The argininosuccinate lyase gene of Chlamydomonas reinhardtii: cloning of the cDNA and its characterization as a selectable shuttle marker.

We describe the cDNA sequence for ARG7, the gene that encodes argininosuccinate lyase--a selectable nuclear marker--in Chlamydomonas reinhardtii. The 5' end of the cDNA contains one more exon and the organisation of the mRNA is different from that predicted from the genomic sequence. When expressed under the control of the endogenous RbcS2 promoter, the 2.22-kb cDNA complements the arg7 mutation as well as the genomic DNA. A linear cDNA fragment lacking promoter sequences is also able to complement, suggesting that it could be used in promoter-trapping experiments. Despite the presence of a sequence encoding a potential chloroplast transit peptide in the cDNA the protein is not targeted to the chloroplast, nor can it complement the arg7 mutation when expressed there. By inserting a T7 bacteriophage promoter into the plasmid, a version of the cDNA which is able to complement both the C. reinhardtii arg7 mutant and the Escherichia coli argH mutant has been created. This modified Arg7 cDNA provides two advantages over the genomic DNA currently in use for gene tagging: it is shorter (6.2 kb versus 11.9 kb for pARG7.8phi3), and the selectable marker used in C. reinhardtii is the same as that used in E. coli, making plasmid rescue of the tag much more likely to succeed.

Interactive regulation of Azorhizobium nifA transcription via overlapping promoters.

The Azorhizobium nifA promoter (PnifA) is positively regulated by two physiological signal transduction pathways, NtrBC, which signals anabolic N status, and FixLJK, which signals prevailing O2 status. Yet, PnifA response (gene product per unit time) to these two activating signals together is more than twice that of the summed, individual signals. In the absence of NIFA, a negative PnifA autoregulator, the fully induced PnifA response is more than 10-fold greater than that of summed, individual signals. Given this synergism, these two signal transduction pathways must interactively regulate PnifA activity. PnifA carries three cis-acting elements, an anaerobox, which presumably binds FIXK, a NIFAbox, which presumably binds NIFA itself, and a sigma 54 box, which presumably binds sigma 54 initiator, a subunit of RNA polymerase. For combinatorial analysis, single, double, and triple promoter mutations were constructed in these cis-acting elements, and PnifA activities were measured in six different trans-acting background, i.e., fixK, fixJ, nifA, ntrC, rpoF, and wild type. Under all physiological conditions studied, high-level PnifA activity required both FIXK in trans and the anaerobox element in cis. Surprisingly, because PnifA was hyperactive with a mutated sigma 54box, this cis-acting element mediates both negative and positive control. Because PnifA hyperactivity also required a wild-type upstream NIFAbox element, even in the absence of NIFA, a second upstream nifA transcription start superimposed on the NIFAbox element was hypothesized. When nifA mRNA 5' start points were mapped by primer extension, both a minor upstream transcript(s) starting 45 bp distal to the anaerobox and a major downstream transcript starting 10 bp distal to the sigma 54 box were observed. In Azorhizobium, RNA polymerase sigma 54 initiator subunits are encoded by a multigene family, which includes rpoF and rpoN genes. Because rpoF mutants show an Ntr+ phenotype, whereas rpoN mutants are Ntr-, multiple sigma 54 initiators are functionally distinct. Two independent rpoF mutants both show a tight Nif- phenotype. Moreover, rpoF product sigma 54F is absolutely required for high-level PnifA activity. In summary, the Azorhizobium nifA gene carries overlapping housekeeping-type and sigma 54-type promoters which interactively respond to different signals. Effectively, the upstream, housekeeping-type promoter responds to FIXK and positively regulates the downstream, sigma 54-type promoter. The downstream, sigma 54-type promoter responds to NTRC and negatively regulates the upstream, housekeeping-type promoter. In terms of transcript yield, the upstream, housekeeping-type promoter is therefore weak, and the downstream, sigma 54-type promoter is strong.

Characterization of three genomic loci encoding Rhizobium sp. strain ORS571 N2 fixation genes.

Sixty-five independent, N2 fixation-defective (Nif-) vector insertion (Vi) mutants were selected, cloned, and mapped to the ORS571 genome. The recombinant Nif::Vi plasmids obtained in this way were used as DNA hybridization probes to isolate homologous phages from a genomic library of ORS571 constructed in lambda EMBL3. Genomic maps were drawn for three ORS571 Nif gene loci. Forty-five Nif::Vi mutants in genomic Nif locus 1 defined two gene clusters separated by 8 kilobase pairs (kb) of DNA. In the first cluster, 36 Nif::Vi mutants mapped to a 7-kb DNA segment that showed DNA homology with Klebsiella pneumoniae nifHDKE and encoded at least two Nif operons. In the other cluster, nine Nif::Vi mutants mapped to a 1.5-kb DNA segment that showed homology with K. pneumoniae and Rhizobium meliloti nifA; this DNA segment encoded a separate Nif operon. Fifteen Nif::Vi mutants mapped to a 3.5-kb DNA segment defined as Nif locus 2 and showed DNA homology with the R. meliloti P2 fixABC operon. Nif locus 2 carries a second nifH (nifH2) gene. Four Nif::Vi mutants mapped to a 2-kb DNA segment defined as Nif locus 3 and showed DNA homology with K. pneumoniae nifB. DNA from lambda Nif phages comprising all three genomic Nif loci was subcloned in plasmid vectors able to stably replicate in ORS571. These plasmid subclones were introduced into ORS571 strains carrying physically mapped Nif::Vi insertions, and genetic complementations were conducted. With the exception of certain mutants mapping to the nifDK genes, all mutants could be complemented to Nif+ when they carried plasmid subclones of defined genomic DNA regions. Conversely, most nifDK mutants behaved as pseudodominant alleles.