Improvement of vegetable soybean: genetic diversity and correlations of traits between immature and mature plants

Casas-Leal, Nelson Enrique; Pereira, Fernanda Aparecida Castro; Vello, Natal Antonio

doi:10.1590/1984-70332022v22n1a08

Abstract

Human consumption of vegetable soybeans is increasing, and consequently, breeding programs need to be encouraged and optimized. Therefore, there is a need to understand the relationship between the traits evaluated in the R₆ (full seed) and R₈ (full maturity) stages and estimate genetic divergence. At two sites and two crop seasons, we evaluated 42 progenies (F₆ generation) from crosses between vegetable soybean genotypes and three commercial cultivars. In general, we found significant coincident correlations between environments. Positive and significant correlations between pod width (PWR₆) and hundred-seed weight (HSW) and between PWR₆ and hundred-pod weight (HPW) suggest the possibility of replacing the labor-intensive process of obtaining HSW and HPW by estimating PWR₆, which is faster and easier to apply. The unweighted pair-group method arithmetic average analysis allocated soybean genotypes into six major clusters. Furthermore, information from the present work may guide practical actions in breeding programs.

Keywords:
Glycine max; soybean breeding; edamame; Pearson correlation

INTRODUCTION

Soybean is one of the most important crops and has enormous potential for improving the dietary quality of people worldwide. Soybeans can be consumed as a vegetable crop or processed into various products (Hartman et al. 2011HartmanGLWestEDHermanTK2011 Crops that feed the world 2. Soybean-worldwide production, use, and constraints caused by pathogens and pests. Security 3:5-17). Vegetable soybean, also known as “edamame” in Japan, “maodou” in China, and “poot kong” in Korea (Kumar et al. 2011KumarVRaniAGoyalLPratapDBilloreSDChauhanGS2011 Evaluation of vegetable-type soybean for sucrose, taste-related amino acids, and isoflavones contents. International Journal of Food Properties 14:1142-1151), belongs to the same species as soybean-grain or “commodity” soybean [Glycine max (L.) Merrill]. However, beans are consumed when they are immature or unripe (Konovsky et al. 2020KonovskyJLumpkinTAMcClaryD2020 Edamame: the vegetable soybean. In Understanding the Japanese food and agrimarket. CRC Press, Boca Raton, p. 173-181); that is, the pods are harvested at the R₆ stage (Fehr and Caviness 1977FehrWRCavinessCE1977 Stages of soybean development. Iowa State University, Ames, 11p), when the seeds are already fully developed inside the pods. The short growth duration allows edamame to fit into narrow windows during crop rotation.

Although beans are often available in pods, only the beans are edible. Vegetable soybeans have gained special attention from breeders, non-breeder researchers, growers, and consumers, and new edamame varieties are currently being developed (Carneiro et al. 2021CarneiroRCDuncanSEO'KeefeSFYinYNeillCLZhangB2020 Sensory and consumer studies in plant breeding: A guidance for edamame development in the US. Frontiers in Sustainable Food Systems 4:124). Soybean is a popular crop in Asian countries, but the consumption of edamame is increasing in the United States (Carneiro et al. 2020CarneiroRCYinYDuncanSEO’KeefeSF2021 Edamame flavor characteristics driving consumer acceptability in the United States: a review. ACS Food Science & Technology 1:1748-1756), Australia (Figueira et al. 2019FigueiraNCurtainFBeckEGrafenauerS2019 Consumer understanding and culinary use of legumes in Australia. Nutrients 11:1575), Europe (Hong and Gruda 2020HongJGrudaNS2020 The potential of introduction of Asian vegetables in Europe. Horticulturae 6:38), and sub-Saharan Africa (Djanta et al. 2020DjantaMKAAgoyiEEAgbahoungbaSQuenumFJBChadareFJAssogbadjoAEAgbanglaCSinsinB2020 Vegetable soybean, edamame: Research, production, utilization and analysis of its adoption in Sub-Saharan Africa. Journal of Horticulture and Forestry 12:1-12). In comparison to grain soybean, the seeds of vegetable soybean cultivars are larger (>30 g per 100 dry seeds) and occupy 80% to 90% of the pods, in addition to being better in flavor and texture. The physicochemical properties of edamame vary during different growth stages. According to Yu et al. (2022YuDLordNPolkJDhakalKLiSYinYDuncanSEWangHZhangBHuangH2022 Physical and chemical properties of edamame during bean development and application of spectroscopy-based machine learning methods to predict optimal harvest time. Food Chemistry 368:130799), pod/bean weight and pod thickness peaked at the R₆ stage. Moreover, sugar, starch, alanine, and glycine levels also peaked at R₆ and then declined. The seeds had a lower percentage of starch, which caused flatulence. However, as in grain soybeans, vegetable soybeans also have anti-nutritional factors such as tannins, protease inhibitors, and phytic acid (Gondim-Tomaz et al. 2022Gondim-TomazRMABragaNRCarvalhoCRLGalloPBErismannNDM2022 Phytochemical evaluation of lipoxygenase-free soybean genotypes for human consumption. Brazilian Journal of Food Technology 25: e2021032.).

Soybeans are one of the main crops in Brazil and are of social and economic importance (Sentelhas et al. 2015SentelhasPCBattistiRCâmaraGMSFariasJRBHampfACNendelC2015 The soybean yield gap in Brazil-magnitude, causes and possible solutions for sustainable production. The Journal of Agricultural Science 153:1394-1411). Vegetable soybean can be an important source of high-quality, low-cost protein and other nutrients for Brazilians (Keatinge et al. 2011KeatingeJDHEasdownWJYangRYChadhaMLShanmugasundaramS2011 Overcoming chronic malnutrition in a future warming world: the key importance of mungbean and vegetable soybean. Euphytica 180:129-141, Rizzo and Baroni 2018RizzoGBaroniL2018 Soy, soy foods and their role in vegetarian diets. Nutrients 10:1-51). In Brazil, the consumption of soybeans in the human diet remains limited (Juhász et al. 2017JuhászACPCiabottiSTeixeiraLCA2017 Breeding for nutritional quality. In da Silva FL, Borém A, Sediyama T and Ludke W (eds) Soybean breeding. Springer, Cham, p. 375-394) but is exhibiting an increasing trend as a result of the dissemination of the benefits of soybeans for human health and the increasing offer in the market of better-quality soybean-based products (Carrão-Panizzi et al. 2009Carrão-PanizziMCPípoloAEMandarinoJMGArantesNEGarciaABenassiVDTCarneiroGDS2009 Breeding specialty soybean cultivars for processing and value-added utilization at Embrapa in Brazil. In Proceedings of the VIII world soybean research conference. Developing a global soy blueprint for a safe secure and sustainable supply. Institute of Crop Science, Beijing, p. 1-4).

Vegetable soybeans possess antioxidant properties and exert inhibitory effects on inflammatory mediators, suggesting their potential use as dietary supplements (Lin and Wu 2021LinYWuS2021 Vegetable soybean (Glycine max (L.) Merr.) leaf extracts: Functional components and antioxidant and anti‐inflammatory activities. Journal of Food Science 86:2468-2480). The market demand for edamame has begun to grow and expand dramatically in recent decades owing to increased knowledge of its nutritional properties compared with that of mature soybeans (Islam et al. 2019IslamMZhangMFanD2019 Ultrasonically enhanced low-temperature microwave-assisted vacuum frying of edamame: Effects on dehydration kinetics and improved quality attributes. Drying Technology 37:2087-2104) and changes in lifestyle with diets shifting toward healthier food (Zhang et al. 2017ZhangQLiYChinKLQiY2017 Vegetable soybean: Seed composition and production research. Italian Journal of Agronomy 12:276-282). Thus, the objectives of the present study are as follows: i) to estimate the correlation between traits in the R₆ and R₈ stages of vegetable soybean progenies in advanced stages of endogamy; and ii) to study the genetic diversity between progenies for use in a breeding program for vegetable soybeans.

MATERIAL AND METHODS

Plant material

The genotypes used in this study were 42 soybean lines (F₆) from crosses between inbred lines from the soybean breeding program of the Department of Genetics of the University of São Paulo (ESALQ-USP). The genealogy of the crosses included vegetable soybean genotypes: HAKUCHO, IAC PL-1, MAJÓS, P.I. 80.441, P.I. 165.672, P.I. 229.320, P.I. 230.970 F7-4, STWART, TAMBA, TMV, and TN#4. Moreover, three checks were used in all experiments: two soybean cultivars, especially those developed for human consumption (BRS 257 and BRS 267), and a cultivar (IAC 100) with insect resistance.

Experimental conditions

The experiments were conducted during two crop seasons at two locations in the city of Piracicaba (lat 22° 42′ 30″ S, long 47° 39′ 00″ W, alt 540 m asl), São Paulo: Esalq (Site 1) and Areão (Site 2). The Esalq site is the headquarters of the soybean breeding program of the Luiz de Queiroz School of Agriculture, University of São Paulo, and has the ferric red nitossol soil (Santos et al. 2018SantosHGJacominePTAnjosLHCOliveiraVALumbrerasJFCoelhoMRCunhaTJF2018 Brazilian soil classification system. Embrapa Solos, Brasília, 303p) with a clayey texture and undulating relief. The Areão site has dystrophic red-yellow argisol soil with a medium-clay texture and undulating relief. The experiments were carried out in a randomized complete block design with three replicates. The experimental units were single-row plots (2 m x 0.5 m). Planting was performed in a commercial production setting, with a planting density of 40 seeds per plot. Fertilization, supplemental irrigation, and pesticide application followed the technical recommendations for soybeans in this region.

Phenotyping

When the plants reached the R₆ stage (full seed), two plants per plot were harvested, and the traits evaluated were pod yield (PY, g plant^-1), hundred pod weight (HPW, g), number of days from planting to the R₆ stage (NDR₆), pod width (PWR₆, mm), and number of pods per plant (NP). At the R₈ stage (full maturity), the plots were evaluated for grain yield (GY, g plot^-1), hundred seed weight (HSW, g), number of days from planting to maturity (NDM), agronomic value (AV), and plant height at maturity (PHM, cm).

Data analysis

All analyses were performed using the Genes software in integration with R software (Cruz 2016CruzCD2016 Genes software-extended and integrated with the R, Matlab and Selegen. Acta Scientiarum. Agronomy 38:547-552). Thus, the integration of the correlation network used the “Qgraph” package (Epskamp et al. 2012EpskampSCramerAOWaldorpLJSchmittmannVDBorsboomD2012 Qgraph: Network visualizations of relationships in psychometric data. Journal of Statistical Software 48:1-18). According to Singh (1981SinghD1981 The relative importance of characters affecting genetic divergence. The Indian Journal of Genetics and Plant Breeding 14:237-245), the relative importance of the characteristics in relation to genetic diversity among the genotypes was studied. The generalized quadratic distance of Mahalanobis was adopted as a dissimilarity measure between the soybean genotypes to perform clustering using the unweighted pair group method (UPGMA). In path analysis, the coefficients of phenotypic correlation between PY and the other traits from R₆ (HPW, NDR₆, PWR₆, and NP) were partitioned into direct and indirect effects. The same was considered for GY and other traits from R₈.

RESULTS AND DISCUSSION

In the present work, we phenotyped soybean lines at the R₆ and R₈ stages and found great variation between environments and genotypes. This provides important and necessary information for breeding programs. Analysis of variance revealed significant differences among the genotypes for all traits, except for PY and AV. The interaction between genotypes and environments was not significant for PHM. Moreover, the effects of the environment had the highest contributions to variation in traits in relation to the other main effects. Du et al. (2020DuYZhaoQChenLYaoXZhangHWuJXieF2020 Effect of drought stress during soybean R2-R6 growth stages on sucrose metabolism in leaf and seed. International Journal of Molecular Sciences 21:618) observed that drought stress significantly affected seed weight in the soybean R₆ stage. Between genotypes, the average seed weight in the four environments ranged from 111.9 to 198.4 g plant^-1 (PY), 80.9 to 137.2 g (HPW), 9.4 to 12 mm (PWR₆), 52.7 to 106.5 (NP), 492.8 to 861.8 g plot^-1 (GY), 13.4 to 23.7 g (HSW), 128.4 to 143.9 (NDM), 2.5 to 3.3 (AV), and 72.9 to 133.3 cm (PHM) (Table 1). In the present study, NDR₆ ranged from 109.8 to 117.3 d; these values were higher than those reported by Kumar et al. (2006KumarVRaniABilloreSDChauhanGS2006 Physico-chemical properties of immature pods of Japanese soybean cultivars. International Journal of Food Properties 9:51-59) at 60 to 93 d. Interestingly, these authors evaluated mostly the exotic genotypes not adapted to the local environment, which caused a reduction in the cycle duration due to differences in photoperiod sensitivity. By contrast, Rao et al. (2002RaoMSSBhagsariASMohamedAI2002 Fresh green seed yield and seed nutritional traits of vegetable soybean genotypes. Crop Science 42:1950-1958) found values of NDR₆ ranging from 99 to 134 d. Assessment of NDR₆ is relevant for vegetable soybean genotypes because it allows the identification of early and late genotypes that can be planted at different dates while maintaining high quality (Silva e Souza et al. 2020Silva e SouzaRBarbosaPAMYassueRMBornhofenEEspoladorFGNazatoFMVelloNA2020 Combining ability for the improvement of vegetable soybean. Agronomy Journal 112:3535-3548).

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Table 1
Average percentages of R₆ and R₈ traits of the 45 soybean genotypes cultivated in four environments: two sites and two crop seasons

For all traits, we found superior means in relation to commercial cultivars. In a multi-year study of edamame conducted by Jiang et al. (2018JiangGRuttoLKRenSBowenRABerryHEppsK2018 Genetic analysis of Edamame seed composition and trait relationships in soybean lines. Euphytica 214:158), it was reported that there are significant trait variations between years, including changes in PY and PHM, suggesting that environmental variation is an important factor in the development of edamame lines. Yu et al. (2021YuDLinTSuttonKLordNCarneiroRJinQZhangBKuharTRideoutSRossJDuncanSYinYWangHHuangH2021 Chemical compositions of edamame genotypes grown in different locations in the US. Frontiers in Sustainable Food Systems 5:22) concluded that for breeding better edamame genotypes, both genotype and planting location should be considered.

Establishing the relationship between characteristics is important for reducing the number of evaluated traits and optimizing the selection steps in a breeding program. In our study, we evaluated the correlation between traits and genetic diversity, which is useful for improving vegetable soybeans. Significant positive correlations coinciding in all environments and the respective mean estimates of the Pearson's correlation among the characteristics of R₆ were PY x HPW (0.363), PY x NP (0.692), and HPW x PWR₆ (0.649). Negative coincident correlations occurred only for HPW x NDR₆ (-0.541). Between traits from R₆ and R₈, positive and significant correlations were found for HPW x HSW (0.696), NDR₆ x NDM (0.497), and PWR₆ x HSW (0.657). Among the traits from the R₈ stage, only the correlation between AV x PHM was significant in all environments but was negative in first year and positive in second year. The correlation network (Figure 1) helped visualize the association between groups (R₆ and R₈) and graphically demonstrated the importance of all traits. In all environments, we observed a strong correlation between R₆ traits and strong relation of HSW to them. The width of the line was proportional to the intensity of the correlation. These analyses help to detect complex statistical patterns that are difficult to extract using other approaches (Silva et al. 2016SilvaARRegoERPessoaAMSRegoMM2016 Correlation network analysis between phenotypic and genotypic traits of chili pepper. Pesquisa Agropecuária Brasileira 51:372-377).

Figure 1
Phenotypic correlation network, which the red and green lines represent negative and positive correlations, respectively. Legend: in blue circles are the traits evaluated in R₆ (PY, HPW, NDR6, PWR6 and NP) and in orange are the traits from R₈ (GY, HSW, NDM, AV and PHM) stage of soybean plants from experiments conducted in two sites and two crop seasons.

Significant correlations, independent of the environment, suggest a strong genetic association between traits. The positive and significant phenotypic correlations between PWR₆ and HSW and between PWR₆ and HPW suggest the possibility of an alternative method for obtaining HSW and HPW. Similar results have been reported by Yokomizo et al. (2000YokomizoGKDuarteJBVelloNA2000 Phenotypic correlation between seed size and other characteristics in topcrosses of vegetable soybean with grain type. Pesquisa Agropecuária Brasileira 35:2223-2234) and Silva e Souza et al. (2020Silva e SouzaRBarbosaPAMYassueRMBornhofenEEspoladorFGNazatoFMVelloNA2020 Combining ability for the improvement of vegetable soybean. Agronomy Journal 112:3535-3548) for PWR₆ and HSW, with high positive and significant phenotypic correlations of 0.892 (P < 0.01) and 0.830 (P < 0.05), respectively. HSW is an important trait, especially in soybean food products such as edamame (Kaler and Purcell 2021KalerASPurcellLC2021 Association mapping identifies and confirms loci for soybean seed weight. Crop Science 61:1289-1300). HSW and HPW quantification is quite laborious and can be replaced with PWR₆ estimation, which is faster and easier to apply. Moreover, by selecting plants with higher PWR₆, the HSW and, consequently, the GY can be increased by approximately 66%. These results are consistent with the findings of Li et al. (2019LiXZhangXZhuLBuYWangXZhangXZhouYWangXGuoNQiuLZhaoJXingH2019 Genome-wide association study of four yield-related traits at the R6 stage in soybean. BMC Genetics 20:1-15). High moisture content of approximately 57-79% is present in fresh seeds of vegetable soybeans, and it has a significant positive correlation with yield. Thus, moisture content is an important yield-related trait in vegetable soybeans (Li et al. 2021LiXZhouYBuYWangXZhangYGuoNZaoJXingH2021 Genome-wide association analysis for yield-related traits at the R6 stage in a Chinese soybean mini core collection. Genes & Genomics 1:1-16).

The correlation between PWR₆ and NP was moderately negative (-0.529, P < 0.01). Although the significance was observed in only three locations, this indicates that the selection of plants with larger pods may cause a reduction in NP. The occurrence of compensation in some traits related to productivity is well recognized in this species, which may explain these results (Vaz Bisneta et al. 2015Vaz BisnetaMDuarteJBMello FilhoOLZitoRKRodriguesJSCarvalho JuniorEMAlvarengaWB2015 Correlação entre componentes de produção em soja como função de tipo de crescimento e densidade de plantas. In Proceedings of the VII congresso brasileiro de soja. Embrapa Soja, Florianópolis, p. 659-661). However, the appearance of pods and large size are important criteria for the selection of quality vegetable soybeans (Manninen et al. 2015ManninenHPaakkiMHopiaAFranzénR2015 Measuring the green color of vegetables from digital images using image analysis. LWT-Food Science and Technology 63:1184-1190).

The positive and significant estimate between HPW and HSW is highlighted, indicating that these characteristics are highly correlated, allowing an increase in HSW of approximately 69.6% when selecting plants with higher HPW. We observed that the estimate of the correlation coefficient between the characteristics NDM and NDR₆ was moderate and positive; that is, earlier plants in the R₆ stage reached maturity faster. Indirect selection through mature soybeans may benefit the edamame allowing for improvement in most amino acids (Jiang et al. 2018JiangGRuttoLKRenSBowenRABerryHEppsK2018 Genetic analysis of Edamame seed composition and trait relationships in soybean lines. Euphytica 214:158). The strong to moderate significant correlations between R₆ and R₈ physiological stages without changes in the genotype rankings for yield, texture, protein, sucrose, calcium, and iron content suggest that breeders could evaluate vegetable soybean lines at the R₈ stage and indirectly select for other traits at the R₆ stage (Mozzoni and Chen 2019MozzoniLChenP2019 Correlations of yield and quality traits between immature and mature seed stages of edamame soybean. Journal of Crop Improvement 33:67-82). Moreover, Jiang and Katuuramu (2021JiangGLKatuuramuDN2021 Comparison of seed fatty and amino acids in edamame dried using two oven‐drying methods and mature soybeans. Journal of the Science of Food and Agriculture 101:1515-1522) found significant correlations between fatty amino acids of edamame and mature soybeans.

Taware et al. (1997TawareSPHalvankarGBRautVMPatilVP1997 Variability, correlation and path analysis in soybean hybrids. Soybean Genetics Newsletter 24:96-98) equally demonstrated non-significant correlation values between GY and HSW and reported that soybean often promotes compensation between GY and HSW, increasing or decreasing the size of seeds as a function of the number of pods and seeds in development. When limiting environmental factors causes intense competition between plants, intense competition also occurs between different parts of the plant for nutrients and metabolism. This competition is particularly pronounced during the formation of reproductive structures, which results in compensatory variation between the primary components of production (Santos et al. 2013SantosJMSPeixotoCPRangelMASCruzTVSilvaRNALedoCAS2013 Desempenho agronômico de genótipos de soja hortaliça cultivados no recôncavo Baiano. Revista Brasileira de Ciências Agrárias 8:2013). According to path analysis results the trait that contributed the most to PY was the number of pods, which showed the highest direct effect on PY. In terms of GY, PHM had the greatest direct effect. The associations found in the path analysis were similar to those reported in other studies (Gomes and Almeida Lopes 2005GomesRLFAlmeida LopesAC2005 Correlations and path analysis in peanut. Crop Breeding and Applied Biotechnology 5:105-112, Machado et al. 2017MachadoBQVNogueiraAPOHamawakiOTRezendeGFJorgeGLSilveiraICMedeirosIAHamawakiRLHamawakiCDL2017 Phenotypic and genotypic correlations between soybean agronomic traits and path analysis. Genetics and Molecular Research 16:1-11, Ferrari et al. 2018FerrariMCarvalhoIRPelegrinAJNardinoMSzareskiVJOlivotoTFollmannDNPegoraroCMaiaLCSouzaVQRosaTC2018 Path analysis and phenotypic correlation among yield components of soybean using environmental stratification methods. Australian Journal of Crop Science 12:193-202).

To obtain hybrids, it is essential to identify contrasting genotypes with high degrees of genetic divergence. Genetic variability is the raw material for breeders, providing genetic material to generate significant genetic gains in the characteristics of interest (Govindaraj et al. 2015GovindarajMVetriventhanMSrinivasanM2015 Importance of genetic diversity assessment in crop plants and its recent advances: an overview of its analytical perspectives. Genetics Research International 1:1-14). To leverage genetic diversity in edamame breeding, the major challenge lies in phenotyping (Dhakal et al. 2021DhakalKZhuQZhangBLiMLiS2021 Analysis of shoot architecture traits in edamame reveals potential strategies to improve harvest efficiency. Frontiers in Plant Science 12:249). The cophenetic correlation coefficient was 0.6 with a significant t-test at 1% probability, which showed an adequate relationship between the distance matrix and the generated dendrogram.

A significant cutoff, using the Mojena criterion (Mojena 1977MojenaR1977 Hierarchical grouping methods and stopping rules: an evaluation. The Computer Journal 20:359-363), reached approximately 84% dissimilarity, allowing the formation of six distinct groups (Figure 3). Clusters 3, 2, and 5 showed the greatest diversity, with 17, 11, and 10 soybean lines, respectively. In contrast, clusters 4, 6, and 1 contained less genetic diversity, with one, two, and four soybean genotypes, respectively. Commercial cultivars BRS-257 and BRS-267 were allocated to Clusters 2 and 3, respectively. IAC100 was allocated in a single group. The six clusters had 4, 11, 17, 1, 10, and 2 soybean lines. In general, the means varied for all traits.

Figure 3
Unweighted pair‐group method arithmetic average cluster analysis from genetic distances (Mahalanobis’ distance) among soybean lines (1 to 45) evaluated for traits in R₆ and R₈ stage. In blue: soybean cultivar checks 43: BRS 257, 44: BRS 267 and 45: IAC100. The cut-off was based on Mojena’s criterion (Mojena 1977MojenaR1977 Hierarchical grouping methods and stopping rules: an evaluation. The Computer Journal 20:359-363).

We observed some clusters composed of only one or two genotypes (Figure 3), and cultivar IAC100 proved to be the most divergent among all evaluated genotypes. Other studies have found genetic divergence between soybean genotypes. Shilpashree et al. (2021ShilpashreeNDeviSNManjunathagowdaDCMuddappaAAbdelmohsenSATamamNElansaryHOEl-AbedinTKZAbdelbackiAMMJanhaviV2021 Morphological characterization, variability and diversity among vegetable soybean (Glycine max L.) genotypes. Plants 10:671) identified eight clusters based on morphological and quality traits. When the intention is to perform crossings resulting in superior progenies in relation to the traits of interest, selection of divergent parents should be based on the magnitude of the genetic divergence among genotypes (Cantelli et al. 2016CantelliDAVHamawakiOTRochaMRNogueiraAPOHamawakiRLSousaLBHamawakiCDL2016 Analysis of the genetic divergence of soybean lines through hierarchical and Tocher optimization methods. Genetics and Molecular Research 15:1-13).

In the present study, generalized Mahalanobis distance allowed us to quantify the relative importance of traits for genetic diversity by evaluating the contribution of the characteristics to the values of D². In general, the traits that contributed the most to genetic divergence were HSW, NDM, PWR₆, and NDR₆ (Figure 2). Removal of the least important variable from each group of traits evaluated in R₆ (PY) and R₈ (AV) caused no change in the grouping of genotypes. This indicates that there is little genetic diversity in these traits. However, producing large numbers of fresh pods is a major goal of edamame breeding (Dhakal et al. 2021DhakalKZhuQZhangBLiMLiS2021 Analysis of shoot architecture traits in edamame reveals potential strategies to improve harvest efficiency. Frontiers in Plant Science 12:249); thus, we could identify nine genotypes with means numerically superior to the two vegetable soybean checks (43 and 44), of which six belonged to cluster 3, the cluster with the highest number of genotypes (n = 17).

Figure 2
The relative importance of the traits for genetic diversity among the soybean lines evaluated at R₆ (PY, HPW, NDR6, PWR6 and NP) and R₈ (GY, HSW, NDM, AV and PHM) stage.

In conclusion, the path analysis determined that NP has the greatest favorable effect on PY, and PHM on GY. Thus, it is useful for indirect selection toward vegetable soybean genotypes. The present work suggests optimization of the phenotyping process in the two stages of soybean development. The positive and significant estimate between HPW and HSW suggests that one of the variables can be disregarded. According to the path analysis, breeders should maintain HPW as it has a direct effect on PY. In contrast, HSW stands out as the most important trait for genetic divergence. Therefore, phenotyping should consider the objectives and stages of the breeding program. According to the present work, we conclude that there is sufficient genetic variability in vegetable soybean lines, with the potential to be used for hybridization in a breeding program for vegetable soybeans.

ACKNOWLEDGEMENTS

The authors thank Coordenação de Aperfeiçoamento de Pessoal de Nível Superior and Conselho Nacional de Desenvolvimento Científico e Tecnológico for scholarship and funding the project.

REFERENCES

CantelliDAVHamawakiOTRochaMRNogueiraAPOHamawakiRLSousaLBHamawakiCDL2016 Analysis of the genetic divergence of soybean lines through hierarchical and Tocher optimization methods. Genetics and Molecular Research 15:1-13
CarneiroRCDuncanSEO'KeefeSFYinYNeillCLZhangB2020 Sensory and consumer studies in plant breeding: A guidance for edamame development in the US. Frontiers in Sustainable Food Systems 4:124
CarneiroRCYinYDuncanSEO’KeefeSF2021 Edamame flavor characteristics driving consumer acceptability in the United States: a review. ACS Food Science & Technology 1:1748-1756
Carrão-PanizziMCPípoloAEMandarinoJMGArantesNEGarciaABenassiVDTCarneiroGDS2009 Breeding specialty soybean cultivars for processing and value-added utilization at Embrapa in Brazil. In Proceedings of the VIII world soybean research conference. Developing a global soy blueprint for a safe secure and sustainable supply. Institute of Crop Science, Beijing, p. 1-4
CruzCD2016 Genes software-extended and integrated with the R, Matlab and Selegen. Acta Scientiarum. Agronomy 38:547-552
DhakalKZhuQZhangBLiMLiS2021 Analysis of shoot architecture traits in edamame reveals potential strategies to improve harvest efficiency. Frontiers in Plant Science 12:249
DjantaMKAAgoyiEEAgbahoungbaSQuenumFJBChadareFJAssogbadjoAEAgbanglaCSinsinB2020 Vegetable soybean, edamame: Research, production, utilization and analysis of its adoption in Sub-Saharan Africa. Journal of Horticulture and Forestry 12:1-12
DuYZhaoQChenLYaoXZhangHWuJXieF2020 Effect of drought stress during soybean R2-R6 growth stages on sucrose metabolism in leaf and seed. International Journal of Molecular Sciences 21:618
EpskampSCramerAOWaldorpLJSchmittmannVDBorsboomD2012 Qgraph: Network visualizations of relationships in psychometric data. Journal of Statistical Software 48:1-18
FehrWRCavinessCE1977 Stages of soybean development. Iowa State University, Ames, 11p
FerrariMCarvalhoIRPelegrinAJNardinoMSzareskiVJOlivotoTFollmannDNPegoraroCMaiaLCSouzaVQRosaTC2018 Path analysis and phenotypic correlation among yield components of soybean using environmental stratification methods. Australian Journal of Crop Science 12:193-202
FigueiraNCurtainFBeckEGrafenauerS2019 Consumer understanding and culinary use of legumes in Australia. Nutrients 11:1575
GomesRLFAlmeida LopesAC2005 Correlations and path analysis in peanut. Crop Breeding and Applied Biotechnology 5:105-112
Gondim-TomazRMABragaNRCarvalhoCRLGalloPBErismannNDM2022 Phytochemical evaluation of lipoxygenase-free soybean genotypes for human consumption. Brazilian Journal of Food Technology 25: e2021032.
GovindarajMVetriventhanMSrinivasanM2015 Importance of genetic diversity assessment in crop plants and its recent advances: an overview of its analytical perspectives. Genetics Research International 1:1-14
HartmanGLWestEDHermanTK2011 Crops that feed the world 2. Soybean-worldwide production, use, and constraints caused by pathogens and pests. Security 3:5-17
HongJGrudaNS2020 The potential of introduction of Asian vegetables in Europe. Horticulturae 6:38
IslamMZhangMFanD2019 Ultrasonically enhanced low-temperature microwave-assisted vacuum frying of edamame: Effects on dehydration kinetics and improved quality attributes. Drying Technology 37:2087-2104
JiangGRuttoLKRenSBowenRABerryHEppsK2018 Genetic analysis of Edamame seed composition and trait relationships in soybean lines. Euphytica 214:158
JiangGLKatuuramuDN2021 Comparison of seed fatty and amino acids in edamame dried using two oven‐drying methods and mature soybeans. Journal of the Science of Food and Agriculture 101:1515-1522
JuhászACPCiabottiSTeixeiraLCA2017 Breeding for nutritional quality. In da Silva FL, Borém A, Sediyama T and Ludke W (eds) Soybean breeding. Springer, Cham, p. 375-394
KalerASPurcellLC2021 Association mapping identifies and confirms loci for soybean seed weight. Crop Science 61:1289-1300
KeatingeJDHEasdownWJYangRYChadhaMLShanmugasundaramS2011 Overcoming chronic malnutrition in a future warming world: the key importance of mungbean and vegetable soybean. Euphytica 180:129-141
KonovskyJLumpkinTAMcClaryD2020 Edamame: the vegetable soybean. In Understanding the Japanese food and agrimarket. CRC Press, Boca Raton, p. 173-181
KumarVRaniABilloreSDChauhanGS2006 Physico-chemical properties of immature pods of Japanese soybean cultivars. International Journal of Food Properties 9:51-59
KumarVRaniAGoyalLPratapDBilloreSDChauhanGS2011 Evaluation of vegetable-type soybean for sucrose, taste-related amino acids, and isoflavones contents. International Journal of Food Properties 14:1142-1151
LiXZhangXZhuLBuYWangXZhangXZhouYWangXGuoNQiuLZhaoJXingH2019 Genome-wide association study of four yield-related traits at the R6 stage in soybean. BMC Genetics 20:1-15
LiXZhouYBuYWangXZhangYGuoNZaoJXingH2021 Genome-wide association analysis for yield-related traits at the R6 stage in a Chinese soybean mini core collection. Genes & Genomics 1:1-16
LinYWuS2021 Vegetable soybean (Glycine max (L.) Merr.) leaf extracts: Functional components and antioxidant and anti‐inflammatory activities. Journal of Food Science 86:2468-2480
MachadoBQVNogueiraAPOHamawakiOTRezendeGFJorgeGLSilveiraICMedeirosIAHamawakiRLHamawakiCDL2017 Phenotypic and genotypic correlations between soybean agronomic traits and path analysis. Genetics and Molecular Research 16:1-11
ManninenHPaakkiMHopiaAFranzénR2015 Measuring the green color of vegetables from digital images using image analysis. LWT-Food Science and Technology 63:1184-1190
MojenaR1977 Hierarchical grouping methods and stopping rules: an evaluation. The Computer Journal 20:359-363
MozzoniLChenP2019 Correlations of yield and quality traits between immature and mature seed stages of edamame soybean. Journal of Crop Improvement 33:67-82
RaoMSSBhagsariASMohamedAI2002 Fresh green seed yield and seed nutritional traits of vegetable soybean genotypes. Crop Science 42:1950-1958
RizzoGBaroniL2018 Soy, soy foods and their role in vegetarian diets. Nutrients 10:1-51
SantosHGJacominePTAnjosLHCOliveiraVALumbrerasJFCoelhoMRCunhaTJF2018 Brazilian soil classification system. Embrapa Solos, Brasília, 303p
SantosJMSPeixotoCPRangelMASCruzTVSilvaRNALedoCAS2013 Desempenho agronômico de genótipos de soja hortaliça cultivados no recôncavo Baiano. Revista Brasileira de Ciências Agrárias 8:2013
SentelhasPCBattistiRCâmaraGMSFariasJRBHampfACNendelC2015 The soybean yield gap in Brazil-magnitude, causes and possible solutions for sustainable production. The Journal of Agricultural Science 153:1394-1411
ShilpashreeNDeviSNManjunathagowdaDCMuddappaAAbdelmohsenSATamamNElansaryHOEl-AbedinTKZAbdelbackiAMMJanhaviV2021 Morphological characterization, variability and diversity among vegetable soybean (Glycine max L.) genotypes. Plants 10:671
SilvaARRegoERPessoaAMSRegoMM2016 Correlation network analysis between phenotypic and genotypic traits of chili pepper. Pesquisa Agropecuária Brasileira 51:372-377
Silva e SouzaRBarbosaPAMYassueRMBornhofenEEspoladorFGNazatoFMVelloNA2020 Combining ability for the improvement of vegetable soybean. Agronomy Journal 112:3535-3548
SinghD1981 The relative importance of characters affecting genetic divergence. The Indian Journal of Genetics and Plant Breeding 14:237-245
TawareSPHalvankarGBRautVMPatilVP1997 Variability, correlation and path analysis in soybean hybrids. Soybean Genetics Newsletter 24:96-98
Vaz BisnetaMDuarteJBMello FilhoOLZitoRKRodriguesJSCarvalho JuniorEMAlvarengaWB2015 Correlação entre componentes de produção em soja como função de tipo de crescimento e densidade de plantas. In Proceedings of the VII congresso brasileiro de soja. Embrapa Soja, Florianópolis, p. 659-661
YokomizoGKDuarteJBVelloNA2000 Phenotypic correlation between seed size and other characteristics in topcrosses of vegetable soybean with grain type. Pesquisa Agropecuária Brasileira 35:2223-2234
YuDLinTSuttonKLordNCarneiroRJinQZhangBKuharTRideoutSRossJDuncanSYinYWangHHuangH2021 Chemical compositions of edamame genotypes grown in different locations in the US. Frontiers in Sustainable Food Systems 5:22
YuDLordNPolkJDhakalKLiSYinYDuncanSEWangHZhangBHuangH2022 Physical and chemical properties of edamame during bean development and application of spectroscopy-based machine learning methods to predict optimal harvest time. Food Chemistry 368:130799
ZhangQLiYChinKLQiY2017 Vegetable soybean: Seed composition and production research. Italian Journal of Agronomy 12:276-282

Publication Dates

Publication in this collection
04 May 2022
Date of issue
2022

History

Received
07 Jan 2022
Accepted
16 Mar 2022
Published
30 Mar 2022

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[24] KonovskyJLumpkinTAMcClaryD2020 Edamame: the vegetable soybean. In Understanding the Japanese food and agrimarket. CRC Press, Boca Raton, p. 173-181

[25] KumarVRaniABilloreSDChauhanGS2006 Physico-chemical properties of immature pods of Japanese soybean cultivars. International Journal of Food Properties 9:51-59

[26] KumarVRaniAGoyalLPratapDBilloreSDChauhanGS2011 Evaluation of vegetable-type soybean for sucrose, taste-related amino acids, and isoflavones contents. International Journal of Food Properties 14:1142-1151

[27] LiXZhangXZhuLBuYWangXZhangXZhouYWangXGuoNQiuLZhaoJXingH2019 Genome-wide association study of four yield-related traits at the R6 stage in soybean. BMC Genetics 20:1-15

[28] LiXZhouYBuYWangXZhangYGuoNZaoJXingH2021 Genome-wide association analysis for yield-related traits at the R6 stage in a Chinese soybean mini core collection. Genes & Genomics 1:1-16

[29] LinYWuS2021 Vegetable soybean (Glycine max (L.) Merr.) leaf extracts: Functional components and antioxidant and anti‐inflammatory activities. Journal of Food Science 86:2468-2480

[30] MachadoBQVNogueiraAPOHamawakiOTRezendeGFJorgeGLSilveiraICMedeirosIAHamawakiRLHamawakiCDL2017 Phenotypic and genotypic correlations between soybean agronomic traits and path analysis. Genetics and Molecular Research 16:1-11

[31] ManninenHPaakkiMHopiaAFranzénR2015 Measuring the green color of vegetables from digital images using image analysis. LWT-Food Science and Technology 63:1184-1190

[32] MojenaR1977 Hierarchical grouping methods and stopping rules: an evaluation. The Computer Journal 20:359-363

[33] MozzoniLChenP2019 Correlations of yield and quality traits between immature and mature seed stages of edamame soybean. Journal of Crop Improvement 33:67-82

[34] RaoMSSBhagsariASMohamedAI2002 Fresh green seed yield and seed nutritional traits of vegetable soybean genotypes. Crop Science 42:1950-1958

[35] RizzoGBaroniL2018 Soy, soy foods and their role in vegetarian diets. Nutrients 10:1-51

[36] SantosHGJacominePTAnjosLHCOliveiraVALumbrerasJFCoelhoMRCunhaTJF2018 Brazilian soil classification system. Embrapa Solos, Brasília, 303p

[37] SantosJMSPeixotoCPRangelMASCruzTVSilvaRNALedoCAS2013 Desempenho agronômico de genótipos de soja hortaliça cultivados no recôncavo Baiano. Revista Brasileira de Ciências Agrárias 8:2013

[38] SentelhasPCBattistiRCâmaraGMSFariasJRBHampfACNendelC2015 The soybean yield gap in Brazil-magnitude, causes and possible solutions for sustainable production. The Journal of Agricultural Science 153:1394-1411

[39] ShilpashreeNDeviSNManjunathagowdaDCMuddappaAAbdelmohsenSATamamNElansaryHOEl-AbedinTKZAbdelbackiAMMJanhaviV2021 Morphological characterization, variability and diversity among vegetable soybean (Glycine max L.) genotypes. Plants 10:671

[40] SilvaARRegoERPessoaAMSRegoMM2016 Correlation network analysis between phenotypic and genotypic traits of chili pepper. Pesquisa Agropecuária Brasileira 51:372-377

[41] Silva e SouzaRBarbosaPAMYassueRMBornhofenEEspoladorFGNazatoFMVelloNA2020 Combining ability for the improvement of vegetable soybean. Agronomy Journal 112:3535-3548

[42] SinghD1981 The relative importance of characters affecting genetic divergence. The Indian Journal of Genetics and Plant Breeding 14:237-245

[43] TawareSPHalvankarGBRautVMPatilVP1997 Variability, correlation and path analysis in soybean hybrids. Soybean Genetics Newsletter 24:96-98

[44] Vaz BisnetaMDuarteJBMello FilhoOLZitoRKRodriguesJSCarvalho JuniorEMAlvarengaWB2015 Correlação entre componentes de produção em soja como função de tipo de crescimento e densidade de plantas. In Proceedings of the VII congresso brasileiro de soja. Embrapa Soja, Florianópolis, p. 659-661

[45] YokomizoGKDuarteJBVelloNA2000 Phenotypic correlation between seed size and other characteristics in topcrosses of vegetable soybean with grain type. Pesquisa Agropecuária Brasileira 35:2223-2234

[46] YuDLinTSuttonKLordNCarneiroRJinQZhangBKuharTRideoutSRossJDuncanSYinYWangHHuangH2021 Chemical compositions of edamame genotypes grown in different locations in the US. Frontiers in Sustainable Food Systems 5:22

[47] YuDLordNPolkJDhakalKLiSYinYDuncanSEWangHZhangBHuangH2022 Physical and chemical properties of edamame during bean development and application of spectroscopy-based machine learning methods to predict optimal harvest time. Food Chemistry 368:130799

[48] ZhangQLiYChinKLQiY2017 Vegetable soybean: Seed composition and production research. Italian Journal of Agronomy 12:276-282

ID genotype	R₆ stage					R₈ stage
ID genotype	PY (g plant^-1)	HPW (g)	NDR₆ (days)	PWR₆ (mm)	NP	GY (g plot^-1)	HSW (g)	NDM (days)	AV	PHM (cm)
1	140.4	91.9	114.6	9.6	76.0	759.2	15.5	130.3	2.8	133.3
2	172.7	101.6	116.0	10.6	86.1	741.2	16.3	132.5	3.2	112.9
3	173.3	128.2	112.4	10.7	68.0	658.2	19.7	137.4	2.8	86.3
4	178.2	117.9	112.2	10.4	75.8	730.3	19.1	129.7	2.8	83.8
5	124.1	109.7	113.1	11.2	57.2	752.5	17.4	136.3	3.0	89.2
6	141.5	113.2	114.4	11.6	63.0	595.7	19.7	137.1	2.7	88.3
7	156.3	125.2	112.2	10.7	62.0	694.3	19.8	131.8	2.9	92.9
8	138.6	117.4	112.0	10.8	59.0	618.2	19.5	132.5	2.7	82.9
9	169.6	124.3	110.8	10.5	67.5	697.5	19.0	128.7	3.0	89.6
10	167.2	120.4	112.6	10.7	68.2	724.0	20.0	131.4	2.8	89.2
11	120.2	111.9	114.8	10.5	54.5	737.3	20.1	137.1	2.8	91.3
12	132.4	113.7	113.7	10.6	58.1	751.2	20.1	134.1	3.0	93.8
13	192.8	117.2	112.4	10.6	83.6	676.5	19.8	130.8	3.0	102.9
14	140.4	107.9	115.0	10.8	64.6	557.0	15.8	131.1	2.8	87.5
15	141.9	129.8	111.8	11.1	52.7	602.3	23.7	133.9	3.0	89.6
16	148.5	104.4	114.7	10.5	71.3	783.8	19.1	136.6	2.9	96.3
17	143.5	101.3	114.3	10.6	70.6	687.3	18.9	135.0	2.9	91.3
18	142.0	91.0	114.3	9.4	75.0	649.7	14.8	137.8	2.8	89.6
19	125.2	110.6	112.5	10.2	54.1	594.3	20.2	136.3	2.9	86.3
20	136.0	80.9	115.0	9.5	84.6	660.0	14.4	134.8	3.0	89.2
21	111.9	82.3	112.8	9.6	67.1	518.2	14.5	133.0	2.8	83.3
22	154.0	120.9	110.3	10.7	64.0	492.8	21.2	131.0	2.6	72.9
23	114.3	94.4	112.3	10.7	61.7	621.3	18.0	142.0	2.6	74.6
24	161.4	106.1	115.6	10.9	76.8	623.7	19.6	143.2	2.9	79.2
25	149.0	120.0	115.6	11.1	61.7	704.0	15.8	138.3	2.7	99.6
26	157.6	132.7	109.8	10.4	59.4	588.8	16.2	128.4	2.5	112.1
27	185.2	133.9	110.2	10.5	70.2	600.3	16.0	129.3	2.6	110.4
28	160.6	122.4	115.9	12.0	66.3	747.2	20.4	141.1	2.7	87.1
29	143.7	99.2	116.7	11.3	71.5	739.7	17.3	143.9	2.9	95.4
30	136.5	101.8	112.7	10.5	63.5	656.5	15.9	135.8	2.9	75.0
31	129.6	113.7	115.5	11.3	57.3	644.0	17.9	133.8	2.8	82.1
32	119.4	107.5	113.2	10.5	54.3	532.7	15.5	129.8	2.7	73.8
33	140.8	102.8	113.8	10.4	68.4	717.0	16.8	139.9	2.8	90.8
34	169.3	137.2	112.1	11.2	60.1	705.3	21.2	137.1	2.7	89.2
35	144.0	83.0	116.8	9.9	86.1	741.3	15.1	138.8	2.9	97.1
36	198.4	87.6	114.4	9.8	106.5	590.2	15.9	135.4	2.7	86.7
37	132.0	91.6	116.7	9.7	75.8	651.2	13.4	139.7	3.0	91.7
38	141.0	95.9	117.3	10.1	73.6	819.0	15.8	140.3	3.0	114.6
39	127.5	86.5	117.0	10.0	75.2	786.0	14.7	139.1	2.9	102.1
40	138.0	81.9	117.1	9.9	82.0	740.5	14.6	139.7	3.2	96.7
41	166.0	84.0	116.8	9.7	92.3	861.8	14.7	139.9	3.3	106.3
42	198.3	125.1	110.5	10.5	78.1	667.7	19.6	134.0	2.8	90.4
43 (BRS 257)	167.3	113.5	110.3	10.7	71.6	695.1	17.7	136.1	2.9	78.8
44 (BRS 267)	165.3	133.0	111.8	11.4	60.0	811.3	22.8	137.7	3.2	94.8
45 (IAC 100)	146.1	76.3	112.7	9.1	99.0	626.4	10.6	135.6	3.2	81.3