gsa1 is a universal tetrapyrrole synthesis gene in soybean and is regulated by a GAGA element.

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.

Analysis of the Bradyrhizobium japonicum hemH gene and its expression in Escherichia coli.

Complementation analysis showed that the Bradyrhizobium japonicum hemH gene was both necessary and sufficient to rescue mutant strains I110ek4 and I110bk2 in trans with respect to hemin auxotrophy, protoporphyrin accumulation, and the deficiency in ferrochelatase activity. The B. japonicum hemH gene was expressed in an Escherichia coli T7 expression system and yielded a 39-kDa protein, which was consistent with the predicted size of the deduced product. The overexpressed protein was purified and shown to contain ferrochelatase activity, thereby demonstrating that the hemH gene encodes ferrochelatase. When expressed from the lac promoter, the B. japonicum hemH gene was able to complement the enzyme activity of a ferrochelatase-defective E. coli mutant, and it also conferred hemin prototrophy on those cells. These latter findings confirm the identity of the hemH gene product and demonstrate that B. japonicum ferrochelatase can interact with the E. coli heme synthesis enzymes for heme formation in complemented cells.

The Escherichia coli visA gene encodes ferrochelatase, the final enzyme of the heme biosynthetic pathway.

An Escherichia coli mutant with a disrupted visA gene was defective in ferrochelatase activity but expressed wild-type levels of protoporphyrinogen oxidase activity. The visA coding region was placed under the transcriptional control of T7 RNA polymerase in an E. coli expression system, and the product was expressed as a 38-kDa protein. The overexpressed protein was purified to near homogeneity and was found to contain ferrochelatase activity. The data show that the visA gene encodes ferrochelatase, and we propose that it be renamed hemH to reflect that conclusion.

Characterization of a Bradyrhizobium japonicum ferrochelatase mutant and isolation of the hemH gene.

A Tn5-induced mutant of Bradyrhizobium japonicum, strain LORBF1, was isolated on the basis of the formation of fluorescent colonies, and stable derivatives were constructed in backgrounds of strains LO and I110. The stable mutant strains LOek4 and I110ek4 were strictly dependent upon the addition of exogenous hemin for growth in liquid culture and formed fluorescent colonies. The fluorescent compound was identified as protoporphyrin IX, the immediate precursor of protoheme. Cell extracts of strains LOek4 and I110ek4 were deficient in ferrochelatase activity, the enzyme which catalyzes the incorporation of ferrous iron into protoporphyrin IX to produce protoheme. Mutant strain I110ek4 could take up 55Fe from the growth medium, but, unlike the parent strain, no significant incorporation of radiolabel into heme was found. This observation shows that heme was not synthesized in mutant strain I110ek4 and that the heme found in those cells was derived from exogenous hemin in the growth medium. The putative protein encoded by the gene disrupted in strain LORBF1 and its derivatives was homologous to ferrochelatases from eukaryotic organisms. This homology, along with the described mutant phenotype, provides strong evidence that the disrupted gene is hemH, that which encodes ferrochelatase. Mutant strain I110ek4 incited nodules on soybean that did not fix nitrogen, contained few viable bacteria, and did not express leghemoglobin heme or apoprotein. The data show that B. japonicum ferrochelatase is essential for normal nodule development.

Aerobic growth and respiration of a delta-aminolevulinic acid synthase (hemA) mutant of Bradyrhizobium japonicum.

Oxygen-dependent growth of the Bradyrhizobium japonicum hemA mutant MLG1 (M.L. Guerinot and B.K. Chelm, Proc. Natl. Acad. Sci. USA 83:1837-1841, 1986) was demonstrated in cultured cells in the absence of exogenous delta-aminolevulinic acid (ALA), but growth of analogous mutants of Rhizobium meliloti or of Escherichia coli was not observed unless ALA was added to the yeast extract-containing media. No heme could be detected in extracts of strain MLG1 cells as measured by the absorption or by the peroxidase activity of the heme moiety, but the rates of growth and endogenous respiration of the mutant were essentially identical to those found in the parent strain. A role for ALA in the viability of strain MLG1 could not be ruled out since the ALA analog levulinic acid inhibited growth, but neither ALA synthase nor glutamate-dependent ALA synthesis activity was found in the mutant. The data show that the cytochromes normally discerned in wild-type B. japonicum cultured cells by absorption spectroscopy are not essential for aerobic growth or respiration.

Steroidogenesis activator polypeptide (SAP) in the guinea pig adrenal cortex.

Steroidogenesis activator polypeptide (SAP), a cytosolic stimulator of cholesterol side-chain cleavage (cholesterol SCC) previously characterized in the rat, was isolated from guinea pig adrenal cortex. This factor exhibited behavior on reverse-phase high-performance liquid chromatography (HPLC) that was indistinguishable from authentic SAP and crossreacted fully in a SAP radioimmunoassay. In dexamethasone-suppressed guinea pigs neither the concentrations of immunoreactive adrenal SAP nor the levels of cholesterol SCC activity were significantly different between the outer zones (zonae glomerulosa and fasciculata) and the inner zone (zona reticularis). However, at 10 min after treatment of dexamethasone-suppressed animals with ACTH1-24, the outer zone content of SAP was increased 42-fold over unstimulated controls whereas inner zone SAP was elevated only 4-fold. At the same time, cholesterol SCC activity was increased 2-fold in the outer zones but unchanged in the inner zone. In addition to SAP itself, a crossreacting 82 kDa protein (p82)--similar to the putative SAP precursor identified in the rat--was detected on two-dimensional immunoblots of guinea pig whole adrenal homogenate. There were no significant differences in the protein concentrations of p82 or of cytochrome P-450scc between zones, either with or without ACTH treatment. We conclude that the widely reported contrast in corticosteroidogenic potential between the zona fasciculata and the zona reticularis of the guinea pig may reflect a differential capacity to generate SAP, and thus activate cholesterol SCC, in response to ACTH.