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Erenstein O, Jaleta M, Sonder K, Mottaleb K, Prasanna BM. 2022. Global maize production, consumption and trade: trends and R&D implications. Food Security 14:1295−1319

Mondo VHV, Cicero SM, Dourado-Neto D, Pupim TL, Dias MAN. 2013. Effect of seed vigor on intraspecific competition and grain yield in maize. Agronomy Journal 105:222−228

Albarenque S, Basso B, Davidson O, Maestrini B, Melchiori R. 2023. Plant emergence and maize (Zea mays L.) yield across multiple farmers' fields. Field Crops Research 302:109090

Zhao J, He Y, Zhang H, Wang Z. 2024. Advances in the molecular regulation of seed germination in plants. Seed Biology 3:e006

Fu H, Cao DD, Hu WM, Guan YJ, Fu YY, et al. 2017. Studies on optimum harvest time for hybrid rice seed. Journal of the Science of Food and Agriculture 97:1124−1133

Han D, Hu H, Yang J, Liang X, Ai J, et al. 2022. The ideal harvest time for seed production in maize (Zea mays L.) varieties of different maturity groups. Journal of the Science of Food and Agriculture 102:5867−5874

Siddique AB, Wright D. 2003. Effects of different drying time and temperature on moisture percentage and seed quality (viability and vigour) of pea seeds (Pisum sativum L.). Asian Journal of Plant Sciences 2:978−982

Jittanit W, Srzednicki G, Driscoll R. 2010. Corn, rice, and wheat seed drying by two-stage concept. Drying Technology 28:807−815

Gu RL, Huang R, Jia GY, Yuan ZP, Ren LS, et al. 2019. Effect of mechanical threshing on damage and vigor of maize seed threshed at different moisture contents. Journal of Integrative Agriculture 18:1571−1578

Wang R, Liu L, Guo Y, He X, Lu Q. 2020. Effects of deterioration and mildewing on the quality of wheat seeds with different moisture contents during storage. RSC Advances 10:14581−14594

Li LL, Wang KR, Xie RZ, Ming B, Zhao L, et al. 2017. Corn kernel weight and moisture content after physiological maturity in field. Scientia Agricultura Sinica 50:2052−2060 (in Chinese)

Chu ZD, Ming B, Li LL, Xue J, Zhang WX, et al. 2022. Dynamics of maize grain drying in the high latitude region of Northeast China. Journal of Integrative Agriculture 21:365−374

Liu J, Yu H, Liu Y, Deng S, Liu Q, et al. 2020. Genetic dissection of grain water content and dehydration rate related to mechanical harvest in maize. BMC Plant Biology 20:118

Zhang GP, Marasini M, Li WW, Zhang FL. 2022. Grain filling leads to backflow of surplus water from the maize grain to the cob and plant via the xylem. Frontiers in Plant Science 13:1008896

Sripathy KV, Groot SPC. 2023. Seed development and maturation. In Seed Science and Technology, eds. Dadlani M, Yadava DK. Singapore: Springer Nature Singapore. pp. 17−38 doi: 10.1007/978-981-19-5888-5_2

Gao S, Ming B, Li L, Hou L, Wang K, et al. 2025. Grain water weight dynamics and their relationships with grain filling in maize. European Journal of Agronomy 164:127481

Kang MS, Zuber MS. 1989. Combining ability for grain moisture, husk moisture, and maturity in maize with yellow and white endosperms. Crop Science 29:689−692

Ordás A. 1991. Heterosis in crosses between American and Spanish populations of maize. Crop Science 31:931−935

Purdy JL, Crane PL. 1967. Inheritance of drying rate in “mature” corn (Zea mays L.). Crop Science 7:294−297

Prado SA, Gambín BL, Novoa AD, Foster D, Senior ML, et al. 2013. Correlations between parental inbred lines and derived hybrid performance for grain filling traits in maize. Crop Science 53:1636−1645

Ni P, Anche MT, Ruan Y, Dang D, Morales N, et al. 2022. Genomic prediction strategies for dry-down-related traits in maize. Frontiers in Plant Science 13:930429

Kulembeka HP, Ferguson M, Herselman L, Kanju E, Mkamilo G, et al. 2012. Diallel analysis of field resistance to brown streak disease in cassava (Manihot esculenta Crantz) landraces from Tanzania. Euphytica 187:277−288

Griffing B. 1956. A generalised treatment of the use of diallel crosses, in quantitative inheritance. Heredity 10:31−50

Sprague GF, Tatum LA. 1942. General versus specific combining ability in single crosses of corn. Agronomy Journal 34:923−932

Köhler C, Wolff P, Spillane C. 2012. Epigenetic mechanisms underlying genomic imprinting in plants. Annual Review of Plant Biology 63:331−352

Kermicle JL. 1970. Dependence of the R-mottled aleurone phenotype in maize on mode of sexual transmission. Genetics 66:69−85

Yang J, Liu S, Lin Z, Song N, Dong X, et al. 2025. The role of imprinted gene ZmFIE1 during maize kernel development. The Crop Journal 13:395−405

Danilevskaya ON, Hermon P, Hantke S, Muszynski MG, Kollipara K, et al. 2003. Duplicated fie genes in maize: expression pattern and imprinting suggest distinct functions. The Plant Cell 15:425−438

Raissig MT, Baroux C, Grossniklaus U. 2011. Regulation and flexibility of genomic imprinting during seed development. The Plant Cell 23:16−26

Haun WJ, Laoueillé-Duprat S, O'Connell MJ, Spillane C, Grossniklaus U, et al. 2007. Genomic imprinting, methylation and molecular evolution of maize Enhancer of zeste (Mez) homologs. The Plant Journal 49:325−337

Gutiérrez-Marcos JF, Costa LM, Biderre-Petit C, Khbaya B, O'Sullivan DM, et al. 2004. Maternally expressed gene1 is a novel maize endosperm transfer cell-specific gene with a maternal parent-of-origin pattern of expression. The Plant Cell 16:1288−1301

Li W, Yu Y, Wang L, Luo Y, Peng Y, et al. 2021. The genetic architecture of the dynamic changes in grain moisture in maize. Plant Biotechnology Journal 19:1195−1205

Smolikova G, Leonova T, Vashurina N, Frolov A, Medvedev S. 2020. Desiccation tolerance as the basis of long-term seed viability. International Journal of Molecular Sciences 22:101

Yu Y, Li W, Liu Y, Liu Y, Zhang Q, et al. 2025. A Zea genus-specific micropeptide controls kernel dehydration in maize. Cell 188:44−59.e21

Bolger AM, Lohse M, Usadel B. 2014. Trimmomatic: a flexible trimmer for Illumina sequence data. Bioinformatics 30:2114−2120

Kim D, Langmead B, Salzberg SL. 2015. HISAT: a fast spliced aligner with low memory requirements. Nature Methods 12:357−360

Chen J, Zeng B, Zhang M, Xie S, Wang G, et al. 2014. Dynamic transcriptome landscape of maize embryo and endosperm development. Plant Physiology 166:252−264

Qu J, Xu S, Gou X, Zhang H, Cheng Q, et al. 2023. Time-resolved multiomics analysis of the genetic regulation of maize kernel moisture. The Crop Journal 21:247−257

Huang H, Møller IM, Song SQ. 2012. Proteomics of desiccation tolerance during development and germination of maize embryos. Journal of Proteomics 75:1247−1262

Yu T, Li G, Dong S, Liu P, Zhang J, et al. 2016. Proteomic analysis of maize grain development using iTRAQ reveals temporal programs of diverse metabolic processes. BMC Plant Biology 16:241

Chen L, Wang Z, Li M, Ma X, Tian E, et al. 2018. Analysis of the natural dehydration mechanism during middle and late stages of wheat seeds development by some physiological traits and iTRAQ-based proteomic. Journal of Cereal Science 80:102−110

Zhang H, Gou X, Ma L, Zhang X, Qu J, et al. 2024. Reveal the kernel dehydration mechanisms in maize based on proteomic and metabolomic analysis. BMC Plant Biology 24:15

Grossniklaus U, Spillane C, Page DR, Köhler C. 2001. Genomic imprinting and seed development: endosperm formation with and without sex. Current Opinion in Plant Biology 4:21−27

Huh JH, Bauer MJ, Hsieh TF, Fischer R. 2007. Endosperm gene imprinting and seed development. Current Opinion in Genetics & Development 17:480−485

Luo M, Taylor JM, Spriggs A, Zhang H, Wu X, et al. 2011. A genome-wide survey of imprinted genes in rice seeds reveals imprinting primarily occurs in the endosperm. PLoS Genetics 7:e1002125

Wang X, Clark AG. 2014. Using next-generation RNA sequencing to identify imprinted genes. Heredity 113:156−166

Wyder S, Raissig MT, Grossniklaus U. 2019. Consistent reanalysis of genome-wide imprinting studies in plants using generalized linear models increases concordance across datasets. Scientific Reports 9:1−13

Chen C, Begcy K. 2020. Genome-wide identification of allele-specific gene expression in a parent-of-origin specific manner. In Cereal Genomics, ed. Vaschetto LM. New York, USA: Humana. pp. 129−139 doi: 10.1007/978-1-4939-9865-4_11

Sato H, Köhler C. 2022. Genomic imprinting regulates establishment and release of seed dormancy. Current Opinion in Plant Biology 69:102264

Dong X, Luo H, Bi W, Chen H, Yu S, et al. 2023. Transcriptome-wide identification and characterization of genes exhibit allele-specific imprinting in maize embryo and endosperm. BMC Plant Biology 23:470

Jahnke S, Scholten S. 2009. Epigenetic resetting of a gene imprinted in plant embryos. Current Biology 19:1677−1681

Dong X, Zhang M, Chen J, Peng L, Zhang N, et al. 2017. Dynamic and antagonistic allele-specific epigenetic modifications controlling the expression of imprinted genes in maize endosperm. Molecular Plant 10:442−455

Raas MWD, Zijlmans DW, Vermeulen M, Marks H. 2022. There is another: H3K27me3-mediated genomic imprinting. Trends in Genetics 38:82−96

Xu Q, Wu L, Luo Z, Zhang M, Lai J, et al. 2022. DNA demethylation affects imprinted gene expression in maize endosperm. Genome Biology 23:77

Du X, Xu Z, Lu J, Chen Y, Gao X, et al. 2025. A LTR retrotransposon insertion leads to leafy phenotype in maize by elevating ZmOM66 expression. Nature Communications 16:3152

Abramowitz LK, Bartolomei MS. 2012. Genomic imprinting: recognition and marking of imprinted loci. Current Opinion in Genetics & Development 22:72−78

Zhang Z, Yu S, Li J, Zhu Y, Jiang S, et al. 2021. Epigenetic modifications potentially controlling the allelic expression of imprinted genes in sunflower endosperm. BMC Plant Biology 21:570