Slowdown of surface diffusion during early stages of bacterial colonization.

We study the surface diffusion of the model cyanobacterium Synechocystis sp. PCC6803 during the incipient stages of cell contact with a glass surface in the dilute regime. We observe a twitching motility with alternating immobile tumble and mobile run periods, resulting in a normal diffusion described by a continuous-time random walk with a coefficient of diffusion D. Surprisingly, D is found to decrease with time down to a plateau. This is observed only when the cyanobacterial cells are able to produce released extracellular polysaccharides, as shown by a comparative study between the wild-type strain and various polysaccharides-depleted mutants. The analysis of the trajectories taken by the bacterial cells shows that the temporal characteristics of their intermittent motion depend on the instantaneous fraction of visited sites during diffusion. This describes quantitatively the time dependence of D, related to the progressive surface coverage by the polysaccharides. The observed slowdown of the surface diffusion may constitute a basic precursor mechanism for microcolony formation and provides clues for controlling biofilm formation.

Characterization and analysis of an NAD(P)H dehydrogenase transcriptional regulator critical for the survival of cyanobacteria facing inorganic carbon starvation and osmotic stress.

The three Synechocystis PCC6803 genes homologous to proteobacterial Calvin cycle regulators (cbbR) have been analysed. sll0998 appeared to be crucial to cell viability, whereas both sll0030 and sll1594 were found to be dispensable for cell growth. In spite of their sequence homology, Sll0030 and Sll1594 did not appear to regulate the transcription of Calvin cycle key genes. Further analysis of Sll1594 showed that this protein plays an important role in the adaptation to inorganic carbon starvation and osmotic stress. Sll1594 mediates the response to these stress conditions by regulating the transcription of a new regulon including the monocistronic genes sll1594 and slr1727 (encoding a presumptive Na+/H+ antiporter), as well as the ndh3 operon encoding the NAD(P)H-dehydrogenase subunits F3 and D3 and a protein of unknown function. The sll1594 gene and the ndh3 operon are negatively controlled by Sll1594, which also regulates the expression of the slr1727 gene. Sequence alignment of the diverse Sll1594 DNA binding sites led us to propose the TCAATG-(N10)-ATCAAT sequence as the consensus motif. To our knowledge, this is the first report on the characterization and analysis of a transcriptional regulator for ndh genes in a photoautotrophic organism.

The carbon metabolism-controlled Synechocystis gap2 gene harbours a conserved enhancer element and a Gram-positive-like -16 promoter box retained in some chloroplast genes.

The two glyceraldehyde-3-phosphate dehydrogenase-encoding genes (gap) of Synechocystis were shown to be expressed as monocistronic transcripts. Whereas gap1 expression is slow and weak, gap2 gene induction is rapid and strong. Transcription of the gap2 gene was shown to depend on functional photosynthetic electron transport and on active carbon metabolism. The basal promoter of gap2 (P, -45 to +34, relative to the transcription start site) is controlled by three cis-acting elements designated A (-443 to -45), B (+34 to +50, in the untranslated leader region) and C (+50 to +167, in the coding region) that, together, promote a 100-fold stimulation of P activity. Element B was found to behave as a transcriptional enhancer, in that it was active regardless of its position, orientation and distance relative to P. All three cis-acting stimulatory elements exhibit a common 5'-agaTYAACg-3' nucleotide motif that appears to be conserved in cyanobacteria and may be the target for a transcriptional enhancer. We also report that gap2 transcription depends on a Gram-positive-like -16 promoter box (5'-TRTG-3') that was obviously conserved throughout the evolution of chloroplasts. This is the first report on the occurrence of a -16 promoter element in photoautotrophic organisms.

The gene encoding the NdhH subunit of type 1 NAD(P)H dehydrogenase is essential to survival of synechocystis PCC6803.

The physiological function of the type 1 NAD(P)H dehydrogenase (Ndh-1) of Synechocystis sp. PCC6803 has been investigated by inactivating the gene ndhH encoding a subunit of the complex. Molecular analysis of independent transformants revealed that all clones were heteroploid, containing both wild-type and mutant ndhH copies, whatever the metabolic conditions used during genome segregation, including high CO(2) concentration. By replacing the chromosomal copy of the ndhH gene by a plasmidial copy under the control of a temperature-controlled promoter, we induce a conditional phenotype, growth being only possible at high temperature. This clearly shows for the first time that an ndh gene is indispensable to the survival of Synechocystis sp. PCC6803.

Targeted deletion and mutational analysis of the essential (2Fe-2S) plant-like ferredoxin in Synechocystis PCC6803 by plasmid shuffling.

The genes encoding (2Fe-2S) plant-like ferredoxins were studied in the widely used cyanobacterium Synechocystis PCC6803. The fedl gene (ssI0020) coding for the most abundant ferredoxin product was found to be expressed strongly as a light-induced monocistronic transcript, whereas the other fed genes appeared to be silent (sIr1828) or moderately expressed as polycistronic transcripts regulated by either light fluence (sIr0150, negative control) or glucose availability (sII1382). fedl was found to be critical to Synechocystis PCC6803 viability in spite of sIr0150, sII1382 or flavodoxin induction, even after the addition of glucose that compensates for the loss of photosynthesis. Nevertheless, fedl could be deleted from all chromosome copies in cells propagating a fedl gene (even of heterologous origin) on a replicating plasmid. This strain was used as the host for the subsequent introduction of fedl mutant alleles propagated on a second vector. Analysis of the fedl mutant strains generated after plasmid exchange showed that the C18-C85 disulphide bridge is not central either to the tight compaction of ferredoxin I or to its reduction by photosystem I and demonstrated that the length of the Fedl carboxy terminus is important for effective PSI/FedI interactions. The plasmid-shuffling strategy presently described has general applicability for mutational analysis of essential genes in many organisms, as it is based on promiscuous plasmids.

Promoter element spacing controls basal expression and light inducibility of the cyanobacterial secA gene.

The Synechocystis PCC6803 secA gene was found to be essential for cell viability and to be transcriptionally controlled by the redox state of the cells. The basic promoter (BP, -71 to +47 relative to the transcription start site) is controlled by three cis-acting elements, which together mediate the fourfold light induction of BP activity. The positively acting element (PE1, -361 to -71) upstream of BP exerts a twofold stimulation of BP; the negative element (NE, +47 to +104) downstream of BP decreases BP strength about sixfold. The PE2 element (+104 to +175) lying in the coding sequence overcomes NE-dependent downregulation of BP. BP harbours Escherichia coli sigma70-like promoter elements -35 (5'-TTGAat-3') and -10 (5'-TAagAT-3'). The -10 motif, which has the features of an 'extended -10' box, is absolutely essential to promoter activity. The -35 hexamer is critical to the enhancement of promoter strength above BP level and to light inducibility, both features involving regulatory elements flanking BP. Most interestingly, reducing the length of the 30 bp spacing between the -35 and -10 boxes down to 17 bp was found to increase promoter activity and to confer light inducibility to BP. This demonstrates that promoter element spacing controls basal expression and light inducibility of the secA gene.

Three insertion sequences from the cyanobacterium Synechocystis PCC6803 support the occurrence of horizontal DNA transfer among bacteria.

Three insertion sequences were characterized from the widely-used cyanobacterium Synechocystis PCC6803. They all harbored a putative transposase sequence flanked by two imperfect inverted repeats, seemed to have duplicated their target insertion site and occurred as multiple copies in the host genome. They exhibited no obvious homology with any other cyanobacterial ISs and were termed IS5S (871 bp), IS4S (1299 bp) and ISS1987 (949 bp) because they were, respectively, homologous to IS5- and IS4-bacterial elements, and to several members of the IS630-Tc1-mariner superfamily of IS elements occurring in a wide range of hosts. This suggests that these IS-elements were spread through horizontal transfer between evolutionary distant organisms. Three IS5S-copies were isolated as a rescue insertion into a replicating plasmid (IS5Sa), or subsequently cloned from a Synechocystis DNA-library probed with IS5Sa (IS5Sb and IS5Sc), and appeared to be almost identical. In the vicinity of IS5Sb, we found the ISS1987 element inserted into the IS4S element. This indicates that the ISS1987 element has been, and could still be, mobile since its transposase sequence is not interrupted with stop codons or translational frameshifts, unlike that which is found in most members of the IS630-Tc1-mariner superfamily of transposable elements.

Sequence of the flavodoxin-encoding gene from the cyanobacterium Synechocystis PCC6803.

The flavodoxin-encoding gene of the unicellular, facultatively heterotrophic and transformable cyanobacterium Synechocystis PCC6803 was cloned and sequenced. This single-copy gene is highly conserved in prokaryotes, irrespective of their ability to perform photosynthesis.

Light-regulated promoters from Synechocystis PCC6803 share a consensus motif involved in photoregulation.

A library of Synechocystis PCC6803 (S.6803) DNA cloned in front of the promoterless cat reporter gene of the plasmid pFF11 was used to transform S.6803 to high light-dependent resistance to chloramphenicol. In five clones harbouring a stably replicating pFF11-derived plasmid, this phenotype occurred independently of the photosystem II electron transport and resulted from the correlated increase of CAT activity level and cat mRNA accumulation. The five promoter inserts contained no Escherichia coli sigma 70 promoter element, in agreement with their lack of activity in this organism, but shared two conserved motifs. Two secondary mutations, which restored light-regulated promoter activity to an inactive mutant of the smallest insert, mapped within one of the common motifs, emphasizing the probable involvement of this element in photoregulation.

A conjugative plasmid vector for promoter analysis in several cyanobacteria of the genera Synechococcus and Synechocystis.

A promoter-probe vector, pSB2A, based on the plasmid RSF1010 and the promoterless chloramphenicol acetyl transferase (cat) reporter gene, has been constructed. pSB2A appeared to be most efficiently transferred by conjugation to the widely used cyanobacteria Synechocystis strains PCC6803 (S.6803) and PCC6714 (S.6714) and Synechococcus strains PCC7942 (S.7942) and PCC6301 (S.6301), where it replicates stably even though it contains no cyanobacterial DNA. Using pSB2A we found that (1) a light-regulated promoter from S.6803 remains controlled by light intensity in S.7942 while it is silent in Escherichia coli, and (2) the E. coli tac promoter behaves as a strong and light-independent promoter in the four cyanobacterial hosts tested.

A similar defect in UV-induced mutagenesis conferred by the rad6 and rad18 mutations of Saccharomyces cerevisiae.

The single rad6 and rad18 yeast mutants share a number of physiological and biochemical properties related to DNA repair, suggesting that they affect closely related steps. However, it has been reported that UV-induced mutagenesis is considerably more depressed in rad6 than it is in rad18 cells. In an attempt to better understand the role of these genes, a genetic system believed to differentiate between targeted and untargeted events was used. The data are interpreted to mean that both mutations prevent the occurrence of targeted events, as if they prevent error-prone replication in front of pyrimidine dimers. The number of non-targeted mutants per survivor in each mutant was increased by UV irradiation. This may correspond to a stimulation of the error-prone replication.

RADH, a gene of Saccharomyces cerevisiae encoding a putative DNA helicase involved in DNA repair. Characteristics of radH mutants and sequence of the gene.

A new type of radiation-sensitive mutant of S. cerevisiae is described. The recessive radH mutation sensitizes to the lethal effect of UV radiations haploids in the G1 but not in the G2 mitotic phase. Homozygous diploids are as sensitive as G1 haploids. The UV-induced mutagenesis is depressed, while the induction of gene conversion is increased. The mutation is believed to channel the repair of lesions engaged in the mutagenic pathway into a recombination process, successful if the events involve sister-chromatids but lethal if they involve homologous chromosomes. The sequence of the RADH gene reveals that it may code for a DNA helicase, with a Mr of 134 kDa. All the consensus domains of known DNA helicases are present. Besides these consensus regions, strong homologies with the Rep and UvrD helicases of E. coli were found. The RadH putative helicase appears to belong to the set of proteins involved in the error-prone repair mechanism, at least for UV-induced lesions, and could act in coordination with the Rev3 error-prone DNA polymerase.

Allelism between pso1-1 and rev3-1 mutants and between pso2-1 and snm1 mutants in Saccharomyces cerevisiae.

In the yeast Saccharomyces cerevisiae, allelism between the pso1-1 and the rev3-1 mutants on the one hand and the pso2-1 and snm1 mutants on the other, is demonstrated by the comparison of phenotypes, complementation tests and meiotic segregation analysis.