for specific individuals, such as pregnant or breastfeeding mothers, children and adolescents, older adults, very lean persons or special disease groups.
For this reason, much effort has been invested in developing alternative strategies that induce CR-like effects without the need of reducing calorie intake. One non-invasive approach consists in the use of compounds that activate the same protective pathways as would CR. We refer to such agents as ‘caloric restriction mimetics’ (CRMs)8. Importantly, many if not all CRMs depend on autophagy induction to exert their beneficial effects. Some examples include rapamycin, a specific inhibitor of the negative autophagy regulator mTOR9, the polyamine spermidine10, the hypoglycemic drug metformin11, the glycolytic inhibitor D-glucosamine12, NAD+ precursors13, or acetylsalicylic acid14, among others8. Some CRMs are being evaluated in clinical trials for their capacity to mitigate are-related diseases15.
Flavonoids and chalcones
One group of CRMs falls into the class of polyphenols, which - like most CRMs - are naturally occurring compounds. Polyphenols are a very diverse group of secondary plant metabolites that can be found in a variety of food items, including fruits, vegetables, tea, coffee or cocoa. Of note, their translational potential is significant because side effects in humans are rare, perhaps due to the coevolution of higher animals with polyphenol-containing plants used as a food source. Polyphenols have characteristic structural features and represent the largest group of phytochemicals. A polyphenol-rich diet reportedly decreased the risk of chronic diseases16, and some polyphenols, most prominently resveratrol17, have been characterized as CRMs8. The largest family within the polyphenols are the flavonoids, which share a structural backbone in which two C6 units are of phenolic nature. Several flavonoids, like epigallocatechin-3-gallate or quercetin, have been suggested to act as CRMs8.
The flavonoid family is subdivided into several other subclasses, one of which are the chalcones. Chalcones are characterized by a core chemical scaffold. They are α,β-unsaturated ketones, composed of two aromatic rings (referred to as rings A and B) connected by a three-carbon alkenone moiety, also known as chalconoid18 (Fig. 1). The term “chalcone” originates from the Greek word “chalcos,” meaning “bronze,” owing to the typical colors exhibited by most natural chalcones. The therapeutic potential of chalcones has been acknowledged for long. A wide variety of biological activities have been ascribed to chalcones, such as antimicrobial, antidiabetic, anti-inflammatory and antiproliferative effects19. In fact, chalcone-rich plants have been connected to health benefits and used as therapeutic remedies across different cultures19. While the first natural chalcone was isolated in 1910, the first successful attempt to synthesize chalcones dates back to the 19th century. In fact, chalcones have attracted much interest with respect to their natural or artificial synthesis and are considered as privileged structures in the field of medicinal chemistry18. This is linked to the fact that the synthesis and chemical modification of chalcones is relatively easy.
Chalcones are characterized by two aromatic rings (termed as rings A and B) connected by a three-carbon alkenone moiety.
In this minireview, we compile evidence in favor of the potential antiaging effects of chalcones. We place special emphasis on chemically defined compounds (rather than chalcone-containing plant extracts), for which (i) antiaging phenotypes have been reported in different model organisms, (ii) preferentially by several laboratories, and (iii) mechanistic evidence points towards their mode of action as CRMs.
4,4’-dimethoxychalcone
Longevity effects of 4,4’-DMC
4,4’-dimethoxychalcone (4,4’-DMC) has been the first chalcone to be causally linked to geroprotective properties20. In a screening campaign comparing 180 different flavonoids, 4,4’-DMC emerged as the strongest hit to promote chronological lifespan (i.e., cell survival during aging) and to reduce the aging-associated production of reactive oxygen species (ROS) in the yeast species Saccharomyces cerevisiae. These markers are commonly applied to model the aging of postmitotic tissues21. This geroprotective capacity was validated in further aging-relevant model systems. 4,4’-DMC extended the lifespan of the nematode Caenorhabditis elegans as well as the fruit fly Drosophila melanogaster, and in different human cell lines, it promoted clonogenic survival upon prolonged culturing. In addition, intraperitoneal injection of 4,4’-DMC significantly diminished the infarction area in mice challenged with prolonged myocardial ischemia (with no reperfusion), thus establishing cardioprotective effects in an aging-relevant scenario20.
Notably, 4,4’-DMC was identified in the leaves and stems (but not in the roots) of Angelica keiskei Koidzumi20, a plant that has been used in Asian traditional folk medicine for millennia22. Incidentally, this plant is also known in Japan as “ashitaba”, meaning “tomorrow leaf”, or in Korea as “shinsuncho”, meaning “elixir of life”. A. keiskei Koidzumi was heavily consumed in Hachijojima (Japan), also known as the “island of longevity”. Indeed, A. keiskei Koidzumi extracts have been reported to have anti-carcinogenic, anti-diabetic, anti-inflammatory and anti-hypertensive properties22. A number of bioactive flavonoids isolated from this plant might account for these effects, including several chalcones beyond 4,4’-DMC. For instance, 4-hydroxyderricin and xanthoangelol, two of the most abundant chalcones contained in this plant, have been shown to exert effects against tumors, inflammation and diabetes22.
Mode of action of 4,4’-DMC
The identification of 4,4’-DMC came along with a number of mechanistic studies. 4,4’-DMC induces autophagy in all model organisms including yeast, nematodes, flies and mice20. As true for CRMs8, the geroprotective effects of 4,4’-DMC largely depend on autophagy. The disruption of autophagy-related (ATG) genes, which are essential for autophagic flux, abrogated 4,4’-DMC-induced lifespan extension in yeast, worms and flies, as well as cardioprotection in mice20. Still, 4,4’-DMC may also act in an autophagy-independent manner under certain conditions23. For instance, 4,4’-DMC protects mice against liver damage triggered by acute ethanol intoxication, and this hepatoprotective effect does not depend on autophagy20. Short-term effects like this one might likely be attributed to the antioxidant properties of 4,4’-DMC, a trait shared by many flavonoids. A number of studies have delineated important structural features that contribute to oxidative radical scavenging24. Nevertheless, it has become evident that the idea that the health-improving effects of flavonoids solely rely on their antioxidant capacity is outdated24,25,26, and that this capacity represents just one among several mechanisms explaining their beneficial effects.
The autophagy-inducing and geroprotective activity of 4,4’-DMC turned out to largely rely on the inhibition of GATA transcription factors (TFs) (Fig. 2). In yeast, the deletion of the yeast GATA TF Gln3 extended chronological lifespan and promoted autophagy induction20, suggesting that basal Gln3 activity might be a repressor of autophagy. Importantly, 4,4’-DMC seems to mimic a state of Gln3 inhibition. Accordingly, DMC-treated wildtype cells showed a metabolic profile similar to untreated Gln3-deficient mutants20. Moreover 4,4’-DMC could not extend the chronological lifespan of yeast cells lacking Gln3 but maintained favorable effects on the longevity of yeast cells lacking other GATA TFs such as Gat1, Dal80 and Gzf3. This dependency on specific GATA TFs could be corroborated in human cells, where 4,4’-DMC failed to induce autophagosome formation upon knockdown of GATA-2 (and to a lesser extent of GATA-3 and GATA-4), but not when other GATA TFs were depleted20.
4,4’-dimethoxychalcone (i) inhibits specific, autophagy-repressing GATA TFs, (ii) interacts with iron homeostasis and (iii) promotes redox capacity both via enzymatic and scavenging activities. The engagement of these pathways results in diverse protective effects, including promotion of organismal lifespan. TFs, transcription factors. HMOX1, heme oxygenase 1. NCOA4, nuclear receptor coactivator 4. NRF2, Nuclear factor erythroid 2-related factor 2. Keap1, Kelch-like ECH-associated protein 1. RFK, riboflavin kinase. FMN, flavin mononucleotide. Created in BioRender. Zimmermann, A. (2025) https://BioRender.com/vj1425e.
GATA transcription factors and 4,4’-DMC
In multicellular animals, GATA TFs are expressed in a tissue- and cell type-dependent manner. In hematopoietic cells, GATA-1 promotes the expression of some autophagy-associated genes while it seems to repress that of others, suggesting a complex role in autophagy regulation27. It has also been connected to the autophagy-promoting activity of resveratrol in an osteoblast-like cell line28. In other tissues, GATA-229, GATA-430 and GATA-631 might contribute to accelerated cell senescence. Interestingly, GATA-1 and GATA-2 have been suggested to regulate differentially expressed genes that characterize several brain regions of Alzheimer’s disease (AD) patients32. However, the potential aging-modulatory impact of these GATA TFs needs further examination. In AD, fibrillar assemblies of amyloid-β peptides (Aβ) are thought to drive the neurodegenerative process. GATA-1 reportedly represses the expression of γ-secretase-activating protein, thus attenuating the formation of Aβ plaques33. In contrast, knockdown of GATA-4 in Aβ fibril-infused rats reduced amyloid plaque deposition, hippocampal inflammation and cognitive dysfunction34. Another study modelled cell rejuvenation based on reprogramming induced pluripotent stem cells and suggested GATA-6 as a pro-aging factor that attenuates the activity of sonic hedgehog signaling and the expression level of downstream forkhead box P1 (FOXP1)35. The authors reported autophagy to be increased upon GATA-6 knockdown35. In contrast, other GATA TFs have been connected to autophagy induction under different settings. For example, GATA-3-driven autophagy may accelerate chemically induced hepatic fibrosis in mice36.
In nematodes, the GATA TF elt-2, the homolog of human GATA4, might counteract aging. The levels of elt-2 decrease with aging, while elt-2 overexpression extends lifespan37. A lifespan-relevant target of elt-2 might be O-GlcNAc transferase, the expression of which usually diminishes upon aging, but can be boosted by elt-238. The GATA TF elt-3 has also been attributed a protective function. For instance, elt-3 enhances the expression of another conserved GATA TF, egl-27, the overexpression of which extends lifespan39. elt-3 was also shown to mediate lifespan extension upon treatment with the flavonoid baicalein40. During the aging process of C. elegans, expression of elt-3 declines following an increase in elt-5 and elt-6, and elt-3 apparently controls a significant portion of the transcriptome changes observed in association with nematode aging41. Mitochondrion-targeted sulfide delivery, which exerts health span-promoting effects, can reverse this decrease in elt-3 expression levels, driving geroprotective cytoskeletal and peroxisomal transcriptomic changes42. Interestingly, the induction of autophagy and the extension of longevity observable in 4,4’-DMC -treated nematodes were lost upon knockdown of elt-120. Other GATA TFs, however, were not assessed with respect to their potential implication in 4,4’-DMC-mediated antiaging effects.
In Drosophila melanogaster, the GATA TF serpent (srp) has been connected to autophagy induction, since srp knockdown suppresses lysosome-autophagosomal fusion43. Conversely, recent research suggests that srp may act as a negative regulator of dietary restriction (DR)-induced lifespan extension. Fat body-specific knockdown of srp extended fruit fly survival, although less than DR, and these effects were further improved upon whole-body knockdown, though at the expense of a reduced fecundity44. In contrast to srp, GATAe, a TF involved in the maintenance of intestinal stem cells, seems to be required for DR-mediated longevity. Intestinal knockdown of GATAe reduced lifespan and also diminished the lifespan-extending benefits of DR44.
Altogether, the different GATA TFs affect the aging process in a variegated fashion. Although they participate to the aging-modulatory effects of CR/DR and 4,4’-DMC, this participation is not uniform.
Other protective effects of 4,4’-DMC
4,4’-DMC has been shown to improve the fertilization ability and developmental potential of oocytes undergoing postovulatory aging (POA) from mice, at least in vitro45. This may be important in the context of in vitro fertilization, where POA limits the success rate. In particular, 4,4’-DMC counteracts a number of hallmarks of POA, including excessive ROS levels, abnormal distribution of mitochondria and increased cellular loss due to apoptosis. Accordingly, 4,4’-DMC improved fertilization and blastocyst formation rates46. 4,4’-DMC-induced autophagy seems to play a role in this scenario, at least with respect to ROS production. However, the role of autophagy in enhancing fertilization rates and early embryonic development has not yet been clarified. In a mouse model of traumatic brain injury (TBI), DMC was shown to improve neurological impairment, specifically learning and memory as well as motor function deficits. Interestingly, DMC administration seems to reduce neuronal apoptosis and suppress microglial activation, altogether mitigating TBI-induced neuronal tissue damage and the associated inflammatory response. These effects might be exerted through the TREM2/PI3K/AKT/NF-κB pathway47. It will be interesting to follow whether these mechanistic signals may be partly involved in other (neuroprotective) activities of DMC.
Recently, 4,4’-DMC has been described as a senolytic48. Senolytics are drugs that selectively eliminate senescent cells, which are characterized by an irreversible cell cycle arrest, resistance to apoptosis and the continuous secretion of pro-inflammatory factors. Senescent cells accumulate during aging in different tissues and drive chronic inflammation, which underlies many aging-associated diseases49. Reportedly, 4,4’-DMC selectively eliminates senescent cells both in vitro and in vivo. In 20-month-old mice, repeated intraperitoneal 4,4’-DMC injections for 2 months reduced the number of senescent hepatocytes, decreased the mRNA levels of multiple pro-inflammatory cellular senescence-associated factors, prevented hair loss and improved motor coordination. 4,4’-DMC alone exerted these effects, which were further improved when 4,4’-DMC was combined with the tyrosine kinase inhibitor dasatinib or the flavonoid quercetin48. The combination of quercetin and dasatinib was previously identified to have senolytic potential50. Mechanistically, in this experimental setting, 4,4’-DMC seems to induce ferritinophagy, a process in which nuclear receptor coactivator 4 (NCOA4) mediates autophagic degradation of ferritin and induces ferroptosis48, an iron-dependent form of regulated cell death characterized by excessive lipid peroxidation (Fig. 2). Ferritinophagy and ferroptosis are generally impaired in senescent cells51. Intriguingly, ferritinophagy and ferroptosis have been implicated in major diseases including cancer and neurodegeneration52. For instance, some cancer therapies can induce ferroptosis to suppress tumor growth53, and α-synuclein, a neuronal protein connected to Parkinson’s disease (PD), impairs ferritinophagy54. It will be interesting to study 4,4’-DMC -induced ferritinophagy in the context of these diseases.
Of note, 4,4’-DMC was found to inhibit the proliferation of different cancer cell lines via induction of ferroptosis55,56. Reportedly, 4,4’-DMC synergistically promotes the accumulation of labile ferrous iron (i) through upregulation of heme oxygenase 1 (HMOX1), which liberates free iron from heme and (ii) via direct binding to and inhibition of ferrochelatase, altogether resulting in iron overload55 (Fig. 2). Interestingly, the HMOX1 gene is transactivated by the transcription factor NRF2, which is negatively controlled by Keap1-dependent degradation. 4,4’-DMC treatment decreased Keap1 levels, which was dependent on the ubiquitin proteasome system (UPS) but not on autophagy. Autophagy-independent 4,4’-DMC effects have been suggested previously, depending on the cell-physiological context20. It will be interesting to see whether this putative capacity to differentially induce the two main degradation systems (autophagy and UPS) can be harnessed for therapeutic purposes.
NRF2, a master TF enhancing the expression of antioxidant genes, and its main negative regulator Keap1 play a pivotal role in maintaining intracellular redox homeostasis57. Ultimately, NRF2 also contributes to anti-inflammatory responses, for instance, through direct transactivation of HMOX1. HMOX1 catalyzes the rate-limiting step of oxidative heme degradation, resulting in several bioactive products that are important for inflammatory control58. Importantly, the NRF2-HMOX1 axis has been specifically connected to the regulation of the NF-κB pathway59 and macrophage metabolism60. Given the pivotal importance of inflammation and immunosenescence in aging and aging-associated diseases61, inducers of NRF2-HMOX1 hold extensive therapeutic potential. However, some hurdles remain to be overcome, including possible off-target effects, bioavailability and safety issues57,58. Irrespectively, the capacity of 4,4’-DMC to upregulate HMOX1 via NRF2 activation55 warrants further investigation. In fact, a number of natural and synthetic chalcones have been connected to NRF2 activation in the context of various diseases62. This also includes natural dimethoxy-derived variants like 2’,4’-dihydroxy-3,4-dimethoxychalcone or 2’,3’-dihydroxy-4’,6’-dimethoxychalcone. Intriguingly, upon intracerebral administration, the latter chalcone suppressed the death of dopaminergic neurons in a chemically-induced PD mouse model63. 4,4’-DMC has shown similar effects in thus far that 4,4’-DMC mitigated motor deficits, α-synuclein aggregation and neuronal death in the substantia nigra in a mouse model of PD64,65. Here, 4,4’-DMC, which does not cross the blood brain barrier65, was subjected to a galenic reformulation to incorporate it into nanoparticles conjugated to a brain barrier-penetrating peptide. This strategy of 4,4’-DMC delivery into the brain restored redox homeostasis by promoting riboflavin metabolism via increased expression of riboflavin kinase, which generates neuroprotective flavin mononucleotide66 (Fig. 2).
Altogether, these results underline the possibility to use 4,4’-DMC for the prevention or treatment of a large panel of age-related diseases.
3,4-dimethoxychalcone
A stereoisomer of 4,4’-DMC, 3,4-dimethoxychalcone (3,4-DMC), also stimulates autophagy and promotes good health. 3,4-DMC emerged as the best hit in a screen involving human cells that was designed to identify stimulators of autophagic flux and cytoplasmic protein deacetylation67, which are commonly induced by CRMs8,68. The pro-autophagy effects of 3,4-DMC depended on the transcription factor EB (TFEB) and the transcription factor binding to IGHM Enhancer 3 (TFE3)67, which are well known to favor lysosomal biogenesis and autophagy69,70 (Fig. 3). Double knockout of both transcription factors efficiently reduced 3,4-DMC-elicited autophagic flux and expression of key autophagy genes67. Intriguingly, double knockout of TFEB and TFE3 did not influence 4,4’-DMC-mediated autophagy induction; in turn, knockdown of the specific GATA transcription factors that preclude 4,4’-DMC-mediated autophagy failed to interfere with autophagy induction by 3,4-DMC.
3,4-dimethoxychalcone promotes lysosomal biogenesis and autophagy via two specific transcription factors, eventually promoting protective effects in different tissues. TFEB, transcription factor EB. TFE3, transcription factor binding to IGHM Enhancer 3 (TFE3). Created in BioRender. Zimmermann, A. (2025) https://BioRender.com/auoinz4.
Mice receiving intraperitoneal 3,4-DMC injection exhibited increased autophagic flux in the heart and liver. In the context of cardiac ischemia/reperfusion, 3,4-DMC treatment reduced the relative volume of the myocardial infarction in an autophagy-dependent manner67. It should be noted that the role of autophagy on ischemia and reperfusion might be time-dependent: protective during ischemia and the early phase of reperfusion but detrimental during the late phase of reperfusion71. Accordingly, the cardioprotective effects of TFEB induction via 3,4-DMC treatment might not apply to the late phase of reperfusion. Indeed, in that phase, TFEB activation promotes cardiomyocyte autosis - an autophagy-dependent non-apoptotic form of cell death – and 3,4-DMC treatment aggravates myocardial injury72. Of note, a recent study addressed the protective effects of 3,4-DMC in limb ischemia/reperfusion injury and showed that protection is partly elicited through TFEB-mediated activation of autophagy73.
In mouse models of fibrosarcoma and non-small-cell lung cancer, 3,4-DMC had no effect as a standalone treatment but improved the reduction of tumor growth elicited by the chemotherapeutic drugs mitoxantrone or oxaliplatin. This chemotherapy-improving effect was lost when cancer cells were manipulated to remove TFEB/TFE3 or when T lymphocytes were removed from the system67. These observations are reminiscent of some established CRMs, which have been shown to improve the capacity of chemotherapeutics to induce therapeutically relevant anticancer immune responses, provided that cancer cells are autophagy-competent74.
Finally, 3,4-DMC has been described to mediate beneficial effects on several mouse models of human disease. 3,4-DMC was able to reduce glial scar formation and motor neuron death while promoting functional recovery after spinal cord injury in mice. These effects were lost when TFEB was knocked down in the spinal cord75. Furthermore, 3,4-DMC showed antiatherogenic activity in two different mouse models of atherosclerosis, which was accompanied by autophagy induction76. 3,4-DMC also protected the skin against ultraviolet-A irradiation77. It remains to be determined, to which extent these effects can be explained by antioxidant activity or the induction of autophagy, knowing that autophagy enhancement does reduce ultraviolet radiation-mediated photoaging78.
Altogether, these findings support the idea that 3,4-DMC exerts broad antiaging effects that may be explained through the induction of autophagy. In this context, it appears intriguing that 3,4-DMC and 4,4’-DMC promote autophagy via separate routes of transcriptional control, namely, activation of TFEB/TFE3 for 3,4-DMC and inhibition of GATA transcription factors for 4,4’-DMC. Thus, it is plausible, yet remains to be demonstrated, that these two chalcones might be advantageously combined to optimally enhance autophagy.
Other chalcones
A large body of evidence obtained in vitro and in vivo has connected numerous chalcones to the mitigation of age-related diseases. Several chalcones protect mice against cancer, as extensively reviewed elsewhere79. Furthermore, several chalcones have been shown to exhibit aging-relevant anti-inflammatory effects. Butein, for example, promotes neuronal cell viability in a lipopolysaccharide (LPS)-induced cell culture model of neuroinflammation80, and isoliquiritigenin reduces brain damage and attenuates motor and cognitive impairments in a rat model of TBI81. Moreover, isobavachalcone induces autophagic flux in a TFEB/TFE3-dependent manner and improves the outcome of immunogenic chemotherapy against established tumors in mice82. In a rat model of diabetes, isobavachalcone ameliorates renal damage83, and in a mouse model of PD, it mitigates neuroinflammation84. Isobavachalcone reduced Aβ aggregation in a cellular model of AD85 and protected cultured skeleton muscle cells against tumor necrosis factor-α-induced atrophy86.
Hydroxysafflor yellow A (HSYA), a chalcone glycoside present in safflower (Carthamus tinctorius), reportedly has geroprotective effects87. Like several other chalcones, HSYA protects against photoaging in thus far that skin damage induced by UV radiation in depilated mice was reduced upon topical application of HSYA88. Although these effects have been attributed to its anti-oxidative properties, HSYA has been shown to activate autophagy in cultured human cells and mice89. Furthermore, in a rotenone-induced mouse model of PD, HSYA promoted α-synuclein clearance89 and improved motor function90. Similar neuroprotective effects were observed in PD induced by the Parkinsonian toxin MPTP91. HSYA reduces LPS-induced neurotoxicity and neuroinflammation in dopaminergic neurons92. Further neuroprotective effects have been observed in models of cerebral ischemia reperfusion-injury66,93 and vascular dementia94. Moreover, in mouse models of myocardial ischemia/reperfusion injury and D-galactose-induced aging, HSYA administration alleviates heart95 and liver damage96, respectively. Notably, other chalcones like 4,4’-DMC, 3,4-DMC (see above), butein or xanthohumol also exert cardio- and/or hepatoprotective effects in vivo97,98.
Another group of chalcones with documented anti-aging potential are the licochalcones, found in licorice root (radix glycyrrhizae). For instance, licochalcone A reduces microglial activation and dopaminergic neurodegeneration while improving behavioral impairments in an LPS-induced rat model of PD99. In middle-aged mice, licochalcone A injection improves their cognitive ability and cerebral blood flow, possibly through immune-modulating activities100. Licochalcone A also exerts anti-obesity effects101. Thus, intraperitoneal injections of high-fat diet-induced obese mice with licochalcone A improved a number of obesity-associated markers compared with control animals, including decreased body weight, hepatocyte steatosis and fasting glycemia, among others102. Such anti-obesity effects may extend to other licochalcones, a series of other natural chalcones, and several synthetic chalcones. For instance, a dimethyl- and trimethoxy-substituted chalcone derivative reduces food intake, glucose intolerance, and hepatic steatosis in a mouse model of obesity103. Two halogen-containing 4‘-methoxychalcone derivatives, which are structurally closely related to 4,4’-DMC and 3,4-DMC, prevent body weight gain as well as deficits in glucose tolerance and insulin resistance in high-fat diet-induced obese mice. In vitro experiments revealed that these chalcones activate AMP-activated protein kinase (AMPK)104, a major positive regulator of autophagy. Similarly, the anti-obesity effects of licochalone A have also been mechanistically linked to AMPK activation102. Thus, it would be interesting to see whether these effects are connected to autophagy induction.
Besides the studies on 4,4’-DMC (see above), reports addressing possible activities of specific chalcones on organismal lifespan remain rare. One study performed in C. elegans showed that the dihydrochalcone aspalathin, a major active ingredient of rooibos (Aspalathus linearis), has antioxidative properties and also promotes the expression of the superoxide dismutase sod-3 and that of the sole ortholog of the FOXO family of transcription factors daf-16. Notably, continuous feeding of aspalathin extended lifespan of C. elegans in a dose-dependent manner, albeit only under high glucose conditions105.
A screen designed to identify drugs that confer oxidative stress resistance to human primary-fibroblasts identified a chloro- and benzimidazole-substituted chalcone as one of the top hits among over 100,000 small molecules106. This chalcone dubbed Gr-4D exhibits no obvious cell toxicity and extends C. elegans lifespan by up to 50%. In human cell cultures, Gr-4D induces the expression of different NRF2-regulated genes as well as that of sestrin 1 (SESN1). Since both NRF2 and SESN1 are involved in antioxidative responses107, this outcome is consistent with the objective of the original screen. However, the cytoprotective activity of the chalcone was largely retained upon NRF2 siRNA knockdown, suggesting that it does not rely on NRF2 activation106. Whether SESN1 is involved in the prolongevity effects of Gr-4D has not been determined. However, studies in various model organisms (including mice) indicate that sestrins contribute to the regulation of aging pathways108. In human cells, Sestrin-2 induces autophagy109. In C. elegans, RNAi-mediated inhibition of SESN1 expression shortens, while SESN1 overexpression promotes lifespan110.
In sum, beyond their effects against age-related diseases, various chalcones exemplified by aspalathin, 4,4’-DMC and Gr-4D increase the lifespan of C. elegans. It will be interesting to see whether such pro-longevity effects extend to higher animals as well.
Limitations, clinical potential and sex-specific responses
Taking together the above evidence, the geroprotective potential of chalcones is based on the observed efficacy across various model organisms, all of which share a crucial trait for their legitimate application: the strong evolutionary conservation of aging-associated cellular and molecular pathways. Still, each model has its distinct limitations and advantages. The genetic tractability of S. cerevisiae allows for comparably simple dissection of mechanistic features upon compound treatment. This includes the possibility of rather rapid screening of aging-related genes and pathways due to its short lifespan. However, it lacks the tissue complexity, endocrine systems, and immune functions of multicellular animals, precluding assessment of some translational aspects111. Similarly, C. elegans, while representing a more complex multicellular organism with differentiated tissues, also has a short lifespan and well-mapped genome. Nonetheless, its simple physiology and lack of complex organs like a circulatory system or adaptive immune system can restrict the relevance of certain findings112. The use of D. melanogaster combines a relatively short lifespan with more complex tissues, including a brain and a heart-like structure. It can be used to study behavioral aspects of aging and has advanced tools for tissue-specific gene manipulation. However, some fundamental differences in physiology, like its open circulatory system113 may pose challenges in modeling human responses to CRMs. One general disadvantage of all the above models is the assessment of pharmacodynamics: drug absorption and metabolism can differ markedly from mammals. In that sense, the use of mice provides the closest approximation of human aging in common preclinical research to help bridge the gap to clinical potential. Mice possess similar organ systems, metabolic processes, and immune functions, making them valuable for evaluating the systemic effects of CRMs. However, besides the technical, economic and ethical hurdles, several aspects like genetic homogeneity of laboratory animals and controlled (external trigger-free) experimental conditions represent key limitations114, since they contrast sharply with the diverse, multifactorial health conditions seen in human populations. Still, mice remain the gold standard for pharmacological testing prior to clinical endeavours. In that sense, mouse studies on the geroprotective effects of chalcones, especially regarding longevity, remain limited and further work will be needed to address systemic effects in mammals.
The clinical potential of chalcones as geroprotective agents will not only be subject to their long-term efficacy, but also to their pharmacokinetic characteristics, including favorable absorption, distribution, metabolism and excretion as well as to their safety profile. Natural chalcones are part of many traditional human diets and seem to be considered generally adventageous regarding toxicity and side effects115, although each compound certainly needs to be assessed individually. Still, a number of CRMs exemplify that in the course of translational efforts, limitations may arise that need to be tackled. For instance, the bioavailability of resveratrol is low, with rapid metabolism and excretion limiting its systemic concentrations116. This galenic problem seems to be common to other polyphenols, underscoring the importance of searching for strategies and formulations that at least partly reduce this limitation. For example, micronization technology increases the surface area of a particle and allows to decrease its size, potentially promoting drug bioavailability117. Specific adjuvants may also be advantageous: for example, the poor bioavailability of another polyphenol, the potential CRM curcumin, can be significantly increased by piperine118, a compound found in black pepper. Another possibility can also involve adapting administration strategies. For example, rapamycin carries immunosuppressive properties119 and has been linked to insulin resistance and hyperlipidemia120. In this case, intermittent administration has been proposed to circumvent these limitations121. Metformin is generally considered to have a favorable safety profile, but it can cause gastrointestinal discomfort in some individuals. Here, several approaches have been proposed to mitigate these side effects, including the use of extended-release and delayed-release strategies122. Altogether, these examples show that – beyond demonstrating efficacy in humans – translational steps for the use of chalcones as geroprotective agents may be challenged by pharmacokinetic and safety constraints. Thus, exploring strategies to optimize dosing regimens or develop analogs with improved therapeutic windows will likely accompany further clinical development of chalcones as potential CRMs. Nevertheless, a limited number of clinical trials do exist on specific chalcones. For example, hesperidin methylchalcone, at least in combination with Ruscus extract and vitamin C, seems to be well tolerable and effective in the frame of chronic venous disease123. Similar results were obtained for preparations containing licochalcone A regarding different inflammatory skin conditions124. Furthermore, xanthohumol was positively assessed for safety and tolerability, and its anti-inflammatory properties are currently being evaluated in patients with Crohn’s disease125.
One intriguing aspect upon clinical evaluation are sex-specific physiological responses. With respect to chalcones connected to geroprotection, the preclinical data in rodent models so far shows that effects are present in both male and female animals. This is the case, for example, regarding anticancer activities of xanthohumol126,127 or cardamonin128,129, among others. For other geroprotective effects, most studies in rodent models have concentrated on male animals. This includes the PD-protective potential of HSYA89,90,91 and isobavachalcone84 as well as other effects of HSYA, including cardio- and hepatoprotective activities95,96 and against vascular dementia94. Further examples include the activities of 4,4’-DMC20 and 3,4-DMC67 against prolonged myocardial ischaemia and 4,4’-DMC against hepatotoxicity20 as well as of xanthohumol against age-associated liver alterations97 and the anti-obesity potential of licochalcone A101,102. In turn, female animals were used to assess protective effects of HSYA against skin photoaging88 as well as neuroprotective activities of licochalcone A against PD99 and age-associated cognitive decline100. In summary, the broad range of protective effects exerted by different chalcones may be applicable to both sexes. However, more studies with female animals are necessary and comparative analyses, which are currently lacking, would be needed to determine whether some of these effects may be more pronounced in one sex or the other.
In this context, it is important to note that chalcones, including several ones that have been mentioned in this review, act as estrogen receptor (ER) modulators130. For example, butein131 and isobavachalcone132 exert estrogenic activities via both ERα and Erβ, while licochalcone A is anti-estrogenic133. Others, like isoliquiritigenin, exhibit biphasic estrogenic actions134, i.e., they act estrogenic at low and anti-estrogenic at high concentrations. Interestingly, several chalcone derivatives have also been connected to anti-androgenic activities135,136. Beyond receptor-modulatory effects, several chalcones also seem to interact with androgen and estrogen biosynthetic pathways. Two important enzymes involved in these pathways are the 17β-hydroxysteroid dehydrogenase AKR1C3, which catalyzes the conversion of androstenedione to testosterone and of estrone to estradiol, and the cytochrome P450 family member CYP19A1 (aromatase), which catalyzes the conversion of androgens (androstenedione and testosterone) into estrogens (estrone and estradiol). Several chalcones have been shown to inhibit AKR1C3137,138 or aromatase137, including isoquiritigenin139 and butein140. Thus, the efficacy and safety profile of chalcones might exhibit sex-specific variations. Of note, the dualistic view of estrogens as “female” hormones and “androgens” as male hormones is inaccurate, and both classes of steroids regulate critical pathophysiological circuitries in both males and females141. Therefore, chalcone-mediated modulation of sex steroid activity might have an impact on both sexes, independently of whether the effect involves androgenic or estrogenic pathways.
Conclusions
Pharmacological strategies aimed at combating aging and age-related diseases are gaining significant attention as promising geroprotective approaches. In this regard, recent evidence has highlighted the remarkable potential of the flavonoid subfamily of chalcones. Several studies have demonstrated anti-aging effects of specific chalcones in various preclinical models, revealing effects on lifespan and healthspan in various models of age-related diseases. Nevertheless, data from mammalian models remain limited, especially regarding longevity and sex-specific responses. As seen with other CRMs, issues such as bioavailability, safety, and long-term efficacy will also need to be more closely addressed to substantiate the potential for future clinical application. Mechanistic studies suggest commonalities in the mode of action of a diverse array of chalcones, among which antioxidant and pro-autophagic activities stand out. However, the proximal targets/receptors of chalcones have not been identified and the pathways activated by chalcones (e.g., the transcription factors from the GATA and TFEB families, the redox homeostasis-regulatory transcription factor NRF2, induction of sestrins, ferritinophagy) may be specific to particular chalcones. These findings do not only encourage the search for additional natural chalcones but also support the development of more potent semisynthetic variants. Chalcones are particularly advantageous, since they are comparably easy to produce and modify, thus supporting future efforts in designing structure-activity relationships, especially with respect to hit-to-lead optimization of affinity and selectivity. This may also help to improve pharmacokinetic parameters (absorption, distribution, metabolism, and excretion). Future will tell which chalcone(s) and combinations thereof will enter pharmacological development.
References
López-Otín, C., Blasco, M. A., Partridge, L., Serrano, M. & Kroemer, G. Hallmarks of aging: An expanding universe. Cell 186, 243–278 (2023).
López-Otín, C. & Kroemer, G. Hallmarks of health. Cell 184, 1929–1939 (2021).
Green, C. L., Lamming, D. W. & Fontana, L. Molecular mechanisms of dietary restriction promoting health and longevity. Nat. Rev. Mol. Cell Biol. 23, 56–73 (2022).
Hofer, S. J., Carmona-Gutierrez, D., Mueller, M. I. & Madeo, F. The ups and downs of caloric restriction and fasting: from molecular effects to clinical application. EMBO Mol. Med. 14, e14418 (2022).
Klionsky, D. J. et al. Autophagy in major human diseases. EMBO J. 40, e108863 (2021).
Galluzzi, L., Pietrocola, F., Levine, B. & Kroemer, G. Metabolic Control of Autophagy. Cell 159, 1263–1276 (2014).
Yin, Z., Pascual, C. & Klionsky, D. J. Autophagy: machinery and regulation. Microb. Cell 3, 588–596 (2016).
Madeo, F., Carmona-Gutierrez, D., Hofer, S. J. & Kroemer, G. Caloric Restriction Mimetics against Age-Associated Disease: Targets, Mechanisms, and Therapeutic Potential. Cell Metab. 29, 592–610 (2019).
Harrison, D. E. et al. Rapamycin fed late in life extends lifespan in genetically heterogeneous mice. Nature 460, 392–395 (2009).
Eisenberg, T. et al. Induction of autophagy by spermidine promotes longevity. Nat. Cell Biol. 11, 1305–1314 (2009).
Martin-Montalvo, A. et al. Metformin improves healthspan and lifespan in mice. Nat. Commun. 4, 2192 (2013).
Weimer, S. et al. D-Glucosamine supplementation extends life span of nematodes and of ageing mice. Nat. Commun. 5, 3563 (2014).
Zhang, H. et al. NAD+ repletion improves mitochondrial and stem cell function and enhances life span in mice. Science 352, 1436–1443 (2016).
Pietrocola, F. et al. Aspirin Recapitulates Features of Caloric Restriction. Cell Rep. 22, 2395–2407 (2018).
Hofer, S. J., Davinelli, S., Bergmann, M., Scapagnini, G. & Madeo, F. Caloric Restriction Mimetics in Nutrition and Clinical Trials. Front. Nutr. 8 (2021).
Vauzour, D., Rodriguez-Mateos, A., Corona, G., Oruna-Concha, M. J. & Spencer, J. P. E. Polyphenols and Human Health: Prevention of Disease and Mechanisms of Action. Nutrients 2, 1106–1131 (2010).
Baur, J. A. et al. Resveratrol improves health and survival of mice on a high-calorie diet. Nature 444, 337–342 (2006).
Zhuang, C. et al. Chalcone: A Privileged Structure in Medicinal Chemistry. Chem. Rev. 117, 7762–7810 (2017).
Salehi, B. et al. Pharmacological Properties of Chalcones: A Review of Preclinical Including Molecular Mechanisms and Clinical Evidence. Front. Pharmacol. 11, 592654 (2021).
Carmona-Gutierrez, D. et al. The flavonoid 4,4’-dimethoxychalcone promotes autophagy-dependent longevity across species. Nat. Commun. 10, 651 (2019).
Carmona-Gutierrez, D. et al. Guidelines and recommendations on yeast cell death nomenclature. Microb. Cell 5, 4–31 (2018).
Caesar, L. K. & Cech, N. B. A Review of the Medicinal Uses and Pharmacology of Ashitaba. Planta Med. 82, 1236–1245 (2016).
Zimmermann, A. et al. 4,4’Dimethoxychalcone: a natural flavonoid that promotes health through autophagy-dependent and -independent effects. Autophagy 15, 1662–1664 (2019).
Rolt, A. & Cox, L. S. Structural basis of the anti-ageing effects of polyphenolics: mitigation of oxidative stress. BMC Chem. 14, 50 (2020).
Lu, M.-F., Xiao, Z.-T. & Zhang, H.-Y. Where do health benefits of flavonoids come from? Insights from flavonoid targets and their evolutionary history. Biochem Biophys. Res Commun. 434, 701–704 (2013).
Rodriguez-Mateos, A., Le Sayec, M. & Cheok, A. Dietary (poly)phenols and cardiometabolic health: from antioxidants to modulators of the gut microbiota. Proc. Nutr. Soc. 1–11 https://doi.org/10.1017/S0029665124000156 (2024).
Kang, Y.-A. et al. Autophagy driven by a master regulator of hematopoiesis. Mol. Cell. Biol. 32, 226–239 (2012).
Liu, X. et al. Resveratrol induces proliferation in preosteoblast cell MC3T3-E1 via GATA-1 activating autophagy. Acta Biochim Biophys. Sin. (Shanghai) 53, 1495–1504 (2021).
Mourkioti, I. et al. A GATA2-CDC6 axis modulates androgen receptor blockade-induced senescence in prostate cancer. J. Exp. Clin. Cancer Res, 42, 187 (2023).
Kang, C. et al. The DNA damage response induces inflammation and senescence by inhibiting autophagy of GATA4. Science 349, aaa5612 (2015).
Li, X. et al. The transcription factor GATA6 accelerates vascular smooth muscle cell senescence-related arterial calcification by counteracting the role of anti-aging factor SIRT6 and impeding DNA damage repair. Kidney Int, 105, 115–131 (2024).
Abyadeh, M. et al. Key Genes and Biochemical Networks in Various Brain Regions Affected in Alzheimer’s Disease. Cells 11, 987 (2022).
Chu, J., Wisniewski, T. & Pratico, D. Correction: GATA1-Mediated Transcriptional Regulation of the γ-Secretase Activating Protein Increases Aβ Formation in Down Syndrome. Ann. Neurol. 93, 1050 (2023).
Liu, L. et al. GATA-binding protein 4 promotes neuroinflammation and cognitive impairment in Aβ1-42 fibril-infused rats through small nucleolar RNA host gene 1/miR-361-3p axis. Chin. J. Physiol. 66, 14–20 (2023).
Jiao, H., Walczak, B. E., Lee, M.-S., Lemieux, M. E. & Li, W.-J. GATA6 Regulates Aging of Human Mesenchymal Stem/Stromal Cells. Stem Cells https://doi.org/10.1002/stem.3297 (2020).
Xie, Z., Li, Y., Xiao, P. & Ke, S. GATA3 promotes the autophagy and activation of hepatic stellate cell in hepatic fibrosis via regulating miR-370/HMGB1 pathway. Gastroenterol. Hepatol. 47, 219–229 (2024).
Mann, F. G., Van Nostrand, E. L., Friedland, A. E., Liu, X. & Kim, S. K. Deactivation of the GATA Transcription Factor ELT-2 Is a Major Driver of Normal Aging in C. elegans. PLoS Genet, 12, e1005956 (2016).
Su, L. et al. ELT-2 promotes O-GlcNAc transferase OGT-1 expression to modulate Caenorhabditis elegans lifespan. J. Cell Biochem 121, 4898–4907 (2020).
Xu, X. & Kim, S. K. The GATA transcription factor egl-27 delays aging by promoting stress resistance in Caenorhabditis elegans. PLoS Genet, 8, e1003108 (2012).
Mohanty, S. K. & Suchiang, K. Baicalein mitigates oxidative stress and enhances lifespan through modulation of Wnt ligands and GATA factor: ELT-3 in Caenorhabditis elegans. Life Sci. 329, 121946 (2023).
Budovskaya, Y. V. et al. An elt-3/elt-5/elt-6 GATA Transcription Circuit Guides Aging in C. elegans. Cell 134, 291–303 (2008).
Vintila, A. R. et al. Mitochondrial sulfide promotes life span and health span through distinct mechanisms in developing versus adult treated Caenorhabditis elegans. Proc. Natl. Acad. Sci. USA 120, e2216141120.
Bánréti, Á, Lukácsovich, T., Csikós, G., Erdélyi, M. & Sass, M. PP2A regulates autophagy in two alternative ways in Drosophila. Autophagy 8, 623–636 (2012).
Dobson, A. J. et al. Tissue-specific transcriptome profiling of Drosophila reveals roles for GATA transcription factors in longevity by dietary restriction. npj Aging Mechanisms Dis. 4, 5 (2018).
Liu, L. et al. 4,4’-dimethoxychalcone increases resistance of mouse oocytes to postovulatory aging in vitro. Reprod. Biomed. Online 44, 411–422 (2022).
Petri, T. et al. In vitro postovulatory oocyte aging affects H3K9 trimethylation in two-cell embryos after IVF. Ann. Anat. - Anatomischer Anz. 227, 151424 (2020).
Wang, M. et al. 4,4′-Dimethoxychalcone Mitigates Neuroinflammation Following Traumatic Brain Injury Through Modulation of the TREM2/PI3K/AKT/NF-κB Signaling Pathway. Inflammation https://doi.org/10.1007/s10753-025-02279-4 (2025).
Wang, T. et al. Flavonoid 4,4′-dimethoxychalcone selectively eliminates senescent cells via activating ferritinophagy. Redox Biol. 69, 103017 (2023).
Di Micco, R., Krizhanovsky, V., Baker, D. & d’Adda di Fagagna, F. Cellular senescence in ageing: from mechanisms to therapeutic opportunities. Nat. Rev. Mol. Cell Biol. 22, 75–95 (2021).
Zhang, L., Pitcher, L. E., Prahalad, V., Niedernhofer, L. J. & Robbins, P. D. Recent advances in the discovery of senolytics. Mech. Ageing Dev. 200, 111587 (2021).
Masaldan, S. et al. Iron accumulation in senescent cells is coupled with impaired ferritinophagy and inhibition of ferroptosis. Redox Biol. 14, 100–115 (2018).
Liu, M.-Z. et al. The critical role of ferritinophagy in human disease. Front. Pharmacol. 13, 933732 (2022).
Su, Y. et al. Ferroptosis, a novel pharmacological mechanism of anti-cancer drugs. Cancer Lett. 483, 127–136 (2020).
Baksi, S. & Singh, N. α-Synuclein impairs ferritinophagy in the retinal pigment epithelium: Implications for retinal iron dyshomeostasis in Parkinson’s disease. Sci. Rep. 7, 12843 (2017).
Yang, C. et al. Flavonoid 4,4’-dimethoxychalcone induced ferroptosis in cancer cells by synergistically activating Keap1/Nrf2/HMOX1 pathway and inhibiting FECH. Free Radic. Biol. Med. 188, 14–23 (2022).
Yang, C. et al. Flavonoid 4,4’-dimethoxychalcone suppresses cell proliferation via dehydrogenase inhibition and oxidative stress aggravation. Free Radic. Biol. Med. 175, 206–215 (2021).
Cuadrado, A. et al. Therapeutic targeting of the NRF2 and KEAP1 partnership in chronic diseases. Nat. Rev. Drug Discov. 18, 295–317 (2019).
Campbell, N. K., Fitzgerald, H. K. & Dunne, A. Regulation of inflammation by the antioxidant haem oxygenase 1. Nat. Rev. Immunol. 21, 411–425 (2021).
Gao, W. et al. Dissecting the Crosstalk Between Nrf2 and NF-κB Response Pathways in Drug-Induced Toxicity. Front. Cell Dev. Biol. 9, 809952 (2022).
Vijayan, V., Wagener, F. A. D. T. G. & Immenschuh, S. The macrophage heme-heme oxygenase-1 system and its role in inflammation. Biochem Pharm. 153, 159–167 (2018).
Liu, Z. et al. Immunosenescence: molecular mechanisms and diseases. Sig Transduct. Target Ther. 8, 1–16 (2023).
Egbujor, M. C., Saha, S., Buttari, B., Profumo, E. & Saso, L. Activation of Nrf2 signaling pathway by natural and synthetic chalcones: a therapeutic road map for oxidative stress. Expert Rev. Clin. Pharmacol. 14, 465–480 (2021).
Masaki, Y., Izumi, Y., Matsumura, A., Akaike, A. & Kume, T. Protective effect of Nrf2-ARE activator isolated from green perilla leaves on dopaminergic neuronal loss in a Parkinson’s disease model. Eur. J. Pharm. 798, 26–34 (2017).
Zhang, W. et al. Trojan Horse Delivery of 4,4’-Dimethoxychalcone for Parkinsonian Neuroprotection. Adv. Sci. (Weinh.) 8, 2004555 (2021).
Gong, J. et al. 4,4’-Dimethoxychalcone regulates redox homeostasis by targeting riboflavin metabolism in Parkinson’s disease therapy. Free Radic. Biol. Med. 174, 40–56 (2021).
Yang, X. et al. Protective effect of Hydroxysafflor Yellow A on cerebral ischemia reperfusion-injury by regulating GSK3β-mediated pathways. Neurosci. Lett. 736, 135258 (2020).
Chen, G. et al. 3,4-Dimethoxychalcone induces autophagy through activation of the transcription factors TFE3 and TFEB. EMBO Mol. Med. 11, e10469 (2019).
Madeo, F., Pietrocola, F., Eisenberg, T. & Kroemer, G. Caloric restriction mimetics: towards a molecular definition. Nat. Rev. Drug Discov. 13, 727–740 (2014).
Martina, J. A. et al. The nutrient-responsive transcription factor TFE3 promotes autophagy, lysosomal biogenesis, and clearance of cellular debris. Sci. Signal 7, ra9 (2014).
Settembre, C. et al. TFEB Links Autophagy to Lysosomal Biogenesis. Science 332, 1429–1433 (2011).
Nah, J. et al. Upregulation of Rubicon promotes autosis during myocardial ischemia/reperfusion injury. J. Clin. Invest. 130, 2978–2991 (2020).
Nah, J., Sung, E.-A., Zhai, P., Zablocki, D. & Sadoshima, J. Tfeb-Mediated Transcriptional Regulation of Autophagy Induces Autosis during Ischemia/Reperfusion in the Heart. Cells 11, 258 (2022).
Qiu, Y.-H. et al. 3,4-Dimethoxychalcone alleviates limb ischemia/reperfusion injury by TFEB-mediated autophagy enhancement and antioxidative response. FASEB J. 39, e70496 (2025).
Pietrocola, F. et al. Caloric Restriction Mimetics Enhance Anticancer Immunosurveillance. Cancer Cell 30, 147–160 (2016).
Zhang, H. et al. 3,4-Dimethoxychalcone, a caloric restriction mimetic, enhances TFEB-mediated autophagy and alleviates pyroptosis and necroptosis after spinal cord injury. Theranostics 13, 810–832 (2023).
Cerrato, G. et al. 3,4-dimethoxychalcone induces autophagy and reduces neointimal hyperplasia and aortic lesions in mouse models of atherosclerosis. Cell Death Dis. 14, 758 (2023).
Fatmasari, E., Zulkarnain, A. K. & Kuswahyuning, R. 3,4-dimethoxychalcone novel ultraviolet-A-protection factor in conventional sunscreen cream. J. Adv. Pharm. Technol. Res. 12, 279–284 (2021).
Wang, M., Charareh, P., Lei, X. & Zhong, J. L. Autophagy: Multiple Mechanisms to Protect Skin from Ultraviolet Radiation-Driven Photoaging. Oxid. Med Cell Longev. 2019, 8135985 (2019).
Michalkova, R. et al. Anticancer Potential of Natural Chalcones: In Vitro and In Vivo Evidence. Int J. Mol. Sci. 24, 10354 (2023).
Liu, Y. et al. Butein attenuates the cytotoxic effects of LPS-stimulated microglia on the SH-SY5Y neuronal cell line. Eur. J. Pharm. 868, 172858 (2020).
Liu, J., Xiong, X. & Sui, Y. Isoliquiritigenin Attenuates Neuroinflammation in Traumatic Brain Injury in Young Rats. Neuroimmunomodulation 26, 102–110 (2019).
Wu, Q. et al. Isobacachalcone induces autophagy and improves the outcome of immunogenic chemotherapy. Cell Death Dis. 11, 1–16 (2020).
Dong, W., Chu, Q., Liu, S., Deng, D. & Xu, Q. Isobavachalcone ameliorates diabetic nephropathy in rats by inhibiting the NF-κB pathway. J. Food Biochem. 44, e13405 (2020).
Jing, H. et al. Isobavachalcone Attenuates MPTP-Induced Parkinson’s Disease in Mice by Inhibition of Microglial Activation through NF-κB Pathway. PLoS One 12, e0169560 (2017).
Chen, X., Yang, Y. & Zhang, Y. Isobavachalcone and bavachinin from Psoraleae Fructus modulate Aβ42 aggregation process through different mechanisms in vitro. FEBS Lett. 587, 2930–2935 (2013).
Hur, J., Kim, M., Choi, S. Y., Jang, Y. & Ha, T. Y. Isobavachalcone attenuates myotube atrophy induced by TNF-α through muscle atrophy F-box signaling and the nuclear factor erythroid 2-related factor 2 cascade. Phytother. Res. 33, 403–411 (2019).
Zhao, F. et al. Hydroxysafflor Yellow A: A Systematical Review on Botanical Resources, Physicochemical Properties, Drug Delivery System, Pharmacokinetics, and Pharmacological Effects. Front. Pharm. 11, 579332 (2020).
Kong, S.-Z. et al. Inhibitory effect of hydroxysafflor yellow a on mouse skin photoaging induced by ultraviolet irradiation. Rejuvenation Res. 16, 404–413 (2013).
Han, B. et al. Hydroxysafflor yellow A promotes α-synuclein clearance via regulating autophagy in rotenone-induced Parkinson’s disease mice. Folia Neuropathol. 56, 133–140 (2018).
Wang, T. et al. Hydroxysafflor Yellow A Improves Motor Dysfunction in the Rotenone-Induced Mice Model of Parkinson’s Disease. Neurochem Res 42, 1325–1332 (2017).
Han, B. & Zhao, H. Effects of hydroxysafflor yellow A in the attenuation of MPTP neurotoxicity in mice. Neurochem Res 35, 107–113 (2010).
Wang, T. et al. Hydroxysafflor Yellow A Attenuates Lipopolysaccharide-Induced Neurotoxicity and Neuroinflammation in Primary Mesencephalic Cultures. Molecules 23, 1210 (2018).
Wei, R. et al. Hydroxysafflor Yellow A Exerts Neuroprotective Effects via HIF-1α/BNIP3 Pathway to Activate Neuronal Autophagy after OGD/R. Cells 11, 3726 (2022).
Zhang, N. et al. Hydroxysafflor yellow A improves learning and memory in a rat model of vascular dementia by increasing VEGF and NR1 in the hippocampus. Neurosci. Bull. 30, 417–424 (2014).
Ye, J. et al. Hydroxysafflor Yellow A Protects Against Myocardial Ischemia/Reperfusion Injury via Suppressing NLRP3 Inflammasome and Activating Autophagy. Front Pharm. 11, 1170 (2020).
Min, F. et al. Hepatoprotective effects of hydroxysafflor yellow A in D-galactose-treated aging mice. Eur. J. Pharm. 881, 173214 (2020).
Fernández-García, C. et al. Xanthohumol exerts protective effects in liver alterations associated with aging. Eur. J. Nutr. 58, 653–663 (2019).
Liu, P. & Pan, Q. Butein Inhibits Oxidative Stress Injury in Rats with Chronic Heart Failure via ERK/Nrf2 Signaling. Cardiovasc. Ther. 2022, 8684014 (2022).
Huang, B. et al. Licochalcone A Prevents the Loss of Dopaminergic Neurons by Inhibiting Microglial Activation in Lipopolysaccharide (LPS)-Induced Parkinson’s Disease Models. Int J. Mol. Sci. 18, 2043 (2017).
Wu, Y., Zhu, J., Liu, H. & Liu, H. Licochalcone A improves the cognitive ability of mice by regulating T- and B-cell proliferation. Aging (Albany NY) 13, 8895–8915 (2021).
Lee, H. E. et al. Anti-obesity potential of Glycyrrhiza uralensis and licochalcone A through induction of adipocyte browning. Biochem. Biophys. Res. Commun. 503, 2117–2123 (2018).
Liou, C.-J. et al. Protective Effects of Licochalcone A Ameliorates Obesity and Non-Alcoholic Fatty Liver Disease Via Promotion of the Sirt-1/AMPK Pathway in Mice Fed a High-Fat Diet. Cells 8, 447 (2019).
Gaigé, S. et al. 3,5-Dimethyl-2,4,6-trimethoxychalcone Lessens Obesity and MAFLD in Leptin-Deficient ob/ob Mice. Int. J. Mol. Sci. 25, 9838 (2024).
Hsieh, C.-T., Chang, F.-R., Tsai, Y.-H., Wu, Y.-C. & Hsieh, T.-J. 2-Bromo-4’-methoxychalcone and 2-Iodo-4’-methoxychalcone Prevent Progression of Hyperglycemia and Obesity via 5’-Adenosine-Monophosphate-Activated Protein Kinase in Diet-Induced Obese Mice. Int J. Mol. Sci. 19, 2763 (2018).
Chen, W. et al. Ameliorative effect of aspalathin from rooibos (Aspalathus linearis) on acute oxidative stress in Caenorhabditis elegans. Phytomedicine 20, 380–386 (2013).
Zhang, P. et al. Stress Resistance Screen in a Human Primary Cell Line Identifies Small Molecules That Affect Aging Pathways and Extend Caenorhabditis elegans’ Lifespan. G3 (Bethesda 10, 849–862 (2020).
Rhee, S. G. & Bae, S. H. The antioxidant function of sestrins is mediated by promotion of autophagic degradation of Keap1 and Nrf2 activation and by inhibition of mTORC1. Free Radic. Biol. Med. 88, 205–211 (2015).
Fang, H., Shi, X., Wan, J. & Zhong, X. Role of sestrins in metabolic and aging-related diseases. Biogerontology 25, 9–22 (2024).
Maiuri, M. C. et al. Stimulation of autophagy by the p53 target gene Sestrin2. Cell Cycle 8, 1571–1576 (2009).
Yang, Y.-L. et al. SESN-1 is a positive regulator of lifespan in Caenorhabditis elegans. Exp. Gerontol. 48, 371–379 (2013).
Zimmermann, A. et al. Yeast as a tool to identify anti-aging compounds. FEMS Yeast Res. 18, foy020 (2018).
Tissenbaum, H. A. Using C. elegans for aging research. Invertebr. Reprod. Dev. 59, 59–63 (2015).
Zhao, Y., van de Leemput, J. & Han, Z. The opportunities and challenges of using Drosophila to model human cardiac diseases. Front. Physiol. 14 (2023).
Anczuków, O. et al. Challenges and opportunities for modeling aging and cancer. Cancer Cell 41, 641–645 (2023).
Villa, S. M., Heckman, J. & Bandyopadhyay, D. Medicinally Privileged Natural Chalcones: Abundance, Mechanisms of Action, and Clinical Trials. Int. J. Mol. Sci. 25, 9623 (2024).
Smoliga, J. M. & Blanchard, O. Enhancing the Delivery of Resveratrol in Humans: If Low Bioavailability is the Problem, What is the Solution?. Molecules 19, 17154–17172 (2014).
Aguiar, G. P. S. et al. Micronization of trans-resveratrol by supercritical fluid: Dissolution, solubility and in vitro antioxidant activity. Ind. Crops Products 112, 1–5 (2018).
Shoba, G. et al. Influence of Piperine on the Pharmacokinetics of Curcumin in Animals and Human Volunteers. Planta Med. 64, 353–356 (1998).
Dumont, F. J. & Su, Q. Mechanism of action of the immunosuppressant rapamycin. Life Sci. 58, 373–395 (1996).
Houde, V. P. et al. Chronic rapamycin treatment causes glucose intolerance and hyperlipidemia by upregulating hepatic gluconeogenesis and impairing lipid deposition in adipose tissue. Diabetes 59, 1338–1348 (2010).
Arriola Apelo, S. I., Pumper, C. P., Baar, E. L., Cummings, N. E. & Lamming, D. W. Intermittent Administration of Rapamycin Extends the Life Span of Female C57BL/6J Mice. J. Gerontol. A Biol. Sci. Med. Sci. 71, 876–881 (2016).
Bonnet, F. & Scheen, A. Understanding and overcoming metformin gastrointestinal intolerance. Diab. Obes. Metab. 19, 473–481 (2017).
Kakkos, S. K. & Allaert, F. A. Efficacy of Ruscus extract, HMC and vitamin C, constituents of Cyclo 3 fort®, on improving individual venous symptoms and edema: a systematic review and meta-analysis of randomized double-blind placebo-controlled trials. Int. Angiol. 36, 93–106 (2017).
Weber, T. M. et al. Skin tolerance, efficacy, and quality of life of patients with red facial skin using a skin care regimen containing Licochalcone A. J. Cosmet. Dermatol 5, 227–232 (2006).
Langley, B. O. et al. Xanthohumol microbiome and signature in adults with Crohn’s disease (the XMaS trial): a protocol for a phase II triple-masked, placebo-controlled clinical trial. Trials 23, 885 (2022).
Monteiro, R. et al. Xanthohumol inhibits inflammatory factor production and angiogenesis in breast cancer xenografts. J. Cell. Biochem. 104, 1699–1707 (2008).
Saito, K. et al. Xanthohumol inhibits angiogenesis by suppressing nuclear factor-κB activation in pancreatic cancer. Cancer Sci. 109, 132–140 (2018).
He, W. et al. Anticancer cardamonin analogs suppress the activation of NF-kappaB pathway in lung cancer cells. Mol. Cell Biochem. 389, 25–33 (2014).
Shrivastava, S. et al. Cardamonin, a chalcone, inhibits human triple negative breast cancer cell invasiveness by downregulation of Wnt/β-catenin signaling cascades and reversal of epithelial–mesenchymal transition. BioFactors 43, 152–169 (2017).
Kiyama, R. Estrogenic flavonoids and their molecular mechanisms of action. J. Nutritional Biochem. 114, 109250 (2023).
Sun, S. et al. Estrogenic activity of a Rhus verniciflua extract and its major components. J. Funct. Foods 11, 250–260 (2014).
Lim, S.-H., Ha, T.-Y., Ahn, J. & Kim, S. Estrogenic activities of Psoralea corylifolia L. seed extracts and main constituents. Phytomedicine 18, 425–430 (2011).
Gong, S. et al. Licochalcone A is a natural selective inhibitor of arginine methyltransferase 6. Biochem J. 478, 389–406 (2021).
Tamir, S., Eizenberg, M., Somjen, D., Izrael, S. & Vaya, J. Estrogen-like activity of glabrene and other constituents isolated from licorice root. J. Steroid Biochem. Mol. Biol. 78, 291–298 (2001).
Zhou, J., Geng, G. & Wu, J. H. Synthesis and in vitro characterization of ionone-based chalcones as novel antiandrogens effective against multiple clinically relevant androgen receptor mutants. Invest. N. Drugs 28, 291–298 (2010).
Kim, Y. S. et al. Methoxychalcone Inhibitors of Androgen Receptor Translocation and Function. Bioorg. Med. Chem. Lett. 22, 2105–2109 (2012).
Le Bail, J. C. et al. Chalcones are potent inhibitors of aromatase and 17beta-hydroxysteroid dehydrogenase activities. Life Sci. 68, 751–761 (2001).
Möller, G. et al. Analogues of Natural Chalcones as Efficient Inhibitors of AKR1C3. Metabolites 12, 99 (2022).
Ye, L., Gho, W. M., Chan, F. L., Chen, S. & Leung, L. K. Dietary administration of the licorice flavonoid isoliquiritigenin deters the growth of MCF-7 cells overexpressing aromatase. Int J. Cancer 124, 1028–1036 (2009).
Wang, Y., Chan, F. L., Chen, S. & Leung, L. K. The plant polyphenol butein inhibits testosterone-induced proliferation in breast cancer cells expressing aromatase. Life Sci. 77, 39–51 (2005).
Hammes, S. R. & Levin, E. R. Impact of estrogens in males and androgens in females. J. Clin. Invest 129, 1818–1826 (2019).
Acknowledgements
This research was funded in whole, or in part, by the Austrian Science Fund (FWF) [10.55776/COE14]. For the purpose of open access, the author has applied a CC BY public copyright licence to any author-accepted manuscript version arising from this submission. We thank the University of Graz (Institute of Molecular Biosciences) for financial support. F.M. is grateful to the FWF for excellence cluster 10.55776/COE14, and D.C.G., A.Z. and F.M. thank the FWF. for further grants (DOC-50, F3012, W1226, P29203, P29262, P27893, P31727, and P37278). GK is supported by the Ligue contre le Cancer (équipe labellisée); Agence National de la Recherche (ANR-22-CE14-0066 VIVORUSH, ANR-23-CE44-0030 COPPERMAC, ANR-23-R4HC-0006 Ener-LIGHT); Association pour la recherche sur le cancer (ARC); Cancéropôle Ile-de-France; Fondation pour la Recherche Médicale (FRM); a donation by Elior; European Joint Programme on Rare Diseases (EJPRD) Wilsonmed; European Research Council Advanced Investigator Award (ERC-2021-ADG, Grant No. 101052444; project acronym: ICD-Cancer, project title: Immunogenic cell death (ICD) in the cancer-immune dialogue); The ERA4 Health Cardinoff Grant Ener-LIGHT; European Union Horizon 2020 research and innovation programmes Oncobiome (grant agreement number: 825410, Project Acronym: ONCOBIOME, Project title: Gut OncoMicrobiome Signatures [GOMS] associated with cancer incidence, prognosis and prediction of treatment response, Prevalung (grant agreement number 101095604, Project Acronym: PREVALUNG EU, project title: Biomarkers affecting the transition from cardiovascular disease to lung cancer: towards stratified interception), Neutrocure (grant agreement number 861878: Project Acronym: Neutrocure; project title: Development of “smart” amplifiers of reactive oxygen species specific to aberrant polymorphonuclear neutrophils for treatment of inflammatory and autoimmune diseases, cancer and myeloablation); National support managed by the Agence Nationale de la Recherche under the France 2030 programme (reference number 21-ESRE-0028, ESR/Equipex+ Onco-Pheno-Screen); Hevolution Network on Senescence in Aging (reference HF-E Einstein Network); Institut National du Cancer (INCa); Institut Universitaire de France; LabEx Immuno-Oncology ANR-18-IDEX-0001; a Cancer Research ASPIRE Award from the Mark Foundation; PAIR-Obésité INCa_1873, the RHUs Immunolife and LUCA-pi (ANR-21-RHUS-0017 and ANR-23-RHUS-0010, both dedicated to France Relance 2030); Seerave Foundation; SIRIC Cancer Research and Personalized Medicine (CARPEM, SIRIC CARPEM INCa-DGOS-Inserm-ITMO Cancer_18006 supported by Institut National du Cancer, Ministère des Solidarités et de la Santé and INSERM). This study contributes to the IdEx Université de Paris Cité ANR-18-IDEX-0001. Views and opinions expressed are those of the author(s) only and do not necessarily reflect those of the European Union, the European Research Council or any other granting authority. Neither the European Union nor any other granting authority can be held responsible for them.
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D.C.G. and F.M. conceptualized the review and outlined the manuscript structure. D.C.G. conducted the primary literature search and drafted the initial version of the manuscript. F.M. contributed to content synthesis and critically revised the manuscript for intellectual content. A.Z. prepared the preliminary versions of the figures and contributed to text editing. G.K. assisted with manuscript refinement, referencing, and final editing. All authors have read and approved the final version.
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F.M. declares receiving paid consultancy fees from The Longevity Labs (TLL). F.M. and G.K. have equity interests in Samsara Therapeutics. GK has been holding research contracts with Daiichi Sankyo, Eleor, Kaleido, Lytix Pharma, PharmaMar, Osasuna Therapeutics, Samsara Therapeutics, Sanofi, Sutro, Tollys, and Vascage. G.K. is on the Board of Directors of the Bristol Myers Squibb Foundation France. G.K. is a scientific co-founder of everImmune, Osasuna Therapeutics, Samsara Therapeutics and Therafast Bio. G.K. is in the scientific advisory boards of Hevolution, Institut Servier, Longevity Vision Funds and Rejuveron Life Sciences/Centenara Labs AG. G.K. is the inventor of patents covering therapeutic targeting of aging, cancer, cystic fibrosis and metabolic disorders. Among these patents, one “Methods for weight reduction” (US11905330B1) is relevant to this study. GK’s brother, Romano Kroemer, was an employee of Sanofi and now consults for Boehringer-Ingelheim. GK’s wife, Laurence Zitvogel, has held research contracts with Glaxo Smyth Kline, Incyte, Lytix, Kaleido, Innovate Pharma, Daiichi Sankyo, Pilege, Merus, Transgene, 9 m, Tusk and Roche, was on the on the Board of Directors of Transgene, is a cofounder of everImmune, and holds patents covering the treatment of cancer and the therapeutic manipulation of the microbiota. These companies had no role in the design of the study; in the writing of the manuscript, or in the decision to publish the results. DCG and AZ declare no competing interests.
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Carmona-Gutierrez, D., Zimmermann, A., Kroemer, G. et al. The geroprotective potential of chalcones. Nat Commun 16, 9152 (2025). https://doi.org/10.1038/s41467-025-64167-7
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DOI: https://doi.org/10.1038/s41467-025-64167-7
