Plastid Signals Remodel Light Signaling Networks and Are Essential for Efficient Chloroplast Biogenesis in Arabidopsis

Michael E. Ruckle ¹, Stephanie M. DeMarco ², and Robert M. Larkin ¹^*

¹ Michigan State University–Department of Energy Plant Research Laboratory, Michigan State University, East Lansing, Michigan 48824; Department of Biochemistry and Molecular Biology, Michigan State University, East Lansing, Michigan 48824
² Michigan State University–Department of Energy Plant Research Laboratory, Michigan State University, East Lansing, Michigan 48824

^* To whom correspondence should be addressed. E-mail: larkinr{at}msu.edu.

Plastid signals are among the most potent regulators of genesthat encode proteins active in photosynthesis. Plastid signalshelp coordinate the expression of the nuclear and chloroplastgenomes and the expression of genes with the functional stateof the chloroplast. Here, we report the isolation of new cryptochrome1(cry1) alleles from a screen for Arabidopsis thaliana genomesuncoupled mutants, which have defects in plastid-to-nucleussignaling. We also report genetic experiments showing that apreviously unidentified plastid signal converts multiple lightsignaling pathways that perceive distinct qualities of lightfrom positive to negative regulators of some but not all photosynthesis-associatednuclear genes (PhANGs) and change the fluence rate responseof PhANGs. At least part of this remodeling of light signalingnetworks involves converting HY5, a positive regulator of PhANGs,into a negative regulator of PhANGs. We also observed that mutantswith defects in both plastid-to-nucleus and cry1 signaling exhibitedsevere chlorophyll deficiencies. These data show that the remodelingof light signaling networks by plastid signals is a mechanismthat plants use to integrate signals describing the functionaland developmental state of plastids with signals describingparticular light environments when regulating PhANG expressionand performing chloroplast biogenesis.

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