A Plant-Specific Protein Essential for Blue-Light-Induced Chloroplast Movements

Stacy L. DeBlasio , Darron L. Luesse , and Roger P. Hangarter ^*

Department of Biology, Indiana University, Bloomington, Indiana 47405

^* Corresponding author; email: rhangart{at}indiana.edu.

In Arabidopsis (Arabidopsis thaliana), light-dependent chloroplastmovements are induced by blue light. When exposed to low fluencerates of light, chloroplasts accumulate in periclinal layersperpendicular to the direction of light, presumably to optimizelight absorption by exposing more chloroplast area to the light.Under high light conditions, chloroplasts become positionedparallel to the incoming light in a response that can reduceexposure to light intensities that may damage the photosyntheticmachinery. To identify components of the pathway downstreamof the photoreceptors that mediate chloroplast movements (i.e.phototropins), we conducted a mutant screen that has led tothe isolation of several Arabidopsis mutants displaying alteredchloroplast movements. The plastid movement impaired1 (pmi1)mutant exhibits severely attenuated chloroplast movements underall tested fluence rates of light, suggesting that it is a necessarycomponent for both the low- and high-light-dependant chloroplastmovement responses. Analysis of pmi1 leaf cross sections revealedthat regardless of the light condition, chloroplasts are moreevenly distributed in leaf mesophyll cells than in the wildtype. The pmi1-1 mutant was found to contain a single nonsensemutation within the open reading frame of At1g42550. This geneencodes a plant-specific protein of unknown function that appearsto be conserved among angiosperms. Sequence analysis of theprotein suggests that it may be involved in calcium-mediatedsignal transduction, possibly through protein-protein interactions.

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