Suppression of heterocyst differentiation in Anabaena PCC 7120 by a cosmid carrying wild-type genes encoding enzymes for fatty acid synthesis.

A cosmid containing a wild-type Anabaena PCC 7120 DNA fragment was found to suppress heterocyst differentiation, creating a Het phenotype in an otherwise wild-type strain. Curing of the cosmid restored the full wild-type Het+ Nif+ phenotype. The cosmid contains at least four genes encoding proteins with significant sequence similarity to enzymes involved in the synthesis of fatty acids. Selection for Nif+ revertants of the suppressed strain yielded modified cosmids, one of which contained a 10.2-kb transposon, Tas1, inserted into the promoter region of a gene encoding a protein with acyl carrier and beta-keto reductase domains. This gene, called hetN, was shown previously by Black and Wolk (J. Bacteriol. (1994) 176, 2282-2292) to inhibit heterocyst differentiation when present alone on a plasmid. Oddly, hetN gene transcription is detected later than 6 h into heterocyst differentiation.

Cell-type specificity of the Anabaena fdxN-element rearrangement requires xisH and xisI.

The fdxN element, along with two other DNA elements, is excised from the chromosome during heterocyst differentiation in Anabaena sp. strain PCC 7120. Previous work showed that rearrangement of the fdxN element requires the xisF gene, which encodes a site-specific recombinase, and suggested that at least one other heterocyst-specific factor is involved. Here we report that the xisH and xisI genes are necessary for the heterocyst-specific excision of the fdxN element. Deletion of a 3.2 kb region downstream of the xisF gene blocked the fdxN-element rearrangement in heterocysts. The 3.2 kb deletion was complemented by the two overlapping genes xisH and xisI. Interestingly, extra copies of xisHI on a replicating plasmid resulted in the xisF-dependent excision of the fdxN element in vegetative cells. Therefore, xisHI are involved in the control of cell-type specificity of the fdxN rearrangement. The xisHI genes had no effect on the two other DNA rearrangements. The xisHI-induced excision of the fdxN element produced strains lacking the element and demonstrates that the 55 kb element contains no essential genes. xisH and xisI do not show similarity to any known genes.

Nitrate reductase activity and heterocyst suppression on nitrate in Anabaena sp. strain PCC 7120 require moeA.

Mutants of Anabaena sp. strain PCC 7120 that form heterocysts when grown on nitrate-containing media were isolated following nitrosoguanidine mutagenesis. Six independent mutants were isolated, and the characterization of one mutant, strain AMC260, which forms 6 to 8% heterocysts in the presence of nitrate, is presented. A 1.8-kb chromosomal fragment that complemented the AMC260 mutant was sequenced, and a 1.2-kb open reading frame, named moeA, was identified. The deduced amino acid sequence of the predicted Anabaena sp. strain PCC 7120 MoeA polypeptide shows 37% identity to MoeA from Escherichia coli, which is required for the synthesis of molybdopterin cofactor. Molybdopterin is required by various molybdoenzymes, such as nitrate reductase. Interruption of the moeA gene in Anabaena sp. strain PCC 7120 resulted in a strain, AMC364, that showed a phenotype similar to that of AMC260. We show that AMC260 and AMC364 lack methyl viologen-supported nitrate reductase activity. We conclude that the inability of the moeA mutants to metabolize nitrate results in heterocyst formation on nitrate-containing media. Northern (RNA) analysis detected a 1.5-kb moeA transcript in wild-type cells grown in the presence or absence of a combined nitrogen source.

Anabaena xisF gene encodes a developmentally regulated site-specific recombinase.

Two DNA elements are excised from the chromosome during Anabaena heterocyst differentiation. We have identified the gene xisF which encodes the site-specific recombinase responsible for the excision of a 55-kb element from within the fdxN gene. The cloned xisF gene is sufficient to cause site-specific rearrangement of an artificial substrate in Escherichia coli. Inactivation of xisF in the Anabaena chromosome prevents excision of the fdxN element and growth in nitrogen-deficient medium but does not alter the development of heterocysts. Forced transcription of xisF in vegetative cells did not result in excision of the fdxN element, suggesting that other factors may be involved in cell-type specificity. The predicted XisF protein shows significant similarity to the Bacillus subtilis SpoIVCA recombinase.