Systemic resistance induction in ‘Ortanique’ tangor

Kirinus, Marines Batalha Moreno; Silva, Pricila Santos da; Barreto, Caroline Farias; Oliveira, Roberto Pedroso de; Malgarim, Marcelo Barbosa

doi:10.1590/0100-29452019105

Abstract

This study aimed to evaluate the quality of ‘Ortanique’ tangor, in the post-harvest and refrigerated storage after application of pre-harvest resistance inducers, in the 2015 and 2016 crops. The experimental design in the field was in completely randomized blocks, in a single factorial scheme. The treatment factor was composed of the following resistance inducers [without inducer, selenium (Se), silicon (Si), acibenzolar-s-methyl (ASM), methyl jasmonate (MeJa), thiamethoxam (TMT) and imidacloprid (IMI)]. In the laboratory, the design used was the same as that established in the field, but in a two-factorial scheme, where factor A was composed of the same inducers and factor B, for the storage period [zero (fruits that were not submitted to storage) and 30 days (Cold chamber 5±1°C, relative humidity 85 to 95%)], with simulation of the commercialization time (7 days at 20±1°C). The following analysis were performed: coloration (L *, a *, b * and hue), fresh mass loss, rot index, soluble solids (SS), pH, titratable acidity (TA), SS/TA ratio, ascorbic acid, phenolic compounds and antioxidant capacity. The application of resistance inducers reduces the percentage of fresh mass loss and fruit rot after 30 days of refrigerated storage. Inducers keep phenolic compounds and antioxidant capacity, both in pulp and fruit peel, over the storage period. The inducers Si, MeJa and IMI provide phytochemicals improvement, when compared to the control.

Index terms
Citrus sinensis x Citrus reticulate; elicitors; refrigerated storage; rot

Resumo

Este estudo objetivou avaliar a qualidade do tangor ‘Ortanique’ na pós-colheita e no armazenamento refrigerado após aplicação de indutores de resistência na pré-colheita, nas safras de 2015 e 2016. O delineamento experimental a campo foi em blocos completos casualizados, em esquema unifatorial. O fator de tratamento foi composto pelos indutores de resistência [sem indutor (testemunha), selênio (Se), silício (Si), acibenzolar-s-metil (ASM), metil jasmonato (MeJa), tiametoxam (TMT) e imidacloprido (IMI)]. No laboratório, o delineamento utilizado foi o mesmo estabelecido a campo, porém em esquema bifatorial, em que o fator A foi composto pelos mesmos indutores, e o fator B, pelo período de armazenamento [zero (frutos que não foram submetidos ao armazenamento) e 30 dias (câmara fria 5±1ºC, umidade relativa de 90±5%)], com simulação do tempo de comercialização (7 dias a 20±1ºC). As análises realizadas foram coloração (L*, a*, b* e hue), perda de massa fresca, índice de podridões, sólidos solúveis (SS), pH, acidez titulável (AT), razão SS/AT, ácido ascórbico, compostos fenólicos e capacidade antioxidante. A aplicação dos indutores de resistência reduz o percentual de perda de massa fresca e podridões nos frutos após 30 dias de armazenamento refrigerado. Os indutores mantêm os compostos fenólicos e a capacidade antioxidante, tanto na polpa quanto na casca dos frutos, ao longo do período de armazenamento. Os indutores Si, MeJa e IMI proporcionam aumento dos fitoquímicos quando comparados à testemunha.

Termos para indexação
Citrus sinensis x Citrus reticulata; elicitores; armazenamento refrigerado; podridão

Introduction

The Brazilian citriculture is dedicated mainly to produce oranges to be used as raw materials of the juice industry. The state of São Paulo accounts for 76.3% of the national citrus production, followed by the states of Bahia, Sergipe, Rio Grande do Sul and Paraná. Of 19 million tons harvested per crop, approximately 1.5 million tons correspond to the production of ‘Tahiti’ acid lime [Citrus latifolia Tanaka] and tangerines, such as ‘Ponkan’ [Citrus Reticulata Blanco] and tangor ‘Murcott’ [Citrus sinensis L. Osbeck x Citrus reculata Blanco] (FAO, 2016 FAO. Faostat: production crops. Rome, 2016. Disponível em: http://faostat.fao.org/site/567/DesktopDefault.aspx?PageID=567#ancor>. Acesso em: 10 nov. 2016.
http://faostat.fao.org/site/567/DesktopD... ).

With the expansion of acreage and densification of orchards, there was increase of damage caused by different pathogens, the major causes of reduced productivity (ALBRECHT et al., 2012 ALBRECHT, U.; BOWMAN, K.D. Transcriptional response of susceptible and tolerant citrus to infection with Candidatus Liberibacter asiaticus. Plant Science, Amsterdam, v. 185/186, p. 118-130, 2012. ; BOCK et al., 2011 BOCK, C.H.; PARKER, P.E.; COOK, A.Z.; GRAHAM, J.H.; GOTTWALD, T.R. Infection and decontamination of citrus canker-inoculated leaf surfaces. Crop Protection, Guildford, v. 30, p. 259-264, 2011. ). As there are not always tolerant genotypes available, the control of these pathogens is usually accomplished with chemical pesticides. However, the demand for producing healthier food is gaining more and more importance, requiring the search for alternative approaches to pesticides for pathogen control. In this context, the use of systemic acquired resistance (SAR) is a defense mechanism induced by biotic or abiotic agents, which gives long-lasting protection against a broad spectrum of microorganisms, causing a wide variety of metabolic and physiological responses (AGHDAM et al., 2016 AGHDAM, M.S.; ASGHARI, M.; BABALAR, M.; SARCHESHMEH, M.A.A. Impact of salicylic acid in postharvest physiology of fruits and vegetables. In: SIDDIQUI, M.W. Eco-friendly technology for postharvest produce quality. Cambridge: Academic Press, 2016. p.244-260. ), related to direct and indirect defense in the secondary metabolism (ROBERT-SEILANIANTZ et al., 2011 ROBERT-SEILANIANTZ, A.; GRANT, M.; JONES, J.D. Hormone crosstalk in plant disease and defense: more than just jasmonate-salicylate antagonism. Annual Reviews of Phytopathology, Palo Alto, v. 49, p. 317-343, 2011. ).

Among the substances that promote resistance induction, highlighting their ability to activate fruit defenses, such as in citrus, are selenium, silicon, acibenzolar-s-methyl, methyl jasmonate and neocotinoids. Selenium regulates the expression of genes involved in the ethylene biosynthesis, which can slow down ripening and improve antioxidant defense system (ZHU et al., 2017 ZHU, Z.; CHEN, Y.; SHI, G.; ZHANG, X. Selenium delays tomato fruit ripening by inhibiting ethylene biosynthesis and enhancing the antioxidant defense system. Food Chemistry, New York, v. 219, p. 179-184, 2017. ), thereby increasing the potential of plants to fight stressful conditions (HANDA et al., 2016 HANDA, N.; BHARDWAJ, R.; KAUR, H.; POONAM, D.K.; RATTAN, A.; KAUR, S.; THUKRAL, A.K.; KAUR, S.; ARORA, S.; KAPOOR, N. Selenium: an antioxidative protectant in plants under stress. In: AHMAD, P. Plant metal interaction emerging remediation techniques. Srinagar: Department of Botany, 2016. v.1, p.179-207. ). Silicon is a beneficial nutrient, which operates in the metabolic system of the plants, inducing resistance (IMTIAZ et al., 2016 IMTIAZ, M.; RIZWAN, M.S.; MUSHTAQ, M.A.; ASHRAF, M.; SHAHZAD, S.M.; YOUSAF, B.; SAEED, D.A.; RIZWAN, M.; AZHER, M.N.; MEHMOOD, S.; TU, S. Silicon occurrence, uptake, transport and mechanisms of heavy metals, minerals and salinity enhanced tolerance in plants with future prospects: a review. Journal of Environmental Management, Berkeley, v. 183, n. 3, p. 521-529, 2016. ), increasing cell wall fragments (ZHICHAO et al., 2016 ZHICHAO, W.; FUHUA, W.; SHUAI, L.; YINGQIONG, D.; FURONG, L.; RUIYING, D.; DIAN, W.; JIE, Z. Comparative responses to silicon and selenium in relation to cadmium uptake, compartmentation in roots, and xylem transport in flowering Chinese cabbage (Brassica campestris) L. ssp. Chinensis var. utilis) under cadmium stress. Environmental and Experimental Botany, Amsterdam, v. 131, p. 173-180, 2016. ) and enzymatic activity of plant tissues (CONCEIÇÃO et al., 2014 CONCEIÇÃO, C.S.; FELIX, K.C.S.; MARIANO, R.L.R.; MEDEIROS, E.V.; SOUZA, E.B. Combined effect of yeast and silicon on the control of bacterial fruit blotch in melon. Scientia Horticulturae, New York, v. 174, p. 164-170, 2014. ).

Acibenzolar-s-methyl is able to activate proteins of pathogenesis, generating plant defense, as reported in apple (QUAGLIA et al., 2011 QUAGLIA, M.; EDERLI, L; PASQUALINI, S; ZAZZERINI, A. Biological control agentes and chemicas induceres of resistance for postharvest control of Penicillium expansumLink.on apple fruit. Postharvest Biology and Technology, Amsterdam, v. 59, n. 3, p. 307-315, 2011. ) and citrus (NETO et al., 2015 NETO, A.C.R.; MARASCHIN, M.; DI PIERO, R.M. Antifungal activity of salicylic acid against Penicillium expansum and its possible mechanisms of action. International Journal of Food Microbiology, Turin, v. 215, p. 64-70, 2015. ). Methyl jasmonate is important in the process of molecular signaling, raising the activation and induction of defense genes expression in citrus (ALBRECHT; BOWMAN, 2012 ALBRECHT, U.; BOWMAN, K.D. Transcriptional response of susceptible and tolerant citrus to infection with Candidatus Liberibacter asiaticus. Plant Science, Amsterdam, v. 185/186, p. 118-130, 2012. ; FAN et al., 2011 FAN, J.; CHEN, C.; YU, Q.; BRLANSKY, R.; ZHENG-GUO, L.; GMITTER, F.G. Comparative Itraq proteome and transcriptome analyses of sweet orange infected by Candidatus Liberibacter asiaticus. Physiologia Plantarum, Lund, v. 143, n. 3, p. 235-245, 2011. ). Substances such as the neocotinoids have property to induce systemic resistance in citrus plants (GRAHAM; MYRES, 2011 GRAHAM, J.H.; MYERS, M.E. Soil Application of SAR inducers imidacloprid, thiamethoxam, and acibenzolar-S-Methyl for citrus canker control in young grapefruit trees. Plant Disease, New York, v. 95, n. 6, p. 720-729, 2011. ).

Due to the great functionality of resistance inducers in plants, specific studies must be carried out in pre-harvest, improving their applications and expected results, consequently, providing production security. This study aimed to evaluate the quality of ‘Ortanique’ tangor [Citrus reticulata Blanco x Citrus sinensis (L.) Osbeck] fruit in post-harvest and under refrigerated storage after the application of resistance inducers in pre-harvest in the 2015 and 2016 crops.

Material and Methods

The experiment for the application of resistance inducers was carried out in the field, in the 2015 and 2016 crops, in a commercial orchard (31º40’47”S and 52º26’24”O, with 60 m above sea level), located in Monte Bonito, 9thdistrict of the municipality of Pelotas, Rio Grande do Sul (RS), Brazil. The soil in the region is moderately deep, with medium texture in the A horizon and clayey in the B horizon, classified as Yellow-Red Argisoil (SANTOS et al., 2006 SANTOS, H.G. Sistema brasileiro de classificação dos solos. 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306 p. ). The climate of the region is Cfa, i.e., temperate or humid subtropical with hot summers (KÖPPEN; GEIGER, 1928 KÖPPEN, W.; GEIGER, R. Klimate der Erde. Gotha: Verlag Justus Perthes. 1928. Wall-map 150cmx200cm ) with average annual rainfall of 1590 mm, annual average temperature of 18.4°C and relative humidity annual average 78.8% (INMET, 2016 INMET - Instituto Nacional de Meteorologia. BDMEP - Banco de Dados Meteorológicos para Ensino e Pesquisa. Brasília, 2016. Disponível em: http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep. Acesso em: 12 dez. 2016.
http://www.inmet.gov.br/portal/index.php... ).

The ‘Ortanique’ tangor [Citrus reticulata Blanco x Citrus sinensis (L.) Osbeck] plants with 6 years grafted onto ‘Rangpur’ lime [Citrus limonia Osbeck] with 5-m spacing between rows and 4 m between plants.

The experimental field was handled in accordance with the requirements of integrated citrus production (AZEVEDO et al., 2010 AZEVEDO, C.L.L.; SILVA, J.A.A.; CARVALHO, J.E.B. Segunda versão de normas técnicas específicas (NTE) da produção integrada de citros no Brasil. Cruz das Almas: Embrapa Mandioca e Fruticultura, 2010. 19p. (Documento, 192) ). The orchard was applied with Nativo® fungicide (Trifloxystrobin 100g.L-1 and Tebuconazole 200g.L-1), 3 applications spaced 30 days.

The first application was in the phenological stage of newly formed fruits and the application of the Bordeaux mixture (copper sulfate and lime) with 6 applications spaced 45 days, from flowering to 60 days before harvest.

The experimental design the field for the application of resistance inducers was in complete randomized blocks, with five repetitions, three plants per plot, by evaluating the central plant, in unifactorial scheme. The treatment was composed of resistance inducers [no inducer (control, water), selenium (Se, 10 mg.L-1), silicon (Si, 400 mg.L-1), acibenzolar-smethyl (ASM, 100 mg.L-1), methyl jasmonate (MeJa, 10 mg.L-1), Thiamethoxam (TMT, 2000 mg.L-1) and Imidacloprid (IMI, 714mg.L-1)]. These concentrations were established through preliminary tests in ‘Murcott’ tangor [Citrus sinensis L. Osbeck x Citrus reculata Blanco] and ‘Oktisu’ tangerine [Citrus unshiu Marc.], in an experimental area of Embrapa, and based on the literature.

The application of resistance inducers occurred at a 15-day interval, totaling three applications in the orchard, at 45, 30 and 15 days before harvest, with total dosage in each application. The products Si, ASM and MeJa were applied with knapsack (Guarani®), with flat fan nozzle and fine droplet size (101-200μ), throughout the plant, avoiding run-off. For Se, TMT and IMI inducers, each product was prepared and then applied in the soil around the plant canopy. The total volume of each treatment applied was 1L.plant-¹, in all treatments, 0.1% of nonionic Silwet adhesive L-77® adhesive spreader was added. The fruits were collected at ideal maturation for marketing, randomly in four quarters of the plant canopy. They were placed in plastic boxes cleaned and disinfected, transported to the Physiology Laboratory and Post-Harvest Technology of Fruit, Department of Crop Science at the Universidade Federal de Pelotas (UFPel), where they were submitted to pre-screening for standardization, by removing damaged fruits, and precooling (15±2°C) for 24 hours.

In the laboratory the design used was the same as established in the field, but in a two-factorial scheme, where factor A was composed of the same resistance inducers described previously and factor B, a storage period (zero and 30 days). The zero time corresponded to fruits that were not subjected to storage and at 30 days of storage in a cold chamber at 5±1°C under 85-95% of relative humidity. After removing from the chamber, the fruits were subjected to simulation of commercialization time, 7 days at 20±1°C. For each treatment, three replicates were used with 20 fruits each and the same quantity was allocated to refrigerated storage, totaling 840 fruits.

The analyses made were coloring (L*, a*, b* and hue), fresh mass loss, rot index, soluble solids (SS), pH, titratable acidity (TA), SS/TA ratio, ascorbic acid, phenolic compounds and antioxidant capacity. The pulp color was measured with Minolta colorimeter CR-300, with reading system CIE L* a* b*, and the chromatic tone, represented by the hue angle (hº) through the arctangent formula b*/a*. The result of this equation, expressed in radians, was converted into degrees (MINOLTA, 1994 MINOLTA. Precise color communication: color control from feeling to instrumentation. Tokyo: Konica Minolta, 1994. 49p. ).

The fresh mass loss of fruits was obtained by the difference between the initial and final mass of the cold storage period and the values expressed in percentage (%). The rot index was established by the percentage of fruit attacked by pathogens through visual inspection, where fruits with lesion greater than or equal to 5 mm were considered rot. Both evaluations were conducted after 30 days of refrigerated storage.

The soluble solids (SS) were quantified with digital Refractometer (Atago®) model PAL-1 and the results were expressed in °Brix. The hydrogen potential (pH) was measured through a digital pH meter (Digimed®). For titratable acidity (TA), 10 ml of fruit juice was added to 90 mL of distilled water. The sample titration was made with the aid of digital burette (Brand®), containing sodium hydroxide solution (0.1 N) until reaching pH 8.1, the values were expressed in percentage of citric acid. The SS/TA ratio of tangor was expressed by the relationship between the soluble solids and titratable acidity (INSTITUTO ADOLFO LUTZ, 2008 INSTITUTO ADOLFO LUTZ. Métodos físico-químicos para análise de alimentos. 4. ed. São Paulo: Instituto Adolfo Lutz, 2008. v. 1, 1020 p. ). The ascorbic acid content was quantified through the official AOAC method (1997) A.O.A.C. (Association of Official Analytical Chemists) . Official Methods of Analisis; Editted by Sidney Williams. 16 ed. Arlington, 1997. 1141p. by oxidative titration with 2.6-DiclorofenolIndofenol (DCFI), with the titration point detected by the appearance of the pink coloration, the result was expressed in mg of ascorbic acid per 100 g-1of sample (JACOBS, 1958 JACOBS, M.B. The chemical analysis of foods and food products. New York: Van Nostrand, 1958. 979 p. ; LEME; MALAVOLTA, 1950 LEME, J.J.; MALAVOLTA, E. Determinação fotométrica de ácido ascórbico. Anais da Escola Superior de Agricultura Luiz de Queiroz, Piracicaba, v. 7, p. 115-129, 1950. ).

To analyze the phytochemicals of ‘Ortanique’ tangor the exocarp or epicarp (peel) of the endocarp (pulp) were separated and evaluated separately. The total phenolic compounds were quantified using the Folin-Ciocalteau reagent according to the method described by Swain and Hillis (1959) SWAIN, T.; HILLS, W.E. The phenolic constituents of Punnus domestica.The quantitative analysis of phenolic constituents. Journal of the Science of Food and Agriculture, Washington, v. 19, p. 63-68, 1959. , expressed in mg of chlorogenic acid equivalent (CAE) per 100 g-1 of tangor. The antioxidant capacity was determined by spectrophotometry, according to the method adapted from Brand-Williams et al. (1995) BRAND-WILLIAMS, W.; CUVELIER, M.E.; BERSET, C. Use of a free radical method to evaluate antioxidant activity. Lebensmittel Wissenschaft und Technologie – Food Science and Technology, London, v. 28, n. 1, p. 25-30, 1995. , and the results expressed as μg of Trolox equivalent antioxidant capacity (TEAC) g-1 of tangor.

The 2015 and 2016 crops were used as repetition.

The data were analyzed for normality by the Shapiro- Wilk test and for homoscedasticity by the Hartley test.

Subsequently, the data were submitted to analysis of variance (p≤0.05). In case of significance, the effect of resistance inducers was examined by the Tukey test (p≤0.05) and the storage period by the t test (p≤0.05).To compare the inducers with the control, the Dunnett test (p≤0.05) was used. The presence of correlations between the dependent variables of the study was analyzed through the Pearson correlation coefficient (r) (p<0.05).

Results and Discussion

The variables color (L* and a*), titratable acidity, soluble solids and ascorbic acid showed interaction between the treatment factors tested (Table 1). When evaluating the coloring through luminosity (L*), there was no difference between the inducers in both storage periods. However, after 30 days of refrigerated storage, the Selenium, ASM and TMT inducers kept the L* values of the fruits.

Thumbnail

Table 1
Coloring (L* and a*), titratable acidity (% citric acid), soluble solids (°Brix) and ascorbic acid (mg 100 g-1) of ‘Ortanique’ tangor fruits due to resistance inducers applied in pre-harvest and periods of refrigerated storage with subsequent simulation of commercialization time (7 days at 20±1°C) in the 2015 and 2016 crops. UFPel, Pelotas/RS.

Regarding the intensity of a*, there was no difference between the inducers; however, treatments with Si, ASM, MeJa, TMT and IMI provided increased intensity of reddish color throughout the storage period. For L* and a*, the application of inducers did not differ when compared to control (Table 1). Coloring is a parameter used by citrus consumers, who prefer fresh and semi-ripened fruit (PACHECO et al., 2014 PACHECO, C.A.; SCHINOR, E.H.; AZEVEDO, F.A.; BASTIANEL, M.; CRISTOFANI-YALY, M. Characterization of fruits of Tangor TM x LP 290 for fresh fruit market. Revista Brasileira de Fruticultura, Jaboticabal, v.36, n.4, p.805-812, 2014. ). In this work, acceptable indices of coloring were kept, strong color and bright are preferred, although color, in most cases, does not contribute to an increase of nutritional value (CHITARRA; CHITARRA, 2005 CHITARRA, M. I. F.; CHITARRA, A. B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: ESAL/FAEPE, 2005. 2ed. 783p. ).

Regarding fruit acidity, the inducers differed from one another after 30 days of storage, and IMI, Se and TMT showed higher percentage of citric acid.

When comparing the storage period, time zero differed from 30 days for the ASM, MeJa and IMI inducers.

Only the neocotinoid IMI (1.85% citric acid) differed from control. The soluble solids content of ‘Ortanique’ tangor did not present significant difference between the inducers at day zero. At 30 days of storage, the Selenium inducer characterized the highest soluble solids content, differing only from ASM. There was an increase along the storage period only for IMI. No differences were observed in relation to the control. The solids indicate the amount of sugar dissolved in juice or pulp of tangor fruits and tend to increase with the advancement of maturation (CHITARRA; CHITARRA, 2005 CHITARRA, M. I. F.; CHITARRA, A. B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: ESAL/FAEPE, 2005. 2ed. 783p. ). Fruits of ‘URSBRS Hada’ tangor of double purpose cultivated in Butiá - RS presented 12.2 and 12.1°Brix and acidity of 1.59 to 1.65% of citric acid (GONZATTO et al., 2015 GONZATTO, M.P.; SCHWARZ, S.F.; OLIVEIRA, R.P.; BENDER, R.J.; SOUZA, P.V.D. ‘URSBRS Hada’: Tangoreiro de maturação tardia de duplo propósito. Revista Brasileira de Fruticultura, Jaboticabal, v.37, n.2, p.524-527, 2015. ), corroborating with the results found in this work.

ASM showed the lowest content of ascorbic acid between the inducers analyzed in both periods. During the cold storage period, the ascorbic acid reduced the presence of Se inducer. IMI showed higher results at both zero and 30 days of storage and Se only in the fruits that were not submitted to storage, when compared to control.

Studies on ‘Murcott’ tangor fruit after 60 days of storage at 4±0.2°C and 7 days of shelf life at 20ºC showed levels of fresh mass loss between 3 and 6%, while keeping the physical and chemical qualities, such as ascorbic acid, soluble solids and titratable acidity (PINTO et al., 2015 PINTO, J.A.V.; THEWES, F.R.; SCHORR, M.R.W.; CECONI, D.L.; BRACKMANN, A.; HAMANN, J.J.; FRONZA, D. Mass loss induction on physical and chemical qualities of ‘Murcott’ Tangor during cold storage. Bioscience Journal, Uberlândia, v.31, n.5, p.1325-1332, 2015. ).

This percentage of fresh mass loss is consistent with the data found in this study (Table 4).

Thumbnail

Table 4
Fresh mass loss (%) and rot index (%) of fruits of ‘Ortanique’ treated in pre-harvest with resistance inducers in the 2015 and 2016 crops. UFPel, Pelotas/RS.

For the conservation of ‘Newhall’ oranges, antimicrobial coatings were also studied as a way to reduce the use of agrochemicals, and it was observed that the clove extract reduced deterioration of fruits in cold storage at 7°C, mainly for the physical-chemical characteristics, such as soluble solids, titratable acidity and ascorbic acid (ZENG et al., 2012 ZENG, R.; ZHANG, A.; CHEN, J.; FU, Y. Postharvest quality and physiological responses of clove bud extract dip on ‘Newhall’ navel orange. Scientia Horticulturae, New York, v. 138, p. 253-258, 2012. ).

The color expressed by b* and hue angle, besides the pH and SS/TA ratio, showed significance only for the main effect of the storage period (Table 3). For b* coloring, all fruits showed the intensity of yellow with positive values. Similarly, for hue in which the coloring of the fruit epidermis was characterized as yellow; however, both showed reduction throughout the storage period. The pH and SS/TA ratio of fruits increased with cold storage. Different results were found in ‘Ortanique’ tangor fruits subject to application of carnauba wax in post-harvest, where neither coating nor storage period influenced soluble solids, titratable acidity, pH and SS/ TA ratio (MACHADO et al., 2012 MACHADO, F.L.C.; COSTA, J.M.C.; BATISTA, E.N. Application of carnauba-based wax maintains postharvest quality of ‘Ortanique’ tangor. Food Science and Technology, Melbourne, v. 32, n. 2, p. 261-266, 2012. ).

Thumbnail

Table 3
Coloring (b* and Hue), pH and SS/TA ratio of ‘Ortanique’tangor fruits under effect of refrigerated storage with subsequent simulation of commercialization time (7 days at 20±1°C) in the 2015 and 2016 crops. UFPel, Pelotas/RS.

The reduction in the percentage of mass loss and rot index was significant with the application of inducers evaluated after 30 days of storage (Table 4). The MeJa inducer had greater fresh fruit mass loss, being different from other inductors and similar to control. Fresh mass loss is determined by the evaporation and respiration rate of tangor fruits, which must be kept to the minimum necessary to ensure fruit quality (CHITARRA; CHITARRA, 2005 CHITARRA, M. I. F.; CHITARRA, A. B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: ESAL/FAEPE, 2005. 2ed. 783p. ).

The percentage of rot index of the fruit showed that that inducers applied reduced rota long the storage period of 30 days, in relation to the control; however, they did not differ between each other, possibly by the short storage period of the fruit. Due to the advancement in the ripening degree, a greater susceptibility of tangor fruits to the development of pathogens occurred. Studies conducted by Wang and Liu (2012) WANG, Y.; LIU J. Exogenous treatment with salicylic acid attenuates occurrence of citrus canker in susceptible navel Orange (Citrus sinensis Osbeck). Journal of Plant Physiology, Amsterdam, v. 169, n. 12, p. 1143-1149, 2012. in citrus fruits with the application of salicylic acid inducer showed various physiological and molecular events, which conferred resistance, reducing the incidence of rot and bacterial diseases.

For the total phenolics in pulp of ‘Ortanique’ fruit, the ASM inducer at initial time presented the lowest content of phenols; nevertheless, it was the only inducer showed no decrease throughout the storage period. The IMI inducers at zero and 30 days, and Se, Si and MeJa only at 30 days of refrigerated storage differed from control (Table 2). According to Siboza et al. (2014) SIBOZA, X.I.; BERTLING, I.; ODINDO, A.O. Salicylic acid and methyl jasmonate improve chilling tolerance in cold-stored lemon fruit (Citrus limon). Journal of Plant Physiology, Amsterdam, v. 171, n. 18, p. 1722-1731, 2014. , MeJa combined with ASM kept the membrane integrity of lime fruits, becoming effective in tolerance to cold storage, in addition to increasing the phenolic compounds.

Thumbnail

Table 2
Total phenolics (mg CAE 100 g-1) and antioxidant capacity (DPPH, µg TEAC g-1) in pulp and peel of ‘Ortanique’ tangor fruits in resistance inducers function applied in pre-harvest and periods of refrigerated storage with posterior simulation of commercialization time (7 days at 20±1°C) in the 2015 and 2016 crops. UFPel, Pelotas/RS.

When these compounds were evaluated in peel, there was no difference between the inducers both at zero and at 30 days of cold storage. However, throughout storage, all inducers kept the levels of total phenolic compounds, with the exception of IMI. The Si and IMI inducers were superior to the control in both evaluations. For antioxidant capacity in fruit pulp, no difference between the inducers was observed both at the beginning and at end of storage, and all inducers kept the antioxidant capacity throughout the storage period.

However, when compared with the control at day zero, all inducers, except for ASM, showed superior results. At 30 days of storage, however, only Si, MeJa and IMI were higher than control. The systemic neonicotinoid insecticides, IMI and TMT, reduced the incidence of disease in grapefruit and young orange (GRAHAM; MYERS, 2013 GRAHAM, J.H.; MYERS, M.E. Integration of soil applied neocicotinoid insecticides and acibenzolar-S-methyl for systemic acquired resistance (SAR) control of citrus canker on young citrus trees. Crop Protection, Guildford, v. 54, p. 239-243, 2013. ).

Evaluation of the antioxidant capacity of fruit peel of ‘Ortanique’ tangor showed no difference between the inducers in the two periods evaluated. Throughout storage, the antioxidant capacity reduced, with the exception of inducer MeJa, which kept high levels and was the only inducer that differed from control in both storage periods thus inducing structural and/or metabolic responses associated with resistance expression. Moulehi et al. (2012) MOULEHI, I.; BOURGOU, S.; OURGHEMMI, I.; TOUNSI, M.S. Variety and ripening impact on phenolic composition and antioxidant activity of mandarin (Citrus reticulate Blanco) and bitter orange (Citrus aurantium L.) seeds extracts. Industrial Crops and Products, Amsterdam, v. 39, p. 74-80, 2012. conducted an experiment and found that the antioxidant capacity of tangerine (Citrus reticulata) and bitter orange (Citrus auratium) varied during the ripening period, and the antioxidant capacity in orange was greater than in tangerine. In navel oranges [Citrus sinensis (L). Osbeck], the treatment with the inducer Oligochitosan spray in pre-harvest also proved to be a potential alternative to replace conventional control methods by preventing disease in post-harvest due to increase of the concentration of enzymes related to defense mechanisms (DENG et al., 2015 DENG, L.; ZHOU, Y.; ZENG, K. Pre-harvest spray of oligochitosan induced the resistance of harvested navel oranges to anthracnose during ambient temperature storage. Crop Protection, Guildford, v. 70, p. 70-76, 2015. ).

When the fruit phenolic compounds were correlated with their total antioxidant capacity, the selenium (r = 0.518), silicon (r = 0.755), MeJa (r = 0.883) and TMT (r = 0.802) inducers characterized positive association between these variables, demonstrating that the capacity antioxidant of ‘Ortanique’ fruit is attributed to phenolic compounds, unlike the control, which showed no correlation. However, between the antioxidant capacity in peel and fruit phenols, the silicon inducers (r = 0.631) and MeJa (r = 0.917) were superior to the control (r = 0.607). Preventive and curative activities of post-harvest treatments have been reported in the literature, such as the use of sodium silicate resistance inducer for the control of Penicillium digitatum and Penicillium italicum, showing an effective result (MOSCOSO-RAMÍREZ; PALOU, 2013 MOSCOSO-RAMÍREZ, P.A.; PALOU, L. Evaluation of postharvest treatments with chemical resistance inducers to control Green and blue molds on Orange fruit. Postharvest Biology and Technology, Amsterdam, v. 85, p. 132-135, 2013. ).

By correlating the phenolic compounds in pulp and peel, the ASM (r = 0.925) and IMI (r = 0.707) inducers were above the control (r = 0.562). In the association between antioxidant capacity and total phenols, both in peel, the selenium inducers (r = 0.883) and silicon (r =0.861) were higher than the control (r = 0.801). In the antioxidant capacity of the endocarp correlated to peel, only the MeJa inducer (r = 0.739) was higher than the control (r = 0.546). MeJa has been investigated in the role of plant defense in bean (Phaseolus vulgaris L.) and was responsible for influencing many metabolic functions, such as biogenesis, protein degradation and cellular defense (OLIVEIRA et al., 2015 OLIVEIRA, M.B.; JUNIOR, M.L.; GROSSI-DE-SÁ, M.F.; PETROFEZA, S. Exogenous application of methyl jasmonate induces a defense response and resistance against Sclerotinia sclerotiorum in dry bean plants. Journal of Plant Physiology, Amsterdam, v. 182, p. 13-22, 2015. ).

Conclusion

The application of resistance inducers reduces the percentage of fresh mass loss and rot index in fruits after 30 days of refrigerated storage. The inducers keep the phenolic compounds and antioxidant capacity, in both pulp and peel, throughout the storage period. Si, MeJa and IMI provide increase of phytochemicals when compared to the control.

AGHDAM, M.S.; ASGHARI, M.; BABALAR, M.; SARCHESHMEH, M.A.A. Impact of salicylic acid in postharvest physiology of fruits and vegetables. In: SIDDIQUI, M.W. Eco-friendly technology for postharvest produce quality. Cambridge: Academic Press, 2016. p.244-260.
ALBRECHT, U.; BOWMAN, K.D. Transcriptional response of susceptible and tolerant citrus to infection with Candidatus Liberibacter asiaticus. Plant Science, Amsterdam, v. 185/186, p. 118-130, 2012.
ALBRECHT, U.; MCCOLLUM, G.; BOWMAN, K.D. Influence of rootstock variety on Huanglongbing disease development in field-grown sweet orange (Citrus sinensis L. Osbeck) trees. Scientia Horticulturae, New York, v. 138, p. 210-220, 2012.
A.O.A.C. (Association of Official Analytical Chemists) . Official Methods of Analisis; Editted by Sidney Williams. 16 ed. Arlington, 1997. 1141p.
AZEVEDO, C.L.L.; SILVA, J.A.A.; CARVALHO, J.E.B. Segunda versão de normas técnicas específicas (NTE) da produção integrada de citros no Brasil. Cruz das Almas: Embrapa Mandioca e Fruticultura, 2010. 19p. (Documento, 192)
BOCK, C.H.; PARKER, P.E.; COOK, A.Z.; GRAHAM, J.H.; GOTTWALD, T.R. Infection and decontamination of citrus canker-inoculated leaf surfaces. Crop Protection, Guildford, v. 30, p. 259-264, 2011.
BRAND-WILLIAMS, W.; CUVELIER, M.E.; BERSET, C. Use of a free radical method to evaluate antioxidant activity. Lebensmittel Wissenschaft und Technologie – Food Science and Technology, London, v. 28, n. 1, p. 25-30, 1995.
CHITARRA, M. I. F.; CHITARRA, A. B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: ESAL/FAEPE, 2005. 2ed. 783p.
CONCEIÇÃO, C.S.; FELIX, K.C.S.; MARIANO, R.L.R.; MEDEIROS, E.V.; SOUZA, E.B. Combined effect of yeast and silicon on the control of bacterial fruit blotch in melon. Scientia Horticulturae, New York, v. 174, p. 164-170, 2014.
DENG, L.; ZHOU, Y.; ZENG, K. Pre-harvest spray of oligochitosan induced the resistance of harvested navel oranges to anthracnose during ambient temperature storage. Crop Protection, Guildford, v. 70, p. 70-76, 2015.
FAN, J.; CHEN, C.; YU, Q.; BRLANSKY, R.; ZHENG-GUO, L.; GMITTER, F.G. Comparative Itraq proteome and transcriptome analyses of sweet orange infected by Candidatus Liberibacter asiaticus. Physiologia Plantarum, Lund, v. 143, n. 3, p. 235-245, 2011.
FAO. Faostat: production crops. Rome, 2016. Disponível em: http://faostat.fao.org/site/567/DesktopDefault.aspx?PageID=567#ancor>. Acesso em: 10 nov. 2016.
» http://faostat.fao.org/site/567/DesktopDefault.aspx?PageID=567#ancor
GONZATTO, M.P.; SCHWARZ, S.F.; OLIVEIRA, R.P.; BENDER, R.J.; SOUZA, P.V.D. ‘URSBRS Hada’: Tangoreiro de maturação tardia de duplo propósito. Revista Brasileira de Fruticultura, Jaboticabal, v.37, n.2, p.524-527, 2015.
GRAHAM, J.H.; MYERS, M.E. Integration of soil applied neocicotinoid insecticides and acibenzolar-S-methyl for systemic acquired resistance (SAR) control of citrus canker on young citrus trees. Crop Protection, Guildford, v. 54, p. 239-243, 2013.
GRAHAM, J.H.; MYERS, M.E. Soil Application of SAR inducers imidacloprid, thiamethoxam, and acibenzolar-S-Methyl for citrus canker control in young grapefruit trees. Plant Disease, New York, v. 95, n. 6, p. 720-729, 2011.
HANDA, N.; BHARDWAJ, R.; KAUR, H.; POONAM, D.K.; RATTAN, A.; KAUR, S.; THUKRAL, A.K.; KAUR, S.; ARORA, S.; KAPOOR, N. Selenium: an antioxidative protectant in plants under stress. In: AHMAD, P. Plant metal interaction emerging remediation techniques. Srinagar: Department of Botany, 2016. v.1, p.179-207.
IMTIAZ, M.; RIZWAN, M.S.; MUSHTAQ, M.A.; ASHRAF, M.; SHAHZAD, S.M.; YOUSAF, B.; SAEED, D.A.; RIZWAN, M.; AZHER, M.N.; MEHMOOD, S.; TU, S. Silicon occurrence, uptake, transport and mechanisms of heavy metals, minerals and salinity enhanced tolerance in plants with future prospects: a review. Journal of Environmental Management, Berkeley, v. 183, n. 3, p. 521-529, 2016.
INMET - Instituto Nacional de Meteorologia. BDMEP - Banco de Dados Meteorológicos para Ensino e Pesquisa. Brasília, 2016. Disponível em: http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep Acesso em: 12 dez. 2016.
» http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep
INSTITUTO ADOLFO LUTZ. Métodos físico-químicos para análise de alimentos. 4. ed. São Paulo: Instituto Adolfo Lutz, 2008. v. 1, 1020 p.
JACOBS, M.B. The chemical analysis of foods and food products. New York: Van Nostrand, 1958. 979 p.
KOLLER, O.L. (org.) Citricultura catarinense. Florianópolis: EPAGRI, 2013. 319p.
KÖPPEN, W.; GEIGER, R. Klimate der Erde. Gotha: Verlag Justus Perthes. 1928. Wall-map 150cmx200cm
LEME, J.J.; MALAVOLTA, E. Determinação fotométrica de ácido ascórbico. Anais da Escola Superior de Agricultura Luiz de Queiroz, Piracicaba, v. 7, p. 115-129, 1950.
MACHADO, F.L.C.; COSTA, J.M.C.; BATISTA, E.N. Application of carnauba-based wax maintains postharvest quality of ‘Ortanique’ tangor. Food Science and Technology, Melbourne, v. 32, n. 2, p. 261-266, 2012.
MINOLTA. Precise color communication: color control from feeling to instrumentation. Tokyo: Konica Minolta, 1994. 49p.
MOSCOSO-RAMÍREZ, P.A.; PALOU, L. Evaluation of postharvest treatments with chemical resistance inducers to control Green and blue molds on Orange fruit. Postharvest Biology and Technology, Amsterdam, v. 85, p. 132-135, 2013.
MOULEHI, I.; BOURGOU, S.; OURGHEMMI, I.; TOUNSI, M.S. Variety and ripening impact on phenolic composition and antioxidant activity of mandarin (Citrus reticulate Blanco) and bitter orange (Citrus aurantium L.) seeds extracts. Industrial Crops and Products, Amsterdam, v. 39, p. 74-80, 2012.
NETO, A.C.R.; MARASCHIN, M.; DI PIERO, R.M. Antifungal activity of salicylic acid against Penicillium expansum and its possible mechanisms of action. International Journal of Food Microbiology, Turin, v. 215, p. 64-70, 2015.
OLIVEIRA, M.B.; JUNIOR, M.L.; GROSSI-DE-SÁ, M.F.; PETROFEZA, S. Exogenous application of methyl jasmonate induces a defense response and resistance against Sclerotinia sclerotiorum in dry bean plants. Journal of Plant Physiology, Amsterdam, v. 182, p. 13-22, 2015.
PACHECO, C.A.; SCHINOR, E.H.; AZEVEDO, F.A.; BASTIANEL, M.; CRISTOFANI-YALY, M. Characterization of fruits of Tangor TM x LP 290 for fresh fruit market. Revista Brasileira de Fruticultura, Jaboticabal, v.36, n.4, p.805-812, 2014.
PINTO, J.A.V.; THEWES, F.R.; SCHORR, M.R.W.; CECONI, D.L.; BRACKMANN, A.; HAMANN, J.J.; FRONZA, D. Mass loss induction on physical and chemical qualities of ‘Murcott’ Tangor during cold storage. Bioscience Journal, Uberlândia, v.31, n.5, p.1325-1332, 2015.
QUAGLIA, M.; EDERLI, L; PASQUALINI, S; ZAZZERINI, A. Biological control agentes and chemicas induceres of resistance for postharvest control of Penicillium expansumLink.on apple fruit. Postharvest Biology and Technology, Amsterdam, v. 59, n. 3, p. 307-315, 2011.
ROBERT-SEILANIANTZ, A.; GRANT, M.; JONES, J.D. Hormone crosstalk in plant disease and defense: more than just jasmonate-salicylate antagonism. Annual Reviews of Phytopathology, Palo Alto, v. 49, p. 317-343, 2011.
SANTOS, H.G. Sistema brasileiro de classificação dos solos. 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306 p.
SIBOZA, X.I.; BERTLING, I.; ODINDO, A.O. Salicylic acid and methyl jasmonate improve chilling tolerance in cold-stored lemon fruit (Citrus limon). Journal of Plant Physiology, Amsterdam, v. 171, n. 18, p. 1722-1731, 2014.
SWAIN, T.; HILLS, W.E. The phenolic constituents of Punnus domestica.The quantitative analysis of phenolic constituents. Journal of the Science of Food and Agriculture, Washington, v. 19, p. 63-68, 1959.
WANG, Y.; LIU J. Exogenous treatment with salicylic acid attenuates occurrence of citrus canker in susceptible navel Orange (Citrus sinensis Osbeck). Journal of Plant Physiology, Amsterdam, v. 169, n. 12, p. 1143-1149, 2012.
ZENG, R.; ZHANG, A.; CHEN, J.; FU, Y. Postharvest quality and physiological responses of clove bud extract dip on ‘Newhall’ navel orange. Scientia Horticulturae, New York, v. 138, p. 253-258, 2012.
ZHICHAO, W.; FUHUA, W.; SHUAI, L.; YINGQIONG, D.; FURONG, L.; RUIYING, D.; DIAN, W.; JIE, Z. Comparative responses to silicon and selenium in relation to cadmium uptake, compartmentation in roots, and xylem transport in flowering Chinese cabbage (Brassica campestris) L. ssp. Chinensis var. utilis) under cadmium stress. Environmental and Experimental Botany, Amsterdam, v. 131, p. 173-180, 2016.
ZHU, Z.; CHEN, Y.; SHI, G.; ZHANG, X. Selenium delays tomato fruit ripening by inhibiting ethylene biosynthesis and enhancing the antioxidant defense system. Food Chemistry, New York, v. 219, p. 179-184, 2017.

Publication Dates

Publication in this collection
2019

History

Received
31 Aug 2018
Accepted
10 Jan 2019

This is an Open-Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AGHDAM, M.S.; ASGHARI, M.; BABALAR, M.; SARCHESHMEH, M.A.A. Impact of salicylic acid in postharvest physiology of fruits and vegetables. In: SIDDIQUI, M.W. Eco-friendly technology for postharvest produce quality. Cambridge: Academic Press, 2016. p.244-260.

[2] ALBRECHT, U.; BOWMAN, K.D. Transcriptional response of susceptible and tolerant citrus to infection with Candidatus Liberibacter asiaticus. Plant Science, Amsterdam, v. 185/186, p. 118-130, 2012.

[3] ALBRECHT, U.; MCCOLLUM, G.; BOWMAN, K.D. Influence of rootstock variety on Huanglongbing disease development in field-grown sweet orange (Citrus sinensis L. Osbeck) trees. Scientia Horticulturae, New York, v. 138, p. 210-220, 2012.

[4] A.O.A.C. (Association of Official Analytical Chemists) . Official Methods of Analisis; Editted by Sidney Williams. 16 ed. Arlington, 1997. 1141p.

[5] AZEVEDO, C.L.L.; SILVA, J.A.A.; CARVALHO, J.E.B. Segunda versão de normas técnicas específicas (NTE) da produção integrada de citros no Brasil. Cruz das Almas: Embrapa Mandioca e Fruticultura, 2010. 19p. (Documento, 192)

[6] BOCK, C.H.; PARKER, P.E.; COOK, A.Z.; GRAHAM, J.H.; GOTTWALD, T.R. Infection and decontamination of citrus canker-inoculated leaf surfaces. Crop Protection, Guildford, v. 30, p. 259-264, 2011.

[7] BRAND-WILLIAMS, W.; CUVELIER, M.E.; BERSET, C. Use of a free radical method to evaluate antioxidant activity. Lebensmittel Wissenschaft und Technologie – Food Science and Technology, London, v. 28, n. 1, p. 25-30, 1995.

[8] CHITARRA, M. I. F.; CHITARRA, A. B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: ESAL/FAEPE, 2005. 2ed. 783p.

[9] CONCEIÇÃO, C.S.; FELIX, K.C.S.; MARIANO, R.L.R.; MEDEIROS, E.V.; SOUZA, E.B. Combined effect of yeast and silicon on the control of bacterial fruit blotch in melon. Scientia Horticulturae, New York, v. 174, p. 164-170, 2014.

[10] DENG, L.; ZHOU, Y.; ZENG, K. Pre-harvest spray of oligochitosan induced the resistance of harvested navel oranges to anthracnose during ambient temperature storage. Crop Protection, Guildford, v. 70, p. 70-76, 2015.

[11] FAN, J.; CHEN, C.; YU, Q.; BRLANSKY, R.; ZHENG-GUO, L.; GMITTER, F.G. Comparative Itraq proteome and transcriptome analyses of sweet orange infected by Candidatus Liberibacter asiaticus. Physiologia Plantarum, Lund, v. 143, n. 3, p. 235-245, 2011.

[12] FAO. Faostat: production crops. Rome, 2016. Disponível em: http://faostat.fao.org/site/567/DesktopDefault.aspx?PageID=567#ancor>. Acesso em: 10 nov. 2016.
» http://faostat.fao.org/site/567/DesktopDefault.aspx?PageID=567#ancor

[13] GONZATTO, M.P.; SCHWARZ, S.F.; OLIVEIRA, R.P.; BENDER, R.J.; SOUZA, P.V.D. ‘URSBRS Hada’: Tangoreiro de maturação tardia de duplo propósito. Revista Brasileira de Fruticultura, Jaboticabal, v.37, n.2, p.524-527, 2015.

[14] GRAHAM, J.H.; MYERS, M.E. Integration of soil applied neocicotinoid insecticides and acibenzolar-S-methyl for systemic acquired resistance (SAR) control of citrus canker on young citrus trees. Crop Protection, Guildford, v. 54, p. 239-243, 2013.

[15] GRAHAM, J.H.; MYERS, M.E. Soil Application of SAR inducers imidacloprid, thiamethoxam, and acibenzolar-S-Methyl for citrus canker control in young grapefruit trees. Plant Disease, New York, v. 95, n. 6, p. 720-729, 2011.

[16] HANDA, N.; BHARDWAJ, R.; KAUR, H.; POONAM, D.K.; RATTAN, A.; KAUR, S.; THUKRAL, A.K.; KAUR, S.; ARORA, S.; KAPOOR, N. Selenium: an antioxidative protectant in plants under stress. In: AHMAD, P. Plant metal interaction emerging remediation techniques. Srinagar: Department of Botany, 2016. v.1, p.179-207.

[17] IMTIAZ, M.; RIZWAN, M.S.; MUSHTAQ, M.A.; ASHRAF, M.; SHAHZAD, S.M.; YOUSAF, B.; SAEED, D.A.; RIZWAN, M.; AZHER, M.N.; MEHMOOD, S.; TU, S. Silicon occurrence, uptake, transport and mechanisms of heavy metals, minerals and salinity enhanced tolerance in plants with future prospects: a review. Journal of Environmental Management, Berkeley, v. 183, n. 3, p. 521-529, 2016.

[18] INMET - Instituto Nacional de Meteorologia. BDMEP - Banco de Dados Meteorológicos para Ensino e Pesquisa. Brasília, 2016. Disponível em: http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep Acesso em: 12 dez. 2016.
» http://www.inmet.gov.br/portal/index.php?r=bdmep/bdmep

[19] INSTITUTO ADOLFO LUTZ. Métodos físico-químicos para análise de alimentos. 4. ed. São Paulo: Instituto Adolfo Lutz, 2008. v. 1, 1020 p.

[20] JACOBS, M.B. The chemical analysis of foods and food products. New York: Van Nostrand, 1958. 979 p.

[21] KOLLER, O.L. (org.) Citricultura catarinense. Florianópolis: EPAGRI, 2013. 319p.

[22] KÖPPEN, W.; GEIGER, R. Klimate der Erde. Gotha: Verlag Justus Perthes. 1928. Wall-map 150cmx200cm

[23] LEME, J.J.; MALAVOLTA, E. Determinação fotométrica de ácido ascórbico. Anais da Escola Superior de Agricultura Luiz de Queiroz, Piracicaba, v. 7, p. 115-129, 1950.

[24] MACHADO, F.L.C.; COSTA, J.M.C.; BATISTA, E.N. Application of carnauba-based wax maintains postharvest quality of ‘Ortanique’ tangor. Food Science and Technology, Melbourne, v. 32, n. 2, p. 261-266, 2012.

[25] MINOLTA. Precise color communication: color control from feeling to instrumentation. Tokyo: Konica Minolta, 1994. 49p.

[26] MOSCOSO-RAMÍREZ, P.A.; PALOU, L. Evaluation of postharvest treatments with chemical resistance inducers to control Green and blue molds on Orange fruit. Postharvest Biology and Technology, Amsterdam, v. 85, p. 132-135, 2013.

[27] MOULEHI, I.; BOURGOU, S.; OURGHEMMI, I.; TOUNSI, M.S. Variety and ripening impact on phenolic composition and antioxidant activity of mandarin (Citrus reticulate Blanco) and bitter orange (Citrus aurantium L.) seeds extracts. Industrial Crops and Products, Amsterdam, v. 39, p. 74-80, 2012.

[28] NETO, A.C.R.; MARASCHIN, M.; DI PIERO, R.M. Antifungal activity of salicylic acid against Penicillium expansum and its possible mechanisms of action. International Journal of Food Microbiology, Turin, v. 215, p. 64-70, 2015.

[29] OLIVEIRA, M.B.; JUNIOR, M.L.; GROSSI-DE-SÁ, M.F.; PETROFEZA, S. Exogenous application of methyl jasmonate induces a defense response and resistance against Sclerotinia sclerotiorum in dry bean plants. Journal of Plant Physiology, Amsterdam, v. 182, p. 13-22, 2015.

[30] PACHECO, C.A.; SCHINOR, E.H.; AZEVEDO, F.A.; BASTIANEL, M.; CRISTOFANI-YALY, M. Characterization of fruits of Tangor TM x LP 290 for fresh fruit market. Revista Brasileira de Fruticultura, Jaboticabal, v.36, n.4, p.805-812, 2014.

[31] PINTO, J.A.V.; THEWES, F.R.; SCHORR, M.R.W.; CECONI, D.L.; BRACKMANN, A.; HAMANN, J.J.; FRONZA, D. Mass loss induction on physical and chemical qualities of ‘Murcott’ Tangor during cold storage. Bioscience Journal, Uberlândia, v.31, n.5, p.1325-1332, 2015.

[32] QUAGLIA, M.; EDERLI, L; PASQUALINI, S; ZAZZERINI, A. Biological control agentes and chemicas induceres of resistance for postharvest control of Penicillium expansumLink.on apple fruit. Postharvest Biology and Technology, Amsterdam, v. 59, n. 3, p. 307-315, 2011.

[33] ROBERT-SEILANIANTZ, A.; GRANT, M.; JONES, J.D. Hormone crosstalk in plant disease and defense: more than just jasmonate-salicylate antagonism. Annual Reviews of Phytopathology, Palo Alto, v. 49, p. 317-343, 2011.

[34] SANTOS, H.G. Sistema brasileiro de classificação dos solos. 2.ed. Rio de Janeiro: Embrapa Solos, 2006. 306 p.

[35] SIBOZA, X.I.; BERTLING, I.; ODINDO, A.O. Salicylic acid and methyl jasmonate improve chilling tolerance in cold-stored lemon fruit (Citrus limon). Journal of Plant Physiology, Amsterdam, v. 171, n. 18, p. 1722-1731, 2014.

[36] SWAIN, T.; HILLS, W.E. The phenolic constituents of Punnus domestica.The quantitative analysis of phenolic constituents. Journal of the Science of Food and Agriculture, Washington, v. 19, p. 63-68, 1959.

[37] WANG, Y.; LIU J. Exogenous treatment with salicylic acid attenuates occurrence of citrus canker in susceptible navel Orange (Citrus sinensis Osbeck). Journal of Plant Physiology, Amsterdam, v. 169, n. 12, p. 1143-1149, 2012.

[38] ZENG, R.; ZHANG, A.; CHEN, J.; FU, Y. Postharvest quality and physiological responses of clove bud extract dip on ‘Newhall’ navel orange. Scientia Horticulturae, New York, v. 138, p. 253-258, 2012.

[39] ZHICHAO, W.; FUHUA, W.; SHUAI, L.; YINGQIONG, D.; FURONG, L.; RUIYING, D.; DIAN, W.; JIE, Z. Comparative responses to silicon and selenium in relation to cadmium uptake, compartmentation in roots, and xylem transport in flowering Chinese cabbage (Brassica campestris) L. ssp. Chinensis var. utilis) under cadmium stress. Environmental and Experimental Botany, Amsterdam, v. 131, p. 173-180, 2016.

[40] ZHU, Z.; CHEN, Y.; SHI, G.; ZHANG, X. Selenium delays tomato fruit ripening by inhibiting ethylene biosynthesis and enhancing the antioxidant defense system. Food Chemistry, New York, v. 219, p. 179-184, 2017.

Inducers	L*				a*				Titratable acidity (% citric acid)				Soluble solids (°Brix)				Ascorbic acid (mg 100g^-1)
	Storage period
	0		30		0		30		0		30		0		30		0		30
Control	60.61		58.94		26.43		27.77		1.82		1.46		12.10		13.03		22.21		21.64
Selenium	61.64	aA^1/ns	60.70	aA^ns	26.95	aA^ns	28.39	aA^ns	1.84	aA^ns	1.72	abA^ns	13.11	aA^ns	13.95	aA^ns	25.68	aA^s	23.93	abB^ns
Silicon	62.06	aA^ns	60.29	aB^ns	26.13	aB^ns	29.30	aA^ns	1.77	aA^ns	1.54	bA^ns	12.50	aA^ns	13.30	abA^ns	22.95	abA^ns	21.48	abA^ns
ASM	61.06	aA^ns	59.99	aA^ns	26.70	aB^ns	27.94	aA^ns	1.68	aA^ns	1.30	cB^ns	11.20	aA^ns	12.35	bA^ns	21.31	bA^ns	20.73	bA^ns
MeJa	61.90	aA^ns	60.29	aB^ns	25.54	aB^ns	27.61	aA^ns	1.81	aA^ns	1.51	bcB^ns	11.63	aA^ns	12.95	abA^ns	23.58	abA^ns	22.76	abA^ns
Thiamethoxam	60.92	aA^ns	59.99	aA^ns	25.74	aB^ns	27.84	aA^ns	1.79	aA^ns	1.67	abA^ns	12.71	aA^ns	13.33	abA^ns	23.20	abA^ns	21.91	abA^ns
Imidacloprid	62.02	aA^ns	59.64	aB^ns	25.45	aB^ns	27.87	aA^ns	1.99	aA^ns	1.85	aB^s	12.56	aB^ns	13.46	abA^ns	25.32	aA^s	24.46	aA^s
C.V. (%)	1.2				3.2				10.7				3.8				6.8

Inducers	Fresh mass loss (%)		Rot index (%)
Control	13.83		5.00
Selenium	7.74	b^1/s	0.83	a ^s
Silicon	7.78	b ^s	0.83	a ^s
Acibenzolar-S-methyl	7.35	b ^s	0.83	a ^s
Methyl Jasmonate	11.35	a ^ns	0.83	a ^s
Thiamethoxam	8.23	b ^s	0.83	a ^s
Imidacloprid	8.25	b ^s	0.83	a ^s
C.V. (%)	34.7		58.8

Variables	Storage period				C.V. (%)
Variables	0		30		C.V. (%)
b*	63.46	a¹	58.77	b	1.8
Hue	67.65	a	64.35	b	1.6
pH	3.16	b	3.21	a	1.7
SS/TA ratio	6.79	b	8.41	a	12.0

Inducers	Total phenolics (mg EAC 100g^-1) in pulp				Total phenolics (mg EAC 100g^-1) in peel					DPPH (μg TEAC g^-1) in pulp					DPPH (μg TEAC g^-1) in peel
	Storage period
	0		30			0		30			0		30			0		30
Control	75.89		60.76			451.69		428.57			85.66		76.46			629.35		530.19
Selenium	85.10	abA^{1/ ns}	73.44	aB^s		457.68	aA^ns	435.22	aA^ns		109.75	aA^s	97.10	aA^ns		663.34	aA^ns	545.18	aB^ns
Silicon	86.19	abA^ns	75.53	aB^s		500.04	aA^s	477.59	aA^s		123.19	aA^s	109.82	aA^s		721.95	aA^ns	605.28	aB^ns
ASM	77.00	bA^ns	66.18	aA^ns		468.05	aA^ns	445.10	aA^ns		100.35	aA^ns	92.01	aA^ns		701.84	aA^ns	583.18	aB^ns
MeJa	86.99	abA^ns	76.16	aB^s		485.07	aA^ns	462.29	aA^ns		116.39	aA^s	102.01	aA^s		763.20	aA^s	644.54	aA^s
Thiamethoxam	82.82	abA^ns	69.49	aB^ns		479.18	aA^ns	456.56	aA^ns		111.44	aA^s	93.15	aA^ns		700.61	aA^ns	581.78	aB^ns
Imidacloprid	90.92	aA^s	76.08	aB^s		507.04	aA^s	484.42	aB^s		124.87	aA^s	111.57	aA^s		734.03	aA^ns	615.04	aB^ns
C.V. (%)	7.9					6.0					11.7					10.4

Brasil

Brasil

Systemic resistance induction in ‘Ortanique’ tangor

Indução de resistência sistêmica em tangor ‘Ortanique’

Abstract

Resumo

Introduction

Material and Methods

Results and Discussion

Conclusion

Publication Dates

History