St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026
Phosphate mineral weathering by carboxylic acids is driven by functional group composition and orientation July 2, 2026
St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026
Phosphate mineral weathering by carboxylic acids is driven by functional group composition and orientation July 2, 2026
HomePublicationsCSA NewsIssuesCSA News: Volume 66, Issue 11Tracing the evolution and domestication of citrus fruits September 25, 2021 Researchers scrutinizing fruits of pummelo (left) and mandarin (right), two extant species derived from parental, ancestral wild species that through successive hybridization and introgression gave rise to all palatable current citrus. Photos by Ángel García. The ancestral citrus inhabited the foothills of the Himalayas during the late Miocene global cooling about eight million years ago—then, it immediately diversified into a rapid radiation. How the current enormous citrus diversity was achieved is a question that remains unanswered. In contrast to the appealing, seedless, and tasteful fruit of edible citrus, wild pure citrus mandarins, for instance, bear inedible, small, distasteful, acidic, and seedy fruit.A series of two articles in The Plant Genome provide original insights on these questions. The researchers performed comparative genomic analyses on wild and domesticated citrus, showing that the abundance of pectins, terpenoids, and flavonoids characterizing citrus fruit were the result of large expansions of pivotal gene families. Interestingly, domestication removed genes involved in the biogenesis of distasteful compounds and affected genes associated with the regulation of citric acid, increasing palatability. Other key genes were highly conserved in stretches of pure mandarin regions, such as the apomictic reproduction gene that allowed huge dispersion of the edible genotypes.These results support the idea that some genes that naturally evolved in citrus later became potential targets of domestication and that the pervasive adaptive evolution that citrus shows may be in part responsible for the phenotypic differences observed among current species.Dig DeeperGonzalez-Ibeas, D., Ibanez, V., Perez-Roman, E., Borredá, C., Terol, J., & Talon, M. (2021). Shaping the biology of citrus: I. Genomic determinants of evolution. The Plant Genome. https://doi.org/10.1002/tpg2.20104 and Gonzalez-Ibeas, D., Ibanez, V., Perez-Roman, E., Borredá, C., Terol, J., & Talon, M. (2021). Shaping the biology of citrus: II. Genomic determinants of domestication. (2021). The Plant Genome. https://doi.org/10.1002/tpg2.20133 More science articles Back to issue Back to home Text © . The authors. CC BY-NC-ND 4.0. Except where otherwise noted, images are subject to copyright. Any reuse without express permission from the copyright owner is prohibited.Share this:Send Message Related articles St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026 The Drought Resilience Calculator July 7, 2026 Mohanty named Distinguished Professor July 6, 2026 Recent articles St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026 Mohanty named Distinguished Professor July 6, 2026 Phosphate mineral weathering by carboxylic acids is driven by functional group composition and orientation July 2, 2026
St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026
St. Augustinegrass remains resilient under certain irrigation and fertilization restrictions, with or without soil humectants July 7, 2026
Phosphate mineral weathering by carboxylic acids is driven by functional group composition and orientation July 2, 2026