Sugar-and-acid profile of Penjar tomatoes and its evolution during storage

Missio, Joan Casals; Renau, Raul Marti; Artigas, Francesc Casañas; Cornejo, Jaime Cebolla

doi:10.1590/0103-9016-2014-0311

Abstract

The alcobaça mutation in the Penjar tomato (Solanum lycopersicum L.) variety alters the ripening process and confers a long shelf life (more than four months). Storage of Penjar tomatoes leads to a distinctive sensory profile valued by local consumers, who prefer aged tomatoes to fresh ones. To study chemical changes occurring during storage, we characterized the complete sugar-and-acid profile of 25 accessions at harvest and at 2 and 4 months after harvest. We found considerable variability in the sugar-and-acid profile within the Penjar variety, especially for fructose and glucose. Some accessions presented exceptionally high values for sugars, making them especially interesting for breeding programs. During postharvest, the concentration of glucose, fructose, and citric acid decreased, whereas the concentration of malic and glutamic acids increased. Data from this study offer novel insights into postharvest changes in tomato quality parameters and help elucidate the reasons for the appreciation of this variety by consumers.

tomato landrace; alcobaça; ripening mutant; postharvest; quality

Introduction

Ripening and postharvest behavior are strongly disrupted in ripening mutants of tomato (Solanum lycopersicum L.) (Klee and Giovannoni, 2011Klee, H.J.; Giovannoni, J.J. 2011. Genetics and control of tomato fruit ripening and quality attributes. Annual Review of Genetics 45: 41-59.). A number of mutations related to these disruptions have been found in scientific breeding programs (e.g.: ripening inhibitor (rin) (Robinson and Tomes, 1968Robinson, R.W.; Tomes, M.L. 1968. Ripening inhibitor: a gene with multiple effects on ripening. Report of the Tomato Genetics Cooperative 18: 36-37.)) and others have been found in landraces. In Europe, long-storage landraces (Bota et al., 2014Bota, J.; Conesa, M.À.; Ochogavia, J.M.; Medrano, H.; Francis, D.M.; Cifre, J. 2014. Characterization of a landrace collection for Tomàtiga de Ramellet (Solanum lycopersicum L.) from the Balearic Islands. Genetic Resources and Crop Evolution 61: 1131-1146.; Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.; Siracusa et al., 2012Siracusa, L.; Patane, C.; Avola, G.; Ruberto, G. 2012. Polyphenols as chemotaxonomic markers in italian "long-storage" tomato genotypes. Journal of Agricultural and Food Chemistry 60: 309-314.) are highly valued by local consumers, especially in Italy and Spain, where they are traditionally consumed after a storage period that confers a specific sensory profile. For these special tomatoes, the postharvest period could be referred to as the “aging phase” (Watada et al., 1984Watada, A.E.; Herner, R.C.; Kader, A.A.; Romani, R.J.; Staby, G.L. 1984. Terminology for the description of developmental stages of horticultural crops. Hortscience 19: 20-21.), because it involves a series of changes in quality parameters after maturity and before consumption.

In the Penjar variety, long shelf life (mean, 126.8 days) is mainly due to the alcobaça (alc) mutation in conjunction with small fruit size (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.). During the aging phase, Penjar tomatoes undergo a rearrangement of the concentrations of volatiles, resulting in fruits with a distinctive “sharp-floral” aroma that is very intense in some genotypes (Casals et al., 2011Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.), and consumers prefer aged tomatoes (between one and four months) over recently harvested ones. In addition to changes in the aroma profile, aging in Penjar tomatoes probably entails changes in the concentrations of molecules related to sweetness and acidity. During the first stages of the postharvest period in standard tomatoes, reducing sugars (glucose and fructose) continue to accumulate due to degradation of stored carbohydrates, lipids, and proteins (Beckles, 2012Beckles, D.M. 2012. Factors affecting the postharvest soluble solids and sugar content of tomato (Solanum lycopersicum L.) fruit. Postharvest Biology and Technology 63: 129-140.), but within a few days the concentration of sugars falls due to the respiratory metabolism (Getinet et al., 2008Getinet, H.; Seyoum, T.; Woldetsadik, K. 2008. The effect of cultivar, maturity stage and storage environment on quality of tomatoes. Journal of Food Engineering 87: 467-478.). On the other hand, the concentration of organic acids (malic and citric acids) decreases throughout the postharvest period (Getinet et al., 2008Getinet, H.; Seyoum, T.; Woldetsadik, K. 2008. The effect of cultivar, maturity stage and storage environment on quality of tomatoes. Journal of Food Engineering 87: 467-478.). Differences between standard tomatoes and alc mutants during the ripening period have been well described (Kopeliovitch et al., 1980Kopeliovitch, E.; Mizrahi, Y.; Rabinowitch, H.D.; Kedar, N. 1980. Physiology of the tomato mutant alcobaça. Physiologia Plantarum 48: 307-311.; Mutschler, 1984Mutschler, M. 1984. Ripening and storage characteristics of the alcobaça ripening mutant in tomato. Journal of the American Society for Horticultural Science 109: 504-507.), but much less is known about differences in the postharvest period. Thus, we sought to describe the evolution of malic, glutamic, and citric acids and of glucose and fructose during the long aging phase. Moreover, because the alc allele in the Penjar tomatoes occurs in a variety of genetic backgrounds (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.), we also sought to ascertain the reasons for consumers’ postharvest preferences of this variety so that this information could be transferred to breeding programs.

Materials and Methods

Plant materials

In a previous study, we analyzed genetic variability within the Penjar variety (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.). Characterization of 118 accessions provided by local farmers enabled us to select 21 accessions representing the major part of the genetic variability found in the variety. In the current study, we used these 21 accessions plus two additional Penjar accessions widely cultivated by local farmers (Table 1). The previous study confirmed the presence of the alc allele in all the Penjar accessions using a cleaved amplified polymorphism (CAP) marker (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.). All these materials are available from the germplasm bank of the Miquel Agustí Foundation (Spain). We included as controls four ripening mutants from the Tomato Genetics Resource Center (TGRC, University of California, Davis, CA; LA0162 (Never ripe (Nr)), LA3770 (non-ripening (nor)), LA3012 (ripening inhibitor (rin)), and LA3134 (alcobaça (alc)), and one normal-ripening commercial hybrid widely grown in NE Spain (Bodar, Royal Sluis).

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Table 1
− Tomato accessions used in this study.

As described by Casals et al. (2012)Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229., plants were grown in an experimental field in Sabadell (NE Spain, 41º32’ N 2º4’ E) in the open air at a density of 25,000 plants ha⁻¹ using standard local farming practices (canes for support, pruning every 15 days, with local irrigation and fertigation) and a random three-block design with 12 plants per plot. Agromorphological traits for each variety have been published in a previous work (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.). From each plot, fruits were collected at the red ripe stage in one single harvest. Fruits were stored in a dark room at 20 ± 5 ºC and 68 % to 75 % relative humidity. Shelf life was calculated for each plot as the mean number of days from harvesting to discarding of fruits (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.).

Previous studies based on aroma profile (Casals et al., 2011Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.) showed that Penjar tomatoes maintain their high commercial value for 4 months after harvesting (Figure 1). Thus, we targeted this period for the present study, and selected three sampling dates: at harvest (0 months), at 2 months postharvest, and at 4 months postharvest. At each sampling date, we froze three replicates per accession and kept them at -20 ºC until analysis. Each replicate consisted of three fruits with good external appearance from a single plot.

Figure 1
– External appearance, longitudinal and transversal sections of fruits from three Penjar accessions (CDP05468, CDP01255, CDP00235) after 4 months’ storage.

Sample preparation

Samples were thawed in a refrigerator in the dark. Then the three replicates were blended and homogenized at a low temperature. Samples were centrifuged at 2,500 rpm (510 x g) for 5 min. The upper phase was diluted (1:10) in deionized water and the internal standard D-fructose 1.6-diphosphate added. The solution was filtered using centrifuge tube filters with 0.22 μm membranes and analyzed.

Chemical analysis

Sucrose, fructose, glucose, malic acid, citric acid, and glutamic acid were quantified by capillary electrophoresis following the method described by Cebolla-Cornejo et al. (2012)Cebolla-Cornejo, J.; Valcarcel, M.; Herrero-Martinez, J.M.; Rosello, S.; Nuez, F. 2012. High efficiency joint CZE determination of sugars and acids in vegetables and fruits. Electrophoresis 33: 2416-2423. on an Agilent 7100 system using fused silica capillaries with a 50 μm internal diameter, 363 μm external diameter, 67 cm total length, and 60 cm effective length. Capillaries were initially conditioned with consecutive rinses at 95000 Pa and 50 ºC, as follows: 1 M NaOH (5 min), 1 M NaOH (5 min), and deionized water (10 min). At the beginning of each working session, the capillary was flushed at 20 ºC with the background electrolyte (20 mM 2.6-piridin dicarboxylic acid at pH 12.1 and 0.1 % w/v hexadimethrine bromide) running for 30 min. Between runs, it was flushed with 58 mM SDS solution (2 min) followed by the background electrolyte running for 5 min. Samples were injected hydrodynamically at 3447 Pa for 20 s. Separations were performed at -25 kV and 20 ºC. Indirect detection was done at 214 nm. Results are expressed in grams per kilogram of fresh weight (FW).

Statistical analysis

As proposed by Sakiyama and Stevens (1976)Sakiyama, R.; Stevens, M.A. 1976. Organic-acid accumulation in attached and detached tomato fruits. Journal of the American Society for Horticultural Science 101: 394-396., to avoid presumed increases in acid and sugar concentration due to water loss during postharvest, concentrations at 2 and 4 months’ postharvest were corrected according to the following formula: Reported value = Measured value × Weight after storage/Weight at harvest. We used the SAS statistical package (Statistical Analysis System, Cary, NC, USA, version 8.02) for ANOVA. Differences between storage times and between accessions were determined by the Student-Newman-Keuls test with significance set at 0.05. Genotypic correlations (between mean phenotypic values of each accession) were estimated using the Pearson coefficient. Using this approach, we analyzed the correlations between chemical composition and agromorphological traits to evaluate whether the chemical composition of Penjar tomatoes was related to shelf life.

Results

The controls Bodar, rin, alc, and Nr lost their commercial value at one month postharvest and were therefore discarded as controls for the long-term postharvest evolution of sugars and acids. However, like the Penjar accessions, accession LA3770 carrying the nor allele provided fruits that maintained their commercial value after 4 months storage.

The average weight loss for the accessions of the Penjar variety at 4 months postharvest was 17 %. The nor control lost less weight (13 %). For the Penjar accessions, the average weight loss in the first period (11 %, 0-2 months postharvest) was significantly higher (1.6 fold, p < 0.0001) than in the second (7 %, 2-4 months postharvest) (Figure 2). All the Penjar accessions had the same pattern of weight loss, and no significant interaction between accession and postharvest period was detected (p = 0.49). In the nor control, weight loss was also greater in the first period (8 %) than in the second (5 %) (p < 0.01).

Figure 2
− Fruit weight loss in the 0-2 months and 2-4 months postharvest periods for the Penjar variety and for the LA3770 non-ripening (nor) control. Data represent the mean ± standard error of the mean of 25 accessions for the Penjar variety and of three replicates for the nor control. Within each variety, different letters indicate differences between periods (Student-Newman-Keuls test, p < 0.05).

The concentration of sugars and acids varied widely between accessions at harvest (p < 0.0001) (Table 2). Sucrose concentrations were not evaluated because they were below the detection threshold (8.99 µg mL⁻¹) of the analytical method (Cebolla-Cornejo et al., 2012)Cebolla-Cornejo, J.; Valcarcel, M.; Herrero-Martinez, J.M.; Rosello, S.; Nuez, F. 2012. High efficiency joint CZE determination of sugars and acids in vegetables and fruits. Electrophoresis 33: 2416-2423. in both the Penjar accessions and the controls. For the other metabolites, concentrations ranged from 0.59 to 1.57 g kg⁻¹ FW for malic acid, from 3.94 to 7.11 g kg⁻¹ FW for citric acid, from 0.92 to 3.82 g kg⁻¹ FW for glutamic acid, from 14.41 to 34.76 g kg⁻¹ FW for fructose, and from 11.62 to 29.64 g kg⁻¹ FW for glucose. The range of variation in acid concentrations at harvest within the Penjar variety was similar to that observed in the controls.

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Table 2
− Sugar and acid concentrations for table-ripe tomatoes at harvest. Data represent means from three replicates ± standard error of the mean.

Maximum sugar concentrations at harvest were lower in the controls than in the Penjar accessions with the highest concentrations. Specifically, the highest fructose concentration in a Penjar accession (CDP07789 = 34.76 g kg⁻¹ FW) was 1.5-fold higher (p < 0.0001) than in the control with the highest concentration (nor = 20.17 g kg⁻¹ FW), and the highest glucose concentration in a Penjar accession (LC77 = 29.64 g kg⁻¹ FW) was 1.6-fold higher (p < 0.0001) than the highest concentration in a control (Bodar = 18.44 g kg⁻¹ FW). Values of the fructose-to-glucose ratio in the Penjar accessions at harvest ranged from 1.11 to 1.37, although no differences were detected between accessions. The ratio was lowest in the control Bodar (1.00), where it was lower than the four highest rated Penjar accessions (p = 0.0038).

During the 4 months after harvest, the concentrations of sugars evolved differently from the concentrations of acids (Figure 3). Concentrations of sugars decreased sharply during the first two months (in the Penjar accessions, 43 % for glucose and 39 % for fructose) and then more gradually in the third and fourth months (in the Penjar accessions, 28 % for glucose and 12 % for fructose). The evolution in the nor control was similar to that in the Penjar variety. In Penjar tomatoes, the average fructose-to-glucose ratio increased slightly (p < 0.0001) during postharvest, from 1:1.22 at harvest to 1:1.32 two months after harvest and 1:1.62 four months after harvest.

Figure 3
− Evolution of sugars and acids during long-term storage for the Penjar variety and the LA3770 non-ripening (nor) control. Data represent the mean ± standard error of the mean of 25 accessions for the Penjar variety (solid line) and of three replicates for the nor control (dotted line). Within each variety, different letters indicate differences between periods (Student-Newman-Keuls test, p < 0.05); ns = not significant, FW = fresh weight.

Of the three acids analyzed, only the citric decreased in concentration during the postharvest period in Penjar accessions (8 % over the 4-month period) (Figure 3). Similar results were observed in the nor control (Figure 3). The other two acids increased in concentration during postharvest in the Penjar accessions. The concentration of malic acid remained unchanged in the first 2 months postharvest and increased 29 % in the remaining 2 months (Figure 3). The concentration of glutamic acid increased 60 % in the first 2 months after harvest and then decreased 11 % in the remaining 2 months. By contrast, in the nor control no differences in the concentrations of malic and glutamic acids were observed during postharvest (Figure 3).

Shelf life had significant correlations with malic acid concentration at 2 months postharvest (r = 0.53, p = 0.0076) and with malic acid (r = 0.47, p = 0.027), fructose (r = 0.59, p = 0.003), and glucose (r = 0.51, p = 0.01) concentrations at 4 months postharvest. Glucose and fructose were negatively correlated with fruit weight at each postharvest time (e.g.: at harvest, r = -0.54 and -0.63, respectively, p < 0.001). Regarding correlations between the concentrations of compounds at harvest.highly significant correlations were found between fructose and glucose (r = 0.98, p < 0.0001) and between glutamic acid and both fructose (r = 0.69, p = 0.0002) and glucose (r = 0.67, p = 0.0004).

Discussion

Genetic background, agromorphological characteristics (Casals et al., 2012Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.) and aroma profile (Casals et al., 2011Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.) vary widely between accessions of Penjar tomatoes. In the present study, the concentrations of sugar and acid at harvest varied widely between accessions. The mean concentrations of malic, citric, and glutamic acids in the Penjar accessions were similar to those reported for tomatoes in general (Causse et al., 2007Causse, M.; Damidaux, R.; Rousselle, P. 2007. Traditional and enhanced breeding for quality traits in tomato. v. 2, p. 153-192. In: Razdan, M.K.; Mattoo, A.K., eds. Genetic improvement of Solanaceous crops: tomato. CRC Press, Boca Raton, FL, USA.), but the concentrations of sugars in the Penjar accessions were on average higher than in conventional tomatoes. Glucose concentrations in Penjar ranged from 11.62 to 29.64 g kg⁻¹ FW, compared to 9 to 17 g kg⁻¹ FW in conventional tomatoes (Causse et al., 2007Causse, M.; Damidaux, R.; Rousselle, P. 2007. Traditional and enhanced breeding for quality traits in tomato. v. 2, p. 153-192. In: Razdan, M.K.; Mattoo, A.K., eds. Genetic improvement of Solanaceous crops: tomato. CRC Press, Boca Raton, FL, USA.). Similarly, fructose concentration in Penjar accessions ranged from 14.41 to 34.76 g kg⁻¹ FW, compared to 11 to 20 g kg⁻¹ FW in conventional tomatoes (Causse et al., 2007Causse, M.; Damidaux, R.; Rousselle, P. 2007. Traditional and enhanced breeding for quality traits in tomato. v. 2, p. 153-192. In: Razdan, M.K.; Mattoo, A.K., eds. Genetic improvement of Solanaceous crops: tomato. CRC Press, Boca Raton, FL, USA.). Likewise, the sugar content in Penjar is clearly higher than in other tomato landraces from the Mediterranean basin (Ercolano et al., 2008Ercolano, M.R.; Carli, P.; Soria, A.; Cascone, A.; Fogliano, V.; Frusciante, L.; Barone, A. 2008. Biochemical, sensorial and genomic profiling of traditional Italian tomato varieties. Euphytica 164: 571-582.; Loiudice et al., 1995Loiudice, R.; Impembo, M.; Laratta, B.; Villari, G.; Lovoi, A.; Siviero, P.; Castaldo, D. 1995. Composition of San-Marzano tomato varieties. Food Chemistry 53: 81-89.).

The high sugar concentrations of some accessions could be related to their low fruit weight (mean 64.1 g). We found a negative correlation between these traits, and this relation has been reported in other tomato varieties (Prudent et al., 2009Prudent, M.; Causse, M.; Genard, M.; Tripodi, P.; Grandillo, S.; Bertin, N. 2009. Genetic and physiological analysis of tomato fruit weight and composition: influence of carbon availability on QTL detection. Journal of Experimental Botany 60: 923-937.). In fact, the degree of sugar accumulation in Penjar fruits seems comparable to that found in cherry tomatoes (Rosales et al., 2007Rosales, M.A.; Rubio-Wilhelmi, M.M.; Castellano, R.; Castilla, N.; Ruiz, J.M.; Romero, L. 2007. Sucrolytic activities in cherry tomato fruits in relation to temperature and solar radiation. Scientia Horticulturae 113: 244-249.). Although low fruit weight is an undesirable trait for most tomato breeding programs and the high glucose and fructose traits could be partly lost when transferred to breeding lines with higher fruit weight (Levin and Schaffer, 2013Levin, I.; Schaffer, A.A. 2013. Mapping and tagging of simply inherited traits. p. 109-149. In: Liedl, B.E.; Labate, J.A.; Stommel, J.R.; Slade, A.; Chittaranjan, K., eds. Genetics, genomics and breeding of tomato. CRC Press, Boca Raton, FL, USA.), a number of the Penjar accessions evaluated could provide germplasm for developing new cultivars with improved quality and shelf life. Particularly interesting were the accessions CDP06989 (fructose = 33.29 g kg⁻¹ FW; glucose = 29.25 g kg⁻¹ FW) and LC313 (fructose = 32.15 g kg⁻¹ FW; glucose = 28.05 g kg⁻¹ FW), which also had good aroma and taste characteristics according to the trained sensory panel’s descriptions (data not shown).

Average fruit weight loss during storage of Penjar tomatoes (17 % in 120 days) is far lower than that reported in standard varieties. For instance, Getinet et al. (2008)Getinet, H.; Seyoum, T.; Woldetsadik, K. 2008. The effect of cultivar, maturity stage and storage environment on quality of tomatoes. Journal of Food Engineering 87: 467-478. reported that the cultivars Roma and Marglobe lost 14 % to 19 % fruit weight after 32 days of storage, and Javanmardi and Kubota (2006)Javanmardi, J.; Kubota, C. 2006. Variation of lycopene, antioxidant activity, total soluble solids and weight loss of tomato during postharvest storage. Postharvest Biology and Technology 41: 151-155. reported that the cultivar Clermon lost 1 % to 5 % fruit weight after 7 days of storage at different temperatures. Although the effects of temperature and other environmental factors on fruit weight loss make it difficult to compare results across studies, the Penjar variety’s pattern of transpiration clearly differs from that of standard tomatoes. Reduced polygalacturonase activity (Mutschler et al., 1988Mutschler, M.; Guttieri, M.; Kinzer, S.; Grierson, D.; Tucker, G. 1988. Changes in ripening-related processes in tomato conditioned by the alc mutant. Theoretical and Applied Genetics 76: 285-292.) and changes in cuticle composition (Saladie et al., 2007Saladie, M.; Matas, A.J.; Isaacson, T.; Jenks, M.A.; Goodwin, S.M.; Niklas, K.J.; Ren, X.L.; Labavitch, J.M.; Shackel, K.A.; Fernie, A.R.; Lytovchenko, A.; O'Neill, M.A.; Watkins, C.B.; Rose, J.K.C. 2007. A reevaluation of the key factors that influence tomato fruit softening and integrity. Plant Physiology 144: 1012-1028.) described in alc mutants could be the basis of the low postharvest fruit weight loss of the Penjar variety. Nevertheless, the presence of alc is insufficient to explain the long shelf life, as the shelf life of the alc control included in the study was only about one month. As reported by Casals et al. (2012)Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229., shorter shelf life in the alc control is probably related to its larger fruit size.

Long-term storage of Penjar tomato results in a large decrease in sugars, a slight decrease in citric acid, and an increase in malic and glutamic acids. Fructose and glucose, found in approximately equimolar concentrations in cultivated tomatoes (Davies and Hobson, 1981Davies, J.N.; Hobson, G.E. 1981. The constituents of tomato fruit: the influence of environment, nutrition, and genotype. Critical Reviews in Food Science and Nutrition 15: 205-280.; Levin et al., 2000Levin, I.; Gilboa, N.; Yeselson, E.; Shen, S.; Schaffer, A.A. 2000. Fgr, a major locus that modulates the fructose to glucose ratio in mature tomato fruits. Theoretical and Applied Genetics 100: 256-262.), are involved in the initial oxidative step of the Embden-Meyerhof-Parnas pathway; thus, their decrease during postharvest must be related to respiration (Wills et al., 1982Wills, R.B.H.; Lee, T.H.; Graham, D.; McGlasson, W.B.; Hall, E.G. 1982. Postharvest, An Introduction to the Physiology and Handling of Fruit and Vegetables. New South Wales University Press, Kensington, UK.). The increase in the fructose-to-glucose ratio during storage is probably due to the different activity of the two molecules in metabolic pathways during postharvest, which results in higher glucose consumption (Patching et al., 1975Patching, C.R.; Maw, G.A.; Davies, J.N. 1975. Metabolism of glucose during ripening of detached tomato fruit. Journal of the Science of Food and Agriculture 26: 23-29.).

Similarly, the decrease in citric acid during postharvest can be explained mainly by its participation in the first steps of the Krebs cycle. Contrary to citric acid, malic acid and glutamic acid increased during postharvest. Malic acid is the second most abundant acid in tomato fruit, and in normal tomatoes its content decreases markedly during ripening (Davies, 1966Davies, J.N. 1966. Changes in non-volatile organic acids of tomato fruit during ripening. Journal of the Science of Food and Agriculture 17: 396-400.) and more slowly during postharvest (Thorne and Efiuvwevwere, 1988Thorne, S.N.; Efiuvwevwere, B.J.O. 1988. Changes in organic-acids in chilled tomato fruit (Lycopersicon esculentum Mill.). Journal of the Science of Food and Agriculture 44: 309-319.). However, malic acid metabolism is under ethylene regulation; Gao et al. (2007)Gao, H.Y.; Zhu, B.Z.; Zhu, H.L.; Zhang, Y.L.; Xie, Y.H.; Li, Y.C.; Luo, Y.B. 2007. Effect of suppression of ethylene biosynthesis on flavor products in tomato fruits. Russian Journal of Plant Physiology 54: 80-88. reported increased malic acid during ripening in transgenic tomatoes with suppressed ethylene biosynthesis. The alc allele induces changes in the ethylene content (Mutschler, 1984Mutschler, M. 1984. Ripening and storage characteristics of the alcobaça ripening mutant in tomato. Journal of the American Society for Horticultural Science 109: 504-507.) similar to those reported by Gao et al. (2007)Gao, H.Y.; Zhu, B.Z.; Zhu, H.L.; Zhang, Y.L.; Xie, Y.H.; Li, Y.C.; Luo, Y.B. 2007. Effect of suppression of ethylene biosynthesis on flavor products in tomato fruits. Russian Journal of Plant Physiology 54: 80-88., so this may explain the postharvest increase in malic acid in Penjar tomatoes.

Glutamic acid is one of the major amino acids present in tomato fruits (Kader et al., 1978Kader, A.A.; Stevens, M.A.; Albright, M.; Morris, L.L. 1978. Amino-acid composition and flavor of fresh market tomatoes as influenced by fruit ripeness when harvested. Journal of the American Society for Horticultural Science 103: 541-544.; Oruna-Concha et al., 2007Oruna-Concha, M.J.; Methven, L.; Blumenthal, H.; Young, C.; Mottram, D.S. 2007. Differences in glutamic acid and 5'-ribonucleotide contents between flesh and pulp of tomatoes and the relationship with umami taste. Journal of Agricultural and Food Chemistry 55: 5776-5780.), and its content increases 10-to-40-fold during ripening (Boggio et al., 2000Boggio, S.B.; Palatnik, J.F.; Heldt, H.W.; Valle, E.M. 2000. Changes in amino acid composition and nitrogen metabolizing enzymes in ripening fruits of Lycopersicon esculentum Mill. Plant Science 159: 125-133.; Oms-Oliu et al., 2011Oms-Oliu, G.; Hertog, M.L.A.T.M.; Poel, B. van de; Ampofo-Asiama, J.; Geeraerd, A.H.; Nicolai, B.M. 2011. Metabolic characterization of tomato fruit during preharvest development, ripening, and postharvest shelf-life. Postharvest Biology and Technology 62: 7-16.). However, less information is available about changes in glutamic acid content during postharvest, making it difficult to compare our results. Oms-Oliu et al. (2011)Oms-Oliu, G.; Hertog, M.L.A.T.M.; Poel, B. van de; Ampofo-Asiama, J.; Geeraerd, A.H.; Nicolai, B.M. 2011. Metabolic characterization of tomato fruit during preharvest development, ripening, and postharvest shelf-life. Postharvest Biology and Technology 62: 7-16. reported an increase in glutamic acid concentration during postharvest; however, the period analyzed was much shorter (10 days) than the 4 month period considered in our study. We found that glutamic acid continued to accumulate during extended storage in all the Penjar accessions. It seems that the metabolic pathways related to glutamic acid accumulation are reinforced during storage (Freeman and Woodbridge, 1960Freeman, J.A.; Woodbridge, C.G. 1960. Effect of maturation, ripening and truss position on the free amino acid content in tomato fruits. Proceedings of the American Society for Horticultural Science 76: 515-523.; Sorrequieta et al., 2010Sorrequieta, A.; Ferraro, G.; Boggio, S.B.; Valle, E.M. 2010. Free amino acid production during tomato fruit ripening: a focus on l-glutamate. Amino Acids 38: 1523-1532.).

The positive correlation between shelf life and fructose and glucose levels at 4 months postharvest most likely reflects an indirect relationship between shelf life and fruit weight rather than a role for reducing sugars in the fruits’ storage ability. Moreover, we found a significant correlation (p < 0.05) between glutamic acid and fructose and glucose. Some authors have hypothesized that glutamic acid uptake in fruit is coupled to the mass flow of sucrose while the fruit is attached to the plant (Valle et al., 1998Valle, E.M.; Boggio, S.B.; Heldt, H.W. 1998. Free amino acid composition of phloem sap and growing fruit of Lycopersicon esculentum. Plant and Cell Physiology 39: 458-461.; Winter et al., 1992)Winter, H.; Lohaus, G.; Heldt, H.W. 1992. Phloem transport of amino-acids in relation to their cytosolic levels in barley leaves. Plant Physiology 99: 996-1004., and this hypothesis might explain the correlation observed between the concentration of sugars and glutamic acid.

During the aging phase, the sensory profile of Penjar tomatoes varies with changes in sugar and acid levels, as well as with changes in volatile concentrations (Casals et al., 2011Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.). On the one hand, sweetness decreases with the reduction of glucose and fructose, although the unusually high concentrations of these molecules at harvest ensure adequate levels of sweetness during the first months of storage. On the other hand, although citric acid content decreased, the combined level of citric and malic acids remained unchanged during storage. This more acidic profile of aged Penjar tomatoes could explain the enhancement of some aroma descriptors in Penjar tomatoes reported by Casals et al. (2011)Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342., as acidity probably affects the perception of some volatiles (Baldwin et al., 2008Baldwin, E.A.; Goodner, K.; Plotto, A. 2008. Interaction of volatiles, sugars, and acids on perception of tomato aroma and flavor descriptors. Journal of Food Science 73: S294-S307.). Finally, the increased glutamic acid concentration may also contribute to the appreciation of the consumer for aged Penjar tomatoes.

Glutamate is a powerful taste enhancer (Bellisle, 1999Bellisle, F. 1999. Glutamate and the UMAMI taste: sensory, metabolic, nutritional and behavioural considerations: a review of the literature published in the last 10 years. Neuroscience & Biobehavioral Reviews 23: 423-438.), but its role in tomato flavor has been scarcely studied since Bucheli et al. (1999)Bucheli, P.; Voirol, E.; Torre, R. de la; Lopez, J.; Rytz, A.; Tanksley, S.D.; Petiard, V. 1999. Definition of nonvolatile markers for flavor of tomato (Lycopersicon esculentum Mill.) as tools in selection and breeding. Journal of Agricultural and Food Chemistry 47: 659-664. who reported its negative effect on fruitiness attribute. The combined effect of high concentrations of sugars and acid, together with the appearance of new flavors due to the rearrangement of the relative concentrations among volatiles and the increase in glutamic acid content, makes the period between 1 and 4 months after harvest the best time to consume Penjar tomatoes. These findings on compositional changes during the aging phase and their relation to the commercial success of Penjar tomatoes could help breeders develop new cultivars with better flavor and longer shelf life.

Conclusions

The sugar-and-acid profile varies widely between accessions of the Penjar variety, but on average, sugar concentrations at harvest are higher than in conventional tomatoes; higher concentrations of sugar are probably related to Penjar’s medium-small fruit size. Some of the studied accessions have good quality characteristics at harvest, making them particularly interesting as non-aged materials for quality markets or for use in breeding programs. During storage, concentrations of the compounds involved in the first steps of respiration (glucose, fructose, and citric acid) decrease, and concentrations of malic acid and glutamic acid increase significantly. Nevertheless, due to the high concentrations of sugars at harvest, acceptable levels of sweetness are maintained for several months after harvest. These postharvest changes contribute to the characteristic sensory profile of Penjar tomatoes, which is highly appreciated by local consumers. Penjar tomatoes reach their best sensory quality between 1 and 4 months postharvest, although the shelf life of many accessions may exceed this period.

Acknowledgements

To Dr. Luís Bosch Roura for his active participation in this study.

References

Baldwin, E.A.; Goodner, K.; Plotto, A. 2008. Interaction of volatiles, sugars, and acids on perception of tomato aroma and flavor descriptors. Journal of Food Science 73: S294-S307.
Beckles, D.M. 2012. Factors affecting the postharvest soluble solids and sugar content of tomato (Solanum lycopersicum L.) fruit. Postharvest Biology and Technology 63: 129-140.
Bellisle, F. 1999. Glutamate and the UMAMI taste: sensory, metabolic, nutritional and behavioural considerations: a review of the literature published in the last 10 years. Neuroscience & Biobehavioral Reviews 23: 423-438.
Boggio, S.B.; Palatnik, J.F.; Heldt, H.W.; Valle, E.M. 2000. Changes in amino acid composition and nitrogen metabolizing enzymes in ripening fruits of Lycopersicon esculentum Mill. Plant Science 159: 125-133.
Bota, J.; Conesa, M.À.; Ochogavia, J.M.; Medrano, H.; Francis, D.M.; Cifre, J. 2014. Characterization of a landrace collection for Tomàtiga de Ramellet (Solanum lycopersicum L.) from the Balearic Islands. Genetic Resources and Crop Evolution 61: 1131-1146.
Bucheli, P.; Voirol, E.; Torre, R. de la; Lopez, J.; Rytz, A.; Tanksley, S.D.; Petiard, V. 1999. Definition of nonvolatile markers for flavor of tomato (Lycopersicon esculentum Mill.) as tools in selection and breeding. Journal of Agricultural and Food Chemistry 47: 659-664.
Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.
Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.
Causse, M.; Damidaux, R.; Rousselle, P. 2007. Traditional and enhanced breeding for quality traits in tomato. v. 2, p. 153-192. In: Razdan, M.K.; Mattoo, A.K., eds. Genetic improvement of Solanaceous crops: tomato. CRC Press, Boca Raton, FL, USA.
Cebolla-Cornejo, J.; Valcarcel, M.; Herrero-Martinez, J.M.; Rosello, S.; Nuez, F. 2012. High efficiency joint CZE determination of sugars and acids in vegetables and fruits. Electrophoresis 33: 2416-2423.
Davies, J.N. 1966. Changes in non-volatile organic acids of tomato fruit during ripening. Journal of the Science of Food and Agriculture 17: 396-400.
Davies, J.N.; Hobson, G.E. 1981. The constituents of tomato fruit: the influence of environment, nutrition, and genotype. Critical Reviews in Food Science and Nutrition 15: 205-280.
Ercolano, M.R.; Carli, P.; Soria, A.; Cascone, A.; Fogliano, V.; Frusciante, L.; Barone, A. 2008. Biochemical, sensorial and genomic profiling of traditional Italian tomato varieties. Euphytica 164: 571-582.
Freeman, J.A.; Woodbridge, C.G. 1960. Effect of maturation, ripening and truss position on the free amino acid content in tomato fruits. Proceedings of the American Society for Horticultural Science 76: 515-523.
Gao, H.Y.; Zhu, B.Z.; Zhu, H.L.; Zhang, Y.L.; Xie, Y.H.; Li, Y.C.; Luo, Y.B. 2007. Effect of suppression of ethylene biosynthesis on flavor products in tomato fruits. Russian Journal of Plant Physiology 54: 80-88.
Getinet, H.; Seyoum, T.; Woldetsadik, K. 2008. The effect of cultivar, maturity stage and storage environment on quality of tomatoes. Journal of Food Engineering 87: 467-478.
Javanmardi, J.; Kubota, C. 2006. Variation of lycopene, antioxidant activity, total soluble solids and weight loss of tomato during postharvest storage. Postharvest Biology and Technology 41: 151-155.
Kader, A.A.; Stevens, M.A.; Albright, M.; Morris, L.L. 1978. Amino-acid composition and flavor of fresh market tomatoes as influenced by fruit ripeness when harvested. Journal of the American Society for Horticultural Science 103: 541-544.
Klee, H.J.; Giovannoni, J.J. 2011. Genetics and control of tomato fruit ripening and quality attributes. Annual Review of Genetics 45: 41-59.
Kopeliovitch, E.; Mizrahi, Y.; Rabinowitch, H.D.; Kedar, N. 1980. Physiology of the tomato mutant alcobaça. Physiologia Plantarum 48: 307-311.
Levin, I.; Gilboa, N.; Yeselson, E.; Shen, S.; Schaffer, A.A. 2000. Fgr, a major locus that modulates the fructose to glucose ratio in mature tomato fruits. Theoretical and Applied Genetics 100: 256-262.
Levin, I.; Schaffer, A.A. 2013. Mapping and tagging of simply inherited traits. p. 109-149. In: Liedl, B.E.; Labate, J.A.; Stommel, J.R.; Slade, A.; Chittaranjan, K., eds. Genetics, genomics and breeding of tomato. CRC Press, Boca Raton, FL, USA.
Loiudice, R.; Impembo, M.; Laratta, B.; Villari, G.; Lovoi, A.; Siviero, P.; Castaldo, D. 1995. Composition of San-Marzano tomato varieties. Food Chemistry 53: 81-89.
Mutschler, M. 1984. Ripening and storage characteristics of the alcobaça ripening mutant in tomato. Journal of the American Society for Horticultural Science 109: 504-507.
Mutschler, M.; Guttieri, M.; Kinzer, S.; Grierson, D.; Tucker, G. 1988. Changes in ripening-related processes in tomato conditioned by the alc mutant. Theoretical and Applied Genetics 76: 285-292.
Oms-Oliu, G.; Hertog, M.L.A.T.M.; Poel, B. van de; Ampofo-Asiama, J.; Geeraerd, A.H.; Nicolai, B.M. 2011. Metabolic characterization of tomato fruit during preharvest development, ripening, and postharvest shelf-life. Postharvest Biology and Technology 62: 7-16.
Oruna-Concha, M.J.; Methven, L.; Blumenthal, H.; Young, C.; Mottram, D.S. 2007. Differences in glutamic acid and 5'-ribonucleotide contents between flesh and pulp of tomatoes and the relationship with umami taste. Journal of Agricultural and Food Chemistry 55: 5776-5780.
Patching, C.R.; Maw, G.A.; Davies, J.N. 1975. Metabolism of glucose during ripening of detached tomato fruit. Journal of the Science of Food and Agriculture 26: 23-29.
Prudent, M.; Causse, M.; Genard, M.; Tripodi, P.; Grandillo, S.; Bertin, N. 2009. Genetic and physiological analysis of tomato fruit weight and composition: influence of carbon availability on QTL detection. Journal of Experimental Botany 60: 923-937.
Robinson, R.W.; Tomes, M.L. 1968. Ripening inhibitor: a gene with multiple effects on ripening. Report of the Tomato Genetics Cooperative 18: 36-37.
Rosales, M.A.; Rubio-Wilhelmi, M.M.; Castellano, R.; Castilla, N.; Ruiz, J.M.; Romero, L. 2007. Sucrolytic activities in cherry tomato fruits in relation to temperature and solar radiation. Scientia Horticulturae 113: 244-249.
Sakiyama, R.; Stevens, M.A. 1976. Organic-acid accumulation in attached and detached tomato fruits. Journal of the American Society for Horticultural Science 101: 394-396.
Saladie, M.; Matas, A.J.; Isaacson, T.; Jenks, M.A.; Goodwin, S.M.; Niklas, K.J.; Ren, X.L.; Labavitch, J.M.; Shackel, K.A.; Fernie, A.R.; Lytovchenko, A.; O'Neill, M.A.; Watkins, C.B.; Rose, J.K.C. 2007. A reevaluation of the key factors that influence tomato fruit softening and integrity. Plant Physiology 144: 1012-1028.
Siracusa, L.; Patane, C.; Avola, G.; Ruberto, G. 2012. Polyphenols as chemotaxonomic markers in italian "long-storage" tomato genotypes. Journal of Agricultural and Food Chemistry 60: 309-314.
Sorrequieta, A.; Ferraro, G.; Boggio, S.B.; Valle, E.M. 2010. Free amino acid production during tomato fruit ripening: a focus on l-glutamate. Amino Acids 38: 1523-1532.
Thorne, S.N.; Efiuvwevwere, B.J.O. 1988. Changes in organic-acids in chilled tomato fruit (Lycopersicon esculentum Mill.). Journal of the Science of Food and Agriculture 44: 309-319.
Valle, E.M.; Boggio, S.B.; Heldt, H.W. 1998. Free amino acid composition of phloem sap and growing fruit of Lycopersicon esculentum Plant and Cell Physiology 39: 458-461.
Watada, A.E.; Herner, R.C.; Kader, A.A.; Romani, R.J.; Staby, G.L. 1984. Terminology for the description of developmental stages of horticultural crops. Hortscience 19: 20-21.
Wills, R.B.H.; Lee, T.H.; Graham, D.; McGlasson, W.B.; Hall, E.G. 1982. Postharvest, An Introduction to the Physiology and Handling of Fruit and Vegetables. New South Wales University Press, Kensington, UK.
Winter, H.; Lohaus, G.; Heldt, H.W. 1992. Phloem transport of amino-acids in relation to their cytosolic levels in barley leaves. Plant Physiology 99: 996-1004.

Edited by

Edited by: Leonardo Oliveira Medici

Publication Dates

Publication in this collection
Jul-Aug 2015

History

Received
17 Sept 2014
Accepted
01 Mar 2015

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

[1] Baldwin, E.A.; Goodner, K.; Plotto, A. 2008. Interaction of volatiles, sugars, and acids on perception of tomato aroma and flavor descriptors. Journal of Food Science 73: S294-S307.

[2] Beckles, D.M. 2012. Factors affecting the postharvest soluble solids and sugar content of tomato (Solanum lycopersicum L.) fruit. Postharvest Biology and Technology 63: 129-140.

[3] Bellisle, F. 1999. Glutamate and the UMAMI taste: sensory, metabolic, nutritional and behavioural considerations: a review of the literature published in the last 10 years. Neuroscience & Biobehavioral Reviews 23: 423-438.

[4] Boggio, S.B.; Palatnik, J.F.; Heldt, H.W.; Valle, E.M. 2000. Changes in amino acid composition and nitrogen metabolizing enzymes in ripening fruits of Lycopersicon esculentum Mill. Plant Science 159: 125-133.

[5] Bota, J.; Conesa, M.À.; Ochogavia, J.M.; Medrano, H.; Francis, D.M.; Cifre, J. 2014. Characterization of a landrace collection for Tomàtiga de Ramellet (Solanum lycopersicum L.) from the Balearic Islands. Genetic Resources and Crop Evolution 61: 1131-1146.

[6] Bucheli, P.; Voirol, E.; Torre, R. de la; Lopez, J.; Rytz, A.; Tanksley, S.D.; Petiard, V. 1999. Definition of nonvolatile markers for flavor of tomato (Lycopersicon esculentum Mill.) as tools in selection and breeding. Journal of Agricultural and Food Chemistry 47: 659-664.

[7] Casals, J.; Cebolla-Cornejo, J.; Rosello, S.; Beltran, J.; Casanas, F.; Nuez, F. 2011. Long-term postharvest aroma evolution of tomatoes with the alcobaça (alc) mutation. European Food Research and Technology 233: 331-342.

[8] Casals, J.; Pascual, L.; Canizares, J.; Cebolla-Cornejo, J.; Casanas, F.; Nuez, F. 2012. Genetic basis of long shelf life and variability into Penjar tomato. Genetic Resources and Crop Evolution 59: 219-229.

[9] Causse, M.; Damidaux, R.; Rousselle, P. 2007. Traditional and enhanced breeding for quality traits in tomato. v. 2, p. 153-192. In: Razdan, M.K.; Mattoo, A.K., eds. Genetic improvement of Solanaceous crops: tomato. CRC Press, Boca Raton, FL, USA.

[10] Cebolla-Cornejo, J.; Valcarcel, M.; Herrero-Martinez, J.M.; Rosello, S.; Nuez, F. 2012. High efficiency joint CZE determination of sugars and acids in vegetables and fruits. Electrophoresis 33: 2416-2423.

[11] Davies, J.N. 1966. Changes in non-volatile organic acids of tomato fruit during ripening. Journal of the Science of Food and Agriculture 17: 396-400.

[12] Davies, J.N.; Hobson, G.E. 1981. The constituents of tomato fruit: the influence of environment, nutrition, and genotype. Critical Reviews in Food Science and Nutrition 15: 205-280.

[13] Ercolano, M.R.; Carli, P.; Soria, A.; Cascone, A.; Fogliano, V.; Frusciante, L.; Barone, A. 2008. Biochemical, sensorial and genomic profiling of traditional Italian tomato varieties. Euphytica 164: 571-582.

[14] Freeman, J.A.; Woodbridge, C.G. 1960. Effect of maturation, ripening and truss position on the free amino acid content in tomato fruits. Proceedings of the American Society for Horticultural Science 76: 515-523.

[15] Gao, H.Y.; Zhu, B.Z.; Zhu, H.L.; Zhang, Y.L.; Xie, Y.H.; Li, Y.C.; Luo, Y.B. 2007. Effect of suppression of ethylene biosynthesis on flavor products in tomato fruits. Russian Journal of Plant Physiology 54: 80-88.

[16] Getinet, H.; Seyoum, T.; Woldetsadik, K. 2008. The effect of cultivar, maturity stage and storage environment on quality of tomatoes. Journal of Food Engineering 87: 467-478.

[17] Javanmardi, J.; Kubota, C. 2006. Variation of lycopene, antioxidant activity, total soluble solids and weight loss of tomato during postharvest storage. Postharvest Biology and Technology 41: 151-155.

[18] Kader, A.A.; Stevens, M.A.; Albright, M.; Morris, L.L. 1978. Amino-acid composition and flavor of fresh market tomatoes as influenced by fruit ripeness when harvested. Journal of the American Society for Horticultural Science 103: 541-544.

[19] Klee, H.J.; Giovannoni, J.J. 2011. Genetics and control of tomato fruit ripening and quality attributes. Annual Review of Genetics 45: 41-59.

[20] Kopeliovitch, E.; Mizrahi, Y.; Rabinowitch, H.D.; Kedar, N. 1980. Physiology of the tomato mutant alcobaça. Physiologia Plantarum 48: 307-311.

[21] Levin, I.; Gilboa, N.; Yeselson, E.; Shen, S.; Schaffer, A.A. 2000. Fgr, a major locus that modulates the fructose to glucose ratio in mature tomato fruits. Theoretical and Applied Genetics 100: 256-262.

[22] Levin, I.; Schaffer, A.A. 2013. Mapping and tagging of simply inherited traits. p. 109-149. In: Liedl, B.E.; Labate, J.A.; Stommel, J.R.; Slade, A.; Chittaranjan, K., eds. Genetics, genomics and breeding of tomato. CRC Press, Boca Raton, FL, USA.

[23] Loiudice, R.; Impembo, M.; Laratta, B.; Villari, G.; Lovoi, A.; Siviero, P.; Castaldo, D. 1995. Composition of San-Marzano tomato varieties. Food Chemistry 53: 81-89.

[24] Mutschler, M. 1984. Ripening and storage characteristics of the alcobaça ripening mutant in tomato. Journal of the American Society for Horticultural Science 109: 504-507.

[25] Mutschler, M.; Guttieri, M.; Kinzer, S.; Grierson, D.; Tucker, G. 1988. Changes in ripening-related processes in tomato conditioned by the alc mutant. Theoretical and Applied Genetics 76: 285-292.

[26] Oms-Oliu, G.; Hertog, M.L.A.T.M.; Poel, B. van de; Ampofo-Asiama, J.; Geeraerd, A.H.; Nicolai, B.M. 2011. Metabolic characterization of tomato fruit during preharvest development, ripening, and postharvest shelf-life. Postharvest Biology and Technology 62: 7-16.

[27] Oruna-Concha, M.J.; Methven, L.; Blumenthal, H.; Young, C.; Mottram, D.S. 2007. Differences in glutamic acid and 5'-ribonucleotide contents between flesh and pulp of tomatoes and the relationship with umami taste. Journal of Agricultural and Food Chemistry 55: 5776-5780.

[28] Patching, C.R.; Maw, G.A.; Davies, J.N. 1975. Metabolism of glucose during ripening of detached tomato fruit. Journal of the Science of Food and Agriculture 26: 23-29.

[29] Prudent, M.; Causse, M.; Genard, M.; Tripodi, P.; Grandillo, S.; Bertin, N. 2009. Genetic and physiological analysis of tomato fruit weight and composition: influence of carbon availability on QTL detection. Journal of Experimental Botany 60: 923-937.

[30] Robinson, R.W.; Tomes, M.L. 1968. Ripening inhibitor: a gene with multiple effects on ripening. Report of the Tomato Genetics Cooperative 18: 36-37.

[31] Rosales, M.A.; Rubio-Wilhelmi, M.M.; Castellano, R.; Castilla, N.; Ruiz, J.M.; Romero, L. 2007. Sucrolytic activities in cherry tomato fruits in relation to temperature and solar radiation. Scientia Horticulturae 113: 244-249.

[32] Sakiyama, R.; Stevens, M.A. 1976. Organic-acid accumulation in attached and detached tomato fruits. Journal of the American Society for Horticultural Science 101: 394-396.

[33] Saladie, M.; Matas, A.J.; Isaacson, T.; Jenks, M.A.; Goodwin, S.M.; Niklas, K.J.; Ren, X.L.; Labavitch, J.M.; Shackel, K.A.; Fernie, A.R.; Lytovchenko, A.; O'Neill, M.A.; Watkins, C.B.; Rose, J.K.C. 2007. A reevaluation of the key factors that influence tomato fruit softening and integrity. Plant Physiology 144: 1012-1028.

[34] Siracusa, L.; Patane, C.; Avola, G.; Ruberto, G. 2012. Polyphenols as chemotaxonomic markers in italian "long-storage" tomato genotypes. Journal of Agricultural and Food Chemistry 60: 309-314.

[35] Sorrequieta, A.; Ferraro, G.; Boggio, S.B.; Valle, E.M. 2010. Free amino acid production during tomato fruit ripening: a focus on l-glutamate. Amino Acids 38: 1523-1532.

[36] Thorne, S.N.; Efiuvwevwere, B.J.O. 1988. Changes in organic-acids in chilled tomato fruit (Lycopersicon esculentum Mill.). Journal of the Science of Food and Agriculture 44: 309-319.

[37] Valle, E.M.; Boggio, S.B.; Heldt, H.W. 1998. Free amino acid composition of phloem sap and growing fruit of Lycopersicon esculentum Plant and Cell Physiology 39: 458-461.

[38] Watada, A.E.; Herner, R.C.; Kader, A.A.; Romani, R.J.; Staby, G.L. 1984. Terminology for the description of developmental stages of horticultural crops. Hortscience 19: 20-21.

[39] Wills, R.B.H.; Lee, T.H.; Graham, D.; McGlasson, W.B.; Hall, E.G. 1982. Postharvest, An Introduction to the Physiology and Handling of Fruit and Vegetables. New South Wales University Press, Kensington, UK.

[40] Winter, H.; Lohaus, G.; Heldt, H.W. 1992. Phloem transport of amino-acids in relation to their cytosolic levels in barley leaves. Plant Physiology 99: 996-1004.

Type	Accession	Origin	Fruit shape	Fruit weight¹	Shelf life¹
Landraces				g	days
	CDP01203	Sant Vicenç de Montalt, NE Spain	Cylindrical	34.4	139.3
	CDP05566	Cassà de la Selva, NE Spain	Cylindrical	37.9	129.4
	CDP01254	Llinars del Vallès, NE Spain	Heart-shaped	25.2	133.9
	CDP01447	Pineda de Mar, NE Spain	Cylindrical	42.2	128.8
	CDP00235	Mollet del Vallès, NE Spain	Slightly flattened	95.0	94.3
	CDP01255	Arenys de Munt, NE Spain	Rounded	60.7	132.3
	CDP07789	Argentona, NE Spain	Ellipsoid	34.6	132.0
	CDP01114	Creixell, NE Spain	Rounded	53.6	118.3
	CDP07531	Sant Quintí de Mediona, NE Spain	Highly rounded	50.8	117.9
	LC77	Castellbell i el Vilar, NE Spain	Ellipsoid	34.5	40.6
	CDP03512	Palafolls, NE Spain	Rounded	51.5	129.8
	CDP02569	Sabadell, NE Spain	Heart-shaped	54.0	126.0
	CDP03365	Sabadell, NE Spain	Slightly flattened	74.1	117.9
	CDP02588	Unknown	Flattened	78.0	106.9
	CDP06432	Sabadell, NE Spain	Flattened	47.7	138.6
	CDP00023	Unknown	Rounded	100.5	118.4
	CDP01245	Estanyol, NE Spain	Slightly flattened	46.5	137.6
	CDP01475	Santa Coloma de Farners, NE Spain	Cylindrical	62.3	115.2
	CDP05468	Unknown	Heart-shaped	31.2	133.9
	CDP01127	Mallorca, Balearic Islands	Heart-shaped	120.2	98.7
	CDP03698	Unknown	Cylindrical	71.0	99.3
	LC313	Blanes, NE Spain	Heart-shaped	68.4	127.9
	CDP06989	Blanes, NE Spain	Heart-shaped	60.9	131.5

Commercial varieties (Penjar)
	CDP03366	Hortícola Alavesa SL	Slightly flattened	120.9	98.4
	CDP02356	Diamond Seeds SL	Rounded	57.0	123.6

Ripening mutants (controls)³
	LA3770 (nor)	TGRC²	Rounded	51.9	124.8
	LA3012 (rin)	TGRC²	Rounded	128.2	18.1
	LA3134 (alc)	TGRC²	Rounded	130.7	20.8
	LA0162 (Nr)	TGRC²	Rounded	122.0	11.2

Commercial hybrid
	Bodar	Royal Sluis	Rounded	131.96	19.2

Accession	Malic acid	Citric acid	Glutamic acid	Fructose	Glucose	Fructose to glucose ratio
			g kg⁻¹fresh weight (FW)
Bodar	0.89 ± 0.05	4.23 ± 0.43	1.50 ± 0.13	18.39 ± 1.23	18.43 ± 1.04	1.00 ± 0.03
LA0162 (Nr)¹	1.20 ± 0.10	6.04 ± 0.28	1.71 ± 0.15	12.82 ± 0.72	10.28 ± 0.90	1.25 ± 0.04
LA3012 (rin)¹	1.32 ± 0.13	3.16 ± 0.01	2.86 ± 0.83	16.44 ± 1.82	13.66 ± 1.28	1.20 ± 0.03
LA3134 (alc)¹	0.89 ± 0.12	6.44 ± 0.20	2.22 ± 0.07	16.77 ± 3.61	13.56 ± 4.18	1.24 ± 0.12
LA3770 (nor)¹	1.63 ± 0.28	5.11 ± 0.37	0.85 ± 0.29	20.17 ± 4.32	18.18 ± 3.83	1.11 ± 0.03
CDP03512	1.01 ± 0.10	5.26 ± 0.68	3.21 ± 0.87	28.16 ± 6.43	21.19 ± 3.35	1.33 ± 0.11
CDP01203	1.05 ± 0.10	5.30 ± 0.30	3.58 ± 0.67	28.18 ± 2.62	22.34 ± 1.41	1.26 ± 0.06
CDP02569	0.84 ± 0.13	6.41 ± 1.07	2.38 ± 0.43	23.10 ± 3.09	20.29 ± 2.49	1.14 ± 0.04
CDP03365	1.57 ± 0.30	4.95 ± 0.43	3.49 ± 0.16	22.71 ± 4.13	19.26 ± 3.94	1.18 ± 0.05
CDP05566	1.05 ± 0.07	4.92 ± 0.65	3.13 ± 0.14	33.67 ± 5.19	29.23 ± 5.47	1.15 ± 0.09
CDP02588	0.81 ± 0.13	7.11 ± 0.56	2.78 ± 0.39	17.13 ± 1.23	13.83 ± 0.62	1.24 ± 0.03
CDP06432	0.96 ± 0.13	4.42 ± 0.03	3.21 ± 0.39	22.39 ± 1.56	17.28 ± 0.32	1.30 ± 0.11
CDP00023	0.86 ± 0.22	4.90 ± 0.71	2.30 ± 0.33	18.78 ± 3.28	14.70 ± 3.25	1.28 ± 0.19
CDP01245	1.04 ± 0.11	4.58 ± 0.44	2.40 ± 0.72	25.02 ± 5.50	19.70 ± 4.36	1.27 ± 0.09
CDP01254	0.85 ± 0.16	4.83 ± 0.37	3.17 ± 0.32	24.80 ± 4.42	19.44 ± 3.99	1.28 ± 0.08
CDP01475	1.17 ± 0.21	4.14 ± 0.42	3.42 ± 0.29	27.82 ± 2.28	22.95 ± 2.59	1.21 ± 0.07
CDP05468	1.09 ± 0.14	4.24 ± 0.13	2.60 ± 0.32	21.15 ± 3.72	15.42 ± 2.05	1.37 ± 0.12
CDP01127	0.84 ± 0.20	4.11 ± 0.78	1.21 ± 0.44	14.41 ± 0.92	11.62 ± 0.30	1.24 ± 0.11
CDP03698	1.39 ± 0.13	5.06 ± 0.07	3.79 ± 0.45	25.24 ± 1.13	22.65 ± 2.48	1.11 ± 0.09
CDP01447	0.85 ± 0.12	4.48 ± 1.18	2.75 ± 0.87	29.71 ± 9.83	23.60 ± 7.96	1.26 ± 0.07
LC313	1.21 ± 0.13	4.89 ± 0.36	3.13 ± 0.25	32.15 ± 4.26	28.05 ± 3.65	1.15 ± 0.01
CDP06989	0.96 ± 0.14	4.23 ± 1.04	3.82 ± 0.08	33.29 ± 1.56	29.25 ± 0.56	1.14 ± 0.03
CDP00235	0.71 ± 0.01	4.00 ± 0.79	2.40 ± 0.04	19.90 ± 3.57	16.29 ± 3.16	1.22 ± 0.03
CDP01255	1.29 ± 0.34	4.56 ± 0.73	3.67 ± 0.62	29.22 ± 2.83	25.20 ± 2.59	1.16 ± 0.02
CDP07789	0.59 ± 0.09	5.48 ± 0.33	3.74 ± 0.51	34.76 ± 2.83	28.26 ± 4.08	1.23 ± 0.07
CDP01114	1.29 ± 0.15	4.41 ± 0.48	3.17 ± 0.45	26.50 ± 2.98	20.07 ± 3.32	1.32 ± 0.05
CDP07531	1.44 ± 0.06	4.15 ± 0.37	0.92 ± 0.25	17.28 ± 2.70	12.96 ± 1.78	1.33 ± 0.04
LC77	1.10 ± 0.09	6.15 ± 1.20	3.20 ± 0.89	33.78 ± 6.48	29.64 ± 5.43	1.14 ± 0.07
CDP03366	0.93 ± 0.10	3.94 ± 0.52	2.62 ± 0.21	16.03 ± 0.05	12.61 ± 1.84	1.27 ± 0.19
CDP02356	1.20 ± 0.25	4.42 ± 0.87	3.77 ± 0.61	27.11 ± 5.08	22.86 ± 3.92	1.19 ± 0.02
p-value	<0.0001	<0.0001	<0.0001	<0.0001	<0.0001	0.0038

Brasil