Hostname: page-component-78c5997874-m6dg7 Total loading time: 0 Render date: 2024-11-05T08:23:54.819Z Has data issue: false hasContentIssue false

In vivo anti-diabetic potential of chlorogenic acid as a consequence of synergism with other phenolic compounds?

Published online by Cambridge University Press:  12 January 2015

Salvatore Chirumbolo*
Affiliation:
Laboratory of Physiopathology of Obesity, Department of Medicine, University of Verona, LURM est Policlinico GB Rossi, Piazzale AL Scuro 10, 37134Verona, Italy email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Type
Letter to the Editor
Copyright
Copyright © The Author 2015 

A recent article by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ), in the British Journal of Nutrition, reported that chlorogenic acid (CGA) and caffeine inhibit fat accumulation by regulating hepatic function in mice. The authors investigated the effect of CGA and caffeine in female Imprinting Control Region (ICR) mice, drawing the conclusion that these components of coffee reduced serum and hepatic lipid levels and led to the suppression of body-weight gain and fat accumulation in treated animals( Reference Zheng, Qiu and Zhang 1 ). The evidence reported in the study suggested the hypothesis that CGA and caffeine exert their action by biological synergism and that, more generally, coffee polyphenols usually work through a synergistic mechanism. Comments, in brief, are discussed below.

Anti-obesity action of chlorogenic acid

CGA, namely (1S,3R,4R,5R)-3-{((2Z)-3-(3,4-dihydroxyphenyl)prop-2-enoyl)oxy}-1,4,5-trihydroxycyclohexanecarboxylic acid, is one of the most frequently assumed polyphenolic compounds in the daily diet, due to its usual presence in a widely diffused beverage such as coffee. CGA was reported to act as an anti-obesity natural molecule; however, a recent paper on the effect of coffee on the prevention of type 2 diabetes has raised yet some criticism( Reference Akash, Rehman and Chen 2 ). Despite the evidence reported by the authors( Reference Zheng, Qiu and Zhang 1 ), physiological supplementation (1·0 g/kg per d) in C57BL/6 male mice with CGA in combination with a high-fat diet did not reduce body weight compared with mice fed with the high-fat diet alone( Reference Mubarak, Hodgson and Considine 3 ). Yet, the anti-diabetic property of CGA along with caffeic acid or other phenolic acids and/or polyphenols was assessed in other experimental models, besides the above contribution by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 , Reference Cho, Jeon and Kim 4 , Reference Peng, Liu and Chuang 5 ). CGA alone was reported to inhibit in vitro animal fatty acid synthase (FAS) or bacterial β-chetoacyl reductase (EC 1.1.1.100) in a concentration-dependent manner with respective half-maximal inhibitory concentrations (IC50) of 94·8 and 88·1 μm ( Reference Li, Ma and Wu 6 ). This suggests that CGA can act directly on liver enzymes involved in metabolism. However, in the paper by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ), the effect of this ester of caffeic acid and ( − )-quinic acid on liver FAS was small, not statistically significant, while FAS activity was ameliorated by the addition of caffeine.

Mechanism of synergism and related complexity

The contribution of caffeine to improving the efficacy of CGA should stress the hypothesis that synergistic actions occur when two or more bioactive phenolic molecules share similar signalling or metabolic pathways. This may hamper any full elucidation of the biological effect of coffee polyphenols in different biological models. As a matter of fact, complexity pertains to the many, different issues regarding the biological activity of phytochemicals, fundamentally represented by raw-extract biochemistry, pharmacokinetics and bioavailability, in addition to the complex network of intracellular targets. In humans, gut absorption of CGA is at least one-third lower than that of other coffee-derived components, such as caffeic acid, but it exhibited high bioavailability in plasma( Reference Olthof, Hollman and Katan 7 Reference Budryn, Nebesny and Rachwal-Rosiak 10 ). Moreover, CGA exists in the form of a mixture of different caffeoyl-quinic acids, the commonest being probably 5-caffeoyl-quinic acid( Reference Lallemand, Zubieta and Lee 11 ). Such specification may be important because different isomers of caffeoyl-quinic acids exhibit different patterns of activity on liver enzymes( Reference Henry-Vitrac, Ibarra and Roller 12 ). As a matter of fact, all these observations lead to the suggestion that, at least in animal or in vivo models, the anti-diabetic and obesity-preventing activity attributed to CGA may occur when the polyphenol is associated with another phenolic acid or plant-derived alkaloid, such as the 1,3,7-trimethylpurine-2,6-dione reported by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ), an occurrence that may also improve the bioavailability and biological action of CGA. Synergism between CGA and other components probably accounts for the action of CGA plus caffeine reported in the paper by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ). Caffeine improves glucose tolerance, insulin sensitivity and hyperinsulinaemia in C57BL/6J and ameliorates the inflammatory response of adipose tissue, which is notoriously involved in the metabolic syndrome( Reference Bandsma, Wiegman and Herling 13 ). In addition, CGA exerts inhibitory activity on hepatic glucose-6-phosphatase (EC 3.1.3.9), then influencing glucose homeostasis and contributing to the prevention of metabolic stress and type 2 diabetes( Reference Henry-Vitrac, Ibarra and Roller 12 ). The authors did not address any further hypothesis on the mechanism by which CGA and caffeine exerted an anti-diabetic action, except for a significant inhibition of liver FAS and increase in lipid β-oxidation.

Further comments and conclusions

In their paper, Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ) concluded that the observed enhancement of β-oxidation and suppression of lipogenesis were the major reasons for the reduction of fat accumulation and body-weight gain in mice. If true, lipid β-oxidation in hepatic and adipose tissue may be enhanced by the request of lipids from tissues, consequently leading to lipolysis in adipose tissue and changes in the plasma lipid profile. Unfortunately, the paper by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ) did not fully elucidate this issue by evaluating, for example, the serum lipoprotein profile. In this respect, inhibition of hepatic EC 3.1.3.9 by CGA should yet lead to an increase in lipogenesis, without affecting VLDL production and cholesterol synthesis by the liver( Reference Bandsma, Wiegman and Herling 13 ). Therefore, the effect reported by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ) on serum lipids might not be associated with the inhibition of liver glucose-6-phosphatase by CGA, but most presumably caused by other mechanisms. While synergism appears to possibly explicate the observed reduction in FAS activity, the effect of caffeine appears to overwhelm the action of CGA on carnitine acyltransferase (EC 2.3.1.21) and acyl-CoA-oxidase (EC 1.3.3.6), namely that the enhancement of the activity of enzymes involved in lipid oxidation in the mitochondria and peroxisomes should be attributed principally to caffeine, at least as emerging from the paper by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ). In addition, CGA may enhance the inhibitory effect on serum lipids, as it was reported that in Zucker rats, it lowers plasma cholesterol and TAG levels( Reference Rodriguez de Sotillo and Hadley 14 ), thus contributing to the overall observed effect( Reference Zheng, Qiu and Zhang 1 ). Both CGA and caffein shared the same liver enzyme system, which targeted to modulate glucose and lipid homeostasis. The interesting study by Zheng et al. ( Reference Zheng, Qiu and Zhang 1 ) raises many questions about how these components act in coffee, where many other polyphenolic substances, i.e. kaempferol, ferulic acid and caffeic acid, may participate in the synergistic/antagonistic mechanism characterising most of the plant-derived raw extracts. While a possible purpose of such studies is to highlight particular molecules as effective prodrugs against the metabolic syndrome, we should not forget that molecules in a complex mixture behave quite far from our in vitro and animal models, due to the many reasons such as synergism, gut microflora modification, adsorption rate, bioavailability and different cell responses to the indicated molecule.

Acknowledgements

The author has no conflict of interest to declare.

References

1 Zheng, G, Qiu, Y, Zhang, QF, et al. (2014) Chlorogenic acid and caffeine in combination inhibit fat accumulation by regulating hepatic lipid metabolism-related enzymes in mice. Br J Nutr 112, 10341040.Google Scholar
2 Akash, MS, Rehman, K & Chen, S (2014) Effects of coffee on type 2 diabetes mellitus. Nutrition 30, 755763.Google Scholar
3 Mubarak, A, Hodgson, JM, Considine, MJ, et al. (2013) Supplementation of a high-fat diet with chlorogenic acid is associated with insulin resistance and hepatic lipid accumulation in mice. J Agric Food Chem 61, 43714378.Google Scholar
4 Cho, AS, Jeon, SM, Kim, MJ, et al. (2010) Chlorogenic acid exhibits anti-obesity property and improves lipid metabolism in high-fat diet-induced-obese mice. Food Chem Toxicol 48, 937943.CrossRefGoogle ScholarPubMed
5 Peng, CH, Liu, LK, Chuang, CM, et al. (2011) Mulberry water extracts possess an anti-obesity effect and ability to inhibit hepatic lipogenesis and promote lipolysis. J Agric Food Chem 59, 26632671.Google Scholar
6 Li, BH, Ma, XF, Wu, XD, et al. (2006) Inhibitory activity of chlorogenic acid on enzymes involved in the fatty acid synthesis in animals and bacteria. IUBMB Life 58, 3946.Google Scholar
7 Olthof, MR, Hollman, PC & Katan, MB (2001) Chlorogenic acid and caffeic acid are absorbed in humans. J Nutr 131, 6671.Google Scholar
8 Stalmach, A, Steiling, H, Williamson, G, et al. (2010) Bioavailability of chlorogenic acids following acute ingestion of coffee by humans with an ileostomy. Arch Biochem Biophys 501, 98105.Google Scholar
9 Farah, A, Monteiro, M, Donangelo, CM, et al. (2008) Chlorogenic acids from green coffee extract are highly bioavailable in humans. J Nutr 138, 23092315.Google Scholar
10 Budryn, G, Nebesny, E, Rachwal-Rosiak, D, et al. (2013) Fatty acids, essential amino acids, and chlorogenic acids profiles, in vitro protein digestibility and antioxidant activity of food products containing green coffee extract. Int Food Res J 20, 21332144.Google Scholar
11 Lallemand, LA, Zubieta, C, Lee, SG, et al. (2012) A structural basis for the biosynthesis of the major chlorogenic acids found in coffee. Plant Physiol 160, 249260.CrossRefGoogle ScholarPubMed
12 Henry-Vitrac, C, Ibarra, A, Roller, M, et al. (2010) Contribution of chlorogenic acids to the inhibition of human hepatic glucose-6-phosphatase activity in vitro by Svetol, a standardized decaffeinated green coffee extract. J Agric Food Chem 58, 41414144.Google Scholar
13 Bandsma, RH, Wiegman, CH, Herling, AW, et al. (2001) Acute inhibition of glucose-6-phosphate translocator activity leads to increased de novo lipogenesis and development of hepatic steatosis without affecting VLDL production in rats. Diabetes 50, 25912597.Google Scholar
14 Rodriguez de Sotillo, DV & Hadley, M (2000) Chlorogenic acid modifies plasma and liver concentrations of: cholesterol, triacylglycerol, and minerals in (fa/fa) Zucker rats. J Nutr Biochem 13, 717726.CrossRefGoogle Scholar