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Access Type

Campus Access

Document Type


Degree Program

Molecular & Cellular Biology

Degree Type

Master of Science (M.S.)

Year Degree Awarded


Month Degree Awarded



Reactive Oxygen Species, Fertilization, Arabidopsis thaliana, Pollen tube reception, FERONIA


Fertilization, both in plants and animals, is at its core, a study of cell to cell communication. With respect to plants, the male gametophyte, the pollen tube, elongates within the female organ called the pistil, transporting in its cytoplasm two sperm cells. The pollen tube is attracted by signals secreted from the synergid cells that are located at the entrance to the female gametophyte that resides in the ovule. Secondary pollen tube visitors to the ovules are unwanted and repelled presumably by signals emitted by the fertilized female. The final communication between the pollen tube and female gametophyte is the induction of pollen tube rupture upon penetration of the synergid cell, an event that leads to the release of the two sperm cells, which go on to fertilize the central cell and egg cell within the female gametophyte, completing a double fertilization process that is unique to plants. My thesis research is centered on elucidating the mechanism behind the synergid cell-induced pollen tube rupture process. Studies in our laboratory have established that the synergid cell-expressed receptor like kinase, called FERONIA, mediates a highly oxidative environment in the female gematophyte that is necessary for the pollen tube rupture process. Using an in vitro pollen tube culture system, my research showed that reactive oxygen species (ROS) induces pollen tube rupture in a Ca2+-dependent manner. My results suggests a careful and truly fascinating, though still hypothetical, design of a two molecule, FERONIA and ROS, two step activation system that uses ROS to prime the pollen tube outside the synergid cell, then expose it to calcium within the synergid cell to ensure that pollen tube rupture happens in the synergid cell, enabling fertilization.


First Advisor

Alice Y. Cheung