beyond reason
Fig. 1. Cellular senescence and senolytics. Senescence-induced stimuli lead to normal cells to be senescent, senolytic agents can eliminate senescent cells (SCs) and promote regeneration of normal cells.
Fig. 2. Benefits of natural senolytics on aging. During the aging process, senescent cells (SCs) accumulate in tissues and associated with various age-related diseases. Senolytics derived from nature plants may help delay aging, reduce age-related diseases and extend healthspan through eliminating SCs.
ABSTRACT
Cellular senescence is a hallmark of aging, it is a permanent state of cell cycle arrest induced by cellular stresses. During the aging process, senescent cells (SCs) increasingly accumulate in tissues, causing a loss of tissue-repair capacity because of cell cycle arrest in progenitor cells and produce proinflammatory and matrix-degrading molecules which are known as the senescence-associated secretory phenotype (SASP), and thereby contribute to the development of various age-related diseases. Genetic evidence has demonstrated that clearance of SCs can delay aging and extend healthspan. Senolytics, small molecules that can selectively kill SCs, have been developed to treat various age-related diseases. In recent years, emerging natural compounds have been discovered to be effective senolytic agents, such as quercetin, fisetin, piperlongumine and the curcumin analog. Some of the compounds have been validated in animal models and have great potential to be pushed to clinical applications. In this review, we will discuss cellular senescence and its potential as a target for treating age-related diseases, and summarize the known natural compounds as senolytic agents and their applications.
1. Introduction
Aging is an irreversible process characterized by a progressive loss of physiological integrity, causing impaired function and increased vulnerability to death (López-Otín et al., 2013). It has been shown to be the primary risk factor for major age-related diseases, such as cancer, diabetes, cardiovascular disorders, and neurodegenerative diseases. The hallmarks of aging, such as cellular senescence, genomic instability, telomere attrition, epigenetic alterations, and mitochondrial dysfunction, have been described previously (López-Otín et al., 2013). Accumulating evidence suggests that targeting some of the aging hallmarks, for example, cellular senescence, can significantly improve human health and extend healthspan (Childs et al., 2017; He and Sharpless, 2017; Kirkland and Tchkonia, 2017; Naylor et al., 2013; Niedernhofer and Robbins, 2018).
Cellular senescence is a phenomenon where normal cells stop dividing. Senescent cells (SCs) accumulate in various tissues during the aging process. On one hand, cellular senescence blocks the propagation of damaged cells in order to maintain tissue homeostasis (Demaria et al., 2014). On the other hand, it plays a causative role in irreparable, deleterious cellular damage and loss of tissue homeostasis, which relates to aging and aging-associated diseases (Campisi and d’Adda di Fagagna, 2007). Accumulating evidence demonstrates that elimination of SCs can reduce age-dependent deterioration in tissues and organs, which is useful in improving the treatment of age-associated diseases and alleviating the side effects of therapy-induced senescence (Baker et al., 2011; Campisi and d’Adda di Fagagna, 2007; Childs et al., 2015; He and Sharpless, 2017; Kirkland and Tchkonia, 2017; Naylor et al., 2013; Niedernhofer and Robbins, 2018).
Small molecules that can selectively kill SCs, called senolytics, have the potential to both prevent and treat age-related diseases, thereby extending healthspan. Until now, several classes of senolytic agents, including natural compounds such as quercetin (Geng et al., 2018; Hwang et al., 2018; Zhu et al., 2015), fisetin (Yousefzadeh et al., 2018), piperlongumine (Wang et al., 2016b; Zhang et al., 2018), and curcumin analog EF24 (Li et al., 2019), and targeted therapeutics, which are mainly senolytic target inhibitors, have been identified. Compared to the targeted senolytics, natural senolytic compounds are less potent, but have low toxicity. They may also have a better chance of being translated into the clinical setting to treat age-related diseases or used as a lead for the development of more specific and potent senolytic agents. In this review, we summarize the natural senolytic compounds and their applications in eliminating SCs.
2. Cellular senescence
In 1961, Leonard Hayflick and Paul Moorhead first discovered that normal human fibroblasts have a finite proliferative capacity in culture (Hayflick and Moorhead, 1961), coined as “cellular senescence”, and hypothesized that it might be an underlying cause of aging. Later, it was uncovered that this kind of cellular senescence (replicative senescence) was due to the loss of telomeres after extensive proliferation in the absence of endogenous telomerase activity (Sharpless and Sherr, 2015). Indeed, in vitro senescence can be induced by different damaging stimuli, such as DNA damage, oncogene induction, oxidative stress, chemotherapy, mitochondrial dysfunction and epigenetic changes (Hernandez-Segura et al., 2018). A key feature of in vitro senescence is the enlarged and irregularly shaped cell body, which is associated with the activation of mTOR (Bent et al., 2016) and ATF6α pathways (Cormenier et al., 2018; Druelle et al., 2016). In addition, SCs display increased lysosomal content, accumulation of mitochondria, enlarged nuclear size and increased DNA damage (Hernandez-Segura et al., 2018). Based on these changes, scientists identified a series of senescence markers, such as increased p16 and beta-galactosidase activity, to detect cellular senescence (Childs et al., 2017).
An increasing body of evidence demonstrates that cellular senescence plays an important role in tissue remodeling, injury, and repair both in normal development and physiology and in various pathological conditions and diseases (Childs et al., 2017; He and Sharpless, 2017; Hernandez-Segura et al., 2018; Naylor et al., 2013). Transient induction of senescence during the acute phase of tissue injury is presumably beneficial. SCs can help tissue repair by recruiting immune cells to clear damaged cells and stimulating the proliferation and differentiation of neighboring cells including tissue stem and progenitor cells to repopulate the damaged tissue through secreting senescenceassociated secretory phenotype (SASP) (Demaria et al., 2014). Cellular senescence is also a mechanism to suppress tumor occurrence. However, excessive and aberrant accumulation of SCs in tissues can negatively affect regenerative capacities and create a proinflammatory environment favorable for the onset and progression of various agerelated diseases, including cancer. Therefore, cellular senescence is a double-edged sword, especially in fighting against cancer. Inhibiting the induction of senescence is detrimental, but elimination of SCs after detrimental stimuli may be beneficial. Besides cancer, cellular senescence is associated with many other diseases, termed senescence-related diseases, including organ fibrosis, atherosclerosis, obesity, type 2 diabetes, neurological, muscle disorders and osteoarthritis, which was described previously (Muñoz-Espín and Serrano, 2014). Therefore, both pro-senescent and anti-senescent approaches can be desirable, depending on the therapeutic context.
3. Cellular senescence as a therapeutic target
Although cellular senescence is known to be involved in aging, whether SCs are causally implicated in age-related dysfunction, and whether their removal is beneficial had remained unclear until 2011 (Baker et al., 2011). To examine the role of cellular senescence in aging and age-related pathologies, Baker et al. designed a transgenic strategy for the clearance of SCs in mice and demonstrated that elimination of SCs using the genetic method can significantly delay the onset of agerelated pathologies and extend healthspan, providing the first evidence that cellular senescence is causally implicated in generating age-related phenotypes (Baker et al., 2011). Later, they further demonstrated that clearance of SCs delayed tumorigenesis and attenuated age-related deterioration of several organs without apparent side effects (Baker et al., 2016). Furthermore, they reported that senescent intimal foam cells are deleterious at all stages of atherosclerosis and using transgenic and pharmacological approaches to eliminate SCs hold promise for the treatment of atherosclerosis (Childs et al., 2016). Consistently, Demaria et al. generated a mouse model in which SCs can be visualized and eliminated in living animals, and demonstrated the beneficial role of SCs and their SASP in tissue repair (Demaria et al., 2014). Therefore, pro-senescent therapies can be useful for the treatment of age-related diseases and for ongoing tissue repair processes (Demaria et al., 2014), whereas anti-senescent therapies may be beneficial to eliminate senescence and fibrosis in ‘resolved’ injuries or to rejuvenate the tissues (Fig. 1). Above all, the evidence from genetic animal models suggest that cellular senescence can be a therapeutic target for aging and agerelated diseases.
4. Senolytics
Clearance of SCs by genetic methods prompted a gold rush in the discovery of small molecules that can selectively kill SCs without depending on a transgene. These molecules are called “senolytics” which is from the words “senescence” and “lytic” (destroying). To date, a series of senolytic agents have been identified to target SCs, including targeted therapeutics such as dasatinib (Zhu et al., 2015), a non-specific tyrosine kinase inhibitor; inhibitors of the anti-apoptotic Bcl-2 family proteins (Chang et al., 2016; Yosef et al., 2016; Zhu et al., 2016), HSP90 and histone deacetylase (Fuhrmann-Stroissnigg et al., 2017); UBX101 (Jeon et al., 2017), an inhibitor of the MDM2/p53 protein interaction; and a modified FOXO4-p53 interfering peptide (IP) (Baar et al., 2017). In addition, cytotoxic agents encapsulated with β(1,4)‐galacto‐oligosaccharides have also been used to target SCs that have a high level of lysosomal β‐galactosidase activity (Muñoz-Espín et al., 2018). In this review we will just briefly touch on the targeted senolytics as they were well summarized elsewhere (Childs et al., 2017). Of notice is that emerging natural compounds such as quercetin (Justice et al., 2019; Zhu et al., 2015), fisetin (Yousefzadeh et al., 2018; Zhu et al., 2017) and piperlongumine (Wang et al., 2016b; Zhang et al., 2018) are discovered to be effective senolytic agents. Recently we reported that EF24, a novel curcumin analog, to be another senolytic agent (Li et al., 2019). Because most of these senolytic agents come from food or other natural products, they have the advantage of low toxicity and have great potential to be translated into clinical applications. Here we will focus on discussing the new natural senolytics and their applications in treating or delaying age-related diseases.
5. Senolytic agents derived from natural product
Many natural compounds have been reported to have effects of antiaging or age-related diseases, such as resveratrol (Knutson and Leeuwenburgh, 2008), berberine (Xu et al., 2017), rutin (Li et al., 2016; Yang et al., 2012), catechin (Assuncao and Andrade, 2015; Bernatoniene and Kopustinskiene, 2018), proanthocyanidin (Liu et al., 2018), ginkgo biloba extract (EGb 761) (Sastre et al., 1998) and other phytomolecules (Mukherjee et al., 2011). Most of them are antioxidants, but not all were reported to reduce the viability of SCs. For example, Yousefzadeh et al. tested a panel of flavonoids, including resveratrol, fisetin, luteolin, rutin, epigallocatechin gallate, curcumin, pirfenidone, myricetin, apigenin, catechin, and quercetin, of which fisetin was shown to have good senolytic activity, luteolin and curcumin showed weak senolytic activity while the others were not able to reduce the viability of SCs (Yousefzadeh et al., 2018). Many of the compounds exert their anti-aging functions mainly by reducing the oxidative damage levels in certain organs instead of through killing SCs, which therefore were not categorized as senolytic agents in this review. We believe that more and more natural compounds will be discovered to be effective senolytic agents in the near future. Here we focus on summarizing both the classical function and the new senolytic activities of the reported senolytic agents from natural products.
5.1. Quercetin, an attractive flavonol
Quercetin is one of the most studied dietary flavonoid ubiquitously present in various vegetables as well as in tea and red wine (Formica and Regelson, 1995). Quercetin has wide bio-activities, such as antioxidant, anti-obesity, anti-carcinogenic, anti-viral, anti-bacterial and anti-inflammatory (Anand David et al., 2016). Accordingly, quercetin is now largely utilized as a nutritional supplement and as a phytochemical remedy for a variety of diseases like diabetes, obesity, and circulatory dysfunction, including inflammation, as well as mood disorders. The most obvious feature of quercetin is its strong antioxidant activity which potentially enables it to quench free radicals from forming resonance-stabilized phenoxyl radicals. However, chemical instability, poor water solubility and low bioavailability of quercetin greatly limit its applications (Wang et al., 2016a). However, delivery systems have been utilized to improve its stability, efficacy and bioavailability.
The bio-activities and clinical applications of quercetin are well summarized elsewhere (Boots et al., 2008; Formica and Regelson, 1995); here we will focus on its senolytic activity. Oxidative stress levels increase with progression of the aging process, and given that quercetin is a strong antioxidant, people hypothesize that quercetin may delay aging via reducing oxidative stress levels. Chronic quercetin treatment can reverse cognitive deficits in aged and ethanol-intoxicated mice, which is associated with its antioxidant property (Singh et al., 2003). In 2007, it was reported that quercetin increases oxidative stress resistance and longevity in Saccharomyces cerevisiae (Belinha et al., 2007). The data suggests the potential of quercetin in delaying aging and extending lifespan. It has been demonstrated that the healthspan of mice can be enhanced by killing SCs. In 2015, quercetin was first found to be a senolytic agent that can effectively kill senescent human endothelial cells and mouse bone marrow-derived mesenchymal stem cells (BM-MSCs) (Zhu et al., 2015). Later, quercetin was used as a geroprotective agent against both accelerated and natural aging in hMSCs (Geng et al., 2018), providing a potential therapeutic intervention for treating age-associated disorders. However, quercetin has to be combined with dasatinib to show good senolytic activity (Zhu et al., 2015).
5.2. Fisetin
Fisetin is another flavonoid which exists in various fruits and vegetables such as apples, grapes, persimmons, strawberries, cucumbers, and onions (Arai et al., 2000). The average dietary intake of naturally occurring fisetin in Japan is approximately 0.4 mg/day (Arai et al., 2000; Kimira et al., 1998), apparently without any adverse effects. It has been reported that fisetin can exert numerous beneficial biological activities, including anti-tumor, anti-oxidant, anti-inflammatory, antiangiogenic, hypolipidemic and neuroprotective effects (Khan et al., 2013; Pal et al., 2016; Sundarraj et al., 2018). The ability of flavonoids to scavenge free radicals confer them marked antioxidant activity and significant biological effects. The anti-oxidative effect of fisetin have been evaluated by both cyclic voltammetry and quantum-chemicalbased calculations (Khan et al., 2013; Marković et al., 2009). Emerging data have demonstrated that fisetin has good anti-tumor activity by inhibiting cancer cell proliferation, inducing cancer cell apoptosis, in a variety of cancer cell lines (Kashyap et al., 2018; Lall et al., 2016). Interestingly, the fisetin mediated anti-proliferative and proapoptotic effects were limited to cancer cells, and normal cells were much less affected by fisetin treatment (Lall et al., 2016), showing good selectivity between normal and cancer cells. Fisetin is widely available as a nutritional supplement and has a highly favorable side-effect profile. In 2017, fisetin was first discovered to selectively induce apoptosis in SCs but not in proliferating human umbilical vein endothelial cells (HUVECs) (Zhu et al., 2017). However, it is not senolytic in senescent IMR90 cells, a human lung fibroblast strain, or primary human preadipocytes (Zhu et al., 2017), suggesting that it is a cell-specific senolytic agent. Later, the senolytic activity was validated by an in-vivo study in which a panel of flavonoid polyphenols were screened for senolytic activity using senescent murine and human fibroblasts (Yousefzadeh et al., 2018). Of the flavonoids tested, fisetin was the most potent senolytic agent that can reduce senescence markers in multiple tissues. Consistent with the in vitro result, fisetin reduced senescence within a subset of cells in murine and human adipose tissue, demonstrating its cell-type specificity.
5.3. Piperlongumine, an active alkaloid
Piperlongumine is a biologically active component from Piper species. It is the major alkaloid from long peppers and is also found in other important medicinal plants (Bezerra et al., 2013). Piperlongumine has been reported to have wide pharmacological activities, such as antitumor, anti-angiogenic, anti-metastatic, anti-platelet aggregation, antinociceptive, anti-depressant, anti-atherosclerotic, anti-diabetic, and anti-bacterial (Bezerra et al., 2013). Particularly, its anti-cancer activities has been extensively studied by different research groups. Specifically, piperlongumine can kill various cancer types, including leukemia and solid tumors, such as colon, skin, breast, lung, central nervous system (CNS), pancreatic, nasopharyngeal, osseous, bladder, renal, and prostate cancers (Bezerra et al., 2013; Piska et al., 2018). Of notice is that its cytotoxicity was limited to tumor cells in the micromolar range without causing toxicity to normal cells (Bezerra et al., 2013). This compound showed selective cytotoxicity over cancer cells and presents only weak activity in normal cells. For example, piperlongumine was able to suppress leukemia growth and reduce cell viability by triggering cell apoptosis, however, only weak cytotoxicity was observed in normal lymphocytes (Bezerra et al., 2007). Besides affecting cell death and cell cycle, piperlongumine can also regulate signal transduction pathways, such as receptor tyrosine kinase (Raf-1) and extracellular signal-regulated kinases (ERK1/2) (Bezerra et al., 2013).
In addition, piperlongumine can suppress tumor progression and migration. Piperlongumine induces cell death selectively in tumor cells, possibly by its effects on oxidative stress response enzymes such as GSTp1 and CRB1 (Bezerra et al., 2013). By screening a small library of structurally diverse, rationally-selected small molecules that target pathways predicted to be important for the survival of SCs, we identified piperlongumine as a promising novel lead for the development of senolytic agents (Wang et al., 2016b). Piperlongumine preferentially killed senescent human WI-38 fibroblasts induced by ionizing radiation, replicative exhaustion, or ectopic expression of the oncogene Ras. Pretreatment of the pan-caspase inhibitor Q-VD-OPh (QVD) can significantly block the apoptosis induced by piperlongumine, suggesting the involvement of caspase in the cell death caused by piperlongumine. Interestingly, unlike in some cancer types, piperlongumine killed SCs by inducing apoptosis without inducing the production of reactive oxygen species (ROS) (Wang et al., 2016b). In addition, we found that piperlongumine synergistically killed SCs in combination with ABT-263, a Bcl-2/Bcl-xL inhibitor. Initial structural modifications to piperlongumine identified analogs with improved potency and/or selectivity in inducing SC death. However, the targets of piperlongumine are largely unknown. Later, we used a piperlongumine-based chemical probe to pull-down piperlongumine-binding proteins from live cells and then performed a mass spectrometry-based proteomic analysis to identify potential molecular targets of piperlongumine in SCs. One prominent target was oxidation resistance 1 (OXR1), an important antioxidant protein that regulates the expression of a variety of antioxidant enzymes. We found that OXR1 was upregulated in senescent human WI38 fibroblasts. Piperlongumine was bound to OXR1 directly and induced its degradation through the ubiquitin-proteasome system in an SC-specific manner (Zhang et al., 2018). These findings provide new insights into the mechanism by which SCs are highly resistant to oxidative stress and suggest that OXR1 is a novel senolytic target of piperlongumine that can be further exploited for the development of new senolytic agents.
5.4. EF24, a novel curcumin analog
Besides the aforementioned natural compounds, many others have been identified for medicinal purposes (Harvey, 2008; He et al., 2014, 2013; Molinski et al., 2009; Newman and Cragg, 2016). Curcumin, a hydrophobic polyphenol derived from the rhizome of the herb Curcuma longa, is a well-defined one. Curcumin has been demonstrated to have wide-spectrum biological and pharmacological activities, such as anticancer, anti-inflammation, anti-oxidation, and anti-microbial, which was summarized previously (Aggarwal and Harikumar, 2009; Anand et al., 2008; Gupta et al., 2013; Hatcher et al., 2008; Maheshwari et al., 2006). Many researches have studied the therapeutic potential of curcumin and showed the beneficial aspects of curcumin in delaying aging and the prevention and treatment of age-associated diseases (Grill et al., 2018; Takano et al., 2018; Yang et al., 2017). Moreover, curcumin was shown to prolong lifespan and extend health span in Drosophila melanogaster (fruit fly) (Chandrashekara et al., 2014) and Caenorhabditis elegans (Liao et al., 2011). However, one potential problem hindering the clinical use of curcumin is its low potency and poor absorption characteristics (Shoba et al., 1998). Indeed, curcumin itself was reported to show weak senolytic activity by a recent study (Yousefzadeh et al., 2018). To improve the bioavailability and biological efficiency of curcumin, a series of curcumin analogs were developed, such as EF24 (Adams et al., 2005; He et al., 2018), HO-3867 (Selvendiran et al., 2009), 2-HBA (Dinkova-Kostova et al., 2007) and Dimethoxycurcumin (DIMC) (Tamvakopoulos et al., 2007), which were shown to be more active over curcumin in reducing age-dependent deterioration (such as cancer, inflammation, et al). Recently, from these curcumin analogs, we identified EF24 as the most potent senolytic agent (Li et al., 2019). EF24 reduced cell viability not only in ionizing radiation induced SCs, but also in SCs induced by extensive replication or ectopic transfection of the Ras oncogene. More importantly, EF24 has a broad-spectrum senolytic activity against different types of SCs, including human IMR-90 fibroblasts, HUVECs and human renal epithelial cells (Li et al., 2019). It has been shown that EF24 induces apoptosis in various tumor cells in part by increasing ROS production and inducing oxidative stress-mediated endoplasmic reticulum stress. However, EF24 did not increase ROS production in normal or SCs, suggesting that EF24 induces apoptosis in SCs in a ROS production independent manner. Alternatively, EF24 can reduce the expression of Bcl-xl and Mcl-1 expression in SCs but not in normal cells, which may be in part mediated by the proteasomal degradation pathway. These findings provide new insights into the mechanisms by which curcumin analogs function as anti-aging agents and suggest that the curcumin analog EF24 has the potential to be used as a novel senolytic agent for the treatment of age-related diseases.
5.5. Moderate senolytic activity of goldenrod extract
In 2018, Lämmermann et al. identified an extract from the plant Solidago virgaurea subsp. alpestris, 1201, that can block the negative effects of senescence in human skin fibroblasts, including the SASP in vitro (Lämmermann et al., 2018). 1201 was not only able to delay the acquisition of a senescent phenotype, but was also able to reduce the cell numbers of SCs by 30%, with the senolytic effect of 1201 being mediated by the induction of apoptosis. Interestingly, when 1201 was added to the medium during the differentiation process of the epidermal layer, it resulted in an increase in the epidermal thickness compared to untreated controls. Thus, the natural plant extract may represent a promising possibility to block age-related loss of tissue functionality.
5.6. Effect of natural senolytics on aged mice
As summarized above, only a small number of natural compounds were evidenced to be effective senolytic agents in vitro. However, two of them have been demonstrated to beneficial to health in animal models, that is, fisetin and quercetin; the rest are yet to be determined. Fisetin has been shown to extend the replicative lifespan of S. cerevisiae by 55% (Howitz et al., 2003) and the lifespan of D. melanogaster by 23% (Wood et al., 2004). Administration of fisetin to wild-type mice late in life restored tissue homeostasis, reduced age-related pathology, and extended median and maximum lifespan (Yousefzadeh et al., 2018). Given that fisetin is a natural compound found in common foods and available as an oral dietary supplement without adverse side effects, it is feasible to translate fisetin to human clinical trials in the future. For quercetin, it shows senolytic activity in vitro but in a cell-specific manner. The combination of quercetin with dasatinib, a tyrosine kinase receptor inhibitor, showed better effect on eliminating SCs. Single treatments of quercetin plus dasatinib had phenotypic effects persisting far after the drug is no longer present (Zhu et al., 2015). Transplanting small numbers of SCs into young mice was shown to cause persistent physical dysfunction, as well as the spread of cellular senescence to host tissues (Xu et al., 2018). The senolytic cocktail of quercetin plus dasatinib was able to cause selective elimination of SCs and decrease the number of naturally occurring SCs and SASP in explants of human adipose tissue (Xu et al., 2018). Moreover, the senolytic cocktail increased post-treatment survival by 36% while reducing mortality hazard to 65% in the study, providing proof-of-concept evidence that senolytics can enhance remaining health and lifespan in old mice (Xu et al., 2018). The existing in vivo results are encouraging and indicate that the natural compounds have great potential to be pushed to clinical applications (Fig. 2).
6. Conclusion and perspectives
Genetically and pharmacologically targeting fundamental mechanisms of aging is anticipated to treat or delay the onset of multiple agerelated diseases (Childs et al., 2017; Hernandez-Segura et al., 2018; Kirkland and Tchkonia, 2017; Muñoz-Espín and Serrano, 2014; Naylor et al., 2013; Niedernhofer and Robbins, 2018). Cellular senescence has been demonstrated to be a key mechanism that drives aging. In this review we summarized the known senolytic agents derived from natural compounds. Natural senolytic compounds have the advantages of low toxicity, however they are usually less potent than targeted senolytics and thus have to be combined with other senolytic agents to be effective in clearing SCs (Zhu et al., 2015). Additionally, the mechanisms of action of most natural senolytics have not been well defined nor have their molecular targets been identified and characterized, making it very difficult to rationally modify the compounds to improve their senolytic activity. Exploring and understanding the targets and mechanisms will provide insights into the mechanisms of their senolytic actions. Most of the natural compounds, except fisetin, are studied with just in vitro experiments; animal experiments or human population studies are urgently needed to verify their senolytic activity in vivo. It is promising that we develop more natural compounds to the forefront of senolytic agents and apply them in the treatment of aging and agerelated diseases.
Author contributions
Conceptualization, R.P.Z.; Writing-Original Draft Preparation, W.L., L.Q., and Y.H.H.; Writing-Review & Editing, R.P.Z.; Literature collection, R.N.F., G.R.H., and H.S.