The regulation of HanA during heterocyst development in cyanobacterium Anabaena sp. PCC 7120

In response to deprivation of combined nitrogen, the filamentous cyanobacterium Anabaena sp. strain PCC 7120 develops heterocyst, which is specifically involved in the nitrogen fixation. In this study, we focused on the regulation of HanA, a histone-like protein, in heterocyst development. Electrophoretic mobility shift assay results showed that NtcA, a global nitrogen regulator necessary for heterocyst differentiation, could bind to two NtcA-binding motifs in the hanA promoter region. qPCR results also showed that NtcA may regulate the expression of hanA. By using the hanA promoter-controlled gfp as a reporter gene and performing western blot we found that the amount of HanA in mature heterocysts was decreased gradually.     

Sequential binding of FurA from Anabaena sp. PCC 7120 to iron boxes: Exploring regulation at the nanoscale

Fur (ferric uptake regulator) proteins are involved in the control of a variety of processes in most prokaryotes. Although it is assumed that this regulator binds its DNA targets as a dimer, the way in which this interaction occurs remains unknown. We have focused on FurA from the cyanobacterium Anabaena sp. PCC 7120. To assess the molecular mechanism by which FurA specifically binds to “iron boxes” in P_furA, we examined the topology arrangement of FurA–DNA complexes by atomic force microscopy. Interestingly, FurA–P_furA complexes exhibit several populations, in which one is the predominant and depends clearly on the regulator/promoter ratio on the environment. Those results together with EMSA and other techniques suggest that FurA binds P_furA using a sequential mechanism: (i) a monomer specifically binds to an “iron box” and bends P_furA; (ii) two situations may occur, that a second FurA monomer covers the free “iron box" or that joins to the previously used forming a dimer which would maintain the DNA kinked; (iii) trimerization in which the DNA is unbent; and (iv) finally undergoes a tetramerization; the next coming molecules cover the DNA strands unspecifically. In summary, the bending appears when an “iron box” is bound to one or two molecules and decreases when both “iron boxes” are covered. These results suggest that DNA bending contributes at the first steps of FurA repression promoting the recruitment of new molecules resulting in a fine regulation in the Fur-dependent cluster associated genes.     

Impairment of <Emphasis Type="Italic">ntc</Emphasis>A gene revealed its role in regulating iron homeostasis,ROS production and cellular phenotype under iron deficiency in cyanobacterium <Emphasis Type="Italic">Anabaena</Emphasis> sp. PCC 7120

Iron deficiency ends up into several unavoidable consequences including damaging oxidative stress in cyanobacteria. NtcA is a global nitrogen regulator controls wide range of metabolisms in addition to regulation of nitrogen metabolism. In present communication, NtcA based regulation of iron homeostasis, ROS production and cellular phenotype under iron deficiency in Anabaena 7120 has been investigated. NtcA regulates the concentration dependent iron uptake by controlling the expression of furA gene. NtcA also regulated pigment synthesis and phenotypic alterations in Anabaena 7120. A significant increase in ROS production and corresponding reduction in the activities of antioxidative enzymes (SOD, CAT, APX and GR) in CSE2 mutant strain in contrast to wild type Anabaena 7120 also suggested the possible involvement of NtcA in protection against oxidative stress in iron deficiency. NtcA has no impact on the expression of furB and furC in spite of presence of consensus NtcA binding site (NBS) and ?10 boxes in their promoter. NtcA also regulates the thylakoid arrangement as well as related photosynthetic and respiration rates under iron deficiency in Anabaena 7120. Overall results suggested that NtcA regulates iron acquisition and in turn protect Anabaena cells from the damaging effects of oxidative stress induced under iron deficiency.     

Effects of selenium, iron and cobalt addition to growth and yessotoxin production of the toxic marine dinoflagellate Protoceratium reticulatum in culture

The marine dinoflagellate Protoceratium reticulatum has been recently identified as a source for the disulfated polyether toxin, yessotoxin (YTX), and may pose a risk to human health, aquaculture development and coastal environments. The requirements of P. reticulatum for selenium, iron and cobalt were assessed in culture. P. reticulatum was grown in nutrient enriched seawater (1/10 GP medium) without selenium or with 0.003 and 0.0003 μM selenium added; without iron or with 0.076 and 0.0076 μM iron added; and without cobalt or with 0.008 μM cobalt added. Test flasks were monitored for growth rate, cell yield and YTX production. P. reticulatum was found to exhibit a strong requirement for both selenium and iron. Growth rate and cell yield in treatments without added selenium were significantly (P<0.05) reduced to 60.2% (μ=0.15 day⁻¹) and 20.2% (4942 cell ml⁻¹), respectively, of those with selenium added (μ=0.23 day⁻¹ and 24, 387 cell ml⁻¹). YTX production was significantly increased by addition of selenium in two of three transfers tested. Cells of P. reticulatum subjected to medium without selenium added showed morphological changes observable at the light microscope level which included enlarged cell size. The diameter of cells in medium without selenium added were significantly (P<0.05) enlarged to 36.7±0.90 μm compared to cells in the medium with selenium added, 27.5±1.25 μm. Growth rate and cell yield in treatments without added iron were also significantly reduced to 70.1% (μ=0.16 day⁻¹) and 34.2% (8003 cells ml⁻¹), respectively, of those with iron added (μ=0.23 day⁻¹ and 23,416 cells ml⁻¹). No significant effect on YTX production was measured. In contrast to selenium and iron, no limitation of growth or cell yield or differences in YTX production were observed for flasks without cobalt as compared to those with cobalt added. The possibility that harmful algal events of P. reticulatum may be influenced by selenium or iron in neritic waters is discussed.     

Differential regulation of ssb genes in the nitrogen‐fixing cyanobacterium,Anabaena sp. strain PCC71201

Anabaena sp. PCC7120 possesses three genes coding for single‐stranded DNA‐binding (SSB) protein, of which ssb1 was a single gene, and ssb2 and ssb3 are the first genes of their corresponding operons. Regulation of the truncated ssb genes, ssb1 (alr0088) and ssb2 (alr7559), was unaffected by N‐status of growth. They were negatively regulated by the SOS‐response regulatory protein LexA, as indicated by the (i) binding of Anabaena LexA to the LexA box of regulatory regions of ssb1 and ssb2, and (ii) decreased expression of the downstream gfp reporter gene in Escherichia coli upon co‐expression of LexA. However, the full‐length ssb gene, ssb3 (all4779), was regulated by the availability of Fe²⁺ and combined nitrogen, as indicated by (i) increase in the levels of SSB3 protein on Fe²⁺‐depletion and decrease under Fe²⁺‐excess conditions, and (ii) 1.5‐ to 1.6‐fold decrease in activity under nitrogen‐fixing conditions compared to nitrogen‐supplemented conditions. The requirement of Fe²⁺ as a co‐factor for repression by FurA and the increase in levels of FurA under nitrogen‐deficient conditions in Anabaena (Lopez‐Gomollon et al. 2007) indicated a possible regulation of ssb3 by FurA. This was substantiated by (i) the binding of FurA to the regulatory region of ssb3, (ii) repression of the expression of the downstream gfp reporter gene in E. coli upon co‐expression of FurA, and (iii) negative regulation of ssb3 promoter activity by the upstream AT‐rich region in Anabaena. This is the first report on possible role of FurA, an important protein for iron homeostasis, in DNA repair of cyanobacteria.