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Is ergothioneine a ‘longevity vitamin’ limited in the American diet?

Published online by Cambridge University Press:  11 November 2020

Robert B. Beelman*
Affiliation:
Department of Food Science, College of Agricultural Sciences, Center for Plant and Mushroom Foods for Health, Penn State University, 202 Rodney A. Erickson Food Science Building, University Park, PA16802, USA
Michael D. Kalaras
Affiliation:
Department of Food Science, College of Agricultural Sciences, Center for Plant and Mushroom Foods for Health, Penn State University, 202 Rodney A. Erickson Food Science Building, University Park, PA16802, USA
Allen T. Phillips
Affiliation:
Department of Biochemistry and Molecular Biology, Eberly College of Science, Center for Plant and Mushroom Foods for Health, Penn State University, 203A South Frear Building, University Park, PA16802, USA
John P. Richie Jr.
Affiliation:
Department Public Health Science, College of Medicine, Center for Plant and Mushroom Foods for Health, Penn State University, 500 University Dr., Hershey, PA17033, USA
*
*Corresponding author: Robert B. Beelman, email rbb6@psu.edu

Abstract

There is mounting evidence for the potential for the natural dietary antioxidant and anti-inflammatory amino acid l-Ergothioneine (ERGO) to prevent or mitigate chronic diseases of aging. This has led to the suggestion that it could be considered a ‘longevity vitamin.’ ERGO is produced in nature only by certain fungi and a few other microbes. Mushrooms are, by far, the leading dietary source of ERGO, but it is found in small amounts throughout the food chain, most likely due to soil-borne fungi passing it on to plants. Because some common agricultural practices can disrupt beneficial fungus–plant root relationships, ERGO levels in foods grown under those conditions could be compromised. Thus, research is needed to further analyse the role agricultural practices play in the availability of ERGO in the human diet and its potential to improve our long-term health.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s), 2020. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Ergothioneine (ERGO) is a potent dietary antioxidant amino acid, first discovered in 1909 in Ergot fungus(Reference Tanret1). It has been shown to be an effective antioxidant partly because of the stability of its thione form which predominates at physiological pH(Reference Motohasi, Mori and Sugiura2) (Fig. 1), making it resistant to autoxidation(Reference Hartman3,Reference Cumming, Chinta and Reddy4) . ERGO can scavenge reactive oxygen and nitrogen species and thereby mitigate oxidative damage to biological molecules that contribute to chronic human diseases(Reference Halliwell, Cheah and Tang5).

Fig. 1. Structure of ergothioneine thiol (a) and thione (b) tautomers. At physiological pH, the thione form predominates.

ERGO is currently gaining the attention of the scientific community as a result of its ability to reduce oxidative stress and act as an anti-inflammatory agent with the potential to serve as a therapeutic agent(Reference Halliwell, Cheah and Tang5). ERGO is not synthesised in animals or human subjects and is only obtained through dietary intake, leading us to consider it to be an important micronutrient. Limited intake of ERGO in the diet may compromise long-term health and life expectancy. In the present paper, we seek to illustrate the role ERGO may have in long-term human health and how limited dietary sources could be further impacted by agricultural practices.

The role of ERGO in long-term human health

All mammals synthesise a cell membrane transport protein (in human subjects, the gene product of the SLC22A4 gene) which is highly specific for ERGO(Reference Gründemann, Harlfinger and Golz6). Prior to the discovery of the specificity for ERGO, the transporter originally was designated as OCTN1 or novel cation transporter, but it has repeatedly been shown to have a high affinity for ERGO and it more appropriately should be designated as the ERGO transporter (ETT)(Reference Gründemann, Harlfinger and Golz6Reference Tucker, Cheah and Halliwell8). ETT is responsible for the rapid and efficient transport of food-derived ERGO from the intestine and into various tissues in the body. ETT is strongly expressed in erythrocyte progenitor cells in the bone marrow, small intestine, trachea, kidney, cerebellum, lung and monocytes(Reference Tschirka, Kreisor and Betz7). In a bioavailability study, the uptake of ERGO into erythrocytes occurred within an hour of consumption(Reference Weigand-Heller, Kris-Etherton and Beelman9). ETT has been evolutionarily conserved through time leading to much speculation and interest about ERGO's importance to human health(Reference Oumari, Goldfuss and Stoffels10).

Considerable attention has been focused on the potential for ERGO to mitigate chronic neurodegenerative diseases. One study demonstrated that ERGO blood levels in human subjects decline with age and declined faster in those who show cognitive impairment compared to age-matched individuals with no cognitive impairment(Reference Cheah, Feng and Tang11). In a similar study, blood ERGO levels were lower in individuals with Parkinson's Disease (PD) than with age-matched individuals without the disease(Reference Hatano, Saiki and Okuzumi12). These observations are not surprising considering that ETT is found in the brain and it has been demonstrated that ERGO passes the blood–brain barrier(Reference Tang, Cheah and Yew13), suggesting that low blood ERGO levels may predispose people to neurological diseases of aging.

Despite limited data on ERGO intake from the diet, Americans have been estimated to consume less ERGO (1⋅1 mg/day) than individuals in four European countries (up to 4⋅6 mg/day in Italy)(Reference Ramirez-Martinez, Wesolek and Yadan14,Reference Beelman, Kalaras and Richie15) . These lower intakes were shown to coincide with a greater prevalence of chronic neurological diseases of aging and lower life expectancies(Reference Beelman, Kalaras and Richie15). In a similar analysis, utilising WHO data(16) from 2010, we demonstrate in Fig. 2 that ERGO consumption appears to be negatively associated with total mortality and mortality from neurological disorders and positively associated with greater longevity. These associations cannot be interpreted as causal but have led us to the hypothesis that the American diet may be lacking in sufficient ERGO to adequately protect against chronic diseases of aging. Clearly, detailed ERGO intake data from other regions of the world are required to more fully examine these relationships.

Fig. 2. Estimated ergothioneine consumption in selected countries(Reference Ramirez-Martinez, Wesolek and Yadan14,Reference Beelman, Kalaras and Richie15) compared to (a) total annual mortality, (b) annual mortality from all neurological disorders (includes Alzheimer's disease and other dementias, Parkinson's disease, multiple sclerosis, epilepsy and other neurological conditions) and (c) life expectancy (data from WHO 2010)(16).

Supporting our hypothesis, a recent longitudinal unbiased metabolomic study conducted in Sweden involving over 3200 adult men and women consuming a health-conscious food pattern at baseline sought to identify blood metabolites that could predict a lower risk of cardiovascular disease (CVD) and overall mortality(Reference Smith, Ottosson and Hellstrand17). Out of 112 metabolites measured at baseline, they found that plasma ERGO levels were the most strongly associated with decreased risk of CVD and reduced mortality after 21⋅4 years of follow-up. The authors proposed that raising plasma ERGO levels with diets containing more ERGO may reduce the risk of CVD and mortality. Another recent metabolomic study evaluated 131 blood metabolites as frailty markers in elderly hospital patients(Reference Kameda, Teruya and Yanagida18). The metabolic profiles were clearly able to distinguish frailty from non-frailty and ERGO was lower in frail individuals than in those identified as non-frail. In addition, ERGO was also lower in those identified as having impaired cognition.

Numerous studies have demonstrated that mushroom consumption can be linked to decreased incidence of chronic diseases of aging such as dementia(Reference Zhang, Tomata and Sugiyama19,Reference Feng, Cheah and Ng20) , prostate cancer(Reference Zhang, Sugawara and Chen21) and risk factors of diabetes(Reference Calvo, Mehrotra and Beelman22Reference Hodge and Calvo24). Given the strong associations observed between blood ERGO levels and mushroom consumption(Reference Pallister, Jennings and Mohney25), it is possible that many of these beneficial health effects of mushrooms could be attributed to ERGO. However, further research is required to support this speculation.

ERGO as a vitamin

Dr. Bruce Ames recently suggested that ERGO should be considered a ‘longevity vitamin’ based on his Triage Theory that specifies that the human body uses certain micronutrients as though it were in a triage situation where priority is given to functions of reproduction and survival(Reference Ames26). If an insufficient supply is available, then functions that support long-term health can be compromised, leading to reduced life expectancy. Such effects can be insidious, cumulative and not readily apparent but devasting just the same. In a similar light but a decade earlier, Paul and Snyder suggested that ERGO is ‘an important physiologic cytoprotectant which probably merits designation as a vitamin’(Reference Paul and Snyder27). However, ERGO does not meet the classic definition of a vitamin such that an inadequacy of it in the diet leads to an overt form of a disease in a short time frame. Contrary to the classic definition of a vitamin, researchers recently submitted the idea that since ERGO is commonly found in small amounts in nearly all foods but may not be present in sufficient amounts for optimum long-term health, it possibly could be considered as a vitamin(Reference Borodina, Kenny and McCarthy28). We believe that ‘longevity vitamin’ is a more appropriate term for describing the role ERGO may play in human health.

Sources of ERGO in the diet

Only certain fungi and a few other microbes(Reference Borodina, Kenny and McCarthy28) are currently known to be able to produce ERGO. Since mushrooms are the fruiting bodies of fungi, it is not surprising that edible mushrooms are, by far, the leading dietary source of ERGO(Reference Kalaras, Richie and Calcagnotto29). However, ERGO is also widespread in our food supply(Reference Halliwell, Cheah and Tang5,Reference Ey, Schömig and Taubert30) albeit in smaller amounts in most foods other than mushrooms(Reference Kalaras, Richie and Calcagnotto29).

Fig. 3 illustrates these large differences in ERGO content between mushrooms and some of the other foods that have been shown to contain measurable amounts. While the values of nutritional components in foods can vary from study to study, we have chosen representative ERGO values from the available literature for these foods. The ERGO content of commercially grown edible mushrooms such as white button (Agaricus bisporus) and gray oyster (Pleurotus ostreatus) mushrooms are much higher (630 and 1310 mg/kg d.w., respectively)(Reference Kalaras, Richie and Calcagnotto29) than foods, such as oats(Reference Halliwell, Cheah and Tang5), kidney beans(Reference Halliwell, Cheah and Tang5) or chicken livers(Reference Ey, Schömig and Taubert30), which contain some of the next highest documented levels (1⋅8, 2⋅1 and 47 mg/kg d.w., respectively). Tempeh, which is a soyabean product fermented with fungi, has been shown to contain moderately high levels of ERGO(Reference Halliwell, Cheah and Tang5) (201 mg/kg d.w.) but it is rarely consumed in the American diet compared to the other foods illustrated. Relatively low mushroom consumption, coupled with the predominant consumption of mushroom species with lower ERGO levels, may be partially responsible for the relatively low ERGO levels available in the American diet. In the U.S., Agaricus bisporus is by far the most consumed species of mushroom, with around 97 % of all mushrooms produced belonging to that species, compared to other mushroom species (such as oyster mushrooms) which typically have a much higher ERGO content(Reference Beelman, Kalaras and Richie15).

Fig. 3. ERGO content of selected foods*.(Reference Halliwell, Cheah and Tang5,Reference Kalaras, Richie and Calcagnotto29,Reference Ey, Schömig and Taubert30) . All values converted to mg/kg d.w. (dry weight).

Role of agricultural practices

It appears that some conventional agricultural practices may compromise the ERGO content of the diet. For example, excessive tillage of the soil, a common practice in conventional agriculture, may result in reduced ERGO content of crops. Excessive tillage is known to be disruptive to the mycelia of the mycorrhizal fungi in symbiotic association with the roots of crops grown in those soils(Reference Brito, Goss and de Carvalho31). Those mycelial networks are thought to be primarily responsible for passing ERGO on to plants as described previously(Reference Park, Lee and Kim32). A proposed schematic in which ERGO is distributed within our food supply through these interactions is demonstrated in Fig. 4.

Fig. 4. Sources of ergothioneine in the human diet originating from fungi in the soil.

Regenerative or restorative agriculture is a recent alternative to conventional agriculture that is considered more sustainable by employing no till, or minimal tillage, along with the use of cover crops, crop rotations and reduction in the use of chemical fertilizers and pesticides. Importantly, these practices have been shown to maintain healthy microbial populations in farm soils(Reference Montgomery and Bikle33). The regenerative agriculture movement has led to a burgeoning interest in evaluating the connection between soil health and human health. We believe that ERGO may be an important link since it is likely affected by agricultural practices.

Conclusion

In conclusion, we believe that ERGO is a ‘longevity vitamin’ that is limited in the American diet, and likely other countries as well. This may be due to limited sources of ERGO in the diet and the implementation of agricultural practices that may have an impact on the ERGO content of the food supply. Hence, research is imminently needed to evaluate means to increase ERGO in the diet in order to improve our long-term health. One aspect of major importance is to determine if alternative agricultural approaches can successfully increase the ERGO content in the food supply.

Acknowledgements

The authors would like to thank Carol Vadenais for illustrating Fig. 4.

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

There are no conflicts of interest.

R.B.B. was responsible for formulating the concept and hypothesis for the paper. R.B.B., J.R.R. and M.D.K. were responsible for writing the manuscript and preparing the figures. R.B.B., M.D.K., J.R.R. and A.T.P. were responsible for editing the final manuscript.

References

Tanret, M (1909) Sur une base nouvelle retiree du seigle ergote, l'ergothioneine. Compt Rende 149, 222224.Google Scholar
Motohasi, N, Mori, I & Sugiura, Y (1976) 13C-nuclear magnetic resonance and Raman spectroscopic studies on ionization and mercury complex of ergothioneine. Chem Pharm Bull (Tokyo) 24, 17371741.CrossRefGoogle Scholar
Hartman, PE (1990) Ergothioneine as antioxidant. Methods Enzymol 186, 310318.CrossRefGoogle ScholarPubMed
Cumming, BM, Chinta, KC, Reddy, VP, et al. (2018) Role of ergothioneine in microbial physiology and pathogenesis. Antioxidants Redox Signal 28, 431444.CrossRefGoogle ScholarPubMed
Halliwell, B, Cheah, IK & Tang, RMY (2018) Ergothioneine – a diet-derived antioxidant with therapeutic potential. FEBS Lett 592, 33573366.CrossRefGoogle ScholarPubMed
Gründemann, D, Harlfinger, S, Golz, S, et al. (2005) Discovery of the ergothioneine transporter. Proc Natl Acad Sci USA 102, 52565261.CrossRefGoogle ScholarPubMed
Tschirka, J, Kreisor, M, Betz, J, et al. (2018) Substrate selectivity check of the ergothioneine transporter. Drug Metab Dispos 46, 779785.CrossRefGoogle ScholarPubMed
Tucker, RAJ, Cheah, IK & Halliwell, B (2019) Specificity of the ergothioneine transporter natively expressed in HeLa cells. Biochem Biophys Res Commun 513, 2227.CrossRefGoogle ScholarPubMed
Weigand-Heller, A, Kris-Etherton, P & Beelman, R (2012) The bioavailability of ergothioneine from mushrooms (Agaricus bisporus) and the acute effects on antioxidant capacity and biomarkers of inflammation. Prev Med (Baltim) 54, S75S78.CrossRefGoogle ScholarPubMed
Oumari, M, Goldfuss, B, Stoffels, C, et al. (2019) Regeneration of ergothioneine after reaction with singlet oxygen. Free Radic Biol Med 134, 498504.CrossRefGoogle ScholarPubMed
Cheah, IK, Feng, L, Tang, RMY, et al. (2016) Ergothioneine levels in an elderly population decrease with age and incidence of cognitive decline; a risk factor for neurodegeneration? Biochem Biophys Res Commun 478, 162167.CrossRefGoogle Scholar
Hatano, T, Saiki, S, Okuzumi, A, et al. (2016) Identification of novel biomarkers for Parkinson's disease by metabolomic technologies. J Neurol Neurosurg Psychiatry 87, 295301.CrossRefGoogle ScholarPubMed
Tang, RMY, Cheah, IKM, Yew, TSK, et al. (2018) Distribution and accumulation of dietary ergothioneine and its metabolites in mouse tissues. Sci Rep 8, 115.Google ScholarPubMed
Ramirez-Martinez, A, Wesolek, N, Yadan, J, et al. (2016) Intake assessment of L-ergothioneine in some European countries and in the United States. Hum Ecol Risk Assess An Int J 22, 667677.CrossRefGoogle Scholar
Beelman, RB, Kalaras, MD & Richie, JP (2019) Micronutrients and bioactive compounds in mushrooms: a recipe for healthy aging? Nutr Today 54, 1622.CrossRefGoogle Scholar
World Health Organization (2020) Global health estimates. https://www.who.int/healthinfo/global_burden_disease/en/.Google Scholar
Smith, E, Ottosson, F, Hellstrand, S, et al. (2020) Ergothioneine is associated with reduced mortality and decreased risk of cardiovascular disease. Heart 106, 691697.CrossRefGoogle ScholarPubMed
Kameda, M, Teruya, T, Yanagida, M, et al. (2020) Frailty markers comprise blood metabolites involved in antioxidation, cognition, and mobility. Proc Natl Acad Sci USA 117, 94839489.CrossRefGoogle ScholarPubMed
Zhang, S, Tomata, Y, Sugiyama, K, et al. (2017) Mushroom consumption and incident dementia in elderly Japanese: The Ohsaki Cohort 2006 study. J Am Geriatr Soc 65, 14621469.CrossRefGoogle ScholarPubMed
Feng, L, Cheah, IKM, Ng, MMX, et al. (2019) The association between mushroom consumption and mild cognitive impairment: a community-based cross-sectional study in Singapore. J Alzheimer's Dis 68, 197203.CrossRefGoogle ScholarPubMed
Zhang, S, Sugawara, Y, Chen, S, et al. (2020) Mushroom consumption and incident risk of prostate cancer in Japan: a pooled analysis of the Miyagi Cohort Study and the Ohsaki Cohort Study. Int J Cancer 146, 27122720.CrossRefGoogle ScholarPubMed
Calvo, MS, Mehrotra, A, Beelman, RB, et al. (2016) A retrospective study in adults with metabolic syndrome: diabetic risk factor response to daily consumption of Agaricus bisporus (White button mushrooms). Plant Foods Hum Nutr 71, 245251.CrossRefGoogle Scholar
Okada, E, Takahashi, K, Nakamura, K, et al. (2019) Dietary patterns and abnormal glucose tolerance among Japanese: findings from the national health and nutrition survey, 2012. Public Health Nutr 22, 24602468.CrossRefGoogle ScholarPubMed
Hodge, AM & Calvo, MS (2019) Do bioactive components in non-animal food sources contribute to the beneficial health effect of a Japanese dietary pattern? Public Health Nutr 22, 24692471.CrossRefGoogle ScholarPubMed
Pallister, T, Jennings, A, Mohney, RP, et al. (2016) Characterizing blood metabolomics profiles associated with self-reported food intakes in female twins. PLoS One 11, 116.CrossRefGoogle ScholarPubMed
Ames, BN (2018) Prolonging healthy aging: longevity vitamins and proteins. Proc Natl Acad Sci U S A 115, 1083610844.CrossRefGoogle ScholarPubMed
Paul, BD & Snyder, SH (2010) The unusual amino acid L-ergothioneine is a physiologic cytoprotectant. Cell Death Differ 17, 11341140.CrossRefGoogle ScholarPubMed
Borodina, I, Kenny, LC, McCarthy, CM, et al. (2020) The biology of ergothioneine, an antioxidant nutraceutical. Nutr Res Rev 128.Google ScholarPubMed
Kalaras, MD, Richie, JP, Calcagnotto, A, et al. (2017) Mushrooms: a rich source of the antioxidants ergothioneine and glutathione. Food Chem 233, 429433.CrossRefGoogle ScholarPubMed
Ey, J, Schömig, E & Taubert, D (2007) Dietary sources and antioxidant effects of ergothioneine. J Agric Food Chem 55, 64666474.CrossRefGoogle ScholarPubMed
Brito, I, Goss, MJ, de Carvalho, M, et al. (2012) Impact of tillage system on arbuscular mycorrhiza fungal communities in the soil under Mediterranean conditions. Soil Tillage Res 121, 6367.CrossRefGoogle Scholar
Park, EJ, Lee, WY, Kim, ST, et al. (2010) Ergothioneine accumulation in a medicinal plant Gastrodia elata. J Med Plants Res 4, 11411147.Google Scholar
Montgomery, DR & Bikle, A (2016) The Hidden Half of Nature: The Microbial Roots of Life and Health. New York: W. W. Norton & Company.Google Scholar
Figure 0

Fig. 1. Structure of ergothioneine thiol (a) and thione (b) tautomers. At physiological pH, the thione form predominates.

Figure 1

Fig. 2. Estimated ergothioneine consumption in selected countries(14,15) compared to (a) total annual mortality, (b) annual mortality from all neurological disorders (includes Alzheimer's disease and other dementias, Parkinson's disease, multiple sclerosis, epilepsy and other neurological conditions) and (c) life expectancy (data from WHO 2010)(16).

Figure 2

Fig. 3. ERGO content of selected foods*.(5,29,30). All values converted to mg/kg d.w. (dry weight).

Figure 3

Fig. 4. Sources of ergothioneine in the human diet originating from fungi in the soil.