Abstract
Null-point action spectra of the light-growth response were measured for three mutants of Phycomyces blakesleeanus (Burgeff) and compared with the action spectrum of the wild type (WT). The action spectrum for L150, a recently isolated “night-blind” mutant, differs from the WT spectrum. The L150 action spectrum has a depression near 450 nm and small alterations in its long-wavelength cutoff, the same spectral regions where its photogravitropism action spectrum is altered. This indicates that the affected gene product influences both phototropism and the light-growth response. For L85, a “hypertropic” (madH) mutant, the light-growth-response action spectrum is very similar to that of WT even though the photogravitropism action spectrum of L85 has been shown previously to be altered in the near-UV region. The affected gene product in this mutant appears to affect phototropic transduction but not light-growth-response transduction. The action spectrum of C110, a “stiff” (madE) mutant, differs significantly from the WT spectrum near 500 nm, the same spectral region where sporangiophores of madE mutants have been shown to have small alterations in second-derivative absorption spectra. This indicates that the madE gene product may be physically associated with a photoreceptor complex, as predicted by system-analysis studies.
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Abbreviations
- SE:
-
standard error of the mean
- UV:
-
ultraviolet light
- Wt:
-
wild type
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I dedicated to Masaki Furuya on the occasion of his 65th birthday
We thank H. Reiner Schaefer for performing some of the experiments and for help in data analysis, David Durant for computer programming, and Benjamin Horwitz for helpful discussions. This work was supported by a grant from the National Institutes of Health (GM29707) to E.D. Lipson.
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Ensminger, P.A., Lipson, E.D. Action spectra of the light-growth response in three behavioral mutants of Phycomyces . Planta 184, 506–509 (1991). https://doi.org/10.1007/BF00197899
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DOI: https://doi.org/10.1007/BF00197899