Nutrients and Bioactive Molecules of the Early and Late Cultivars of the Treviso Red Chicory (Cichorium intybus L.)

DOI: 10.4236/fns.2017.85031   PDF   HTML   XML   916 Downloads   1,296 Views   Citations

Abstract

The study provides original data on the compositional profile (macronutrients, dietary fiber, mineral and trace elements, bioactive molecules) of an Italian typical plant foods, Treviso Red Cichory, studying the two cultivars (Early, Late) grown following two different traditional cultivation systems. For two consecutive years plants from three growing areas, were studied. Major, significant differences, between Early and Late cultivars, were observed in minerals (Ca, Mg, P), trace elements (Fe, Zn) and bioactive molecules content. The Late cv. was found the richest in minerals and trace elements content than the Early cv., but for Ca. Treviso Red Cichory was found a valuable source of bioactive molecules such as ascorbic acid, anthocyanins and total polyphenols. The Early cv. showed a significantly higher (p < 0.05) ascorbic acid and total anthocyanins content (8.63 and 92.15 mg/100g, respectively) than the Late cv. (6.15 and 24.38 mg/100g, respectively), by contrast total polyphenols content was significantly higher (p < 0.05) in the Late cv. A marked variability in bioactive molecules content among the growing areas was found only for the Late cv. The observed differences between the Early and Late cultivars could be strictly related to the traditional growing systems applied during plant’s growth.

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D’Evoli, L. , Lucarini, M. , Pulgar, J. , Aguzzi, A. , Gabrielli, P. , Azzini, E. and Lombardi-Boccia, G. (2017) Nutrients and Bioactive Molecules of the Early and Late Cultivars of the Treviso Red Chicory (Cichorium intybus L.). Food and Nutrition Sciences, 8, 457-464. doi: 10.4236/fns.2017.85031.

1. Introduction

Italy has a wide range of local plant foods that evoke cultural traditions strongly representative of cultural realities of specific territories. The enhancement of local foods production has increasingly becoming a key component for the improvement of an agro-food system strongly linked to the history and culture of the specific geographical area to which these foods belong. The cultivation of local ecotypes has also a strategic importance for both germoplasm and bio- diversity preservation. An example is the ancient typical Italian red leafy plants belonging to the chicory family (Cichorium intybus L.) locally named “Radicchio”, the Treviso Red Cichory. This local plant food, typical of the North-East Italy, received the attribution of Protected Geographical Indication (PGI) according to EU rules Council Regulation (2081/92) (http://eur-lex.europa.eu) for their pecu- liar cultivation system and the nutritional and organoleptic characteristics. Treviso Red Cichory, named after the Italian town where it comes from, is one of the most distinctive Italian vegetables, it is characterized by elongated red leaves with white ribs and by a typical slightly bitter taste. Two cultivars of Treviso Red Cichory, named Early and Later, are still cultivated according to different tra- ditional growing systems that involve leaf tying during growth; this induce a bleaching process and give rise to the typical red leaves. The Early cultivar is harvested in autumn; the Late cultivar, after the harvest, is placed in vats filled with resurgent running water where new shoots appear, after about twenty days the plants are harvested. Treviso Red Cichory is particularly resistant to low temperature, and it is grown and consumed during the fall and winter seasons.

Data on the qualitative and quantitative composition of nutrients and bioac- tive compounds generally refer almost exclusively to a common cultivar (Radic- chio of Chioggia) used in an extensive crops while, to date, there are no sys- tematic studies representing the compositional figure of the two typical cultivars (Early, Late) of the Treviso Red Cichory. The red color of the leaves of the two Treviso Red Cichory ecotypes originated by the synthesis of anthocyanin pig- ments during growth [1] [2] . D’Evoli et al. [2] found cyanidin-3-O-(6’’malonyl)- glucoside the predominant anthocyanin in Treviso Red Cichory. Studies carried out on the same ecotypes demonstrated that anthocyanins exerted a high peroxyl radical scavenging activity [3] , furthermore D’Evoli et al. [4] highlighted a direct scavenging effect against ROS formation in terms of antioxidant, cytoprotective activities and antiproliferative activity in Caco-2 cell exerted by the red part of the leaf compared with the whole leaf. Azzini et al. [5] found beneficial effects of polyphenol-rich extracts from Treviso Red Cichory in counteracting the oxi- dative stress and cellular damage in in vitro Caco-2 cells model. Furthermore, Treviso Red Cichory also received attention because of its lower nitrate content compared to other leafy vegetables. Lucarini et al. [6] reported a lower nitrate content in Treviso Red Cichory compared to other leafy vegetables suggesting a great influence of the cultivation methods developed for the cultivation of this plant on nitrogen metabolism.

This study was addressed to characterize the compositional profile of Treviso Red Cichory, studying the two cultivars (Early and Later) commonly consumed in Italy. Plants were collected, for two consecutive years, in three different areas of the largest PGI production area and analysed for macronutrients (moisture, ash, protein, lipid, carbohydrates), total dietary fiber, minerals (Ca, Mg, K, P, Na) and trace elements (Fe, Zn, Cu, Mn) content. The study also aimed to evaluate the influence of the two different cultivation methods applied for the growth of the Early and Late cultivars on the concentration of some bioactive molecules, such as ascorbic acid, total anthocyanins and total polyphenols.

2. Materials and Methods

2.1. Materials

Treviso Red Cichory (Cichorium intybus L.) has intense red coloured leaves and white ribs, during the plant growth leaves are tied together. Two cultivars of Treviso Red Cichory were studied: Early cv. which was harvested in field on autumn; Late cv. which was removed from field in late autumn and then transferred in nylon covered “bleaching tanks” with roots bathed in circulating springwater, no fertilizer treatments were applied until plants were harvested after at least 20 days when new roots and new leaves sprouted up.

2.2. Methods

The plants of both the cultivar (Early and Late cv.) of the Treviso Red Cichory were collected for two consecutive years from three respective growing areas: Scorzè, Quinto, Zero Branco. For two consecutive years, 5Kg of plants from each selected area were collected at the harvesting time and delivered to the laboratory. Only the edible portion of the plants was utilised for analysis. Plants from each growing area (500 g) were weighed, washed in distilled water and dried with filter paper. The collected samples were freeze-dried before analysis, or immediately analysed. The analyses were carried out in triplicate. Each experimental data refers to two growing years, a total of six analyses for each area were performed.

Proximate composition: Moisture, protein, lipid and ash were determined according to AOAC methods [7] .

Carbohydrates: carbohydrates were quantified by High-Performance Anion- Exchange Chromatography [8] .

Total dietary fiber: Total dietary fiber was determined following the method of Prosky et al. [9] .

Minerals and Trace Elements: Samples were analyzed for mineral (Ca, Mg, Na, K, P) and trace element (Fe, Zn, Cu, Mn) contents by ICP-OES (Optima 3200XL-Perkin-Elmer) after liquid ashing (4 mL HNO3 + 1 mL H2O2) of the samples in a microwave digestion system (Milestone, 1200 Mega). Standard Reference Materials: Cabbage (IAEA-359, International Atomic Energy Agency Reference Materials Group) and Haricots vert (BCR 383, Community Bureau of Reference, Brussels) were analyzed as a check on the accuracy of the analysis.

Ascorbic acid: Ascorbic acid was determined by RP-HPLC (Waters 996, PAD detector) as described by Valls et al. [10] .

Total Anthocyanins: About 100 g of Treviso red chicory were homogenized with cold methanol (HCl 0.1%) using an Ultra Turrax homogenizer for 5 min. The extraction was repeated until the residue was uncoloured. Subsequently, homogenates were filtered through a Whatman paper under vacuum, and the MeOH in the filtrate was evaporated at 35˚C. Total anthocyanin content was quantified by RP-HPLC (Waters 996, PAD detector) [11] .

Total Polyphenols: Total polyphenols content was determined following the method by Singleton et al. [12] . Gallic acid was used as standard phenol and results expressed as milligrams of gallic acid equivalents (GAE) per 100 g.

2.3. Statistics

All experimental data are presented as the Mean ± Standard Deviation. Statistical analysis was performed utilizing the Student’s t-test; the effect was considered significative at p < 0.05. Data were statistically processed by XL-STAT software.

3. Results

The macronutrients profile and total dietary fiber content of the Early and Late cultivars of Treviso Red Chicory is reported in Table 1. Both the cultivars of the Treviso Red Chicory, as all horticultural products, showed a high water content with an average value of about 92.5%. The ash content was found significantly higher (p < 0.05) in the Early cv. compared with the Late cv. (Table 1).

The protein content of the Early cv. showed not significant differences among the three cultivation areas. By contrast the protein content in the Late cv. was significant different (p < 0.05) among the three cultivation areas, with the highest value in Scorzè area followed by Zero Branco and Quinto areas (Table 1). The differences in protein content was not significant between the two cultivars studied (Table 1). Lipid content was negligible, while charbohydrates, resulted about 2.9 g/100 g in both the cultivars (Table 1). Carbohydrates content resulted significantly higher (p < 0.05) in the Late cv. compared to the Early one; no substantial differences in their content was observed among the growing areas for each cultivar (Table 1). The quantitative analysis of total dietary fiber showed similar amounts in both the Early and the Late cultivars

Table 1. Moisture, ash, protein, lipid charbohydrates and total dietary fiber in the Early and Late cultivars of Treviso Red Chicory (Cichorium intybus L.) (mg/100 g) (f.w.).

Values are the M ± SD of two growing years. Values in the same row (among growing areas) followed by different small letters are statistically significant (p < 0.05). Values (between Mean values) in the same row followed by different capital letters are statistically significant (p < 0.05). *From “Banca dati BIOVITA”-ISBN 978-88-96597-02-6.

(2.4 and 2.1 mg/100g, respectively). No differences minerals and trace ele- ments content within the growing areas of each cultivar were found (Table 2); on the other hand major differences were observed between the Early and Late cultivars (Table 2). Among minerals, Ca content was significantly higher (p < 0.05) in the Early cv. compared to the Late cv. (23.2 and 15.0 mg/100g, res- pectively) (Table 2). By contrast Mg and especially P content was signifi- cangtly higher in the Late cv., P was twice that found in the Early cv. (53 and 25.7 mg/100 g, respectively) (Table 2). The differences observed in both K and Na content between the cultivars were not significant. Among trace elements, significant differences (p < 0.05) in both Fe and Zn content between the two cultivars were found, the Late cv. having the highest value compared with the Early cv. (Table 2).

The study of bioactive molecules of nutritional interest in Treviso Red Chicory included the analysys of ascorbic acid, total anthocyanins and total polyphenols content. Ascorbic acid content in both the cultivars of Treviso Red Chicory from the three growing areas is reported in Figure 1(a). The mean value of the ascorbic acid content in Treviso Red Chicory was 8.6 mg/100g for the Early cv. grown in open field, a value significantly higher (p < 0.05) than that found for the Late cv. (6.15 mg/100g). The effect of the growing areas on ascor- bic acid content was not significant for the Early cv. (Figure 1(a)). On the other hand, the Late cv. showed significant differences (p < 0.05) in ascorbic acid content among the growing areas: Scorzè area showed the highest values (7.15 mg/100g) with respect to Zero Branco (5.67 mg/100g) and Quinto (4.81 mg/100g) areas (Figure 1(a)). Total anthocyanins content in both the cultivars of Treviso Red Chicory from the three respective growing areas is reported in Figure 1(b). As previously found for ascorbic acid, also for total anthocyanins content the mean value for the three growing areas was found significantly higher

Table 2. Minerals and trace elements content (two cultivation years) in the Early and Late cultivars of Treviso Red Chicory (Cichorium intybus L.) (mg/100g) (f.w.).

Values are the M ± SD of two growing years. Values (between Mean values) in the same row followed by different letters are statistically significant (p < 0.05).

(a) (b) (c)

Figure 1. Ascorbic acid, total Anthocyanins and Total polyphenols content in the Early and Late cultivars of Treviso Red Chicory (Cichorium intibus L.) (f.w.). Values are the M ± SD of two growing years.

(p < 0.05) in the Early cv., than in the Late cv. (92.1 and 24.4 mg/100g, res- pectively). Also in this case the Early cv. did not show significant differences in total anthocyanins content among the three growing areas (Figure 1(b)). By contrast significant differences (p < 0.05) in total antocyanins content among the three growing areas of the Late cv. were observed: plants from Scorzè area showed the highest total anthocyanins content (38.15 mg/100g) compared to both Quinto and Zero Branco areas (22.4 and 12.6 mg/100g, respectively) (Fig- ure 1(b)).

A previous HPLC and NMR study (D’Evoli et al., 2012) carried out on the same Treviso Red Chicory cultivars described cyanidin-3-O-(6’’malonyl)-glu- coside as the main anthocyanin in the cultivars, contributing with 70% of total anthocyanins. Total polyphenols content in Treviso Red Chicory is reported in Figure 1c. A marked difference in total polyphenols content between the two cultivars of the Treviso Red Chicory was found. The Early cv. had a very low content in total polyphenols (mean value 0.11 g gallic ac./100 g) compared with Late cv. where a mean value of 0.54 g gallic ac./100 g was found (p < 0.05) (Figure 1(c)). Furthermore, whilst the total polyphenols content was very si- milar in the three areas of the Early cv., the Late cv. showed a high variability in total polyphenols content among the three growing areas, it ranged from 0.47 to 0.64 g gallic ac. /100 g, a significant difference (p < 0.05) was observed only be- tween Scorzè and Quinto areas (Figure 1(c)). Azzini et al. (2015) found, among flavonols, a significantly higher Kaempferol content in the Late cv. compared with the Early one.

4. Conclusion

Our findings provide a fingerprint of the two cultivars, Early and Late, of the Treviso Red Chicory (Chicorium intibus L.), that is a basic element for both recognition of cultivars and market competitiveness. The daily consumption of these traditional red-leafy cultivars significantly contributes to the dietary intake of relevant minerals, trace elements, dietary fiber and of some bioactive mole- cules, such as ascorbic acid, anthocyanins and total polyphenols. The Early and Late cultivars of the Treviso Red Chicory showed substantial differences in the content of these molecules, the Early cv. was the richest in anthocyanins and ascorbic acid, whereas the Late cv. was richest in total poplyphenols. The Late cv. was the only showing a high variability in the concentration in these molecules among the three growing areas. These differences between the two cultivars (Early and Late) could be strictly related to the traditional growing systems applied during plant’s growth, the different approach may greatly influence, other than the minerals and trace elements content, the synthesis of the bioactive molecules analysed. This effect was noticeable in the Late cv., grown in the last months in spring-water without any further fertilization. Further studies are needed to elucidate the contribution of these peculiar cultivation systems to the high variability in bioactive molecules content observed.

Acknowledgements

This study was funded by Italian Ministry of Agriculture, Food, and Forestry Policies (MiPAAF), Research Project “BIOVITA”.

Conflicts of Interest

The authors declare no conflicts of interest.

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