A high-resolution, single-grain, in vivo pollen hydration bioassay for arabidopsis thaliana

James Doughty, Yui-Leung Lau, Ludi Wang, Mutian Yang

Research output: Contribution to journalArticlepeer-review

Abstract

Sexual reproduction in flowering plants requires initial interaction between the pollen grain and the stigmatic surface, where a molecular dialog is established between the interacting partners. Studies across a range of species have revealed that a series of molecular checkpoints regulate the pollen-stigma interaction to ensure that only compatible, generally intraspecific pollen is successful in effecting fertilization. In species that possess a ‘dry stigma’, such as the model plant Arabidopsis thaliana, the first post-pollination, prezygotic compatibility checkpoint is the establishment of pollen hydration.

This phase of pollination is tightly regulated, whereby signals from the pollen grain elicit the release of water from the stigma, thus permitting pollen hydration. The ability to accurately measure and track pollen hydration over time is key to the design of experiments directed at understanding the regulation of this critical step in reproduction. Published protocols frequently utilize flowers that have been excised from the parent plant, maintained on liquid or solid media, and bulk pollinated.

This paper describes a noninvasive, in vivo pollination bioassay that permits minute-by-minute hydration tracking of individual A. thaliana pollen grains at high resolution. The assay is highly reproducible, able to detect very subtle variations of pollen hydration profiles, and thus is suitable for the analysis of mutants that affect pathways regulating pollination. Although the protocol is lengthier than those described for bulk pollinations, the precision and reproducibility it provides, along with its in vivo nature, make it ideal for the detailed dissection of pollination phenotypes.
Original languageEnglish
Article numbere65280
Number of pages14
JournalJournal of Visualized Experiments
Volume196
Early online date30 Jun 2023
DOIs
Publication statusPublished - 30 Jun 2023

Bibliographical note

This research was supported by University of Bath (University of Bath, Bath, UK, BA2 7AY) postgraduate scholarships

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