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. 1991 Aug;3(8):829–840. doi: 10.1105/tpc.3.8.829

Phenylpropanoid pathway intermediates regulate transient expression of a chalcone synthase gene promoter.

G J Loake 1, A D Choudhary 1, M J Harrison 1, M Mavandad 1, C J Lamb 1, R A Dixon 1
PMCID: PMC160050  PMID: 1820822

Abstract

A chimeric gene construct containing a bean chalcone synthase (CHS) promoter fused to the chloramphenicol acetyltransferase (CAT) reporter gene was strongly expressed when electroporated into alfalfa protoplasts that were then exposed to a fungal elicitor. Low concentrations (5 x 10(-6) to 10(-4) M) of exogenously applied trans-cinnamic acid (CA), the first intermediate of the phenylpropanoid pathway, slightly stimulated elicitor-induced CAT expression, whereas high concentrations (greater than 10(-4) M) severely reduced expression to below the levels observed in the absence of elicitor. In contrast, trans-p-coumaric acid (4-CA, the second intermediate in the pathway) stimulated expression from the CHS promoter up to 4.5-fold at 5 x 10(-4) M. Expression of CAT driven by the promoters of other elicitor-inducible defense response genes was not markedly affected by CA or 4-CA. Stimulation of CHS promoter expression by low concentrations of CA and 4-CA was completely abolished by 5' deletion to position -130, but not -174. When the -180 to -130 region of the CHS15 promoter was coelectroporated into elicited protoplasts on a separate plasmid along with the intact -326 CHS-CAT construct, the decreased CAT expression as a function of CA or 4-CA concentration was consistent with the coelectroporated sequence competing in trans with the intact promoter for the binding of a factor(s) involved in the up regulation of CHS transcription by 4-CA and low concentrations of CA. Our data support the hypothesis that phenylpropanoid compounds may act as natural and specific regulators of plant gene expression and define the location of a cis-acting element in the CHS15 promoter involved in the induction by phenylpropanoid pathway intermediates.

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Selected References

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