Yasuhiko Endo1. 1. College of Science, Ibaraki University, Bunkyo, Mito, Japan. endoy@mx.ibaraki.ac.jp
Abstract
PREMISE OF THE STUDY: In angiosperm seeds, the developing embryo acquires nutrients via a suspensor that typically undergoes programmed cell death (PCD) at the early cotyledon stage. However, in Leguminosae (the third largest angiosperm family), the suspensors can disappear at the heart-shaped stage (i.e., prior to the cotyledon stage) or still persist at the cotyledon stage. Here, in a comprehensive survey of legume suspensors and embryos, the variation and the evolutionary direction of timing of suspensor PCD in Leguminosae were characterized, and systematic implications were evaluated. METHODS: Suspensor development and morphology for 66 leguminous species from 49 genera, 21 tribes, and 3 subfamilies were comparatively studied using standard paraffin sectioning and light microscopy. KEY RESULTS: Three patterns of suspensor PCD were observed at the early cotyledon stage. (A) The suspensor persisted. (B) The suspensor separated from the wall of the embryo sac and persisted as a vestige at the radicle apex. (C) The suspensor disappeared completely, and the absorption of nutrients by embryo was carried out via a "contact zone" between the embryo and the endosperm. Pattern C of early suspensor PCD was found only in the tribe Fabeae. An ancestral character reconstruction revealed that the long-lived suspensors of pattern A represented a plesiomorphic condition in Leguminosae and that the suspensors of pattern C evolved only once in the common ancestor of Fabeae. CONCLUSIONS: In Leguminosae, short-lived suspensors have thus evolved multiple times from long-lived suspensors. It remains largely unknown, however, how the embryo acquires nutrients after the early suspensor PCD.
PREMISE OF THE STUDY: In angiosperm seeds, the developing embryo acquires nutrients via a suspensor that typically undergoes programmed cell death (PCD) at the early cotyledon stage. However, in Leguminosae (the third largest angiosperm family), the suspensors can disappear at the heart-shaped stage (i.e., prior to the cotyledon stage) or still persist at the cotyledon stage. Here, in a comprehensive survey of legume suspensors and embryos, the variation and the evolutionary direction of timing of suspensor PCD in Leguminosae were characterized, and systematic implications were evaluated. METHODS: Suspensor development and morphology for 66 leguminous species from 49 genera, 21 tribes, and 3 subfamilies were comparatively studied using standard paraffin sectioning and light microscopy. KEY RESULTS: Three patterns of suspensor PCD were observed at the early cotyledon stage. (A) The suspensor persisted. (B) The suspensor separated from the wall of the embryo sac and persisted as a vestige at the radicle apex. (C) The suspensor disappeared completely, and the absorption of nutrients by embryo was carried out via a "contact zone" between the embryo and the endosperm. Pattern C of early suspensor PCD was found only in the tribe Fabeae. An ancestral character reconstruction revealed that the long-lived suspensors of pattern A represented a plesiomorphic condition in Leguminosae and that the suspensors of pattern C evolved only once in the common ancestor of Fabeae. CONCLUSIONS: In Leguminosae, short-lived suspensors have thus evolved multiple times from long-lived suspensors. It remains largely unknown, however, how the embryo acquires nutrients after the early suspensor PCD.