Autoregulatory control of translatable phytochrome mRNA levels
- PMID: 16578769
- PMCID: PMC393796
- DOI: 10.1073/pnas.80.8.2248
Autoregulatory control of translatable phytochrome mRNA levels
Abstract
Translatable phytochrome mRNA represents approximately 5 x 10(-3)% of the total poly(A)-RNA present in etiolated Avena seedlings, as determined by incorporation of radioactivity into the immunoprecipitable apoprotein in a cell-free translation system. Irradiation of such seedlings with 5-s red light induces a decline in this mRNA that is detectable within 15-30 min, shows a 50% reduction within 50-60 min, and results in a >95% reduction within 2 hr. The effect of the red light pulse is reversed by an immediately subsequent far-red pulse to the level of the far-red-light control, indicating that phytochrome exerts autoregulatory control over its own translatable mRNA level. This result necessitates revision of existing concepts of how phytochrome concentrations are modulated in vivo. Red-light dose-response curves show that the response is sensitive to very low light levels. Conversion of <1% of the total cellular phytochrome to the biologically active far-red-absorbing form is sufficient to induce approximately 60% of the maximal response, and 20% far-red-absorbing form saturates the response. The observed change in translatable phytochrome mRNA level is one of the most rapid phytochrome-induced alterations in any cellular mRNA yet recorded. Thus, autoregulation of phytochrome mRNA provides an attractive opportunity to examine the early sequence of events in phytochrome control of gene expression.
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