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Open Access Article This Open Access Article is licensed under a Creative Commons Attribution 3.0 Unported Licence DOI: 10.1039/D1NP00018G (Review Article) Nat. Prod. Rep., 2021, 38, 2315-2346 Multi-colored shades of betalains: recent advances in betacyanin chemistry Agnieszka Kumorkiewicz-Jamro ORCID logo, Tomasz Świergosz ORCID logo, Katarzyna Sutor ORCID logo, Aneta Spórna-Kucab ORCID logo and Sławomir Wybraniec ORCID logo Department of Chemical Technology and Environmental Analysis, Faculty of Chemical Engineering and Technology, Cracow University of Technology, Warszawska 24, 31-155 Cracow, Poland. E-mail: agnieszka.kumorkiewicz-jamro@pk.edu.pl; slawomir.wybraniec@pk.edu.pl

Received 13th March 2021 First published on 13th September 2021

Contents 1 Introduction 2 Characterization of betacyanins 2.1 Sources of betacyanin pigments 2.2 Biological properties of betacyanins 2.3 Applications of betacyanin pigments 3 Chemistry of betacyanins and betalamic acid derivatives 3.1 Overview of betacyanin chemical reactions 4 Chemistry of betacyanins and their semi-synthetic derivatives based on betanin hydrolysis 4.1 Hydrolysis of betanin 4.2 One step semi-synthesis of betalains from betalamic acid-derivatized support 4.3 Semi-synthetic betalain pigments with extended conjugated systems 5 Conclusions 6 Conflicts of interest Acknowledgements References Abstract Covering: 2001 to 2021

Betacyanins cover a class of remarkable natural red-violet plant pigments with prospective chemical and biological properties for wide-ranging applications in food, pharmaceuticals, and the cosmetic industry. Betacyanins, forming the betalain pigment group together with yellow betaxanthins, have gained much attention due to the increasing social awareness of the positive impact of natural products on human health. Betalains are commercially recognized as natural food colorants with preliminarily ascertained, but to be further investigated, health-promoting properties. In addition, they exhibit a remarkable structural diversity based on glycosylated and acylated varieties. The main research directions for natural plant pigments are focused on their structure elucidation, methods of their separation and analysis, biological activities, bioavailability, factors affecting their stability, industrial applications as a plant-based food, natural colorants, drugs, and cosmetics as well as methods for high-yield production and stabilization. This review covers period of the last two decades of betacyanin research. In the first part of the review, we present an updated classification of all known betacyanins and their derivatives identified by chemical means as well as by mass spectrometric and NMR techniques. In the second part, we review the current research reports focused on the chemical properties of the pigments (decarboxylation, oxidation, conjugation, and chlorination reactions as well as the acyl group migration phenomenon) and describe the semi-synthesis of natural and artificial fluorescent betalamic acid conjugates, showing various prospective research directions.

image file: d1np00018g-p1.tif Agnieszka Kumorkiewicz-Jamro

Agnieszka Kumorkiewicz-Jamro received her PhD in 2021 from AGH University of Science and Technology (Cracow, Poland). She graduated with a BSc in the field of biotechnology and MSc in analytical chemistry. She is a research and teaching assistant at the Cracow University of Technology. Her main research interests are in phytochemical analysis, and chromatographic methods for natural compounds' separation, purification, and identification. Her current work focuses on (bio)chemical research on betalain pigments isolated from versatile plant sources.

image file: d1np00018g-p2.tif Tomasz Świergosz

Tomasz Świergosz is a researcher at the Department of Chemical Technology and Environmental Analysis, Faculty of Chemical Engineering and Technology (Cracow University of Technology, Poland). His research interests include natural compounds, active organic and macromolecular materials, in particular, supramolecular chemistry of functional dyes and π-conjugated systems, molecular self-assemblies, nanostructures and molecular probes, synthesis and characterization of polymers, photoinitiators for cationic polymerization processes and the investigation of their effectiveness and efficiency in photopolymerization, along with the synthesis of fluorescent compounds as fluorescent probes for special applications.

image file: d1np00018g-p3.tif Katarzyna Sutor

Katarzyna Sutor is a second year PhD student at the Cracow University of Technology (Faculty of Chemical Engineering and Technology). She graduated from MA studies in the field of biotechnology. During her BSc and MSc studies, she focused on the influence of reactive oxygen species on the properties of cancer cells studied by AFM and fluorescence microscopy. This research was carried out in cooperation with the Department of Biophysical Microstructures, H. Niewodniczański Institute of Nuclear Physics of Polish Academy of Sciences (Cracow, Poland), where she was on internship. Currently, she focuses on the chemical and bioactive properties of acylated betacyanins from plant sources.

image file: d1np00018g-p4.tif Aneta Spórna-Kucab

Aneta Spórna-Kucab studied at the Cracow University of Technology (Faculty of Chemical Engineering and Technology). She received her MSc degree in 2008 and PhD in 2013 under the guidance of assoc. prof. Sławomir Wybraniec, working on the chemistry of betalains. During her PhD, she was a researcher at Technische Universität Braunschweig (Braunschweig, Germany) and Brunel University (London, England) where she received formal training in countercurrent chromatography. She is particularly interested in the analytical chemistry of betalains, saponins, and polyphenols as well as the antimicrobial and antioxidant activities of natural compounds.

image file: d1np00018g-p5.tif Sławomir Wybraniec

Sławomir Wybraniec is an associate professor at the Faculty of Chemical Engineering and Technology (Cracow University of Technology, Poland), where he formerly received his BSc and MSc degrees and started his work (in 1991) at the position of Assistant at the Department of Analytical Chemistry. He graduated with a PhD degree from Jagiellonian University (Chemistry Department) in 1997 and after his postdoctoral fellowship (1998–2000) at the Institutes for Applied Research-Ben-Gurion University of the Negev (Beer-Sheva, Israel), he started research on betalain pigments, which he has continued at the Cracow University of Technology to date, exploring the chemistry and bioactivity of betalains.

1 Introduction Betacyanins are unique, water-soluble, red-violet indoline- and dihydropyridine-derived nitrogen-containing natural plant pigments that occur in most families of the Caryophyllales order. Betacyanins, together with yellow-orange betaxanthins, form a group of betalain pigments.1 Simultaneously with anthocyanins, carotenoids, and chlorophylls, betalains are one of the most common plant pigments found in nature.2,3 These compounds share betalamic acid as the main chromogenic structural unit condensed with cyclo-DOPA, forming betanidin or glycosylated cyclo-DOPA in other betacyanins as well as different amino acids or amines in betaxanthins.4,5 So far, betacyanins (Table 1) have been assigned to four structural groups comprising betanin-type, gomphrenin-type, amaranthin-type, and Bougainvillea-r-I-type,6,7 the latter was recently renamed as melocactin-type.8 However, for a convenient view on a wide spectrum of pigments, an expanded division with three additional betacyanin groups is proposed based on the sugar linkage: oleracin-type9 (a very early result, not indepedently confirmed), apiocactin-type,10–12 and Bougainvillea-v-type (here, we propose to name it as glabranin-type). In particular, the latter group of the pigments with the structures based on gomphrenin is important in the division system not only because of its less common 6-O-glycosylation pattern but also because of its unique and extremely complex profile of ca. 146 betacyanins tentatively detected in only one plant species, Bougainvillea glabra Choisy,11 including nine definitively identified betacyanins by LC-ESI-MS and NMR.13

Table 1 List of betacyanins (with proposed new trivial namesa) identified by chemical methods; LC-MS and NMR in different plant sources No. Name Trivial name/proposed new namea m/z [M + H]+ Chem. LC-MS NMR Plant sources(Chem.)/(LC-MS)/(NMR) Ref. (Chem.)/(LC-MS)/(NMR) 1 Betanidin 5-O-β-glucoside Betanin 551 + + + B. vulgaris/G. globosa/B. vulgaris 47 and 48/24/24 2 Betanidin Betanidin 389 + + + B. vulgaris/B. glabra/B. vulgaris 49/50/50 3 2-Decarboxy-betanin 507 − + + B. vulgaris 51 4 14,15-Dehydro-betanin Neobetanin 549 + + + B. vulgaris 52 and 53 5 6′-O-Sulfate-betanin Prebetanin 631 + + + 3x P. americana; B. vulgaris/B. vulgaris/ 54/10/54 6 2-Decarboxy-phyllocactin 593 − + + B. vulgaris 51 7 2-Decarboxy-betanidin 345 + + − C. acinaciformis 55/51 8 2′-O-β-Apiosyl-betanin Apiocactina 683 − + + H. ocamponis 11 9 5′′-O-E-Sinapoyl-apiocactin 889 + + − 2x H. ocamponis/Melocactus spp. 11/8, 11 10 4′-O-Malonyl-betanin 637 + + − H. ocamponis 11 11 5′′-O-E-Feruloyl-apiocactin 859 + + + P. americana 10 12 6′-O-Malonyl-betanin Phyllocactin 637 − + + S. buckleyi/P. hybridus 38/48 13 2′-O-β-Apiosyl-phyllocactin 683 − + + S. buckleyi 38 14 2′-O-β-(5′′-O-E-Feruloyl)-apiosyl-phyllocactin 945 − + − S. buckleyi 38 15 6′-O-(3′′-Hydroxy-3′′-methylglutaryl)-betanin Hylocerenin 695 − + + H. polyrhizus 56 16 Betanidin 5-O-(6′-O-E-4-coumaroyl-β-glucoside) Lampranthin I (697) + − − Lampranthus sp. 57 17 Betanidin 5-O-β-(6′-O-E-feruloyl)-glucoside Lampranthin II 727 + + + Lampranthus sp./G. globosa/L. sociorum 57/24/58 18 3′-O-Sulfate-betanin Rivinianin (631) + − − R. humilis 59 19 Betanidin 5-O-β-sophoroside Bougainvillein-r-I; melocactina 713 + + + 3x Boug. Mrs. Butt’/Melocactus spp./ 32/8, 11/11 20 (Caffeoyl and/or coumaroyl)-bougainvillein-r I Bougainvillein-r-II, III, IV, V − + − − Boug. Mrs. Butt 32 21 Betanidin 5-O-(2′-O-β-glucuronosyl)-glucoside Amaranthin 727 + + + A. tricolor/Amaranthus sp./C. cristata 60/27/61 22 2′′-O-E-4-Coumaroyl-amaranthin Celosianin I; argentianina 873 − + − C. cristata 25 and 27 23 2′′-O-E-Feruloyl-amaranthin Celosianin II; celosianina 903 − + + C. cristata 27 and 58/58 24 6′-O-Malonyl-amaranthin Celoscristatin 813 + + + C. cristata 29 25 4′-O-Malonyl-amaranthin 813 − + − C. cristata 29 26 6′-O-(3′′-Hydroxy-3′′-methylglutaryl)-amaranthin Iresinin I 871 + + + I. herbstii 61/27/61 27 4′-O-Malonyl-bougainvillein-r I 799 − + − Mammillaria spp. 36 28 6′-O-Malonyl-bougainvillein-r I Mammillarinin 799 − + + Mammillaria spp. 36 29 2-Decarboxy-mammillarinin 755 + + − Mammillaria spp. 36 30 17-Decarboxy-mammillarinin 755 − + − Mammillaria spp. 36 31 17-Decarboxy-bougainvillein-r I 669 − + − Mammillaria spp. 36 32 Feruloyl-bougainvillein-r I 889 − + − M. crystallinum L.; B. vulgaris (Swiss chard) 62 and 63 33 (Dehydrated phyllocactin) 619 − + − U. tuberosus 64 35 Betanidin 6-O-β-D-sophoroside Bougainvillein-v; glabranina 713 − + + B. glabra v. sander. 13/33 36 6′′-O-Rhamnosyl-glabranin 859 + − − B. glabra v. sander. 65 37 6′-O-E-Caffeoyl-glabranin Cafglabranina 875 − + + B. glabra 13 38 6′-O-E-4-Coumaroyl-glabranin Coumglabranina 859 − + + B. glabra 13 39 6′′-O-E-4-Coumaroyl-glabranin 859 − + + B. glabra 13 40 6′,6′′-Di-O-E-4-coumaroyl-glabranin Bicoumglabranina 1005 − + + B. glabra 13 41 2′′-O-[(6′′-O-E-4-Coumaroyl)]-glucosyl-cafglabranin 1183 − + + B. glabra 13 42 2′′-O-Glucosyl-bicoumglabranin 1167 − + + B. glabra 13 43 2′′-O-[(6′′-O-E-4-Coumaroyl)]-sophorosyl-cafglabranin 1345 − + + B. glabra 13 44 Feruloyl-dihexosyl-betanidin 889 − + − M. amoenus 8 45 Sinapoyl-dihexosyl-betanidin 919 − + − M. amoenus 8 47 Citryl-(caffeoyl or 4-coumaroyl)-amaranthin Suaedin − + − − S. fruticosa 66 48 2′′-O-E-Sinapoyl-amaranthin Lindenina 933 − + − G. globosa; I. lindenii 25, 30 and 67 49 Betanidin 6-O-β-glucoside Gomphrenin I; gomphrenina 551 + + + G. globosa; B. alba 68/24/24, 69 50 6′-O-E-4-Coumaroyl-gomphrenin I Gomphrenin II; globosina 697 + + + G. globosa 68/24, 25/24 51 6′-O-E-Feruloyl-gomphrenin I Gomphrenin III; basellina 727 + + + G. globosa 68/24, 25/24 52 6′-O-E-Sinapoyl-gomphrenin I Gomphrenin IV; gandolina 757 − + − G. globosa 25 and 26 53 E-Isomer of gomphrenin II 697 − + − G. globosa 30 54 E-Isomer of gomphrenin III 727 − + − G. globosa 30 55 Betanidin 5-O-β-(E-feruloyl)-cellobioside Oleracin I (889) + − − P. oleracea 9 and 60 Number of betacyanins identified by a given method 22 50 31

The schematic division of betacyanins into seven main structural groups based on their chemical structures is shown in Fig. 1. Betacyanins assigned to particular types differ in the attachment of the glucosyl moiety to the oxygen atom in the ortho position of cyclo-DOPA as well as the position of the substitution with additional glycosyl or glucuronosyl moieties.6 The esterification of sugar moieties with organic acids such as ferulic, p-coumaric, caffeic, sinapic, and malonic acids is very common and leads to the formation of various acylated derivatives. The 15R diastereomers (the isoforms, epimers) of betacyanins are found in plants at much lower concentrations than the 15S forms and are regarded rather as artifacts due to epimerization, which takes place during the preparation of extracted plant samples.14 The first studies on isomerization (as well as decarboxylation) mechanism in betacyanins were performed by Dunkelblum et al.15 In more recent reports, the chromatographic differences in the 15S/15R diastereomers of decarboxylated betacyanins16,17 as well as in the acyl migration products18 were investigated.

image file: d1np00018g-f1.tif Fig. 1 A new comprehensive classification of betacyanin pigments belonging to the betanin-type (A); amaranthin-type (B); melocactin-type (C); oleracin-type (D); apiocactin-type (E); gomphrenin-type (F); and glabranin-type (G). The structures of betacyanins belonging to the (B–E) types are based on betanin (I), while the structures of glabranins are based on the gomphrenin backbone (II). Betanin (betanidin 5-O-β-D-glucopyranoside) is the main representative and most common betacyanin pigment found in the plant kingdom (Fig. 1 and 2A). In addition, betanin isolated from Beta vulgaris L. (beetroot, red beet) is the most studied pigment in the context of the antioxidant properties of betacyanins. Structurally, betanin and most of its derivatives are composed of aglycone (betanidin) linked by the β-glucosidic bond with the glucose unit at the C-5 carbon atom.19,20 The chemical structures of additional compounds belonging to betanin-type betacyanins are shown in Fig. 2. Such compounds share a common betanidin backbone in their structures with an additional glucose moiety (betanin) along with (3-methyl-3-hydroxy-methyl)glutaryl-, malonyl-, E-4-coumaroyl-, and E-feruloyl-moieties as well as the half sulphate ester in hylocerenin, phyllocactin, lampranthin I, lampranthin II, and prebetanin, respectively, but can be also partially oxidized (neobetanin) (Fig. 2).

image file: d1np00018g-f2.tif Fig. 2 Chemical structures of betanin-type betacyanins. Gomphrenin (betanidin 6-O-β-D-glucopyranoside), which is the isomeric pigment to betanin, is found at high concentrations in Basella alba L. fruits as well as in the leaves of its variety Basella alba var. ‘Rubra’ L.21,22 According to our recent recommendation, we propose to rename gomphrenin I as “gomphrenin” in order to simplify the naming of its derivatives, especially generated by gomphrenin decarboxylation and oxidation.16 In contrast to betanins, gomphrenins are characterized by the presence of a glucosyl moiety attached at the carbon C-6 (Fig. 1 and 3A).21,22 Furthermore, the acylation of gomphrenin enables the formation of its derivatives such as E-4-coumaroyl-gomphrenin (former gomphrenin II, globosin), E-feruloyl-gomphrenin (former gomphrenin III, basellin), and E-sinapoyl-gomphrenin (gomphrenin IV, gandolin) (Table 1, Fig. 3B–D).12 Gomphrenin pigments are of interest because their glucosylation position at the carbon C-6 should promote an interaction of the acylated residues with the carboxyl groups by increasing the intramolecular stabilization (by intramolecular stacking) of globosin and basellin23 or other types of multiple acylated sophorosyl residues observed in glabranins. Betacyanins were also detected in red and purple Gomphrena globosa L. inflorescences. The most dominant betacyanins present in red G. globosa cultivars are amaranthin and celosianin but in violet species, gomphrenin and especially the acylated derivatives, globosin and basellin, are present.24,25 In addition, other betacyanins were initially identified, namely, Z-4-coumaroyl-gomphrenin and Z-feruloyl-gomphrenin isomers as well as gandolin.25,26

image file: d1np00018g-f3.tif Fig. 3 Chemical structures of basic betacyanins (A–D) belonging to gomphrenin-type. Plant pigments belonging to the amaranthin-type group have a characteristic glucuronosylglucosyl moiety attached to the carbon C-5 in their structure. The most common example of these pigments is amaranthin [betanidin 5-O-β-(2′-O-β-glucuronosyl)glucoside] (Fig. 4A) isolated from plants of the Amaranthaceae family.27,28 The other frequently detected pigments in the plants are betanin and 6′-O-malonyl-amaranthin.29 Furthermore, sinapoyl-amaranthin has been tentatively identified in G. globosa petals.30 Iresinin I [6′-O-(3′′-hydroxy-3′′-methyl)glutaryl-2′-O-glucuronosyl-betanin] and amaranthin are the most abundant pigments detected in Iresine herbstii Hook. ex Lindl leaves (Table 1).27 Acylated amaranthin-based pigments, argentianin and celosianin, were also found in Celosia species31 and the purple leaves of I. herbstii (Fig. 4).25

image file: d1np00018g-f4.tif Fig. 4 Chemical structures of betacyanins (A–E) belonging to amaranthin-type. Most of the pigments from the two Bougainvillea groups have sophorosyl moieties linked to carbons C-5 or C-6 of the basic skeleton of betanidin, expanded further by glucosyl, rhamnosyl, apiosyl, or xylosyl moieties.13,26,32–35 A complex mixture of betacyanins that differs in acyl-oligoglycoside units and exists mostly in the 6-O-glycosylated forms of betanidin was initially identified in the purple bracts of B. glabra.13 However, due to the complex mixture of a huge number of betacyanins present in B. glabra,34 its profile has not been completely characterized. The examples of bougainvillein-type betacyanins are bougainvillein-r-I (melocactin-type) and bougainvillein-v (glabranin-type) (Table 1, Fig. 5A and B). Similar betacyanins were recently found within Melocactus species.8 The most abundant pigment, melocactin, previously named ‘bougainvillein-r-I’, was identified as betanidin 5-O-β-sophoroside (Fig. 5A). The presence of feruloylated and sinapoylated melocactins as well as melocactin's malonylated derivative, mammillarinin, was also noted (Fig. 5C).8 In some Mammillaria species, mammillarinin [betanidin 5-O-(6′-O-malonyl)-β-sophoroside] was reported as the dominant pigment.36

image file: d1np00018g-f5.tif Fig. 5 Chemical structures of betacyanins belonging to both the bougainvillein groups: melocactin-type (bougainvillein-r-I (A) and mammillarinin (C)) and glabranin-type (bougainvillein-v) (B). Two red-violet acylated betacyanins, oleracins I and II, have been found in Portulaca oleracea L. Upon hydrolysis in alkaline conditions, oleracins gave ferulic acid and two newly detected pigments that were identified as 5-O-β-cellobiosides of betanidin and isobetanidin (Fig. 1E).9 Five other yellow oleracins were also detected in P. oleracea; however, in contrast to oleracins I and II, they did not possess betalamic acid in their structures.37

Betacyanins belonging to the apiocactin-type group contain the rare branched pentose, apiose, bound to the carbon C-2′ of betanin. Pigments such as 2′-O-β-apiosyl-betanin (apiocactin) and/or its acylated derivatives (Table 1, Fig. 6A–C) have been found in fruits of pokeberry and its corresponding suspension and callus cultures (Phytolacca americana L.), Christmas cactus flowers (Schlumbergera x buckleyi), and Hylocereus species.10,11,38 The chemical structure of the basic apiocactin-type betacyanin present in Hylocereus species was confirmed as 2′-O-β-apiosyl-betanin by Wybraniec et al.11 In addition, in the same study, acylated compounds with sinapoyl and feruloyl residues attached to C-5′′ of the apiose moiety were identified as 5′′-O-E-sinapoyl-apiocactin and 5′′-O-E-feruloyl-apiocactin.11 Similarly, 5′′-O-E-feruloyl-apiocactin was identified earlier in P. americana cultures by Schliemann et al.10 Another betacyanin, 2′-O-β-(5′′-O-E-feruloyl)-apiosyl-phyllocactin, which is the first betacyanin example containing both an aliphatic and an aromatic acyl residue, was tentatively detected in Christmas cactus flower extracts together with other apiocactin derivatives38 and later in Hylocereus species.11

image file: d1np00018g-f6.tif Fig. 6 Chemical structures of betacyanins (A–D) belonging to apiocactin-type. 2 Characterization of betacyanins 2.1 Sources of betacyanin pigments There are several known edible sources of betacyanins (Table 1). These include red and yellow beetroots (B. vulgaris ssp. vulgaris),1B. alba fruits,39G. globosa flowers,13,30 grainy amaranth (Amaranthus sp.),27 grains of Chenopodium quinoa,40 leaves of A. hortensis var. rubra,41 and fruits/flowers of cacti genera (Opuntia, Hylocereus, Mammillaria, Melocactus, and Myrtillocactus spec.).8,36,42–45 Pokeberry (Phytolacca americana L.) is another source of betacyanins but it has been forbidden as a food colorant due to the presence of toxic saponins and lectins.46 Compounds tentatively identified as betacyanin-like are also found in some higher fungi such as Amanita muscaria (fly agaric).70,71 The less common edible sources are Ulluco tubers (Ullucus tuberosus)64,72 as well as fruits and berries of pigeonberry (Rivina humilis).73

Table 1 presents a detailed summary of the identified betacyanins in different plant sources along with the methods of their identification. Most of the chemical methods were applied in the early decades of betalain research based on the typical reactions of hydrolysis and derivatization, such as permethylation and partial degradation, resulting in the generation of diagnostic products, which can be identified and can confirm certain parts of the chemical structure of a starting compound. The chemical structures of 31 naturally occurring betacyanins were definitively identified by NMR methods, whereas a huge group of over 187 betacyanins (including pigments from their richest source, B. glabra) were detected by LC-MS techniques and still await the final confirmation. In addition, structures of 18 betacyanin derivatives were also confirmed by NMR and 61 tentatively were identified by LC-MS methods (Fig. 7).

image file: d1np00018g-f7.tif Fig. 7 The number of naturally-occurring betacyanins and semi-synthesized betacyanins derivatives identified chemically, by NMR techniques and detected by LC-MS methods. 2.2 Biological properties of betacyanins Numerous health-promoting activities are attributed to betacyanin pigments, including antioxidative,6,74 chemopreventive,75 and anti-inflammatory76,77 properties. Furthermore, it was noted that betacyanins protect low-density lipoproteins (LDL) against oxidative damage by reacting with the LDL polar groups.78 In addition, betanin present in red beets prevents DNA from damage in lymphocytes and hepatocytes.79 Betanin also shows neuroprotective effects, improves cognitive functions and reduces oxidative stress caused by D-galactose in the brain of mice by increasing the level of antioxidant enzymes and reducing lipid peroxidation.80 Some betacyanin pigments have been shown to have higher antioxidant activity compared to typical natural antioxidants such as ascorbic acid,81 rutin,82 catechin,83 β-carotene,84 and α-tocopherol.6,85 In a test of the antioxidant activity expressed in TROLOX equivalents, betacyanins extracted from red beet exhibited 1.5–2.0 times higher free radical scavenging activity than some anthocyanins such as cyanidine-3-O-glucoside and cyanidine above pH 4.86,87

The effect of the hydroxyl group position on the antioxidant activity of the betacyanins bearing the conjugated phenol moiety was studied. Three non-natural regioisomeric phenolic betacyanins (common name: o-, m-, p-OH-pBeets) were semi-synthesized by coupling betalamic acid with appropriate aminophenols in water according to a procedure described by Schliemann and co-authors88 and their antioxidant activity was studied.89,90 The results showed that the meta isomer exhibits greater antiradical activity than most of the betalains, flavonoids, and anthocyanins. This result may be explained by the fact that the phenolic moiety is not conjugated with the diazapolymethine system but both groups are prone to further oxidation and can stabilize the radicals by resonance. In addition, the N–H imine bond present in the meta regioisomeric structure is the preferred site for oxidation, whereas 1e− oxidation of the phenolic groups in p- and o-OH-pBeet results in the formation of semi-quinone and leads to lower values of the potential energy (Ep) compared to m-OH-pBeet.89,90

Betacyanins have been shown to actively participate in free radical scavenging and consequently, their consumption may lead to chemoprevention and delay of the development of cancer tissues.75 Purified betanin shows strong inhibition of melanoma cancer cell proliferation91 and excellent growth inhibition of MCF-7 (breast), HCT-116 (colon), AGS (stomach), SF-268 (CNS), and NCI-H460 (lungs) cancer cell lines with IC50 values of 162, 142, 158, 164, and 147 μg mL−1, respectively.92 It has also been found that betanin induces dose- and time-dependent apoptosis of cells in the human chronic myelogenous leukemia (K562) cell line.93

In vitro experiments revealed that betalains extracted from B. vulgaris juice show pro-apoptotic effects on activated neutrophils and inhibit the neutrophil oxidative metabolism.94 In addition, pilot clinical trials have shown that short-term treatment with red beet extract improves joint function in people with knee joint discomfort.76,95

2.3 Applications of betacyanin pigments In Fig. 8, betacyanin applications are schematically presented. Natural plant extracts containing betacyanin pigments are increasingly used in food technology as a safe alternative to synthetic food colorants. According to Title 21 of the Code of Federal Regulations part 73.40 of the Food and Drug Administration (FDA), USA, and under the E-162 code in the European Union, beetroot powder rich in betanin is permitted as a natural red food colorant.3 Food preparations obtained in different industrial conditions can significantly vary in their stability and coloration due to the presence and the composition of betacyanin degradation products. Betalains are stable at pH ranging from 3 to 7 and they are suitable for dyeing low acidic and neutral foods. In addition, they may be stabilized by ascorbic acid. In contrast, due to instability at pH over 3, the application of anthocyanins in the coloration of such foods is not possible. Furthermore, the use of ascorbic acid also facilitates the degradation of anthocyanins. For this reason, the utilization of betalain pigments instead of anthocyanins for coloring food with a high amount of vitamin C or vitamin C-supplemented products seems to be more favorable.96,97 Beetroot extracts are utilized to emphasize the redness of dairy products such as tomato soups, sauces, pastes, desserts, jams, sweets, and jelly beans. They are also used to protect meat from discoloration and to extend its shelf-life.98 However, due to the unpleasant flavor of beetroot extracts due to their geosmin and pyrazine derivatives content, a membrane process during juice concentration is needed to be applied for commercial red beet application.14 image file: d1np00018g-f8.tif Fig. 8 Overview of various betacyanin pigment applications. Due to health-related benefits, betalains are also regarded as natural dietary supplements.99 The effect of food supplements containing betalain-rich extracts (a betalain-rich supplement of red beetroot and a betacyanin-rich supplement of Opuntia stricta) on different atherosclerotic risk factors were tested among coronary artery disease patients. The results showed that the levels of glucose, total cholesterol, homocysteine, triglyceride, and low-density lipoprotein (LDL) of 48 male patients were decreased. Furthermore, betalain-rich supplements taken at a safe dose of 50 mg betalain/betacyanins for 2 week interventions reduced the systolic and diastolic blood pressures.100 In the past 20 years, a number of food and nutraceutical preparations have been developed from quinoa (Chenopodium quinoa Willd.) as well. Several clinical studies have demonstrated that quinoa supplementation exerts prominent effects on the cardiovascular, gastrointestinal, and metabolic health of humans.101

Natural plant pigments were also tested in the context of solar cell applications as a cheaper, faster, low energy, and environment-friendly alternative to dyes based on ruthenium complexes.102,103 Betanin, 2,17-bidecarboxy-betanin, vulgaxanthin I, extracted from red beetroot extract and betanidin-6-O-(6′,6′′-di-O-E-4-coumaroyl)-β-sophoroside from Bougainvillea were also tested toward the application as dye-sensitized solar cells (DSSC). The construction of betalain-based DSSC is possible due to the carboxylic groups in betalains, which serve as anchors after the immersion of TiO2 electrodes in betalain aqueous solutions at pH ≈ 3. The quantum yield of electron injection in betacyanin-based and betaxanthin-based DSSC is about 50% and 70%, respectively. In the case of betaxanthin-based DSSC, the total sunlight conversion efficiency was however smaller because of the blue-shifted absorption band.104 The electron injection from betanin to TiO2 is a two-electron, one-proton process.105,106

Enhanced light-harvesting and the photoconversion efficiency of nanocrystalline TiO2 sensitized with betanin was observed and revealed the self-assembly of betanin on the surface. Due to the fact that an aggregated betanin sensitizer improved the performance in DSSC, the mechanism of improved electron injection and collection in DSSCs with more aggregation as compared to monomeric betanin need to be regarded.107

Betanin is capable of injecting up to two electrons per photon absorbed into the ZnO conduction band in less than 15 ps.108 Betanin was also used for the light-harvesting process in ultra-stable ZnO nanocrystals modified with a carboxylate oligoethylene glycol shell system studied for utilization in H2 production under visible light irradiation.109

The photophysical properties of betanin in aqueous and alcoholic solutions were determined and formation of betanin electronically excited species was studied. Betanin has a short S1 state lifetime (π, π*) (6.4 ps in water), mainly determined by the efficient S1 → S0 radiationless relaxation, which probably requires a strong geometry change. Other processes, such as photoproduct formation or S1 → T1 intersystem crossing have been reported as virtually absent. In the absence of triplet excited state formation, the fast light-to-heat conversion was observed, supporting the consideration that betanin is a photoprotector in vivo.110,111

Due to the presence of the phenolic moiety within the betanin structure, which may react with 1O2, the colorimetric detection of reactive oxygen species is possible. Efficient singlet oxygen quenching by betanin in deuterated water was reported. The capacity of betanin to quench 1O2 supports the photo-protective role of betanin in vivo.112

In another study, a red beetroot pigment-based colorimetric sensor for detecting copper ions in drinking water was developed. In addition, an application for quantitative and visual colorimetric analysis was designed for the Android system smartphone. When Cu2+ concentration in drinking water increased, the red beet pigment solution gradually changed from bright purple to orange-red as it formed a complex by chelating Cu2+. The linear range of this detection system ranged from 4 to 20 μM and the limit of detection was 0.84 μM.113

Betanin can also compete with synthetic dyes in terms of the depth and color stability. The possibility of dying of modified acrylic fabrics with betanin was investigated. It was found that the optimal conditions during 45 min dyeing of acrylic fabrics with betanin were 50 °C and pH 5. The modified materials were resistant to color loss under the influence of water and the addition of cobalt(II) sulphate(VI) (CoSO4) ensured light resistance.114

Attempts are being made to develop cheap, green, and easy-to-use betalain-based biosensors. A good example is a need for the early detection of Bacillus species. The highly stable and virulent B. anthracis has been considered as a dangerous bioterrorism agent after the anthrax attack took place in 2001.115 Another threat is pathogenic B. cereus that grows on food.116 In order to detect the Bacillus species early, research on the application of betanin as a ligand in the new europium(III) complex, sensitive to calcium dipicolinate, CaDPA (the major component of the bacterial spore core) was conducted. In the presence of Eu(III) ions, betanin was converted into a water-soluble, non-luminescent orange complex. The addition of CaDPA changes the orange color of the [Eu(betanin)+] aqueous solution to magenta. The limit of detection of CaDPA is about 2.06 × 10−6 mol L−1. In addition, the complex is sensitive to CaDPA but not to other structurally similar aromatic, pyridinic, and acidic ligands.117,118

Beetroot extracts are under consideration as a mild alternative to organometallic reductants, such as NaBH4 and N2H4, and as stabilizing (growth-limiting) agents. Beetroot extract was exploited for the bottom-up synthesis of metal nanoparticles, leading to broad size and shape distributions.119

3 Chemistry of betacyanins and betalamic acid derivatives 3.1 Overview of betacyanin chemical reactions Taking into account the pro-health nature of betacyanin pigments, their diversity, structural characteristics, and light-absorption properties, there is a growing need to supplement and broaden the knowledge on their chemistry. Understanding the reactions that betacyanins undergo may contribute to the determination of their fate and distribution in the human body, increase their stability, the development of betalain-based biosensors, screening assays and tailor-made probes, the preparation of betalain-based potential medicinal substances or cosmetics. In the following part of this contribution, we sum up the current knowledge obtained during the last decade on the chemical properties of betacyanins as well as new perspectives of the semi-synthesis of betalamic acid derivatives with extended chromophoric systems. The list of betacyanin derivatives semi-synthesized from plant sources and betacyanin degradation or chemical conversion products, with their structural identification by LC-MS and NMR methods, is presented in Table 2. Table 2 List of betacyanin derivatives semi-synthesized from plant sources and betacyanin degradation or chemical conversion products, with their structural identification by LC-MS and NMR methods No. Name Trivial name or abbreviation m/z [M + H]+ LC-MS NMR Plant sources (Chem.)/(LC-MS)/(NMR) References (Chem.)/(LC-MS)/(NMR) 56 2-Decarboxy-betanin 2-dBt 507 + + B. vulgaris/H. polyrhizus 126/127 57 15-Decarboxy-betanin 15-dBt 507 + − B. vulgaris 122 58 17-Decarboxy-betanin 17-dBt 507 + + B. vulgaris/H. polyrhizus 122/127 59 2,17-Bidecarboxy-betanin 2,17-dBt 463 + + B. vulgaris/H. polyrhizus 126/127 60 2,15,17-Tridecarboxy-betanin 2,15,17-dBt 419 + − B. vulgaris 126 61 2-Decarboxy-neobetanin 2-dNBt 505 + − B. vulgaris 126 62 2,17-Bidecarboxy-neobetanin 2,17-dNBt 461 + − B. vulgaris 126 63 2,15,17-Tridecarboxy-neobetanin 2,15,17-dNBt 417 + − B. vulgaris 126 64 2,17-Bidecarboxy-xanbetanin 2,17-dXBt 461 + − B. vulgaris 52 65 2-Decarboxy-xanneobetanin 2-dXNBt 503 + + B. vulgaris 52 66 2,17-Bidecarboxy-xanneobetanin 2,17-dXNBt 459 + + B. vulgaris 52 67 2,15,17-Tridecarboxy-xanneobetanin 2,15,17-dXNBt 415 + + B. vulgaris 52 68 18-Chloro-betanin Bt-Cl 585 + + B. vulgaris 156 69 18-Chloro-17-decarboxy-betanin 17-dBt-Cl 541 + + B. vulgaris 156 70 18-Chloro-2,17-bidecarboxy-betanin 2,17-dBt-Cl 497 + + B. vulgaris 156 71 18-Chloro-2-decarboxy-betanin 2-dBt-Cl 541 + − B. vulgaris 156 72 18-Chloro-15-decarboxy-betanin 15-dBt-Cl 541 + − B. vulgaris 156 73 Cysteinyl-2-decarboxy-xanbetanin 2-dXBt-Cys 624 + − B. vulgaris 149 74 2-Decarboxy-xanbetanin 2-dXBt 505 + − B. vulgaris 149 75 N-Methyl-phenyl-betalain mepBeet 301 + + B. vulgaris 165 76 N-Aryl-phenyl-betalains dipBeet 363 + + B. vulgaris 165 77 2,4-Dimethylpyrrole-betalain BeetBlue 289 + + B. vulgaris 166 78 7-Amino-4-methylcoumarin-betalain cBeet120 369 + + B. vulgaris 167 79 7-Amino-4-trifluoromethylcoumarin-betalain cBeet151 423 + + B. vulgaris 167 80 7-Amino-4-methylcoumarin-betalain BtC 369 + − B. vulgaris 168 81 17-Decarboxy-neobetanin 17-dNBt 505 + − H. polyrhizus 125 82 2-Decarboxy-phyllocactin 2-dPc 593 + + H. polyrhizus 125/127 83 17-Decarboxy-phyllocactin 17-dPc 593 + + H. polyrhizus 125/127 84 2,17-Bidecarboxy-phyllocactin 2,17-dPc 549 + + H. polyrhizus 125/127 85 2,15,17-Tridecarboxy-phyllocactin 2,15,17-dPc 505 + − H. polyrhizus 125 86 2-Decarboxy-hylocerenin 2-dHc 651 + + H. polyrhizus 125/127 87 17-Decarboxy-hylocerenin 17-dHc 651 + − H. polyrhizus 125 88 2,17-Bidecarboxy-hylocerenin 2,17-dHc 607 + + H. polyrhizus 125/127 89 2,15,17-Tridecarboxy-hylocerenin 2,15,17-dHc 563 + − H. polyrhizus 125 90 2-Decarboxy-neophyllocactin 2-dNPc 591 + − H. polyrhizus 125 91 17-Decarboxy-neophyllocactin 17-dNPc 591 + − H. polyrhizus 125 92 2,17-Bidecarboxy-neophyllocactin 2,17-dNPc 547 + − H. polyrhizus 125 93 2,15,17-Tridecarboxy-neophyllocactin 2,15,17-dNPc 503 + − H. polyrhizus 125 94 2-Decarboxy-neohylocerenin 2-dNHc 649 + − H. polyrhizus 125 95 17-Decarboxy-neohylocerenin 17-dNHc 649 + − H. polyrhizus 125 96 2,17-Bidecarboxy-neohylocerenin 2,17-dNHc 605 + − H. polyrhizus 125 97 2,15,17-Tridecarboxy-neohylocerenin 2,15,17-dNHc 561 + − H. polyrhizus 125 98 2-Decarboxy-xanbetanidin 2-dXBd 343 + − B. alba 140 99 2,17-Bidecarboxy-xanbetanidin 2,17-dXBd 299 + − B. alba 140 100 2-Decarboxy-xangomphrenin; 2-dXGp 505 + − B. alba 140 101 2,17-Bidecarboxy-xangomphrenin 2,17-dXGp 461 + − B. alba 140 102 2-Decarboxy-xanneobetanidin 2-dXNBd 341 + − B. alba 140 103 2,17-Bidecarboxy-xanneobetanidin 2,17-dXNBd 297 + − B. alba 140 104 2-Decarboxy-xanneogomphrenin 2-dXNGp 503 + − B. alba 140 105 2,17-Bidecarboxy-xanneogomphrenin 2,17-dXNGp 459 + − B. alba 140 106 2,15,17-Tridecarboxy-xanneogomphrenin 2,15,17-dXNGp 415 + − B. alba 140 107 Cysteinyl-betanidin Cys-Bd 508 + − B. alba 149 108 Cysteaminyl-betanidin CSH-Bd 464 + − B. alba 149 109 N-Acetyl-cysteinyl-betanidin NAC-Bd 550 + − B. alba 149 110 Dithiothreitol-betanidin DTT-Bd 541 + − B. alba 149 111 Cysteinyl-gomphrenin Cys-Gp 670 + − B. alba 149 112 Cysteaminyl-gomphrenin CSH-Gp 626 + − B. alba 149 113 Dithiothreitol-gomphrenin DTT-Gp 703 + − B. alba 149 114 N-Acetyl-cysteinyl-gomphrenin NAC-Gp 712 + + B. alba 149 115 Glutathionyl-betanidin GSH-Bd 694 + + B. alba 140 116 Glutathionyl-gomphrenin GSH-Gp 856 + − B. alba 140 Number of betacyanin derivatives identified by a given method 18 6

3.1.1 Thermal decarboxylation and dehydrogenation of betacyanins. Considering the significant impact of organoleptic characteristics on food selection and consumer acceptance, color is one of the most important attributes of foods as it is considered as a quality indicator.120,121 Nowadays, the complex processing of most foodstuffs may cause some unwanted changes in their visual appearance, contributing to the fading effect in their coloration. During the degradation of betacyanins, they may undergo deglucosylation, decarboxylation, dehydrogenation, and isomerization processes (Fig. 9). image file: d1np00018g-f9.tif Fig. 9 Possible pathways of betanin transformation by decarboxylation, dehydrogenation, and deglucosylation.129 The m/z values are from the [M + H]+ ions. The first heat-degradation structural studies on betanin from B. vulgaris, as well as betacyanins isolated from H. polyrhizus (betanin, phyllocactin, and hylocerenin), were performed by Herbach et al.122–124 and Wybraniec et al.125–127 Betanin was proven to be the most stable pigment, while the stability of phyllocactin and hylocerenin was seemingly enhanced due to the formation of red degradation products, exhibiting improved color retention in comparison to their precursors. Betanin degradation proceeded through hydrolytic cleavage, while hylocerenin dominated in decarboxylation and dehydrogenation. The degradation of phyllocactin involves the decarboxylation of the malonic acid moiety and the formation of betanin by demalonylation along with subsequent betanin degradation. After prolonged heating, dehydrogenation at C2–C3 carbons was also noticed.123–125,127

Decarboxylated and dehydrogenated betanin derivatives occurring at the highest concentrations in a betacyanin-rich red beetroot extract (RBE) were also characterized (Table 2).128 The main pigments in the RBE are betanin and its isoform with 17-decarboxy-betanin/-isobetanin, 15-decarboxy-betanin, and small quantities of 2-decarboxy-betanin/-isobetanin as well as 2,17-bidecarboxy-betanin/-isobetanin.128 Furthermore, mixtures of mono-, bi-, and tridecarboxylated betanins together with their corresponding neo-derivatives obtained from the RBE were identified as the heating degradation products.129 In addition, new isomeric decarboxylated derivatives, namely, 2,15-bidecarboxy-betanin and 15,17-bidecarboxy-betanin, were detected for the first time. These newly detected derivatives were also formed during heating experiments on red beetroot extract. Furthermore, the presence of 2,15,17-tridecarboxy-betanin was also acknowledged.129 Presumably, the presence of these additional betanin derivatives results from enhanced decarboxylation, which is an integral process during RBE preparation. It was also reported that the higher concentration of acetic acid during the thermal treatment of RBE contributes to a selective formation of 2-decarboxy-betanin/-isobetanin. The latter pigments are present in the RBE at a very low level. However, according to the report, the most decisive factors are the concentrations of the substrate and acetic acid. Higher RBE concentration favors the formation of 2,17-bidecarboxy-betanin/-isobetanin over 2,15-bidecarboxy-betanin.129

An effective method for the separation of newly formed derivatives was also proposed. A bunch of decarboxylated and dehydrogenated betacyanins obtained during mild thermal treatment of B. vulgaris juice was subjected to high-performance counter-current chromatographic (HPCCC) preparative fractionations.130 The mixtures composed of betacyanins with different polarity and physicochemical properties were separated in highly polar solvent systems containing a high concentration of ammonium sulfate and ion-pairs, aqueous-organic solvent systems including ion-pair reagents (trifluoroacetic acid, heptafluorobutyric acid). The application of both the solvent systems enabled the separation and purification of 2-decarboxy-betanin, 2,17-bidecarboxy-betanin, their corresponding isoforms, and neobetanin from a mixture composed mainly of betacyanins, neobetanin, and their decarboxylated derivatives (Table 2), as well as 17-decarboxy-neobetanin, 2,15,17-tridecarboxy-2,3-dehydro-neobetanin, 2,17-bidecarboxy-2,3-dehydro-neobetanin, 2,15,17-tridecarboxy-neobetanin, and 2-decarboxy-neobetanin from another mixture consisting of decarboxy- and dehydrobetacyanins. The results also show that the utilization of heptafluorobutyric acid as an ion-pair reagent is more suitable than a polar solvent system with trifluoroacetic acid because it contributes to the formation of more hydrophobic betacyanin ion-pairs.130 The separation of betacyanins from a processed B. vulgaris juice (betanin, isobetanin, neobetanin, and decarboxylated betacyanins) was also demonstrated in a food-grade, gradient solvent system consisting of sodium chloride, butanol, water, as well as different volumes of phosphoric acid and/or ethanol. The quality of isolation was dependent on the ethanol and acid concentrations with the lowest volume gradient, providing the best separation conditions. Betacyanins were eluted in the organic, upper mobile phase, which has a low salt content compared to the aqueous lower phase.131

The first study on the thermal decomposition of gomphrenin pigments present in the fruit juice of B. alba was carried out and the chromatographic profiles, as well as fragmentation pathways of decarboxylation and dehydrogenation products of gomphrenin (Table 2), were determined by LC-DAD-ESI-MS/MS and LC-MS-IT-TOF.16 The short-term treatment of B. alba juice revealed the profiles of mono- and bi-decarboxylated gomphrenins analogous to betacyanins from heated beetroot juice.

Prolonged heating of B. alba extract acidified with acetic acid led to the formation of dehydrogenated derivatives as a result of gomphrenin derivative oxidation. The presence of neogomphrenin was detected at a low concentration level in the heated juice, which is opposite to RBE rich in neobetanin. In addition, in contrast to the results of the RBE heating experiments,129 the isomeric 2,15- and 15,17-decarboxylated derivatives were not detected in the heated samples. The above experiments indicated that the chromatographic differences between gomphrenin and betanin derivatives arose from the position of glucosylation in betanidin at carbon atoms C-5 or C-6.16

Sawicki and Wiczkowski investigated the impact of boiling and spontaneous fermentation on the betalain profile and content in beetroot. The boiling and fermentation of beetroot decreased the content of the betalains by 51–61% and 61–88%, respectively. Processes occurring during boiling and spontaneous fermentation such as heating, softening, leaching, and acidification together with the matrix effect may be responsible for the changes. In addition, the microbial activity and matrix softening occurring during fermentation caused a release of betalains, which is responsible for the potent antioxidant capacity of the formed beet juice.132

Sawicki et al. determined the impact of three technological processes (fermentation, boiling, and microwave-vacuuming treatment) and in vitro digestion on betalain profiles. The content of betalains in the products was reduced by 42–70%. Microwave-vacuuming treatment has contributed to the degradation of betanin at the lowest level and may be regarded as the best treatment method. In addition, the content of betalains released from the beetroot products after in vitro digestion reached the range of 0.001–0.10%, and the number of compounds identified in the digestion phases was decreased.133

3.1.2. Oxidation of betacyanin pigments. Preliminary studies on the enzymatic and non-enzymatic oxidation of betanidin, betanin, neobetanin, as well as decarboxylated betanins along with the research on intermediate and final reaction products, were carried out.134–136 Betanidin is the basic structure of all the betacyanins and the only one with the catechol moiety (5,6-dihydroxyl moiety). Studies show that during the oxidation of betanidin, the pigment is most likely converted into three tautomeric quinoid derivatives (Fig. 10). Interconvertions, which occur slowly at pH 4–7 and quickly in a more acidic environment, are likely to result in the formation of dehydrogenated and decarboxylated derivatives. Interconversions between the three tautomeric quinoid forms of oxidized betanidin are based on the proven oxidation pathways of DOPA and dopamine.137,138

image file: d1np00018g-f10.tif Fig. 10 Scheme of the initial transformations of betanidin during its oxidation and with an indication of the intramolecular conversions between three tautomeric forms based on.134 The initial oxidation of betanidin should generate the transient radical cation, which rapidly loses a proton and forms a neutral phenoxy radical; it is equivalent to the donation of a hydrogen atom by betanidin or to the loss of a proton with further electron transfer. In the next step, the loss of a second proton and electron results in the formation of a two-electron oxidized form, i.e., one of the three quinoid tautomers. Presumably, not only the betanidin o-quinone with its characteristic absorption spectrum (λmax at 550 and 400 nm) is formed on the first oxidation stage but it is assumed that the two other quinoid derivatives are also possible: dopamine derivative and/or quinone methide. The discussion of the balance between the three tautomeric forms of quinoid remains open.135 As a result, 2,17-bidecarboxy-xanbetanidin (synonym of 2,17-bidecarboxy-2,3-dehydro-betanidin) and 2-decarboxy-xanbetanidin (synonym of 2-decarboxy-2,3-dehydro-betanidin) are postulated as the principal oxidation products formed (Table 2). The recently proposed xan is derived from the hypsochromic shift toward the yellow color of the resulting compounds.

The further oxidation of 2,17-bidecarboxy-xanbetanidin again involves the formation of one of the two possible quinoid forms as the oxidized intermediates, e.g., the dopachromic derivative of the indolic system. Subsequent rearrangement of the conjugated system of the originated structures into the neo-forms (14,15-dehydrogenated derivatives) is possible which finally leads to 2,17-bidecarboxy-xanneobetanidin (2,17-bidecarboxy-2,3-dehydro-neobetanidin), i.e., a compound doubly dehydrogenated at the positions C-2,3 and C-14,15.134–136

In contrast to betanidin oxidation, no compound that could be regarded as the betanin oxidation intermediate (quinone methide) was detected.139 This could be a consequence of its instability and fast rearrangement combined with decarboxylation. The main compound formed during the first step of betanin oxidation is 2-decarboxy-xanbetanin (Table 2), which exhibits a characteristic protonated molecular ion [M + H]+ at m/z 505 and an absorption maximum at λmax = 446 nm (Fig. 11). It is not excluded, however, that the generated 2-decarboxy-xanbetanin rearranges to a more stable structure of 2-decarboxy-neobetanin (synonym of 2-decarboxy-14,15-dehydro-betanin). According to the alternative pathway proposed by Wybraniec et al.,135 the formation of 2-decarboxy-neobetanin can result from a rearrangement of the quinone methide generated from 2-decarboxy-betanin. This alternate pathway does not include the presumably more stable product, 2-decarboxy-xanbetanin. Further, the decarboxylation of 2-decarboxy-xanbetanin presumably results in the formation of 2,17-bidecarboxy-xanbetanin. The most hydrophobic product of betanin degradation/oxidation is 2-decarboxy-xanneobetanin, characterized by a protonated molecular ion at m/z 503 and maximum absorption at λmax 422 nm, followed by 2,15,17-tridecarboxy-xanneobetanin.

image file: d1np00018g-f11.tif Fig. 11 Proposed mechanism of betanin oxidation proceeding through the quinone methide intermediate based on.134,136 In Fig. 12, the schematic formation of dehydrogenated betanin derivatives is presented along with 2,3-dehydro- and 14,15-dehydro-positions marked on particular pigment structures, together with their abbreviations (xan- and neo-, respectively).52

image file: d1np00018g-f12.tif Fig. 12 Possible pathways of betanin oxidation with dehydrogenation positions marked on dehydrogenated derivative structures.52,136 In the case of gomphrenin oxidation by the ABTS cation radical, except for its decarboxylated and dehydrogenated derivatives, the formation of betanidin as well as betanidin derivatives was detected. It is assumed that the rearrangement of dopachromic derivative affects the hydrolysis of the glucosidic bond. This is opposite to betanin, which is not deglucosylated during oxidation in the same reaction conditions. Therefore, it is important to notice that the position of betanidin glucosylation at carbon C-5 or C-6 has a significant influence on the differences in the reactivity of both the 5-O- and 6-O-glucosides.140

It was reported that metal cations, e.g., copper, aluminum, tin, and iron, accelerate the degradation of betanin even at trace amounts. It is worth noting that the release of metals from food packaging materials may also catalyze the unwanted betacyanin degradation.141 The results of high-resolution mass spectrometry experiments (HRMS) and NMR structural studies on key dehydrogenation products generated during the oxidation of betanin, neobetanin, and decarboxylated derivatives by ABTS cation radical as well as by Cu2+ complexation confirmed that Cu2+ catalyzed oxidation of betanin and 2-decarboxy-betanin leads to the formation of neo-derivatives (14,15-dehydrogenated betanins). It has been proven for the first time that betanin oxidation is possible in the dihydropyridine ring and this can be achieved presumably by omitting the stage of quinone methide formation in the dihydroindole system (Fig. 13). The additional results obtained for Cu2+-catalyzed oxidation of 17-decarboxy-betanin and 2,17-bidecarboxy-betanin suggest the possibility of formation of xan-derivatives, similar to the results obtained for oxidation by the ABTS cation radical. In this case, the factor determining the oxidation direction is presumably the absence of the carboxyl moiety at carbon C-17, clearly changing the geometry of the complex formed with Cu2+. In addition, the exclusive effect of 2,3-dehydrogenation in 17-decarboxy-betanin is probably supported by the concurrent occurrence of decarboxylation at carbon C-2.52

image file: d1np00018g-f13.tif Fig. 13 Proposed general oxidation mechanism for betanin and its derivatives, superimposing the effect of Cu2+-catalyzed oxidation with an indication of marked 2,3- and 14,15-dehydrogenation positions based on.52 3.1.3 Conjugation of oxidized betacyanin pigments with sulfhydryl scavengers. A well-developed approach for the direct detection of reactive, short-lived intermediates generated during the oxidation processes is to utilize trapping agents capable of forming stable adducts with the reactive species. The adducts may be detected and characterized using LC-MS/MS and NMR techniques.142 There are many reports on the formation of adducts between nucleophilic thiols and a variety of compounds.143–148 Research on the conjugation of quinones generated during betacyanin oxidation in the presence of thiols seems essential and may broaden the knowledge on betacyanin functions in biological systems. The first studies on the possibility of conjugation of betacyanin reactive quinoids with sulfhydryl scavengers such as glutathione (GSH), cysteine (Cys), N-acetylcysteine (NAC), cysteamine (CSH), and DL-ditiothreitol (DTT) were performed recently (Table 2, Fig. 14).140,149 The formation of glutathionylated quinoids, following betanidin and gomphrenin oxidation, confirmed the presence of quinoid forms in the products of pigment oxidation. The chemical structure of glutathionylated betanidin was confirmed by NMR studies. It was also reported that glutathione reacts with quinones at the C-4 carbon of the betanidin ring. On the contrary, the conjugation of the betanin quinoid intermediate (quinone methide) with glutathione was not observed, presumably because of a steric hindrance at the C-7 carbon of betanin, which presumably confirms that the quinoid form generated during betanin oxidation is a quinone methide.140

image file: d1np00018g-f14.tif Fig. 14 Schematic representation of the conjugation mechanism of betanidin and gomphrenin (A) with sulfhydryl radical scavengers as well as the oxidation of betanin to 2-decarboxy-xanbetanin (B) through the quinone methide intermediate with the following conjugation based on.149 In order to determine the possibility of attaching thiols to the C-7 carbon of the betanin quinoid, additional research was performed using low molecular weight thiols (Cys, CSH, NAC, DTT). Furthermore, since the conjugation of betacyanins with the thiol groups may generate new molecules with the modified chemical and biological properties, the conjugation reactions with quinones derived from betanidin and gomphrenin were also performed (Fig. 14). The chemical structure of N-acetylcysteinyl-gomphrenin, generated with the highest yield, was determined by the NMR method. The dopachrome derivative from gomphrenin oxidation undergoes conjugation at the C-4 carbon atom. In addition, cysteine conjugate with the oxidized betanin derivative was produced for the first time. The results suggest that the formation of quinone methide during the oxidation of betanin and the production of dopachrome derivative during the oxidation of gomphrenin is highly possible.149

The results confirm so far that gomphrenin is able to form conjugates with a higher yield than betanin but the ability to form stable conjugates with dehydrogenated betanin derivatives produced during the oxidation of betanin or its intermediate conjugates may also favor this pigment as a valuable food protection component.149 From the perspective of the food industry, this aspect appears to be relevant as the biological activity of gomphrenin and betanin in combination with the possibility of adduct formation between the thiols and betacyanin quinoids may contribute to the increased quality and durability of food products such as meat.146 From another perspective, adduct research can significantly contribute to the development of detection methods for betacyanin quinoids formed in the complex food matrices as well as to research the bioavailability and distribution of betacyanins in humans. The sulfhydryl part of the molecules may modulate their ability to penetrate the biological membranes as well as their absorption and metabolism. Many attempts have been made in the food chemistry to inhibit the formation of oxidative cross-linking proteins, affecting the quality, water content, and red color of meat products. In this respect, CS-conjugates of betacyanins may play a significant role in blocking the thiol groups in food proteins, contributing to improving the food quality.150–152

Whether betacyanins act as effective antioxidants without adverse pro-oxidative effects depends on how quickly their oxidized derivatives gradually degrade through decarboxylation and dehydrogenation as well as through other transformations, including hydrolysis and the final polymerization of betalamic acid and cyclo-DOPA to inactive forms.134,136 So far, no research on the toxicity and stability of quinones produced from betacyanins has been conducted. The literature data are lacking on the pro-oxidative properties of betalains. In addition, there are questions whether betalains are susceptible to undesired metabolic activation and if the blocking of the sites prone to the formation of reactive forms in molecules is required for betalain application as potential therapeutic agents.

3.1.4 Chlorination of betacyanins. The literature reports suggest that betacyanins may be regarded as potent scavengers of inflammatory factors such as hypochlorous acid (HOCl). In 2007, Allegra et al. reported that betanin and indicaxanthin are effective in the scavenging of hypochlorous acid.77 In addition, both the betalains reduce the myeloperoxidase activity and oxidation, and are therefore regarded as the two key components of the anti-inflammatory processes, leading to the reduction of hypochlorous acid generation.153 In 2016, Wybraniec et al.154 reported that in the reaction between betanin/betanidin/neobetanin and sodium hypochlorite or myeloperoxidase (MPO)/H2O2/Cl− systems, the chlorination of betanin and betanidin took place within the aglycone unit. In addition, the possible reaction with another potent chlorinating agent, Cl2O, which co-exists with HOCl in equilibrium, especially in acidic conditions, was suggested according to a similar mechanism. For neobetanin, no chlorinated products in the reaction mixtures were detected. The fact that the pyridinic ring within the neobetanin structure cannot be chlorinated to form the detectable pigment products indicates that only the unsaturated bond is attacked, preferably at C-18, due to its partial negative charge.154 Monochloro-betanin and monochloro-betanidin were formed with the highest yield at pH 3–5 while at higher Cl− concentrations, the efficiency was dramatically decreased, suggesting that the generated Cl2 is not the chlorinating agent in the presence of sodium hypochlorite. The low activity of Cl2 during betanin and betanidin chlorination compared to HOCl and/or Cl2O was explained by a special position (C-18) of the attack by HOCl and/or Cl2O. In the case of the MPO/H2O2/Cl− system, the highest efficiency of monochloro-betanin/-betanidin generation was observed at pH 5.

In another study,155 additional chlorination experiments were extended to decarboxylated betacyanins (Table 2). The comparison of the chromatographic profiles of the chlorinated decarboxylated betanins and betanidins generated under the activity of hypochlorous acid revealed two different directions of retention changes in relation to the corresponding precursors. The chlorination of betacyanins decarboxylated at C-17 (17-, 2,17-bi-, and 2,15,17-tri-decarboxy derivatives) resulted in higher retention times in comparison to the corresponding substrates. In contrast, the non-decarboxylated betacyanins as well as their 2- and 15-decarboxy-derivatives exhibited lower chromatographic retention after chlorination.155

The identification of the chlorinated betacyanins was completed by a further study on the chlorination mechanism and the position of the electrophilic substitution in betacyanins by high-resolution mass spectrometry and further structural analyses by NMR techniques,156 which confirmed that the chlorination position in betanin and decarboxylated betanins occurs within the dihydropyridinic moiety at the C-18 carbon.156

According to an electrophilic mechanism based upon the leaving group ability from Cl+ in HOCl (–OH−) and in Cl2O (–OCl−), the reaction paths between betanin and HOCl/Cl2O were proposed (Fig. 15).157 The mechanism was supported by the NMR elucidation results as well as by the inactivity of neobetanin toward chlorination.154 Chlorination version A shows the position of Cl+ attack on C-18 carbon within the betanin structure. The failure in the chlorination of betanin with Cl2, which is an active oxidizing agent, confirmed that Cl+ leaving from HOCl or Cl2O can be the chlorinating factor. Also, the hypothesis that H2OCl+ may be regarded as a chlorinating factor carrying Cl+ is intriguing but has not been confirmed for decades.158

image file: d1np00018g-f15.tif Fig. 15 Proposed mechanism of betanin chlorination based on two versions of Cl+ ion attack on C-18 carbon. Chlorination version B presents a cyclic intermediate formed during the electrophilic attack of the whole HOCl or Cl2O with the stabilizing effect of the hydrogen bonding. In the chlorination version B, a cyclic intermediate159 is formed during the electrophilic attack of the whole HOCl or Cl2O molecules as a result of the polarization of Cl–O bond along with the stabilizing effect of hydrogen bonding. The oxidation of C-18 carbon in betanin did not take place because of its negative charge, making the nucleophilic attack of oxygen159 impossible.

Since fluorescent probes have been promising analytical tools for the rapid and specific detection of HOCl/OCl−, the HCSe and HCS probes were tested in the determination of the betalains' anti-hypochlorite activity. The comparison of the in vitro anti-hypochlorite activities of a betalain-rich red beetroot extract (RBE) with its pure betalainic pigments revealed that the extract had the highest anti-hypochlorite activity, far exceeding the activity of all of the betalainic derivatives and selected reference antioxidants.160 In addition, the pilot clinical studies showed that the short-term treatment with RBE improved the function and comfort of knee joints in individuals with knee distress resulting from increased hypochlorous acid formation.76

3.1.5 The acyl migration phenomenon. The acyl migration phenomenon in betacyanins isolated from Mammillaria and Hylocereus fruits was discovered by Wybraniec et al.11,18,36,56 The driving force behind the research on the acyl migration effect was the fact that 4′-O-malonyl betanin isolated from the cacti fruits of Hylocereus species isomerized to 6′-O-malonyl betanin (phyllocactin) (Fig. 16). It was proved that acyl migration is intramolecular; hence, hydrolysis and re-esterification mechanisms are not relevant in that process.161 For that reason, free carboxylic groups in the acyl moieties present in hylocerenin, phyllocactin, and their derivatives are not involved in the rearrangement. The acyl migration mechanism is based on the interaction of the adjacent group with an ortho acid ester being an intermediate. In many cases, the distance between the acyl migrating group and the free hydroxyl is appropriate for creating of a cyclic intermediate.161–163 The formation of the six-membered cyclic intermediate between the glucosidic O-6′ and O-4′ hydroxyls may be responsible for the intramolecular rearrangement in phyllocactin. The significant factor that provides this phenomenon is the alkaline reaction environment; however, the effect is also observed in acidic conditions. image file: d1np00018g-f16.tif Fig. 16 The general chemical structure of 6′-O-acylated betacyanin submitted to acyl migration (A) with an established six-membered cyclic intermediate structure formed during acyl migration between the glucosidic O-6′ and O-4′ oxygens in betacyanins (B); a five-membered cyclic ortho ester formed during the acyl migration between O-4′ and O-3′ (C) as well as the final products of acyl migration (D) and (E) (Bd = the rest of betanidin; R = a fragment of an acyl moiety). A series of new isomers of various 6′-O-acylated betacyanins as well as decarboxylated betacyanins formed by intramolecular pH-dependent acyl migration between adjacent hydroxy groups on polyhydroxy compounds in aqueous solutions was chromatographically characterized.18 The migration rate was markedly accelerated under alkaline conditions at pH 10.5, however, always favoring the 6′-O-position. The phenomenon of acyl migration was less apparent at pH below 7.0. Partial rearrangement may result in the formation of 3′-O- and 4′-O-acylated compounds. In malonylated betacyanins and 17-decarboxy-betacyanins, the 3′-O-acylated forms were presumably the most polar isomers and were eluted first in RP-HPLC, whereas the 4′-O-forms were characterized by retention higher than the 6′-O forms. In contrast, in 2-decarboxy- and 2,17-bidecarboxy-betacyanins, both 3′-O- and 4′-O-acyl-betacyanins were eluted before the 6′-O-acylated forms. The study on the acyl migration effect in 4′-O-malonyl-betanin revealed a strong tendency to reverse acyl migration (4′ → 6′) and also partial rearrangement (4′ → 3′), leading to the monoester regioisomeric distribution in the proportion 87[thin space (1/6-em)]:[thin space (1/6-em)]7[thin space (1/6-em)]:[thin space (1/6-em)]6 [%] in relation to 6′-O-, 4′-O-, and 3′-O-, respectively.

A new malonyl betacyanin, 6′-O-malonyl-amaranthin (celoscristatin), as well as 4′-O-malonyl-amaranthin, formed as a result of the malonyl group migration in celoscristatin, were also identified in Celosia cristata Linn. callus culture.29

3.1.6 NMR elucidation of betacyanin pigments. First NMR structural investigations on betacyanins performed at low pH resulted in the quick degradation of the substances, preventing longer in-depth structural analysis of the betacyanins.53 Nevertheless, key experiments were performed, e.g., confirming the E/Z-stereoisomerism at one of the partial double bonds (C-11,12) in betanidin/isobetanidin.50 As a consequence, only the 13C NMR spectrum of neobetanin was properly registered due to the stability of this dehydrogenated derivative in a highly acidic environment in contrast to other betacyanins. In Fig. 17, an overview of the solvents used for NMR analysis of particular betacyanin pigments is shown. Data acquisition was improved by changing the solvent system for NMR analysis. D2O was found to be the most suitable solvent, which afforded the best long-term stability required for NOESY, HSQC, and HMQC experiments by preventing betacyanin hydrolysis. 1D (1H, 1D TOCSY) and 2D NMR (COSY, TROESY, HSQC, HMQC) measurements for betanin, isobetanin, phyllocactin, and hylocerenin isolated from red-purple pitaya (H. polyrhizus) were performed in D2O.164 For the confirmation of the presence of malonyl moiety exchangeable protons, additional 1H, HSQC, and HMQC experiments for phyllocactin were carried out in a mixture of H2O and D2O (90/10, v/v), slightly acidified with 20 mL of 0.05% aqueous TFA solution (v/v).164 image file: d1np00018g-f17.tif Fig. 17 The summary of the solvents used for NMR spectra registration of particular betacyanins. The key products formed after betanin decomposition were identified and their structures were confirmed by NMR analysis. The structural elucidation of 2-, 17-, and 2,17-decarboxy-betacyanins generated during the decarboxylation of betanin, phyllocactin, and hylocerenin isolated from H. polyrhizus fruits was performed by Wybraniec et al.127 A variety of coupled spin systems of all the analyzed compounds were successfully distinguished and assigned by 1H NMR, 1D TOCSY, gCOSY, and NOESY spectra in D2O. Due to gHSQC correlations, the 13C chemical shifts for all the carbons directly bound to the protons were unambiguously assigned, while the gHMBC (the 1H–13C long-range) correlations enabled the establishment of the chemical shifts of the quaternary carbons. In addition, the first 1H NMR spectra of 2-decarboxy-hylocerenin together with all the studied 17-decarboxy- and 2,17-bidecarboxy-betacyanins were received. Furthermore, the 13C NMR spectra of the decarboxylated betacyanins were obtained for the first time.127

The NMR spectra of amaranthin and iresinin I were recorded in trifluoroacetic acid.61 The structures of the two other acylated betacyanins and lampranthin II from the petals of Lampranthus peersii and L. sociorum as well as celosianin (previously named as celosianin II) from the cell suspension cultures of Chenopodium rubrum were elucidated as 6′-O-E-feruloyl-betanin and 2′′-O-E-feruloyl-β-(1′′,2′)-glucuronosyl-betanin, respectively, by 1H NMR. All 1D (normal and NOE difference) and 2D spectra (COSY) were registered in acidic DMSO-d6 containing traces of DCl.58 A low field shift of the protons H-6′A and H-6′B of the glucosylic moiety in lampranthin II caused by acylation indicated an attachment of the feruloyl moiety at the C-6′ carbon. For celosianin II, the NOE difference spectra indicated that the β-glucuronosyl moiety was bound to C-2′ of the β-glucosyl moiety. The presence of the feruloyl moiety attached at C-2′′ of β-glucuronosyl was evident from the low field shift of H-2′′.58

In addition to betanin and phyllocactin in H. polyrhizus fruits, another characteristic pigment, hylocerenin [6′-O-(3′′-hydroxy-3′′-methyl-glutaryl)-betanin], was also characterized by 1D and 2D (COSY) NMR techniques in deuterated methanol (CD3OD) containing traces of deuterium chloride (DCl).56 Other unknown pigments, 2′-O-β-apiofuranosyl-betanin and 2′-O-β-apiofuranosyl-phyllocactin, were also elucidated by 1H and 13C NMR techniques in non-acidified D2O.11 The structure of a new malonyl derivative, celoscristatin (6′-O-malonyl-amaranthin), isolated from C. cristata callus culture was confirmed by NMR analysis in D2O.29

In order to determine the oxidation mechanism of betanin, structures of tentatively identified key dehydrogenation products of betanin, decarboxylated betanin, and neobetanin oxidation by the ABTS cation radical were elucidated by NMR.52 The 1H and 2D (COSY, TOCSY, HSQC, HMBC, and NOESY) measurements were performed in DMSO-d6 for all the studied compounds except for 2-decarboxy-neobetanin, which was analyzed in CD3OD acidified with 0.01% deuterated TFA. The structures of five neo- and xanneo-derivatives, namely, neobetanin, 2-decarboxy-neobetanin, 2-decarboxy-xanneobetanin, 2,17-bidecarboxy-xanneobetanin, and 2,15,17-tridecarboxy-xanneobetanin, were confirmed.52

The structures of gomphrenin as well as its acylated derivatives, globosin and basellin, (gomphrenin I, II, and III, respectively) were elucidated by NMR spectroscopy by Heuer et al.24 The 1H and 2D COSY NMR spectra were recorded in CD3OD containing traces of DCl. The presence of acyl (4-coumaroyl- and feruloyl-) moieties at the C-6′ carbon in globosin and basellin, respectively, was indicated by a low field shift of the corresponding protons H-6′A and H-6′B. Non-typical 1H chemical shift differences between gomphrenin I and globosin and basellin suggested intramolecular stacking occurring in the latter two compounds.24 In another attempt, gomphrenin was identified by means of 1H, selective NOESY, and TOCSY as well as 2D NMR (COSY, NOESY, HSQC, and HMBC) techniques in D2O.69 By NOESY-correlation spectral analysis, it was demonstrated that the glucopyranosyl group is linked to the phenolic group at the C-6 carbon of gomphrenin, which differentiated it from betanin.

The structures of glutathionylated conjugate of betanidin140 and N-acetylcysteinylated gomphrenin149 were established by NMR analysis, confirming the conjugation position at the C-4 carbon, thus indicating the presence of a dopachromic intermediate during gomphrenin oxidation. All 1H and 2D NMR (COSY, HSQC, HMBC, TOCSY, and NOESY) analyses were accomplished in non-acidified D2O. The attachment position of the glutathionyl moiety was primarily indicated by the strong long-range correlation of the H-12a/b′ protons to quaternary C-4 and C-9 carbons as well as a weak correlation to C-8. The lack of the H-4 signal in the 1H spectrum unambiguously confirmed this position.140,149 In the case of N-acetylcysteinylated gomphrenin, the attachment position of the N-acetyl-cysteinyl moiety was initially suggested by a strong, long-range correlation of H-6a/b′′ protons to quaternary carbon C-4. In addition, the lack of the H-4 signal in the 1H spectrum definitely confirmed this position. Furthermore, the CS-conjugation position in gomphrenin was supported by the downfield chemical shift of the H-6a/b′′ proton signal compared to the signal obtained for free N-acetyl-cysteine.149

In order to prove the position of chlorination in betanin and its decarboxylated derivatives, structural studies were also performed.156 The structure elucidation of 18-chloro-betanin, 18-chloro-17-decarboxy-betanin, and 18-chloro-2,17-bidecarboxy-betanin confirmed that the chlorination position in betanin occurs within the dihydropyridine moiety at carbon C-18. The results of 1H NMR, COSY, and TOCSY analyses obtained for 18-chloro-betanin in non-acidified D2O enabled to distinguish and characterize several diagnostic, conjugated spin systems characteristic for betanin (H-2, H-3ab; H-11, H-12; H-14ab, H-15) in D2O. The dihydroindolic system was indicated by the HSQC correlations of H-2, H-3ab, H-4, and H-7 with their respective carbons. In the dihydropyridine system, the correlations of H-14ab and H-15 with their respective carbons in the HSQC spectra were visible.156

The structural studies of the newly semi-synthesized pseudo-natural pigments based on betanin hydrolysis were also reported. The structures of various compounds semi-synthesized by coupling betalamic acid with N-methyl anilines, N-aryl anilines, and blue solid named BeetBlue as well as 7-amino-4-methylcoumarin- and 7-amino-4-trifluoromethylcoumarin-betacyanins (cBeet120 and cBeet151) were accomplished by NMR analysis in D2O.165–167

4 Chemistry of betacyanins and their semi-synthetic derivatives based on betanin hydrolysis 4.1 Hydrolysis of betanin Betanin is susceptible to acid- and base-catalyzed hydrolysis, leading to the formation of colorless cyclo-DOPA-5-O-β-D-glucoside and fairly stable bright yellow betalamic acid (Fig. 18). Recently, new light was shed on betanin hydrolysis mechanism.169 The impact of temperature and pH on the rate of betanin hydrolysis was examined. The mechanism of betanin decomposition was studied in the phosphate solution at pH ranging from 2 to 11 and temperature of 60–85 °C. It was postulated that the fully protonated betanin form is reactive toward the nucleophilic attack of water and the intramolecular hydrogen bond between the carboxylic group at C-2 carbon and N-1 nitrogen stabilizes the transition state, leading to the hydrated betanin. The N-1 nitrogen atom was expected to be protonated in the acidic media and to form a leaving group. The protonation of the N-16 nitrogen atom enhances the electrophilicity of C-11, C-13, and C-17 carbons and catalyzes betanin hydrolysis, finally contributing to the opening of the 2,6-dicarboxy-1,2,3,4-tetrahydropyridine ring of betalamic acid. It was indicated that the hydrogen phosphate ion may act as a general base at pH 8.2, even at a low buffer concentration. The formation of cyclo-DOPA and 2,6-dicarboxy-4-methylpyridine as the products of betanin degradation in an alkaline environment at 130 °C identified by IR spectroscopy was reported in the pioneering work of Wyler and Dreiding on betanin purification by crystallization.47,170 In contrast to that study, 2,6-dicarboxy-4-methylpyridine was not detected.169 However, the presence of cyclo-DOPA, betalamic acid, and decarboxylation/oxidation products was observed. image file: d1np00018g-f18.tif Fig. 18 Hydrolysis of betanin leading to the formation of betalamic acid and cyclo-DOPA-5-O-β-D-glucoside. Based on theoretical calculations, the double protonation of the nitrogen atom within the tetrahydropyridine ring cannot be excluded from what was observed for the amino dicarboxylic acids of simpler structures.169

Next to hydrolysis, betacyanins are also sensitive to water-catalyzed isomerization. A study on the hydrolytic stability of betanin Bn, indicaxanthin BtP, and an artificial betalainic coumarin BtC soluble hydrogen bond donating 2,2,2-trifluoroethanol (TFE) was conducted.171 The hydrolytic stability in water was as follows: BtP > Bn > BtC. Improved hydrolytic stability of the abovementioned betalains in hydroalcoholic solutions was noticed with an increase in the TFE co-solvent. The hydrolysis rate of betalainic coumarin in water was 700-fold greater than in TFE, whereas the use of TFE as a co-solvent reduced the hydrolysis of betanin and indicaxanthin by 20 and 100-times, respectively. The proportion of water and TFE in the co-solvent mixture determined the hydrogen-bond donating capacity, polarity, and ionization power. However, the most important factor of the enhanced hydrolytic stability of the betacyanins is probably due to the low nucleophilicity of TFE. In addition, the fluorescence quantum yields of betaxanthins were also increased with the presence of TFE.171

4.2 One step semi-synthesis of betalains from betalamic acid-derivatized support So far, all the proposed methods of the de novo synthesis of betalains achieve very low efficiency; therefore, the best way to obtain individual betalain derivatives is to isolate them from the biological material and purify. However, this makes the whole process highly time-consuming due to the plant matrix that is rich in various compounds, especially polysaccharides. The process of betalain formation was simplified using a novel betalamic acid-derivatized support (Fig. 19).172 Betalamic acid was produced during betanin hydrolysis from B. vulgaris extract in the presence of cross-linked polystyrene resin at room temperature and nitrogen atmosphere. After the release of betalamic acid and neutralization with acetic acid, the reaction of imine formation between the aldehyde group of betalamic acid and the free primary amine groups present in the matrix surface was performed, resulting in the immobilization of betalamic acid in the resin. The derivatization of the resin with betalamic acid was indicated by the resin color change from pale to intense yellow. After washing and drying at room temperature, the novel solid support was generated and characterized by SEM. The material exhibited the spectroscopic properties of a pseudobetaxanthin. Then, the resin from the betalamic acid-derivatized support was tested toward the production of betalains. As model amines, individual dopamine, tyramine, indoline, and pyrrolidine were added to the support turning the color of the solutions from colorless into yellow in the case of dopamine, tyramine, and pyrrolidine, as well as into purple in the case of indoline. Then, a Schiff's condensation between the amine and betalamic acid anchored in the support provided the dopamine-, tyramine-, pyrrolidine-, and indoline-betaxanthins.172 image file: d1np00018g-f19.tif Fig. 19 Betalamic acid-derivatized support and the surface reaction leading to pigment isolation, based on dopamine-derived betaxanthin: (A) starting material containing primary amine groups; (B) betalamic acid-derivatized support; (C) amine attack to betalamic acid; (D) synthesis and concomitant release of miraxanthin V.172 4.3 Semi-synthetic betalain pigments with extended conjugated systems 4.3.1 Semi-synthesis of blue pigments from betanin. Naturally-occurring blue pigments are rare, especially among plants. A metal-free photostable blue pigment was designed by extending the π-system of betalains (Table 2).166 The dye was semi-synthesized from betalamic acid, which may be obtained from the hydrolysis of red beetroot juice or by the enzymatic oxidative cleavage of S-DOPA. The 1,11-diazaundecamethinium chromophore of the dye is formed by the irreversible dehydrative C–C coupling of betalamic acid with the carbon nucleophile 2,4-dimethylpyrrole in acidified ethyl acetate (Fig. 20). The reaction lasted less than 30 min and it was performed at room temperature under air condition. The 1,11-diazaundecamethinium chromophore induces a redshift of the absorption and fluorescence spectra in water in relation to standard betanin and indicaxanthin. The product was purified by flash gel permeation chromatography with water used as eluent. This dye exhibits high solubility in polar solvents, e.g., water, and does not produce singlet oxygen upon photoexcitation.166 image file: d1np00018g-f20.tif Fig. 20 Semi-synthesis of a blue dye from betanin derived from beetroot juice.166 4.3.2 Semi-synthesis of a pseudo-natural betalain-nitrone OxiBeet pigment. A prototypical betalain-nitrone pigment (OxiBeet) based on the N-oxide 1,7-diazaheptamethinium scaffold was semi-synthesized for the first time by Capistrano Pinheiro et al. (Table 2).173 Betalamic acid was produced by the hydrolysis of the betalains present in red beetroot juice and coupled with N-phenylhydroxylamine in acidified water, giving rise to OxiBeet pigment (Fig. 21). The resulting product was purified and isolated with 50% yield, which is twice as high as the values reported for other betalains. image file: d1np00018g-f21.tif Fig. 21 Semi-synthesis of OxiBeet pigment (3) by the acid-catalyzed coupling of betalamic acid (1) and N-phenylhydroxylamine 2 in water. This bio-based molecule exhibits low reduction potential and even higher radical scavenging activity than typical antioxidants such as ascorbic acid and gallic acid. Furthermore, it is non-cytotoxic toward human hepatic cell line HepaRG up to 1 mM concentrations. This pseudo-natural product is resistant to hydrolysis under neutral and slightly alkaline conditions and it may also be converted into a persistent N-oxide 1,7-diazaheptamethinium radical cation in an aqueous solutions via autoxidation. These findings open up new perspectives for utilizing betalain pigments and betalain derivatives as therapeutics against various human diseases.

4.3.3 Semi-synthesis of N-methyl phenyl-betaxanthin and N-aryl phenyl-betaxanthin pigments. The semi-synthesis of N-methyl phenyl-betaxanthin (common name: mepBeets) and N-aryl phenyl-betaxanthin (dipBeets) pigments (Table 2) was described by Pioli et al. and the influence of the structure on the betalain derivatives' hydrolytic stability and electronic properties were compared.165 Eight compounds were formed by the derivatization of betalamic acid and N-methyl-anilines as well as N-aryl-anilines in ethyl acetate in the presence of p-toluenesulfonic acid used as a catalyst (Fig. 22). The stabilization of the positive charge density at the nitrogen atom N-9 by the N-methyl group reduces the rate of hydrolysis by decreasing charge delocalization through the 1,7-diazaheptamethinium system as compared to the non-methylated phenyl-betaxanthin. On the contrary, the N-aryl moiety increases charge delocalization while improving the hydrolytic stability. The electron-withdrawing substituents within the aryl moiety increase the fluorescence quantum yields of semi-synthesized betaxanthins, accelerate hydrolysis, and lower the anodic potential compared to the corresponding unsubstituted betalains. On the other hand, the presence of electron-donating substituents improves their hydrolytic stability. The fluorescence of N-aryl phenyl-betaxanthins is strongly influenced by the polarity and viscosity of the medium which enables the design of the “turn-on” fluorescent (bio)sensors.165 image file: d1np00018g-f22.tif Fig. 22 Semi-synthesis of the mepBeets and the dipBeets via the acid-catalyzed coupling of betalamic acid (1) with N-substituted anilines (2) in ethyl acetate.165 4.3.4 Semi-synthesis of artificial coumarinic betalains. Betalains may be modified to produce water-soluble two-photon fluorophores.167 Coumarinic betalains cBeet120 and cBeet151 (Table 2) were obtained in the reaction between betalamic acid and aminocoumarins in acidified ethyl acetate (Fig. 23). Betalamic acid underwent Schiff condensation (aldimine formation) with 7-amino-4-methylcoumarin c120 and 7-amino-4-trifluoromethylcoumarin c151 in the presence of p-toluenesulfonic acid used as a catalyst. The coupling of the betalamic acid chromophore to the fluorescent hydrophobic chromophore via the 1,7-diazeheptamethine π-bridge results in a D–π–A molecular arrangement. Coumarinic betalain containing a trifluoromethyl electron-withdrawing substituent within the coumarin moiety is more fluorescent than the one with a methyl group but it has a lower two-photon absorption cross-section, which is attributed to the destabilization of the charge transfer character of the excited state affecting the transition dipole moment.167 image file: d1np00018g-f23.tif Fig. 23 Semi-synthesis of artificial coumarinic betalain pigments with an extended conjugated system.167 In another study, an artificial coumarinic betalain (BtC) semi-synthesized via the aldimine coupling of 7-amino-4-methylcoumarin to betalamic acid was used for the fabrication of the fluorescent probe for the live-cell imaging of erythrocytes infected with Plasmodium falciparum responsible for malaria disease in humans.168 In order to test the capacity of BtC for labeling living Plasmodium-infected red blood cells, erythrocytes with parasites were incubated with BtC and examined by fluorescence microscopy. BtC was accumulated within the infected cells selectively and fluorescence imaging microscopy has shown that only the parasite was stained. On the contrary, no stain was observed in the infected erythrocytes incubated with an indicaxanthin (control probe) and uninfected cells.168

5 Conclusions During the last two decades, the research on betalains, more specifically on betacyanins, has experienced significant acceleration due to their health-protective properties as well as applications in the food industry. Before 2000, there were no reports on any pro-health activities of betacyanins; from 2020 onwards, this is the main direction of projects and research on betacyanins. Furthermore, studies on the oxidation mechanism of betacyanins are highly relevant because pigments with different chemical structures seem to have different influence on their oxidation pathways. Considering the fairly simple semi-synthetic methods for additional betacyanin derivatives summarized in this review as well as the first promising results of various studies, the perspectives for further investigations on the bioactivity of betacyanins are inexhaustible. For the time being, the main obstacle that limits the research is the lack of highly efficient and inexpensive methods of betacyanin isolation and purification as well as methods of de novo synthesis. The constantly growing number of potential applications of betalains as natural colorants of food, fabrics, and dietary supplements but also their utilization in sensors, photoprotectors, and solar cells set promising directions of the investigations on these still not fully-explored plant pigments in the near future. In spite of the most recognizable betanin-based betacyanins present in a variety of betalainic plant sources, gomphrenin-like pigments also represent a promising group of potentially more stable and more active compounds at once. There are still many unexplored plants with presumably new interesting betacyanin profiles. The chemical structures of only 31 betalain pigments isolated from the plant sources were definitively identified by the NMR method, which is relatively small in comparison to the other groups of plant pigments. Furthermore, a huge group of over 187 betacyanins (including pigments from their richest source, B. glabra) detected by LC-MS techniques still awaits the final confirmation of their structures. Particular attention should also be paid to the chemical modifications of betacyanins that result in the generation of an increasing number of new derivatives with completely unknown bioactivities. The aspects discussed in this review show that the field of betalain chemistry is a goldmine and ideas for further research are still limitless. 6 Conflicts of interest The authors declare no competing financial interest. 7 Acknowledgements This research was financed by Polish National Science Centre for the years 2020–2023 (Project No. UMO-2019/33/N/NZ9/01590) as well as for the years 2018–2021 (Project No. UMO-2017/27/B/NZ9/02831). The authors are grateful to Dr Willibald Schliemann for his invaluable suggestions and comments.

Raw text of https://pubs.rsc.org/en/content/articlehtml/2021/np/d1np00018g

I am going to paste the plain text of a scientific publication. I would like you to detect all molecules names you can find in this text and report them as a list.

Betacyanins Betaxanthins Betalamic acid Betanidin Cyclo-DOPA Betanin Gomphrenin Amaranthin Bougainvillea-r-I-type (renamed as Melocactin-type) Oleracin-type Apiocactin-type Bougainvillein-v-type (proposed as Glabranin-type) Hylocerenin Phyllocactin Lampranthin I Lampranthin II Rivinianin Celosianin I (Argentianina) Celosianin II (Celosianina) Celoscristatin Iresinin I Mammillarinin Amaranthin Indicaxanthin 2-Decarboxy-betanin 14,15-Dehydro-betanin (Neobetanin) 6′-O-Sulfate-betanin (Prebetanin) 2-Decarboxy-phyllocactin 2-Decarboxy-betanidin 2′-O-β-Apiosyl-betanin (Apiocactin) 5′′-O-E-Sinapoyl-apiocactin 4′-O-Malonyl-betanin 5′′-O-E-Feruloyl-apiocactin 6′-O-Malonyl-betanin (Phyllocactin) 2′-O-β-Apiosyl-phyllocactin 2′-O-β-(5′′-O-E-Feruloyl)-apiosyl-phyllocactin 6′-O-(3′′-Hydroxy-3′′-methylglutaryl)-betanin (Hylocerenin) Betanidin 5-O-(6′-O-E-4-coumaroyl-β-glucoside) (Lampranthin I) Betanidin 5-O-β-(6′-O-E-feruloyl)-glucoside (Lampranthin II) 3′-O-Sulfate-betanin (Rivinianin) Betanidin 5-O-β-sophoroside (Bougainvillein-r-I; Melocactin) (Caffeoyl and/or coumaroyl)-bougainvillein-r I (Bougainvillein-r-II, III, IV, V) Betanidin 5-O-(2′-O-β-glucuronosyl)-glucoside (Amaranthin) 2′′-O-E-4-Coumaroyl-amaranthin (Celosianin I; Argentianina) 2′′-O-E-Feruloyl-amaranthin (Celosianin II; Celosianina) 6′-O-Malonyl-amaranthin (Celoscristatin) 4′-O-Malonyl-amaranthin 6′-O-(3′′-Hydroxy-3′′-methylglutaryl)-amaranthin (Iresinin I) 4′-O-Malonyl-bougainvillein-r I 6′-O-Malonyl-bougainvillein-r I (Mammillarinin) 2-Decarboxy-mammillarinin 17-Decarboxy-mammillarinin 17-Decarboxy-bougainvillein-r I Feruloyl-bougainvillein-r I (Dehydrated phyllocactin) Betanidin 6-O-β-D-sophoroside (Bougainvillein-v; Glabranina) 6′′-O-Rhamnosyl-glabranin 6′-O-E-Caffeoyl-glabranin (Cafglabranina) 6′-O-E-4-Coumaroyl-glabranin (Coumglabranina) 6′′-O-E-4-Coumaroyl-glabranin 6′,6′′-Di-O-E-4-coumaroyl-glabranin (Bicoumglabranina) 2′′-O-[(6′′-O-E-4-Coumaroyl)]-glucosyl-cafglabranin 2′′-O-Glucosyl-bicoumglabranin 2′′-O-[(6′′-O-E-4-Coumaroyl)]-sophorosyl-cafglabranin Feruloyl-dihexosyl-betanidin Sinapoyl-dihexosyl-betanidin Citryl-(caffeoyl or 4-coumaroyl)-amaranthin (Suaedin) 2′′-O-E-Sinapoyl-amaranthin (Lindenina) Betanidin 6-O-β-glucoside (Gomphrenin I; Gomphrenina) 6′-O-E-4-Coumaroyl-gomphrenin I (Gomphrenin II; Globosina) 6′-O-E-Feruloyl-gomphrenin I (Gomphrenin III; Basellina) 6′-O-E-Sinapoyl-gomphrenin I (Gomphrenin IV; Gandolina) E-Isomer of gomphrenin II E-Isomer of gomphrenin III Betanidin 5-O-β-(E-feruloyl)-cellobioside (Oleracin I)

import pandas as pd

Creating a DataFrame from the list

data = [ ["Betanin", "-", "Beta vulgaris (beetroot, red beet)", "Fruits"], ["Betanidin", "-", "Beta vulgaris", "Fruits"], ["Gomphrenin", "-", "Basella alba L.", "Fruits"], ["Gomphrenin", "-", "Basella alba var. ‘Rubra’ L.", "Leaves"], ["Amaranthin", "-", "Amaranthaceae family plants", "-"], ["Melocactin", "Previously 'Bougainvillein-r-I'", "Bougainvillea glabra", "Bracts"], ["Glabranin", "Previously 'Bougainvillein-v'", "Bougainvillea glabra", "-"], ["Hylocerenin", "-", "Hylocereus polyrhizus", "Fruits"], ["Phyllocactin", "-", "Schlumbergera x buckleyi", "-"], ["Phyllocactin", "-", "Pereskia hybridus", "-"], ["Lampranthin I", "-", "Lampranthus sp.", "-"], ["Lampranthin II", "-", "Lampranthus sp.", "-"], ["Lampranthin II", "-", "Gomphrena globosa", "-"], ["Lampranthin II", "-", "L. sociorum", "-"], ["Rivinianin", "-", "Rivina humilis", "-"], ["Amaranthin", "-", "Amaranthus tricolor", "-"], ["Amaranthin", "-", "Amaranthus sp.", "-"], ["Amaranthin", "-", "Celosia cristata", "-"], ["Celosianin I", "Argentianina", "Celosia cristata", "-"], ["Celosianin II", "Celosianina", "Celosia cristata", "-"], ["Celoscristatin", "-", "Celosia cristata", "-"], ["Iresinin I", "-", "Iresine herbstii", "-"], ["Mammillarinin", "-", "Mammillaria spp.", "-"], ["Suaedin", "-", "Suaeda fruticosa", "-"], ["Lindenina", "-", "Gomphrena globosa", "-"], ["Lindenina", "-", "Iresine lindenii", "-"], ["Gomphrenin I", "Gomphrenina", "Gomphrena globosa", "-"], ["Gomphrenin I", "Gomphrenina", "Basella alba", "-"], ["Gomphrenin II", "Globosina", "Gomphrena globosa", "-"], ["Gomphrenin III", "Basellina", "Gomphrena globosa", "-"], ["Gomphrenin IV", "Gandolina", "Gomphrena globosa", "-"], ["Oleracin I", "-", "Portulaca oleracea", "-"] ]

df = pd.DataFrame(data, columns=["Molecule Name", "Molecule Name Alt", "Biological Source", "Organ"])

Convert DataFrame to CSV

csv_file = "/mnt/data/Betacyanins_Biological_Sources.csv" df.to_csv(csv_file, index=False)

csv_file

https://chat.openai.com/share/80771cb4-b018-48e4-8573-a9643c0b084d

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