Next Article in Journal
Phytochemical Characterization of Dillenia indica L. Bark by Paper Spray Ionization-Mass Spectrometry and Evaluation of Its Antioxidant Potential Against t-BHP-Induced Oxidative Stress in RAW 264.7 Cells
Next Article in Special Issue
Priming with γ-Aminobutyric Acid against Botrytis cinerea Reshuffles Metabolism and Reactive Oxygen Species: Dissecting Signalling and Metabolism
Previous Article in Journal
BMS-986020, a Specific LPA1 Antagonist, Provides Neuroprotection against Ischemic Stroke in Mice
Previous Article in Special Issue
ROS and NO Regulation by Melatonin Under Abiotic Stress in Plants
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Antioxidants
Volume 9
Issue 11
10.3390/antiox9111098
antioxidants-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Are Flavonoids Effective Antioxidants in Plants? Twenty Years of Our Investigation

by
Giovanni Agati
1,
Cecilia Brunetti
2,
Alessio Fini
3,
Antonella Gori
4,
Lucia Guidi
5,
Marco Landi
5,
Federico Sebastiani
2 and
Massimiliano Tattini
2,*
1
Institute of Applied Physics ‘Carrara’, National Research Council of Italy (CNR), Via Madonna del Piano 10, Sesto F.no, I-50019 Florence, Italy
2
Institute for Sustainable Plant Protection, National Research Council of Italy (CNR), Via Madonna del Piano 10, I-50019, Sesto F.no, Florence, Italy
3
Department of Agriculural and Environmental Sciences - Production, Landscape, Agroenergy, University of Milan, Via Celoria 2, I-20133 Milan, Italy
4
Department of Agriculture, Food, Environment and Forestry, University of Florence, Viale delle Idee 30, Sesto F.no, I-50019 Florence, Italy
5
Department of Agriculture, Food and Environment, University of Pisa, Via del Borghetto 80, I-56124 Pisa, Italy
*
Author to whom correspondence should be addressed.
Antioxidants 2020, 9(11), 1098; https://doi.org/10.3390/antiox9111098
Submission received: 12 October 2020 / Revised: 5 November 2020 / Accepted: 6 November 2020 / Published: 9 November 2020
(This article belongs to the Special Issue Antioxidant Defenses in Plants)
Browse Figures
Versions Notes

Abstract

Whether flavonoids play significant antioxidant roles in plants challenged by photooxidative stress of different origin has been largely debated over the last few decades. A critical review of the pertinent literature and our experimentation as well, based on a free-of-scale approach, support an important antioxidant function served by flavonoids in plants exposed to a wide range of environmental stressors, the significance of which increases with the severity of stress. On the other side, some questions need conclusive answers when the putative antioxidant functions of plant flavonoids are examined at the level of both the whole-cell and cellular organelles. This partly depends upon a conclusive, robust, and unbiased definition of “a plant antioxidant”, which is still missing, and the need of considering the subcellular re-organization that occurs in plant cells in response to severe stress conditions. This likely makes our deterministic-based approach unsuitable to unveil the relevance of flavonoids as antioxidants in extremely complex biological systems, such as a plant cell exposed to an ever-changing stressful environment. This still poses open questions about how to measure the occurred antioxidant action of flavonoids. Our reasoning also evidences the need of contemporarily evaluating the changes in key primary and secondary components of the antioxidant defense network imposed by stress events of increasing severity to properly estimate the relevance of the antioxidant functions of flavonoids in an in planta situation. In turn, this calls for an in-depth analysis of the sub-cellular distribution of primary and secondary antioxidants to solve this still intricate matter.

1. Introduction

It has been known for decades that UV, particularly UV-B radiation, triggers the biosynthesis of flavonoids (for recent review articles see [1,2,3]), the vast class of phenylpropanoids comprising more than 8000 structures with a huge array of decorations [3]. The flavonoid metabolic pathway was raised during the water-to-land transition of plants, when plants were challenged against an abrupt increase in UV-B radiation [3,4]. This led to the hypothesis that flavonoids have an almost exclusive UV-B screening role in photoprotection [5,6]. It was suggested that flavonoids have the peculiar capacity to absorb strongly over the UV-B portion of the solar spectrum, while offering negligible shielding to visible light radiation, thereby protecting DNA [7,8] and PSII [9,10] from damage. Nonetheless, the very same UV-B absorbing features belong to the vast majority of phenylpropanoids; a wide range of polyphenols display even greater capacity to shield sensitive leaf targets from high UV-B irradiance compared to flavonoids [11]. It has been inferred, therefore, that unveiling how and how much flavonoids serve photoprotective functions in the network of UV-screening phenylpropanoids synthesized by current-day land plants needs deeper analysis [12].
The first time we encountered flavonoids was when examining leaves of Phillyrea latifolia adapted to deep shade (5% of full solar irradiance) or full sunlight [13]. We observed that glandular trichomes, distributed on both the adaxial and the abaxial leaf surface in fully developed leaves, exclusively synthesized hydroxycinnamic acid (HCA) or flavonoid derivatives in the shade or in full sunlight, respectively. The almost exclusive distribution of flavonoids in glandular trichomes of leaves growing in full sunlight was confirmed later using multispectral fluorescence microimaging (Figure 1) [14]. These observations led to the hypothesis that flavonoids have functional roles beyond the absorption of UV, particularly of UV-B radiation in photoprotection. In fact, flavonoids (particularly the dihydroxy B-ring-substituted structure detected in our studies) are less effective than HCA in absorbing UV-B wavelengths [15,16]. In a series of successive experiments, we also observed a steep increase in the ratio of dihydroxy to monohydroxy B-ring-substituted flavonoids in response to high light irradiance, in the presence or in the absence of UV radiation [17,18,19,20]. Based on the relative light screening and antioxidant properties of mono- and dihydroxy B-ring-substituted flavonoids (reviewed in [16]), we hypothesized that flavonoids might serve major antioxidant functions in photoprotection. We conducted studies, at very different scale levels, to support this hypothesis over the last two decades. Here, we discuss the significance of flavonoids as antioxidants in plants and their relative contribution to the integrated and modular network of antioxidant defenses plants activate when exposed to photooxidative stress of increasing severity. The matter is still under hot debate, in part because an unequivocal definition of a plant antioxidant is still missing [21,22,23].

2. Major Antioxidant Functions of Flavonoids in Photoprotection: Free-of-Scale Evidence

When plants moved from water to colonize land they were challenged by a wide range of “novel” environmental pressures, including, but not limited to, an abrupt increase in UV-B radiation [24,25,26,27,28]. It has been believed for decades that the rise of flavonoid metabolism aimed at equipping plants with a more effective UV-B screening shield as compared to algae. However, this does not seem to be exactly the case (for critical reviews, see [24,29,30,31,32]). First, a range of algal species synthesizes a variety of mycosporine-like amino acids, which are more effective than flavonoids in absorbing UV-B wavelengths [16]. Second, flavonoids have minimum molar extinction coefficients (ε) over the 290-315, UV-B portion of the solar spectrum. Third, in plant organs most exposed to UV-B radiation, the synthesis of hydroxycinnamic acid (HCA) derivative declines in favor of flavonoid biosynthesis [12,13], even though HCAs absorb UV-B more efficiently than flavonoids [16]. Fourth, the biosynthesis of quercetin (or dihydroxy B-ring-substituted flavonoids) is strongly favored with respect to kaempferol (or monohydroxy B-ring-substituted flavonoids) biosynthesis following exposure to UV-B radiation, though quercetin and kaempferol have similar UV-B screening efficiency. Finally, a series of relatively recent experiments have shown UV-B radiation is not a prerequisite [19,33,34], and blue light is more effective than UV-B light in stimulating flavonoid biosynthesis [35]. There is increasing evidence suggesting that during the water-to-land transition, water stress and excessive light including, but not limited to UV-B radiation, drove most molecular innovations enabling early plants to successfully colonize land [36,37,38,39,40].
Caldwell and colleagues [41] questioned the functional significance of flavonoids as mere UV-B absorbing pigments in UV-B exposed plants, approx. 40 years ago: they indeed noted that UV-B radiation promotes the biosynthesis of metabolites maximally absorbing over the UV-A portion of the solar spectrum. There are very few plant species synthesize flavonoids acylated with a range of HCA moieties, which may offer an effective shield against the penetration of the entire spectrum of UV wavelengths in the leaf (Figure 2).
We note that the vast majority of early studies examining the photoprotective functions of flavonoids exposed plants to unrealistic UV-B doses for very short time periods (e.g., see [43,44,45,46,47,48]). Consequently, flavonoids exclusively accumulated in leaf epidermal cells, further reinforcing the idea of their exclusive roles as UV-B screening pigments. We also observe that the concentration of UV-B absorbing compounds, as estimated through absorption at 300-330 nm of tissue extracts, was in some instances assumed to represent the flavonoid concentration [49,50,51]. This is actually wrong, as different phenylpropanoid classes effectively absorb over this portion of the solar spectrum. In other instances, identification of flavonoids was erroneously assessed based on the absorption spectra of isolated compounds [44]. Finally, while studies examining the UV-B responses of mutants lacking the biosynthesis of a range of flavonoids conclusively showed their essential roles against UV-B damage [44,51,52,53], they did not offer a conclusive explanation about how flavonoids afford photo-protection. It is logically hard to perform experiments with the aim of unveiling the molecular events that trigger the flavonoid biosynthesis and, at the same time of assessing their functional roles in plant-environment interactions: it is simply a matter of scale (scaling-up). Results arising from growth chamber experiments, in which model plant species are exposed to unrealistic light irradiance, should not be considered as informative to describe the complexity of plants growing in their natural habitats. High UV and visible light irradiance are just two of the range of concomitant environmental stressors plants face in the field [17,18]. The picture is complicated further by the observation that flavonoids occur in different plant organs, tissues and subcellular compartments in plants growing in full sun-exposed leaves (Figure 3; for a review see [31]). Exploring the functional roles of flavonoids in photoprotection is an ecophysiological, not only a “molecular biology” challenge. This, when coupled with our constitutive inability to leave well-traced paths, has made complex the study of the primary roles played by flavonoids in photoprotection.
Helen Stafford [29] hypothesized that a nascent and, hence, inefficient metabolism unlikely produced flavonoid at concentrations sufficient to provide an effective UV-B screening, thereby suggesting that flavonoids have alternative roles (i.e., developmental regulators) in response to UV-B stress. A few years later, Landry et al. [54] and Sheahan [15] first hypothesized for flavonoids an antioxidant, perhaps primary, function in UV-B treated leaves. As reported above, this hypothesis has been corroborated later by the steep increase in the ratio of dihydroxy to monohydroxy B-ring-substituted flavonoid glycosides in response to UV-B in a range of species [17,18,48,55,56,57,58]. The capacity to scavenge reactive oxygen species (ROS) of glycosylated flavonoids is mostly conferred by the catechol group in 3′-4′ position, since the most reactive and, hence, the most reducing OH-group in 3-position is preferentially glycosylated. In other words, quercetin, but not kaempferol derivatives, are effective antioxidants [17]. Interestingly, an increase in dihydroxy to monohydroxy B-ring-substituted flavonoids has been also reported in response to visible light [19,20], drought [17] and salinity stress (in the absence of UV radiation, [20]). A preferential increase in the concentration of the antioxidant quercetin glycosides was also shown in response to low temperature or nutrient deficiency in high light growing plants [59,60,61,62]. These observations are consistent with the notion of flavonoid biosynthesis being activated by over-reduction of photosynthetic electron transport chain (PETC), a common feature, together with ROS production plants face when exposed to different abiotic stressors [63,64]. Notably, that application of far-red light (700–780 nm), which is known to induce the oxidation of the PETC, depresses both the biosynthesis of flavonoids and the ratio of quercetin to kaempferol [65]. This supports the view the redox and/or ROS signals are key drivers for the biosynthesis of flavonols (and for the biosynthesis of other secondary metabolites as well [66,67,68,69]). This conforms to the notion that the activity of R2R3MYB proteins, regulating key genes of flavonol biosynthesis, is also under strict redox control, even because of posttranslational modifications [70,71,72,73,74].
It has been reasonably inferred, therefore, that the biosynthesis of flavonoids is activated by alteration in the redox potential of the cell and, in turn, flavonoids may help to limit oxidative damage primarily acting as antioxidants and not as light screeners in photoprotection [12,30,31]. These are likely ancestral functions of flavonoids, as early land plants underwent severe desiccation and large temperature fluctuations, in addition to high light intensity, when they moved from water [37,75]. In other words, “an excess of UV-B radiation” was just one (possibly not the most detrimental) of the “novel” environmental pressures plants faced when moving on land [25,28,76,77]. Early land plants had to live with and adapt to an ever-changing ROS environment from the very beginning [26]. The evolution of flavonoid (and the phenylpropanoid) metabolism as well as of TFs regulating their biosynthesis [4] represent key components of the suite of traits whose evolution has been responsible for the increased complexity of land plants, thereby allowing their radiation toward less favorable environments [4,5]. For example, in a range of modern land plants, a suite of flavonoid and hydroxycinnamate structures accumulate in plants growing under partial shading, with the monohydroxy B-ring-substituted structures dominating the phenylpropanoid pool [13,14,16]. These compounds are mostly distributed in the external leaf tissues, such as the epidermal cells and different types of trichomes (Figure 2), and may well represent a constitutively (i.e., in plants growing in partial shading) efficient shield against UV-B radiation [78,79]. The observation that monohydroxy B-ring-substituted phenylpropanoids are almost unresponsive, whereas dihydroxy B-ring-substituted flavones and flavonols increase in concentration because of UV-B, UV-A as well as visible light irradiance, offers strong support to a major antioxidant role of flavonoids in photoprotection [12,17,18,31]. We note indeed that photoprotection must be “measured” only when plants experience light irradiance largely exceeding that actually used for photosynthesis, i.e., under strong photoinhibitory conditions [80].

3. Do Flavonoids Play Relevant Antioxidant Functions in Plants? A Matter of Definition

The actual role of flavonoids as effective antioxidants in both plants and animals has been extensively debated over the last few decades [3,12,31,81,82,83]. Though flavonoids have great potential to counter the detrimental effects of the massive generation of reactive oxygen species (ROS), authoritative criticisms have been raised in many instances. Barry Halliwell, who provided a series of definitions of “antioxidants”, has always been critical of the effective ability of flavonoids to “delay, prevent or remove oxidative damage to a target molecule”, a widely accepted definition of antioxidant given in Gutteridge and Halliwell [21]. This is because the flavonoid structures with the greatest ability to reduce (i.e., flavonoid aglycones) the levels of oxidants are usually in very low concentrations in human tissues [84,85,86]. This, in turn, implies flavonoids cannot play systematic antioxidant functions. Even more, Halliwell [85], and Gutteridge and Halliwell [87] suggested that the beneficial effects of flavonoids on human health might be also due to their pro-oxidant actions, thereby activating a range of endogenous antioxidant defenses. The Gutteridge–Halliwell definition of antioxidant was shaped over time taking into account novel evidence from studies performed on humans, but has been largely used by plant biologists as well. Being wide in its nature, this definition is rather robust, since it applies to organisms in different kingdoms [88], and includes not only the substance ability to quench/scavenge oxidants, but also to limit the rate at which oxidants form, i.e., the substance ability to “avoid” oxidative stress. In other words, the way through which a substance “protects” a target molecule from oxidative damage does not matter.
However, this has sparked and continues to spark debate among plant biologists. For instance, the capacity of flavonoids, both the colorless (e.g., flavones and flavonols) and the colored structures (i.e., anthocyanins) to strongly absorb over the UV- and the visible portion of the solar spectrum may effectively protect so-called sensitive targets from uncontrolled ROS-generation, and from the consequential oxidative damage [31,86,89]. Similar reasoning also applies to relevant products of the MEP pathway, such as the volatile isoprene and the non-volatile xanthophyll, zeaxanthin. Isoprene and zeaxanthin may both increase the rigidity of thylakoid membranes in high light-grown plants concomitantly exposed to heat and water stress (drought stress, sensu stricto), and preserve lipids membrane from peroxidation [90,91,92,93]: this is an antioxidant function, sensu Gutteridge and Halliwell [21]. Even though these “indirect” functions should be regarded as antioxidant, the vast majority of plant scientists commonly refer to more restrictive definitions of antioxidants. The very same reasoning also applies to the definition of “oxidative damage”, and Halliwell [94] posed the “debatable” question of direct or indirect biomolecular damage caused by an attack of ROS upon the constituents of living organisms [95,96].
Definitions delineate the frame, within which we have to reason to assess the effective antioxidant functions of any substance in an in planta condition. Therefore, any definition must be unbiased and robust, as much as possible. Foyer and Noctor [23] defined antioxidant as a compound that “outcompetes others in reacting with ROS to give a relatively stable oxidized product”. The authors specifically refer to the quenching/scavenging of ROS, and introduce the concept of effective antioxidant, partly using an older definition of antioxidant given in 1995 by Halliwell and Gutteridge: “any substance that, when present at low concentrations compared with those of an oxidizable substrate, significantly delays or prevents oxidation of that substrate” [97]. Hernandez et al. [22] reasoned on the relevance of flavonoids as an antioxidant in plants, and defined an antioxidant as “a molecule that donates electrons or hydrogen atoms, yields an antioxidant derived radical that is efficiently quenched by other electron or hydrogen sources to prevent cellular damage; and whose properties are spatially and temporally correlated with oxidative stress events”. This is a restrictive definition compared to those given by Gutteridge and Halliwell [21] and Foyer and Noctor [23]. Within the framework delineated by their definition, Hernandez et al. [22] posed serious concerns on the relevance of flavonoids as antioxidants in an in planta situation, since flavonoid radicals have not been detected in the vast majority of studies. We note, however, that by just following the authors’ definition, antioxidant-derived radicals are to be efficiently reduced to prevent oxidative/cellular damage. It is conceivable, therefore, that the phenoxyl radicals, the products of flavonoid oxidation, are at the trace level in healthy cells and unlikely detectable even with the most sensitive equipment [31]. In actuality, Hernandez et al. [98] detected quinones (i.e., the phenoxyl radicals ECQ and EGCGQ) of both epicatechin (EC) and epigallo catechin gallate (EGCG) (the reduced flavonoid forms) in tea plants exposed to severe drought stress, when relative water content (RWC) dropped down below 60% and maximum PSII quantum yield for photochemistry, Fv/Fm, was as low as 0.5. It is likely this study was not the most appropriate to unveil the actual antioxidant functions of flavonoids in an in planta situation, since the concentration of ECQ was 25 times higher than that of EC, and EGCGQ and EGCG did not differ much in concentration. We reason that either (perhaps both) the reduction system of flavanols was severely compromised and/or, more probably, damage to the vacuolar membrane occurred, under the severe drought stress event plants were faced with. We therefore suggest that the detection of flavonoid radicals is not the best-suited estimate of their occurred antioxidant action.
The required spatio-temporal correlation between antioxidants and oxidative stress events proposed by Hernandez et al. [22] also poses further questions. For instance, products synthesized through the plastidial MEP pathway, such as β-carotene and isoprene, have been reported as actual quenchers of singlet oxygen, based upon the generation of their oxidation products [99,100,101,102,103,104,105]. Since the production of isoprene and its oxidation products (methyl vinyl ketone and metacrolein) decreases under prolonged stress conditions [93,106,107,108,109,110] unlikely may accomplish increased antioxidant protection when oxidative stress becomes more severe. Similarly, the concentrations of a suite of β-carotene endo-peroxides and of the volatile β-cycocitral generated by singlet oxygen-induced oxidation of β-carotene, decline as light stress become particularly severe [101,102]. Similar observations have been also reported in the case of well-recognized antioxidants, such as antioxidant enzymes and ascorbate. There is vast and compelling evidence indeed that the activity of antioxidant enzymes may steeply decline during stress progression, when their action should be at the maximum [111,112,113,114,115]. This is the case of plants suffering from high temperature or drought stress when concomitantly exposed to high solar irradiance, as also recently shown for the large declines in antioxidant enzyme activities in Platanus × acerifolia leaves during the hottest hours of the day [93]. There is consensus indeed, that “stress-sensitive” species or genotypes are unable to maintain an efficient system for ROS removal when long exposed to stress [116]. This is because large restrictions in the plant’s ability to use radiant energy for carbon fixation, translates into severe excess light stress antioxidant enzymes are unable to counter efficiently [112,117,118,119].
There is also evidence that the level of ascorbate (ASC) declines markedly, as also observed for the activity of ascorbate peroxidase, in the chloroplast, while steeply increasing in the vacuole because of both high light and drought stress [120,121]. This stress-induced subcellular ASC redistribution decreases the usually (under non-stress conditions) high reducing the capacity of the chloroplast stroma [23]. This poses some concerns on the effective antioxidant role of ASC (based on the spatio-temporal relationship between oxidative stress event and proper antioxidant location, [22]) when the excess of radiant energy becomes particularly severe. There is old evidence that ASC is a relatively poor substrate [122,123] for vacuolar peroxidase aimed at reducing H2O2 likely entering the vacuole at considerable rates under the most severe stressful conditions [117,124,125,126,127]. Notably, the vacuole is the preferential site of flavonoid accumulation, although in some species colorless flavonoids have been detected in the chloroplast and in the nucleus. The functional significance of chloroplast- and nuclear-located flavonoids in preserving cells from irreversible oxidative damage has been already explored [16,31], and it will be briefly discussed in the next section. In contrast to ASC, flavonoids are excellent substrates for vacuolar class III peroxidases (POX), [122,125,128]. More than two decades ago, Yamasaki et al. [128] proposed a model in which phenoxyl radicals generated by the action of POX are recycled back to their reduced forms by ascorbate, and by mono-dehydroascorbate reductase as well, which act as “secondary antioxidants” [123,129]. At that time, the model assumed an exclusive distribution of flavonoids in the vacuole of epidermal cells, thus raising the question about how H2O2 generated in mesophyll cells might reach that compartment. There is now compelling evidence that H2O2 is transported at both intra- and inter-cellular level [130,131,132,133] through the action of the very same H2O transporters: H2O2 and H2O have indeed very similar physico-chemical properties [133,134,135,136]. There is evidence that aquaporins are involved indeed in oxidative stress responses [136,137].
In addition, we note that the epidermis is not the tissue with the highest flavonoid level in plants living under natural conditions. The concentration of epidermal flavonoids, usually estimated by fluorescence microscopy of Naturstoff reagent-stained tissues, largely exceeds that in mesophyll tissues, simply because of the small volume in which epidermal flavonoids are dissolved (Figure 3). The whole-leaf content of flavonoids may reach as much as 8-10 micromoles in plants long-exposed to full sunlight [17,18], but less than 1 micro mole may accumulate in the vacuoles of epidermal layers, because of their relatively low solubility in the aqueous cellular milieu [138]. Flavonoids located in the vacuoles of mesophyll cells are therefore close enough to ROS generating organelles (Figure 3), and hence optimally suited to buffer large alterations from ROS homeostasis. Furthermore, the view that flavonoids must be located in the very same cell organelle of ROS generation is likely to be strongly re-thought: ROS are not only involved cell-to-cell [132,139], but also in leaf-to-leaf communications, as is the case of light-induced control of stomata aperture [140,141]. There is also intriguing evidence that collapsed chloroplasts are included in the vacuole following both UV-B and high light stress (so-called chlorophagy) [142,143], as usually occurs in response to broad oxidative stress conditions [144,145,146]. We likely have to re-draw the picture representing the complexity of the dynamic cellular organization during the most severe stressful conditions, to delineate the actual scenario within which biological processes occur. Autophagy is functional in ROS detoxification indeed [147], and there is a possibility that flavonoids might be involved in this process.
Recent findings from Gloria Muday’s lab have offered conclusive support for an effective role of flavonoids as in vivo scavengers of H2O2 (for a review, see Chapman et al. [148]). In both Arabidopsis and tomato, flavonols, particularly quercetin mostly occurring in the cytoplasm and in the nucleus, greatly reduced the levels of H2O2 (estimated by fluorescence microscopy), thereby antagonizing ABA-induced stomatal closure [149,150]. Flavonols were also effective in preserving the integrity and the growth of pollen tubes upon heat stress in tomato, by decreasing ROS levels [151]. Agati et al., 2007 [152], also offered compelling evidence for the effective ability of quercetin (and luteolin) derivatives to quench singlet oxygen (1O2) generated by high PAR irradiance using cross-sections of P. latifolia leaves with largely different levels of flavonoids. It was shown that dihydroxy B-ring-substituted flavonoids accumulated in the chloroplast outer envelope membrane and, hence optimally suited to quench 1O2 (Figure 4).
We observe that albeit the formation of flavonoid oxidation products is conclusive proof of their occurred in vivo antioxidant actions, the very same strong evidence comes from their capacity to reduce the level of oxidative stress. We suggest that the reduction of oxidative stress may be well suited to estimate the antioxidant role of flavonoids in an in planta situation. As already noted the occurrence of flavonoid oxidation products may be transient and largely dependent upon the severity of stress indeed, and hence, unlikely suitable for systemic measurements. Instead, newly developed imaging techniques seem to be suitable for quantifying ROS, and hence oxidative stress, not only at the cell and organ [153], but also at the whole-plant level [154,155]. We believe that a plant antioxidant is best defined in terms of its ability to “counter” oxidative stress and damage: this ability is suitably “quantified” by measurements of “oxidative stress reduction” more than by the formation of oxidation products.

4. Conclusions: Still Open Questions

In the previous section, we offered compelling evidence of in vivo ROS scavenging by “cytoplasm-located” flavonoids (Figure 4 A–D) [149,150,151,152]. Nonetheless, there are very few examples of this subcellular flavonoid distribution, which also includes nuclear flavonoids [31,156,157]. The potential antioxidant effects of nuclear-located flavonoids are of the greatest significance, as they include not only ROS quenching, but also the ability of antioxidant flavonol glycosides to chelate transition metal ions, thereby limiting the generation of ROS: this has to be regarded as an antioxidant function sensu lato. Nonetheless, studies aimed at exploring the sub-cellular distribution of flavonoids have not increased much in number over the last few years, and future investigation aimed at extending our knowledge on the sub-cellular distribution of specific flavonoid classes may help to solve the matter.
That said, the discussion about the effective antioxidant role of flavonoids in plants has been (and is still) based upon their vacuolar distribution, as observed in the vast majority of plants. In turn, this imposes to reason about the contribution of the H2O2-scavenging by vacuolar located flavonoids in modulating stress-induced changes in whole-cell redox homeostasis. The very same reasoning applies to the actual contribution of the vacuole in the maintenance of cellular redox homeostasis under stressful conditions, e.g., during excessive light [153,158,159]. There are suggestions, indeed, that H2O2 may enter the vacuole at low rates to have major significance in altering the whole-cell redox homeostasis [22]. We note that the rates at which H2O2 may diffuse out of the chloroplast (or the peroxisome) [117,125,160,161] when the activity and the concentration of primary antioxidants decline greatly in response to severe stress are practically impossible to quantify. Additionally, we observe that the concentration range within which H2O2 activates signaling pathways to enhance further stress resistance or instead irreversibly damages cell metabolism and functioning appears very narrow [23,162]. We highlight methods used to quantify H2O2 are conducted at the level of the whole-organ and, hence, are unsuitable to detect the small changes in H2O2 concentration that may occur in a very short time level in different subcellular compartments, and are responsible for the subsequent cell fate. Our deterministic approach encounters, once again, insurmountable scale-level obstacles.
In our opinion, the conclusive question regards the role of flavonoids relative to that of the modular and integrated network of antioxidant defenses plants activate in response to stress conditions of increasing severity. Plants face photo-oxidative stress of increased severity not only on long- (days/weeks) but also on a short-term (hour) basis. For instance, solar irradiance is in a large excess of that used for photosynthesis during the central hours of the day (midday depression of photosynthesis), because of stomatal limitations and supra-optimal leaf temperatures [163]. This, in turn, leads to reductions in both Rubisco activation, thereby imposing additional biochemical limitations to photosynthesis [164,165,166] and PSII photochemical efficiency. As already noted, excess excitation energy-induced large alterations in redox homeostasis are the very conditions that depress the activity of primary antioxidants [107,167,168,169], while promoting the biosynthesis of antioxidant flavonoids [19,93,113,170]. Unveiling the extent to which primary and secondary antioxidants vary, on a short-term basis, in response to abrupt changes in excess radiant energy may help to solve the question of the actual significance of flavonoids in the modular and integrated network of antioxidant defenses. The notion that large alterations in the cell redox state trigger the biosynthesis of flavonoids [72,171] leads us to hypothesize that flavonoids may complement the functions of primary antioxidants when their ROS detoxifying capacity declines in plants suffering from severe photooxidative stress [93,112,113,170]. The matter needs future investigation aimed at estimating the changes in the whole spectrum of primary and secondary antioxidant defenses in plants with constitutively different levels of antioxidant flavonoids (using both natural or induced variation), challenged against the excess of radiant energy of increasing severity induced by abiotic stressors of different origin.

Author Contributions

Conceptualization, M.T.; writing—original draft preparation G.A., L.G., M.L. and M.T.; writing—review and editing, A.G., C.B., A.F. and F.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Tohge, T.; Fernie, A.R. Leveraging natural variance towards enhanced understanding of phytochemical sunscreens. Trends Plant Sci. 2017, 22, 308–315. [Google Scholar] [CrossRef]
  2. Brunetti, C.; Fini, A.; Sebastiani, F.; Gori, A.; Tattini, M. Modulation of phytohormone signaling: A primary function of flavonoids in plant–environment interactions. Front. Plant Sci. 2018, 9, 1042. [Google Scholar] [CrossRef]
  3. Davies, K.M.; Jibran, R.; Zhou, Y.; Albert, N.W.; Brummell, D.A.; Jordan, B.R.; Bowman, J.L.; Schwinn, K.E. The evolution of flavonoid biosynthesis: A bryophyte perspective. Front. Plant Sci. 2020, 11, 7. [Google Scholar] [CrossRef] [PubMed]
  4. Brunetti, C.; Sebastiani, F.; Tattini, M. ABA, flavonols and the evolvability of land plants. Plant Sci. 2019, 280, 448–454. [Google Scholar] [CrossRef] [PubMed]
  5. Rozema, J.; van de Staaij, J.; Björn, L.A.; Caldwell, M. UV-B as an environmental factor in plant life: Stress and regulation. Trends Ecol. Evol. 1997, 12, 22–28. [Google Scholar] [CrossRef]
  6. Bassman, J.H. Ecosystem consequences of enhanced solar ultraviolet radiation: Secondary plant metabolites as mediators of multiple trophic interactions in terrestrial plant communities. Photochem. Photobiol. 2004, 79, 382–398. [Google Scholar] [CrossRef] [PubMed]
  7. Jansen, M.A.K.; Gaba, V.; Greenberg, B.M. Higher plants and UV-B radiation: Balancing damage, repair and acclimation. Trends Plant Sci. 1998, 3, 131–135. [Google Scholar] [CrossRef]
  8. Britt, A.N. Molecular genetics of DNA repair in higher plants. Trends Plant Sci. 1999, 4, 20–25. [Google Scholar] [CrossRef]
  9. Szilárd, A.; Sass, L.; Deák, Z.; Vass, I. The sensitivity of Photosystem II to damage by UV-B radiation depends on the oxidation state of the water-splitting complex. Biochim. Biophys. Acta-Bioenerg. 2007, 1767, 876–882. [Google Scholar]
  10. Takahashi, S.; Milward, S.E.; Yamori, W.; Evans, J.R.; Hillier, W.; Badger, M.R. The solar action spectrum of Photosystem II damage. Plant Physiol. 2010, 153, 988–993. [Google Scholar] [CrossRef]
  11. Harborne, J.B.; Williams, C.A. Advances in Flavonoid Research since 1992. Phytochemistry 2000, 55, 481–504. [Google Scholar] [CrossRef]
  12. Agati, G.; Tattini, M. Multiple functional roles of flavonoids in photoprotection. New Phytol. 2010, 186, 786–793. [Google Scholar] [CrossRef] [PubMed]
  13. Tattini, M.; Gravano, E.; Pinelli, P.; Mulinacci, N.; Romani, A. Flavonoids accumulate in leaves and glandular trichomes of Phillyrea latifolia exposed to excess solar radiation. New Phytol. 2000, 148, 69–77. [Google Scholar] [CrossRef]
  14. Agati, G.; Galardi, C.; Gravano, E.; Romani, A.; Tattini, M. Flavonoid distribution in tissues of Phillyrea latifolia as estimated by microspectrofluorometry and multispectral fluorescence microimaging. Photochem. Photobiol. 2002, 76, 350–360. [Google Scholar] [CrossRef]
  15. Sheahan, J.J. Sinapate esters provide greater UV-B attenuation than flavonoids in Arabidopsis thaliana (Brassicaceae). Am. J. Bot. 1996, 83, 679–686. [Google Scholar] [CrossRef]
  16. Agati, G.; Brunetti, C.; Di Ferdinando, M.; Ferrini, F.; Tattini, M. Functional roles of flavonoids in photoprotection: New evidence, lessons from the past. Plant Physiol. Biochem. 2013, 72, 35–45. [Google Scholar] [CrossRef]
  17. Tattini, M.; Galardi, C.; Pinelli, P.; Massai, R.; Remorini, D.; Agati, G. Differential accumulation of flavonoids and hydroxycinnamates in leaves of Ligustrum vulgare under excess light and drought stress. New Phytol. 2004, 163, 547–561. [Google Scholar] [CrossRef]
  18. Tattini, M.; Guidi, L.; Morassi-Bonzi, L.; Pinelli, P.; Remorini, D.; Degl’Innocenti, E.; Giordano, C.; Massai, R.; Agati, G. On the role of flavonoids in the integrated mechanisms of response of Ligustrum vulgare and Phillyrea latifolia to high solar radiation. New Phytol. 2005, 167, 457–470. [Google Scholar] [CrossRef]
  19. Agati, G.; Stefano, G.; Biricolti, S.; Tattini, M. Mesophyll distribution of antioxidant flavonoids in Ligustrum vulgare leaves under contrasting sunlight irradiance. Ann. Bot. 2009, 104, 853–861. [Google Scholar] [CrossRef] [PubMed]
  20. Agati, G.; Biricolti, S.; Guidi, L.; Ferrini, F.; Fini, A.; Tattini, M. The biosynthesis of flavonoids is enhanced similarly by UV radiation and root zone salinity in L. vulgare leaves. J. Plant Physiol. 2011, 168, 204–212. [Google Scholar] [CrossRef]
  21. Halliwell, B.; Gutteridge, J.M.C. Free Radicals in Biology and Medicine, 4th ed.; Oxford University Press: Oxford, UK, 2007. [Google Scholar]
  22. Hernández, I.; Alegre, L.; van Breusegem, F.; Munné-Bosch, S. How relevant are flavonoids as antioxidants in plants? Trends Plant Sci. 2009, 14, 125–132. [Google Scholar] [CrossRef]
  23. Foyer, C.H.; Noctor, G. Stress-triggered redox signalling: What’s in pROSpect? Plant Cell Environ. 2016, 39, 951–964. [Google Scholar] [CrossRef] [PubMed]
  24. Cockell, C.S.; Knowland, J. Ultraviolet radiation screening compounds. Biol. Rev. 1999, 74, 311–345. [Google Scholar] [CrossRef]
  25. Delwiche, C.F.; Cooper, E.D. The evolutionary origin of a terrestrial flora. Curr. Biol. 2005, 25, R899–R910. [Google Scholar] [CrossRef]
  26. Mittler, R. ROS are good. Trends Plant Sci. 2017, 22, 11–19. [Google Scholar] [CrossRef]
  27. Horandl, E.; Hadacek, F. Oxygen, life forms, and the evolution of sexes in multicellular eukaryotes. Heredity 2020, 125, 1–14. [Google Scholar] [CrossRef] [PubMed]
  28. Tena, G. From algae to land plants. Nat. Plants 2020, 6, 594. [Google Scholar] [CrossRef] [PubMed]
  29. Stafford, H.A. Flavonoid evolution: An enzymic approach. Plant Physiol. 1991, 96, 680–685. [Google Scholar] [CrossRef]
  30. Pollastri, S.; Tattini, M. Flavonols, old compounds for old roles. Ann. Bot. 2011, 108, 1225–1233. [Google Scholar] [CrossRef]
  31. Agati, G.; Azzarello, E.; Pollastri, S.; Tattini, M. Flavonoids as antioxidants in plants: Location and functional significance. Plant Sci. 2012, 196, 67–76. [Google Scholar] [CrossRef]
  32. Schwinn, K.E.; Davies, K.M. Flavonoids. In Annual Plant Reviews 14: Plant Pigments and Their Manipulation; CRC Press: Boca Raton, FL, USA; Blackwell Publishing: Oxford, UK, 2004; pp. 92–149. [Google Scholar]
  33. Liu, Y.; Fang, S.; Yang, W.; Shang, X.; Fu, X. Light quality affects flavonoid production and related gene expression in Cyclocarya paliurus. J. Photochem. Photobiol. B Biol. 2018, 179, 66–73. [Google Scholar] [CrossRef]
  34. Rai, N.; Neugart, S.; Yan, Y.; Wang, F.; Siipola, S.M.; Lindfors, A.V.; Winkler, J.B.; Albert, A.; Brosché, M.; Lehto, T.; et al. How do cryptochromes and UVR8 interact in natural and simulated sunlight? J. Exp. Bot. 2019, 70, 4975–4990. [Google Scholar] [CrossRef]
  35. Siipola, S.M.; Kotilainen, T.; Sipari, N.; Morales, L.O.; Lindfors, A.V.; Robson, T.M.; Aphalo, P.J. Epidermal UV-A absorbance and wholeleaf flavonoid composition in pea respond more to solar blue light than to solar UV radiation. Plant Cell Environ. 2015, 38, 941–952. [Google Scholar] [CrossRef]
  36. Charron, A.J.; Quatrano, R.S. Between a rock and a dry place: The water-stressed moss. Mol. Plant 2009, 2, 478–486. [Google Scholar] [CrossRef]
  37. Stevenosn, S.R.; Kamisugi, Y.; Trinh, C.H.; Schmutz, J.; Jenkins, J.W.; Grimwood, J.; Muchero, W.; Tuskan, G.A.; Rensing, S.A.; Lang, D.; et al. Genetic analysis of Physcomitrella patens identifies ABSCISIC ACID NON-RESPONSIVE, a regulator of ABA responses unique to basal land plants and required for desiccation tolerance. Plant Cell 2016, 28, 1310–1327. [Google Scholar] [CrossRef] [PubMed]
  38. Farrant, J.M.; Moore, J.P. Programming desiccation-tolerance: From plants to seeds to resurrection plants. Curr. Opin. Plant Biol. 2011, 14, 340–345. [Google Scholar] [CrossRef]
  39. De Vries, J.; Archibald, J.M. Plant evolution: Landmarks on the path to terrestrial life. New Phytol. 2018, 217, 1428–1434. [Google Scholar] [CrossRef]
  40. Furst-Jansen, J.M.R.; de Vries, S.; de Vries, J. Evo-physio: On stress, responses and the earliest land plants. J. Exp. Bot. 2020, 71, 3254–3269. [Google Scholar] [CrossRef]
  41. Caldwell, M.M.; Robberecht, R.; Flint, S.D. Internal filters: Prospects for UV-acclimation in higher plants. Physiol. Plant. 1983, 58, 445–450. [Google Scholar] [CrossRef]
  42. Tattini, M.; Matteini, P.; Saracini, E.; Traversi, M.L.; Giordano, C.; Agati, G. Morphology and biochemistry of non-glandular trichomes in Cistus salvifolius L. leaves growing in extreme habitats of the Mediterranean basin. Plant Biol. 2007, 9, 411–419. [Google Scholar] [CrossRef]
  43. Teramura, A.H.; Sullivan, J.H. Effects of UV-B radiation on photosynthesis and growth of terrestrial plants. Photosynth. Res. 1994, 39, 463–473. [Google Scholar] [CrossRef] [PubMed]
  44. Li, J.; Ou-Lee, T.M.; Raba, R.; Amundson, R.G.; Last, R.L. Arabidopsis flavonoid mutants are hypersensitive to UV-B irradiation. Plant Cell 1993, 5, 171–179. [Google Scholar] [CrossRef]
  45. Lois, R. Accumulation of UV-absorbing flavonoids induced by UV-B radiation in Arabidopsis thaliana L. I. Mechanisms of UV-resistance in Arabidopsis. Planta 1994, 194, 498–503. [Google Scholar] [CrossRef]
  46. Strid, Å.; Chow, W.S.; Anderson, J.M. UV-B damage and protection at the molecular level in plants. Photosynth. Res. 1994, 39, 475–489. [Google Scholar] [CrossRef]
  47. Bucholz, G.; Ehmann, B.; Wellmann, E. Ultraviolet light inhibition of phytochrome-induced flavonoid biosynthesis and DNA photolyase formation in mustard cotyledons (Sinapis alba L.). Plant Physiol. 1995, 108, 227–234. [Google Scholar] [CrossRef]
  48. Markham, K.R.; Ryan, K.G.; Bloor, S.J.; Mitchell, K.A. An increase in luteolin: Apigenin ratio in Marchantia polymorpha on UV-B enhancement. Phytochemistry 1998, 48, 791–794. [Google Scholar] [CrossRef]
  49. Middleton, E.M.; Teramura, A.H. The role of flavonol glycosides and carotenoids in protecting soybean from ultraviolet-B damage. Plant Physiol. 1993, 103, 741–752. [Google Scholar] [CrossRef] [PubMed]
  50. Nogues, S.; Baker, N.R. Effects of drought on photosynthesis in Mediterranean plants grown under enhanced UV-B radiation. J. Exp. Bot. 2000, 51, 1309–1317. [Google Scholar] [CrossRef]
  51. Bieza, K.; Lois, R. An Arabidopsis mutant tolerant to lethal ultraviolet-B levels shows constitutively elevated accumulation of flavonoids and other phenolics. Plant Physiol. 2001, 126, 1105–1115. [Google Scholar] [CrossRef] [PubMed]
  52. Lois, R.; Buchanan, B.-B. Severe sensitivity to ultraviolet radiation in an Arabidopsis mutant deficient in flavonoid accumulation II. Mechanisms of UV-resistance in Arabidopsis. Planta 1994, 194, 504–509. [Google Scholar] [CrossRef]
  53. Booij-James, I.S.; Dube, S.K.; Jansen, M.A.K.; Edelman, M.; Mattoo, A.K. Ultraviolet-B radiation impacts light-mediated turnover of the Photosystem II reaction center heterodimer in Arabidopsis mutants altered in phenolic metabolism. Plant Physiol. 2000, 124, 1275–1283. [Google Scholar] [CrossRef]
  54. Landry, L.G.; Chapple, C.C.S.; Last, R.L. Arabidopsis mutants lacking phenolic sunscreen exhibit enhanced ultraviolet-B-induced injury and oxidative damage. Plant Physiol. 1995, 109, 1159–1166. [Google Scholar] [CrossRef]
  55. Olsson, L.C.; Veit, M.; Bornman, J.F. Epidermal transmittance and phenolic composition of atrazine-tolerant and atrazine-sensitive cultivars of Brassica napus grown under enhanced UV-B radiation. Physiol. Plant. 1999, 107, 259–266. [Google Scholar] [CrossRef]
  56. Hofmann, R.W.; Swinny, E.E.; Bloor, S.J.; Markham, K.R.; Ryan, K.G.; Campbell, B.D.; Jordan, B.R.; Fountain, D.W. Responses of nine Trifolium repens L. populations to ultraviolet-B radiation: Differential flavonol glycoside accumulation and biomass production. Ann. Bot. 2000, 86, 527–537. [Google Scholar] [CrossRef]
  57. Hofmann, R.W.; Campbell, B.D.; Fountain, D.W.; Jordan, B.R.; Greer, D.H.; Hunt, D.Y.; Hunt, C.L. Multivariate analysis of intraspecific responses to UV-B radiation in white clover (Trifolium repens L.). Plant Cell Environ. 2001, 24, 917–927. [Google Scholar] [CrossRef]
  58. Berli, F.J.; Moreno, D.; Piccoli, P.; Hespanhol-Viana, L.; Silva, M.F.; Bressan-Smith, R.; Cavagnaro, J.B.; Borrini, R. Abscisic acid is involved in the response of grape (Vitis vinifera L.) cv. malbec leaf tissues to ultraviolet-B radiation by enhancing ultraviolet-absorbing compounds, antioxidant enzymes and membrane sterols. Plant Cell Environ. 2010, 33, 1–10. [Google Scholar]
  59. Olsen, K.M.; Slimestad, R.; Lea, U.S.; Brede, C.; Løvdal, T.; Ruoff, P.; Verheul, M.; Lillo, C. Temperature and nitrogen effects on regulators and products of the flavonoid pathway: Experimental and kinetic model studies. Plant Cell Environ. 2009, 32, 286–299. [Google Scholar] [CrossRef]
  60. Lillo, C.; Lea, U.S.; Ruoff, P. Nutrient depletion as a key factor for manipulating gene expression and product formation in different branches of the flavonoid pathway. Plant Cell Environ. 2008, 31, 587–601. [Google Scholar] [CrossRef]
  61. Løvdal, T.; Olsen, K.M.; Slimestad, R.; Verheul, M.; Lillo, C. Synergetic effects of nitrogen depletion, temperature, and light on the content of phenolic compounds and gene expression in leaves of tomato. Phytochemistry 2010, 71, 605–613. [Google Scholar] [CrossRef]
  62. Bathia, C.; Pandey, A.; Gaddam, S.R.; Hoecker, U.; Trivedi, P.K. Low temperature-enhanced flavonol synthesis requires light-associated regulatory components in Arabidopsis thaliana. Plant Cell Physiol. 2018, 59, 2099–2112. [Google Scholar]
  63. Akhtar, T.A.; Lees, H.A.; Lampi, M.A.; Enstone, D.; Brain, R.A.; Greenberg, B.M. Photosynthetic redox imbalance influences flavonoid biosynthesis in Lemma gibba. Plant Cell Environ. 2010, 33, 1205–1219. [Google Scholar] [PubMed]
  64. Babu, S.; Akhtar, T.A.; Lampi, M.A.; Tripuranthakam, S.; Dixon, G.R.; Greenberg, B.M. Similar stress responses are elicited by copper and ultraviolet radiation in the aquatic plant Lemma gibba: Implication of reactive oxygen species as common signals. Plant Cell Physiol. 2003, 44, 1320–1329. [Google Scholar] [CrossRef]
  65. Gerhardt, K.E.; Lampi, M.A.; Greenberg, B.M. The effect of far-red light on plant growth and flavonoid accumulation in Brassica napus in the presence of ultraviolet B radiation. Photochem. Photobiol. 2008, 84, 1445–1454. [Google Scholar] [CrossRef] [PubMed]
  66. Fanciullino, A.L.; Bidel, L.P.R.; Urban, L. Carotenoid responses to environmental stimuli: Integrating redox and carbon controls into a fruit model. Plant Cell Environ. 2013, 37, 273–289. [Google Scholar] [CrossRef]
  67. Selmar, D.; Kleinweichter, M. Stress enhances the synthesis of secondary plant products: The impact of stress-related over-reduction on the accumulation of natural products. Plant Cell Physiol. 2013, 54, 817–826. [Google Scholar] [CrossRef] [PubMed]
  68. Galant, A.; Koester, R.P.; Ainsworth, E.A.; Hicks, L.M.; Jez, J.M. From climate change to molecular response: Redox proteomics of ozone-induced responses in soybean. New Phytol. 2012, 194, 220–229. [Google Scholar] [CrossRef]
  69. Viola, A.L.; Camoirano, A.; Gonzalez, D.H. Redox-dependent modulation of anthocyanin biosynthesis by the TCP transcription factor TCP15 during exposure to high light intensity conditions in Arabidopsis. Plant Physiol. 2016, 170, 74–85. [Google Scholar] [CrossRef]
  70. Guehmann, S.; Vorbrueggen, G.; Kalkbrenner, F.; Moelling, K. Reduction of a conserved Cys is essential for Myb DNA-binding. Nucleic Acids Res. 1992, 20, 2279–2286. [Google Scholar] [CrossRef]
  71. Heine, G.F.; Hernandez, J.M.; Grotewold, E. Two cysteines in plant R2R3MYB domains participate in REDOX-dependent DNA binding. J. Biol. Chem. 2004, 279, 37878–37885. [Google Scholar] [CrossRef]
  72. Taylor, L.P.; Grotewold, E. Flavonoids as developmental regulators. Curr. Opin. Plant Biol. 2005, 8, 317–323. [Google Scholar] [CrossRef] [PubMed]
  73. Serpa, V.; Vernal, J.; Lamattina, L.; Grotewold, E. Inhibition of AtMYB2 DNA-binding by nitric oxide involves cysteine S-nitrosylation. Biochem. Biophys. Res. Commun. 2007, 361, 1048–1053. [Google Scholar] [CrossRef]
  74. Page, M.; Sultana, N.; Paszkievicz, K.; Florance, H.; Smirnoff, N. The influence of ascorbate on anthocyanin accumulation during high light acclimation in Arabidopsis thaliana: Further evidence for redox control of anthocyanin synthesis. Plant Cell Environ. 2012, 35, 388–404. [Google Scholar] [CrossRef]
  75. Wang, S.; Li, L.; Li, H.; Sahu, S.K.; Wang, H.; Xu, Y.; Xian, W.; Song, B.; Liang, H.; Cheng, S.; et al. Genomes of early-diverging streptophyte algae shed light on plant terrestrialization. Nat. Plants 2020, 6, 95–106. [Google Scholar] [CrossRef] [PubMed]
  76. Pierangelini, M.; Glaser, K.; Mikhailyuk, T.; Karsten, U.; Holzinger, A. Light and dehydration but not temperature drive photosynthetic adaptations of basal streptophytes (Hormidiella, Streptosarcina and Streptofilum) living in terrestrial habitats. Microb. Ecol. 2019, 77, 380–393. [Google Scholar] [CrossRef]
  77. Jiao, C.; Sorensen, I.; Sun, X.; Sun, H.; Behar, H.; Alseekh, S.; Philippe, G.; Lopez, K.P.; Sun, L.; Reed, R.; et al. The Penium margaritaceum genome: Hallmarks of the origins of land plants. Cell 2020, 181, 1097–1111. [Google Scholar] [CrossRef]
  78. Reuber, S.; Bornman, J.F.; Weissenbock, G. A flavonoid mutant of barley (Hordeum vulgare L.) exhibits increased sensitivity to UV-B radiation in the primary leaf. Plant Cell Environ. 1996, 19, 593–601. [Google Scholar] [CrossRef]
  79. Burchard, P.; Bilger, W.; Weissenböck, G. Contribution of hydroxycinnamates and flavonoids to epidermal shielding of UV-A and UV-B radiation in developing rye primary leaves as assessed by ultraviolet-induced chlorophyll fluorescence measurements. Plant Cell Environ. 2000, 23, 1373–1380. [Google Scholar] [CrossRef]
  80. Landi, M.; Agati, G.; Fini, A.; Guidi, L.; Sebastiani, F.; Tattini, M. Unveiling the shade nature of cyanic leaves: A view from the “blue absorbing side” of anthocyanins. Plant Cell Environ. 2020. [Google Scholar] [CrossRef]
  81. Swain, T. Plant flavonoids in biology and medicine. In Progress in Clinical and Biological Research; Cody, V., Middleton, E., Jr., Harborne, J.B., Eds.; Liss: New York, NY, USA, 1986; Volume 213, pp. 1–14. [Google Scholar]
  82. Halliwell, B. Are polyphenols antioxidants or pro-oxidants? What do we learn from cell culture and in vivo studies? Arch. Biochem. Biophys. 2008, 476, 107–112. [Google Scholar] [CrossRef] [PubMed]
  83. Williams, R.J.; Spencer, J.P.E.; Rice-Evans, C. Flavonoids: Antioxidants or signalling molecules? Free Radic. Biol. Med. 2004, 36, 838–849. [Google Scholar] [CrossRef]
  84. Virgili, F.; Marino, M. Regulation of cellular signaling from nutritional molecules: A specific roles of phytochemical beyond antioxidant activity. Free Radic. Biol. Med. 2008, 45, 1205–1216. [Google Scholar] [CrossRef]
  85. Halliwell, B. The wanderings of a free radical. Free Radic. Biol. Med. 2009, 46, 531–542. [Google Scholar] [CrossRef]
  86. Brunetti, C.; Di Ferdinando, M.; Fini, A.; Pollastri, S.; Tattini, M. Flavonoids as antioxidants and developmental regulators: Relative significance in plants and humans. Int. J. Mol. Sci. 2013, 14, 3540–3555. [Google Scholar] [CrossRef] [PubMed]
  87. Gutteridge, J.M.C.; Halliwell, B. Antioxidants: Molecules, medicines, and myths. Biochem. Biophys. Res. Commun. 2010, 393, 561–564. [Google Scholar] [CrossRef]
  88. Lesne, A. Robustness: Confronting lessons from physics and biology. Biol. Rev. 2008, 83, 509–532. [Google Scholar] [CrossRef]
  89. Landi, M.; Tattini, M.; Gould, K.S. Multiple functional roles of anthocyanins in plant-environment interactions. Environ. Exp. Bot. 2015, 119, 4–17. [Google Scholar] [CrossRef]
  90. Havaux, M.; Dall’Osto, L.; Bassi, R. Zeaxanthin has enhanced antioxidant capacity with respect to all other xanthophylls in Arabidopsis leaves and functions independent of binding to PSII antennae. Plant Physiol. 2007, 145, 1506–1520. [Google Scholar] [CrossRef]
  91. Vickers, C.; Gershenzon, J.; Lerdau, M.T.; Loreto, F. A unified mechanism of action for volatile isoprenoids in plant abiotic stress. Nat. Chem. Biol. 2009, 5, 283–291. [Google Scholar] [CrossRef] [PubMed]
  92. Beckett, M.; Loreto, F.; Velikova, V.; Brunetti, C.; Di Ferdinando, M.; Tattini, M.; Calfapietra, C.; Farrant, J.M. Photosynthetic limitations and volatile and non-volatile isoprenoids in the poikilochlorophyllous resurrection plant Xerophyta humilis during dehydration and rehydration. Plant Cell Environ. 2012, 35, 2061–2074. [Google Scholar] [CrossRef]
  93. Tattini, M.; Loreto, F.; Fini, A.; Guidi, L.; Brunetti, C.; Velikova, V.; Gori, A.; Ferrini, F. Isoprenoids and phenylpropanoids are part of the antioxidant defense orchestrated daily by drought-stressed Platanus × acerifolia plants during Mediterranean summers. New Phytol. 2015, 207, 613–626. [Google Scholar] [CrossRef]
  94. Halliwell, B. Biochemistry of oxidative stress. Biochem. Soc. Tans. 2007, 35, 1147–1150. [Google Scholar] [CrossRef]
  95. Halliwell, B.; Whiteman, M. Measuring reactive species and oxidative damage in vivo and in cell culture: How should you do it and what do the results mean? Br. J. Pharmacol. 2004, 142, 231–255. [Google Scholar] [CrossRef]
  96. Gutteridge, J.M.C.; Halliwell, B. Mini-Review: Oxidative stress, redox stress or redox success? Biochem. Biophys. Res. Commun. 2018, 502, 183–186. [Google Scholar] [CrossRef]
  97. Halliwell, B.; Aeschbach, R.; Loliger, J.; Auroma, O.I. The characterization of antioxidants. Food. Chem. Toxicol. 1995, 33, 601–617. [Google Scholar] [CrossRef]
  98. Hernandez, I.; Alegre, L.; Munné-Bosch, S. Enhanced oxidation of flavan-3-ols and proanthocyanidin accumulation in water-stressed tea plants. Phytochemistry 2006, 67, 1120–1126. [Google Scholar] [CrossRef]
  99. Haffek, H.P.; Yakir, D. Protection of isoprene against singlet oxygen in leaves. Plant Physiol. 2002, 129, 269–277. [Google Scholar]
  100. Zeinali, N.; Altarawneh, M.; Li, D.; Nu’rait, A.; Dlugogorski, B.Z. New mechanistic insights: Why do plants produce isoprene? ACS Omega 2016, 1, 220–225. [Google Scholar] [CrossRef]
  101. Ramel, F.; Birtic, S.; Cuiné, S.; Triantaphylidès, C.; Ravanat, J.-L.; Havaux, M. Chemical quenching of singlet oxygen by carotenoids in plants. Plant Physiol. 2012, 158, 1267–1278. [Google Scholar] [CrossRef]
  102. Ramel, F.; Birtic, S.; Ginies, C.; Soubigou-Taconnat, L.; Triantaphylidès, C.; Havaux, M. Carotenoid oxidation products are stress signals that mediate gene responses to singlet oxygen in plants. Proc. Natl. Acad. Sci. USA 2012, 109, 5535–5540. [Google Scholar] [CrossRef]
  103. Tattini, M.; Velikova, V.; Vickers, C.; Brunetti, C.; Di Ferdinando, M.; Trivellini, A.; Fineschi, S.; Agati, G.; Ferrini, F.; Loreto, F. Isoprene production in transgenic tobacco alters isoprenoid, non-structural carbohydrate and phenylpropanoid metabolism, and protects photosynthesis from drought stress. Plant Cell Environ. 2014, 37, 1950–1964. [Google Scholar] [CrossRef] [PubMed]
  104. D’Alessandro, S.; Ksas, B.; Havaux, M. Decoding β-cyclocitral-mediated retrograde signaling reveals the role of a detoxification response in plant tolerance to photooxidative stress. Plant Cell 2018, 30, 2495–2511. [Google Scholar] [CrossRef] [PubMed]
  105. D’Alessandro, S.; Havaux, M. Sensing β-carotene oxidation in photosystem II to master plant stress tolerance. New Phytol. 2019, 223, 1776–1783. [Google Scholar] [CrossRef]
  106. Saunier, A.; Ormeno, E.; Worthman, H.; Temime-Roussel, B.; Lecareux, C.; Boissard, C.; Fernandez, C. Chronic drought decreases anabolic and catabolic BVOC emissions of Quercus pubescens in a Mediterranean forest. Front. Plant Sci. 2017, 8, 71. [Google Scholar] [CrossRef]
  107. Fini, A.; Brunetti, C.; Loreto, F.; Centritto, M.; Ferrini, F.; Tattini, M. Isoprene responses and functions in plants challenged by environmental pressures associated to climate change. Front. Plant Sci. 2017, 8, 1281. [Google Scholar] [CrossRef] [PubMed]
  108. Cappellin, L.; Loreto, F.; Biasioli, F.; Pastore, P.; McKinney, K. A mechanism for biogenic production and emission of MEK from MVK decoupled from isoprene biosynthesis. Atmos. Chem. Phys. 2019, 19, 3125–3135. [Google Scholar] [CrossRef]
  109. Yanez-Serrano, A.M.; Mahlau, L.; Fasbender, L.; Byron, J.; Williams, J.; Kreuzwieser, J.; Wierner, C. Heat stress causes enhanced use of cytosolic pyruvate for isoprene biosynthesis. J. Exp. Bot. 2019, 70, 5827–5838. [Google Scholar] [CrossRef]
  110. Monson, R.K.; Winkler, B.; Rosenstiel, T.N.; Block, K.; Merl-Pham, J.; Strauss, S.H.; Ault, K.; Maxfield, J.; Moore, D.J.P.; Trahan, N.A.; et al. High productivity in hybrid-poplar plantations without isoprene emission to the atmosphere. Proc. Natl. Acad. Sci. USA 2020, 117, 1596–1605. [Google Scholar] [CrossRef]
  111. Sharma, P.; Dubey, R.S. Modulation of nitrate reductase activity in rice seedlings under aluminium toxicity and water stress: Role of osmolytes as enzyme protectants. J. Plant Physiol. 2005, 16, 854–864. [Google Scholar] [CrossRef]
  112. Liu, J.; Wang, C.; Wang, Z.; Zhang, C.; Lu, S.; Liu, J. The antioxidant and free radical scavenging activities of extract and fractions from corn silk (Zea mays L.) and related flavone glycosides. Food Chem. 2011, 126, 261–269. [Google Scholar] [CrossRef]
  113. Fini, A.; Brunetti, C.; Di Ferdinando, M.; Ferrini, F.; Tattini, M. Stress-induced flavonoid biosynthesis and the antioxidant machinery of plants. Plant Signal. Behav. 2011, 6, 709–711. [Google Scholar] [CrossRef]
  114. Fini, A.; Guidi, L.; Ferrini, F.; Brunetti, C.; Di Ferdinando, M.; Biricolti, S.; Pollastri, S.; Calamai, L.; Tattini, M. Drought stress has contrasting effects on antioxidant enzymes activity and phenylpropanoid biosynthesis in Fraxinus ornus leaves: An excess light stress affair? J. Plant Physiol. 2012, 169, 929–939. [Google Scholar] [CrossRef]
  115. Liu, Y.J.; Zhang, W.; Wang, Z.B.; Ma, L.; Guo, Y.P.; Ren, X.L.; Mei, L.X. Influence of shading on photosynthesis and antioxidative activities of enzymes in apple trees. Photosynthetica 2019, 57, 857–865. [Google Scholar] [CrossRef]
  116. Peltzer, D.; Polle, A. Diurnal fluctuations of antioxidative systems in leaves of field-grown beech trees (Fagus sylvatica): Responses to light and temperature. Physiol. Plant. 2001, 111, 158–164. [Google Scholar] [CrossRef]
  117. Mubarakshina, M.M.; Ivanov, B.N.; Naydov, I.A.; Hillier, W.; Badger, M.R.; Krieger-Liszkay, A. Production and diffusion of chloroplastic H2O2 and its implication to signaling. J. Exp. Bot. 2010, 161, 3577–3587. [Google Scholar] [CrossRef] [PubMed]
  118. Yan, N.; Xu, X.-F.; Wang, Z.-D.; Huang, J.-Z.; Guo, D.-P. Interactive effects of temperature and light intensity on photosynthesis and antioxidant enzyme activity in Zizania latifolia Turcz. plants. Photosynthetica 2013, 51, 127–138. [Google Scholar] [CrossRef]
  119. Brunetti, C.; Guidi, L.; Sebastiani, F.; Tattini, M. Isoprenoids and phenylpropanoids are key components of the antioxidant defense system of plants facing severe excess light stress. Environ. Exp. Bot. 2015, 119, 54–62. [Google Scholar] [CrossRef]
  120. Zechmann, B.; Stumpe, M.; Mauch, F. Immunocytochemical determination of the subcellular distribution of ascorbate in plants. Planta 2011, 233, 1–12. [Google Scholar] [CrossRef]
  121. Koffler, B.E.; Lushin-Ebengreuth, N.; Staibentheiner, E.; Muller, M.; Zechmann, B. Compartment specific response of antioxidants to drought stress in Arabidopsis. Plant Sci. 2014, 227, 133–144. [Google Scholar] [CrossRef]
  122. Takahama, U. Oxidation of vacuolar and apoplastic phenolic substrates by peroxidase: Physiological significance of the oxidation reactions. Phytochem. Rev. 2004, 3, 207–219. [Google Scholar] [CrossRef]
  123. Sakihama, Y.; Mano, J.; Sano, S.; Asada, K.; Yamasaki, H. Reduction of phenoxyl radicals mediated by mono dehydroascorbate reductase. Biochem. Biophys. Res. Commun. 2000, 279, 949–954. [Google Scholar] [CrossRef]
  124. Polle, A. Dissecting the superoxide dismutase-ascorbate-glutathione-pathway in chloroplasts by metabolic modeling. Computer simulations as a step towards flux analysis. Plant Physiol. 2001, 126, 445–462. [Google Scholar] [CrossRef]
  125. Ferreres, F.; Figueiredo, R.; Bettencourt, S.; Carqueijeiro, I.; Oliveira, J.; GilIzquierdo, A.; Pereira, D.M.; Valentao, P.; Andrade, P.B.; Duarte, P.; et al. Identification of phenolic compounds in isolated vacuoles of the medicinal plant Catharanthus roseus and their interaction with vacuolar class III peroxidase: An H2O2 affair? J. Exp. Bot. 2011, 62, 2841–2854. [Google Scholar] [CrossRef]
  126. Zipor, G.; Oren-Shamir, M. Do vacuolar peroxidases act as plant caretakers? Plant Sci. 2013, 199–200, 41–47. [Google Scholar] [CrossRef]
  127. Wang, L.-L.; Chen, A.-P.; Zhong, N.-Q.; Liu, N.; Wu, X.-M.; Wang, F.; Yang, C.-L.; Romero, M.F.; Xia, G.-X. The Thellungiella salsuginea tonoplast aquaporin TsTIP1; 2 functions in protection against multiple abiotic stresses. Plant Cell Physiol. 2014, 55, 148–161. [Google Scholar] [CrossRef] [PubMed]
  128. Yamasaki, H.; Sakihama, Y.; Ikehara, N. Flavonoid-peroxidase reaction as a detoxification mechanism of plant cells against H2O2. Plant Physiol. 1997, 115, 1405–1412. [Google Scholar] [CrossRef]
  129. Takahama, U.; Oniki, T. A peroxidase/phenolics/ascorbate system can scavenge hydrogen peroxide in plant cells. Physiol. Plant. 1997, 101, 845–852. [Google Scholar] [CrossRef]
  130. Stonebloom, S.; Brunkard, J.O.; Cheung, A.C.; Jiang, K.; Feldman, L.; Zambryski, P. Redox states of plastids and mitochondria differentially regulate intercellular transport via plasmodesmata. Plant Physiol. 2012, 158, 190–199. [Google Scholar] [CrossRef]
  131. Tian, S.; Wang, X.; Li, P.; Wang, H.; Ji, H.; Xie, J.; Qiu, Q.; Shen, D.; Dong, H. Plant aquaporin AtPIP1;4 links apoplastic H2O2 induction to disease immunity pathways. Plant Physiol. 2016, 171, 1635–1650. [Google Scholar] [CrossRef]
  132. Choi, W.G.; Miller, G.; Wallace, I.; Harper, J.; Mittler, R.; Gilroy, S. Orchestrating rapid long-distance signaling in plants with Ca2+, ROS and electrical signals. Plant J. 2017, 80, 688–707. [Google Scholar] [CrossRef]
  133. Rodrigues, O.; Reshetnyak, G.; Grondin, A.; Saijo, Y.; Leonhardt, N.; Maurel, C.; Verdoucq, L. Aquaporins facilitate hydrogen peroxide entry into guard cells to mediate ABA- and pathogen-triggered stomatal closure. Proc. Natl. Acad. Sci. USA 2017, 114, 9200–9205. [Google Scholar] [CrossRef]
  134. Bienert, G.B.; Schjoerring, J.K.; Jahn, T.P. Membrane transport of hydrogen peroxide. Biochim. Biophys. Acta 2006, 1758, 994–1003. [Google Scholar] [CrossRef]
  135. Bienert, G.P.; Chaumont, F. Aquaporin-facilitated transmembrane diffusion of hydrogen peroxide. Biochim. Biophys. Acta 2014, 1840, 1596–1604. [Google Scholar] [CrossRef]
  136. Kim, Y.X.; Steudle, E. Gating of aquaporins by light and reactive oxygen species in leaf parenchyma cells of the midrib of Zea mays. J. Exp. Bot. 2009, 60, 547–556. [Google Scholar] [CrossRef] [PubMed]
  137. Wudick, M.M.; Li, X.; Valentini, V.; Geldner, N.; Chory, J.; Lin, J.; Maurel, C.; Luu, D.-T. Subcellular redistribution of root aquaporins induced by hydrogen peroxide. Mol. Plant 2015, 8, 1103–1114. [Google Scholar] [CrossRef]
  138. Deng, S.-P.; Yang, Y.-L.; Cheng, X.-X.; Li, W.-R.; Cai, J.-Y. Synthesis, spectroscopic study and radical scavenging activity of kaempferol derivatives: Enhanced water solubility and antioxidant activity. Int. J. Mol. Sci. 2019, 20, 975. [Google Scholar] [CrossRef]
  139. Zandalinas, S.I.; Mittler, R. ROS-induced ROS release in plant and animal cells. Free Radic. Biol. Med. 2018, 122, 21–27. [Google Scholar] [CrossRef]
  140. Devireddy, A.R.; Zandalinas, S.I.; Gomez-Cadenas, A.; Blumwald, E.; Mittler, R. Coordinating the overall stomatal response of plants: Rapid leaf-to-leaf communication during light stress. Sci. Signal. 2018, 11, eaam9514. [Google Scholar] [CrossRef]
  141. Fichman, Y.; Miller, G.; Mittler, R. Whole-plant live imaging of reactive oxygen species. Mol. Plant 2019, 12, 1203–1210. [Google Scholar] [CrossRef]
  142. Izumi, M.; Ishida, H.; Nakamura, S.; Idema, J. Entire photodamaged chloroplasts are transported to the central vacuole by autophagy. Plant Cell 2017, 29, 377–394. [Google Scholar] [CrossRef]
  143. Nakamura, S.; Izumi, M. Regulation of chlorophagy during photoinhibition and senescence: Lessons from mitophagy. Plant Cell Physiol. 2018, 59, 1135–1143. [Google Scholar] [CrossRef]
  144. Xiong, Y.; Contento, A.L.; Nguyen, P.Q.; Bassham, D.C. Degradation of oxidized proteins by autophagy during oxidative stress in Arabidopsis. Plant Physiol. 2007, 143, 291–299. [Google Scholar] [CrossRef]
  145. Yoshimoto, K.; Jikumaru, Y.; Kamiya, Y.; Kusano, M.; Consonni, C.; Panstruga, R.; Ohsumi, Y.; Shirasu, K. Autophagy negatively regulates cell death by controlling NPR1-dependent salicylic acid signaling during senescence and the innate immune response in Arabidopsis. Plant Cell 2009, 21, 2914–2927. [Google Scholar] [CrossRef]
  146. Pérez-Pérez, M.E.; Lemaire, S.D.; Crespo, J.L. Control of autophagy in Chlamydomonas is mediated through redox dependent inactivation of the ATG4 protease. Plant Physiol. 2016, 172, 2219–2234. [Google Scholar] [CrossRef]
  147. Signorelli, S.; Tarkowski, L.P.; vand den Ende, W.; Bassham, D.C. Linking autophagy to abiotic and biotic stress responses. Trends Plant Sci. 2019, 24, 413–430. [Google Scholar] [CrossRef] [PubMed]
  148. Chapman, J.M.; Muhlemann, J.K.; Gayomba, S.R.; Muday, G.K. RBOH-dependent ROS synthesis and ROS scavenging by plant specialized metabolites to modulate plant development and stress responses. Chem. Res. Toxicol. 2019, 32, 370–396. [Google Scholar] [CrossRef]
  149. Watkins, J.M.; Hechler, P.J.; Muday, G.K. Ethylene-induced flavonol accumulation in guard cells suppresses reactive oxygen species and moderates stomatal aperture. Plant Physiol. 2014, 164, 1707–1717. [Google Scholar] [CrossRef]
  150. Watkins, J.M.; Chapman, J.M.; Muday, G.K. Abscisic acid-induced reactive oxygen species are modulated by flavonols to control stomata aperture. Plant Physiol. 2017, 175, 1807–1825. [Google Scholar] [CrossRef]
  151. Muhlemann, J.K.; Younts, T.L.B.; Muday, G.K. Flavonols control pollen tube growth and integrity by regulating ROS homeostasis during high temperature stress. Proc. Natl. Acad. Sci. USA 2018, 115, E11188–E11197. [Google Scholar] [CrossRef] [PubMed]
  152. Agati, G.; Matteini, P.; Goti, A.; Tattini, M. Chloroplast-located flavonoids can scavenge singlet oxygen. New Phytol. 2007, 174, 77–89. [Google Scholar] [CrossRef]
  153. Choi, W.G.; Swanson, S.J.; Gilroy, S. High-resolution imaging of Ca2+, redox status, ROS and pH using GFP biosensors. Plant J. 2012, 70, 118–128. [Google Scholar] [CrossRef] [PubMed]
  154. Rehman, A.U.; Szabo, M.; Deak, Z.; Larkum, A.; Ralph, P.; Vaas, P. Symbiodinium sp. cells produce light-induced intra- and extracellular singlet oxygen, which mediates photodamage of the photosynthetic apparatus and has the potential to interact with the animal host in coral symbiosis. New Phytol. 2016, 212, 472–484. [Google Scholar] [CrossRef]
  155. Prasad, A.; Sedlarova, M.; Balukova, A.; Rac, M.; Pospisil, P. Reactive oxygen species as a response to wounding: In vivo imaging in Arabidopsis thaliana. Front. Plant Sci. 2020, 10, 1660. [Google Scholar] [CrossRef]
  156. Feucht, W.; Treutter, D.; Dithmar, H.; Polster, J. Microspore development of three coniferous species: Affinity of nuclei for flavonoids. Tree Physiol. 2008, 28, 1783–1791. [Google Scholar] [CrossRef]
  157. Feucht, W.; Schmidt, M.; Treutter, D. Flavanols and flavonols in the nuclei of conifer genotypes with different growth. Forests 2014, 5, 2122–2135. [Google Scholar] [CrossRef]
  158. Choudhury, F.K.; Rivero, R.M.; Blumwald, E.; Mittler, R. Reactive oxygen species, abiotic stress and stress combination. Plant J. 2017, 90, 856–867. [Google Scholar] [CrossRef] [PubMed]
  159. Smirnoff, N.; Arnaud, D. Hydrogen peroxide metabolism and functions in plants. New Phytol. 2018, 221, 1197–1214. [Google Scholar] [CrossRef]
  160. Borisova-Mubarakshina, M.M.; Kozuleva, M.A.; Rudenko, N.N.; Naydov, I.A.; Klenina, I.B.; Ivanov, B.N. Photosynthetic electron flow to oxygen and diffusion of hydrogen peroxide through the chloroplast envelope via aquaporins. Biochim. Biophys. Acta 2012, 1817, 1314–1321. [Google Scholar] [CrossRef]
  161. Sewelam, N.; Jaspert, N.; Van Der Kelen, K.; Tognetti, V.B.; Schmitz, J.; Frerigmann, H.; Stahl, E.; Zeier, J.; Van Breusegem, F.; Maurino, V.G. Spatial H2O2 signaling specificity: H2O2 from chloroplasts and peroxisomes modulates the plant transcriptome differentially. Mol. Plant. 2014, 7, 1191–1210. [Google Scholar] [CrossRef]
  162. Cheeseman, J.M. Hydrogen peroxide and plant stress: A challenging relationship. Plant Stress 2007, 1, 4–15. [Google Scholar]
  163. Farooq, M.; Rehman, A.; Wahid, A.; Siddique, K.H.M. Photosynthesis under heat stress. In Handbook of Photosynthesis, 3rd ed.; Pessarakli, M., Ed.; CRC Press Taylor & Francis: Abingdon, UK, 2016; pp. 697–701. [Google Scholar]
  164. Feller, U.; Crafts-Brandner, S.J.; Salvucci, M.E. Moderately high temperatures inhibit ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) activase-mediated activation of Rubisco. Plant Physiol. 1998, 116, 539–546. [Google Scholar] [CrossRef]
  165. Salvucci, M.E.; Crafts-Brandner, S.J. Mechanisms for deactivation of rubisco under moderate heat stress. Physiol. Plant. 2004, 122, 513–519. [Google Scholar] [CrossRef]
  166. Perdomo, J.A.; Capo-Bauca, S.; Carmo-Silva, E.; Galmés, J. Rubisco and rubisco activase play an important role in the biochemical limitations of photosynthesis in rice, wheat, and maize under high temperature and water deficit. Front. Plant Sci. 2017, 8, 490. [Google Scholar] [CrossRef]
  167. Mullineaux, P.; Karpinski, S. Signal transduction in response to excess light: Getting out of the chloroplast. Curr. Opin. Plant Biol. 2002, 5, 43–48. [Google Scholar] [CrossRef]
  168. Hatier, J.-H.B.; Gould, K.S. Foliar anthocyanins as modulators of stress signals. J. Theor. Biol. 2008, 253, 625–627. [Google Scholar] [CrossRef]
  169. De la Haba, P.; De la Mata, L.; Molina, E.; Agüera, E. High temperature promotes early senescence in primary leaves of sunflower (Helianthus annuus L.) plants. Can. J. Plant Sci. 2014, 94, 459–669. [Google Scholar] [CrossRef]
  170. Li, B.; Fan, R.; Guo, S.; Wang, P.; Zhu, X.; Fan, Y.; Chen, Y.; He, K.; Kumar, A.; Shi, J.; et al. The Arabidopsis MYB transcription factor, MYB111 modulates salt responses by regulating flavonoid biosynthesis. Environ. Exp. Bot. 2019, 166, 103807. [Google Scholar] [CrossRef]
  171. Gayomba, S.R.; Muday, G.K. Flavonols regulate root hair development by modulating accumulation of reactive oxygen species in the root epidermis. Development 2020, 147, dev185189. [Google Scholar] [CrossRef] [PubMed]
Antioxidants 09 01098 g001
Figure 1. Flavonoids wxcluively accumulate in P. latifolia leaves. (A) Imaging of the ratio of fluorescence intensity at 580 nm (F580, flavonoid fluorescence) to fluorescence at 470 nm (F470, hydroxycinnamate fluorescence) of a Naturstoff-stained cross-section excited at 365 nm. (B) and (D) False-colour F580 images of the glandular trichome (denoted by the arrow in A), assigning the yellow channel to F580. (C) Three-dimensional false colour image of the cross section in (A). Highest values of F580/F470 in the glandular trichome (white arrows in A and C) indicates hydroxycinnamates do not appreciably accumulate in this organ. Methodological details given in Agati et al. [14].
Figure 1. Flavonoids wxcluively accumulate in P. latifolia leaves. (A) Imaging of the ratio of fluorescence intensity at 580 nm (F580, flavonoid fluorescence) to fluorescence at 470 nm (F470, hydroxycinnamate fluorescence) of a Naturstoff-stained cross-section excited at 365 nm. (B) and (D) False-colour F580 images of the glandular trichome (denoted by the arrow in A), assigning the yellow channel to F580. (C) Three-dimensional false colour image of the cross section in (A). Highest values of F580/F470 in the glandular trichome (white arrows in A and C) indicates hydroxycinnamates do not appreciably accumulate in this organ. Methodological details given in Agati et al. [14].
Antioxidants 09 01098 g001
Antioxidants 09 01098 g002
Figure 2. Mere UV-screening effects of flavonoids in non-glandular trichomes of Cistus salvifolius leaves. (A) View of a leaf cross-section in Cryo Scan Electron Microscopy (Cryo-SEM). (B) Fluorescence image recorded at 565-570 nm of cross-section stained with Naturstoff reagent, and excited at 488 nm. Flavonoids are coumaroyl derivatives of kaempferol 3-O-glucoside and are associated with the cell wall of the trichome arms, as detailed in Tattini et al. [42]. The occurrence of p-coumaric (max. absorbance at 315 nm) and kaempferol moieties (max absorbance at 351 nm) offers the best screening against UV-B and UV-A radiation.
Figure 2. Mere UV-screening effects of flavonoids in non-glandular trichomes of Cistus salvifolius leaves. (A) View of a leaf cross-section in Cryo Scan Electron Microscopy (Cryo-SEM). (B) Fluorescence image recorded at 565-570 nm of cross-section stained with Naturstoff reagent, and excited at 488 nm. Flavonoids are coumaroyl derivatives of kaempferol 3-O-glucoside and are associated with the cell wall of the trichome arms, as detailed in Tattini et al. [42]. The occurrence of p-coumaric (max. absorbance at 315 nm) and kaempferol moieties (max absorbance at 351 nm) offers the best screening against UV-B and UV-A radiation.
Antioxidants 09 01098 g002
Antioxidants 09 01098 g003
Figure 3. Flavonoids occur in different organs, cells and sub-cellular organelles. (A) Confocal laser scanning microscopy of Ligustrum vulgare leaves showing the accumulation of flavonoids in glandular trichomes (solid arrow), the vacuoles of mesophyll cells (dotted arrows) and the guard cells of stomata (*). (B) Flavonoids in mesophyll cells have not unique vacuolar accumulation, but are additionally associated to chloroplasts. (C) A 3D view of mesophyll cells: flavonoids accumulate in different layers of palisade tissue. (D) An enlarged view of flavonoid distribution in mesophyll cells, showing the location of flavonoids in the cell nucleus (enclosed in the circle). Tissue specimen were stained with Naturstoff reagent, excited at 488 nm and fluorescence recorded over both the 562–646 nm and the 687–757 nm waveband to detect flavonoids and chlorophyll, respectively. Pictures are merged images of F562-646 and F687-757.
Figure 3. Flavonoids occur in different organs, cells and sub-cellular organelles. (A) Confocal laser scanning microscopy of Ligustrum vulgare leaves showing the accumulation of flavonoids in glandular trichomes (solid arrow), the vacuoles of mesophyll cells (dotted arrows) and the guard cells of stomata (*). (B) Flavonoids in mesophyll cells have not unique vacuolar accumulation, but are additionally associated to chloroplasts. (C) A 3D view of mesophyll cells: flavonoids accumulate in different layers of palisade tissue. (D) An enlarged view of flavonoid distribution in mesophyll cells, showing the location of flavonoids in the cell nucleus (enclosed in the circle). Tissue specimen were stained with Naturstoff reagent, excited at 488 nm and fluorescence recorded over both the 562–646 nm and the 687–757 nm waveband to detect flavonoids and chlorophyll, respectively. Pictures are merged images of F562-646 and F687-757.
Antioxidants 09 01098 g003
Antioxidants 09 01098 g004
Figure 4. Flavonoids occur in stomata guard cells and chloroplasts. (A) Fluorescence image of Naturstoff-stained abaxial leaf surface excited at 365 nm and fluorescence image acquired at 580 nm. (B). Confocal laser scanning (CLS) 3D image showing flavonoids (yellow fluorescence recorded over 562–646 nm waveband) and chlorophyll (red fluorescence recorded over the 687–757 nm waveband), respectively, in stomata guard cells under 488 nm excitation. Distribution of yellow fluorescence is consistent with a cytoplasmic location of flavonoids (C) A CLS 3D view of palisade mesophyll cells showing the distribution of flavonoids in the vacuole and in the chloroplasts. (D) Profiles of fluorescence intensity of chlorophyll and flavonoids throughout the entire cell as shown by the arrow in (C), showing the co-localization of chlorophyll and flavonoid fluorescence.
Figure 4. Flavonoids occur in stomata guard cells and chloroplasts. (A) Fluorescence image of Naturstoff-stained abaxial leaf surface excited at 365 nm and fluorescence image acquired at 580 nm. (B). Confocal laser scanning (CLS) 3D image showing flavonoids (yellow fluorescence recorded over 562–646 nm waveband) and chlorophyll (red fluorescence recorded over the 687–757 nm waveband), respectively, in stomata guard cells under 488 nm excitation. Distribution of yellow fluorescence is consistent with a cytoplasmic location of flavonoids (C) A CLS 3D view of palisade mesophyll cells showing the distribution of flavonoids in the vacuole and in the chloroplasts. (D) Profiles of fluorescence intensity of chlorophyll and flavonoids throughout the entire cell as shown by the arrow in (C), showing the co-localization of chlorophyll and flavonoid fluorescence.
Antioxidants 09 01098 g004
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Agati, G.; Brunetti, C.; Fini, A.; Gori, A.; Guidi, L.; Landi, M.; Sebastiani, F.; Tattini, M. Are Flavonoids Effective Antioxidants in Plants? Twenty Years of Our Investigation. Antioxidants 2020, 9, 1098. https://doi.org/10.3390/antiox9111098

AMA Style

Agati G, Brunetti C, Fini A, Gori A, Guidi L, Landi M, Sebastiani F, Tattini M. Are Flavonoids Effective Antioxidants in Plants? Twenty Years of Our Investigation. Antioxidants. 2020; 9(11):1098. https://doi.org/10.3390/antiox9111098

Chicago/Turabian Style

Agati, Giovanni, Cecilia Brunetti, Alessio Fini, Antonella Gori, Lucia Guidi, Marco Landi, Federico Sebastiani, and Massimiliano Tattini. 2020. "Are Flavonoids Effective Antioxidants in Plants? Twenty Years of Our Investigation" Antioxidants 9, no. 11: 1098. https://doi.org/10.3390/antiox9111098

APA Style

Agati, G., Brunetti, C., Fini, A., Gori, A., Guidi, L., Landi, M., Sebastiani, F., & Tattini, M. (2020). Are Flavonoids Effective Antioxidants in Plants? Twenty Years of Our Investigation. Antioxidants, 9(11), 1098. https://doi.org/10.3390/antiox9111098

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop