Effect of anti-hail nets with different colors on ‘Eva’ apple trees agronomical responses

Stroka, Marília Aparecida; Ayub, Ricardo Antonio; Silva, Daurimar Mendes da; Pessenti, Isabela Letícia; Pereira, André Belmont; Barbosa, Eduardo Augusto Agnellos

doi:10.1590/0100-29452021157

Abstract

The aim of the current research was to evaluate the impact of ‘Eva’ apple tress cultivation under nets with different colors as opposed to cultivation deprived of net treatment on the attributes related to the vigor of the plant, production and fruit quality. The evaluations were carried out during the 2017/18 and 2018/19 crop growing seasons at commercial production fields located in the municipality of Porto Amazonas, PR. The treatments in study consisted of a control (plants grown with no protecting net), along with plants protected by anti-hail nets of distinct colors such as white, crystal (transparent) and black. The following response variables were assessed herein: length and diameter of the branch, plant height and branch diameter as plant vigor measurements, crop production (kg plant-1) and yield (kg ha-1), and number of fruits per plant as to productive yield of the cropping system, as well as shape (height and diameter) of the fruits, mass, Hue angle, firmness, soluble solids and titratable acidity to test grade or fruit quality. There was no significant effect of protecting nets on both vigor and development of the plants. However, production and yield were consistently more expressive under crystal and white protecting nets throughout the second crop growing season. This demonstrated that ‘Eva’ apple trees were conducive to render as well as or even better than those plants bereft of protecting nets in view of the fact that the former treatments caused the plants to suffer less harmful impacts promoted by hail events, excess of wind, and sun burning disorders. The black anti-hail net resulted in negative outcomes as to coloration of the fruits in conjunction with titratable acidity, making them reddish and acidic and, therefore, less attractive for in natura commercial consumption.

Index terms
Fruit quality; plant growth; photo-selective net

Resumo

Este trabalho objetivou avaliar a interferência do cultivo de macieiras ‘Eva’ sob tela anti-granizo de diferentes cores, em comparação com o cultivo em pleno sol, sobre os atributos relativos ao vigor da planta, à produção e à qualidade de frutos. As avaliações foram realizadas durante as safras de 2017/2018 e 2018/2019 em pomar comercial localizado no município de Porto Amazonas-PR, Brasil. Os tratamentos consistiram em um controle (plantas sem cobertura) e plantas cobertas com telas antigranizo, nas cores branca, cristal (transparente) e preta. As variáveis avaliadas foram as seguintes: comprimento e diâmetro de ramo, altura da planta e diâmetro de tronco, tomadas para medidas de vigor da planta, bem como produção (kg planta^-1), produtividade (kg ha^-1) e número de frutos por planta, com vistas à caracterização do rendimento biológico da spécie cultivada, e ainda forma (altura e diâmetro) dos frutos, massa, ânguloHue, firmeza, sólidos solúveis e acidez titulável, para atestar a qualidade da fruta. Constatou-se que não ocorreram diferença de vigor e desenvolvimento da planta sob telados, em comparação com o cultivo sem tela de proteção. No entanto, a produção e a produtividade foram mais expressivas sob as telas cristal e branca, durante a segunda safra, demonstrando que a cultivar Eva pode produzir tão bem ou melhor que quando cultivada a céu aberto, mantendo-se as plantas mais protegidas de riscos climáticos relativos, como granizo, vento excessivo e queimadura de sol. A tela protetora na cor preta proporcionou impactos negativos sobre a coloração de frutos e a acidez titulável, tornando os frutos menos vermelhos e ácidos e, portanto, menos atraentes para consumo in natura.

Termos para indexação
Qualidade da fruta; crescimento de planta; tela fotoseletiva

Introduction

The cultivation of apple trees (Malus domestica Borkh) promotes remarkable bursts either in national or international agrobusiness, since it favors growth of municipalities all over the world in such a fashion as to generate jobs and substantial incomes. The world apple tree productions reached the mark of 86.1 million of tons of fruits in 2018, from 4.9 million hectares harvested, where as in Brazil particularly at Southern region productions soared to roughly 1.2 million of tons from 33 million hectares harvested (FAO, 2020 FAO. FAOSTAT: Statistics database. 2020. Disponível em: http://www.fao.org/faostat/en/#data. Acesso em: 02 jul. 2019.
http://www.fao.org/faostat/en/#data... ).

Among the challenges featuring apple tree production systems, the need of delivering fruits with good quality and appearance to the rural growers in the face of biotic and abiotic factors conditioning yield in an economically feasible way in view of sustainable agriculture deserves special attention from a research perspective. Especially in the southern region of Brazil, where the State of Paraná is located, destructive hailstorms are frequently observed, with higher incidence in the months of September to November, leading to risks of loss on quality and yield for apple tree cultivation (MARTINS et al., 2016 MARTINS, J.A.; BRAND, V.S.; FELIX, R.R.; MARTINS, L.D.; FREITAS, E.D.; GONÇALVES, F.L.T.; HALLAK, R.; DIAS, M.A.F.S.; CECIL, D.J. Climatology of destructive hailstorms in Brazil. Atmospheric Research, Amsterdam, v.184, p.126-138, 2016. ; PORSCH et al., 2018 PORSCH, A.; GANDORFER, M.; BITSCH, V. Strategies to manage hail risk in apple production. Agricultural Finance Review, Bingley, v.78, n.5, p.532-550, 2018. ; CALDANA et al., 2019 CALDANA, N.F.S.; SILVA, G.M.F.; MARTELOCIO, A.C.; NITSCHE, P.R., CARAMORI, P. Caracterização das ocorrências de precipitação de granizo e seus impactos socioeconômicos no estado do Paraná. Agrometeoros, Passo Fundo, v.27, n.2, p.1-14, 2019. ).

One of the current alternatives to be adopted in apple tree orchards lies in the usage of protecting nets with different colors, which possess a photo-selective action and in turn prevents injuries caused by hail events (MANJA and AOUN, 2019 MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. ). Apart from a conspicuous anti-hail function, such protecting nets might play a role in mitigating the impacts promoted by excess of wind and heat at a given specific-site, reduce physiological disturbs due to sun burning exposures, increase yield uniformity and also guarantee rentability plus profitability at commercial apple tree orchards (MANJA and AOUN, 2019 MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. ; SERVER et al., 2020 SEVER, M.B.; TOJNKO, S.; BREZNIKAR, A.; SKENDROVIC BABOJELIC, M.; IVANCIC, A.; SIRK, M.; UNUK, T. The influence of differently colored anti-hail nets and geomorphologic characteristics on microclimatic and light conditions in apple orchards. Journal of Central European Agriculture, Zagreb, v.21, n.2, p.386-397, 2020. ).

Nevertheless, a number of scientific investigations have been reporting changes in microclimate of apple tree orchards whenever protecting nets were employed, mainly as a function of significant reductions in fractions of photosynthetically active radiation flux densities, with effects ranging from the influence of morphophysiological characteristics of the apple variety, location of production fields, color, material structure and net spectrum taken into consideration. This poses questions and doubts concerning the possibility of protecting nets to trigger damages to cultivation and fruit quality expression at different environmental conditions (TREDER et al., 2016 TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016. ; MANJA and AOUN, 2019 MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. ; SEVER et al., 2020 SEVER, M.B.; TOJNKO, S.; BREZNIKAR, A.; SKENDROVIC BABOJELIC, M.; IVANCIC, A.; SIRK, M.; UNUK, T. The influence of differently colored anti-hail nets and geomorphologic characteristics on microclimatic and light conditions in apple orchards. Journal of Central European Agriculture, Zagreb, v.21, n.2, p.386-397, 2020. ).

In Brazil the main apple varieties cultivated at a large scale are to be ‘Gala’ and ‘Fuji’, mainly for the regions of temperate climates, whereas consumers little by little have their minds open to the introduction of new genotypes far more adaptable to regions with fewer cold hours patterns (BERNARDI et al., 2004 BERNARDI, J.; DENARDI, F.; HOFFMANN, A. Cultivares e porta-enxertos. In: NACHTIGALL, G.R. (ed.) Maçã: produção. Bento Gonçalves: Epagri, 2004. p.32-46. ). The Agronomic Institute of Paraná (IAPAR) selected Eva cultivar in the 1979 breeding program from the crossing between ’Anna’ and ’Gala’ cultivars, pointing out that such a genetic material was considered to demand a less amount of chilling requirements (ranging from 330 to 350 unities of cold hours) and also to be an option for tropical regions and under environmental conditions unsuitable to the development of other genotypes (HAUAGGE and TSUNETA, 1999 HAUAGGE, R.; TSUNETA, M. Iapar 75 - Eva, Iapar 76 - Anabela e Iapar 77 - Carícia - novas cultivares de macieira com baixa necessidade em Frio. Revista Brasileira de Fruticultura, Jaboticabal, v.21, n.3, p.239-242, 1999. ; HILGENBERG and AYUB, 2014 HILGENBERG, T; AYUB, R.A. Evaluation of Brassinosteroids in dormancy break and in growth of branches of Apple Tree (Malus domestica). Ambiência, Guarapuava, v.10, n.2, p.1-6, 2014. ). The ‘Eva’ fruits showed good quality, sweet, possess a balanced acidity, precocity and considerable resistance to diseases excelling yields at production fields located in Paraná, Minas Gerais and Northeast of Brazil (HAUAGGE e TSUNETA, 1999 HAUAGGE, R.; TSUNETA, M. Iapar 75 - Eva, Iapar 76 - Anabela e Iapar 77 - Carícia - novas cultivares de macieira com baixa necessidade em Frio. Revista Brasileira de Fruticultura, Jaboticabal, v.21, n.3, p.239-242, 1999. ; OLIVEIRA et al., 2011 OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; ABRAHÃO, E.; ZAMBON, C.R.; NORBERTO, P.M. Maçã ‘Eva’ desponta a produção no estado de Minas Gerais. Informe Agropecuário Epamig, Belo Horizonte, n.141, p.1-4, 2011. ; LOPES et al., 2012 LOPES, P.R.C.; OLIVEIRA, I.V.M.; SILVA-MATOS, R.R.S.; CAVALCANTE, Í.H.L.C. Caracterização fenológica, frutificação efetiva e produção de maçãs 'Eva' em clima semiárido no nordeste brasileiro. Revista Brasileira de Fruticultura, Jaboticabal, v.34, n.4, p.1277-1283, 2012. ). However, there is no scientific evidence describing the performance of such a genotype grown under protecting net conditions. In light of such a gap in research, this study aimed to evaluate the impacts of protecting nets with different colors (black, white and crystal clear color) compared to no screen treatment (control) on the agronomical responses of Eva cultivar expressed by crop aspects related to plant growth, yield and fruit quality in the region of Campos Gerais do Paraná, Brazil.

Material and methods

A field experiment was carried out throughout 2017/2018 and 2018/2019 crop growing seasons at a commercial apple tree orchard located in the municipality of Porto Amazonas, PR, Brazil (25° 34’ latitude South; 49° 57’ longitude West; 838 m altitude). According to the Köppen-Geiger classification, the climate is supposed to be Cfb (APARECIDO et al., 2016 APARECIDO, L.E. de O.; RICHETTI, J.; SOUZA, P.S. de; JOHANN, J.A. Köppen, Thornthwaite and Camargo climate classifications for climatic zoning in the State of Paraná, Brazil. Ciência e Agrotecnologia, Lavras, v.40, n.4, p.405-417, 2016. ). Sum of rainfall (mm), average air temperature (°C) and global radiation (W m-2) data during the experiment period were collected by Santa Catarina Agricultural Research and Rural Extension Company (EPAGRI) from a weather station, located in the municipality of Porto Amazonas, PR (Figure 1A, 1B and 1C) (EPAGRI, 2020 EPAGRI - Empresa de Pesquisa Agropecuária e Extensão Rural de Santa Catarina. Banco de dados de variáveis ambientais de Santa Catarina. Florianópolis: Epagri, 2020. 20p. ).

Figure 1
Growth conditions during the experimental period in the municipality of Porto Amazonas, PR, Brazil, sum of rainfall (mm) (A), average air temperature (°C) (B) and global radiation (W m-2), based on data from EPAGRI field weather stations. Source: EPAGRI (2020).

’Eva’ apple trees grafted onto ‘Maruba’ as a rootstock and ‘M9’ as an interstem filter were taken into account at our field experiment in view of Princesa cultivar as a pollinizer at a ratio 7:1, at four years-old of physiological age under the tall spindle planting system. In both growing seasons, comprising April through June, pruning and trunk strangulation were performed with the purpose of stimulating bud’s dormancy breaking.

Even using the cultivar Eva, which is less demanding in terms of the number of hours of cold, it is recommended to break dormancy to uniformize the sprout and make flowering compatible for this cultivar (CRUZ JUNIOR and AYUB, 2002 CRUZ JUNIOR, A. de O.; AYUB, R.A. Quebra de dormência de gemas de macieira cv.Eva tratadas com cianamida hidrogenada. Revista Brasileira de Fruticultura, Jaboticabal, v.24, n.2, p.576-578, 2002. ). To this end, 0.8% hydrogenated cyanamide along with 3% mineral oil was applied whenever swollen buds were visible in the field.For the chemical thinning, applications with 90 grams per hectare of benzyladenine growth regulator during both growing seasons were taken into consideration in order to cause the fruits to reach the size of 12-mm diameter along with flowers with low quality so that final load of fruits with 1 to 3 fruits per bud might have been achieved.

The treatments adopted in the current study comprised one control treatment featured by plants deprived of covering nets in conjunction with apple trees covered by anti-hail protecting nets with three different colors, such as white (2x6-mm sieve mesh), crystal (transparent, 3x7-mm sieve mesh) and black (2x5-mm sieve mesh) as illustrated in Figure 2. Plants disposed under such distinct nets remained covered and protected throughout the entire crop cycle of the apple trees in the experimental area. Protecting nets were set up at the first crop growing season along the main planting line in the face of two water format at a distance between rows of 20 – 30 cm to promote hail run-off out of between cultivation lines, following leveled cultivation orientation. All of the protecting nets had dimensions of 0.30-mm thickness by means of weaving ranging only from composition and coloration.

Figure 2
Commercial orchard of ‘Eva’ apple trees located in Porto Amazonas, PR, Brazil under black (A), crystal/transparent (B), white (C) protecting nets, and non-covering treatment (D).

The field experiment itself was split into analyses of plant growth, yield and fruit quality. Plant vigor were assessed by branch diameter (BD, mm) and branch length (BL, mm), gauged on two branches horizontally disposed at the medium height of crop canopy; plant height (PH, mm) measured from soil surface up to the tip of the highest branch of the plant; and trunk diameter (TD, mm) by means of a pachymeter at 15-cm high above soil surface. At manually harvest, fruits in commercial maturation stage were counted and weighted to determinate production (kg plant^-1), number of fruit per plant (NFP) and yield (kg ha^-1).

With regards to analyses dealing with post-harvest and determination of fruit quality, apple fruits were transported to the laboratory and stored in a frigorific chamber for a period lesser than 10 days until biometric and chemical analyses on the fruits were made. For each single apple fruit, the following physical variables were scrutinized: fruit mass (g) by means of a precision scale, fruit diameter (mm), plant height (mm) through a digital pachymeter positioned through equatorial and longitudinal lines of each fruit, respectively; superficial coloration of epidermis with the use of a Minolta colorimeter model Croma meter CR-400/410, seeking L*a*b parameters for the calculation of Hue angle (H) from the equations as follows: $H = t a n (b * / a *)$ when a* > 0 and b* > 0 or as $H = 180 ° - t a n (b * / a *)$ when a* < 0 e b*> 0, since angle 0o depicts pure red color, 90o represents yellow, 180o green, and 270o blue (LANCASTER et al., 1997 LANCASTER, J.E.; LISTER, C.E.; READY, P.F.; TRIGGS, C.M. Influence of pigment composition on skin color in a wide range of fruit and vegetables. Journal of the American Society for Horticultural Science, Alexandria, v.122, n.4, p.594–598, 1997. ); and finally pulp firmness (N) by means of a digital penetrometer with an 11 mm tip positioned at the portion of the fruit with the largest diameter by the removal of the epidermis from the locus.

Chemical variables were evaluated by quantification of total soluble solids (SS – °Brix) using a portable refractometer DIGIT model 103 along with titratable acidity (TA) in compliance with AOAC (2007), expressed in grams of malic acid per 100 mL of apple juice. Moreover, ratio defining the quotient between SS and TA proposed in order to examine aptitude of in natura consumption or industrial use was calculated.

The field experiment itself was split into analyses of vigor, plant development, yield and fruit quality.

As to plant vigor, the following response variables were assessed: branch diameter (BD, mm) and branch length (BL, mm) gauged on two branches horizontally disposed at the medium height of crop canopy, plant height (PH, mm) measured from soil surface up to the tip of the highest branch of the plant, and trunk diameter (TD, mm) by means of a pachymeter at 15-cm high above soil surface. For manual harvesting, fruits at commercial maturation stage were counted and weighted to determine production (kg plant^-1), number of fruits per plant (NFP) and yield (kg ha^-1).

The experimental data collected from apple tree orchards were subjected to statistical analyses by means of a computational system RStudio (R CORE TEAM, 2019 R CORE TEAM . R: a language and environment for statistical computing. A language and environment for statistical computing. Austria: R Foundation for Statistical Computing. Disponível em: https://www.R-project.org/. Acesso em: 05 mai. 2020
https://www.R-project.org/... ), package ExpDes, with the aim of verifying normality of the data by the Shapiro-Wilk Test at a 5% reliability and, whenever necessary, technique of data transformations was adopted prior to the analysis of variance (ANOVA) (p>0.05) to check veracity of both scientific and statistical hypotheses proposed herein. In order to quantify the effect of the factors on response variables scrutinized, the Tukey Test was applied with the main purpose of identifying significant differences among treatments at a 5% probability on the basis of multiple comparisons approach.

Results and discussion

Results have shown that the use of protecting nets throughout both crop growing seasons did not generate significant differences on vigor and plant development of apple trees.The averages obtained from the 2017/2018 and 2018/2019 harvests, were 287.8 and 290 cm for plant height, 7.52 and 7.45 cm for trunk diameter, 24.27 and 25.27 mm for branch diameter, and 101.72 and 109.87 cm for branch length, respectively.

According to Manja and Aoun (2019) MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. , the use of colorful net might be able to be conducive to vegetative growth of apple tree plants due to changes in the orchard microclimate that lead to reductions in leaf and air temperature regime in conjunction with low atmospheric evaporative demand rates, which will advantage net photosynthesis. Nevertheless, Leite et al. (2002) LEITE, G.B.; PETRI, J.L.; MONDARDO, M.. Efeito da tela antigranizo em algumas características dos frutos de macieira. Revista Brasileira de Fruticultura, Jaboticabal, v.24, n.3, p.714–716, 2002. examined the impact of a black anti-hail protecting net on biological responsiveness of Fuji and Gala cultivars in Fraiburgo, State of Santa Catarina, Brazil, throughout five production years and did not come up with significant discrepancies in branch growth between the use or non-use of protecting nets in apple tree commercial orchards. Bastías et al. (2012) BASTÍAS, R.M; MANFRINI, L.; CORELLI GRAPPADELLI, L. Exploring the potential use of photo-selective nets for fruit growth regulation in apple. Chilean Journal Of Agricultural Research, Santiago, v.72, n.2, p.224-231, 2012. found that a reduction of up to 37% of photosynthetic photon flux density, through the use of color nets, did not affect the growth of shoots and did not limit the allocation of carbohydrates in the plant.

Several factors affect the responses of the apple tree under nets (MUPAMBI et al., 2018 MUPAMBI, G.; ANTHONY, B.; LAYNE, D.R.; MUSACCHI, S.; SERRA, S.; SCH MIDT, T.; KALCSITS, L. The influence of protective netting on tree physiology and fruit quality of apple: A review. Scientia Horticulturae, Wageningen, v.236, p.60-72, mar. 2018. ), among which stand out the color of the net and changes in the microclimate (IGLESIAS and ALEGRE, 2006 IGLESIAS, I; ALEGRE, S. The effect of anti-hail nets on fruit protection, radiation, temperature, quality and profitability of ‘Mondial Gala’ apples. Journal of Applied Horticulture, Lucknow, v.2, n.8, p.91-100, 2006. ; AMARANTE et al., 2009 AMARANTE, C.V.T. do; STEFFENS, C.A.; MIQUELOTO, A.; ZANARDI, O.Z.; SANTOS, H.P. dos. Disponibilidade de luz em macieiras 'Fuji' cobertas com telas antigranizo e seus efeitos sobre a fotossíntese, o rendimento e a qualidade dos frutos. Revista Brasileira de Fruticultura, Jaboticabal, v.31, n.3, p.664-670, 2009. ; HUNSCHE et al., 2010 HUNSCHE, M.; BLANK, M.M.; NOGA, G. Does the microclimate under hail nets influence micromorphological characteristics of apple leaves and cuticles? Journal of Plant Physiology, Sttugart, v.167, n.12, p.974-980, 2010. ; TREDER et al., 2016; TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016. ), and mainly genetic characteristics (AMARANTE et al., 2011 AMARANTE, C.V.T. do; STEFFENS, C.A.; ARGENTA, L.C. Yield and fruit quality of ‘Gala’ and ‘Fuji’ apple trees protected by white anti-hail net. Scientia Horticulturae, Wageningen, v.129, n.1, p.79-85, 2011. ; LORDAN et al., 2018 LORDAN, J.; FRANCESCATTO, P.; DOMINGUEZ, L.I.; ROBINSON, T.L. Long-term effects of tree density and tree shape on apple orchard performance, a 20 year study—Part 1, agronomic analysis. Scientia Horticulturae, Wageningen, v.238, p.303-317, 2018. ; BOSCO et al., 2020 BOSCO, L.C.; BERGAMASCHI, H.; CARDOSO, L.S.; DE PAULA, V.A.; MARODIN, G.A.B.; BRAUNER, P.C. Solar radiation effects on growth, anatomy, and physiology of apple trees in a temperate climate of Brazil. International Journal of Biometeorology, Heidelberg, v.64, p.1969-1980, 2020. ). It is noteworthy that most research on the use of anti-hail net was developed for cultivars with high demands on the number of cold hours (‘Gala’ and ‘Fuji’), with no long-term information for ‘Eva’, demonstrating the importance of continuing evaluations of this project for at least another five years, since two harvests may not represent enough time to express significant differences in vegetative vigor.

With regards to production aspects no significant differences among treatments were detected for the averages of production (17.20 kg plant-1), yield (38,229 kg ha-1), and number of fruits per plant, NFP (152,52) during 2017/2018 crop growing season (Table 1), with climatic conditions of clearer days and less rainfall.

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Table 1
Production (kg plant^-1), yield (kg ha^-1) and number of fruits per plant (NFP) for apple trees belonging to the ‘Eva’ grown under protected environmental and open field conditions throughout the 2017/2018 and 2018/2019 crop growing seasons in Porto Amazonas, PR, Brazil.

However, throughout second growing season both crystal and white protecting nets provided the highest significant averages, 237.5 and 190.8 fruits per plant, respectively, as compared to no-screen use (91.0 fruits per plant) and black net treatment (128.1) (Table 1).

Regarding the control treatment, there was a strong impact on the final number of fruits per plant in 2018/2019 due to the vulnerability to which the fruits were exposed in this climatic condition such as episodes of rain, hail damage and also wind regimes. The fruits under black net do not receive the damage caused by the impact of rain, but rather, their development is affected by the quantity and quality of the light intercepted by the canopy. A lesser incidence of solar radiation flux density on crop canopy promoted by the black protecting net reduces carbohydrates reserves up to an extend of compromising differentiation of reproductive buds and reducing the number of fruits (AMARANTE et al., 2012 AMARANTE, C.V.T. do; STEFFENS, C.A.; ARGENTA, L.C. Radiation, yield, and fruit quality of ‘gala’ apples grown under white hail protection nets. Acta Horticulturae, The Hague, n.934, p.1067–1074, 2012. ).

There were divergent outcomes between seasons on mass and shape of the fruits (Table 2). Throughout the first crop growing season the black net treatment was the only one that significantly impacted both fruit mass (136.90 g) and diameter (65.72 mm) compared to control treatment (99.76 g and 58.76 mm, respectively), culminating in better shape responses although production and yield was not affected by the latter treatments adopted. Conversely, during 2018/2019 crop growing season, black net treatment triggered low values of fruit mass (112.94 g), diameter (60.80 mm) and height (62.12 mm).

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Table 2
Fruit mass, shape (diameter and height), and fruit firmness for the ‘Eva’ apple trees grown under protected environmental and open field conditions throughout both 2017/2018 and 2018/2019 crop growing seasons in Porto Amazonas, PR, Brazil.

Cropping system deprived of protecting nets led to a better performance of fruit caliber (diameter and height) throughout the 2018/2019 crop growing season, 99.76 g and 58.40 mm respectively. However, fruits subjected to the absence of net did not differ from fruits under white net in terms of mass (99.20 g), presenting the best results, followed by fruits grown under a crystal net (115. 91 g), both treatments with the best production and productivity averages in this crop growing season.

It is well known that fruit mass, shape (diameter plus height) and color skin are by far very important factors to be borne in mind when it comes to characterize fruit commercial value and also in the view of in natura consumption (TREPTOW et al., 1995 TREPTOW, R. de O.; QUEIROZ, M.; ANTUNES, P. Caracterização físico-química e sensorial de quatro cultivares de maçãs (Malus domestica Borkh.). Revista Brasileira de Agrociência, Pelotas, v.1, n.3, p.179-184, 1995. ). Size and shape might considerably contribute to expedite operations related to fruit processing, such as cuttings, unpeeling, and/ or classification. Fruits subjected to standardization on size and weight ease handling in great quantities, culminating in lesser losses. Oliveira et al. (2014) OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; MALTA, M.R. Qualidade da maçã cv. Eva produzida em duas regiões de Minas Gerais. Brazilian Journal of Food Technology, Campinas, v.17, n.4, p.269-272, 2014. reported that Eva cultivar particularly evidenced substantial variations in fruit mass ranging from 92.75 g to 190.85 g, whose values were quite similar to ours.

In the first growing season, with the climatic condition of greater available radiation, clearer, hotter days and with less rainfall (Figure 1) (EPAGRI, 2020 EPAGRI - Empresa de Pesquisa Agropecuária e Extensão Rural de Santa Catarina. Banco de dados de variáveis ambientais de Santa Catarina. Florianópolis: Epagri, 2020. 20p. ), there is a greater mass and height of fruits under a screened orchard, mainly under black net that offers higher shading, represents greater thermal comfort and use of water use, resulting in larger caliber fruits (AOUN and MANJA, 2019 MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. ). In the following year, with the climate with reversed conditions, the result might be explained by the more pronounced shading of the plants promoted by the black protecting net in conjunction with more frequent cloudy days plus abundant rainfall regimes which, probably, decreased photosynthetically active radiation (PAR) and stomatal opening, as shown in some studies (AMARANTE et al., 2007 AMARANTE, C.V.T. do; STEFFENS, C.A.; MOTA, C.S.; SANTOS, H.P. dos. Radiation, photosynthesis, yield, and fruit quality of 'Royal Gala' apples under hail protection nets. Pesquisa Agropecuária Brasileira, Brasília, DF, v.42, n.7, p.925-931, 2007. ( ; MCAUSLAND et al., 2016 MCAUSLAND, L.; VIALET-CHABRAND, S.; DAVEY, P.; BAKER, N.R.; BRENDEL, O.; LAWSON, T. Effects of kinetics of light-induced stomatal responses on photosynthesis and water-use efficiency. The New Phytologist, London, v.4, n.211, p.1209-1220, 2016. ), thus occurring a reduction in the photosynthetic capacity of the plant and consequently in the production of photoassimilates.Amarante et al. (2009) AMARANTE, C.V.T. do; STEFFENS, C.A.; MIQUELOTO, A.; ZANARDI, O.Z.; SANTOS, H.P. dos. Disponibilidade de luz em macieiras 'Fuji' cobertas com telas antigranizo e seus efeitos sobre a fotossíntese, o rendimento e a qualidade dos frutos. Revista Brasileira de Fruticultura, Jaboticabal, v.31, n.3, p.664-670, 2009. evaluated the effect of white and black nets on biological responses of ‘Fuji’ apple trees grown in Vacaria, RS, throughout three crop growing seasons and, then, obtained higher values of mean weight of fruits under black protecting net treatment as opposed to white net. Conversely, by taking into consideration studies proposed by Amarante et al. (2011) AMARANTE, C.V.T. do; STEFFENS, C.A.; ARGENTA, L.C. Yield and fruit quality of ‘Gala’ and ‘Fuji’ apple trees protected by white anti-hail net. Scientia Horticulturae, Wageningen, v.129, n.1, p.79-85, 2011. the use of white net resulted in increases in mean weight of fruits for both Gala and Fuji cultivars.

Our results demonstrated that plants covered with white and crystal nets may have production equal to or greater than plants uncovered, as demonstrated by Amarante et al. (2012) AMARANTE, C.V.T. do; STEFFENS, C.A.; ARGENTA, L.C. Radiation, yield, and fruit quality of ‘gala’ apples grown under white hail protection nets. Acta Horticulturae, The Hague, n.934, p.1067–1074, 2012. , while they were also safer as to the risk of damage by hail, excessive wind and sunburn, an advantage over the exposed plants (MANJA and AOUN, 2019 MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019. ).

Throughout the 2017/2018 crop growing season pulp firmness was greater for the fruits exposed to the white net treatment (56.09 N), as compared to black and crystal nets (40.44 N and 44.22 N, respectively) or the absence of a screen (41.91 N) (Table 2). On the other hand, during the second crop growing season there was no effect of treatments on pulp firmness, whose average was of 74.53 N.

Softening of the fruits in the face of maturation event is a result of combined actions triggered by enzymes, such as polygalacturonate, cellulate, β-galactosidases among others, which solubilize compounds present in the cellular wall (pectin, hemicellulose, cellulose) (ZHANG et al., 2010 ZHANG, L.; CHEN, F.; YANG, H.; SUN, X.; LIU, H.; GONG, X.; JIANG, C.; DING, C. Changes in firmness, pectin content and nanostructure of two crisp peach cultivars after storage. LWT - Food Science and Technology, Amsterdam, v.43, n.1, p.26-32, 2010. ).

Oliveira et al. (2014) OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; MALTA, M.R. Qualidade da maçã cv. Eva produzida em duas regiões de Minas Gerais. Brazilian Journal of Food Technology, Campinas, v.17, n.4, p.269-272, 2014. reported that ‘Eva’ apple fruits at full-maturity varied from 33.82 to 67.37 N, providing support for the outcomes obtained in our current study during the first crop growing season in particular. Little or no change in firmness under the influence of different colors and shading percentages has also been reported in apple (TREDER et al., 2016 TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016. ), blueberry (LOBOS et al., 2013 LOBOS, G.A.; RETAMALES, J.B.; HANCOCK, J.F.; FLORE, J.A. ROMERO-BRAVO, S.; POZO, A. del. Productivity and fruit quality of Vaccinium corymbosum cv.Elliott under photo-selective shading nets. Scientia Horticulturae, Wageningen, v.153, p.143-149, 2013. ) and pepper fruits (GOREN et al., 2011 GOREN, A.; ALKALIA-TUVIA, S.; PERZELAN, Y.; AHARON, Z.; FALLIK, E. Photoselective shade nets reduce postharvest decay development in pepper fruits. Advances in Horticultural Science, Firenze, v.25, n.1, p.26-31, 2011. ).

Chitarra and Chitarra (2005) CHITARRA, M.I.F.; CHITARRA, A.B. Pós-colheita de frutas e hortaliças: fisiologia e manuseio. Lavras: UFLA, 2005. 785 p. highlighted that in the face of fruit ripening there was a rise in soluble solids, as well as a drop in titratable acidity linked to consumption of organic acids. Usually literature assumes that apple fruits with ratio < 20 are considered to be ideal for industry and processing, whereas fruits featured with ratio above 20 are more amenable to in natura consumption. Under the influence of all of treatments throughout both harvests ratio remained above 20, pointing out the potential of ‘Eva’ apple fruits to be targeted for in natura consumption, regardless of protecting net choice.

Throughout the 2017/2018 crop growing season crystal net referred to the only treatment that promoted significant negative impacts on soluble solids of the fruits, being 11.6% lower than the average of other treatments, with fruits showing an average of 10.44 °Brix. Conversely, during 2018/2019 crop growing season (Table 3) quality parameters of the apple trees was not quite the same, with control treatment providing the highest average of soluble solids (15.12 °Brix) followed by the crystal (14.08 °Brix), black (13.84 °Brix) and white (13.08 °Brix) protecting nets, having noticed, therefore, statistical differences among previous treatments.

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Table 3
Soluble solids (SS), titratable acidity (TA) and Hue angle (oHue) of ‘Eva’ apple trees grown under protected environmental and open field conditions throughout both 2017/2018 and 2018/2019 crop growing seasons in Porto Amazonas, PR, Brazil.

Feliciano et al. (2010) FELICIANO, R.P.; ANTUNES, C.; RAMOS, A.; SERRA, A.T.; FIGUEIRA, M.E.; DUARTE, C.M.M.; CARVALHO, A.; BRONZE, M.R. Characterization of traditional and exotic apple varieties from Portugal. Part 1 – Nutritional, phytochemical and sensory evaluation. Journal of Functional Foods, Binghamton, v.2, n.1, p.35-45, 2010. demonstrated that apple trees more exposed to incident solar radiation are more prone to reveal higher contents of soluble solids, an observation that might explain why cropping system taking into account non-protecting net in the orchard rendered sweeter fruits.

In addition, Iglesias and Alegre (2006) IGLESIAS, I; ALEGRE, S. The effect of anti-hail nets on fruit protection, radiation, temperature, quality and profitability of ‘Mondial Gala’ apples. Journal of Applied Horticulture, Lucknow, v.2, n.8, p.91-100, 2006. report that fruits under a net later ripen to fruits grown without cover, directly affecting the results of soluble solids in this study, since all treatments were harvested on the same day.

Oliveira et al. (2014) OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; MALTA, M.R. Qualidade da maçã cv. Eva produzida em duas regiões de Minas Gerais. Brazilian Journal of Food Technology, Campinas, v.17, n.4, p.269-272, 2014. found values ranging from 9.22 to 13.62 oBrix for the ‘Eva’ along with titratable acidity within the range of 0.32 to 0.43 g 100 g-1, whereas Chagas et al. (2012) CHAGAS, E.A.; CHAGAS, P.C.; PIO, R.; BETTIOL NETO, J.E.; SANCHES, J.; CARMO, S.A. do; CIA, P.; PASQUAL, M.; CARVALHO, A. dos S. Produção e atributos de qualidade de cultivares de macieira nas condições subtropicais da região Leste paulista. Ciência Rural, Santa Maria, v.42, n.10, p.1764-1769, 2012. obtained similar results reported in the current research expressed by an average of 15.2 oBrix for the same genotype under scrutiny, indicating that the use of protective nets did not affect the organoleptic quality of the fruits for this attribute.

In spite of the fact that black net seems to be conducive to acceptable ratios for in natura consumption, such a treatment resulted in the highest titratable acidity throughout both crop growing seasons (Table 3) with thresholds near or above 0.45 g of malic acid 100 mL-1 fruit juice, reference value used in order to label fruits as sweet rather than acid (SCHOBINGER et al., 1995 SCHOBINGER, M. et al. Phenolic compounds in apple juice. Positive and negatives effects. Fruit Processing, Schönborn, v.5, n.6, p.171- 178, 1995. ). The accumulation of organic acids, such as malic acid, was also observed in tomato (ALDRICH et al., 2010 ALDRICH, H.T.; SALANDANAN, K.; KENDALL, P.; BUNNING, M.; STONAKER, F.; KÜLEN, O.; STUSHNOFF, C. Cultivar choice provides options for local production of organic and conventionally produced tomatoes with higher quality and antioxidant content. Journal of the Science of Food And Agriculture, London, v.90, n.15, p.2548-2555, 2010. ) and grape berry (MARTÍNEZ-LÜSCHER et al., 2017 MARTÍNEZ-LÜSCHER, J.; CHEN, C.C.L.; BRILLANTE, L.; KURTURAL, S.K. Partial solar radiation exclusion with color shade nets reduces the degradation of organic acids and flavonoids of grape berry (Vitis vinífera L.). Journal of Agricultural and Food Chemistry, Washington, v.65, n.49, p.10693-10702, 2017. ) under black net, and this result can be directly connected to the lower temperature of the canopy due to the increased shadowing.

Rienth et al. (2016) RIENTH, M.; TORREGROSA, L.; SARAH, G.; ARDISSON, M.; BRILLOUET, J.M.; ROMIEU, C. Temperature desynchronizes sugar and organic acid metabolism in ripening grapevine fruits and remodels their transcriptome. BMC Plant Biology, v.16, n.1, p.1-23, 2016. observed in grapevine fruits that the decrease in the temperature of the environment favors the accumulation of malic acid due to the expression of the genes involved in respiration of this acid being positive regulated with the increase in temperature.

Our results, which are represented in Table 3, demonstrated that the use of black protecting net significantly affected Hue angle in comparison to control treatment in both seasons crop, going from 25.05 in the treatment without using nets to 45.36 under black net in 2017/18 and from 28.06 in the control to 34.28 under black net in the 2018/19 season crop, with negative impacts on appearance of the fruits, which had their core more yellowish and less attractive to the consumers. Both white and crystal protecting net treatments did not bring about any significant effect on Hue angle for ‘Eva’ apple fruits, whose findings obtained herein were in accordance with the outcomes reported by Chagas et al. (2012) CHAGAS, E.A.; CHAGAS, P.C.; PIO, R.; BETTIOL NETO, J.E.; SANCHES, J.; CARMO, S.A. do; CIA, P.; PASQUAL, M.; CARVALHO, A. dos S. Produção e atributos de qualidade de cultivares de macieira nas condições subtropicais da região Leste paulista. Ciência Rural, Santa Maria, v.42, n.10, p.1764-1769, 2012. .

The reddish color of apple peel is mainly due to the biosynthesis and accumulation of anthocyanins and this process is significantly affected by the light composition, as ultraviolet-B (UV-B), light blue, red (R) and far red (FR) radiation, and quantity (BASTÍAS et al., 2012 BASTÍAS, R.M; MANFRINI, L.; CORELLI GRAPPADELLI, L. Exploring the potential use of photo-selective nets for fruit growth regulation in apple. Chilean Journal Of Agricultural Research, Santiago, v.72, n.2, p.224-231, 2012. ; MUSACCHI and SERRA, 2018 MUSACCHI, S.; SERRA, S. Apple fruit quality: overview on pre-harvest factors. Scientia Horticulturae, Wageningen, v.234, p.409-430, 2018. ). With this, it is noted that fruits more exposed to solar radiation under prevailing weather conditions of clear days mainly might galvanize reddish coloration more rapidly and also more intensively as opposed to fruits protected by anti-hail nets in production fields (LEITE et al., 2002 LEITE, G.B.; PETRI, J.L.; MONDARDO, M.. Efeito da tela antigranizo em algumas características dos frutos de macieira. Revista Brasileira de Fruticultura, Jaboticabal, v.24, n.3, p.714–716, 2002. ; SOLOMAKHIN et al., 2012 SOLOMAKHIN, A.; TRUNOV, Y.V.; BLANKE, M.; NOGA, G.J. Environmental changes under hail protective nets with different coloration affect fruit quality. Acta Horticulturae, The Hague, n.932, p.231-237, 2012. ; BOSCO et al., 2017 BOSCO, L.C.; BERGAMASCHI, H.; DE PAULA, V.A.; MARODIN, G.A.B.; BRAUNER, P.C. Microclimate alterations caused by agricultural hail net coverage and effects on apple tree yield in subtropical climate of Southern Brazil. Bragantia, Campinas, v.77, n.1, p.181-192, 2017. ; PAVANELLO et al., 2019) PAVANELLO, A.P.; ZOTH, M.; AYUB, R.A. ; LOS, K.K. de S. Different methods of thinning influenced by variety and hail nets in apple orchards. Agricultural Research and Technology: Open Access Journal, California, v.3, n.22, p.69-79, 2019. . Treder et al. (2016) TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016. examined the effects of white, gray, black protecting nets along with non-covering treatment on the coloration of ‘Sampion’ and ‘Jonagold’ apple fruits and came up with evidences that apple fruits presented a less intense reddish coloration under the influence of gray and black nets, as Pavanello et al. (2019) PAVANELLO, A.P.; ZOTH, M.; AYUB, R.A. ; LOS, K.K. de S. Different methods of thinning influenced by variety and hail nets in apple orchards. Agricultural Research and Technology: Open Access Journal, California, v.3, n.22, p.69-79, 2019. also evidenced negative effects of black net on apple fruit coloration belonging to Braeburn and Pinova cultivars, agreeing with our results.

The results for peel apple fruits can be justified by the higher shading due to the smaller mesh of the black nets and mainly by the reduced availability of UV radiation, blue, R and the R:FR ratio in the canopy of the plants under this net, factors that down regulate the expression of genes and transcription factors of the anthocyanin metabolic pathway (UBI et al., 2006 UBI, E.; HONDA, C.; BESSHO, H.; KONDO, S.; WADA, M.; KOBAYASHI, S.; MORIGUCHI, T. Expression analysis of anthocyanin biosynthetic genes in apple skin: effect of UV-B and temperature. Plant Science, New York, v.170, n.3, p.571-578, 2006. ; AMARANTE et al., 2007 AMARANTE, C.V.T. do; STEFFENS, C.A.; MOTA, C.S.; SANTOS, H.P. dos. Radiation, photosynthesis, yield, and fruit quality of 'Royal Gala' apples under hail protection nets. Pesquisa Agropecuária Brasileira, Brasília, DF, v.42, n.7, p.925-931, 2007. ( ; FENG et al., 2013 FENG, F.; LI, M.; MA, F.; CHENG, L. Phenylpropanoid metabolites and expression of key genes involved in anthocyanin biosynthesis in the shaded peel of apple fruit in response to sun exposure. Plant Physiology And Biochemistry, Amsterdam, v.69, p.54-61, 2013. ; LI et al., 2013 LI, Y.Y.; MAO, K.; ZHAO, C.; ZHAO, X.Y.; ZHANG, R.F.; ZHANG, H.L.; SHU, H.R. HAO, Y.J. Molecular cloning and functional analysis of a blue light receptor gene MdCRY2 from apple (Malus domestica). Plant Cell Reports, Berlin, v.32, n.4, p.555-566, 2013. ; AN et al., 2020 AN, J.P.; LIU, Y.J.; ZHANG, X.W; BI, S.Q.; WANG, X.F.; YOU, C.X.; HAO, Y.J. Dynamic regulation of anthocyanin biosynthesis at different light intensities by the BT2-TCP46-MYB1 module in apple. Journal of Experimental Botany, Oxford, v.71, n.10, p.3094-3109, 2020. ).

Finally, there was no significant effect of protecting nets on vegetative vigor of the ‘Eva’ apple trees grown in Porto Amazonas, PR, Brazil, during the two years of study, with possible long-term effect, so this experiment should be continued to monitor possible changes in plant vigor.

Production and yield were consistently more expressive under crystal and white protecting nets throughout the second crop growing season mainly. Black net treatment evidenced negative outcomes as to coloration of the fruits in conjunction with titratable acidity, making them less reddish and acid and, therefore, less attractive for the commercial consumption. New treatments should be investigated using the same mesh size for nets, negating any effects of this factor.

Conclusions

The use of white or crystal anti-hail nets for ‘Eva’ apple trees is advantageous to guarantee good fruit quality and promote substantial yields in commercial orchards. Conversely, black anti-hail net culminated in negative biological responses concerning coloration of the fruits along with titratable acidity causing them to be less reddish and acidic and, therefore, less enticing for in natura commercial consumption.

Acknowlegments

The authors are very grateful to the Kitty Apple Fruit Company for the concession of ‘Eva’ apple tree fruits employed for the conduction of the field trial related to the current research, as well as to peers who work for the Laboratory of Biotechnology Applied to Fruit Science belonging to the State University of Ponta Grossa for the logistical support provided. Special thanks are also devoted to the technician Wilson Padilha for his pivotal assistance along with crop analyses thoroughly made.

ALDRICH, H.T.; SALANDANAN, K.; KENDALL, P.; BUNNING, M.; STONAKER, F.; KÜLEN, O.; STUSHNOFF, C. Cultivar choice provides options for local production of organic and conventionally produced tomatoes with higher quality and antioxidant content. Journal of the Science of Food And Agriculture, London, v.90, n.15, p.2548-2555, 2010.
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HUNSCHE, M.; BLANK, M.M.; NOGA, G. Does the microclimate under hail nets influence micromorphological characteristics of apple leaves and cuticles? Journal of Plant Physiology, Sttugart, v.167, n.12, p.974-980, 2010.
IGLESIAS, I; ALEGRE, S. The effect of anti-hail nets on fruit protection, radiation, temperature, quality and profitability of ‘Mondial Gala’ apples. Journal of Applied Horticulture, Lucknow, v.2, n.8, p.91-100, 2006.
LANCASTER, J.E.; LISTER, C.E.; READY, P.F.; TRIGGS, C.M. Influence of pigment composition on skin color in a wide range of fruit and vegetables. Journal of the American Society for Horticultural Science, Alexandria, v.122, n.4, p.594–598, 1997.
LEITE, G.B.; PETRI, J.L.; MONDARDO, M.. Efeito da tela antigranizo em algumas características dos frutos de macieira. Revista Brasileira de Fruticultura, Jaboticabal, v.24, n.3, p.714–716, 2002.
LI, Y.Y.; MAO, K.; ZHAO, C.; ZHAO, X.Y.; ZHANG, R.F.; ZHANG, H.L.; SHU, H.R. HAO, Y.J. Molecular cloning and functional analysis of a blue light receptor gene MdCRY2 from apple (Malus domestica). Plant Cell Reports, Berlin, v.32, n.4, p.555-566, 2013.
LOBOS, G.A.; RETAMALES, J.B.; HANCOCK, J.F.; FLORE, J.A. ROMERO-BRAVO, S.; POZO, A. del. Productivity and fruit quality of Vaccinium corymbosum cv.Elliott under photo-selective shading nets. Scientia Horticulturae, Wageningen, v.153, p.143-149, 2013.
LOPES, P.R.C.; OLIVEIRA, I.V.M.; SILVA-MATOS, R.R.S.; CAVALCANTE, Í.H.L.C. Caracterização fenológica, frutificação efetiva e produção de maçãs 'Eva' em clima semiárido no nordeste brasileiro. Revista Brasileira de Fruticultura, Jaboticabal, v.34, n.4, p.1277-1283, 2012.
LORDAN, J.; FRANCESCATTO, P.; DOMINGUEZ, L.I.; ROBINSON, T.L. Long-term effects of tree density and tree shape on apple orchard performance, a 20 year study—Part 1, agronomic analysis. Scientia Horticulturae, Wageningen, v.238, p.303-317, 2018.
MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019.
MARTÍNEZ-LÜSCHER, J.; CHEN, C.C.L.; BRILLANTE, L.; KURTURAL, S.K. Partial solar radiation exclusion with color shade nets reduces the degradation of organic acids and flavonoids of grape berry (Vitis vinífera L.). Journal of Agricultural and Food Chemistry, Washington, v.65, n.49, p.10693-10702, 2017.
MARTINS, J.A.; BRAND, V.S.; FELIX, R.R.; MARTINS, L.D.; FREITAS, E.D.; GONÇALVES, F.L.T.; HALLAK, R.; DIAS, M.A.F.S.; CECIL, D.J. Climatology of destructive hailstorms in Brazil. Atmospheric Research, Amsterdam, v.184, p.126-138, 2016.
MCAUSLAND, L.; VIALET-CHABRAND, S.; DAVEY, P.; BAKER, N.R.; BRENDEL, O.; LAWSON, T. Effects of kinetics of light-induced stomatal responses on photosynthesis and water-use efficiency. The New Phytologist, London, v.4, n.211, p.1209-1220, 2016.
MUPAMBI, G.; ANTHONY, B.; LAYNE, D.R.; MUSACCHI, S.; SERRA, S.; SCH MIDT, T.; KALCSITS, L. The influence of protective netting on tree physiology and fruit quality of apple: A review. Scientia Horticulturae, Wageningen, v.236, p.60-72, mar. 2018.
MUSACCHI, S.; SERRA, S. Apple fruit quality: overview on pre-harvest factors. Scientia Horticulturae, Wageningen, v.234, p.409-430, 2018.
OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; ABRAHÃO, E.; ZAMBON, C.R.; NORBERTO, P.M. Maçã ‘Eva’ desponta a produção no estado de Minas Gerais. Informe Agropecuário Epamig, Belo Horizonte, n.141, p.1-4, 2011.
OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; MALTA, M.R. Qualidade da maçã cv. Eva produzida em duas regiões de Minas Gerais. Brazilian Journal of Food Technology, Campinas, v.17, n.4, p.269-272, 2014.
PAVANELLO, A.P.; ZOTH, M.; AYUB, R.A. ; LOS, K.K. de S. Different methods of thinning influenced by variety and hail nets in apple orchards. Agricultural Research and Technology: Open Access Journal, California, v.3, n.22, p.69-79, 2019.
PORSCH, A.; GANDORFER, M.; BITSCH, V. Strategies to manage hail risk in apple production. Agricultural Finance Review, Bingley, v.78, n.5, p.532-550, 2018.
R CORE TEAM . R: a language and environment for statistical computing. A language and environment for statistical computing. Austria: R Foundation for Statistical Computing. Disponível em: https://www.R-project.org/ Acesso em: 05 mai. 2020
» https://www.R-project.org/
RIENTH, M.; TORREGROSA, L.; SARAH, G.; ARDISSON, M.; BRILLOUET, J.M.; ROMIEU, C. Temperature desynchronizes sugar and organic acid metabolism in ripening grapevine fruits and remodels their transcriptome. BMC Plant Biology, v.16, n.1, p.1-23, 2016.
SEVER, M.B.; TOJNKO, S.; BREZNIKAR, A.; SKENDROVIC BABOJELIC, M.; IVANCIC, A.; SIRK, M.; UNUK, T. The influence of differently colored anti-hail nets and geomorphologic characteristics on microclimatic and light conditions in apple orchards. Journal of Central European Agriculture, Zagreb, v.21, n.2, p.386-397, 2020.
SCHOBINGER, M. et al. Phenolic compounds in apple juice. Positive and negatives effects. Fruit Processing, Schönborn, v.5, n.6, p.171- 178, 1995.
SOLOMAKHIN, A.; TRUNOV, Y.V.; BLANKE, M.; NOGA, G.J. Environmental changes under hail protective nets with different coloration affect fruit quality. Acta Horticulturae, The Hague, n.932, p.231-237, 2012.
TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016.
TREPTOW, R. de O.; QUEIROZ, M.; ANTUNES, P. Caracterização físico-química e sensorial de quatro cultivares de maçãs (Malus domestica Borkh.). Revista Brasileira de Agrociência, Pelotas, v.1, n.3, p.179-184, 1995.
UBI, E.; HONDA, C.; BESSHO, H.; KONDO, S.; WADA, M.; KOBAYASHI, S.; MORIGUCHI, T. Expression analysis of anthocyanin biosynthetic genes in apple skin: effect of UV-B and temperature. Plant Science, New York, v.170, n.3, p.571-578, 2006.
ZHANG, L.; CHEN, F.; YANG, H.; SUN, X.; LIU, H.; GONG, X.; JIANG, C.; DING, C. Changes in firmness, pectin content and nanostructure of two crisp peach cultivars after storage. LWT - Food Science and Technology, Amsterdam, v.43, n.1, p.26-32, 2010.

Publication Dates

Publication in this collection
14 June 2021
Date of issue
2021

History

Received
07 Dec 2020
Accepted
12 Mar 2021

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.

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[23] GOREN, A.; ALKALIA-TUVIA, S.; PERZELAN, Y.; AHARON, Z.; FALLIK, E. Photoselective shade nets reduce postharvest decay development in pepper fruits. Advances in Horticultural Science, Firenze, v.25, n.1, p.26-31, 2011.

[24] HAUAGGE, R.; TSUNETA, M. Iapar 75 - Eva, Iapar 76 - Anabela e Iapar 77 - Carícia - novas cultivares de macieira com baixa necessidade em Frio. Revista Brasileira de Fruticultura, Jaboticabal, v.21, n.3, p.239-242, 1999.

[25] HILGENBERG, T; AYUB, R.A. Evaluation of Brassinosteroids in dormancy break and in growth of branches of Apple Tree (Malus domestica). Ambiência, Guarapuava, v.10, n.2, p.1-6, 2014.

[26] HUNSCHE, M.; BLANK, M.M.; NOGA, G. Does the microclimate under hail nets influence micromorphological characteristics of apple leaves and cuticles? Journal of Plant Physiology, Sttugart, v.167, n.12, p.974-980, 2010.

[27] IGLESIAS, I; ALEGRE, S. The effect of anti-hail nets on fruit protection, radiation, temperature, quality and profitability of ‘Mondial Gala’ apples. Journal of Applied Horticulture, Lucknow, v.2, n.8, p.91-100, 2006.

[28] LANCASTER, J.E.; LISTER, C.E.; READY, P.F.; TRIGGS, C.M. Influence of pigment composition on skin color in a wide range of fruit and vegetables. Journal of the American Society for Horticultural Science, Alexandria, v.122, n.4, p.594–598, 1997.

[29] LEITE, G.B.; PETRI, J.L.; MONDARDO, M.. Efeito da tela antigranizo em algumas características dos frutos de macieira. Revista Brasileira de Fruticultura, Jaboticabal, v.24, n.3, p.714–716, 2002.

[30] LI, Y.Y.; MAO, K.; ZHAO, C.; ZHAO, X.Y.; ZHANG, R.F.; ZHANG, H.L.; SHU, H.R. HAO, Y.J. Molecular cloning and functional analysis of a blue light receptor gene MdCRY2 from apple (Malus domestica). Plant Cell Reports, Berlin, v.32, n.4, p.555-566, 2013.

[31] LOBOS, G.A.; RETAMALES, J.B.; HANCOCK, J.F.; FLORE, J.A. ROMERO-BRAVO, S.; POZO, A. del. Productivity and fruit quality of Vaccinium corymbosum cv.Elliott under photo-selective shading nets. Scientia Horticulturae, Wageningen, v.153, p.143-149, 2013.

[32] LOPES, P.R.C.; OLIVEIRA, I.V.M.; SILVA-MATOS, R.R.S.; CAVALCANTE, Í.H.L.C. Caracterização fenológica, frutificação efetiva e produção de maçãs 'Eva' em clima semiárido no nordeste brasileiro. Revista Brasileira de Fruticultura, Jaboticabal, v.34, n.4, p.1277-1283, 2012.

[33] LORDAN, J.; FRANCESCATTO, P.; DOMINGUEZ, L.I.; ROBINSON, T.L. Long-term effects of tree density and tree shape on apple orchard performance, a 20 year study—Part 1, agronomic analysis. Scientia Horticulturae, Wageningen, v.238, p.303-317, 2018.

[34] MANJA, K; AOUN, M. The use of nets for tree fruit crops and their impact on the production: A review. Scientia Horticulturae, Wageningen, v.246, p. 110-122, 2019.

[35] MARTÍNEZ-LÜSCHER, J.; CHEN, C.C.L.; BRILLANTE, L.; KURTURAL, S.K. Partial solar radiation exclusion with color shade nets reduces the degradation of organic acids and flavonoids of grape berry (Vitis vinífera L.). Journal of Agricultural and Food Chemistry, Washington, v.65, n.49, p.10693-10702, 2017.

[36] MARTINS, J.A.; BRAND, V.S.; FELIX, R.R.; MARTINS, L.D.; FREITAS, E.D.; GONÇALVES, F.L.T.; HALLAK, R.; DIAS, M.A.F.S.; CECIL, D.J. Climatology of destructive hailstorms in Brazil. Atmospheric Research, Amsterdam, v.184, p.126-138, 2016.

[37] MCAUSLAND, L.; VIALET-CHABRAND, S.; DAVEY, P.; BAKER, N.R.; BRENDEL, O.; LAWSON, T. Effects of kinetics of light-induced stomatal responses on photosynthesis and water-use efficiency. The New Phytologist, London, v.4, n.211, p.1209-1220, 2016.

[38] MUPAMBI, G.; ANTHONY, B.; LAYNE, D.R.; MUSACCHI, S.; SERRA, S.; SCH MIDT, T.; KALCSITS, L. The influence of protective netting on tree physiology and fruit quality of apple: A review. Scientia Horticulturae, Wageningen, v.236, p.60-72, mar. 2018.

[39] MUSACCHI, S.; SERRA, S. Apple fruit quality: overview on pre-harvest factors. Scientia Horticulturae, Wageningen, v.234, p.409-430, 2018.

[40] OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; ABRAHÃO, E.; ZAMBON, C.R.; NORBERTO, P.M. Maçã ‘Eva’ desponta a produção no estado de Minas Gerais. Informe Agropecuário Epamig, Belo Horizonte, n.141, p.1-4, 2011.

[41] OLIVEIRA, D.L.; ALVARENGA, A.B.; GONÇALVES, E.D.; MALTA, M.R. Qualidade da maçã cv. Eva produzida em duas regiões de Minas Gerais. Brazilian Journal of Food Technology, Campinas, v.17, n.4, p.269-272, 2014.

[42] PAVANELLO, A.P.; ZOTH, M.; AYUB, R.A. ; LOS, K.K. de S. Different methods of thinning influenced by variety and hail nets in apple orchards. Agricultural Research and Technology: Open Access Journal, California, v.3, n.22, p.69-79, 2019.

[43] PORSCH, A.; GANDORFER, M.; BITSCH, V. Strategies to manage hail risk in apple production. Agricultural Finance Review, Bingley, v.78, n.5, p.532-550, 2018.

[44] R CORE TEAM . R: a language and environment for statistical computing. A language and environment for statistical computing. Austria: R Foundation for Statistical Computing. Disponível em: https://www.R-project.org/ Acesso em: 05 mai. 2020
» https://www.R-project.org/

[45] RIENTH, M.; TORREGROSA, L.; SARAH, G.; ARDISSON, M.; BRILLOUET, J.M.; ROMIEU, C. Temperature desynchronizes sugar and organic acid metabolism in ripening grapevine fruits and remodels their transcriptome. BMC Plant Biology, v.16, n.1, p.1-23, 2016.

[46] SEVER, M.B.; TOJNKO, S.; BREZNIKAR, A.; SKENDROVIC BABOJELIC, M.; IVANCIC, A.; SIRK, M.; UNUK, T. The influence of differently colored anti-hail nets and geomorphologic characteristics on microclimatic and light conditions in apple orchards. Journal of Central European Agriculture, Zagreb, v.21, n.2, p.386-397, 2020.

[47] SCHOBINGER, M. et al. Phenolic compounds in apple juice. Positive and negatives effects. Fruit Processing, Schönborn, v.5, n.6, p.171- 178, 1995.

[48] SOLOMAKHIN, A.; TRUNOV, Y.V.; BLANKE, M.; NOGA, G.J. Environmental changes under hail protective nets with different coloration affect fruit quality. Acta Horticulturae, The Hague, n.932, p.231-237, 2012.

[49] TREDER, W.; MIKA, A.; BULER, Z.; KLAMBOWSKI, K. Effects of hail nets on orchard light microclimate, apple tree growth, fruiting and fruit quality. Acta Scientiarum Polonorum: Hortorum Cultus, Lublin, v.15, n.3, p.17-27, 2016.

[50] TREPTOW, R. de O.; QUEIROZ, M.; ANTUNES, P. Caracterização físico-química e sensorial de quatro cultivares de maçãs (Malus domestica Borkh.). Revista Brasileira de Agrociência, Pelotas, v.1, n.3, p.179-184, 1995.

[51] UBI, E.; HONDA, C.; BESSHO, H.; KONDO, S.; WADA, M.; KOBAYASHI, S.; MORIGUCHI, T. Expression analysis of anthocyanin biosynthetic genes in apple skin: effect of UV-B and temperature. Plant Science, New York, v.170, n.3, p.571-578, 2006.

[52] ZHANG, L.; CHEN, F.; YANG, H.; SUN, X.; LIU, H.; GONG, X.; JIANG, C.; DING, C. Changes in firmness, pectin content and nanostructure of two crisp peach cultivars after storage. LWT - Food Science and Technology, Amsterdam, v.43, n.1, p.26-32, 2010.

	2017/2018			2018/2019
Treatments	Production (planta^-1)^ns	Yield (kg ha^-1)^ns	NFP^ns	Production (kg planta^-1)	Yield (kg ha^-1)	NFP
Crystal	17.87 a	39,702 a	155.3 a	24.08 a	53,512 a	237.5 a
Black	17.66 a	39,231 a	140.0 a	14.27 bc	31,711 bc	128.1 b
White	16.01 a	35,574 a	145.7 a	20.28 ab	45,068 ab	190.8 a
Control	17.29 a	38,409 a	169.1 a	10.60 c	23,562 c	91.0 b
CV	32.90	32.90	32.73	30.04	30.04	29.99

	2017/2018					2018/2019
Treatments	Fruit **** (g)	Fruit diameter (mm)	Fruit height (mm)	Fruit firmness (N)	mass (g)		Fruit (mm)	height (mm)	Fruit (N)
Crystal	115.91 ab	61.40 b	63.40 ab	44.22 b	130.55 b		64.84 b	65.60 b	71,82 a
Black	136.90 a	65.72 a	66.68 a	40.44 b	112.94 c		60.80 d	62.12 d	75,33 a
White	99.20 b	59.32b	59.15 bc	56.09 a	145.07 a		63.80 c	64.01 c	76,35 a
Control	99.76 b	58.76 b	58.40 c	41.91 b	142.72 a		66.76 a	66.40 a	74,62 a
CV	4.88	9.20	9.23	7.08	3.43		1.18	1.37	13,74

	2017/2018			2018/2019
Treatments	SS (°Brix)	(g malic acid 100mL^-1)	°Hue	SS (°Brix)	(g malic acid 100mL^-1)	°Hue
Crystal	10.44 b	0.40 bc	32.53 b	14.08 b	0.29 a	30.24 ab
Black	11.76 a	0.42 c	45.36 a	13.84 bc	0.49 c	34.28 a
White	11.52 a	0.32 b	31.70 b	13.08 c	0.39 b	28.12 b
Control	12.16 a	0.19 a	25.05 b	15.12 a	0.47 c	28.06 b
CV	9.0	37.57	12.93	8.01	16.73	23.70

Brasil

Brasil

Effect of anti-hail nets with different colors on ‘Eva’ apple trees agronomical responses

Efeito de telas antigranizo de diferentes colorações sobre as respostas agronômicas de macieiras ‘Eva’

Abstract

Resumo

Introduction

Material and methods

Results and discussion

Conclusions

Acknowlegments

Publication Dates

History