Abstract
In higher plants, development of the chloroplasts must be coordinated with development of the leaf. In order to study the signals that synchronize these two developmental processes, we have isolated virescent (delayed in greening) mutants of Arabidopsis thaliana. Two such mutants that have pale-green young leaves which gradually green more fully during leaf maturation have been partially characterized. The two, vir1 and vir2, are due to separate nuclear recessive mutations. The pale leaves of vir1 and vir2 both had reduced 77°K fluorescence emission at 730–734 nm relative to that at 686–687 nm, indicating a reduction in the relative amount of LHC I compared to WT. As leaves greened, the amount of LHC I increased to near wildtype levels. The shift in the fluorescence emission peak from 730 nm to 734 nm, characteristic of maturing LHC I, was seen for vir1, but not vir2, suggesting that vir1 is a regulatory mutant while vir2 may be defective in a specific aspect(s) of LHC I function.
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Abbreviations
- D:
-
dark
- EMS:
-
ethyl methanesulfonate
- er:
-
erecta
- gl1:
-
glabrous1
- L:
-
light
- LHC I:
-
light harvesting complex of Photosystem I
- LHC II:
-
light harvesting complex of Photosystem II
- M2:
-
second generation of mutagenized seed
- M3:
-
third generation of mutagenized seed
- vir:
-
virescent
- WT:
-
wildtype
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Brusslan, J.A., Tobin, E.M. Isolation and initial characterization of virescent mutants of Arabidopsis thaliana . Photosynth Res 44, 75–79 (1995). https://doi.org/10.1007/BF00018298
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DOI: https://doi.org/10.1007/BF00018298