1. Introduction
The Rosaceae family, to which the genus
Malus belongs, is widely represented in the European flora [
1]. It seems that most of the cultivated apple trees grown for the production of both table and cider apples come from hybrids from different species, such as
Malus dasyphylla Borkh that originally came from Asia [
2] and the European wild apple (
Malus sylvestris Mill.); both species could be considered as the origin of the cultivated or domestic apple tree (
Malus domestica Borkh.) [
3,
4] and some gene flow between them has been described [
5].
Apple was the third-most important fruit produced and eaten around the world with a production of 86.1 million t in 2018, of which 19.6 million t corresponded to Europe. The largest producer was China, representing around 45.5% of the world’s total production. The US was the second-largest producer with 5.4%, followed by Poland (4.6%), Turkey (4.2%), Iran (2.9%), and Italy (2.8%). Spain, with 0.56 million tons was the 10th European producer [
6]. In Spain, the apple represents the third-most important crop after citrus fruits and the group of peaches and nectarines [
7], and is also one of the most imported fruits along with pineapple, banana, and kiwi [
8]. The main apple production areas are the regions of Catalonia and Aragon, with a very important polarization in the production of the group “Golden”. In the 2008–2018 period, the “Golden Delicious” variety accounted for 45% of the national production [
7].
The “Pero de Cehegín”, framed within the “common cultivated apple trees” in the genus and species
Malus domestica Borkh [
9], is a local variety of apple tree, cultivated mainly in the northwest of the Murcia province (Spain). The reason for its name is that its cultivation has historically been carried out almost exclusively in the municipality of Cehegín, which has a suitable habitat for this apple variety. The fruits (
Figure 1) are medium size, longer than wide, and flat at the ends of their axis. Before ripening, its color is dark green, and once ripe its changes to a greenish-yellow, being more colored in the sun-exposed area. Its pulp is firm and of great quality, and has an exquisite flavor and a fragrant aroma [
10]. The fruit ripening occurs in November [
9].
Although the denomination of “Pero” has enjoyed some esteem in the cultivation region, the name is usually applied with little precision. Thus, for some local farmers, the “Pero” fruits are characterized by their intense aroma, for others, by a peculiar texture of its pulp, and for others by an elongated, oval, or conical shape, almost resembling a pear.
Table 1 shows the differences between “Pero” and “apple” [
9].
Local varieties are the result of selection through climatic and edaphic adaptation and human action [
11,
12]. However, these traditional varieties have been replaced with new ones of foreign origin, which causes a strong genetic erosion in the agricultural heritage. However, these old and local varieties in terms of biodiversity have an extremely high value [
13], and as opposed to commercial varieties, often carry specific and uncommon properties that could be interesting to different consumers. Therefore, consumers must understand the kind of properties that distinguish them from standard varieties in the market [
14,
15]. Due to these reasons, the conservation of the local genetic diversity to prevent its disappearance is urgent. Along this line, Martínez [
16] carried out the first prospection and selection of the “Pero de Cehegín” in several areas of Cehegín (Murcia, Spain); this work was the beginning of two germplasm collections. Germplasm banks, in their current conception, constitute essential systems for avoiding the loss of genetic biodiversity and, therefore, to guarantee the future of endangered species. The collections are located in two different areas, one in the Higher Polytechnic School of Orihuela, EPSO (UMH) in the province of Alicante, and the other in Cehegín, in the northwest of Murcia region. These collections were extended with the introduction of new clones selected in recent years from different geographic origins, and now total 27 accessions.
The genetic and phenotypic characterization of these traditional varieties will help in the conservation and use in future breeding programs. The molecular characterization of apple collections has been performed in the past using Simple Sequence Repeats (SSR). A high number of microsatellites have been described and used to identify different varieties [
17,
18,
19,
20] and to assess the genetic diversity in core collections [
21,
22,
23,
24]. In particular, there are several studies in Spanish germplasm collections [
23] but to our knowledge, the “Pero de Cehegín” has not been included yet.
At present, several studies have been published about apple variety characterization from China [
25], Portugal [
26,
27], Romania [
14], Argentina [
28], Brazil [
29], and India [
30,
31].
Generally, the definition of quality and acceptability of apple fruits by consumers are associated with their sensory appeal and chemical composition [
32,
33]. The concept of “appearance” includes several external fruit characteristics such as size, shape, absence of defects, and color [
33]. The rescue of traditional varieties, with distinctive characteristics and good appearance, will help diversify and enrich the offerings for the consumers’ demand for new apples or traditional and local varieties with good nutritional, organoleptic, and morphological characteristics.
Consequently, the present study aims to determine the genetic identity of “Pero de Cehegín” using microsatellite markers and to evaluate the main physicochemical characteristics, bioactive compounds, and sensory profile of five selected clones of “Pero de Cehegín” fruits. The “Pero de Cehegín” properties were compared with those of two commercial varieties (“Fuji” and “Golden Delicious”). The marketing potential of these five clones is also discussed.
2. Materials and Methods
2.1. Experimental Conditions and Plant Material
For the physicochemical characteristics, bioactive compounds and sensory profile, five clones of “Pero de Cehegín” (identified as P1, P2, P3, P4, P5), Malus domestica, the “Golden Delicious” variety and the “Fuji” variety, were collected from the germplasm bank located in the municipality of Cehegín (Murcia, Spain). Furthermore, the five “Pero de Cehegín” clones were also used for molecular analysis. Aiming to base the molecular characterization of “Pero de Cehegín” and its comparison, two reference varieties were taken, “Fuji” and “Granny Smith”, due its international importance as commercial cultivars.
The apple trees were 12 years old and spaced following a 4 × 2 m pattern. All the clones were grafted onto the M9 rootstock and grown under standard conditions (with a loam-type soil, fertilizing with a quantity of 2 kg of organic matter and 2 kg of complex fertilizer 15% N-15% P
2O
5-15% K
2O per tree and year, and according to Papadakis [
34] for a Mediterranean climate). For each clone, 20 fruit samples were randomly collected from three trees (for a total of 60 fruits per clone) avoiding damaged fruits. Harvest was done manually in all clones at their commercial maturity stage, during November 2017, 10 days after finishing its development and reaching its characteristic color. The fruits were stored refrigerated at 3 °C until their study a few days later.
2.2. Polymerase Chain Reaction Amplification and SSR Analyses
Leaves were collected from the trees of the five “Pero de Cehegín” clones in the Cehegín germplasm bank. Two hundred milligrams were frozen in liquid nitrogen and ground to a fine powder using the mixer mill MM400 (Retsh, Haan Germany) and stored at −20 °C until further processing. Genomic DNA was isolated with Qiagen Dneasy Plant Mini kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions. The DNA concentration was determined with a NanoDrop 2000 (Thermo Fisher Scientific, Wilmington, DE, USA) and adjusted to 5 ng µL−1 for multiplex PCR.
PCR reactions were carried out with 13 SSRs, including 11 recommended by the ECP/GR
Malus/Pyrus Working Group (European Cooperative Programme for Plant Genetic Resources; Lateur et al. [
35] (CH04e05, CH01h10, CH02d08, CH01f02, CH02c11, CH04c07, CH02c09, and CH01h01; GD12, GD147, Hi02c07) plus another two due to their usefulness in discriminating the Spanish varieties (CH05f06 and CH03d07) [
23].
The amplification was performed in a 2700 thermal cycler (Applied Biosystems
®), using three multiplex PCRs A, B, and C; see details [
36] in a final volume of 10 μL using 10 ng of DNA template, 0.10–015 μM of each primer, and 1X PCR Master mix from the QIAGEN multiplex PCR kit (Qiagen, Hilden, Germany). The PCR cycling conditions for the three multiplexes were as follows: pre-incubation for 15 min at 95 °C, followed by five (sets A and B) or seven (set C) touchdown cycles at 95 °C for 30 s, 65–1 °C/cycle for 1 min and 72 °C for 1 min, followed by 30 cycles at 95 °C for 30 s, 60 °C (set A and B) or 58 °C (set C) for 1 min, 72 °C for 1 min and the ending cycle 30 min extension at 72 °C. To evaluate the amplification results, 1 μL of the PCR product was separated by electrophoresis on a 2% agarose gel. The amplification bands were detected using the GelDoc 2000 (Bio-Rad Laboratories, Hercules, CA, USA) transilluminator and visualized with the Quantity One Analysis Software (Bio-Rad Laboratories, Hercules, CA, USA). Then, the diluted products mixed with formamide were analyzed on ABI PRISM DNA sequencer (3130XL; Applied Biosystems, Foster City, CA, USA). The GeneScan 500 LIZ Size standard was used to determine allele size. Fragment analysis and sizing were carried out using the Peak Scanner Software version 1.0 (Applied Biosystems).
2.3. Physical Parameters
For each clone, 20 fruits were taken from the 60 collected and the following physical parameters were measured: fruit weight (FW) (g), equatorial diameter 1 (D1) (mm), equatorial diameter 2 (D2) (mm), average equatorial diameter (AD = (D1 + D2)/2) (mm), fruit height 1 (H1) (mm), fruit height 2 (H2) (mm), average fruit height (Am = (H1/H2)/2) (mm), width of the pedicle cavity (PCw) (mm), depth of the pedicle cavity (PCd) (mm), width of the calycine cavity (CCw) (mm), depth of the calyx cavity (CCd) (mm), aperture of locules (in transverse section) (OL) [
37], number of viable seeds (Sv), number of abortive seeds (Sa), and firmness (F) (kg cm
−2).
Fruit weight was measured with a Sartorius digital bench scale (model BL-600, 0.01 g accuracy). Fruit equatorial diameter, length, and depth of the pedicle cavity and the width and depth of the calycine cavity were measured with a Mitutoyo CD-15DC Digimatic caliper (0.01 mm accuracy). Pulp firmness was assessed with a Bertuzzi penetrometer (model FT 327, with an 8 mm deep probe). Apple peel color (four different measurements at four equidistant points on the equatorial region of each fruit) was assessed using a Minolta C-300 Chroma Meter (Minolta Corp., Osaka, Japan) coupled to a Minolta DP-301 data processor, and the results were expressed in the CIE
Lab system. The mean values for lightness (L *), red-greenness (a *), and blue-yellowness (b *) coordinates for each fruit were reported. In addition, the objective color was calculated as chromaticity or chroma [C * = (a *
2 + b *
2)
1/2] and hue angle [Hº = arctan (b */a *)]. For the moisture content, samples were dried at 60 °C for 48 h until a constant weight was reached [
38].
2.4. Total Soluble Solids, Acidity, and Maturity Index
Total soluble solids (TSS) were assessed in triplicate with a digital refractometer Atago N1 (Atago Co. Ltd., Tokyo, Japan) at 20 °C, and expressed as °Brix. Total titratable acidity (TA) was determined in triplicate using an automatic titration device (877 Titrino plus, Metrohm ion analyses CH9101, Herisau, Switzerland) with 0.1 N NaOH up to pH 8.1, using 1 mL diluted juice in 25 mL distilled H2O, and the results expressed as g malic acid L−1. Once the TSS and TA contents were assessed, the maturity index (MI) of the evaluated varieties was determined (TSS/TA).
2.5. Antioxidant Activities (AA) and Total Polyphenol Content (TPC)
There are different methods for evaluating fruit antioxidant activity. This diversity of methods is because none of them are able to exactly determine the total antioxidant potential in a food system by themselves. For this reason, the antioxidant activity of apple fruits was evaluated using three different assays: (i) the free radical scavenging activity was tested using ABTS
+ and DPPH
• assays and (ii) the ferric reducing ability (FRAP assay). The ABTS
+ (2, 2-azinobis-(3-ethylbenzothiazoline-6-sulfonic acid)) radical cation and ferric-reducing antioxidant power (FRAP) methods were applied according to [
39] and [
40], respectively. The radical scavenging activity was evaluated using the DPPH
• radical (2, 2-diphenyl-1-picrylhydrazyl) method, as described by [
41] with a modification in the reaction time [
42]. Calibration curves, in the 0.5–5.0 mmol Trolox L
−1 range, were prepared for all three methods and showed good linearity (R
2 = 0.998). Results were expressed as mmoles Trolox kg
−1 fresh weight (fw).
The TPC was measured using the Folin–Ciocalteu colorimetric method described by Singleton et al. [
43]. The absorbance of the resulting blue color was measured at 765 nm using a UV–visible spectrophotometer (Termospectromic Helios Gamma UVG 1002 E, Cambridge, UK). Calibration curves with concentrations of gallic acid as the standard were used for quantification. All determinations were performed in triplicate and the results were expressed as gallic acid equivalents (GAE) in, mg 100 g
−1 fw.
2.6. Sugar Profile
Sugar profiles were obtained following the method described by Hernández et al. [
44] using HPLC, with some modifications. The extraction consisted in the homogenization of 1 mL of sample juice with 5 mL of phosphate buffer followed by filtration and injection. A column (Supelcogel TM C-610H column 30 cm × 7.8 mm) and a pre-column (Supelguard 5 cm × 4.6 mm, Supelco, Inc., Bellefonte, PA, USA) were used for the analysis. Sugars were detected using a refractive index detector (RID).
Sugars from Sigma (Poole, Dorset, UK) were used for calibration curves and quantification and showed good linearity (R2 ≥ 0.999). Analyses were run in triplicate and results were expressed as %.
2.7. Sensory Evaluation
Seven trained panelists (aged 40–60 years; four female and three male) with more than 500 h of training in sensory testing from the Department of Agrofood Technology (UMH) participated in this study. The study was conducted in a normalized tasting room of UMH (21 ± 2 °C and 55% ± 5% relative humidity) with 15 normalized sensory cabins. Samples were randomly served into odor-free, disposable 90 mL covered plastic cups, at room temperature, and coded using 3-digit numbers. Unsalted crackers and distilled water were provided to panelists to clean their palates between samples.
Each panelist filled a questionnaire evaluating the following attributes: color (peel color, pulp color, homogeneity of peel color), flavor ((apple, fruity, pineapple, quince, and pear odor (perception of volatile compounds with the fruit outside the mouth), sourness, sweetness, bitterness, astringency and fruity, apple, pineapple, and apple-pear aroma (perception of volatile compounds with the fruit outside the mouth), aftertaste) and texture (hardness, crispness, juiciness, crispy, granularity, fibrousness). The attributes description and the reference materials used are shown in
Table 2.
The panelists used a numerical scale from 0 to 10 with increments of 0.5 points, to rate the attribute’s intensity, where 0 represented “no intensity” or “no perceptible intensity” and 10 “extremely strong”. Spanish trained panels commonly use this scale because it is intuitive and very easy to understand. A different scale was used only for the “peel color” attribute, with a numeric scale from 0 to 20, where 0 represents green, 10 represents yellow, and 20 represents red.
2.8. Statistical Analysis
The results were analyzed using the SPSS v.22.0 statistical program for Windows (SPSS Science, Chicago, IL, USA). The differences among varieties (p < 0.05) were evaluated with an analysis of variance (ANOVA). The method used to discriminate among means (Multiple Range Test) was Tukey’s test (p < 0.05), and all the results were shown as mean values ± SE (standard error). Principal component analysis (PCA) and cluster analysis (CA) were also performed. The cluster analysis was applied to standardized data for hierarchical associations, employing Ward’s method for agglomeration and the squared Euclidean distance as the dissimilarity measure.
3. Results and Discussion
3.1. Molecular Characterization
The five clones of “Pero de Cehegín” shared the same SSR profile at the 13 microsatellite markers studied. The size of the 26 alleles obtained for “Pero de Cehegín” (clone 1), “Fuji”, and “Granny Smith” (references varieties) are shown in
Table 3. The two reference varieties were used for size alignment and comparison with other studies.
To our knowledge, this is the first molecular study for the identification of the “Pero de Cehegín”. The profile of “Pero de Cehegín”, did not show correspondence with profiles of diploid accessions named “Pero” in other Iberian collections conserved at different institutions. No correspondence was found with “Pero Rufino”, “Pero Rosa”, and other “Pero” accessions from local and traditional apples located in Andalucía [
19], “Peruco Lardero” from the germplasm bank at the University of Lleida [
48] and its synonym “Pero Mingan” at Aula Dei-CSIC [
36], “Pero de Coura”, and other “Pero” from three Portuguese germplasm banks [
49]. Additionally, correspondence was neither found with other triploid accessions such as “Pero Pardo”, “Pera de Sangüesa” (syn. Moceta) at Aula Dei-CSIC, all characterized in larger studies including 498 and 1453 accessions [
23] from Spanish apple germplasms. Therefore, this is the first molecular study that identifies “Pero de Cehegín” as a new genotype, not present in other Spanish germplasm banks.
3.2. Physical Parameters
Table 4 shows the results obtained for the physical evaluation of five “Pero de Cehegín” clones studied. Important variability was found for fruit weight, diameter, and height among the different “Pero de Cehegín” clones. The smallest fruits were those produced by the P3 clone with a FW = 148.41 g, which was not significantly different with “Golden Delicious”, while the P2 clone, with a mean weight of 219.43 g, had the largest fruits. The rest of the clones and “Fuji” apples had intermediate values.
As for the AD, we found two groups. Group 1, with the higher values, included two “Pero de Cehegín” clones (P1, P2) and “Fuji” and group 2, with lower values, included the rest of clones and “Golden Delicious”. For the average height (AH) of the fruit, the P2 clone had the highest value (81.77 mm), and P3 (68.33 mm), “Fuji” (68.25 mm), and “Golden Delicious” (64.23 mm) with the lowest values. These results highlight the morphometric differences shown by “Pero de Cehegín” as compared to common commercial varieties such as “Fuji” and “Golden Delicious”.
Fruit size plays an important role in consumer preferences when buying fruit because different fruit sizes can satisfy different types of consumers [
33]. The literature has reported varieties with an average fruit weight above 300 g [
50] but also values below 100 g [
31]. The present results show that the “Pero de Cehegín” clones have an adequate size for commercialization, with values even higher than “Fuji” and “Golden Delicious” varieties, which are widely accepted by consumers. In general, large fruits are preferred by most consumers, but for fresh consumption, only up to a certain size limit [
51,
52]. Hampson et al. [
53] indicated that for the dessert apples, the ideal size was between 74 and 76 mm in diameter. In the “Pero de Cehegín” clones studied the average diameter of the fruit ranged between 66 (P3) and 75 mm (P2), which agrees with the range of acceptance.
On the other hand, the PCw of the “Pero de Cehegín” P3 clone (27.86 mm) has a lower value than the rest of the clones (between 30.53 and 31.11 mm), similar to “Fuji” (28.69 mm) and “Golden Delicious” (27.15 mm). The PCd values oscillated between 14.68 and 17.16 mm, with significant differences only between the P1 and P5 clones but without differences observed with commercial varieties. The CCw varied between 25.30 and 29.89 mm. Only clones P3, P4, and P5 were non-significant with “Fuji” and “Golden Delicious”. The calicine depth (CCd) varied between 12.48 and 15.91 mm, and it was only significantly different between P2 and P3 clones.
For the locule opening characteristic (in a cross-section) (OL) [
37], all the studied samples had a level 2 without significant differences among them.
The number of viable seeds (Sv) for “Pero de Cehegín” clones were similar (average values between 1.05 units for P3 and 2.65 units for P5). The maximum Sv value was found for the “Golden Delicious” variety (3.75). More variability was found for abortive seeds (Sa), with mean values ranging from 0.8 units (P3) to 4.15 units (P4).
Fruit firmness in “Pero de Cehegín” clones had higher values than those of the commercial varieties, ranging from 3.65 (P1) to 4.44 kg cm
−2 (P3). Firmness is one of the most important parameters perceived by consumers [
54], as a high fruit firmness is often related to freshness, while fruit flouriness can be a deterrent to the increase in fresh fruit consumption [
55]. Therefore, the firmness found in “Pero de Cehegín” is a positive characteristic that may help with its consumption. Firmness, juiciness, and no flouriness are the textural features preferred by consumers [
56].
For moisture content, all the clones showed similar values ranging from 77.92% (P5) to 79.72% (P1). The “Fuji” variety had a value of 78.85% and the highest value was observed for the “Golden Delicious” variety (82.53%). In the literature, different varieties have been reported with values between 78.12% and 95.00% [
27,
29,
57,
58]. The low moisture content for “Pero de Cehegín” could be directly related to their good natural properties for conservation.
Similarly, the color directly affects the appearance and the acceptability of the fruit by the consumer [
29]. The green, yellow, and red apple peel colors can help to distinguish the cultivar [
33]. Therefore, color can be considered one of the most important fruit characteristics, aside from being one of the indicators of maturity.
The color parameters for the different studied clones are shown in
Table 5. For all color traits, “Fuji” was significantly different to “Pero de Cehegín” clones and the “Golden Delicious” variety. For all the parameters, except L * and a *, all the “Pero de Cehegín” clones were not significantly different. For luminosity (L *), the results indicated that the peel of “Pero de Cehegín” fruits had light colors. Four clones (P1, P2, P3, and P4) were not significantly different amongst themselves. The “Fuji” variety (bicolor apple) showed the lowest luminosity and the “Golden Delicious” variety was the most luminous fruit, although no significant differences between P2, P3, and P5 “Pero de Cehegín” clones were observed. The results of the a * index, which represents the red-green color scale, showed small differences among the “Pero de Cehegín” clones and Golden Delicious. As expected, only Fuji showed a high value of the colorimetric variable a * (24.52, reddish color).
3.3. Total Soluble Solids, Acidity, and Maturity Index
“Pero de Cehegín” did not show significant differences among clones for any of the traits evaluated (
Table 6). However, among commercial varieties (“Fuji” and “Golden Delicious”) differences were also found in TSS and TA. These differences could be due to the genetic variation among the plant material studied since based on the literature, the composition of apple fruits will be affected by the genotype [
25,
59].
The total soluble solids (TSS) parameter varied from 15.40 °Brix for the P5 clone up to 17.20 °Brix for the P3 clone, without significant differences with the rest of the clones and “Fuji” (16.63 °Brix). Clones P1 and P5 were not different from “Golden Delicious” (13.9 °Brix). Previous studies on different varieties have reported values between 9.99 and 18.1 °Brix [
25,
27,
28,
29,
60].
The total acidity (TA) mean values for the different “Pero de Cehegín” clones ranged from 1.44 (P3) to 1.83 g L
−1 (P4) without significant differences between them, but these values were significantly lower than in the “Fuji” and “Golden Delicious” varieties (3.97 and 3.30 g L
−1, respectively). The total acidity value (TA) of the clone P3 of “Pero de Cehegín” was lower than reported in other studies of apple varieties [
25,
28,
29,
60,
61,
62]. For apples, the total acidity is a very important parameter for the quality of fruit and consumption, particularly in Europe [
63]. Some research studies [
52,
64] have indicated that total acidity values below 3 mg mL
−1 and above 10 mg mL
−1 can be undesirable. This statement could be in contradiction with the results of this work, as the acidity value for the “Pero de Cehegín” clones resulted below 3 mg mL
−1 and this traditional Spanish apple fruit has been historically considered as appealing and of high quality.
The maturity index (MI) for the “Pero de Cehegín” clones ranged from 86.98 (P4) to 122.30 (P3), significantly higher as compared with “Golden Delicious” (MI: 42.47) and “Fuji” (MI: 42.21) varieties. Generally, the maturity index is considered as responsible for the fruit’s taste, thus, based on these results, it could be affirmed that the “Pero de Cehegín” clones are sweet tasting.
3.4. Antioxidant Activities (AA) and Total Polyphenol Content (TPC)
To evaluate the potential antioxidant activity of apple fruit, three in vitro assays, based on the scavenging activity (DPPH
•), radical scavenging capacity (ABTS
+), and ferric reducing antioxidant potential (FRAP) were used and the results are reported in
Table 6. The results did not indicate significant differences between “Pero de Cehegín” clones and commercial varieties (“Golden Delicious” and “Fuji”) for ABTS
+ and DPPH
• (
Table 6). Differences were only obtained by using the FRAP method, with higher values for the “Pero de Cehegín” clones than for “Fuji” and “Golden Delicious” observed. A previous study [
65] indicated the importance of the genotype in the antioxidant activity, and this could be reason for the differences observed.
In the present study, the highest TCP concentration was obtained by the “Golden Delicious” variety (282.07 mg GAE 100 g
−1 fw). This value was significantly different when compared with the “Fuji” variety, which had the lowest TCP value (102.72 mg GAE 100 g
−1 fw). However, the “Pero de Cehegín” clones did not show significant differences between them and the values for “Fuji” and “Golden Delicious”, ranging from 117.04 (P4) to 199.44 mg GAE 100 g
−1 fw (P1). Different studies for apple varieties have shown total polyphenol values between 66.2 and 290 mg GAE 100 g
−1 fw [
66,
67,
68,
69].
3.5. Sugar Profile
Significant differences among the “Pero de Cehegín” clones and “Fuji” and “Golden Delicious” varieties were found for sucrose and fructose. Sucrose content in the “Pero de Cehegín” was higher than in commercial varieties, while fructose was the opposite. For glucose, no differences were observed. In apples, D-fructose has been reported as the principal sugar, independently of the variety [
25,
27,
70,
71]. Conversely, “Pero de Cehegín” had similar, and even higher, values of sucrose than fructose as the main sugars, well above glucose. This sucrose:fructose ratio can be defined as a distinctive characteristic for this variety.
3.6. Sensory Evaluation
The mean values obtained in the sensory evaluation of the different organoleptic attributes of “Pero de Cehegín” clones are presented in
Figure 2. For “Pero de Cehegín” appearance attributes, the panelists provided scores ranging from 5.00 (P1) to 8.00 (P3) for peel color, but notably lower than the Fuji variety (14.20). The homogeneity for peel color in “Pero de Cehegín” ranged between 6.2 (P3 and P4) and 8.4 (P2). For odor related attributes, P3 clone obtained the highest value for apple and fruity odor (the most characteristic odor of this fruit), while P1 and P2 clones showed the highest pineapple odor values. The highest values of quince and pear notes were provided for the “Golden Delicious” variety. Additionally, related to the other attributes, the “Pero de Cehegín” clones showed low sourness, high astringency, corking and fibrosity, and medium crispy when compared with Golden “Delicious” and “Fuji” varieties. The sourness perception in the sensory analysis was in agreement with the total titratable acidity (TA) (
Table 6), that is, smaller values for “Pero de Cehegín” clones (P1–P5) than “Golden Delicious” and “Fuji” varieties (used as controls). The high value of two attributes (corkiness and fibreness) of the “Pero de Cehegín” clones must be highlighted. The high intensity of these attributes could be a disadvantage for fresh fruit consumption, such as apple or quince [
72]. On the other hand, these values can be related to the highest values of firmness (F) (
Table 4) for “Pero de Cehegín” clones. However, in the sensory analysis, a higher level of hardness for “Pero de Cehegín” clones and “Golden Delicious” and “Fuji” samples was not observed. In this sense, the firmness test can be considered as an indirect measurement to predict the consumer’s perception on the texture of the fruit, and contradictory results have been published [
73], indicating the importance of comparing the analytical methods with the sensory ones.
3.7. Principal Component Analysis
Aiming to easily explain the trends and relationships among the measured variables (32) for all clones and varieties (7), a principal component analysis (PCA) was performed. The first five components explained 96.23% of the variation, while the first three components explained 82.89% of the total observed variability (
Table 7). The first component, PC1 (40.64% of the total variance), was related to TA, MI, F, H1, H2, AH, sucrose, and fructose. (
Table 7,
Figure 3). PC2 (27.55% of the total variance) was related with the color coordinates L *, a *, b * C *, and Hº (color), and FW, D1, D2, AD (weight and fruit size), CCw. PC3 (14.70% of the total variance) was related to polyphenols, moisture, and CCd. The rest of the PCs were related to the traits highlighted in
Table 7.
The PC1-PC2 biplot (
Table 7,
Figure 3), separated “Fuji” and “Golden Delicious” varieties, located on the negative
X-axis (PC1), from the “Pero de Cehegín” clones, located on the positive
X-axis. In the same way, and for the “Pero de Cehegín” clones, the results separated the P1 and P2 clones, placed on the negative
Y-axis (PC2) and very close to each other, from the rest of the clones, placed on the positive
Y-axis.
The results obtained from the hierarchical cluster analysis, using the linkage method between groups, were shown as a dendrogram (
Figure 4), with two branches separating “Pero de Cehegín” clones from commercial varieties. Then, “Pero de Cehegín” clones were grouped into two groups. The first group consisted of clones P1 and P2, while the second group include clones P3, P4, and P5. The dendrogram obtained by the cluster analysis matches with results of the principal component analysis (PCA).
4. Conclusions
This study allowed identifying the “Pero de Cehegín” as a unique and new genotype, not reported in the Spanish germplasm banks and revealed the interest in continuing with apple prospection work in Spanish areas of the Southeast which has not been sufficiently explored.
The study of the physicochemical characteristics, bioactive compounds, and sensory profile of five clones of “Pero de Cehegín” has allowed observing the existence of variability between clones. An important variability was found for fruit weight, diameter, and height between the different “Pero de Cehegín” clones. In comparison with “Fuji” and “Golden Delicious”, “Pero de Cehegín” showed high firmness, high total soluble solids, very low total acidity, high FRAP antioxidant capacity, and more sucrose content. These distinctive characteristics and its good appearance and special odor make this variety a marketable product that with an adequate evaluation and diffusion can increase the market offering and complement the demand for new products, thereby opening the possibility of spreading its cultivation in areas where it can be adapted. This is a preliminary study, so to confirm the phenotypic characterization, this study will continue for two more years.