Exploring the genome of the salt-marsh Spartina maritima (Poaceae, Chloridoideae) through BAC end sequence analysis.

Spartina species play an important ecological role on salt marshes. Spartina maritima is an Old-World species distributed along the European and North-African Atlantic coasts. This hexaploid species (2n = 6x = 60, 2C = 3,700 Mb) hybridized with different Spartina species introduced from the American coasts, which resulted in the formation of new invasive hybrids and allopolyploids. Thus, S. maritima raises evolutionary and ecological interests. However, genomic information is dramatically lacking in this genus. In an effort to develop genomic resources, we analysed 40,641 high-quality bacterial artificial chromosome-end sequences (BESs), representing 26.7 Mb of the S. maritima genome. BESs were searched for sequence homology against known databases. A fraction of 16.91% of the BESs represents known repeats including a majority of long terminal repeat (LTR) retrotransposons (13.67%). Non-LTR retrotransposons represent 0.75%, DNA transposons 0.99%, whereas small RNA, simple repeats and low-complexity sequences account for 1.38% of the analysed BESs. In addition, 4,285 simple sequence repeats were detected. Using the coding sequence database of Sorghum bicolor, 6,809 BESs found homology accounting for 17.1% of all BESs. Comparative genomics with related genera reveals that the microsynteny is better conserved with S. bicolor compared to other sequenced Poaceae, where 37.6% of the paired matching BESs are correctly orientated on the chromosomes. We did not observe large macrosyntenic rearrangements using the mapping strategy employed. However, some regions appeared to have experienced rearrangements when comparing Spartina to Sorghum and to Oryza. This work represents the first overview of S. maritima genome regarding the respective coding and repetitive components. The syntenic relationships with other grass genomes examined here help clarifying evolution in Poaceae, S. maritima being a part of the poorly-known Chloridoideae sub-family.

Symbiotic nitrogen fixation does not require adenylylation of glutamine synthetase I in Rhizobium meliloti.

Symbiotic nitrogen fixation is accompanied by a shift of Rhizobium nitrogen metabolism from ammonium assimilation to ammonium export, which probably involves genetic or metabolic regulation of glutamine synthetase activity. In free-living Rhizobium meliloti glutamine synthetase I (GSI) is regulated post-translationally by reversible adenylylation in response to ammonium addition. Moreover, full expression of the GSI gene glnA requires the transcriptional activator, NtrC. A glnA1 mutant synthesizing a non-adenylylatable GSI produces normal nitrogen-fixing nodules on alfalfa: GSI adenylylation is dispensable for symbiotic nitrogen fixation. This is rationalized by the observation that less GS protein is present in R. meliloti bacteroids than in free-living bacterial cells.

Intramolecular signal transduction within the FixJ transcriptional activator: in vitro evidence for the inhibitory effect of the phosphorylatable regulatory domain.

FixJ is a phosphorylatable 'response regulator' controlling the transcription of the key nitrogen fixation genes nifA and fixK in Rhizobium meliloti. Sequence and genetic analyses indicated that FixJ comprises an N-terminal phosphorylatable regulatory domain, FixJN, and a C-terminal transcriptional activator domain, FixJC. We have now overexpressed and purified the FixJC protein and show that it is fully active in an in vitro transcription system with purified RNA polymerase. FixJC appeared to act synergistically with RNA polymerase at the nifA promoter. Furthermore FixJC was more active in vitro than the full-length dephosphorylated FixJ protein. Therefore activity of FixJC is inhibited by FixJN within the FixJ protein. This inhibition is relieved by phosphorylation of FixJN. Such a negative mode of intramolecular signal transduction may be generalizable to other response regulators.

Phosphorylation-induced dimerization of the FixJ receiver domain.

The 'two-component' transcriptional activator FixJ controls nitrogen fixation in Sinorhizobium meliloti. Phosphorylation of FixJ induces its dimerization, as evidenced by gel permeation chromatography and equilibrium sedimentation analysis. Phosphorylation-induced dimerization is an intrinsic property of the isolated receiver domain FixJN. Accordingly, chemical phosphorylation of both FixJ and FixJN are second-order reactions with respect to protein concentration. However, the second-order phosphorylation constant is 44-fold higher for FixJN than for FixJ. Therefore, the C-terminal transcriptional activator domain FixJC inhibits the chemical phosphorylation of the receiver domain FixJN. Conversely, FixJN has been shown previously to inhibit FixJC activity approximately 40-fold, reflecting the interaction between FixJN and FixJC. Therefore, we propose that modulation of FixJ activity involves both its dimerization and the disruption of the interface between FixJN and FixJC, resulting in the opening of the protein structure. Alanine scanning mutagenesis of FixJN indicated that the FixJ approximately P dimerization interface involves Val-91 and Lys-95 in helix alpha4. Dimerization was required for high-affinity binding to fixK promoter DNA.

Molecular genetic analysis of the Rhizobium meliloti fixK promoter: identification of sequences involved in positive and negative regulation.

Transcription of the Rhizobium meliloti fixK gene is induced in symbiotic and microaerobic growth conditions by the FixL/FixJ modulator/effector pair. Transcription of fixK is also negatively autoregulated. By 5' deletion analysis, the involvement in negative regulation of a DNA region between -514 and -450 with respect to the transcription start was demonstrated. Site-directed mutagenesis allowed us to show that a sequence homologous to the binding site of the Escherichia coli Fnr protein, centred at position -487, participates in this effect. However, deletion or mutagenesis of this Fnr-like sequence does not completely eliminate FixK-dependent repression, which suggests that either an additional DNA region is involved in negative regulation or that it is mediated at the level of fixLJ transcription. Deletion analysis also allowed the definition of a DNA region involved in FixJ-mediated activation of the fixK promoter, between -79 and -42. Different point mutations in the -60, -45 and -35 regions were shown to affect promoter activity. In some cases, the activity of mutant promoters could be partly or fully restored by increasing the expression of the fixLJ regulatory genes, in an E. coli strain harbouring a plasmid with fixLJ under the control of an inducible (p-tac) promoter.