Actin bundling in plants

Clément Thomas*, Stéphane Tholl, Danièle Moes, Monika Dieterle, Jessica Papuga, Flora Moreau, André Steinmetz

*Corresponding author for this work

Research output: Contribution to journalArticleResearchpeer-review

80 Citations (Scopus)


Tight regulation of plant actin cytoskeleton organization and dynamics is crucial for numerous cellular processes including cell division, expansion and intracellular trafficking. Among the various actin regulatory proteins, actin-bundling proteins trigger the formation of bundles composed of several parallel actin filaments closely packed together. Actin bundles are present in virtually all plant cells, but their biological roles have rarely been addressed directly. However, decades of research in the plant cytoskeleton field yielded a bulk of data from which an overall picture of the functions supplied by actin bundles in plant cells emerges. Although plants lack several equivalents of animal actin-bundling proteins, they do possess major bundler classes including fimbrins, villins and formins. The existence of additional players is not excluded as exemplified by the recent characterization of plant LIM proteins, which trigger the formation of actin bundles both in vitro and in vivo. This apparent functional redundancy likely reflects the need for plant cells to engineer different types of bundles that act at different sub-cellular locations and exhibit specific function-related properties. By surveying information regarding the properties of plant actin bundles and their associated bundling proteins, the present review aims at clarifying why and how plants make actin bundles.

Original languageEnglish
Pages (from-to)940-957
Number of pages18
JournalCell Motility and the Cytoskeleton
Issue number11
Publication statusPublished - Nov 2009


  • Actin cytoskeleton
  • Actin marker
  • Actin-bundling
  • Fimbrin
  • Forming
  • LIM proteins
  • Myosin
  • Pollen tube
  • Root hair
  • Villin


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