Berries

The effects of blueberry extract on lifespan have been evaluated in C. elegans and D. melanogaster models. Blueberries are rich in anthocyanidins and proanthocyanidins, known for their potent antioxidant activity. These components extended the lifespan of C. elegans via antioxidant activity, CaMKII pathway regulation and increased thermotolerance^{(Reference Wilson, Shukitt-Hale and Kalt10)}. A blueberry extract containing 49·2% cyanidin-3-O-glu and 20·1% petunidin-3-O-glu extended the lifespan of D. melanogaster by approximately 10% by enhancing the gene expression of antioxidant enzymes, such as superoxide dismutase (SOD) and catalase (CAT)^{(Reference Peng, Zuo and Kwan11)}. Among berries, cranberries are the most well studied in lifespan research. In C. elegans, cranberry extract extended the lifespan of the organism by increasing the transactivity of hsf-1^{(Reference Guo, Cao and Zou12)}, a protective factor against thermotolerance and Aβ toxicity. In D. melanogaster, sod1/2 expression levels were increased^{(Reference Wang, Li and Lei13)} and oxidative stress was reduced^{(Reference Sun, Yolitz and Alberico14,Reference Wang, Yolitz and Alberico15)} by cranberries, resulting in a lifespan extension. DAF-16 is a key factor in the daf-2/IlS (insulin/IGF-1 signalling) signal transduction system and is the primary transcription factor involved in the regulation of lifespan^{(Reference Lin, Hsin and Libina16)}. Nrf2/Skn-1 signalling is involved in oxidative stress tolerance^{(Reference Blackwell, Steinbaugh and Hourihan17)}. Raspberry extract extended the lifespan of C. elegans by alleviating oxidative stress via the up-regulation of the SKN-1/Nrf-2 pathway and increased DAF-16 translocation to the nucleus^{(Reference Song, Zheng and Li18,Reference Song, Zheng and Li19)} .

Green tea

Studies of the effects of green tea extract on lifespan have mainly been conducted in D. melanogaster. Reproductive potential in D. melanogaster was inhibited by green tea extract, mainly due to the increased activity of antioxidant enzymes, such as SOD and CAT^{(Reference Li, Chan and Yao20)} and the restriction of iron absorption^{(Reference Lopez, Schriner and Okoro21)}. These findings support the beneficial effects of green tea extract. In another study, SOD and CAT activity increased, whereas lipid hydroxides levels decreased, in response to green tea extract; however, there was no effect on lifespan^{(Reference Li, Chan and Huang22)}. In mouse experiments, green tea extract improved the mid-life (4 month) survival of UM-HET3 female mice, with no significant differences from the controls in terms of locomotor activity^{(Reference Strong, Miller and Astle23)}. Overall, more data are needed to evaluate the effect of green tea extract in mice and other species.

Cocoa

When C. elegans was treated with cocoa suspension, ageing-related decreases in neuromuscular function, learning deficits and memory loss were improved, and the mean and median lifespan was prolonged. However, there was no effect on the maximal lifespan^{(Reference Munasinghe, Almotayri and Thomas24)}. On the other hand, in D. melanogaster, cocoa extended the lifespan via antioxidant and metal chelating effects under excess heavy metals^{(Reference Bahadorani and Hilliker25)}. Cocoa polyphenol extract (total polyphenol content 34%) orally administered to rats at a dose of 24 mg/kg/d for 1 year for 15–27 months delayed age-related brain damage. In addition, it extended the lifespan by approximately 11%^{(Reference Bisson, Nejdi and Rozan26)}. The composition of polyphenols was 88·5% procyanidins, including 0·21% anthocyanins, 10% epicatechin, 1% epicatechin gallate and 0·5% catechin. These results suggested that procyanidins in cocoa are related to its beneficial effects on lifespan.

Black tea

Black tea containing 60% theaflavins increased the survival rate and extended the lifespan of D. melanogaster through a decrease in LPO levels and the partial up-regulation of SOD1 and CAT under oxidative stress^{(Reference Peng, Chan and Li27)}. Water black tea extract also increased resistance to osmotic stress, heat shock and UV irradiation^{(Reference Xiong, Huang and Li28)}. In addition, ROS was decreased due to an increase in the activity of the antioxidant enzyme glutathione peroxidase (GSH-PX). Nevertheless, there was no effect on the lifespan extension of C. elegans.

Orange

The predominant phenolic compound in orange extract obtained with 80% acetone was hesperidin. In C. elegans, orange extract effectively prolonged the lifespan via the reduction of the MDA content, improvement of SOD and CAT activity, increases in daf-16, sod-3, gst-4, sek-1 and skn-1 expression, and a decrease in age-1 expression^{(Reference Wang, Deng and Wang29)}. Orange peel extract also effectively prolonged the lifespan of D. melanogaster via the regulation of locomotor performance, memory index, antioxidant status and enzyme activities of cholinesterase and monoamine oxidase. In addition, DNA damage by free radicals was also prevented^{(Reference Fernández-Bedmar, Anter and de La Cruz-Ares30,Reference Oboh, Olatunde and Ademosun31)} .

Apple

Apple polyphenol extracts increased the lifespan of D. melanogaster by 10% by increasing levels of genes encoding the endogenous antioxidant enzymes SOD1, SOD2 and CAT and downregulating methuselah (MTH)^{(Reference Peng, Chan and Huang32)}. In C. elegans, apple polyphenol extracts improved mean lifespan by 39% and maximal lifespan by 25%. In addition, they enhanced resistance against heat shock, UV irradiation, Pseudomonas aeruginosa infection and paraquat stresses^{(Reference Vayndorf, Lee and Liu33)}. Moreover, combined treatment with apple and blueberry extract exerted a synergistic effect on lifespan (resulting in a 34% extension) compared with the effects of single treatment. The effects on lifespan were mediated by the regulation of the anti-ageing-related gene DAF-16 and insulin signalling^{(Reference Song, Wang and Xia34)}.

Other foods

In addition, the concentration range of 2·5–5 mg/mL ethanol extract of pomegranate was effective in prolonging the lifespan of C. elegans ^{(Reference Kılıçgün, Arda and Uçar35)}. Moreover, pomegranate juice extended the lifespan of the organism by 56% by regulating the DAF-16 pathway^{(Reference Zheng, Heber and Wang36)}. In D. melanogaster, the lifespans of males and females were extended by 18% and 8%, respectively, through the promotion of continuous physical activity and improvement of free-radical-induced stress^{(Reference Balasubramani, Mohan and Chatterjee37)}. Tart cherry extracts extended lifespan in C. elegans via their calorie restriction mimetic function and the regulation of the DAF-16 pathway^{(Reference Jayarathne, Ramalingam and Edwards38,Reference van de Klashorst, van den Elzen and Weeteling39)} . Broccoli increased survival time in D. melanogaster exposed to hydrogen peroxide by reducing lipid peroxides and increasing CuZnSOD, MnSOD and CAT activities^{(Reference Li, Chan and Yao20,Reference Li, Chan and Huang40)} . When grape skins (pomace) were fed to D. melanogaster, an animal model for Parkinson’s disease, after wine fermentation, muscle degeneration was suppressed, and the lifespan was extended^{(Reference Wu, Wu and Dong41)}. Grape skin extracts partially improved the mitochondrial respiration rate with minor effects on memory and ATP levels in aged mice^{(Reference Asseburg, Schäfer and Müller42)}.

Studies of the effects of food extracts on lifespan or healthspan have focused on C. elegans and D. melanogaster. Lifespan studies in mice were limited to grape skin, cocoa and green tea. However, the most well-studied berries have never been evaluated using mice. Therefore, it is necessary to verify the efficacy observed in D. melanogaster and C. elegans using mice in the future and to obtain scientific evidence for the use of food to promote healthy ageing using cohort studies.

Resveratrol

Resveratrol is a representative phytochemical that has attracted much attention as an anti-ageing functional substance since it was first introduced as an activator of NAD⁺-dependent histone deacetylase (sirtuin), a lifespan regulator in metazoans^{(Reference Wood, Rogina and Lavu43,Reference Viswanathan, Kim and Berdichevsky44)} . Subsequent studies on resveratrol have suggested that it promotes lifespan extension via the activation of autophagy, an essential mechanism for maintaining cell homeostasis, in a Sirtuin-1-dependent manner^{(Reference Morselli, Maiuri and Markaki45)}. On the other hand, in an experiment using C. elegans, resveratrol did not relieve oxidative stress or extend the lifespan under normal conditions. However, it prolonged the lifespan of C. elegans under oxidative stress conditions^{(Reference Chen, Rezaizadehnajafi and Wink46)}. Resveratrol induces alterations in the transcription profiles of mice fed a high-calorie diet that are similar to those in mice fed a restricted diet. Resveratrol increased insulin sensitivity, decreased insulin-like growth factor-1 (IGF-1) and improved AMP-activated protein kinase (AMPK), peroxisome proliferator-activated receptor-γ coactivator 1α (PGC1α) and motor function compared with control mice. In addition, resveratrol significantly increased the survival rate of middle-aged obese mice^{(Reference Baur, Pearson and Price47)}. In an experiment with SAMP8 mice, an Alzheimer’s model, resveratrol also extended the lifespan by activating AMPK and pro-survival pathway, such as that of sirtuin1 (SIRT1)^{(Reference Porquet, Casadesús and Bayod48)}. As a SIRT1 activator, resveratrol also extended the lifespan of diabetic mice. Only 10% of the mice fed resveratrol died, while 33% of the mice in the control group died before the study was terminated^{(Reference Sulaiman, Matta and Sunderesan49)}. In SOD (G93A) mutant mice used as a model for amyotrophic lateral sclerosis, the effect of dietary restriction by resveratrol did not influence neurodegenerative diseases or lifespan. These results could be explained by the administration period of resveratrol, which was as short as 90 d^{(Reference Markert, Kim and Gifondorwa50)}. In addition, there was no significant increase in survival rate in male and female UM-HET3 mice; in the same experiment, rapamycin improved the average survival rate by 10% for males and 18% for females^{(Reference Miller, Harrison and Astle51)}. A cohort study that followed urinary resveratrol metabolite concentrations for 9 years found no significant association between resveratrol levels in individuals consuming a Western diet and population health status or mortality risk^{(Reference Semba, Ferrucci and Bartali52)}. Many lifespan studies have focused on resveratrol. However, mouse experiments and cohort studies have yielded inconsistent results regarding the association between resveratrol and lifespan. Therefore, human clinical trials are needed to determine whether resveratrol promotes lifespan extension.

Quercetin

Many studies have evaluated lifespan extension in C. elegans by quercetin under thermal stress. The effects of quercetin are mediated by the increased nuclear translocation of daf-16 and inhibition of ROS accumulation^{(Reference Kampkötter, Nkwonkam and Zurawski53,Reference Kampkötter, Timpel and Zurawski54)} . However, daf-16 may not be necessary for quercetin-mediated longevity and stress resistance, as a daf-16 mutant strain not only showed a lifespan extension of 15% but also showed resistance to thermal and oxidative stress. Therefore, other genes are likely to be involved in the regulation of lifespan^{(Reference Saul, Pietsch and Menzel55)}. In addition, quercetin prolongs lifespan by activating unc-43 (CaMKII), sek-1 (MAPKK)^{(Reference Pietsch, Saul and Menzel56)}, Sir-2·1, co-activator MDT-15^{(Reference Fitzenberger, Deusing and Marx57)} and HSF-1 via the regulation of insulin-like and p38-MAPK pathway signalling^{(Reference Sugawara and Sakamoto58)}. A low concentration (0·125 mg/kg) of quercetin administered to 14-month-old C57BL/6J male mice weekly for 8 months had no effect on lifespan. However, hair loss, blood sugar and bone mineral density were improved. Regarding exercise ability, there was no effect on grip strength; however, there was a significant improvement effect on treadmill and rotarod performance^{(Reference Geng, Liu and Wang59)}. In addition, retrotransposable element (RTE) activity, which increases with age, can promote inflammatory ageing. However, inhibiting RTE activity by quercetin in ageing mouse tissues can affect heterochromatin stabilization, increasing the healthspan of mice.

Curcumin

Curcumin lowers MDA in D. melanogaster, increases the activity of SOD, an antioxidant enzyme, and regulates the expression of ageing-related genes (mth, InR and JNK)^{(Reference Suckow and Suckow60,Reference Lee, Lee and Semnani61)} . In C. elegans, osr-1, sek-1, mek-1, unc-43, sir-2·1 and age-1 have been identified as ageing-related genes required for curcumin-mediated longevity^{(Reference Liao, Yu and Chu62)}. Many studies have evaluated the preventive effects of curcumin in mouse models of diseases; however, studies of its effect on lifespan are rare. Curcumin was administered to genetically heterogenous mice from 4 months of age to investigate its effect on lifespan or healthspan. As a result, curcumin did not have a significant effect on the lifespan of males or females^{(Reference Strong, Miller and Astle23)}. It is thought that curcumin will improve longevity and healthspan by activating autophagy, suppressing cellular senescence, inhibiting inflammatory SASP and changing the intestinal microflora in a beneficial direction^{(Reference Bielak-Zmijewska, Grabowska and Ciolko63)}. However, there is no direct evidence for improvements in mouse lifespan and healthspan.

EGCG

EGCG increased the pharyngeal pumping rate of C. elegans but did not affect lifespan^{(Reference Brown, Evans and Luo64)}. Survival was increased by 60% via aak-2, sir-2·2 and daf-16-dependent redox signalling under lethal conditions caused by oxidative stress^{(Reference Xiong, Chen and Tong65)}. Therefore, EGCG did not increase the lifespan of C. elegans but conferred resistance to oxidative stress. In another experiment, rats were provided drinking-water containing EGCG until they died. As a result, lifespan was extended by the inhibition of NF-κB signalling and activation of FOXOa and SIRT1. In addition, ageing-related inflammation and oxidative stress were improved in the liver and kidney^{(Reference Niu, Na and Feng66)}. In an ageing mouse experiment, EGCG increased the survival rate, although it did not improve cognitive ability or muscle function in ageing mice^{(Reference Pence, Bhattacharya and Park67)}. EGCG significantly increased DNA damage, cell cycle inhibitors, inflammatory markers, senescence-related secreted phenotype regulators, AMPK/AKT signalling, SIRT3/5 expression and autophagy markers in a study of cellular ageing, inflammatory ageing, immune ageing and intestinal bacterial imbalance at four timepoints. Therefore, several deleterious effects of ageing could be attenuated^{(Reference Sharma, Kumar and Sharma68)}.

Spermidine

Spermidine inhibited histone acetyltransferase (HAT) activity in D. melanogaster and C. elegans and increased the expression of genes related to autophagy, resulting in lifespan extension^{(Reference Eisenberg, Knauer and Schauer69)}. In addition, the survival rate and locomotor ability of Drosophila were increased by increasing resistance to paraquat-induced toxicity in an autophagy-dependent manner^{(Reference Minois, Carmona-Gutierrez and Bauer70)}. Spermidine is one of the few compounds studied in mice. Lifespan was extended through cardiovascular protection, prevention of cardiac hypertrophy and maintenance of diastolic function by enhancing autophagy and mitophagy^{(Reference Eisenberg, Abdellatif and Schroeder71)}.

Other phytochemicals

Caffeine^{(Reference Li, Roxo and Cheng72)} and ursolic acid^{(Reference Naß, Abdelfatah and Efferth73,Reference Naß and Efferth74)} extend lifespan in C. elegans by increasing the expression of antioxidant genes and reducing ROS levels. Baicalein also extends the lifespan of C. elegans by activating Nrf2/Skn-1 signalling, which is associated with oxidative stress resistance^{(Reference Havermann, Rohrig and Chovolou75,Reference Havermann, Humpf and Wätjen76)} . Withanolide A^{(Reference Akhoon, Pandey and Tiwari77,Reference Akhoon, Rathor and Pandey78)} , astaxanthin^{(Reference Fu, Zhang and Zhang79)} and caffeic acid^{(Reference Gutierrez-Zetina, González-Manzano and Ayuda-Durán80)} extend lifespan by regulating the insulin-like signalling (IlS) pathway. Compounds that directly mediate DAF-16 are tyrosol^{(Reference Cañuelo, Gilbert-López and Pacheco-Liñán81)} and myricetin^{(Reference Grünz, Haas and Soukup82,Reference Büchter, Ackermann and Havermann83)} . Sesamine extends lifespan by alleviating β-amyloid (Aβ)-induced defects in C. elegans ^{(Reference Keowkase, Shoomarom and Bunargin84)}. In addition, lifespan was extended by the regulation of the sir-2·1 (SIRT1), daf-15 (Raptor) and aak-2 (AMPK) pathways, which are related to caloric restriction, oxidative stress and the TOR pathway^{(Reference Nakatani, Yaguchi and Komura85)}. A recent study also suggested that several phytochemicals suppress degenerative diseases and contribute to longevity through the vitagene network^{(Reference Calabrese, Cornelius and Dinkova-Kostova86)}. Vitagenes, a group of genes that contribute to preserving cellular homeostasis in stress conditions, encode for heat shock proteins (Hsp) 70, Hsp60, haem oxygenase-1 (HO-1), the thioredoxin system and sirtuins^{(Reference Calabrese, Cornelius and Dinkova-Kostova87)}. Carnosic acid found in rosemary activates the vitagene system through Keap1/Nrf2/ARE pathway^{(Reference Satoh, Kosaka and Itoh88)}. In addition, sulforaphane found in broccoli activates vitagenes by activating Nrf2 and enhancing the gene expression of HO-1, a target gene of Nrf2^{(Reference Subedi, Lee and Yumnam89,Reference Zhao, Kobori and Aronowski90)} . These effects of phytochemicals on vitagenes contribute to suppressing the alteration of cells and preventing brain damage^{(Reference Calabrese, Cornelius and Dinkova-Kostova86)}. However, the phytochemicals enhancing the vitagene network are not fully investigated. Therefore, additional studies are needed to enhance the understanding of the effects of vitagene-activating foods and their components on the healthspan of organisms.