Physicochemical characterization of watermelon accessions from traditional agriculture with resistance to Fusarium wilt

Silva, Amanda Rodrigues da; Ishikawa, Francine Hiromi; Costa, Antonio Elton da Silva; Cunha, Fábio Sanchez da; Galhardo, Cristiane Xavier

doi:10.1590/0034-737X2024710004

ABSTRACT

Watermelon has great importance due to its nutritional properties. The aim of this work was to study accessions classified as resistant to fusariosis. Twelve accessions and two cultivars, Sugar Baby and Charleston Gray (controls), were characterized for watermelon fruit quality descriptors. The experiment was conducted in Petrolina-PE, over two production cycles in a randomized complete block design, with three repetitions and five plants per plot. Two fruits per plot were sampled for characterization. Ten quantitative and seven qualitative descriptors were evaluated. For the qualitative traits, dissimilarity measures were determined by a matrix of Euclidean distance. At the second harvest, most accessions had higher organic acid and vitamin C content in the pulp and higher soluble solids (°Brix) content. The accessions were divided into four groups according to the Tocher method. There is variability among the evaluated accessions, and the accessions BGH-Univasf 40, BGH-Univasf 169, and BGH-Univasf 177 are potential sources for use in watermelon breeding programs. Accessions BGH-UNIVASF 76, BGH-UNIVASF 128, and BGH-UNIVASF 185 (Citrullus lanatus var. citroides) performed well in terms of total production, fruit mass, and vitamin C content.

Keywords
Citrullus lanatus ; Fusarium oxysporum f. sp niveum; germplasm; plant breeding

INTRODUCTION

The watermelon (Citrullus lanatus (Thunb.) Matsum. & Nakai), belonging to the cucurbit family (Cucurbitaceae) and originating in tropical regions of Equatorial Africa, is considered one of the most important vegetables produced and marketed worldwide (FAOSTAT, 2021FAOSTAT (2021) Food and Agriculture Organization of the United Nations. Available at: <http://www.fao.org/faostat/en/#data/QC>. Acessed on: March 14th, 2021.
http://www.fao.org/faostat/en/#data/QC... ). In Northeastern Brazil, watermelon can be grown year-round, both under irrigated conditions, as in the Vale do Submédio São Francisco, and in arid regions, where it is grown during the rainy season, often in mixed cultivation with other species (Embrapa, 2010aEMBRAPA – Empresa Brasileira de Pesquisa Agropecuária (2010a) Plantio - Sistema de produção de melancia. Available at: <https://sistemasdeproducao.cnptia.embrapa.br/FontesHTML/Melancia/SistemaProducaoMelancia/plantio.htm>. Accessed on: March 14th, 2021.
https://sistemasdeproducao.cnptia.embrap... ). The fruits of watermelon are used for both human and animal consumption, and due to their sweet and refreshing taste, they are especially appreciated in summer (Ramirez et al., 2021Ramirez JL, Juma S & Du X (2021) Consumer acceptance of watermelon flesh‐rind blends and the effect of rind on refreshing perception. Journal of Food Science, 86:1384-1392.). In 2019, the area under watermelon in Brazil was 91, 922 ha, with a production of 2.14 Mt (FAOSTAT, 2021FAOSTAT (2021) Food and Agriculture Organization of the United Nations. Available at: <http://www.fao.org/faostat/en/#data/QC>. Acessed on: March 14th, 2021.
http://www.fao.org/faostat/en/#data/QC... ).

One of the factors limiting the development of watermelon is the presence of pests and diseases during the cultivation cycle, which affect production and cause losses. Diseases affecting watermelon cultivation include those caused by root pathogens such as Fusarium wilt, which is caused by the fungus Fusarium oxysporum f. sp. niveum (Fon). This pathogen attacks the plant at different stages and causes severe damage with symptoms such as chlorosis, necrosis, vascular system browning, and finally wilting, and death of the plant (Rahman et al., 2021Rahman MZ, Ahmad K, Kutawa AB, Siddiqui Y, Saad N, Hun TG, Hata EM & Hossain MI (2021) Biology, Diversity, Detection and Management of Fusarium oxysporum f. sp. niveum Causing Vascular Wilt Disease of Watermelon (Citrullus lanatus): A Review. Agronomy, 11:1310.). Various aspects, including economic and environmental factors, make it difficult to control Fusarium wilt in growing areas, so it is important to obtain genetically resistant material, which is the most efficient control measure (Zhang et al., 2015Zhang M, Xu JH, Liu G, Yao XF, Li PF & Yang XP (2015) Characterization of the watermelon seedling infection process by Fusarium oxysporum f. sp. niveum. Plant Pathology, 64:1076-1084., Costa et al., 2018Costa AES, Cunha FS, Honorato AC, Capucho AS, Dias RDCS, Borel JC & Ishikawa FH (2018) Resistance to Fusarium Wilt in watermelon accessions inoculated by chlamydospores. Scientia Horticulturae, 228:181-186.).

For the development of new resistant cultivars against Fusarium wilt, it is important to ensure the quality of these materials demanded by consumers. This factor will determine the success of the new cultivar, whether in the field to ensure production or in marketing to ensure consumer acceptance. Therefore, it is important to characterize materials that express resistance to diseases, either for use as parent in crosses (Prakash et al., 2016Prakash NS, Devasia J, Raghuramulu Y & Aggarwal RK (2016) Genetic diversity and coffee improvement in India. In: Vijay Rani Rajpal, Satyawada Rama Rao & Soom Nath Raina (Ed.) Molecular breeding for sustainable crop improvement. Cham, Springer. p.231-268.) or for direct use by the farmers. This is an essential activity that will provide information on potential genotypes conserved in germplasm banks or even landraces, important sources of genetic variability, especially for vegetables.

The aim of this study was to evaluate the physicochemical quality of watermelon accessions from the germplasm bank of the Universidade Federal do Vale do São Francisco (BGH-Univasf) phenotypically classified with resistance to Fusarium wilt.

MATERIAL AND METHODS

Experiments were carried out in the agricultural production area of the Campus de Ciências Agrárias (CCA) from Universidade Federal do Vale do São Francisco, in Petrolina-PE (latitude 9°19’10’’ S; longitude 40°33’39’’ W; average altitude of 376 m). The region’s climate is classified as semi-arid tropical, type BSh, according to the Köppen classification, with sparse and irregular precipitations. Two production cycles were evaluated, the first between the months of April to August 2016 and the second between October 2016 to January 2017. During cycle 1 the average monthly temperature data for the period varied from 24.39 ºC to 26.57 ºC and the average monthly relative humidity varied between 51.01 to 56.84%. For the second cycle, the temperatures were higher, varying from 26.57 to 28.96 ºC, and the average relative humidity in the period ranged from 42.02 to 59.30% (Figure 1).

Figure 1
Monthly average temperature (°C) and average relative humidity (%) data recorded in cycle 1 between the months of April and August 2016 and the second cycle October and January 2016.

Twelve watermelon accessions were evaluated, nine of which were C. lanatus var. lanatus and three of forage watermelon (C. lanatus var. citroides) collected in areas of traditional agricultural producers, which were previously evaluated and classified as resistant to Fusarium Wilt (Costa et al, 2021Costa AES, da Cunha FS, Araújo KMG, Lima Neto IS, Capucho AS, Borel JC & Ishikawa FH (2021) Morph-agronomic characterization of watermelon accessions with resistance to Fusarium Wilt. Anais da Academia Brasileira de Ciências, 93:e20191359.). In addition to the accessions, the commercial cultivars Sugar Baby susceptible to all races of Fon and Charleston Gray resistant to race 0 of Fon were used as control. In both cycles, a randomized block design with 14 treatments and three repetitions was used, with a spacing of 0.80 x 3.00 meters, with the plot consisting of five plants. Seeds of the 14 watermelon genotypes were placed to germinate in plastic trays containing commercial substrate for vegetables, after germination, when the seedlings had two definite fully developed leaves, they were transplanted to the field, located in the experimental sector of CCA - Univasf. The management of culture in the field was carried out with adequate fertigation and phytosanitary activities. For the characterization, two fruits were sampled per plot.

Fruits were harvested when they reached maturity, characterized by the drying of the tendril located in the peduncle of the fruit itself and by the change in the color of the fruit’s peel in the region that remains in contact with the soil (Embrapa, 2010bEMBRAPA – Empresa Brasileira de Pesquisa Agropecuária (2010b) Colheita e Pós-Colheita - Sistema de produção de melancia. Available at: <http://sistemasdeproducao.cnptia.embrapa.br/FontesHTML/Melancia/SistemaProducaoMelancia/colheita.htm>. Accessed on: March 14th, 2021.
http://sistemasdeproducao.cnptia.embrapa... ). After harvesting, the total fruit production per plot (TFP) and the mass of the first fruit developed per plot was obtained by weighing all the fruits produced by the same plant and the first developed fruit of each plant, respectively. For the other variables, two fruits were randomly selected per plot for characterization using eight quantitative descriptors: transversal diameter (TD) (cm), longitudinal diameter (LD) (cm), fruit shape index (FSI), soluble solids content (SS) (°Brix), titratable acidity (TA) (%), pH, vitamin C content (VC) (mg/100mL), SS/AT (ratio). For qualitative data were used: shape of the longitudinal section (SLS), epidermis color (EC), epidermis color intensity (ECI), stripes presence (SP), stripe type (ST), stripe color intensity (SCI) and stripe width (SW).

Transverse diameter and longitudinal diameter measurements were obtained from measuring the fruit with a tape measure. The fruit shape index was calculated using the TD⁄LD ratio, and the fruits were classified as long when they presented values for the ratio below 0.5, oval when 0.5 and 0.79 were observed, and spherical with values between 0.80 to 1.00, according to Silva et al. (2006)Silva MLD, Queiróz MAD, Ferreira MAJDF & Buso GS (2006) Caracterização morfológica e molecular de acessos de melancia. Horticultura Brasileira, 24:405-409..

Content of soluble solids (SS) was performed in a digital refractometer (Hanna ® scale from 0 to 85 °Brix), from the aliquot extracted in the central region of the fruit, from which samples of the pulp were also taken, stored in plastic bags identified and packed in polystyrene boxes carrying out the other post-harvest analyzes. In the laboratory, the watermelon pulps were processed in a blender to obtain the homogeneous juice, subsequently transferred to 45 mL Falcon tubes. The pH was measured with pH meter calibrated with pH 4 and 7 buffers solutions. Measurements were done in duplicate. Titratable acidity was determined by titration, according to the methodology proposed by the Adolfo Lutz Institute (2008)Instituto Adolfo Lutz (2008) Métodos físico químicos para análise de alimentos. 4ª ed. São Paulo, Instituto Adolfo Lutz. 1020p., which is based on the titration with sodium hydroxide (0.01 M) until the turning point with the phenolphthalein indicator (1%). The ratio was obtained by the SS / TA ratio. Levels of vitamin C were determined according to Baccan et al. (2001)Baccan N, Andrade JC, Godinho OE & Barone JS (2001) Química analítica quantitativa elementar. São Paulo, Editora Blucher. 324p..

Qualitative descriptors were evaluated based on seven attributes related to the fruits listed by UPOV (2005)UPOV – International Union for the Protection of New Varieties of Plants (2005) UPOV Report on the Impact of Plant Variety Protection. Geneva, UPOV. 99p., as shown in Table 1. Characterization was made through a scale of notes for each variable, with modifications for type of range, intensity of the band color and band width, to which a note was added corresponding to the absence of the characteristic.

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Table 1
Scales of grades of qualitative descriptors used in the evaluation of the fruits of watermelon accessions

Data were initially tested for homogeneity of variances using the Bartlett test and for normality of residues using the Shapiro-Wilk test. The pH, vitamin C, soluble solids and SS⁄AT ratio data were transformed by the equation , , and , to verify the assumptions of ANOVA. Subsequently, individual analyzes were carried out, as well as the joint analysis of the two cycles. The averages were grouped using the Scott-Knott test at 5% significance to compare the performance of each access used, based on the significance of the F test.

The qualitative traits were subjected to the analysis of genetic diversity, with evaluation of the frequency of each of the categories among the variables and obtaining the dissimilarity matrix by the Euclidean distance. Using Tocher’s optimization method, accesses were then grouped.

Statistical analysis was performed using the statistical programs GENES (Cruz et al., 2013Cruz CD (2013) Genes: a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum. Agronomy, 35:271 276.), R Core Team (2010)R Development Core Team (2010) R: A language and environment for statistical computing. Available at: <https://research.cbs.dk/en/publications/r-development-core-team-2010-r-a-language-and-environment-for-sta>. Accessed on: March 14th, 2021.
https://research.cbs.dk/en/publications/... and SISVAR (Ferreira, 2011Ferreira DF (2011) Sisvar: a computer statistical analysis system. Ciência e Agrotecnologia, 35:1039-1042.).

RESULTS AND DISCUSSION

Genotype × environment interaction was significant for six quantitative descriptors evaluated among the 12 accessions and the two commercial cultivars. In accession performance studies, it is desirable that the traits assessed remain stable across environments so that observed variability can be attributed to the genetic component. Ramalho et al. (2012)Ramalho MAP, Santos JB, Pinto CABP, Souza EA, Gonçalves FMA & Souza JC (2012) Genética na agropecuária. 5ª ed. Lavras, UFLA. 566p. reported that quantitative traits are often controlled by multiple genes, so environmental influence to be expected.

Variability in the physicochemical parameters assessed was observed among the 12 accessions studied. In this way, future studies can identify accessions that can be used directly by farmers or included in breeding programs to be used as parents in crosses. Thus, there is a time gain in the stages of association of disease resistance previously evaluated (Costa et al., 2021Costa AES, da Cunha FS, Araújo KMG, Lima Neto IS, Capucho AS, Borel JC & Ishikawa FH (2021) Morph-agronomic characterization of watermelon accessions with resistance to Fusarium Wilt. Anais da Academia Brasileira de Ciências, 93:e20191359.) with the traits of agronomic interest.

The variables pH, titratable acidity, transverse diameter, and fruit shape did not show significant value for the genotype × environment interaction (Table S1). For these characters, the analysis was based on the average of the environments. In general, experimental precision based on the coefficient of variation, was within the usual range for field experiments, with values ranging from 3.77 (pH) to 27.57% (total production) (Table S1). The lowest amplittudes were observed for pH, indicating greater homogeneity of the character among the genotypes studied. This variable grouped the accessions into three groups of average values, ranging from 4.79 for BGH-Univasf 128 to 5.62 for ‘Sugar Baby’, as shown in Table 2, with values corresponding to those observed in the literature for this crop, around 5.34 (Barros et al., 2012Barros MM, Araújo WF, Neves LTBC, Campos AJ & Tosin JM (2012) Produção e qualidade da melancia submetida a adubação nitrogenada. Revista Brasileira de Engenharia Agrícola e Ambiental, 16:1078-1084.).

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Table 2
Variables with no significant genotype × environment interaction for quantitative characterization of fruits from 12 watermelon accessions and two commercial cultivars

The titratable acidity in cycle 2 was higher than in cycle 1, with a higher content of organic acids in the pulp observed in the accessions of the species Citrullus lanatus var. lanatus: BGH-Univasf 40, BGH-Univasf 174, BGH-Univasf 177, BGH-Univasf 210, BGH-Univasf 321 and ‘Charleston Gray’, with values of 1.13, 1.27, 1.17, 1.37, 1.32 and 1.25%, respectively (Figure 2A). Similar results were found by Lima Neto et al. (2010)Lima Neto IS, Guimarães IP, Batista PF, Aroucha EMM & Queiróz MA (2010) Qualidade de frutos de diferentes variedades de melancia provenientes de Mossoró–RN. Revista Caatinga, 23:14-20. in the evaluation of fruit quality of watermelon cultivars under the conditions of hot and dry climate of Mossoró, RN, conditions like those of the present work. According to Barros et al. (2012)Barros MM, Araújo WF, Neves LTBC, Campos AJ & Tosin JM (2012) Produção e qualidade da melancia submetida a adubação nitrogenada. Revista Brasileira de Engenharia Agrícola e Ambiental, 16:1078-1084., acidity is an important characteristic related to fruit flavor, since low values tend to make the flavor pleasant. Carlos et al. (2002)Carlos ALX, Menezes JB, Rocha RHC, Nunes GHS & Silva GG (2002) Vida útil pós-colheita de melancia submetida a diferentes temperaturas de armazenamento. Revista Brasileira de Produtos Agroindustriais, 4:29-35. reported the tendency for total titratable acidity to increase with the growth process of the fruit until its complete physiological development and then to decrease through the ripening process. Thus, the analysis of titratable acidity values obtained in the present study suggests that the fruits were harvested relatively ripe, which emphasizes the need to correlate the other ripeness indices and to make evaluations of unripe fruits.

Figure 2
Average of 12 watermelon accessions plus Sugar Baby (SB) and Charleston Gray (CG) cultivars in two production cycles for: A) Titratable acidity (%) based on the general average of the cycles and B) Soluble solids (ºBrix). Means followed by the same uppercase letter (between cycles) and lowercase letter (between genotypes) belong to the same group according to the Scott-Knott test at 5% probability. 1 - BGH-UNIVASF 40; 2 - BGH-UNIVASF 76; 3 - BGH-UNIVASF 116; 4 - BGH-UNIVASF 128; 5 - BGH-UNIVASF 169; 6 - BGH-UNIVASF 174; 7 - BGH-UNIVASF 177; 8 - BGH-UNIVASF 185; 9 - BGH-UNIVASF 210; 10 - BGH-UNIVASF 321; 11 - BGH-UNIVASF 395; and 12 - BGH-UNIVASF 398.

Accessions BGH-Univasf 116 and ‘Charleston Gray’ had superior performance for soluble solids content in the second cycle, while BGH-UNIVASF 169 showed a decrease in content compared to the first cycle (Figure 2B). The content of soluble solids varied from 2.51 to 8.94 °Brix among the evaluated genotypes, as expected, the accessions of forage watermelon obtaining the lowest values. For commercial cultivars, soluble solids content was consistent with literature data. Leão et al. (2007)Leão DSS, Peixoto JR & Vieira JV (2007) Teor de licopeno e de sólidos solúveis totais em oito cultivares de melancia. Bioscience Journal, 22:7-15. evaluated soluble solids content in eight watermelon cultivars, including ‘Charleston Gray’, which obtained lower values for this variable than in the present study. In the case of ‘Sugar Baby’, Ramos et al. (2009)Ramos ARP, Dias RCS & Aragão CA (2009) Densidades de plantio na produtividade e qualidade de frutos de melancia. Horticultura Brasileira, 27:560-564. evaluated the effect of planting density on the performance and fruit quality parameters of the cultivar. These authors obtained a value of 7.19 °Brix, which was lower than the value observed for this cultivar in the present study, whose average from cycles were 8.94 °Brix.

Soluble solids content is a characteristic that is strongly influenced by environmental conditions. Sandlin et al. (2012)Sandlin KC, Prothro JM, Heesacker AF, Khalilian N, Okashah R, Xiang W, Bachlava E, Caldwell D, Seymour D, White V, Chan E, Tolla G, White C, Safran D, Graham E, Knapp SJ & McGregor CE (2012) Comparative mapping in watermelon [Citrullus lanatus (Thunb.) Matsum. et Nakai]. Theoretical and applied genetics, 125:1603-1618. reported that soluble solids content in watermelon is considered a polygenic character influenced by genetic and environmental factors, with watermelon being sensitive to temperature and moisture fluctuations during its developmental stage (Figure 1). According to the climate data, there was an increase in temperature and a decrease in humidity during the second cycle compared to the first cycle. These conditions should be more favorable for the development of watermelon fruits with higher organoleptic quality.

Fruit flavor can be better evaluated using the SS/AT ratio, which is considered more representative than isolated measurements of sugar and acidity (Lima Neto et al., 2010Lima Neto IS, Guimarães IP, Batista PF, Aroucha EMM & Queiróz MA (2010) Qualidade de frutos de diferentes variedades de melancia provenientes de Mossoró–RN. Revista Caatinga, 23:14-20.). The accessions BGH-Univasf 40 and ‘Charleston Gray’ obtained lower values in the first cycle (Table 3). By cycle, these two treatments were classified in the group with the highest value for SS/AT. This fact results from the low contents of organic acids obtained in the representative fruits of each treatment.

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Table 3
Variables with significant genotype × environment interaction for quantitative characterization of fruits from 12 watermelon accessions and two commercial cultivars

The vitamin C content ranged from 11.41 to 17.22 mg ascorbic acid 100 mL^-1 of juice. In the genotype × environment interaction, cycle 2 was superior to cycle 1 for most treatments, except for BGH-UNIVASF 210 and BGH-UNIVASF 321, which had a reduction in the second cycle as seen in Figure 3-A. During the second cycle, the highest temperatures were observed (Figure 1). The combination of high light intensity and high temperatures are optimal conditions for development of watermelon fruits (Wehner, 2008Wehner TC (2008) Watermelon. In: Jaime Prohens & Fernando Nuez (Ed.) Vegetables I. New York, Springer. p.381-418.). The accession BGH-UNIVASF 128, of the species Citrullus lanatus var. citroides had better mean values than the commercial cultivars in both experimental periods. The other var. citroides accessions, BGH-UNIVASF 76 and 128, also grouped with BGH-UNIVASF 128 in the second cycle with the highest of vitamin C contents.

Commercial cultivars were grouped with the lowest average values for vitamin C synthesis, but still reached higher values than those reported by Lima Neto et al. (2010)Lima Neto IS, Guimarães IP, Batista PF, Aroucha EMM & Queiróz MA (2010) Qualidade de frutos de diferentes variedades de melancia provenientes de Mossoró–RN. Revista Caatinga, 23:14-20. in Mossoró - RN of 7.64 and 6.97 mg 100g pulp^-1 for ‘Charleston Gray’ and ‘Sugar Baby’, respectively (Figure 3-A). The Brazilian Food Composition Table – TACO (Universidade Estadual de Campinas, 2006Universidade Estadual de Campinas (2006) Tabela brasileira de composição de alimentos - TACO. 2ª ed. Campinas, Nepa-Unicamp. 113p.) is one of the most important Brazilian references on food composition. The values obtained in the present study were higher than those taken as a reference for watermelon in this table (6.1 mg 100g pulp^-1). Vitamin C is considered an important component of human nutrition, mainly because human cannot synthesize this element themselves and therefore must obtain it from food. In this sense, vitamin C can be used as a quality index because it is a characteristic that is strongly influenced by factors such as climatic conditions, cultural practices and ripeness in addition to genetic differences (Lee & Kader, 2000Lee SK & Kader AA (2000) Preharvest and postharvest factors influencing vitamin C content of horticultural crops. Postharvest Biology and Technology, 20:207-220.; Toscano et al., 2019Toscano S, Trivellini A, Cocetta G, Bulgari R, Francini A, Romano D & Ferrante A (2019) Effect of preharvest abiotic stresses on the accumulation of bioactive compounds in horticultural produce. Frontiers in Plant Science, 10:1212.).

Figure 3
Average of 12 watermelon accessions plus Sugar Baby (SB) and Charleston Gray (CG) cultivars in two production cycles for: A) Vitamin C (ascorbic acid mg / 100 mL) and B) Fruit Mass (kg). Means followed by the same uppercase letter (between cycles) and lowercase letter (between genotypes) belong to the same group according to the Scott-Knott test at 5% probability. Description of accessions: 1 - BGH-UNIVASF 40; 2 - BGH-UNIVASF 76; 3 - BGH-UNIVASF 116; 4 - BGH-UNIVASF 128; 5 - BGH-UNIVASF 169; 6 - BGH-UNIVASF 174; 7 - BGH-UNIVASF 177; 8 - BGH-UNIVASF 185; 9 - BGH-UNIVASF 210; 10 - BGH-UNIVASF 321; 11 - BGH-UNIVASF 395; and 12 - BGH-UNIVASF 398.

The accession BGH-UNIVASF 185, of the species Citrullus lanatus var. citroides, was superior to the other treatments in terms of variable fruit mass in cycle 1 with an average value of 11.35 kg (Figure 3-B). This potential was maintained in the second cycle, however, in cycle 2, ‘Charleston Gray, BGH -UNIVASF 76, and BGH-UNIVASF 128 grouped together with BGH-UNIVASF 185, all accessions also belonged to Citrullus lanatus var. citroides. It is also worth mentioning the observed amplitude between BGH-UNIVASF 185 accession with the highest mass (11.35 kg) and BGH-UNIVASF 321 with the lowest mass (2.50 kg), showing the variability of the material under the test conditions. Accessions with small fruits (below four kilograms), such as BGH-UNIVASF 321, BGH-UNIVASF 395 and BGH-UNIVASF398, are promising. Recently, fruit size has become an important characteristic for breeders as consumers increasingly prefer smaller fruits (Ngwepe et al., 2019Ngwepe RM, Mashilo J & Shimelis H (2019) Progress in genetic improvement of citron watermelon (Citrullus lanatus var. citroides): a review. Genetic Resources and Crop Evolution, 66:735-758.).

Fruits obtained in cycle 2 were larger than in cycle 1 in terms of longitudinal diameter (LD), with values ranging from 19.37 cm (BGH-Univasf 174) to 41.68 cm (BGH-Univasf 116). For transverse diameter (TD), four groups were formed, with BGH-UNIVASF 76 (21.06 cm) and BGH-Univasf 185 (21.70 cm) having the highest average values. Regarding the fruit shape index (FSI), 64.3% of the accessions were classified in the oval fruit category, as they had a TD/LD ratio between 0.5 and 0.79, a result that included accessions such as BGH-UNIVASF 76, BGH-UNIVASF 128, BGH-UNIVASF 177, BGH-UNIVASF 185, and ‘Charleston Gray’. It has been reported in the literature fruits considered oval or spherical have a greater portion of edible pulp, and it is more advantageous in terms of storage, as it can be easily placed in boxes (Silva et al., 2006Silva MLD, Queiróz MAD, Ferreira MAJDF & Buso GS (2006) Caracterização morfológica e molecular de acessos de melancia. Horticultura Brasileira, 24:405-409.). In the accessions BGH-UNIVASF 40, BGH-UNIVASF 174 and ‘Sugar Baby’, round fruits were observed, which are classified as spherical, since TD/LD ratio closest to 1.0 (Table 2). In this context, associating the content of soluble solids and fruit size, the accessions BGH-UNIVASF 40 and BGH-UNIVASF 177 are a good source as they are grouped with the highest average values for both variables.

Environmental effects with significant interaction can be observed in production per plot, with three of the evaluated treatments performing better in the first cycle compared to the second cycle (Table 3). Only the accessions BGH-UNIVASF 76 and BGH-UNIVASF 185, both from the species C. lanatus var. citroides, were grouped among accessions with the highest average values in both cycles, indicating a productive capacity to be exploited with potential for animal feed. Silva et al. (2009)Silva RL, Araujo G, Socorro E, Oliveira R, Garces A & Bagaldo A (2009) Níveis de farelo de melancia forrageira em dietas para ovinos. Revista Brasileira de Zootecnia, 38:1142-1148. reported the advantages of using watermelon in animal feed, because it is drought tolerance and easy to grow. ‘Sugar Baby’ achieved the lowest overall production, 7.41 kg, allocated with ‘Charleston Gray’ in the group with the lowest averages. In general, these results demonstrate the potential of these accessions as genetic resources for use in breeding programs.

Using Tocher’s optimization method, the evaluated treatments were divided into four groups, two of which were composed of unique components, one with accession BGH-UNIVASF 40 in another with cultivar ‘Sugar Baby, as shown in Table 4. The evaluation of attributes related to the external appearance of the fruits is necessary because the commercialization conditions of vegetables in general are strongly influenced by the visual attraction to the consumer (Vilela et al., 2000Vilela NJ & Henz GP (2000) Situação atual da participação das hortaliças no agronegócio brasileiro e perspectivas futuras. Cadernos de Ciência & Tecnologia, 17:71-89.). Fruit characterization provides information on accessions and allows genetic diversity analyzes to be conducted, which in turn help identify parents with potential use for hybridization in breeding programs and define groups with a greater or lesser degree of similarity (Cruz et al., 2014Cruz CD, Carneiro PCS & Regazzi AJ (2014) Modelos biométricos aplicados ao melhoramento genético. 3ª ed. Viçosa, Editora UFV. 668p.).

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Table 4
Grouping performed according to the Tocher Method, based on the dissimilarity matrix obtained by the Euclidean distance for qualitative variables1 of twelve accessions and two commercial cultivars

Characteristics of commercial interest for watermelon, such as fruit shape, weight, external and internal color, and stripe pattern, are important aspects for the commercial success of the crop due to strong market demand (Mashilo et al., 2022Mashilo J, Shimelis H, Ngwepe RM & Thungo Z (2022) Genetic Analysis of Fruit Quality Traits in Sweet Watermelon (Citrullus lanatus var. lanatus): A Review. Frontiers in Plant Science, 13:834696-834696.). Fruit longitudinal cut shape varied little among accessions, and it was classified as broadly elliptical for groups I and II and as mid-elliptical for most accessions in groups III and IV. Skin color was homogeneous in all groups, with fruits classified based on their light green color, with the greatest intensity attributed to ‘Sugar Baby’.

Regarding the stripe pattern, group I, which was composed only of the accession BGH-UNIVASF 40 (Table 4), differed from the others, as the fruits were evaluated with the highest score for the description of this characteristic. The accessions BGH-UNIVASF 128, BGH-UNIVASF 395, BGH-UNIVASF 185 and BGH-UNIVASF 76 showed a fruit pattern similar to that of ‘Charleston Gray’, with light green outer tones, stripes (when present), in unique colors and the presence of veins, the color being of low intensity.

Among the evaluated accessions that show resistance to fusariosis, according to a preliminary evaluation, they are alternatives for use both in breeding programs and for direct use by farmers. In this way, it is possible to obtain an improvement in agronomic performance to obtain material that has good agronomic performance both in organoleptic and production terms.

CONCLUSION

Twelve characterized accessions show variability in the physicochemical analysis studied. Among the evaluated accessions, BGH-UNIVASF 40, BGH-UNIVASF 169, and BGH-UNIVASF 177 can be highlighted, as they are phenotypically resistant to fusariosis and present a good performance for the main evaluated characteristics of commercial interest, representing possible sources for watermelon breeding.

The accessions BGH-UNIVASF 76, BGH-UNIVASF 128, and BGH-UNIVASF 185 (Citrullus lanatus var. citroides) showed good performed in total production, fruit mass and vitamin C content.

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

The authors would like to thank the Fitomelhor group for their help during the research activities. This work was supported by grants and research fellowship for the first author from the National Council for Scientific and Technological Development (CNPq) (grant number 480674/2013-2), the Universidade Federal do Vale do São Francisco (Univasf), and research fellowships for the third and fourth authors by the Coordination for the Improvement of Higher Education Personnel (Capes). There is not any conflict of interests in carrying the research and publishing the manuscript.

1
This work was partially supported by Brazilian agencies CAPES, and CNPq throughout fellowships and grant allocation.

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Publication Dates

Publication in this collection
05 Apr 2024
Date of issue
2024

History

Received
27 July 2022
Accepted
24 Aug 2023

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] 1
This work was partially supported by Brazilian agencies CAPES, and CNPq throughout fellowships and grant allocation.

Descriptor*	Class	Scale of grades
Shape of the longitudinal section	Circular	1
	Wide elliptical	2
	Medium elliptical	3
	Narrow elliptical	4
Skin color	Yellow	1
	Very light green	2
	Very light green to light green	3
	Light green	4
	Light to medium green	5
	Medium green	6
	Medium to dark green	7
	Dark green	8
	Dark to very dark green	9
	Very dark green	10
Skin color Intensity	Very weak	1
	Weak	2
	Medium	3
	Strong	4
	Very strong	5
Stripes	Absent	0
Stripes	Present	1
Stripe Type	Only one color	1
	One color and veins	2
	One color, veins and marbled	3
	One color and marbled	4
	Two colors, veins and marbled	5
	Only veins	6
Stripe Color Intensity	Absent	0
	Very weak	1
	Weak	2
	Medium	3
	Strong	4
	Very strong	5
Stripe Width	Absent	0
	Very narrow	1
	Narrow	3
	Medium	5
	Wide	7
	Very wide	9

Accessions	pH³ 3 Dimensionless valueMeans followed by the same lowercase belong to the same grouping according to the Scott-Knott test at 5% probability		Fruit shape index (TD/LD ration)³ 3 Dimensionless valueMeans followed by the same lowercase belong to the same grouping according to the Scott-Knott test at 5% probability
BGH-UNIVASF 40¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.34	a	0.95	a
BGH-UNIVASF 76² 2 Accessions of the species Citrullus lanatus var. citroides	4.91	c	0.6	b
BGH-UNIVASF 116¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.46	a	0.46	c
BGH-UNIVASF 128² 2 Accessions of the species Citrullus lanatus var. citroides	4.79	c	0.52	c
BGH-UNIVASF 169¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.25	a	0.46	c
BGH-UNIVASF 174¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.09	b	1.01	a
BGH-UNIVASF 177¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.39	a	0.57	c
BGH-UNIVASF 185² 2 Accessions of the species Citrullus lanatus var. citroides	4.86	c	0.52	c
BGH-UNIVASF 210¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.19	b	0.56	c
BGH-UNIVASF 321¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.16	b	0.64	b
BGH-UNIVASF 395¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.12	b	0.67	b
BGH-UNIVASF 398¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.42	a	0.71	b
‘Sugar Baby’	5.62	a	0.91	a
‘Charleston Gray’	5.38	a	0.54	c
CV (%)	3.77		15.01

Accessions	SS/TA ratio³ 3 Dimensionless value		Total production (kg)
Accessions	Cycle 1	Cycle 2	Cycle 1	Cycle 2
BGH-UNIVASF 40¹ 1 Accessions of the species Citrullus lanatus var. lanatus	6.12 aB	8.62 aA	7.65 cA	14.66 bA
BGH-UNIVASF 76² 2 Accessions of the species Citrullus lanatus var. citroides	2.61 cA	2.49 dA	41.57 aA	16.98 aB
BGH-UNIVASF 116¹ 1 Accessions of the species Citrullus lanatus var. lanatus	6.75 aA	8.10 aA	7.48 cA	11.73 bA
BGH-UNIVASF 128² 2 Accessions of the species Citrullus lanatus var. citroides	2.73 cA	3.00 dA	25.31 bA	17.75 aB
BGH-UNIVASF 169¹ 1 Accessions of the species Citrullus lanatus var. lanatus	7.94 aA	6.62 bA	20.66 bA	20.09 aA
BGH-UNIVASF 174¹ 1 Accessions of the species Citrullus lanatus var. lanatus	4.88 bA	4.49 cA	7.42 cA	11.46 bA
BGH-UNIVASF 177¹ 1 Accessions of the species Citrullus lanatus var. lanatus	6.84 aA	6.40 bA	16.77 bA	12.75 bA
BGH-UNIVASF 185² 2 Accessions of the species Citrullus lanatus var. citroides	2.35 cA	2.47 dA	46.16 aA	23.59 aB
BGH-UNIVASF 210¹ 1 Accessions of the species Citrullus lanatus var. lanatus	5.75 aA	4.51 cA	14.65 bA	17.84 aA
BGH-UNIVASF 321¹ 1 Accessions of the species Citrullus lanatus var. lanatus	4.76 bA	4.79 cA	8.65 cA	7.72 bA
BGH-UNIVASF 395¹ 1 Accessions of the species Citrullus lanatus var. lanatus	8.43 aA	6.48 bA	11.95 cA	13.05 bA
BGH-UNIVASF 398¹ 1 Accessions of the species Citrullus lanatus var. lanatus	7.11 aA	5.35 cA	18.57 bA	14.17 bA
‘Sugar Baby’	7.39 aA	7.27 bA	9.15 cA	5.67 bA
‘Charleston Gray’	6.63 aB	9.20 aA	5.99 cA	11.66 bA
CV (%)	21.58		27.57

Group	Treatment	Qualitative descriptors *
Group	Treatment	SLS	SC	SCI	SP	ST	SCI	SW
I	BGH-UNIVASF 40	2	2	4	1	1	4	5
II	‘Sugar Baby’	2	2	5	1	0	2	1
III	BGH-UNIVASF 128	3	2	3	1	0	0	0
	BGH-UNIVASF 395	3	2	3	1	0	1	0
	‘Charleston Gray’	3	2	3	1	1	2	1
	BGH-UNIVASF 185	4	2	3	1	0	0	0
	BGH-UNIVASF 76	3	2	3	1	0	0	1
IV	BGH-UNIVASF 116	3	2	4	1	1	4	3
	BGH-UNIVASF 321	3	2	3	1	1	4	5
	BGH-UNIVASF 169	3	2	3	1	1	4	7
	BGH-UNIVASF 174	2	2	2	1	2	5	7
	BGH-UNIVASF 177	3	2	2	1	2	4	5
	BGH-UNIVASF 210	3	2	2	1	1	4	5
	BGH-UNIVASF 398	3	2	2	1	1	3	1

Brasil

Brasil

Physicochemical characterization of watermelon accessions from traditional agriculture with resistance to Fusarium wilt1 1 This work was partially supported by Brazilian agencies CAPES, and CNPq throughout fellowships and grant allocation.

ABSTRACT

INTRODUCTION

MATERIAL AND METHODS

RESULTS AND DISCUSSION

CONCLUSION

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

REFERENCES

Publication Dates

History

Physicochemical characterization of watermelon accessions from traditional agriculture with resistance to Fusarium wilt¹ 1 This work was partially supported by Brazilian agencies CAPES, and CNPq throughout fellowships and grant allocation.