Kathleen J. Eckard

A Lipid Transfer–like Protein Is Necessary for Lily Pollen Tube Adhesion to an in Vitro Stylar Matrix

Flowering plants possess specialized extracellular matrices in the female organs of the flower that support pollen tube growth and sperm cell transfer along the transmitting tract of the gynoecium. Transport of the pollen tube cell and the sperm cells involves a cell adhesion and migration event in species such as lily that possess a transmitting tract epidermis in the stigma, style, and ovary. A bioassay for adhesion was used to isolate from the lily stigma/stylar exudate the components that are responsible for in vivo pollen tube adhesion. At least two stylar components are necessary for adhesion: a large molecule and a small (9 kD) protein. In combination, the two molecules induced adhesion of pollen tubes to an artificial stylar matrix in vitro. The 9-kD protein was purified, and its corresponding cDNA was cloned. This molecule shares some similarity with plant lipid transfer proteins. Immunolocalization data support its role in facilitating adhesion of pollen tubes to the stylar transmitting tract epidermis.

Adhesion of lily pollen tubes on an artificial matrix

Abstract We proposed that pollination in lily is a case of cell adhesion and cell movement, but experimental evidence for the adhesion event is lacking. In this study, we developed an artificial extracellular matrix that mimics the in vivo lily stylar transmitting tract. This artificial matrix was created by applying the transmitting tract exudate extracted from lily styles onto a nitrocellulose membrane. When in vitro-grown pollen tubes were applied to the matrix, they adhered by their tips to the area of the stylar exudate which is rich in arabinogalactan proteins. Once they adhered, they grew on the in vitro artificial matrix at rates faster than normal. This is the first experimental evidence demonstrating the adhesion of in vitro-grown pollen tubes, an event that has been described as common in vivo. The adhesion event is stylar exudate specific, concentration dependent, and is affected by the developmental age of the pollen tube. This bioassay for pollen tube adhesion will be used to isolate the adhesive molecules from the stylar exudate.

HIGH-PRESSURE FREEZING IMPROVES THE ULTRASTRUCTURAL PRESERVATION OF IN VIVO GROWN LILY POLLEN TUBES

SummaryWe have used high-pressure freezing followed by freeze substitution (HPF/FS) to preserve in vivo grown lily pollen tubes isolated from the style. The results indicated that HPF/FS (i) allows excellent preservation of the pollen tubes, (ii) maintains in situ the stylar matrix secreted by the transmitting tract cells, and (iii) preserves the interactions that exist between pollen tubes. Particular attention has been given to the structure of the pollen tube cell wall and the zone of adhesion. The cell wall is composed of an outer fibrillar layer and an inner layer of material similar in texture and nature to the stylar matrix and that is not callose. The stylar matrix labels strongly for arabinogalactan proteins (AGPs) recognized by monoclonal antibody JIM13. The zone of adhesion between pollen tubes contains distinct matrix components that are not recognized by JIM13, and apparent cross-links between the two cell walls. This study indicates that HPF/FS can be used successfully to preserve in vivo grown pollen tubes for ultrastructural investigations as well as characterization of the interactions between pollen tubes and the stylar matrix.

Immunogold localization of a developmentally regulated, tapetal-specific, 15 kDa lily anther protein

SummaryWe have confirmed that the LLA-15 polypeptide ofLilium longiflorum is (a) tapetum specific with some expression possible in the adjacent middle layer cells and (b) relatively abundant as evidenced by the high density of gold particles localized to the tapetal cells. We have established that the protein is cytoplasmic and not associated with organelles, membranes, extracellular matrix or wall. We also report an amino acid composition of the molecule and a partial sequence which bears no resemblance to any protein yet described.