Sustainable Soil Management: Effects of Clinoptilolite and Organic Compost Soil Application on Eco-Physiology, Quercitin, and Hydroxylated, Methoxylated Anthocyanins on Vitis vinifera

Climate change and compostinS1g methods have an important junction on the phenological and ripening grapevine phases. Moreover, the optimization of these composting methods in closed-loop corporate chains can skillfully address the waste problem (pomace, stalks, and pruning residues) in viticultural areas. Owing to the ongoing global warming, in many wine-growing regions, there has been unbalanced ripening, with tricky harvests. Excessive temperatures in fact impoverish the anthocyanin amount of the must while the serious water deficits do not allow a correct development of the berry, stopping its growth processes. This experiment was created to improve the soil management and the quality of the grapes, through the application of a new land conditioner (Zeowine) to the soil, derived from the compost processes of industrial wine, waste, and zeolite. Three treatments on a Sangiovese vineyard were conducted: Zeowine (ZW) (30 tons per ha), Zeolite (Z) (10 tons per ha), and Compost (C) (20 tons per ha). During the two seasons (2021–2022), measurements were made of single-leaf gas exchange and leaf midday water potential, as well as chlorophyll fluorescence. In addition, the parameters of plant yield, yeast assimilable nitrogen, technological maturity, fractionation of anthocyanins (Cyanidin-3-glucoside, Delphinidin-3-glucoside, Malvidin-3-acetylglucoside, Malvidin-3-cumarylglucoside, Malvidin-3-glucoside, Peonidin-3-acetylglucoside, Peonidin-3-cumarylglucoside, Peonidin-3-glucoside, and Petunidin-3-glucoside), Caffeic Acid, Coumaric Acid, Gallic Acid, Ferulic Acid, Kaempferol-3-O-glucoside, Quercetin-3-O-rutinoside, Quercetin-3-O-glucoside, Quercetin-3-O-galactoside, and Quercetin-3-O-glucuronide were analyzed. The Zeowine and zeolite showed less negative water potential, higher photosynthesis, and lower leaf temperature. Furthermore, they showed higher levels of anthocyanin accumulation and a lower level of quercetin. Finally, the interaction of the beneficial results of Zeowine (soil and grapevines) was evidenced by the embellishment of the nutritional and water efficiency, the minimizing of the need for fertilizers, the closure of the production cycle of waste material from the supply chain, and the improvement of the quality of the wines.


Introduction
Climate change and the problem of corporate sustainability (organic and closed-loop companies) are two highly topical and relevant issues of the twenty-first century [1,2].
The optimization of the composting methods in closed-loop corporate chains can skillfully address the waste problem (pomace, stalks, and pruning residues) in viticultural areas [3,4]. The wine industry produces enormous quantities of waste every year along the hydrolysis of glycosides with aglycon supersaturation [41]) and a lesser proportion of Malvidin-3-cumarylglucoside, compared to the shaded ones. In warm and arid climates, overhead bunch degree exposure is not helpful to excellent anthocyanin storage and synthesis [42].
Therefore, a polite approach to water resources turns out to be a component of primary importance for plant and berry development. For these reasons, zeolite soil application was investigated in a lot of research, in which the effects on land hydraulic capacities were fixed [43]. In fact, Bernardi et al. (2013) [44] indicated that joining zeolitic Brazilian sedimentary rocks to soils can sharpen their water-holding capacity (WHC). These hydrated tectoaluminosilicates of alkaline/alkaline earth elements [45] are retained as an important natural inorganic soil improver that can enhance the land's physical/chemical properties (i.e., infiltration rate [46], cation exchange capacity [47], and saturated hydraulic conductivity [48]). It was made extensively clear that soil adaptation using zeolitic equipment refines water holding and minimizes the percolation which lowers water enforcement in agricultural management [49][50][51][52].
Considering the above, this experiment was created to improve soil management, the well-being of the vine, and the quality of the grapes through the application to the soil of a new land conditioner called "Zeowine", derived from the compost processes of industrial wine, waste, and zeolite. The interaction of the beneficial results of Zeowine (soil + grapevines) was evidenced by the embellishment of nutritional and water efficiency, the minimizing of the need for fertilizers, the closure of the production cycle of waste material from the supply chain, and the improvement of the quality of the wines. antheraxanthin and flavonol concentrations; in the Cabernet Sauvignon, it swayed the abscisic acid metabolic pathway (9cis-epoxy carotenoid dioxygenase transcript copiousness) [40]. With high ambient light levels, the berries had the maximum Quercetin-3-glucoside levels (a harmful compound in Sangiovese grapes with a possible precipitate in the wine after the hydrolysis of glycosides with aglycon supersaturation [41]) and a lesser proportion of Malvidin-3-cumarylglucoside, compared to the shaded ones. In warm and arid climates, overhead bunch degree exposure is not helpful to excellent anthocyanin storage and synthesis [42].

Weather Parameters
Therefore, a polite approach to water resources turns out to be a component of primary importance for plant and berry development. For these reasons, zeolite soil application was investigated in a lot of research, in which the effects on land hydraulic capacities were fixed [43]. In fact, Bernardi et al. (2013) [44] indicated that joining zeolitic Brazilian sedimentary rocks to soils can sharpen their water-holding capacity (WHC). These hydrated tectoaluminosilicates of alkaline/alkaline earth elements [45] are retained as an important natural inorganic soil improver that can enhance the land's physical/chemical properties (i.e., infiltration rate [46], cation exchange capacity [47], and saturated hydraulic conductivity [48]). It was made extensively clear that soil adaptation using zeolitic equipment refines water holding and minimizes the percolation which lowers water enforcement in agricultural management [49][50][51][52].
Considering the above, this experiment was created to improve soil management, the well-being of the vine, and the quality of the grapes through the application to the soil of a new land conditioner called "Zeowine", derived from the compost processes of industrial wine, waste, and zeolite. The interaction of the beneficial results of Zeowine (soil + grapevines) was evidenced by the embellishment of nutritional and water efficiency, the minimizing of the need for fertilizers, the closure of the production cycle of waste material from the supply chain, and the improvement of the quality of the wines.  Daily minimum, average, and maximum air temperatures were registered in both seasons of 2021-2022 (from April to September). The 2022 grape harvest unfolded as being more scorching and less rainy during the trial months (from April to July). The rainfall summation was as follows: 128

Ecophysiological Survey (Gaseous Exchange), Midday Stem Water Potential, and Leaf Chlorophyll a Fluorescence
The Vitis vinifera ecophysiological parameters according to three different land treatments (Zeowine, zeolite, and compost) are indicated in  Daily minimum, average, and maximum air temperatures were registered in both seasons of 2021-2022 (from April to September). The 2022 grape harvest unfolded as being more scorching and less rainy during the trial months (from April to July). The rainfall summation was as follows: 128 The Vitis vinifera ecophysiological parameters according to three different land treatments (Zeowine, zeolite, and compost) are indicated in  Stomatal conductance and net photosynthesis follow the seasonal trend. Significant differences in net photosynthesis and stomatal conductance during the seasons were found. Generally, no differences were ever found between the Zeowine and the zeolite treatments. Observing the 2022 vintage in stomatal conductance, differences emerge as early as June. In both years, the compost recorded lower values in net photosynthesis in each measure of the season (2021 and 2022).
The transpiration rates reflect the trend of temperatures and rainfall during the two years. Particularly in the hottest moments, significant differences in leaf temperatures, eWUE, and transpiration during the seasons were found. During the less torrid vintage, there were almost never differences between the treatments in the transpiration. Significantly higher leaf temperatures were found in the compost treatment (from June to August 2021 and 2022).
In the Zeowine and zeolite grapevines in both vintages, higher values of Fv/Fm were customarily found. No differences were recorded in June 2021 and 2022 and in September 2022. Stomatal conductance and net photosynthesis follow the seasonal trend. Significant differences in net photosynthesis and stomatal conductance during the seasons were found. Generally, no differences were ever found between the Zeowine and the zeolite treatments. Observing the 2022 vintage in stomatal conductance, differences emerge as early as June. In both years, the compost recorded lower values in net photosynthesis in each measure of the season (2021 and 2022). ). Data (mean ± SE, n = 10) were subjected to one-way ANOVA. The bars represent the standard deviation. Different letters indicate significant differences between Zeowine, Zeolite, and Compost (LSD test, p ≤ 0.05).   . Data (mean ± SE, n = 10) were subjected to one-way ANOVA. The bars represent the standard deviation. Different letters indicate significant differences between Zeowine, Zeolite, and Compost (LSD test, p ≤ 0.05).
The transpiration rates reflect the trend of temperatures and rainfall during the two years. Particularly in the hottest moments, significant differences in leaf temperatures, eWUE, and transpiration during the seasons were found. During the less torrid vintage, there were almost never differences between the treatments in the transpiration. Significantly higher leaf temperatures were found in the compost treatment (from June to August 2021 and 2022). ). Data (mean ± SE, n = 10) were subjected to one-way ANOVA. The bars represent the standard deviation. Different letters indicate significant differences between Zeowine, Zeolite, and Compost (LSD test, p ≤ 0.05).
In the Zeowine and zeolite grapevines in both vintages, higher values of Fv/Fm were customarily found. No differences were recorded in June 2021 and 2022 and in September 2022.  Significant discrepancies in the water potential parameters (Ψstem) in the 2021-2022 seasons were registered. The compost treatment from July showed clearly more negative values of water potential. The 2022 vintage was classified as the driest and most torrid of the two years, reaching water potentials of less than −2.0 MPa (August 2022). During 2021, the following decrements were found in the compost compared to the Zeowine and the zeolite, respectively: 10.71% and 13.87% (28 June), 8.50% and 9.62% (12 July), 10.19% and 11.61% (29 July), 6.32% and 6.93% (18 August), 8.54% and 13.20% (31 August), and 7.54% and 10.00% (14 September). During 2022, the following decrements were found in the compost compared to the Zeowine and the zeolite, respectively: 2.38% and 2.87% (27 June), 8.44% and 9.86% (4 July), 12.37% and 10.31% (18 July), 17.88% and 18.39% (4 August), 28.49% and 23.96% (17 August), and 27.77% and 24.89% (5 September). Significant discrepancies in the water potential parameters (Ψstem) in the 2021-2022 seasons were registered. The compost treatment from July showed clearly more negative values of water potential. The 2022 vintage was classified as the driest and most torrid of the two years, reaching water potentials of less than −2.0 MPa (August 2022). During 2021, the following decrements were found in the compost compared to the Zeowine and the zeolite, respectively: 10.71% and 13.87% (28 June), 8.50% and 9.62% (12 July), 10.19% and 11.61% (29 July), 6.32% and 6.93% (18 August), 8.54% and 13.20% (31 August), and 7.54% and 10.00% (14 September). During 2022, the following decrements were found in the compost compared to the Zeowine and the zeolite, respectively: 2.38% and 2.87% (27 June), 8.44% and 9.86% (4 July), 12.37% and 10.31% (18 July), 17.88% and 18.39% (4 August), 28.49% and 23.96% (17 August), and 27.77% and 24.89% (5 September). Basically, no difference was found between the Zeowine and the zeolite. Instead, differences were seen between the compost and the other two treatments. The compost treatment proved to be the one characterized by a smaller berry, lower sugar content, and higher acidic content. Regarding the weight of the berry, the following increases in Zeowine and zeolite were found compared to the compost treatment on the harvest date: 29.69% and 18.62% (14 September 2021) and 11.70% and 12.89% (5 September 2022). While in the sugar content, the following increases in Zeowine and zeolite were found compared to the compost treatment on the harvest date: 10.52% and 11.51% (14 September 2021) and 8.32% and 8.60% (5 September 2022).
During harvest, the yeast assimilable nitrogen content proved to be significantly higher in the zeolite treatment in 2021 (117 mg/L) and in the Zeowine treatment in 2022 (164 mg/L).

Principal Component Analysis
The PCA analyses were examined in order to synthetize all the details in an individual elucidatory graph. The PCA described almost 40% of the variability of the data (Figures 9-12). As is illustrated, the PCA bracketed the variables into three specific clusters, depending on their bearing during the season.
The compost treatment was to the upper part of the distribution and positively related to the transpiration and leaf temperature and negatively related to eWUE and Fv/Fm (Dim1 45.2%). Instead, PC 2 (Dim2) explained 24.4% of the data variability.
The Zeowine and zeolite treatments were to the left part of the distribution and negatively related to PN and eWUE and positively related to TLeaf (Dim1 41.0%). Instead, PC 2 (Dim2) explained 28.7% of the data variability.
The compost treatment was to the down part of the distribution and positively related to the phenolic parameters and negatively related to acidity, Fv/Fm, E, and water potential (Dim1 43.6%). Instead, PC 2 (Dim2) explained 18.7% of the data variability.
The Zeowine and zeolite treatments were to the right part of the distribution and negatively related to E, acidity, and TLeaf and positively related to the phenolic parameters (Dim1 47.6%). Instead, PC 2 (Dim2) explained 13.9% of the data variability. lactoside, and Quercetin-3-O-glucuronide). Irrespective of the treatment, in 2022 the amount of quercetin was more abundant with respect to 2021.

Principal Component Analysis
The PCA analyses were examined in order to synthetize all the details in an individual elucidatory graph. The PCA described almost 40% of the variability of the data (Figures 9-12). As is illustrated, the PCA bracketed the variables into three specific clusters, depending on their bearing during the season.   The compost treatment was to the down part of the distribution and positively related to the phenolic parameters and negatively related to acidity, Fv/Fm, E, and water potential (Dim1 43.6%). Instead, PC 2 (Dim2) explained 18.7% of the data variability. Figure 11. PCA ecophysiology and grape parameters 2021 season. PCA of the following variables (29 July, 18 August, 31 August, and 14 September): stem midday water potential, net photosynthesis, transpiration, leaf temperature, stomatal conductance, the fluorescence of chlorophyll, water use efficiency, sugar content, pH, acidity, total and extractable polyphenol, total and extractable anthocyanins, and YAN. The Zeowine and zeolite treatments were to the right part of the distribution and negatively related to E, acidity, and TLeaf and positively related to the phenolic parameters (Dim1 47.6%). Instead, PC 2 (Dim2) explained 13.9% of the data variability.

Production
The production of the treatments was measured at the harvest stage (14 September 2021 and 5 September 2022, Figure 13).  17 August, and 5 September): stem midday water potential, net photosynthesis, transpiration, leaf temperature, stomatal conductance, the fluorescence of chlorophyll, water use efficiency, sugar content, pH, acidity, total and extractable polyphenol, total and extractable anthocyanins, and YAN.

Production
The production of the treatments was measured at the harvest stage (14 September 2021 and 5 September 2022, Figure 13). In both seasons (2021 and 2022), no difference in the number of bunches was monitored. The Zeowine and zeolite treatments differed significantly from the compost one by the following factors: total yield per grapevine and bunch weight. The lower values of these two parameters were noted in the compost one.

Discussion
Global warming and inaccurate agricultural habits are the main factors biassing berries and wine esteem in Mediterranean viniculture [53]. These factors can provoke a soluble solid discharge, together with a decline in anthocyanin content, acidity, and productivity [54]. The aftermath produces slacking (or stuck) fermentations and economic shrinkage in the winery [55]. Furthermore, insensitivity and non-respect for the vineyard ecosystem conservation induced by agronomic choices not aimed at recycling or revaluing the product lead to environmental pollution (the use of synthetic products) [56] on one hand and on the other to greater waste production (the non-closed loop approach) [57,58]. This experimentation was created to improve vine welfare and berry quality through the Zeowine application, a new amendment derived from the compost processes of industrial wine waste and zeolite.
In our study, it was confirmed that environmental agents, such as temperature, soil moisture, and light radiation affect water potential [59,60]. In the water potential parameter, in both seasons, significant differences were recorded between the compost and the two treatments with zeolite owing to the clinoptilolite property (i.e., augmented H 2 O retention capacity [61]). The compost treatment during the driest times recorded the following negative percentage decreases compared to the other two (Zeowine and zeolite): vintage 2021, −10.19% and −11.61% on 29 July, −6.32% and −6.94% on 18 August; vintage 2022, −12.39% and −10.31% on 18 July, 17.88% and −18.39% on 4 August. In fact, we suppose that thanks to the zeolitic ability to retain and release water [62] (up to 60% of its weight) in a reversible way without changing its microporous and crystalline structure [63], the treatments with clinoptilolite alleviated the unfavorable results of water stress thanks to the better management of rainwater and water reserves by increasing the availability of water for the vines [64] in drought conditions [65].  [66]; these markers happen in the xylem vessels when the atmospheric request cannot be satisfied by the water content of the vineyard soil. This generates a tightness inside the tracheid or xylem vessel and an excess of gas molecules from the water (i.e., hydraulic conductivity dwindling) [67]. Moreover, we hypothesized an association with advanced VPD (vapor pressure deficit) that leads to reduced carbon assimilation (lower stomatal conductance) [68] without necessarily reducing the transpiration (E) rate to the same measure. On the other hand, Scholasch et al. (2009) [69] highlighted that for a given water supply rank, elevated VPD rates tend to enhance grapevine transpiration when solar radiation is continuous. In Spain, with arid regimes, Balbontín (2015) [70] reported morning minimum (0.5-1.5 kPa data range) and maximum noon data (4.5-6.0 kPa).
Overall, the photosynthesis rates were lesser in the non-treated plants compared with the Zeowine and zeolite grapevines. The desirable rates of PN per unit/leaf/area for basal health in uncovered vine leaves fluctuate from 6 to 18 µmol m −2 s −1 [71,72]. During the elevated temperature spell, the PN in the compost leaves declined remarkably; it was shown that as a consequence of the high radiation a 30-50% drop in PN can occur, with markedly declining rates during the occurrence of heatwaves [73,74]. Although there was also a physiological declension in photosynthesis in the Zeowine and zeolite plants, this flexure did not affect the performance of the electron transport chain. In fact, the monitored values did not reach stress thresholds, probably thanks to the help of the zeolite [75] being able to soak up the carbon dioxide molecules [76], increasing the total CO 2 adjacent to the stomata. Furthermore, we surmise that this improvement was also related to the mitigating outcome of the zeolite at high leaf temperatures [77], which would negatively influence the trek of the carbohydrates from the leaf by affecting their photosynthetic activity (feedback down-regulation) [78].
Transpiration during the hottest periods also showed differences; Zeowine and zeolite were the treatments with the highest transpiration rate. Even though a full mechanistic comprehension of the transpiration rate under elevated temperature stress status is missing, the literature states that such a rejoinder involves different biophysical or physiological processes [79], such as a modification in membrane permeability [80], a rise in cuticle permeability [81], and a lower water viscosity [82]. As demonstrated by Naveed et al. (2020) [83], in their work developed to assess the occurrences of an endophytic bacterium (Caulobacter sp.) added to the zeolite on Sesamum indicum L., the gaseous exchange values (e.g., transpiration) and water connections were tightened by the co-application of compost and zeolite.
A further limitation was monitored in the compost treatment. The significant abatement in the Fv/Fm (chlorophyll fluorescence parameter) resulted in an increase in energy dissipation in the antenna complex with the probable degradation of the D1 protein [84] (reduction in photosystem II efficiency, i.e., photoinhibition) [85].
As indicated in several works, technological maturity was swayed by water stress (a significant difference in midday water potential) [86] and by temperature stress (a significant difference in leaf temperature) [87]. The results found by Wang et al. (2003) [88] showed that high water deficiency obstructs sugar unloading in the berry. Additionally, the discharging of sugar phloem during the maturation is through the apoplastic system, and this scheme demands energy input [89]. In accordance with these explanations, the compost treatment showed a more delayed ripening than the other two: a lower sugar content, an acidic content unsuitable for a grape harvest (10.14 g/L during the 2021 harvest against the canonical 5-8 g/L) (Frost et al., 2017), and undeveloped berry weight. The disposability of water influences the sugar concentration of the berries in a different and complex way since, on the one hand, a greater availability leads to a major concentration of sugar due to a greater PN activity [90] and, on the other hand, it can lead to a lower concentration by dilution with the berry growth [91]. After an alteration of the water supply, even in the most recent genomic and transcriptomic approach (deep RNA sequencing approach; [92]), when sampling is performed on the same date [93], as in our trial, gene expression modifications were reported. Our results are confirmed in the test realized by Santesteban and Royo (2006) [94], where in order to reach a correct maturation it is necessary to have ratios between the leaf area and the production of at least 5-10 cm 2 /g up to 15-17 cm 2 /g to allow the correct photosynthesis.
The plants that had clinoptilolite applications showed a greater weight of the berry, confirming the beneficial effect of these tectoaluminosilicates on production [95,96]. Probably in addition to the better management of the water resource, the zeolites increased the substrate cation exchange capacity [97], allowing a better and gradual granting of nutrients [98,99] and avoiding losses due to leaching [100]. The effect on the weight of the berries involves cell division or/and cell expansion modifications [101].
The yeast assimilable nitrogen amount denotes changes according to the year; only during 2022, the values reached congruous thresholds to avoid the additions of inorganic nitrogen (diammonium phosphate DAP) or inorganic ammonia added to the primary amino nitrogen (AMM + PAN) [102] (> 140 mgNL − 1 ; necessary for efficient fermentation) [103]. The zeolite intake improved the YAN concentrations in both growing seasons. This result is attributable to the zeolitic ability to exchange cations such as the ammonium cation [104] (NH4+), one of the main parameters soaked up by the plants' plasma membrane [105].
As suggested by González-Sanjosé and Diez (1992) [106], berry skin sugars show a role as regulators in anthocyanin synthesis and, generally, of phenols. We found that the treatments (Zeowine and zeolite) with greater sugar accumulation in parallel recorded a greater content of polyphenols and anthocyanins (both total and extractable). In general, comparing the two vintages, during 2022 we measured lower absolute values compared to the less torrid vintage. In fact, the temperature (high and low) during maturation, particularly during the 3 • stage, presumably conditioned the abscisic acid degradation and production in the berry skins; the endogenous abscisic acid levels sway the VvmybA1 gene expression that drives anthocyanin biosynthetic expression [107]. In addition, high nocturnal temperatures can quell the gene expression of dihydroflavonol 4-reductase, leucoanthocyanidin dioxygenase, chalcone synthase, flavanone 3-hydroxylase, and flavonoid 3-O-glucosyltransferase, causing minor expression levels of anthocyanin biosynthetic genes during the beginning of ripening [108]. Moreover, another factor in addition to anthocyanin degradation could be represented by the mRNA transcription inhibition of the anthocyanin biosynthetic genes [109].
The 2022 severe climatic context may have caused a superior ratio of methoxylated/ non-methoxylated anthocyanins in berry skins with respect to 2021 (17 August and 3 September 2022). In fact, high temperature and solar radiation precipitate the changeover from the hydroxylated (delphinidin and cyanidin) [113] to the methoxylated derivatives of anthocyanins (malvidin, petunidin, and peonidin) [114]. The methoxylation activity depicts a metabolic process that affects the stability of the different anthocyanins, giving them minor susceptibility to non-enzymatic or enzymatic oxidation under tricky and stressful regimes [115], stabilizing the phenolic B ring and causing a red shift in the absorption spectrum [116]. The treatments, generally, did not sway the ratio between methoxylated and non-methoxylated. Contrary to what Tarara et al. (2008) [117] demonstrated, the absolute concentrations of the dihydroxylated anthocyanins (cyanidin and peonidin; red anthocyanins) and the trihydroxylated (delphinidin, malvidin, and petunidin; purple and blue anthocyanins) [118] did not undergo substantial changes in either the treatment or the vintage effect.
Among the non-flavonoid polyphenols, gallic acid (a hydroxybenzoic acid-GA; 3_4_5-trihydroxy benzoic acid) [119], which is chiefly stored as galloylated flavan-3ols [120], showed an increment during the 2022 season for all treatments. In fact, its content is biased by preharvest environmental status [121]. Contrary to what Del Castillo Alonso et al. (2020) [122] found, we saw that hydroxybenzoic acids were probably susceptible to temperature variations. Additionally, in agreement with Xi et al. (2010) [123], their content was enhanced by improving land management habits (at harvests, ZW and Z showed superior content). Therefore, these applications could increase the co-pigmentation between GA and malvidin-3-Oglucoside in red wine (stabilizing role) [124].
Four glycosylated forms of quercetin (flavonols class) (glucosides, galactosides, rutinosides, and glucuronides) as 3-O-glycosylated were found [125]. In both years, significantly higher doses of quercetin in the compost treatment were found. We suppose that this high quantity was correlated to their biosynthesis being influenced by temperature stress and sunlight exposure; in fact, the concentration was found to be 4-8 times less in the shaded cluster [126] (photo-protector role). However, considering the recent studies on this compound in Sangiovese grapes [127,128], this increase was found to be depleted in the finished product. Sangiovese wine can produce a quercetin precipitate during its aging from the glycosides hydrolysis (i.e., supersaturation of the aglycons) [41]. Conversely, the grapes that underwent clinoptilolite applications recorded lower quercetin contents.
Many authors showed that the absorption and checked relief of moisture by zeolite ameliorated the growth and plant yield under drought stress conditions [129][130][131]. In conformity with these results, in our experiment we also noticed an increase in production in the Zeowine and zeolite treatments. The greater yield of both vintages was attributed to a greater weight of the bunch and not to a different number of bunches. The clinoptilolite porous framework might have helped to keep the ground moist and ventilated [132] (less compactness and greater humidity in the periods of development of the berry). In addition, it might have retained principal nutrients (N, Mg, P, B, and K) in the root zone [133] for reuse by the vine when requested. Using an experimental randomized block design, ten blocks per treatment were established; every block consisted of 4 rows; 10 vines per treatment were selected for the measurements. The experiment with three treatments, the Zeolite (Z), Compost (C), and Zeowine (ZW), was set up. Zeowine is a product made by combining the properties of zeolite (clinoptilolite) with the stable organic substance of a compost obtained on a company scale from the reuse of processing waste from grapes, pomace, and stalks. CMM provided the wastes from the 2020 and 2021 harvest (grape skins, stalks, and vineyard pruning waste), which were shredded to 4-5 cm and processed for their composting. The optimal dimensions and typology of the zeolite (Zeocel Italia, PI, Italy) to be used for the production of Zeowine was selected (85% clinoptilolite) with a granulometry of 0.2-2.5 mm, which was identified in order to ensure better aeration of the heaps during composting. For the first composting cycle (start of composting, 11/11/2020) CMM proceeded to prepare three different kinds of composting heaps: the 3 heaps of about 9 tons each with zeolite and organic residues at the ratio 1:2.5 w:w of fresh weight; a heap with zeolite and organic residues at the ratio 1:10 w:w of fresh weight; and a control heap (without zeolite). The two additional kinds of composting heaps were prepared with about 2 tons of waste to demonstrate the efficiency of the presence of zeolite at different rates in improving the composting system and the quality of the end product during the whole experimentation, with respect to the control heap without zeolite.

Materials and Methods
On the basis of the results obtained from the first composting cycle at CMM, in the second composting cycle (start of composting, 12/12/2021), the following piles were prepared at CMM: n. 2 piles of about 9 tons each with zeolite and vine wastes at the ratio 1:10 w/w; n. 1 piles of about 9 tons each with zeolite and vine wastes at the ratio 1:2.5 w/w; n. 1 control piles of about 9 tons with 100% vine wastes ( Figure 14). organic residues at the ratio 1:10 w:w of fresh weight; and a control heap (without zeolite). The two additional kinds of composting heaps were prepared with about 2 tons of waste to demonstrate the efficiency of the presence of zeolite at different rates in improving the composting system and the quality of the end product during the whole experimentation, with respect to the control heap without zeolite.
On the basis of the results obtained from the first composting cycle at CMM, in the second composting cycle (start of composting, 12/12/2021), the following piles were prepared at CMM: n. 2 piles of about 9 tons each with zeolite and vine wastes at the ratio 1:10 w/w; n. 1 piles of about 9 tons each with zeolite and vine wastes at the ratio 1:2.5 w/w; n. 1 control piles of about 9 tons with 100% vine wastes ( Figure 14). Briefly, to facilitate the aerobic compost-making success, mechanical turnings were performed every 30 days for the 150 days of composting with periodical irrigations until the moisture content was >40% [134,135]. Briefly, to facilitate the aerobic compost-making success, mechanical turnings were performed every 30 days for the 150 days of composting with periodical irrigations until the moisture content was >40% [134,135].
The temperature of all the heaps rapidly increased from the beginning of the experimentation. In the control heap, the thermophilic phase (temperature higher than 55 • C) was reached after two weeks, while in the heaps with zeolite it was recorded after three-four weeks. A temperature greater than 55 • C during this stage is extremely important to kill the pathogens, thus achieving the sanitization of the raw material [136,137]. The maximum temperature was measured in the control heap after 18 days (65 • C), while in the heaps with zeolite it was reached after about 34-38 days from the beginning of composting (60-63 • C). The thermophilic phase was maintained for 12 days in the control heap (days 16 to 28), for 24 days in the heap with 1:2.5 zeolite:compost (days 24 to 48), and for 32 days in the heap with 1:10 zeolite:compost (days 22 to 54).
Similar results were also reported by Himanen and Hänninen (2009) [138], who claimed that the duration of the thermophilic stage increased from 2 to 3 weeks following the addition of commercial elements (i.e., zeolite, ashes, kaolinite, chalk, and sulfates) to a biowastes + peat mixture.
In the control heap, the temperature decreased and reached the mesophilic stage (temperature lower than 50 • C) after 30 days from the beginning of the composting process. However, this stage was reached after 52 and 64 days in the heaps with zeolite 1:2.5 and 1:10, respectively. During the mesophilic stage, the zeolite heaps showed a higher temperature with respect to the control heap. In fact, Venglovsky et al. 2005 [139] demonstrated that the presence of zeolite during the composting system, enhancing the porosity of the compost, can enable better aeration for metabolic heat generation by aerobic microorganisms with respect to the control heap. At the end of the thermophilic period, from the turning operations, it was possible to observe the actual state of maturation of the material in which neither the grape stalks nor the pomace were still recognizable, and the assumed consistency was that of mature compost. The complete maturation of Zeowine was achieved after roughly 150 days of composting (Table 3). The application of treatments was executed on 1.2 ha of vineyard in production with a spreader manure (Figures 15 and 16) in the spring: Zeowine 30 t/ha, zeolite 10 t/ha, and compost 20 t/ha [140]. A surface tillage (15-20 cm) for the burial of the treatments was carried out. After the date reported in Table 3, 1:2.5 treatments were selected for the experiment. In fact, the objective of the preliminary implemented experiments was to define the best zeolite:compost ratio to be used in the experiment and to scrupulously follow the composting process. The application of treatments was executed on 1.2 ha of vineyard in production with a spreader manure (Figures 15 and 16) in the spring: Zeowine 30 t/ha, zeolite 10 t/ha, and compost 20 t/ha [140]. A surface tillage (15-20 cm) for the burial of the treatments was carried out. After the date reported in Table 3, 1:2.5 treatments were selected for the experiment. In fact, the objective of the preliminary implemented experiments was to define the best zeolite:compost ratio to be used in the experiment and to scrupulously follow the composting process.    The application of treatments was executed on 1.2 ha of vineyard in production with a spreader manure (Figures 15 and 16) in the spring: Zeowine 30 t/ha, zeolite 10 t/ha, and compost 20 t/ha [140]. A surface tillage (15-20 cm) for the burial of the treatments was carried out. After the date reported in Table 3, 1:2.5 treatments were selected for the experiment. In fact, the objective of the preliminary implemented experiments was to define the best zeolite:compost ratio to be used in the experiment and to scrupulously follow the composting process.   The agro-meteorological system Pre-meteo (Mybatec S.R.L., NO, Italy) monitored the main parameters such as rainfall (mm) and air temperatures ( • C).
On the same days, chlorophyll fluorescence (Fv/Fm) was gauged with a fluorometer (Handy-PEA ® , Hansatech Instruments, Norfolk, UK), adapting leaves in the dark for 30 min, following the Maxwell and Johnson calibration [144].

Berry Quality
In each treatment, 100 berries (per replication) were arbitrarily chosen to develop the technological maturity. Firstly, the berries of each treatment were independently weighed with the Kern PCD model (a precision digital scale). The sample was squeezed to analyze the sugar content (expressed in Brix degree), total acidity (expressed in g L-1 tartaric acid), and pH. The following tools and products were employed for technological analysis: a portable optical refractometer (RHA-503), a pH meter (HHTEC), bromothymol blue, glass burettes, and a sodium hydroxide solution (NaOH-0.1 M).
In each treatment, 100 more berries (per replication) were arbitrarily chosen to develop phenolic maturity. Total and extractable polyphenols and total and extractable anthocyanins were estimated by the Glories method [145].
Finally, the cluster number per vine, the weight of the bunch per vine, and the total yield/vine were determined at harvest with a digital scale (VAR model, Italy) (10 grapevines per treatment).

Statistical Analysis
The data and graphs were processed with R version 4_0_3.-RStudio (R Development Core Team) (Tidyverse packages [148]), first with the Shapiro-Wilk and Levene tests, then with one-way ANOVA (p ≤ 0.05). The means comparison was performed with the Tukey HSD test [149] (p ≤ 0.05). PCA [150] (principal component analysis) was exploited to fix the connections among specific variables under investigation and to distinguish between the different treatments [151].

Conclusions
Global warming and inaccurate agriculture can provoke soluble solid discharge, together with a decline in anthocyanin content, acidity, and productivity. Furthermore, non-respect for the vineyard ecosystem conservation induced by agronomic choices not aimed at recycling or revaluing the product leads to environmental pollution on one hand and, on the other, to greater waste production. Our results seem to argue that, in the years marked by low water disposability, severe water deficiency is a narrowing coefficient for the anthocyanin potential in Sangiovese grapes and that Zeowine or zeolite applications could preserve it. The absence of adjuvant in the soil (compost treatment) leads to a lower production (lower yield per vine), characterized by an excess of quercetin in the must and a lower color (slowed ripening). The Zeowine and zeolite treatments were the most balanced ones for the ecophysiological parameters (water potential and net photosynthesis), grape quality (sugar and anthocyanin content), and berry weight.
On the basis of the following achieved results (the demonstrated efficacy of Zeowine in improving the performance of the vineyard soils and the characteristics of the grapes) in operational practice it would be desirable to define and implement protocols for composting waste from the viticultural chain with zeolite and protocols for the application of the product on vine plants by introducing the culture of the circular economy and the valorization of waste in companies in order to promote the environmental, economic, and social sustainability of companies.

Data Availability Statement:
The data presented in this study are available on request from the corresponding author.