Embryogenesis in Angiosperms: Development of the Suspensor.

Yeung, Edward C.; Meinke, David W.

doi:10.1105/tpc.5.10.1371

Cited by 225 publications

(153 citation statements)

References 31 publications

(35 reference statements)

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“…After fertilization, the zygote divides asymmetrically, giving rise to a small apical cell that develops into the embryo proper and a large basal cell that forms the suspensor. The suspensor is a terminally differentiated structure that supports and nourishes the embryo proper and degenerates later in development (Yeung and Meinke, 1993). The embryo proper, on the other hand, represents the new sporophytic generation and contains the shoot and root meristems that are responsible for generating organ systems of the mature plant after seed germination ( Fig.…”

mentioning

confidence: 99%

Using Genomics to Study Legume Seed Development

Wagmaister²,

Kawashima³

et al. 2007

Plant Physiology

148

157

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mentioning

confidence: 99%

Using Genomics to Study Legume Seed Development

Wagmaister²,

Kawashima³

et al. 2007

Plant Physiology

148

157

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“…Twin and other embryo-defective suspensor mutants delay their autolysis program and replace it with a more embryo-like program (Yeung and Meinke, 1993). Hence the presence of a normally developing embryo proper apparently restricts growth of the suspensor and may provide the signal(s) for the induction of the cell death pathway in suspensors.…”

Section: Degeneration Of the Suspensormentioning

confidence: 99%

“…Arrested embryo growth or destruction of embryos often results in abnormally vigorous growth of suspensors (Yeung and Meinke, 1993, and references therein), including, in the embryo-defective mutant of Arabidopsis, twin, the growth of a second embryo from transformed cells within the suspensor (Vernon and Meinke, 1994). Twin and other embryo-defective suspensor mutants delay their autolysis program and replace it with a more embryo-like program (Yeung and Meinke, 1993).…”

Section: Degeneration Of the Suspensormentioning

confidence: 99%

Programmed cell death during plant growth and development

Beers

1997

Cell Death Differ

147

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This review describes programmed cell death as it signifies the terminal differentiation of cells in anthers, xylem, the suspensor and senescing leaves and petals. Also described are cell suicide programs initiated by stress (e.g., hypoxiainduced aerenchyma formation) and those that depend on communication between neighboring cells, as observed for incompatible pollen tubes, the suspensor and synergids in some species. Although certain elements of apoptosis are detectable during some plant programmed cell death processes, the participation of autolytic and perhaps autophagic mechanisms of cell killing during aerenchyma formation, tracheary element differentiation, suspensor degeneration and senescence support the conclusion that nonapoptotic programmed cell death pathways are essential to normal plant growth and development. Heterophagic elimination of dead cells, a prominent feature of animal apoptosis, is not evident in plants. Rather autolysis and autophagy appear to govern the elimination of cells during plant cell suicide.

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“…[10][11][12] Through horizontal division of the basal cell, the filamentous suspensor contains an enlarged bottom cell, which is attached to maternal tissues, and a single row of 6 to 8 additional cells. 13 The suspensor becomes highly differentiated early in development and then degenerates during the subsequent cotyledon stage of embryogenesis. 12,13 The suspensor plays an important role in embryo development; it transfers nutrients and growth factors to the embryo proper and biosynthesizes plant hormones.…”

mentioning

confidence: 99%

“…13 The suspensor becomes highly differentiated early in development and then degenerates during the subsequent cotyledon stage of embryogenesis. 12,13 The suspensor plays an important role in embryo development; it transfers nutrients and growth factors to the embryo proper and biosynthesizes plant hormones. 12,14,15 For example, auxin is transported from the suspensor to the embryo proper by the suspensor-specific auxin efflux carrier PIN7, and PIN7-mediated auxin transport is essential for embryo development.…”

mentioning

confidence: 99%

NatA is required for suspensor development in Arabidopsis

Feng

2016

Plant Signaling & Behavior

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Suspensor development is essential for early embryogenesis. The filamentous suspensor plays vital roles in supporting the embryo proper and in exchanging nutrients and information between the embryo proper and embryo sac. In addition, at the globular stage, the uppermost suspensor cell differentiates into the hypophysis, which generates the progenitors of the quiescent center and columella stem cells. In naa10 and naa15 mutant plants, suspensor cell identity was found to be abnormal and embryo development was disturbed, leading to embryonic lethality. Therefore, the NatA complex is required for proper suspensor development in Arabidopsis.

show abstract

Embryogenesis in Angiosperms: Development of the Suspensor.

Cited by 225 publications

References 31 publications

Using Genomics to Study Legume Seed Development

Using Genomics to Study Legume Seed Development

Programmed cell death during plant growth and development

NatA is required for suspensor development in Arabidopsis

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