Research Progress on Vegetable Soybean

doi:10.11924/j.issn.1000-6850.casb2025-0165

Abstract

Abstract:

To systematically review the research status and development trends of vegetable soybean, this study retrieved and screened over 100 relevant articles using keywords such as ‘caiyong dadou’, ‘maodou/edamame’, and ‘vegetable soybean’ from Chinese and international databases, including CNKI and Web of Science. The research progress of vegetable soybean has been comprehensively summarized across five core areas: germplasm resources and breeding, omics research, cultivation techniques, nutritional functions, and storage and processing. In terms of variety breeding, a classification system based on growth periods has been established, molecular markers such as SNP and SSR have been developed and preliminarily applied in molecular-assisted breeding, and gene editing technology has enabled targeted modification of specific functional genes. In the field of omics research, the first reference genome of vegetable soybean has been assembled, and GWAS, transcriptomic, and metabolomic analyses have identified a number of key genes and metabolites related to yield, quality, and stress resistance. In cultivation techniques, integrated management strategies involving variety adaptation, environmental regulation, density optimization, and coordinated water-fertilizer management have been formed, while mechanized harvesting remains an industrial bottleneck. Regarding nutritional functions, its food-grade value, such as high protein and folate content, as well as the potential efficacy of medical-grade bioactive components like γ-aminobutyric acid and D-pinitol, have been clarified. In the field of storage and processing, technologies such as low-temperature refrigeration and quick-freezing preservation have achieved industrial application, though the development of high value-added products still requires breakthroughs. The study also identified key challenges in the current field, including the scarcity of excellent and distinctive germplasm, low efficiency in the breeding transformation of omics data, insufficient added value of deep-processed products, and cost-benefit imbalances in preservation technologies. Finally, it is proposed that future efforts should strengthen the deep integration of basic research and industrial demands, leveraging modern biotechnology and information technology to promote the intelligent, green, and high-value upgrading of the vegetable soybean industry, thereby providing theoretical support and technological pathways for ensuring food security, supporting sustainable agricultural development, and enhancing human health.

Key words: vegetable soybean, germplasm resources, omics studies, efficient cultivation, storage, deep processing

ZHANG Wenting, SUN Mingyang, REN Hailong, YUAN Qinghua, SUO Haicui. Research Progress on Vegetable Soybean[J]. Chinese Agricultural Science Bulletin, 2026, 42(3): 80-90.

Figures/Tables 2

References 104

[1]	KEATINGE J D H, EASDOWN W J, YANG R Y, et al. Overcoming chronic malnutrition in a future warming world: the key importance of mungbean and vegetable soybean[J]. Euphytica, 2011, 180(1):129-141. doi: 10.1007/s10681-011-0401-6 URL
[2]	VAITEKHOVICH I, LYUDE A, BOIARSKAIA A, et al. The possibility of introduction and cultivation of vegetable soybean in the Amur region[J]. IOP conference series: earth and environmental science, 2022, 1045(1):012064. doi: 10.1088/1755-1315/1045/1/012064
[3]	ZHANG B, LORD N, KUHAR T, et al. ‘VT Sweet’: a vegetable soybean cultivar for commercial edamame production in the mid-Atlantic USA[J]. Journal of plant registrations, 2022, 16(1):29-33. doi: 10.1002/plr2.v16.1 URL
[4]	ZEIPIŅA S, VÅGEN I M, LEPSE L. Possibility of vegetable soybean cultivation in north Europe[J]. Horticulturae, 2022, 8(7):593. doi: 10.3390/horticulturae8070593 URL
[5]	AHOMONDJI S E, AGOYI E E, AGBANGBA C E, et al. Sensory preference criteria and willingness to adopt vegetable soybean “Edamame” in Benin (West Africa)[J]. Journal of sensory studies, 2023, 38(1):e12797. doi: 10.1111/joss.v38.1 URL
[6]	HUANG Y H, KU H M, WANG C A, et al. A multiple phenotype imputation method for genetic diversity and core collection in Taiwanese vegetable soybean[J]. Frontiers in plant science, 2022, 13(2022):948349. doi: 10.3389/fpls.2022.948349 URL
[7]	SIMONNE A H, WEAVER D B, WEI C I. Immature soybean seeds as a vegetable or snack food: acceptability by American consumers[J]. Innovative food science & emerging technologies, 2000, 1(4):289-296.
[8]	RAO M S S, BHAGSARI A S, MOHAMED A I. Fresh green seed yield and seed nutritional traits of vegetable soybean genotypes[J]. Crop science, 2002, 42(6):1950-1958. doi: 10.2135/cropsci2002.1950 URL
[9]	HOU J, WANG C, HONG X, et al. Association analysis of vegetable soybean quality traits with SSR markers[J]. Plant breeding, 2011, 130(4):444-449. doi: 10.1111/pbr.2011.130.issue-4 URL
[10]	BOWEN R, BARDEAU A, SCHULTZ S, et al. Registration of seven disease- and pest-resistant vegetable soybean germplasm lines[J]. Journal of plant registrations, 2022, 16(2):438-445. doi: 10.1002/plr2.v16.2 URL
[11]	MOSELEY D, MOZZONI L, MANJARREZ-SANDOVAL P, et al. Registration of ‘UA Mulberry’ vegetable soybean cultivar[J]. Journal of plant registrations, 2019, 13(1):28-30. doi: 10.3198/jpr2018.03.0009crc URL
[12]	YOUNG G, MEBRAHTU T, JOHNSON J. Acceptability of green soybeans as a vegetable entity[J]. Plant foods for human nutrition, 2000, 55(4):323-333. doi: 10.1023/a:1008164925103 pmid: 11086875
[13]	MOHAMED A I, MEBRAHTU T, RANGAPPA M. Nutrient composition and anti-nutritional factors in selected vegetable soybean (Glycine max [L.] Merr.)[J]. Plant foods for human nutrition, 1991, 41(1):89-100. doi: 10.1007/BF02196385 URL
[14]	KUMAR V, RANI A, SHUKLA S, et al. Development of Kunitz Trypsin inhibitor free vegetable soybean genotypes through marker-assisted selection[J]. International journal of vegetable science, 2021, 27(4):364-377. doi: 10.1080/19315260.2020.1800886 URL
[15]	FU X J, PEI J X, ZHENG Y T, et al. DNA fingerprinting of vegetable soybean cultivar ‘zhexian No.9’ using 101 new developed HRM-based SNP markers[J]. Legume research, 2019, 43(1):8-17.
[16]	PARDESHI P, JADHAV P, SAKHARE S, et al. Morphological and microsatellite marker-based characterization and diversity analysis of novel vegetable soybean [Glycine max (L.) Merrill][J]. Molecular biology reports, 2023, 50(5):4049-4060. doi: 10.1007/s11033-023-08328-1
[17]	JUWATTANASOMRAN R, SOMTA P, CHANKAEW S, et al. A SNP in GmBADH2 gene associates with fragrance in vegetable soybean variety “Kaori” and SNAP marker development for the fragrance[J]. Theoretical and applied genetics, 2011, 122(3):533-541. doi: 10.1007/s00122-010-1467-6 URL
[18]	ARIKIT S, YOSHIHASHI T, WANCHANA S, et al. A PCR-based marker for a locus conferring aroma in vegetable soybean (Glycine max L.)[J]. Theoretical and applied genetics, 2011, 122(2):311-316. doi: 10.1007/s00122-010-1446-y URL
[19]	BU Y, ZHANG X, WANG C, et al. Conditional and unconditional QTL analyses of seed hardness in vegetable soybean (Glycine max L. Merr.)[J]. Euphytica, 2018, 214(12):237. doi: 10.1007/s10681-018-2308-y
[20]	KAO C F, HE S S, WANG C S, et al. A modified Roger’s distance algorithm for mixed quantitative-qualitative phenotypes to establish a core collection for Taiwanese vegetable soybeans[J]. Frontiers in plant science, 2021, 11(2020):612106. doi: 10.3389/fpls.2020.612106 URL
[21]	SILVA E SOUZA R, BARBOSA P A M, YASSUE R M, et al. Combining ability for the improvement of vegetable soybean[J]. Agronomy journal, 2020, 112(5):3535-3548. doi: 10.1002/agj2.v112.5 URL
[22]	张玉梅, 胡润芳, 林国强. 菜用大豆蔗糖转运蛋白基因Glyma18g15950的克隆及生物信息学分析[J]. 中国农学通报, 2019, 35(23):29-34. doi: 10.11924/j.issn.1000-6850.casb18050022
[23]	冯志娟, 刘娜, 张古文, 等. 菜用大豆蔗糖合酶基因鉴定及表达模式分析[J]. 分子植物育种, 2020, 18(14):4532-4539.
[24]	冯志娟, 刘娜, 张古文, 等. 菜用大豆淀粉合成相关Starch Synthase基因鉴定及其表达温度效应[J]. 分子植物育种, 2020, 18(11):3476-3484.
[25]	FENG Z, LIU N, ZHANG G, et al. Promoter of vegetable soybean GmTIP1;6 responds to diverse abiotic stresses and hormone signals in transgenic Arabidopsis[J]. International journal of molecular sciences, 2022, 23(20):12684. doi: 10.3390/ijms232012684 URL
[26]	冯志娟, 刘娜, 张古文, 等. 干旱和高盐胁迫下菜用大豆GmTIP2;6启动子的功能分析[J]. 分子植物育种, 2022, 20(6):1741-1747.
[27]	DAI D, HUANG L, ZHANG X, et al. Identification and functional analysis of GmPsaL regulating pod color in vegetable soybean[J]. BMC plant biology, 2024, 24(1):925. doi: 10.1186/s12870-024-05643-y
[28]	WANG X X, GAO F, YANG S P, et al. Overexpression of the StP5CS gene promotes nodulation and nitrogen fixation in vegetable soybean under drought stress[J]. Legume research, 2019, 42(5):603-608.
[29]	ZHANG G C, ZHU W L, GAI J Y, et al. Enhanced salt tolerance of transgenic vegetable soybeans resulting from overexpression of a novel Δ1-pyrroline-5-carboxylate synthetase gene from Solanum torvum Swartz[J]. Horticulture, environment, and biotechnology, 2015, 56(1):94-104. doi: 10.1007/s13580-015-0084-3 URL
[30]	高凡, 王夏夏, 朱月林. StP5CS基因过表达增强高温胁迫下菜用大豆结瘤固氮的能力[J]. 河北农业大学学报, 2019, 42(3):51-56. doi: 10.13320/j.cnki.jauh.2019.0055
[31]	CHEN G H, YAN W, YANG L F, et al. Overexpression of StNHX1, a novel vacuolar Na⁺/H⁺ antiporter gene from Solanum torvum, enhances salt tolerance in transgenic vegetable soybean[J]. Horticulture, environment, and biotechnology, 2014, 55(3):213-221. doi: 10.1007/s13580-014-0003-z URL
[32]	YAN W, CHEN G H, YANG L F, et al. Overexpression of the rice phosphate transporter gene OsPT6 enhances tolerance to low phosphorus stress in vegetable soybean[J]. Scientia horticulturae, 2014, 177:71-76. doi: 10.1016/j.scienta.2014.07.037 URL
[33]	刘佳瑞, 张钰, 彭国庆, 等. 基因编辑技术在大豆基因功能鉴定及遗传改良上的应用[J]. 植物遗传资源学报, 2024, 25(6):919-930.
[34]	冯志娟, 刘娜, 张古文, 等. 基于CRISPR/Cas9的菜用大豆GmGBSSⅡ基因编辑载体构建[J/OL]. 分子植物育种, 2022, https://kns.cnki.net/kcms/detail/46.1068.S.20220915.1624.006.html.
[35]	LIU N, NIU Y, ZHANG G, et al. Genome sequencing and population resequencing provide insights into the genetic basis of domestication and diversity of vegetable soybean[J]. Horticulture research, 2022, 9(1):uhab052.
[36]	YU X, FU X, YANG Q, et al. Genome-wide variation analysis of four vegetable soybean cultivars based on re-sequencing[J]. Plants, 2022, 11(1):28. doi: 10.3390/plants11010028 URL
[37]	XU W, LIU H, LI S, et al. GWAS and identification of candidate genes associated with seed soluble sugar content in vegetable soybean[J]. Agronomy, 2022, 12(6):1470. doi: 10.3390/agronomy12061470 URL
[38]	LU W, SUI M, ZHAO X, et al. Genome-wide identification of candidate genes underlying soluble sugar content in vegetable soybean (Glycine max L.) via association and expression analysis[J]. Frontiers in plant science, 2022,13(2022):930639.
[39]	MOSELEY D, MOZZONI L, KALER A, et al. Evaluation of genetic diversity and association mapping for seed weight and size in vegetable soybean germplasm[J]. Crop science, 2021, 61(5):3516-3528. doi: 10.1002/csc2.v61.5 URL
[40]	LI X, ZHOU Y, BU Y, et al. Genome-wide association analysis for yield-related traits at the R6 stage in a Chinese soybean mini core collection[J]. Genes & genomics, 2021, 43(8):897-912.
[41]	LI X, ZHANG X, ZHU L, et al. Genome-wide association study of four yield-related traits at the R6 stage in soybean[J]. BMC genetics, 2019, 20(1):39. doi: 10.1186/s12863-019-0737-9 pmid: 30922237
[42]	ZHANG X, ZHAO J, BU Y, et al. Genome-wide association studies of soybean seed hardness in the Chinese mini core collection[J]. Plant molecular biology reporter, 2018, 36(4):605-617. doi: 10.1007/s11105-018-1102-2
[43]	GAO H, WU G, WU F, et al. Genome-wide association analysis of yield-related traits and candidate genes in vegetable soybean[J]. Plants (Basel), 2024, 13(11):1442.
[44]	刘慧, 许文静, 杨硕, 等. 菜用大豆有机酸的全基因组关联分析[J]. 华北农学报, 2023, 38(4):74-82. doi: 10.7668/hbnxb.20194140
[45]	黎松松. 基于全基因组关联分析发掘菜用大豆种子萌发候选基因GmAOC4及其功能验证[D]. 南京: 南京农业大学, 2022.
[46]	WANG X, ZHANG C, YUAN R, et al. Transcriptome profiling uncovers differentially expressed genes linked to nutritional quality in vegetable soybean[J]. Plos one, 2024, 19(11):e0313632.
[47]	WANG C, LIN J, BU Y, et al. Genome-wide transcriptome analysis reveals key regulatory networks and genes involved in the determination of seed hardness in vegetable soybean[J]. Horticulture research, 2024, 11(5):uhae084.
[48]	WANG B, BU Y, ZHANG G, et al. Comparative transcriptome analysis of vegetable soybean grain discloses genes essential for grain quality[J]. BMC plant biology, 2024, 24(1):491. doi: 10.1186/s12870-024-05214-1 pmid: 38825702
[49]	LIU C, TU B, WANG X, et al. Transcript profile in vegetable soybean roots reveals potential gene patterns regulating K uptake efficiency[J]. Agronomy, 2020, 10(11):1796. doi: 10.3390/agronomy10111796 URL
[50]	XU S, LIU N, MAO W, et al. Identification of chilling-responsive microRNAs and their targets in vegetable soybean (Glycine max L.)[J]. Scientific reports, 2016, 6(1):26619. doi: 10.1038/srep26619
[51]	ZHAO M, QIAN L, CHI Z, et al. Combined metabolomic and quantitative RT-PCR analyses revealed the synthetic differences of 2-acetyl-1-pyrroline in aromatic and non-aromatic vegetable soybeans[J]. International journal of molecular sciences, 2022, 23(23):14529. doi: 10.3390/ijms232314529 URL
[52]	WU M L, CHOU K L, WU C R, et al. Characterization and the possible formation mechanism of 2-acetyl-1-pyrroline in aromatic vegetable soybean (Glycine max L.)[J]. Journal of food science, 2009, 74(5):S192-S197.
[53]	LIU C, WANG X, TU B, et al. Root K affinity drivers and photosynthetic characteristics in response to low potassium stress in K high-efficiency vegetable soybean[J]. Frontiers in plant science, 2021, 12(2021):732164. doi: 10.3389/fpls.2021.732164 URL
[54]	LIU C, TU B, WANG X, et al. Potassium translocation combined with specific root uptake is responsible for the high potassium efficiency in vegetable soybean[J]. Crop and pasture science, 2019, 70(6):516-525. doi: 10.1071/CP19042 URL
[55]	LIU C, WANG X, TU B, et al. Dry matter partitioning and K distribution of vegetable soybean genotypes with higher potassium efficiency[J]. Archives of agronomy and soil science, 2020, 66(5):717-729. doi: 10.1080/03650340.2019.1638508 URL
[56]	KRAEMER M E, MEBRAHTU T, RANGAPPA M. Evaluation of vegetable soybean genotypes for resistance to Mexican bean beetle (Coleoptera: Coccinellidae)[J]. Journal of economic entomology, 1994, 87(1):252-257. doi: 10.1093/jee/87.1.252 URL
[57]	KRAEMER M E, RANGAPPA M, MOHAMED A I. Evaluation of vegetable soybean genotypes for resistance to corn earworm (Lepidoptera: Noctuidae)[J]. Journal of entomological science, 1997, 32(1):25-36. doi: 10.18474/0749-8004-32.1.25 URL
[58]	KRAEMER M E. Insect resistance in vegetable and Tofu soybeans1[J]. Journal of entomological science, 2001, 36(1):57-66. doi: 10.18474/0749-8004-36.1.57 URL
[59]	HIROTA T, YOSHIDA S, SAWADA T, et al. Starch properties affecting maltose production ability in vegetable black soybean seeds (Edamame) with different maturation periods[J]. The horticulture journal, 2018, 87(2):236-249. doi: 10.2503/hortj.OKD-121 URL
[60]	CASAS-LEAL N E, PEREIRA F A C, ROCHA G A D F, et al. Impact of Asian soybean rust on vegetable soybean, considering two stages of development[J]. Agronomy journal, 2023, 115(1):123-134. doi: 10.1002/agj2.v115.1 URL
[61]	CHEN L S, CHU C, LIU C D, et al. PCR-based detection and differentiation of anthracnose pathogens, Colletotrichum gloeosporioides and C. truncatum, from vegetable soybean in Taiwan[J]. Journal of phytopathology, 2006, 154(11-12):654-662. doi: 10.1111/jph.2006.154.issue-11-12 URL
[62]	涂勇, 姚昕. 西昌地区菜用大豆开花结荚期主要真菌病害种类调查[J]. 西昌学院学报(自然科学版), 2012, 26(3):13-15.
[63]	JOSHI J M, JAVAID I, DADSON R B, et al. Antibiosis to corn earworm [Helicoverpa zea (Boddie)] by vegetable soybean cultivars[J]. Journal of agronomy and crop science, 1992, 169(5):354-357. doi: 10.1111/jac.1992.169.issue-5 URL
[64]	PORNPROM T, SUKCHAROENVIPHARAT W, SANSIRIPHUN D. Weed control with pre-emergence herbicides in vegetable soybean (Glycine max L. Merrill)[J]. Crop protection, 2010, 29(7):684-690. doi: 10.1016/j.cropro.2010.02.003 URL
[65]	WILLIAMS M M, MOODY J L, HAUSMAN N E. Vegetable soybean tolerance to flumioxazin-based treatments for waterhemp control is similar to grain-type soybean[J]. Weed technology, 2019, 33(3):530-534. doi: 10.1017/wet.2019.15 URL
[66]	MOLLA A H, SHAMSUDDIN Z H, SAUD H M. Mechanism of root growth and promotion of nodulation in vegetable soybean by Azospirillum Brasilense[J]. Communications in soil science and plant analysis, 2001, 32(13-14):2177-2187. doi: 10.1081/CSS-120000276 URL
[67]	MINAKATA C, WASAI-HARA S, FUJIOKA S, et al. Unique Rhizobial communities dominated by Bradyrhizobium liaoningens and Bradyrhizobium ottawaense were found in vegetable soybean nodules in Osaka Prefecture, Japan[J]. Microbes and environments, 2023, 38(2):ME22081.
[68]	LIU Q, KE X, YOSHIDA H, et al. Optimizing photosynthetic photon flux density and light quality for maximizing space use efficacy in edamame at the vegetative growth stage[J]. Frontiers in sustainable food systems, 2024, 8:1407359. doi: 10.3389/fsufs.2024.1407359 URL
[69]	MOOKHERJI S, FLOYD M. The effect of aluminium on growth of and nitrogen fixation in vegetable soybean germplasm[J]. Plant and soil, 1991, 136(1):25-29. doi: 10.1007/BF02465216 URL
[70]	ZHANG G W, XU S C, HU Q Z, et al. Putrescine plays a positive role in salt-tolerance mechanisms by reducing oxidative damage in roots of vegetable soybean[J]. Journal of integrative agriculture, 2014, 13(2):349-357. doi: 10.1016/S2095-3119(13)60405-0 URL
[71]	WILLIAMS M M, NELSON R L. Vegetable soybean tolerance to bentazon, fomesafen, imazamox, linuron, and sulfentrazone[J]. Weed technology, 2014, 28(4):601-607. doi: 10.1614/WT-D-14-00019.1 URL
[72]	王伟, 丁桔, 丁峰, 等. 不同施肥水平和种植密度对‘浙鲜9号’菜用大豆产量和主要农艺性状的影响[J]. 中国农学通报, 2016, 32(3):43-47. doi: 10.11924/j.issn.1000-6850.casb15080107
[73]	CARPENTER D, PANTALONE V, ALLEN F, et al. Edamame vegetable soybean production in tennessee[J]. Horticultural science, 2006, 41(3):504B-504.
[74]	喻惟, 晏春云. 万载县早稻与秋毛豆水旱轮作栽培技术[J]. 南方农业, 2022, 16(20):43-45.
[75]	肖光辉, 曾晓娟. 辣椒与豆科蔬菜、早稻、荸荠轮作有机栽培技术[J]. 中国瓜菜, 2021, 34(7):104-107.
[76]	NONTHAPA A, IWAI C B, CHANKAEW S, et al. Dual-purpose vermicompost for the growth promotion and suppression of damping-off disease on potted vegetable soybean[J]. Plants, 2024, 13(12):1607. doi: 10.3390/plants13121607 URL
[77]	TU B, LIU C, TIAN B, et al. Reduced abscisic acid content is responsible for enhanced sucrose accumulation by potassium nutrition in vegetable soybean seeds[J]. Journal of plant research, 2017, 130(3):551-558. doi: 10.1007/s10265-017-0912-x pmid: 28247062
[78]	LIU C, WANG X, CHEN H, et al. Nutritional quality of different potassium efficiency types of vegetable soybean as affected by potassium nutrition[J]. Food quality and safety, 2022, 6(2022):fyab039.
[79]	MATSUMURA A, SANO S, UEDA Y, et al. Variabilities in agronomic traits and their relationship with soil properties of vegetable soybean cultivated under greenhouse conditions in the Nakakawachi region, Osaka, Japan[J]. The horticulture journal, 2022, 91(3):356-365. doi: 10.2503/hortj.UTD-353 URL
[80]	BHATTARAI S P, HUBER S, MIDMORE D J. Aerated subsurface irrigation water gives growth and yield benefits to zucchini, vegetable soybean and cotton in heavy clay soils[J]. Annals of applied biology, 2004, 144(3):285-298. doi: 10.1111/aab.2004.144.issue-3 URL
[81]	BHATTARAI S P, MIDMORE D J. Oxygation enhances growth, gas exchange and salt tolerance of vegetable soybean and cotton in a saline vertisol[J]. Journal of integrative plant biology, 2009, 51(7):675-688. doi: 10.1111/j.1744-7909.2009.00837.x
[82]	陈四维, 钟文娟, 廖蕤, 等. 四川菜用大豆产业发展现状及对策[J]. 中国种业, 2024(11):8-13.
[83]	刘志远, 金诚谦, 冯玉岗, 等. 菜用大豆收获机械化发展现状[J]. 中国农机化学报, 2021, 42(5):228-236. doi: 10.13733/j.jcam.issn.2095-5553.2021.05.32
[84]	SONKAMBLE P, NANDANWAR R S, SAKHARE S B, et al. Assessment of grain and vegetable type soybean genotypes for nutritional composition[J]. International journal of chemical studies, 2020, 8(5):619-621.
[85]	EBERT A W, CHANG C H, YAN M R, et al. Nutritional composition of mungbean and soybean sprouts compared to their adult growth stage[J]. Food chemistry, 2017, 237:15-22. doi: S0308-8146(17)30865-8 pmid: 28763980
[86]	AGYENIM-BOATENG K G, ZHANG S, ZHANG S, et al. The nutritional composition of the vegetable soybean (maodou) and its potential in combatting malnutrition[J]. Frontiers in nutrition, 2023, 9(2022):1034115. doi: 10.3389/fnut.2022.1034115 URL
[87]	MEBRAHTU T. Analysis of nutritional contents in vegetable soybeans[J]. Journal of crop improvement, 2008, 21(2):157-170. doi: 10.1080/15427520701885675 URL
[88]	GUO L, HUANG L, CHENG X, et al. Volatile flavor profile and sensory properties of vegetable soybean[J]. Molecules, 2022, 27(3):939. doi: 10.3390/molecules27030939 URL
[89]	WU S J, CHANG C Y, LAI Y T, et al. Increasing γ-aminobutyric acid content in vegetable soybeans via high-pressure processing and efficacy of their antidepressant-like activity in mice[J]. Foods, 2020, 9(11):1673. doi: 10.3390/foods9111673 URL
[90]	SHIU M S, SHYU Y T, WU S J. Flooding stress and high-pressure treatment enhance the GABA content of the vegetable soybean (Glycine max Merr.)[J]. Agriculture, 2020, 10(5):175. doi: 10.3390/agriculture10050175 URL
[91]	TAKAHASHI Y, SASANUMA T, ABE T. Accumulation of gamma-aminobutyrate (GABA) caused by heat-drying and expression of related genes in immature vegetable soybean (edamame)[J]. Breeding science, 2013, 63(2):205-210. doi: 10.1270/jsbbs.63.205 pmid: 23853515
[92]	CHEN J, ZHANG H, CHEN Y, et al. Optimization of d-pinitol extraction from vegetable soybean leaves and its potential application in control of cucumber powdery mildew[J]. Crop protection, 2014, 60:20-27. doi: 10.1016/j.cropro.2014.01.010 URL
[93]	WANG T, ZHAO J, LI X, et al. New alkaloids from green vegetable soybeans and their inhibitory activities on the proliferation of concanavalin a-activated lymphocytes[J]. Journal of agricultural and food chemistry, 2016, 64(8):1649-1656. doi: 10.1021/acs.jafc.5b06107 pmid: 26885886
[94]	KUMAR V, RANI A, GOYAL L, et al. Assessment of antioxidant constituents and anti-oxidative properties of vegetable soybean[J]. International journal of food properties, 2014, 17(3):536-544. doi: 10.1080/10942912.2012.654559 URL
[95]	LIN Y, WU S. Vegetable soybean (Glycine max (L.) Merr.) leaf extracts: functional components and antioxidant and anti-inflammatory activities[J]. Journal of food science, 2021, 86(6):2468-2480. doi: 10.1111/jfds.v86.6 URL
[96]	TONG Y, ZHAO L, TANG J. Research progress on preservation and processing of fresh soya beans[J]. Science and technology of food industry, 2018, 39(21):337-341.
[97]	THAKUR A K, PAN R S, SINGH I S, et al. Influence of blanching and frozen storage on quality characteristics of vegetable soybean (Glycine max)[J]. The Indian journal of agricultural sciences, 2022, 92(4):480-484. doi: 10.56093/ijas.v92i4.123973 URL
[98]	SALDIVAR X, WANG Y J, CHEN P, et al. Effects of blanching and storage conditions on soluble sugar contents in vegetable soybean[J]. LWT - Food science and technology, 2010, 43(9):1368-1372. doi: 10.1016/j.lwt.2010.04.017 URL
[99]	SONG J, WU G, LIU C, et al. Effect of exogenous spermine on chilling injury and antioxidant defense system of immature vegetable soybean during cold storage[J]. Journal of food science and technology, 2018, 55(10):4297-4303. doi: 10.1007/s13197-018-3372-y pmid: 30228428
[100]	MAKINO Y, NISHIZAKA A, YOSHIMURA M, et al. Influence of low O₂ and high CO₂ environment on changes in metabolite concentrations in harvested vegetable soybeans[J]. Food chemistry, 2020, 317:126380. doi: 10.1016/j.foodchem.2020.126380 URL
[101]	LARA L M, WILSON S A, CHEN P, et al. The effects of infrared treatment on physicochemical characteristics of vegetable soybean[J]. Heliyon, 2019, 5(1):e01148. doi: 10.1016/j.heliyon.2019.e01148 URL
[102]	KUMAR V, CHAUHAN G S, RANI A, et al. Effect of boiling treatments on biochemical constituents of vegetable-type soybean[J]. Journal of food processing and preservation, 2012, 36(5):393-400. doi: 10.1111/jfpp.2012.36.issue-5 URL
[103]	XU Y, BARBARO J, REESE F, et al. Physicochemical, functional and microstructural characteristics of vegetable soybean (Glycine max) as affected by variety and cooking process[J]. Journal of food measurement and characterization, 2015, 9(3):471-478. doi: 10.1007/s11694-015-9255-2 URL
[104]	PAO S, ETTINGER M R, KHALID M F, et al. Microbiological quality of frozen “edamame” (vegetable soybean)[J]. Journal of food safety, 2008, 28(2):300-313. doi: 10.1111/jfs.2008.28.issue-2 URL

地域	系列名	育成单位	品种名	审定编号	品种来源	两年平均鲜荚/(t/hm²)	生育期/d
浙江	浙农	浙江省农业科学院蔬菜研究所	浙农20号	浙审豆2023002	浙农8号/浙农6号	12.6	79.4
	浙鲜	浙江省农业科学院作物与核技术利用研究所	浙鲜18	浙审豆2019002	品系39002/极早1号	9.9	77.7
	浙鲜	浙江省农业科学院作物与核技术利用研究所	浙鲜18	国审豆20220050	品系39002/极早1号	12.7	84.0
	衢鲜	衢州市农业科学研究院、南京农业大学	衢鲜11号	浙审豆2022003	南农10-1/南农99-10	11.6	78.2
江苏	苏成	江苏省农业科学院经济作物研究所	苏成6号	苏审豆20230002	台湾75/日本青	10.8	85.5
	苏早	江苏省农业科学院经济作物研究所	苏早1号	苏审豆200301	不详	11.1	94.0
	苏奎	江苏省农业科学院蔬菜研究所	苏奎2号	苏审豆201601	0118-1-1-2/辽鲜1号	11.3	101.0
	苏鲜豆	南京农业大学	苏鲜豆23	苏审豆20180011	南农X54001/南农X6530	11.9	89.9
	淮鲜豆	江苏徐淮地区淮阴农业科学研究所	淮鲜豆12	苏审豆20230005	南农95C-13/Century	11.9	85.7
	南农	南京农业大学	南农413	苏审豆20190011	新六青/南农95C－13	12.1	84.2
	南农	南京农业大学	南农413	国审豆20200043	新六青/南农95C－13	11.6	87.0
	通豆	江苏沿江地区农业科学研究所	通豆2006	国审豆2009025	南农86-4/南农大黄豆	12.2	100.0
上海	交大	上海交通大学	交大31	沪审豆2021001	晋豆39/台湾88	14.7	84.9
上海	青酥	上海市农业科学院联合地方种业公司	青酥八号	沪审豆2018002	青酥二号/黄牛踏扁	26.0	105.0
江西	赣鲜	江西省农业科学院作物研究所	赣鲜2号	国审豆20210068	南农大黄豆/南农95C-5//南农07C-1	11.9	84.0
湖北	中鲜	中国农业科学院油料作物研究所	中鲜豆2号	鄂审豆20200011	苏早3号/H105	13.4	85.7
湖北	冈鲜	黄冈市农业科学院	冈鲜豆1号	鄂审豆20210002	浙农6号/沈鲜3号	13.1	82.0
山西	晋科	山西省农业科学院作物科学研究所	晋科2号	晋审豆20170008	晋遗38/忻毛豆1号	17.3	108.0
		山西省农业科学院作物科学研究所	晋科2号	国审豆20220048	晋遗38/忻毛豆1号	13.6	93.0
		山西农业大学农学院	晋科23号	晋审豆20230008	诱处4号/晋豆(鲜食)39号	20.9	101.0
福建	闽豆	福建省农业科学院作物研究所	闽豆10号	闽审豆20210001	抚鲜5号/K丰72-2	11.4	80.3
辽宁	辽鲜	辽宁省农业科学院作物研究所	辽鲜豆2号	辽审豆2014016	99011-6/辽鲜1号	13.7	99.0
	铁鲜	铁岭市农业科学院	铁鲜3号	辽审豆2017022	辽鲜1号/铁00003-3	13.1	-
	抚鲜	抚顺市农业科学研究院	抚鲜3号	国审豆2007021	台75变异株系选育	12.0	88.0
	奎鲜	铁岭市维奎大豆科学研究所	奎鲜12号	鄂审豆20230002	奎鲜4号/HY-48	14.8	85.3
河北	廊鲜	廊坊市农林科学院	廊鲜豆2号	冀审豆20239008	铁豆49/L1255	11.3	85.0
四川	成鲜	四川省农业科学院作物研究所	成鲜8号	川审豆20213002	铁系087/四粒黄	15.5	85.2
重庆	渝鲜	重庆市农业科学院	渝鲜豆4号	渝审豆20230002	大粒黄	12.85	78.9
重庆	万鲜	重庆三峡农业科学院、浙江省农业科学院作物与核技术利用研究所	万鲜2号	渝审豆20220006	浙鲜豆5号/毛豆3号	11.8	80.0
湖南	湘鲜	湖南省作物研究所	湘鲜春豆1号	湘审豆20210004	AG381/黑五叶	11.6	93.0
湖南	湘鲜	湖南省作物研究所	湘鲜秋豆1号	湘审豆20220005	AG381/黑五叶	10.6	76.0

地域	系列名	育成单位	品种名	审定编号	品种来源	两年平均鲜荚/(t/hm²)	生育期/d
浙江	浙农	浙江省农业科学院蔬菜研究所	浙农20号	浙审豆2023002	浙农8号/浙农6号	12.6	79.4
	浙鲜	浙江省农业科学院作物与核技术利用研究所	浙鲜18	浙审豆2019002	品系39002/极早1号	9.9	77.7
	浙鲜	浙江省农业科学院作物与核技术利用研究所	浙鲜18	国审豆20220050	品系39002/极早1号	12.7	84.0
	衢鲜	衢州市农业科学研究院、南京农业大学	衢鲜11号	浙审豆2022003	南农10-1/南农99-10	11.6	78.2
江苏	苏成	江苏省农业科学院经济作物研究所	苏成6号	苏审豆20230002	台湾75/日本青	10.8	85.5
	苏早	江苏省农业科学院经济作物研究所	苏早1号	苏审豆200301	不详	11.1	94.0
	苏奎	江苏省农业科学院蔬菜研究所	苏奎2号	苏审豆201601	0118-1-1-2/辽鲜1号	11.3	101.0
	苏鲜豆	南京农业大学	苏鲜豆23	苏审豆20180011	南农X54001/南农X6530	11.9	89.9
	淮鲜豆	江苏徐淮地区淮阴农业科学研究所	淮鲜豆12	苏审豆20230005	南农95C-13/Century	11.9	85.7
	南农	南京农业大学	南农413	苏审豆20190011	新六青/南农95C－13	12.1	84.2
	南农	南京农业大学	南农413	国审豆20200043	新六青/南农95C－13	11.6	87.0
	通豆	江苏沿江地区农业科学研究所	通豆2006	国审豆2009025	南农86-4/南农大黄豆	12.2	100.0
上海	交大	上海交通大学	交大31	沪审豆2021001	晋豆39/台湾88	14.7	84.9
上海	青酥	上海市农业科学院联合地方种业公司	青酥八号	沪审豆2018002	青酥二号/黄牛踏扁	26.0	105.0
江西	赣鲜	江西省农业科学院作物研究所	赣鲜2号	国审豆20210068	南农大黄豆/南农95C-5//南农07C-1	11.9	84.0
湖北	中鲜	中国农业科学院油料作物研究所	中鲜豆2号	鄂审豆20200011	苏早3号/H105	13.4	85.7
湖北	冈鲜	黄冈市农业科学院	冈鲜豆1号	鄂审豆20210002	浙农6号/沈鲜3号	13.1	82.0
山西	晋科	山西省农业科学院作物科学研究所	晋科2号	晋审豆20170008	晋遗38/忻毛豆1号	17.3	108.0
		山西省农业科学院作物科学研究所	晋科2号	国审豆20220048	晋遗38/忻毛豆1号	13.6	93.0
		山西农业大学农学院	晋科23号	晋审豆20230008	诱处4号/晋豆(鲜食)39号	20.9	101.0
福建	闽豆	福建省农业科学院作物研究所	闽豆10号	闽审豆20210001	抚鲜5号/K丰72-2	11.4	80.3
辽宁	辽鲜	辽宁省农业科学院作物研究所	辽鲜豆2号	辽审豆2014016	99011-6/辽鲜1号	13.7	99.0
	铁鲜	铁岭市农业科学院	铁鲜3号	辽审豆2017022	辽鲜1号/铁00003-3	13.1	-
	抚鲜	抚顺市农业科学研究院	抚鲜3号	国审豆2007021	台75变异株系选育	12.0	88.0
	奎鲜	铁岭市维奎大豆科学研究所	奎鲜12号	鄂审豆20230002	奎鲜4号/HY-48	14.8	85.3
河北	廊鲜	廊坊市农林科学院	廊鲜豆2号	冀审豆20239008	铁豆49/L1255	11.3	85.0
四川	成鲜	四川省农业科学院作物研究所	成鲜8号	川审豆20213002	铁系087/四粒黄	15.5	85.2
重庆	渝鲜	重庆市农业科学院	渝鲜豆4号	渝审豆20230002	大粒黄	12.85	78.9
重庆	万鲜	重庆三峡农业科学院、浙江省农业科学院作物与核技术利用研究所	万鲜2号	渝审豆20220006	浙鲜豆5号/毛豆3号	11.8	80.0
湖南	湘鲜	湖南省作物研究所	湘鲜春豆1号	湘审豆20210004	AG381/黑五叶	11.6	93.0
湖南	湘鲜	湖南省作物研究所	湘鲜秋豆1号	湘审豆20220005	AG381/黑五叶	10.6	76.0

参考基因组	群体大小	种植地	种植时间（年）	关注表型	参考文献
Wm82.a2.v1	52 份地方种和212份改良栽培种	南宁	2019 2020	总可溶性糖	[37]
Wm82.a2.v1	278份大豆种质资源	哈尔滨、公主岭、沈阳	2019	可溶性糖	[38]
Wm82.a1	343份	阿肯色州费耶特维尔农业研究与推广中心(FAY)和阿肯色州斯图加特水稻研究与推广中心(STU)	2014 2015	种子重量、种子体积、种子长度、种子宽度、种子高度	[39]
Wm82.a1.v1.1	196 份地方种和 28份栽培种	江浦	2015 2016	R6阶段的百荚鲜重(PFW)、百粒鲜重(SFW)、出仁率(KP) 和鲜籽水分含量(MCFS)	[40]
Wm82.a2.v1	大豆核心种质集中的133份地方种	江浦	2015 2016	R6阶段百荚鲜重(PFW)、百粒鲜重(SFW)、百粒干重(SDW)和鲜籽水分含量(MCFS)	[41]
Williams 82	28 份现代栽培种和188份地方种	南京	2011 to 2014	种子硬度	[42]
Wm82. a2. v1	44份地方种和 144份改良栽培种	崖州湾	2021 2022	R6阶段株高、荚长、荚数、荚厚、荚宽和鲜荚重	[43]
Williams 82	212份栽培种及 52份地方种	南京	2020 2021	有机酸（酒石酸、苹果酸、柠檬酸）	[44]
Williams 82	264份菜用大豆种质资源	南京	2019 2020	种子萌发率	[45]

参考基因组	群体大小	种植地	种植时间（年）	关注表型	参考文献
Wm82.a2.v1	52 份地方种和212份改良栽培种	南宁	2019 2020	总可溶性糖	[37]
Wm82.a2.v1	278份大豆种质资源	哈尔滨、公主岭、沈阳	2019	可溶性糖	[38]
Wm82.a1	343份	阿肯色州费耶特维尔农业研究与推广中心(FAY)和阿肯色州斯图加特水稻研究与推广中心(STU)	2014 2015	种子重量、种子体积、种子长度、种子宽度、种子高度	[39]
Wm82.a1.v1.1	196 份地方种和 28份栽培种	江浦	2015 2016	R6阶段的百荚鲜重(PFW)、百粒鲜重(SFW)、出仁率(KP) 和鲜籽水分含量(MCFS)	[40]
Wm82.a2.v1	大豆核心种质集中的133份地方种	江浦	2015 2016	R6阶段百荚鲜重(PFW)、百粒鲜重(SFW)、百粒干重(SDW)和鲜籽水分含量(MCFS)	[41]
Williams 82	28 份现代栽培种和188份地方种	南京	2011 to 2014	种子硬度	[42]
Wm82. a2. v1	44份地方种和 144份改良栽培种	崖州湾	2021 2022	R6阶段株高、荚长、荚数、荚厚、荚宽和鲜荚重	[43]
Williams 82	212份栽培种及 52份地方种	南京	2020 2021	有机酸（酒石酸、苹果酸、柠檬酸）	[44]
Williams 82	264份菜用大豆种质资源	南京	2019 2020	种子萌发率	[45]