Abstract
Expression of plant tetrapyrroles is high in photosynthetic tissues and in legume root nodules in the form of chlorophyll and heme, respectively. The universal tetrapyrrole precursor delta-aminolevulinic acid (ALA) is synthesized from glutamate 1-semialdehyde (GSA) by GSA aminotransferase in plants, which is encoded by gsa. Immunoblot analysis showed that GSA aminotransferase was expressed in soybean leaves and nodules, but not in roots, and that protein correlated with enzyme activity. These observations indicate that GSA aminotransferase expression is controlled in tetrapyrrole formation and argue against significant activity of an enzyme other than the well described aminotransferase for GSA-dependent ALA formation. gas mRNA and protein were induced in soybean nodules, and their activation was temporally intermediate between those of the respective early and late genes endo2 and lb. A GSA aminotransferase gene, designated gsa1, was isolated and appears to be one of two gsa genes in the soybean genome. gsa1 mRNA accumulated to high levels in leaves and nodules, but not in uninfected roots as discerned with a gsa1-specific probe. Message levels were higher in leaves from etiolated plantlets than in mature plants, and expression in the former was slightly elevated by light. The expression pattern of gsa1 mRNA was qualitatively similar to that of total gsa. The data strongly suggest that gsa1 is a universal tetrapyrrole synthesis gene and that a gsa gene specific for a tissue, tetrapyrrole, or light condition is unlikely. The gsa1 promoter contained a genetic element found in numerous Drosophila melanogaster genes; the so-called GAGA element displayed single-stranded character in vitro and formed a complex with nuclear factors from nodules and leaves but not from roots. From these observations we infer that the GAGA element is involved in the transcriptional control of gsa1.
Highlights
Legume root nodules are specialized plant organs elicited by rhizobia bacteria that contain a large quantity of heme for the prosthetic group of plant hemoglobin, but lack chlorophyll
Evidence for two enzymes with glutamyl-tRNA reductase activity are described in two bacterial species [17,18,19], and no similar situation has been reported in plants, separate aminolevulinic acid (ALA) pools for heme and chlorophyll synthesis have been proposed in plant chloroplasts [20]
A high level of glutamate I-semialdehyde (GSA) aminot r ansferase wa s obse r ved only in tissues th at synt hesize a large quantity of tetrapyr role, show ing that expression of gsa is a control point for ALA and tetrapyrrole synthesi s in soybea n
Summary
Legume root nodules are specialized plant organs elicited by rhizobia bacteria that contain a large quantity of heme for the prosthetic group of plant hemoglobin (reviewed in Ref. 12), but lack chlorophyll. Soybean nodule cDNA encoding GSA aminotransferase was isolated, and both enzyme activity and mRNA are induced in the symbiotic tissue [10]. These data strongly support the universality of the C5 pathway in higher plants with respect to the tetrapyrrole formed and its distribution in tissues where ALA formation can be discerned. Gsal Is a Universal Tetrapyrrole Synthesis Gene symbiotic root nodules are unique organs within the plant kingdom, they have high ALA synthetic activity that is not fated to chlorophyll formation. We argue that the primary structure of extant plant gsa genes results from recent evolutionary events
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