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Article

Stability Dynamics of Main Qualitative Traits in Maize Cultivations across Diverse Environments regarding Soil Characteristics and Climate

by
Vasileios Greveniotis
1,2,3,*,
Elisavet Bouloumpasi
4,
Stylianos Zotis
3,†,
Athanasios Korkovelos
5,
Dimitrios Kantas
6 and
Constantinos G. Ipsilandis
7
1
Hellenic Agricultural Organization Demeter, Institute of Industrial and Forage Crops, 41335 Larissa, Greece
2
Department of Agricultural Development, Democritus University of Thrace, 68200 Orestiada, Greece
3
Department of Agricultural Technology, Technological Educational Institute of Western Macedonia, 53100 Florina, Greece
4
Department of Agricultural Biotechnology and Oenology, International Hellenic University, 66100 Drama, Greece
5
Directorate of Water Management of Thessaly, Decentralized Administration of Thessaly—Central Greece, 41335 Larissa, Greece
6
Department of Animal Science, University of Thessaly, Gaiopolis, 41500 Larissa, Greece
7
Regional Administration of Ionian Islands, 49100 Corfu, Greece
*
Author to whom correspondence should be addressed.
Deceased.
Agriculture 2023, 13(5), 1033; https://doi.org/10.3390/agriculture13051033
Submission received: 4 April 2023 / Revised: 22 April 2023 / Accepted: 7 May 2023 / Published: 10 May 2023
(This article belongs to the Special Issue Stability Analysis of Crop Yield under Different Cultivation Systems)
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Abstract

:
One of the main obstacles to finding cultivars with consistent performance across locations and years is the genotype × environment (GE) interaction effect. A new approach to stability analysis for qualitative characteristics in maize was conducted utilizing G × E interactions and further analysis via AMMI and GGE biplots. The study aimed to identify the type of trait inheritance through estimations of the stability index, to evaluate multiple locations and multiple genotypes to determine how different ecosystems and maize genotypes relate to one another, and, finally, to suggest the ideal climatic conditions and genotypes, carefully chosen for their stability. Fifteen F1 commercial maize hybrids comprised the genetic materials tested, along with 15 open-pollination lines created by 4-cycle Honeycomb assessment, at four different environments, Giannitsa, Florina, Trikala, and Kalambaka in Greece. The experiments were conducted in Randomized Complete Block Designs (RCB) with four replications. The tested characteristics were protein content (%), fat (%), ash (%), starch (%), crude fiber (%), moisture (%), seed length, seed thickness, and seed width. All genotypes showed statistically significant differences for all characteristics measured, especially for protein content and size of the kernel. G × E interaction was present only for moisture content and size of the kernel. Environments significantly affected fat, starch content, moisture content, and the kernel’s size (under a multiple G × E interaction). Protein, ash, and fiber content showed no G × E interaction. Further analysis via AMMI and GGE biplots was applied to explore the genotypic stability across all experimental environments for the traits that showed noteworthy G × E interaction. According to our results and approach, protein content is less qualitative than other characteristics like moisture and starch content. Correlations showed that negative selection for the last two characteristics, as well as for ash content, in combination with longer seeds, may lead indirectly to improved stability performance for protein content. Three environments, Giannitsa, Trikala and Kalambaka, exhibited higher stability index values for almost all characteristics measured. Therefore, those environments are perfect for ensuring the stability of the quality characteristics and could be recommended. The best maize hybrids were Mitic, 6818 and 6040, exhibiting high stability indices of quality characteristics and Kermes displaying stability for protein content. Therefore, those should be further tested in multiple environments to confirm the consistency of their high-stability performance.

1. Introduction

One of the most significant crops for many farmers in Greece is maize, soya, and peas, contributing to supporting livestock. According to the Food and Agriculture Organization (FAO) data, maize covered an area of 120,070 ha in 2021 in Greece, with a production of 1.322 million tones [1]. Qualitative traits are beneficial for defining the nutritional value of maize as an animal feed. Carbohydrates, proteins, fats, fiber, minerals, vitamins, and water are essential nutrients for animals to feed, grow, and breed [2]. Maize kernels usually contain a high quantity of starch, 6–12% protein and oil ranging from 3% to sometimes over 6% [3,4]. Studies of genotypes for high protein content are few compared to oil content [5]. Almost 49% of cultivated maize is used as raw material in the animal feed industry [6,7]. Protein and oil content are negatively related to each other and to starch content [8].
A genotype that performs well in one environment during one season or year may not perform well at a different time or another site within the same region because significant genotype-by-environment interactions (G × E) frequently occur under stress situations [9]. This is due to crossover performances from genotypes’ varying degrees of phenotypic expression under various environmental circumstances [10]. Differences in the sensitivity of the genotypes to the conditions in the target environment are another cause of genotype-environment interaction [10]. Therefore, developing better genotypes in various contexts depends heavily on genetic environment interactions (G × E).
Breeders need reliable data to know which genotypes to suggest, select, or reject. The multi-environmental trial (MET) study has extensively used the AMMI model and GGE biplots because they offer more precise estimates and make it simple to interpret the GEI through attractive graphical tools [11].
Different environments affect performance significantly. Thus, maize breeders have to improve new genotypes in terms of performance stability for vegetative and yielding characteristics [12,13]. The strength of maize performance is crucial for proper hybrid selection in various cultivation systems and environments to ensure better performance of genotypes [14]. Stability is referred to as the ability of a genotype to perform satisfactorily under different environments and cope with various biotic and abiotic stresses [15]. Fasoula’s [15] and Fasoula [16] used the Coefficient of Variation as a stability criterion in many cases to describe genotype adaptation under different environments. Maize stability under varying densities was proposed by Ipsilandis and Vafias [17]. Also, Vafias et al. [14] depicted that the most severe stress for maize genotypes was low-input farming that suppressed genotype expression. Greveniotis et al. [18,19] published an implemented method for stability estimations, in maize and other crops, based on Fasoula’s [20,21] approach for selecting stable genotypes that exhibit high performance in various environments. Also, Greveniotis et al. [22,23,24,25] went further in exploring different traits of peas (Pisum sativum L.) and common vetch (Vicia sativa L.), utilizing AMMI and GGE biplot analyses as tools. Fasoula [16,21] used selection criteria for stability according to the squared form of the reversed coefficient of variation, i.e., the ratio ( x ¯ / s ) 2 . Kang [26] reported that breeders must aim at improving high-yielding performance and stability of performance simultaneously. Other authors [27] have assessed different maize genotypes in Greek environments based on grain quality traits and applied AMMI analysis along with Principal Component Analysis. However, to our knowledge, it is the first time that the stability of maize genotypes regarding seed quality and chemical composition parameters was assessed in several diverse environments in Greece, applying new assessment methodology, i.e., Fasoula’s stability index and utilizing the AMMI and GGE biplot analyses as further tools.
The purposes of this study were: (a) to use Fasoula’s stability criterion for the simultaneous selection of best and stable genotypes based on seed quality and chemical composition parameters, (b) through estimations of the stability index to determine the type of trait inheritance, (c) to evaluate multiple locations and multiple genotypes to identify how different environments and maize genotypes are related, and, finally, (d) to suggest the ideal conditions and genotypes, carefully chosen for their stability.

2. Materials and Methods

2.1. Crop Establishment and Experimental Procedures

Four locales in the northern and central parts of the country (Figure 1) were chosen for the installation of two-year experimentation. The selection of locales was based on the availability of farming land and the diversity of geographical position, elevation, soil texture and climate, as displayed in Table 1 and Figure 2, respectively.
The genetic materials were consisted of 15 F1 commercial maize hybrids, i.e., G1 was PR31Y43, G2 was FACTOR, G3 was COSTANZA, G4 was ARMA, G5 was PR31A34, G6 was ELEONORA, G7 was FAMOSO, G8 was DKC6818, G9 was MITIC, G10 was DKC6040, G11 was KERMESS, G12 was PR31G98, G13 was LG3535, G14 was PR33A46 and G15 was PR31P41 and 15 open-pollination lines that were created between 2007 and 2010 after a 4-cycle Honeycomb assessment with a selection intensity close to 1%., i.e., G16 was 1T, 2T was G17, G18 was 3T, G19 was 4T, 5T was G20, G21 was 1F, G22 was 2F, G23 was 3F, G24 was 4F, G25 was 5F, G26 was 6F, G27 was 7F, G28 was 8F, G29 was 9F and G30 was 10F. The F2 (C0) generation of the F1 commercial maize hybrid Costanza has been utilized for open-pollinated lines. The pedigree selection method was used throughout the experimentation on the half-sib offspring regardless of open pollination.
The final trials included four replications and were conducted using the Randomized Complete Block Design (RCB). [28]. The plots had a row-to-row spacing of 75 cm and comprised two single rows. Plant-to-plant spacing was 18 cm, with 25 plants in each row. To reach the necessary plant densities, hills were over-seeded at a double rate and then manually thinned when the maize crop reached the two-leaf stage.
To guarantee a good plant stand, all relevant agronomic and cultural procedures were timely followed. After seeds were sown, the same amounts of nitrogen and phosphorus fertilizer (element level) were administered in all four locations and experimental plots: 150 and 75 kg/ha. Additional nitrogen fertilizer (135 kg/ha) was then applied when the plants reached a height of 50 cm (boot stage). Herbicides applied post-emergence ensured weed control. To prevent water stress at any growth stage, irrigation was carried out regularly (often every ten days). Each plot was picked by hand to ensure excellent accuracy.

2.2. Measurements

After harvest, the seeds from each genotype per plot at a given location were bulked. 100 g maize seed samples were collected and analyzed for quality and chemical composition parameters. All characteristics were measured in the Laboratory of Animal Technology at the University of Thessaly.
For chemical analysis, approximately 50 g of dry maize seeds (13% moisture) were cleaned, and ground using a laboratory mill and were stored at 4 °C until analysis.
Approved methods of the American Association of Cereals Chemists (AACC) were applied for the determination of fat (%) (Soxhlet extraction with petroleum ether based on AACC Method 30-25.01), ash (%) (AACC Method 08-01), crude protein (CP) (%) (determination of total nitrogen by Kjeldahl method according to modified AACC Method 46-12 and expression of protein content as % CP = total N × 6.25), moisture (%) (AACC Method 44-15A) [29]. More specifically, 3 g of ground homogenized seed sample previously dried for fat determination was extracted by Soxhlet extraction using petroleum ether as the solvent for 4 h. The solvent evaporates by a rotary evaporator, and the residue is dried at 100 degrees to a consistent weight. The residue is expressed as % crude fat or ether extract [29]. For ash determination, 3 g of ground homogenized seed samples were weighed in a porcelain crucible previously ignited, cooled in a desiccator, and weighed after reaching room temperature. Next, the sample is ignited in a furnace at 550 °C until constant weight, cooled in a desiccator and weighed when it reaches room temperature [29].
Official Methods by the Association of Official Analytical Chemists (AOAC) were applied for the determination of crude fiber (%) (AOAC 991.43) and total starch (%) (AOAC method 996.11 [30]. In addition, mean values of seed length, seed thickness, and seed width (in mm) were obtained by measuring the three dimensions of 20 randomly selected seeds with a Vernier Calliper.

2.3. Data Analysis

To determine if there are significant differences for all variables examined in this study, data were largely evaluated by ANOVA over locations and years. The experiments were conducted in Randomized Complete Block Designs (RCB) with four replications. The environment was designated as the product of each year and location to make the ANOVA table more illuminating. By doing this, we reduce the number of interactions in the ANOVA table and maintain the G × E (Genotype × Environment) interaction, which is essential for advancing the stability study.
For stability estimations, the presented ratio ( x ¯ / s ) 2 , where x ¯ and s represent the entry mean yield and standard deviation, respectively, is used, namely the stability index [16,21]. Pearson coefficient based on Steel et al. [28] was employed to search for trait correlations, and SPSS ver. 25 software for statistics was used to explore all data for statistical significance at p < 0.05. The PB Tools v.1.4—free version (International Rice Research Institute, Laguna, Philippines) was utilized for computing the AMMI and GGE biplot analysis for interactions.

3. Results

In Table 2, ANOVA main results are presented. All genotypes showed statistically significant differences for all characteristics measured, especially for protein content and size of the kernel. G × E interaction was present only for moisture content and size of the kernel. Environments significantly affected fat, starch content, moisture content, and the kernel’s size (which was under a multiple G × E interaction). Protein content, ash and fibers showed no G × E interaction.
Table 3, Table 4, Table 5 and Table 6 present the trait stability index ( x ¯ / s ) 2 values for protein content (%), fat content (%), ash content (%), starch content (%), crude fiber content (%), moisture content (%), seed length, seed thickness, seed width, in all four different environments. Moisture content and starch content showed the greatest stability index values. Especially moisture content showed extreme values close to or over 100,000 (i.e., 126,070 in Florina, 93,347 in Giannitsa). In contrast, crude fiber content and seed width showed values below 1000. Finally, protein content and general seed size showed low values, just above or near 1000.
Table 7 and Table 8 show indices across environments and genotypes, respectively. Giannitsa, Trikala and Kalambaka exhibited higher indices for almost all characteristics measured. From Table 8, some genotypes showed high indexes, especially for moisture and starch content (such as Mitic, 6818 and 6040). Also, some genotypes showed high stability indices for many other characteristics in specific environments (i.e., Costanza in Giannitsa). Again, crude fiber content and seed size showed low values for every genotype and environment. Hybrid Mitic showed higher values for almost all characteristics. The hybrid Factor showed low values for many characteristics, while lines of the F-series also demonstrated satisfactory results, indicating a stability potential.
In Table 9, numerous statistically significant correlations were found, particularly between characteristics of the kernel (seed) size (up to 0.633). Ash content was strongly and positively correlated to seed size (0.452 to 0.592). The same was found for fat content. Moisture content (%) was negatively correlated to essential characteristics such as protein, fat, fiber, and ash content. Only starch content was positively correlated to moisture content. Protein content generally was negatively correlated to all other characteristics, except for seed length, where the correlation was positive. Generally, larger seeds favor fat, ash, and fiber content but not starch, protein, and moisture.

The AMMI Tool for Multi-Environment Evaluations

The AMMI analysis is a statistical tool that is helpful for multi-environment experimental analysis in a manner that is easily understandable and can depict the complexity of GEI. For this reason, the data of GEI means are arranged in a two-dimension table. The (LS) least squares, estimated by the analysis, are used for generating a two-dimensional ANOVA model for the additive based on main effects and estimating a value decomposition on the residuals of interaction [31].
The statistical AMMI software tool depicts the adaptation figure and the AMMI1 biplot where the two axes are. The x-axis depicts the values of the factor analyzed (axis of the factor), and the y-axis is the one where the PC1 values are depicted. When the values of PC1 on the biplot are placed close to the axis of the factor (x-axis), it means that the factor analyzed expresses stability for all experimental environments. Therefore, the desirable genotypes on the AMMI1 biplot are those representing high values on the x-axis (the axis of factor performance) (x-axis, right position) combined with a low estimation of the PC1 y-axis (near zero).
The GGE biplot analysis combines the main effect of genotype (G) and the interaction of genotype by environment (GE). This combination is the core of stability analysis. A GGE biplot displays the genotype by the environment in the two-dimension data matrix. The methodology of the GGE biplot derives from the analysis by graphical tools of multi-environment trials of genotypes (MET).
In the GGE biplot for the characterization of the environments, the stable one was the one depicted near the ideal and average environment dots. Regarding the genotypes and their stability, the desirable genotypes were those depicted in the area of the ideal genotype.
The analysis using the AMMI1 and G×E biplot creates biplots based on the genotypic performance among environments. The created biplots are a simple tool that can easily categorize each genotype for stability and performance.
Figure 3a–d presents the analysis for the stability of moisture content (%) utilizing both AMMI and GGE biplot.
The analysis for stability using AMMI and GGE biplot for seed length is shown in Figure 4a–d.
Figure 5a–d shows the analysis for the stability of seed thickness using AMMI and GGE biplot.
The analysis for stability using AMMI and GGE biplot for the trait of seed width is presented in Figure 6a–d.
Based on the data of the adaptation map of AMMI analysis, the genotypes with the highest values on the performance axis of the trait, showing a more or less parallel diagram line to the axis of PC1, were desirable, as this was an indication of stability among environments.
Based on the biplot of AMMI1, the stable genotypes expressed high values on the trait performance axis (right position on the x-axis) and near the lowest values on the PC1 axis.
Regarding the environments and the biplot of the GGE, the stable environment was placed near the ideal and average environment and the dot of the ideal environment.
For the biplot of GGE regarding the genotypes, the data showed that the productive and stable (desirable ones) were those placed in the area of the ideal genotype.

4. Discussion

Farmers, especially when they possess livestock, want high and stable yields for their cultivations, with excellent and stable quality that may ensure the high capabilities of their animals [32].
Our research showed that moisture and starch content had the greatest stability index values. These two characteristics may easily ensure stability because they exhibit qualitative gene behavior and inheritance [18,19]. However, although this may be a fact, moisture content and seed size showed strong G × E interaction, revealing their vulnerability against environmental conditions. Also, fat and starch content presented different behavior in different environments. Conversely, protein, ash and fiber content showed no G × E interaction.
In maize, the variation in protein content was found to be lower than the variation in oil content. The opposite was reported by Aliu et al. [33], who reported that the protein and oil contents ranged between 11.02 to 13.02% and 2.56 to 5.57%, respectively. Has et al. [34] observed variation from 11.2 to 15.6%, and Prasanna et al. [35] presented similar results (from 8.9 to 10.2%). The starch content of maize kernels depends on genotype [33]. Similar results for starch content were reported by Has et al. [34]. Also, ash content (AC) ranged from 1.28 to 1.45% [33]. The feed industry must have high protein content in animal feed, especially for poultry and swine [36,37,38]. Therefore, a balanced maize feed must contain high protein and have the proper proportions of oil, starch, fat, water, etc., to be accepted as a complete feed. In our study, we tried to depict the most stable characteristics of maize kernel and the best environments and genotypes to achieve the best result.
In Giannitsa, Trikala, and Kalambaka, nearly all of the seed characteristics that were evaluated had higher indices. That suggests that particular environments are excellent for ensuring the stability of high-quality features. Mitic, 6818, and 6040 were the best maize hybrids, all with high stability indices. Additionally, several genotypes displayed particular adaptation in certain conditions as seen by high stability indices for various characteristics (e.g., hybrid Costanza in Giannitsa). Hybrid Kermess showed high stability for protein content.
Essential properties like protein and fat content and fiber and ash level were inversely linked with moisture content. Only starch content positively correlated with moisture content, maybe due to soluble sugars’ behavior. Except for seed length, protein content often had a negative association with all other variables.
Generally, larger seeds favor fat, ash, and fiber content but not starch, protein, and moisture. Scrob et al. [39] reported positive correlations found between ash content and protein content, test weight, and protein content and 1000-kernel weight among tested corn hybrids. In contrast, a negative correlation was found between starch and protein and starch and ash content. Saleem et al. [40] reported that oil and protein content are negatively correlated. They also reported that an increase in sugar contents might decrease the starch level of grain, which consequently reduces the grain yield. A negative and significant correlation was found between ash contents and grain yield at the genotypic and phenotypic levels.
AMMI and GGE biplot contributed to defining the best combination of the genotypes used and the environments/type of cultivation for the main seed characteristics studied in our research.

4.1. Moisture Content (%)

Figures of the AMMI1 biplot (Figure 3b) and adaptation map (Figure 3a) were created based on the trait of moisture content (%) using AMMI analysis. The AMMI figures explained a percentage of the total variability (45.1%), which is enough for conclusions to be drawn. Both AMMI1 and adaptation map figures show that genotypes G4 (ARMA) and G23 (3F) were the most stable, followed by G24 (4F), G29 (9F) and G18 (3T). The moisture % performance of each of the aforementioned genotypes was quite constant, which is desirable for the quality of the seeds. The trait’s range was 12.35 to 12.60%, which demonstrates the most desirable trait’s environmental stability. The analysis of GGE explained a portion of the whole variability of 74.3% (PC1:42.1%, PC2: 32.2%), which is estimated, very high. The Environment view of the GGE biplot (Figure 3c) revealed that no environment was similar. In contrast, E6 (Florina) and E7 (Trikala) environments were depicted in the area of the average environment. The genotype view of the GGE biplot (Figure 3d) shows that genotypes G28 (8F), G27 (7F), G23 (3F), G8 (DKC6818), G6 (ELEONORA) depicted identical with the ideal genotype and characterized by high stability, although exhibiting lower performance for this trait.

4.2. Seed Length

Regarding the trait of seed length, the AMMI1 biplot and Adaptation map analysis (Figure 4a,b) expressed a PC1:32.9% of the whole variability. In the two figures, it was apparent that the genotypes G1 (PR31Y43), G2 (FACTOR), G7 (FAMOSO) and G3 (COSTANZA) were more or less stable. The analysis of the GGE biplot explained a portion of 97.8% (PC1:96.6%, PC2: 1.2%) of the total variability. The Environment view GGE biplot (Figure 4c) revealed that all the seed length trait experimental environments were very close and highly stable. Every environment fits into the in-centric area of an average and ideal environment. The Genotypes view of the GGE biplot (Figure 4d) shows that G3 (COSTANZA), G2 (FACTOR), G1 (PR31Y43) and G7 (FAMOSO) were rather stable genotypes and were all positioned within the ideal genotype’s concentric circles.

4.3. Seed Thickness

The analysis of AMMI for the seed thickness trait explained for PC1 a portion (38.7%) of the whole variability. Both the AMMI1 biplot (Figure 5b) and Adaptation map (Figure 5a) and shown that the relatively stable genotypes were the G1 (PR31Y43), G2 (FACTOR), G3 (COSTANZA) and G5 (PR31A34). The analysis of the GGE biplot explained 91.6% (PC1:85.8%, PC2: 5.8%) of the whole variability. The environmental view of the GGE biplot revealed that all environments for the seed thickness trait were extremely close and very stable. All environments were positioned into the concentric area of average and ideal environments.
The biplot of GGE for genotype view shows that genotypes G1 (PR31Y43), G2 (FACTOR), G3 (COSTANZA) and G13 (LG3535) were the most desirable, as they were all placed within the concentric area of ideal genotype.

4.4. Seed Width

The analysis of AMMI, as presented from the AMMI1 biplot and Adaptation map figures, explained a PC1: 29.2% of the whole variability. AMMI1 biplot (Figure 6b) and Adaptation map (Figure 6a) showed that the genotypes G2 (FACTOR), G3 (COSTANZA), G5 (PR31A34) and G4 (ARMA) were the most stable. The analysis of the GGE biplot explained a portion of 86.5% (PC1:80.7%, PC2: 5.8%) of the whole variability. The biplot of GGE for environment view revealed that every environment was positioned near the average and the ideal environment. Therefore, all environments were quite similar and stable. The genotype view of the GGE biplot shows that the desirable genotype was the G4 (ARMA), followed by G2 (FACTOR), G3 (COSTANZA), G5 (PR31A34) and G1 (PR31Y43). All the aforementioned genotypes were positioned within the concentric area surrounding the optimum genotype.

5. Conclusions

According to our results and approach, protein content is considered a less qualitative characteristic than other characteristics like moisture and starch content. Therefore, negative selection for the last two characteristics and for ash content, combined with longer seeds, may indirectly lead to improved stability performance for protein content.
Hybrid Mitic showed higher values for almost all characteristics, indicating great adaptability and stability. Lines of the F-series also demonstrated satisfactory results, indicating a stability potential. Hybrid Kermes showed high stability for protein content.
The optimal genotypes to employ and environments/types of cultivation were determined by AMMI and GGE biplot. The genotypes G28 (8F), G27 (7F), G23 (3F), G8 (DKC6818), and G6 (ELEONORA) were relatively stable for moisture content, however, with lower performance for this characteristic. On the other hand, Genotypes G3 (COSTANZA) and G1 (PR31Y43) have the best seed size attributes for stability in the locations evaluated.

Author Contributions

Conceptualization, V.G. and S.Z.; methodology, V.G. and S.Z.; investigation, V.G., C.G.I., D.K. and E.B.; statistical analysis, A.K. and V.G., writing—original draft preparation, V.G. and C.G.I.; writing—review and editing, E.B., A.K., D.K. and C.G.I.; visualization, A.K. and V.G.; supervision, V.G., project administration, V.G. All authors have read and agreed to the published version of the manuscript.

Funding

This research has been partially co-financed by the European Union (European Social Fund-ESF) and Greek national funds through the Operational Program “Education and Lifelong Learning” of the National Strategic Reference Framework (NSRF)-Research Funding Program: Heraclitus II. Investing in knowledge society through the European Social Fund.

Institutional Review Board Statement

Not applicable.

Data Availability Statement

The corresponding author can be reached for a reasonable request for the datasets used and/or analyzed in the current study.

Conflicts of Interest

The authors declare no conflict of interest.

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Agriculture 13 01033 g001 550
Figure 1. Map showing the location of four environments.
Figure 1. Map showing the location of four environments.
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Agriculture 13 01033 g002 550
Figure 2. Monthly mean temperature (in °C) and precipitation (in mm) for growing seasons 2011 and 2012, at the areas of experimentation.
Figure 2. Monthly mean temperature (in °C) and precipitation (in mm) for growing seasons 2011 and 2012, at the areas of experimentation.
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Agriculture 13 01033 g003 550
Figure 3. Analysis for stability for the trait of moisture content (%) based on (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability. The desirable genotypes are those placed near the concentric region of the ideal genotype. The E signs represent the environments combined with the years used as follows E1 was Giannitsa, E2 was Florina, E3 was Trikala, and E4 was Kalambaka for 2011; E5 was Giannitsa, E6 was Florina, E7 was Trikala and E8 was Kalambaka for the year 2012. G signs represent the genotypes used as follows G1 was PR31Y43, G2 was FACTOR, G3 was COSTANZA, G4 was ARMA, G5 was PR31A34, G6 was ELEONORA, G7 was FAMOSO, G8 was DKC6818, G9 was MITIC, G10 was DKC6040, G11 was KERMESS, G12 was PR31G98, G13 was LG3535, G14 was PR33A46, G15 was PR31P41, G16 was 1T, 2T was G17, G18 was 3T, G19 was 4T, 5T was G20, G21 was 1F, G22 was 2F, G23 was 3F, G24 was 4F, G25 was 5F, G26 was 6F, G27 was 7F, G28 was 8F, G29 was 9F and G30 was 10F.
Figure 3. Analysis for stability for the trait of moisture content (%) based on (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability. The desirable genotypes are those placed near the concentric region of the ideal genotype. The E signs represent the environments combined with the years used as follows E1 was Giannitsa, E2 was Florina, E3 was Trikala, and E4 was Kalambaka for 2011; E5 was Giannitsa, E6 was Florina, E7 was Trikala and E8 was Kalambaka for the year 2012. G signs represent the genotypes used as follows G1 was PR31Y43, G2 was FACTOR, G3 was COSTANZA, G4 was ARMA, G5 was PR31A34, G6 was ELEONORA, G7 was FAMOSO, G8 was DKC6818, G9 was MITIC, G10 was DKC6040, G11 was KERMESS, G12 was PR31G98, G13 was LG3535, G14 was PR33A46, G15 was PR31P41, G16 was 1T, 2T was G17, G18 was 3T, G19 was 4T, 5T was G20, G21 was 1F, G22 was 2F, G23 was 3F, G24 was 4F, G25 was 5F, G26 was 6F, G27 was 7F, G28 was 8F, G29 was 9F and G30 was 10F.
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Agriculture 13 01033 g004 550
Figure 4. Analysis of stability for the seed length characteristic based on: (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability.
Figure 4. Analysis of stability for the seed length characteristic based on: (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability.
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Agriculture 13 01033 g005 550
Figure 5. Analysis of stability for the seed thickness characteristic based on: (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability.
Figure 5. Analysis of stability for the seed thickness characteristic based on: (a) adaptation map; (b) AMMI1 biplot; (c) GGE biplot depicting the environmental stability; (d) GGE biplot for genotypes depicting the genotypic stability.
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Agriculture 13 01033 g006 550
Figure 6. Analysis of stability for the seed width trait based on: (a) AMMI adaptation map; (b) AMMI1 biplot; (c) GGE biplot for the environment; (d) GGE biplot for genotypes depicting the stability of the genotypes.
Figure 6. Analysis of stability for the seed width trait based on: (a) AMMI adaptation map; (b) AMMI1 biplot; (c) GGE biplot for the environment; (d) GGE biplot for genotypes depicting the stability of the genotypes.
Agriculture 13 01033 g006
Table
Table 1. Geographical location, elevation, soil chemical analysis and crop information for the experimental plots.
Table 1. Geographical location, elevation, soil chemical analysis and crop information for the experimental plots.
EnvironmentsLongitudeLatitudeElevation (m)SandSiltClaySoil TexturepHOrganic MatterPlanting DateHarvesting Date
Giannitsa22°39′ E40°77′ N108.9%37.4%53.7%clay (C)8.183.50%middle April 2011 and 2012late September 2011 and 2012
Florina21°22′ E40°46′ N70561.2%27.6%11.2%sandy loam (SL)6.251.29%early May 2011, middle May 2012middle December 2011, early November 2012
Trikala21°64′ E39°55′ N12049.0%19.0%32.0%Sandy clay loam (SCL)8.02.40%early April 2011 and 2012Early October 2011 and 2012
Kalambaka21°65′ E39°64′ N1901.6%49.1%49.3%silty clay (SiC)8.182.14%early April 2011 and 2012Early October 2011, late September 2012
Table
Table 2. Mean squares for the tested seed quality and chemical composition parameters from the analysis of variance across environments.
Table 2. Mean squares for the tested seed quality and chemical composition parameters from the analysis of variance across environments.
Source of VariationProtein Content (%)Fat
Content (%)		Ash
Content (%) 		Starch Content (%)Crude
Fiber
Content (%)		Moisture Content (%)Seed Length (mm) Seed Thickness (mm) Seed Width (mm)
Environments (E)0.122 ns0.016 *0.001 ns1.197 **0.021 ns0.212 **0.238 **0.137 **0.069 *
REPS/Environments0.055 ns0.006 ns0.001 ns0.534 ns0.016 ns0.003 ns0.071ns0.055 ns0.048 ns
Genotypes (G)11.910 **0.579 **0.113 **4.615 **0.112 **0.105 **20.158 **2.002 **1.419 **
Genotypes × Environments
(G × E)		0.038 ns0.008 ns0.001 ns0.470 ns0.012 ns0.204 **0.109 **0.051 *0.051 *
Error0.0750.0070.0010.4200.0170.0030.0640.0440.039
Probability values: * p ≤ 0.05; ** p ≤ 0.01; ns = not significant.
Table
Table 3. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Giannitsa.
Table 3. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Giannitsa.
GENOTYPESProtein Content (%)Fat Content (%)Ash Content (%)Starch Content (%)Crude Fiber Content (%)Moisture Content (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
31Y43117615893592911022821,0407702828530
FACTOR1124240422395781426577111312610298
COSTANZA8598746623799148838,18390929931037
ARMA85810932342742817022,708176541381087
31A349841051215431,219256416718074410669
ELEONORA143122981533633033766,52315901445446
FAMOSO10812256255497512761915172413671776
68189491894228927,5052771131191739811165
MITIC9161142195711,0824095428229511802983
604011731310325212,045481110312973710661
KERMESS106220032984702314740,12581724771015
31G98846925294511,5462653424920774350
LG3535122896227129703290431538032574592
33A467432511256111,14032674352324879335
31P4112731678206211,1124171409264114,372658
1T7541509200420,134326417228322212470
2T10171346310463083361357561819391678
10228352360820138235,38439251836973
113810323229561922193,34738891704494
1115132426835942363442325184305646
1F96679023507739290172318954139630
2F9311172285123,876434315417091504572
3F12331633313411,79423628,98714712515994
4F1040167384624,70721910,14812153245521
5F7881709226917,964430148829401034566
6F914121826386032260154123601745365
7F8854213247440624943,753984960341
8F855105825045924430251412491781878
9F94514762225801228713,3596382227536
10F9761515303829,253303153619023633728
Table
Table 4. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Florina.
Table 4. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Florina.
GENOTYPESProtein (%)Fat (%)Ash (%) Starch (%)Crude Fiber (%)Moisture (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
31Y4385316071709711519913,0633442597430
FACTOR75021739280508720648256102656449
COSTANZA10231430162614,170256126,0705761872313
ARMA14431078332115,81555924,0511320879387
31A341155202669467199511611230882229545
ELEONORA83211922223719132933,0841873992394
FAMOSO906856276712,740613205111282008493
681811111376363929,6843141611307716243389
MITIC9391788217532,62952712,1971634787264
604012233155208720,4124151292272340291218
KERMESS9371469288910,01639259,319151020051060
31G981392301025546063359252714173140767
LG3535101518162752725447152546941706575
33A461245128438127888347963425751006660
31P41905172726787105312146823751319808
1T1255167052094720299404311061662371
2T105610892867639323713272529790358
98016482163646732617,10823782620668
86724492605881448765,5611919943375
1042194736209327346394611631685352
1F10623774518975823981808169314,877326
2F116915412308742534630142700850498
3F100215272245480046560,87826363231499
4F95896217946683573692519682650510
5F1201100539938228294175415122929811
6F14101202247015,4704201447268624301014
7F11595702916830058219,50312732076967
8F12922914290510,09132721438832263849
9F108520272471555729716,786445017731744
10F12002181323613,005423178923191143379
Table
Table 5. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Trikala.
Table 5. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Trikala.
GENOTYPESProtein (%)Fat (%)Ash (%)Starch (%)Crude Fiber (%)Moisture (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
31Y43100912618838747406735217683101 238
FACTOR50221912519349928726,3278662146191
COSTANZA6601201391314,386558266523953956616
ARMA96514992342981224721,29321681990271
31A34842248110,19914,81228825,3103689975379
ELEONORA9351429161110,6974233727130637681051
FAMOSO7871644360131,46726812,98811281506452
6818799796304413,060222299717211312973
MITIC8832136191015,23646225,540189025712452
604013692566319111,66333925,96511143122637
KERMESS135312182446917629442,91028021701380
31G9889618703835753180515847007926345
LG3535761337227128299522468810851738429
33A467741434289318,705336718314371152413
31P41117810482839678178022,0952329824330
1T15451798224814,429315727923121000432
2T13321941225911,30333413,32217867361673
8301044354210,062260324437441260770
10861309236077711874443279436361387
1252100628047156168248667341240311
1F108618613176601231111,63442612244550
2F11361844249993193205098202234791050
3F9891478292213,20935514348992472386
4F927130124606845362529314411501889
5F1021124538387837436285226471132740
6F11551584368016,02848228,19116761290392
7F96041630103899330119912161345371
8F12961462233010,4645365391858918895
9F95519844397705224411,25914161138388
10F155414123140986717015,92217973854264
Table
Table 6. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Kalambaka.
Table 6. Trait stability index ( x ¯ / s ) 2 for seed quality and chemical composition parameters in Kalambaka.
GENOTYPESProtein (%)Fat (%)Ash (%)Starch (%)Crude Fiber (%)Moisture Content (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
31Y43668205416876159107520613402178309
FACTOR13491735306410,73323934,4831450630731
COSTANZA1018284021578782265370510074240192
ARMA10302210382312,29336177449391253602
31A341127178416278753597100,64045111890226
ELEONORA1028125527747575348403453822122899
FAMOSO9852083240516,97431794297571698381
68189681646267823,748290643541907935777
MITIC10421643502329,77842714,75626162377847
604010411660362531,20759737,19914082139490
KERMESS300321152840854337016,84825872241894
31G989911884248116,875221142710412067461
LG353513671196284811,483255324617131426543
33A4617251493270913,8534767960193619602772
31P41111211102119945723424,80433701492702
1T12801706404017,896348751821891512949
2T133815323612798836623,1232544872333
111325652101557534927279642571348
1122182044718527618414711753297871
9861813283612,844617207423232045878
1F83018222886862647818,49211501118882
2F946164435408917422565810722750598
3F117616722214500834613506812782477
4F13121849361611,926364314758022173315
5F108720841638513426727688161337702
6F100920212662380427029,75319611686329
7F126346334603398495122080889261125
8F9991290275811,715296492510022261432
9F128311732113886139314,38520352602476
10F9351911346013,34358815,9261984979394
Table
Table 7. Trait stability index ( x ¯ / s ) 2 across environments for seed quality and chemical composition parameters.
Table 7. Trait stability index ( x ¯ / s ) 2 across environments for seed quality and chemical composition parameters.
EnvironmentsProtein Content (%)Fat Content (%)Ash Content (%)Starch Content (%)Crude Fiber Content (%)Moisture Content (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
Giannitsa16939138573062662796153696240
Florina17245338861273052928143621274
Trikala16843036672552873505166744227
Kalambaka16743638866722653495178709262
Real Mean16942838268402813181160693251
Table
Table 8. Trait stability index ( x ¯ / s ) 2 across genotypes for seed quality and chemical composition parameters.
Table 8. Trait stability index ( x ¯ / s ) 2 across genotypes for seed quality and chemical composition parameters.
GENOTYPESProtein Content (%)Fat Content (%)Ash Content (%)Starch Content (%)Crude Fiber Content (%)Moisture Content (%)Seed Length (mm)Seed Thickness (mm)Seed Width (mm)
31Y43877163416497671192925811811256283
FACTOR87917193212550625780169341243328
COSTANZA9371329281511,47933363175822704358
ARMA10541460302910,48828713,97414651610399
31A3410451491321810,720335814229791829407
ELEONORA1086149321037737369757017751779633
FAMOSO9571614303613,545358364811121698558
681810011391299918,1163472107212012911032
MITIC10381711250319,58344810,94818481274582
604012721575320617,328460238912492257698
KERMESS1345151730149315277321716712226740
31G98971171629589229348213414241332418
LG35351125161728449095384333813401908518
33A4610771657299312,258382378621121156559
31P411194145526198728343297320431415524
1T12201445309610,135339338818981596504
2T126915303151828034026122348900610
1075140226396740331242921601153544
1122154932385696289233119591981675
1159122432347732316250816781984484
1F1061165433847878353341419362046538
2F10971649289010,307399349617821544613
3F1170161827847520339284816861718531
4F1135138015659529355264717052399524
5F1090140527768862372195316001297526
6F1169157229507458349312521141626462
7F11284903382375634724599771733556
8F118915312787982440824789951582748
9F1107174428257129312216813811912531
10F11281641325214,061317324321811621353
Table
Table 9. Correlations between all seed quality and chemical composition parameters.
Table 9. Correlations between all seed quality and chemical composition parameters.
Protein (%)Fat (%)Ash (%)Starch (%)Fiber (%)Moisture
Content (%)		Seed Length (mm)Seed Thickness (mm)
Fat (%)0.046
Ash (%)−0.134 **0.283 **
Starch (%)−0.068 *0.065 *−0.206 **
Fiber (%)0.0370.203 **0.195 **−0.024
Moisture content (%)−0.069 *−0.076 *−0.0340.077 *−0.082 *
Seed length0.104 **0.331 **0.592 **−0.233 **0.226 **−0.077 *
Seed thickness−0.144 **0.200 **0.523 **−0.218 **0.169 **−0.0260.633 **
Seed width−0.0040.240 **0.452 **−0.209 **0.103 **−0.0160.574 **0.633 **
* Correlations are significant at the 0.05 level (2-tailed), ** Correlation is significant at the 0.01 level (2-tailed).
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Greveniotis, V.; Bouloumpasi, E.; Zotis, S.; Korkovelos, A.; Kantas, D.; Ipsilandis, C.G. Stability Dynamics of Main Qualitative Traits in Maize Cultivations across Diverse Environments regarding Soil Characteristics and Climate. Agriculture 2023, 13, 1033. https://doi.org/10.3390/agriculture13051033

AMA Style

Greveniotis V, Bouloumpasi E, Zotis S, Korkovelos A, Kantas D, Ipsilandis CG. Stability Dynamics of Main Qualitative Traits in Maize Cultivations across Diverse Environments regarding Soil Characteristics and Climate. Agriculture. 2023; 13(5):1033. https://doi.org/10.3390/agriculture13051033

Chicago/Turabian Style

Greveniotis, Vasileios, Elisavet Bouloumpasi, Stylianos Zotis, Athanasios Korkovelos, Dimitrios Kantas, and Constantinos G. Ipsilandis. 2023. "Stability Dynamics of Main Qualitative Traits in Maize Cultivations across Diverse Environments regarding Soil Characteristics and Climate" Agriculture 13, no. 5: 1033. https://doi.org/10.3390/agriculture13051033

APA Style

Greveniotis, V., Bouloumpasi, E., Zotis, S., Korkovelos, A., Kantas, D., & Ipsilandis, C. G. (2023). Stability Dynamics of Main Qualitative Traits in Maize Cultivations across Diverse Environments regarding Soil Characteristics and Climate. Agriculture, 13(5), 1033. https://doi.org/10.3390/agriculture13051033

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