Author: David Van

1. Introduction

Plants produce a wide variety of compounds to sustain and support growth, development, and reproduction, including secondary metabolites that are not essential for plant growth and, in contrast to primary metabolites, typically bear complex structures. The precise composition and chemical complexity of secondary metabolites became known only with significant improvements with regard to analytical techniques in the middle of the 20th century; particularly the development of chromatography.1 Extractable plant secondary compounds constitute up to 30 % of the dry weight of terrestrial plants, especially in forest ecosystems,2 with their main role as defense against pathogens and herbivores,3 but also as allelopathic agents,4 antioxidants protecting leaves from UV radiation, and excess of light5as well as regulators of nutrient and carbon cycling.6

Among the vast amount of plant secondary compounds, tannins quantitatively dominate, representing the fourth most abundant group of compounds in vascular plant tissue after cellulose, hemicelluloses, and lignin.7 Plants can contain up to 20 % of their dry weight in tannins;7, 8 the amount, however, changes in response to environmental conditions.7 In turn, the effect of environmental stress, such as drought, on the production of tannins is complex and depends on further factors, for example the ontogenetic stage at which the drought stress occurs.9 Additionally, many studies found high tannin concentrations in plants occurring in habitats with low soil fertility and low pH.10 Moreover, it was shown that warming and altered precipitation can affect the chemistry of tannins by increasing their reactivity.11 Chemically, tannins are often divided into two main groups: hydrolysable tannins (HTs) and condensed tannins (CTs) (Figure 1). Hydrolysable tannins can be separated into gallotannins and ellagitannins built up from of gallic acid or hexahydroxydiphenic acid esters, respectively, linked to a sugar moiety (Figures 1 A and 1 B). Condensed tannins (proanthocyanidins) are polymers of three‐ring flavonols joined through C−C bonds12 (Figure 1 D). Monomers of CTs are divided into procyanidins and prodelfinidins (Figure 1 C). The newest findings point to a specific chloroplast‐derived organelle called tannosome as the location of tannin production at the cellular level,13, 14 from which tannins are transported to vacuoles. Overall, the chemical structure of tannins is plant species‐specific and shows a very high variability with probably no two species bearing the same tannin pattern;15 thus, studying tannin chemistry can be very challenging. However, the problem of methodological development is not be presented here.

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Figure 1

Structure of tannins. A) simple gallotannin, B) simple ellagitannin, C) basic unit of condensed tannins, and D) condensed tannin trimer. Modified from Ref. 6.

In this Review, we focus on the recent novel insights into the chemistry of tannins, their interactions with other chemicals, and their influence on enzymatic activity. We challenge tannin chemistry paradigms with the newest findings to obtain a more holistic view on these plant secondary compounds. In Section 2, we evaluate the basic knowledge on tannin–protein interactions, adding the newest findings in the field. In Section 3, we challenge the traditional view on tannin chemistry, that is, that tannins are simply enzyme inhibitors. In Section 4, we expand the reactions of tannins to non‐protein N compounds, underlining the remarkable versatility of tannin chemistry.

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2. Interaction of Tannins with Proteins

According to Bate‐Smith and Swain,16 tannins are “water‐soluble phenolic compounds, with a molecular mass between 0.5 and 3 kDa, able to precipitate proteins and alkaloids”. These tannin mass limitations (0.5–3 kDa) have been extended with time, as also lower and higher molecular mass polyphenolics are able to precipitate proteins;17 however, the ability to form complexes with proteins is still a unique characteristic of tannins,16 for example, used already in ancient times to produce leather from animal skin. The reaction between tannins and proteins involves two stages: first the binding and second the aggregation, resulting in the formation of the precipitate.18, 19, 20 Although earlier work on tannin–protein complexes pointed to non‐covalent bonding and insoluble precipitates, more recent studies add covalent bonding and soluble complexes as a possible result of interactions between tannins and proteins.16

The formation of tannin–protein complexes depends on numerous factors dominated by tannin and protein chemistry (e.g. proline content), concentration, protein isoelectric point, pH, and ionic strength of the solution and also presence of other compounds in the solution.21, 22, 23, 24, 25 The importance of the molecular complexity of tannins for a reaction with proteins was underlined by Haslam,18 who first used structurally well‐defined polyphenols and found that the most crucial features of tannins are phenolic sites crosslinked with proteins. Furthermore, proteins, which are especially prone to reactions with tannins, are proline‐rich proteins (PRPs) found in mammalian saliva.26 These interactions between PRPs and tannins protect dietary nitrogen from polyphenols, but also play a role in taste sensation known as astringency, a feeling of loss of lubrication and dryness.19, 27

According to a well‐known paradigm in tannin chemistry, precipitation of different proteins by tannins strictly depends on the protein isoelectric point (pI).21 At a pH close to the isoelectric point, proteins aggregate more eagerly because they carry no net electrical charge.21 However, according to the newest findings, tannins can also form complexes with proteins at a pH far from their isoelectric point.28, 29 Bovine serum albumin (BSA) typically used in tannin–protein interaction studies with pI 4.7 formed complexes with hydrolysable tannins at neutral pH28, owing to tannin oxidative activity.29 Although interactions between tannins and proteins have been intensively studied over the past 50 years, an in‐depth understanding of all mechanisms regulating tannin–protein interactions is still lacking.

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3. Specific Interaction of Tannins with Enzymes

As the majority of enzymes belong to proteins, it is widely believed that tannins decrease enzymatic activity as a result of enzyme complexation.22, 30−32 Although studies over the past decades have established tannins as potential inhibitors of enzymatic activity,30, 32, 33 some studies found only a minor decrease in their activity.34, 35 Thus, our current understanding on their inhibiting role is still limited. Furthermore, the potential enhancement of enzyme activity by tannins has been overlooked for decades, with only very few exceptions. A study by Tagliazucchi et al.36 showed the ability of some phenolic compounds to enhance pepsin activity, which, however, was explained by phenolic‐induced changes in the substrate protein.37, 38, 39 Moreover, a highly heterogenic incubation study found that tannin‐rich leaves in nylon‐gauze bags in the rumen increased the activity of glutamate ammonia ligase, but no mechanical evidence was provided.40 Only recently, evidence has been found that enzymatic activity is increased after the reaction with tannins present in low concentrations (Figure 2 A).41 This study showed that low concentrations of tannins increased the coiled structures of the enzymes, thereby boosting their catalytic activity.41 High concentrations of tannins lead to opposite results by diminishing the catalytic activity (see Figure 2 C), although even enzyme–tannin complexes exert some residual activity (Figure 2 B).41 The response of enzymes to tannins varied depending on the enzyme.41 Overall, the interactions between tannins and enzymes follow the same rules as for tannins interacting with non‐enzymatic proteins (see Section 2). However, enzymes vary in their affinity to tannins; thus, the potential influence of unknown tannins on a given enzyme is unpredictable. Recent findings in this section suggest that tannins are more than just inhibitors, but rather modifiers of enzyme activity, which should raise interest in different fields controlling enzymatic activity, such as food chemistry, medicine and industry.

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Figure 2

Influence of tannins on enzymatic activity of acid phosphatase: A) changes in enzymatic activity after addition of tannins in different concentrations, B) residual activity of enzymes after formation of complex with tannins, C) infrared spectra of enzyme secondary structure presented as a stacked plot of second derivative. Black lines represent enzyme without tannins and blue lines enzymes with low tannin concentrations. Red lines show enzymes with high tannin concentration. Spectra are smoothed by using eight points. Region of alfa‐helix marked in yellow. Modified from Ref. 42.

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4. Tannin Interactions with Organic Non‐ Protein N Compounds

According to the definition by Bate‐Smith and Swain,16 tannins form precipitates with proteins, but also with alkaloids. However, tannins also create complexes with metals,16, 43 and other compounds, i.e., tannic acid (TA), a common hydrolysable tannin, forms complexes with choline, an amine precursor of acetylcholine;44 TA also adsorbs to chitosan.45, 46 It is widely assumed that tannins from the entire pool of organic N compounds precipitate only proteins/peptides.42 However, only recently, it was shown that tannins can react with a wide set of different organic N compounds,42 including arginine (from all amino acids), nitrogen bases, polyamines, chitin, and chitosan.42 Similarly to tannin–protein reactions, the concentration, chemical structure, and pH of the solution seem to play a decisive role.42 For example, the ability to form multiple hydrogen bonds47 facilitates the formation of complexes with tannins. For proteinaceous amino acids, polyamines, and nitrogen bases, a higher reactivity towards tannins was found with higher molecular masses and more amine groups:42 of all amino acids, arginine has the highest number of amine groups (4) and almost the highest molecular mass (174 Da); for polyamines, spermine has the highest molecular mass (202 Da) and amount of amine groups (4) (see Table 1). For nitrogen bases, the two having no amine groups exerted the weakest reactivity towards tannins.42 Thus, these findings on tannin–non‐protein interactions lead us to further emphasize the importance of tannin chemistry. Moreover, reactions with numerous N compounds call for a change in our way of thinking about tannins: they can react with non‐protein organic N compounds similarly to their reaction with proteins.

Table 1

Reactivity of different organic N compounds towards tannins. Modified from Ref. 42.

Compound	Mw [Da]	N content [%]	Additional information (e.g. functional groups)	Reaction with tannins
Amino acids
alanine	89	15.7	1 amine, 1 methyl, 1carboxyl	−
arginine	174	32.1	4 amine, 1 carboxyl	+
asparagine	132	21.2	1 amide, 1 amine, 1 carboxyl	−
aspartic acid	133	10.5	1 amine, 2 carboxyl	−
cysteine	121	11.5	1 amine, 1 carboxyl, 1 thiol	−
glutamic acid	147	9.5	1 amine, 2 carboxyl	−
glutamine	146	19.1	1 amide, 1 amine, 1 carboxyl	−
glycine	75	18.6	1 amine, 1 carboxyl	−
histidine	155	27.0	1 imidazol, 1 amine, 1 carboxyl	−
isoleucine	131	10.6	1 amine, 1 carboxyl, 1 methyl	−
leucine	131	10.6	1 amine, 1 carboxyl, 1 methyl	−
lysine	146	19.1	2 amine, 1 carboxyl	−
methionine	149	9.3	1 amine, 1 carboxyl, 1 thiol	−
phenyl‐alanine	165	8.4	1 amine, 1 carboxyl, 1 phenyl	−
proline	115	12.1	1 carboxyl, 1 pyrrolidine	−
serine	105	13.3	1 amine, 1 carboxyl, 1 hydroxyl	−
threonine	119	11.7	1 amine, 1 carboxyl, 1 hydroxyl, 1methyl	−
tryptophan	204	13.7	1 amine, 1 carboxyl, 1 indole	−
tyrosine	181	7.7	1 amine, 1 carboxyl, 1 phenyl, 1 hydroxyl	−
valine	117	11.9	1 amine, 1 carboxyl, 2 methyl	−
Polyamines
putrescine	88	31.8	2 amine	+
spermidine	145	28.9	3 amine	+
spermine	202	27.7	4 amine	+
N bases
adenine	135	51.8	1 amine, 4 N in heterocyclic ring	+
cytosine	111	37.8	1 amine, 1 ketone, 2 N in heterocyclic ring	+
guanine	151	46.3	1 amine, 1 ketone, 4 N in heterocyclic ring	+
uracil	112	25.0	1 methyl, 2 ketone, 2 N in heterocyclic ring	+
thymine	126	22.2	1 methyl, 2 ketone, 2 N in heterocyclic ring	+
Aminosugars
chitin	(203)n	6.89	2 amide, 4 hydroxylic, 2 methyl	+
chitosan	(161)n	8.69	1 amine, 2 hydroxyl	+
N‐acetyl‐d‐glucosamine	221	6.3	1 amide, 4 hydroxyl, 1 methyl	−

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5. Conclusions and Perspectives

Interactions between tannins and proteins have been studied for more than 50 years, because of their unique characteristics and potential use in food industry and pharmacology. However, with the new insights regarding regulation of enzymes by tannin concentration and the potential interaction with other non‐protein N compounds, future studies are needed. Special attention should be paid to the use of well‐purified and characterized tannins, because the chemistry of polyphenols and the presence of other compounds in plant extracts may significantly affect tannin interactions with N compounds. Follow‐up studies should aim to extrapolate these results to more complex, heterogenic, realistic systems. In conclusion, studies investigating the interactions between tannins and proteins, but also other organic compounds, are likely to attract significant attention due to the general interest in polyphenols with regard to human health and disease treatment, but also their role in the beverage and food industry.

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Conflict of interest

The authors declare no conflict of interest.

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Biographical Information

Bartosz Adamczyk was born in Lodz (Poland) in 1979. He received a Master’s degree in 2003 (Master of Biology) and PhD degree in 2009 (Doctor of Biology), both from the University of Lodz (Poland). After defending his PhD, he started as a Post‐doc at The Finnish Forest Research Institute (Finland). In 2013, he obtained the title of docent (habilitation) from the University of Helsinki (Finland) and started to work there in 2015. His main interests span chemistry of plant secondary compounds, their role in boreal forest ecosystem, plant biochemistry and mitigation of climate change.

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Biographical Information

Judy Simon leads the Plant Interactions Ecophysiology Group at the University of Konstanz (Germany). After her studies in biology (RWTH Aachen, Germany), biogeography, soil science and geology (Saarland University, Germany), she conducted her PhD research at the University of Melbourne (Australia). She then worked as a Postdoctoral Fellow at the University of Freiburg (Germany), earning her Habilitation (postdoctoral qualification) in 2013. Since 2014, she conducts her research at the University of Konstanz on the influence of global change on plant interactions with regard to resource allocation strategies (i.e. different N acquisition strategies, N allocation to growth vs. defense) in woody species in boreal, temperate and tropical forest ecosystems.

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THE EUROPEAN COMMISSION,

Having regard to the Treaty on the Functioning of the European Union,

Having regard to Regulation (EC) No 1831/2003 of the European Parliament and of the Council of 22 September 2003 on additives for use in animal nutrition (1), and in particular Article 9(2) thereof,

Whereas:

(1)	Regulation (EC) No 1831/2003 provides for the authorisation of additives for use in animal nutrition and for the grounds and procedures for granting such authorisation. Article 10 of that Regulation provides for the re-evaluation of additives authorised pursuant to Council Directive 70/524/EEC (2).

(2)	Tannic acid was authorised without a time limit in accordance with Directive 70/524/EEC as a feed additive for all animal species. That product was subsequently entered in the Register of feed additives as an existing product, in accordance with Article 10(1) of Regulation (EC) No 1831/2003.

(3)

In accordance with Article 10(2) of Regulation (EC) No 1831/2003 in conjunction with Article 7 thereof, an application was submitted for the re-evaluation of tannic acid as a feed additive for all animal species. The applicant requested that additive to be classified in the additive category ‘sensory additives’. That application was accompanied by the particulars and documents required under Article 7(3) of Regulation (EC) No 1831/2003.

(4)

The European Food Safety Authority (‘the Authority’) concluded in its opinion of 11 September 2014 (3) that, under the proposed conditions of use in feed this substance does not have adverse effects on animal health, human health or the environment. The Authority further concluded that the function of tannic acid in feed is similar to that on food. The Authority has already concluded that for food tannic acid is efficacious, as it increases the food smell or palatability. Therefore, that conclusion can be extrapolated for feed.

(5)

Restrictions and conditions should be provided for to allow better control. Since safety reasons do not require the setting of a maximum content and taking into account the re-evaluation performed by the Authority, a recommended content should be indicated on the label of the additive. Where such content is exceeded, certain information should be indicated on the label of premixtures, compound feeds and feed materials.

(6)

The Authority concluded that in the absence of data on user safety tannic acid should be considered as potentially hazardous to the respiratory tract, skin, eyes and mucous membranes. Consequently, appropriate protective measures should be taken. The Authority does not consider that there is a need for specific requirements of post-market monitoring. It also verified the report on the method of analysis of the feed additives in feed submitted by the Reference Laboratory set up by Regulation (EC) No 1831/2003.

(7)	The assessment of the substance concerned shows that the conditions for authorisation, as provided for in Article 5 of Regulation (EC) No 1831/2003, are satisfied. Accordingly, the use of tannic acid should be authorised as specified in the Annex to this Regulation.

(8)	Since safety reasons do not require the immediate application of the modifications to the conditions of authorisation for tannic acid, it is appropriate to allow a transitional period for interested parties to prepare themselves to meet the new requirements resulting from the authorisation.

(9)	The measures provided for in this Regulation are in accordance with the opinion of the Standing Committee on Plants, Animals, Food and Feed,

HAS ADOPTED THIS REGULATION:

Article 1

Authorisation

The substance specified in the Annex, belonging to the additive category ‘sensory additives’ and to the functional group ‘flavouring compounds’, is authorised as a feed additive in animal nutrition subject to the conditions laid down in that Annex.

Article 2

Transitional measures

1.   The substance specified in the Annex and premixtures containing those substances, which are produced and labelled before 6 August 2017 in accordance with the rules applicable before 6 February 2017 may continue to be placed on the market and used until the existing stocks are exhausted.

2.   Compound feed and feed materials containing the substance as specified in the Annex which are produced and labelled before 6 February 2018 in accordance with the rules applicable before 6 February 2017 may continue to be placed on the market and used until the existing stocks are exhausted if they are intended for food-producing animals.

3.   Compound feed and feed materials containing the substance as specified in the Annex which are produced and labelled before 6 February 2019 in accordance with the rules applicable before 6 February 2017 may continue to be placed on the market and used until the existing stocks are exhausted if they are intended for non-food-producing animals.

Article 3

Entry into force

This Regulation shall enter into force on the twentieth day following that of its publication in the Official Journal of the European Union.

This Regulation shall be binding in its entirety and directly applicable in all Member States.

Done at Brussels, 14 December 2016.

For the Commission

The President

Jean-Claude JUNCKER

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(1)  OJ L 268, 18.10.2003, p. 29.

(2)  Council Directive 70/524/EEC of 23 November 1970 concerning additives in feedingstuffs (OJ L 270, 14.12.1970, p. 1).

(3)  EFSA Journal 2014;12(10):3828.

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ANNEX

Identification number of the additive	Name of the holder of authorisation	Additive	Composition, chemical formula, description, analytical method	Species or category of animal	Maximum age	Minimum content	Maximum content	Other provisions	End of period of authorisation
						mg of active substance/kg of complete feedingstuff with a moisture content of 12 %
Category: Sensory additives. Functional group: Flavouring compounds
2b16080	—	Tannic acid	Additive composition Tannic acid Characterisation of the active substance Tannic acid Produced by extraction from different plants. Purity: min. 93 % on dry matter basis Chemical formula: C76H52O46 CAS number 72401-53-7 FLAVIS No: 16.080 Method of analysis  (1) For the determination of tannic acid, in the feed additive: Qualitative colorimetric or precipitation tests (Ph. Eur. 6th edition, monograph 1477) and quantitative gravimetric method (FAO JECFA tannic acid monograph). For the identification of tannic acid (as gallic acid) in the premixture of flavourings: Reversed Phase High Performance Liquid Chromatography coupled to UV detector(RP-HPLC-UV).	All animal species	—	—	—	1. The additive shall be incorporated into the feed in the form of a premixture. 2. In the directions for use of the additive and premixtures, the storage and stability conditions shall be indicated. 3. The recommended maximum content of the active substance shall be: 15 mg/kg of complete feedingstuff with a moisture content of 12 %. 4. On the label of the additive the following shall be indicated: ‘Recommended maximum content of the active substance of complete feedingstuff with a moisture content of 12 %:15 mg/kg’. 5. The functional group, the identification number, the name and the added amount of the active substance shall be indicated on the labelling of the premixtures, feed materials and compound feedingstuffs, if the following content of the active substance in complete feedingstuff with a moisture content of 12 % is exceeded: 15 mg/kg. 6. For users of the additive and premixtures, feed business operators shall establish operational procedures and organisational measures to address potential risks by dermal contact or eyes contact. Where those risks cannot be eliminated or reduced to a minimum by such procedures and measures, the additive and premixtures shall be used with personal protective equipment, including safety glasses and gloves.	6 February 2027

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(1)  Details of the analytical methods are available at the following address of the Reference Laboratory: https://ec.europa.eu/jrc/en/eurl/feed-additives/evaluation-reports

Tannic Acid MW: 772.57 Formula: C34H28O21

What is Tannic Acid? Tannic acid is a polymer of gallic acid molecules and glucose. It the example there are 3 gallic acid molecules, but normally there are about 8. Because there are different molecular structures for tannic acid it would have been better to speak about tannic acids (in plural). Tannic acid will hydrolyze into glucose and gallic or ellagic acid units. Tannic acid is odourless but has a very astringent taste. Pure tannic acid is a light yellowish and amorphous powder. Distribution Tea, nettle, wood, berries, Chinese galls. Oak wood is very rich in tannic acid. When wine is kept in oak kegs some tannic acid will migrate into the wine. High levels of tannic acid are found in some plant galls. These are formed by plants when they are infected by certain insects. These insects pierce the plant leaves and when the egg hatches out into a larva the plant produces a gall which surrounds the larva. Health Benefits of Tannic Acid Tannic acid has anti-bacterial, anti-enzymatic and astringent properties. Tannic acid has constringing action upon mucous tissues such as tongue and inside of mouth. The ingestion of tannic acid caused constipation and can be used to treat diarrhoea (in the absence of fever or inflammation). The anti-oxidant and anti-mutagenic properties of tannic acid are beneficial. However, tannic acid should not be used continuously or in high quantities ad it slows down the absorption of iron and possibly other trace minerals. A study by Afsana K et al entitled Reducing effect of ingesting tannic acid on the absorption of iron, but not of zinc, copper and manganese by rats. published by Bioscience, Biotechnology, and Biochemistry (March 2004) concluded that the usual intake of polyphenols is relatively safe, but that a high intake by supplementation or by dietary habit of tannin affects only the iron level. Tannic acid can also reduce the effectiveness of digestive enzymes. Externally, tannic acid is used to treat ulcers, toothache and wounds. Facts about Tannic Acid Tannic acid is also used in many industrial applications. The best known is the tanning of leather. Tannic is acid is sometimes used to clear wines. Tannic acids reacts with proteins in wine to form insoluble complexes which sediment or can be filtered. Synonyms Gallotanic acid, digallic acid, allotannin, tannimum.