Cloning, sequencing and characterization of the gene encoding a principal sigma factor homolog from the cyanobacterium Microcystis aeruginosa K-81

Sigma factors for cyanobacterial transcription

Cyanobacteria are photosynthesizing microorganisms that can be used as a model for analyzing gene expression. The expression of genes involves transcription and translation. Transcription is performed by the RNA polymerase (RNAP) holoenzyme, comprising a core enzyme and a sigma (sigma) factor which confers promoter selectivity. The unique structure, expression, and function of cyanobacterial sigma factors (and RNAP core subunits) are summarized here based on studies, reported previously. The types of promoter recognized by the sigma factors are also discussed with regard to transcriptional regulation.

Stringent promoter recognition and autoregulation by the group 3 sigma-factor SigF in the cyanobacterium Synechocystis sp. strain PCC 6803

The cyanobacteirum Synechocystis sp. strain PCC 6803 possesses nine species of the sigma (σ)-factor gene for RNA polymerase (RNAP). Here, we identify and characterize the novel-type promoter recognized by a group 3 σ-factor, SigF. SigF autoregulates its own transcription and recognizes the promoter of pilA1 that acts in pilus formation and motility in PCC 6803. The pilA1 promoter (PpilA1-54) was recognized only by SigF and not by other σ-factors in PCC 6803. No PpilA1-54 activity was observed in Escherichia coli cells that possess RpoF (σ²⁸) for fragellin and motility. Studies of in vitro transcription for PpilA1-54 identified the region from −39 to −7 including an AG-rich stretch and a core promoter with TAGGC (−32 region) and GGTAA (−12 region) as important for transcription. We also confirmed the unique PpilA1-54 architecture and further identified two novel promoters, recognized by SigF, for genes encoding periplasmic and phytochrome-like phototaxis proteins. These results and a phylogenetic analysis suggest that the PCC 6803 SigF is distinct from the E. coli RpoF or RpoD (σ⁷⁰) type and constitutes a novel eubacterial group 3 σ-factor. We discuss a model case of stringent promoter recognition by SigF. Promoter types of PCC 6803 genes are also summarized.

Group 2 sigma factors in cyanobacteria

Group 1 and group 2 sigma factors are sigma factors of bacterial RNA polymerase responsible for transcription from consensus-type promoters. Thus, these sigma factors form the framework for basic transcriptional regulation in bacteria. Cyanobacteria are known to have various group 2 sigma factors, typically more than 4, but only recently the particular function of each sigma factor is being elucidated. In response to environmental signals such as nutrients, light and temperature, cyanobacteria change their transcriptional profile first by activating specific transcription factors and subsequently by modifying the basic transcriptional machinery, which is often involved in the regulation of group 2 sigma factors. In this article, we give an overview of the composition and evolution of group 2 sigma factors in cyanobacteria and summarize what was presently revealed regarding their function.

Dark-induced mRNA instability involves RNase E/G-type endoribonuclease cleavage at the AU-box and SD sequences in cyanobacteria

Light-responsive gene expression is crucial to photosynthesizing organisms. Here, we studied functions of cis-elements (AU-box and SD sequences) and a trans-acting factor (ribonuclease, RNase) in light-responsive expression in cyanobacteria. The results indicated that AU-rich nucleotides with an AU-box, UAAAUAAA, just upstream from an SD confer instability on the mRNA under darkness. An RNase E/G homologue, Slr1129, of the cyanobacterium Synechocystis sp. strain PCC 6803 was purified and confirmed capable of endoribonucleolytic cleavage at the AU- (or AG)-rich sequences in vitro. The cleavage depends on the primary target sequence and secondary structure of the mRNA. Complementation tests using Escherichia coli rne/rng mutants showed that Slr1129 fulfilled the functions of both the RNase E and RNase G. An analysis of systematic mutations in the AU-box and SD sequences showed that the cis-elements also affect significantly mRNA stability in light-responsive genes. These results strongly suggested that dark-induced mRNA instability involves RNase E/G-type cleavage at the AU-box and SD sequences in cyanobacteria. The mechanical impact and a possible common mechanism with RNases for light-responsive gene expression are discussed.

Cooperation of group 2 σ factors, SigD and SigE for light-induced transcription in the cyanobacteriumSynechocystissp. PCC 6803

A light-inducible sigma factor of RNA polymerase, SigD, can contributes to the light-induced transcription of psbA in the cyanobacterium Synechocystis sp. PCC 6803. Here, another light-induced sigma factor, SigE, was characterized together with SigD. Results indicated that SigE also contributes to light-induced transcription on the cpcBACD, psbA, petBD and psaAB promoters whose potential sequences are of the Escherichia coli sigma(70)-type. SigD and SigE interfere with each other's expression. A rhythmic expression, in which the periodic peak of SigE exhibits a 24-h interval according to the upcoming night, was observed at the protein level. The cooperation of group 2 sigma factors, SigD and SigE, for light-induced transcription was discussed.

Growth Phase-dependent Activation of Nitrogen-related Genes by a Control Network of Group 1 and Group 2 σ Factors in a Cyanobacterium

It has been reported that an RNA polymerase sigma factor, SigC, mainly contributes to specific transcription from the promoter PglnB-54,-53 under nitrogen-deprived conditions during the stationary phase of cell growth in the cyanobacterium Synechocystis sp. strain PCC 6803 (Asayama, M., Imamura, S., Yoshihara, S., Miyazaki, A., Yoshida, N., Sazuka, T., Kaneko, T., Ohara, O., Tabata, S., Osanai, T., Tanaka, K., Takahashi, H., and Shirai, M. (2004) Biosci. Biotechnol. Biochem. 68, 477-487). In this study, we further examined the functions of group 2 sigma factors of RNA polymerase in NtcA-dependent nitrogen-related gene expression in PCC 6803. Results indicated that SigB and SigC contribute to the transcription from PglnB-54,-53 with a sigma factor replaced in a growth phase-dependent manner. We also confirmed the contribution of SigB and SigC to the transcription of other NtcA-dependent genes, glnA, sigE, and amt1, as in the case of glnB. On the other hand, the transcription of glnN was dependent on SigB and SigE. In the SigB and SigC-based regulation, the level of SigB increased, but that of SigC was constant under conditions of nitrogen deprivation. Furthermore, it was found that SigC negatively and positively regulates the level of SigB in the log and stationary phase, respectively. SigC also had a positive effect on the level of sigB transcript during the stationary phase. In contrast, SigB acts positively on SigC levels in both growth phases. These results and previous findings indicated that multiple group 2 sigma factors take part in the control of NtcA-dependent nitrogen-related gene expression in cooperation with a group 1 sigma factor, SigA.

Antagonistic dark/light-induced SigB/SigD, group 2 sigma factors, expression through redox potential and their roles in cyanobacteria

The expression of group 2 sigma factors is characterized in a cyanobacterium Synechocystis sp. PCC 6803 grown in culture, changing light conditions (white, red and blue light, and darkness), or the presence of drugs (rifampicin, chloramphenicol, DCMU, and DBMIB), and the roles of these sigma factors are elucidated. The expression of dark/light-induced SigB/SigD was accelerated under opposite redox (oxidation/reduction) states in an electron transport chain of photosynthesis. Expression of the dark-induced lrtA and light-induced psbA2/3 transcript was significantly reduced in the sigB and sigD knockout strains, respectively. Abundant amounts of sigB transcript and protein were observed in the sigC knockout strain, implying that SigC represses SigB expression under light. These findings clearly showed that SigB/SigD with another group 2 sigma, SigC, contribute to transcription for a subset of dark/light-responsive genes in the cyanobacterium. A possible model for SigB/SigD is presented and the potential ability for promoter recognition is also discussed.

Two distinct curved DNAs upstream of the light-responsive psbA gene in a cyanobacterium

A functional intrinsic DNA curvature, CIT, and potential DNA-binding factors for the basal transcription of psbA2 have been reported in a cyanobacterium, Microcystis aeruginosa K-81 (Asayama et al., Nucleic Acids Res., 30, 4658-4666 (2002)). In this article, we found another novel curved DNA, which was induced by RNA polymerases binding to the promoter region. Circular permutation analyses showed that the curved center of RNA polymerase-induced DNA bending (RIB) lies at approximately the +10 site, referring to the transcription start point as +1, in the RNA polymerase-DNA complex. Regions containing the curved center of RIB and CIT contributed to the basal transcription in vivo and in vitro. These results indicate that the region upstream of K-81 psbA2 has two distinct curved DNAs, CIT (sequence-directed type) and RIB (protein-induced type).

Purification, characterization, and gene expression of all sigma factors of RNA polymerase in a cyanobacterium

The expression of RNA polymerase (RNAP) sigma factor genes and proteins was characterized as a first step toward understanding their functions in a unicellular cyanobacterium Synechocystis sp. PCC 6803, which can perform photosynthesis. All nine sigma factors (group 1, SigA; group 2, SigB to SigE; and group 3, SigF to SigI) and each RNAP core subunit (RpoA, RpoB, RpoC1 and RpoC2) were overproduced and purified from Escherichia coli cells, then polyclonal antibodies were prepared. Western blot and primer extension analyses revealed that the intracellular levels of group 1 and 2 sigma factors ranged from 0.9 fmol to 9.3 fmol per microgram of the total protein under conditions of steady-state growth, and that growth phase-dependent or constitutive transcripts were observed. Interestingly, no group 3 sigma factor proteins were detected under normal physiological conditions whereas their transcripts were robust, implying a possible regulation of translational attenuation and/or protein instability. Phylogenetic analysis also revealed that group 3 sigma factor homologues of cyanobacteria are conserved with evolutionary or functionary divergence among them. In vitro and in vivo results indicated significant evidence of high-light responsive SigD expression and its promoter recognition of the photosynthesis gene, psbA. On the other hand, autoregulated sigB transcription, a dramatically increased SigB expression upon the exposure of cells to heat-shock, and specific promoter recognition by SigB with redundancy of other sigma factors on the heat-shock hspA promoter were observed. These findings clearly indicated that SigB is a heat-shock responsive sigma factor. The unique promoter architecture and expression of the relevant sigma factor gene are also discussed herein.

The curved DNA structure in the 5'-upstream region of the light-responsive genes: its universality, binding factor and function for cyanobacterial psbA transcription

A unique DNA curvature, the CIT, has been found in the 5'-upstream region of the psbA2 gene, which exhibits basal, light-responsive and circadian rhythmic transcription, in a unicellular photosynthetic cyanobacterium, Microcystis aeruginosa K-81. In this study, we report the universality of curvatures found in 5'-upstream regions in the psbA family and the function of the curvature in gene expression. Intrinsic curvatures were identified within 1000 bp upstream from the psbA genes in another cyanobacterium, a red alga and in plants (monocot and dicot). Mutagenized curvatures were constructed and confirmed to have disrupted architecture by gel electrophoresis and atomic force microscopy. Relatively small amounts but light-responsive transcripts of psbA2 were observed in cyanobacterial transformants harboring the mutagenized curvature under light/dark and light/high-light conditions. This shows that the curvature is important for basal transcription. In vitro primer extension and DNA mobility shift assay revealed that factors which might bind to the region upstream from the bending center contribute to the effective basal transcription of psbA2.

An AU-box motif upstream of the SD sequence of light-dependent psbA transcripts confers mRNA instability in darkness in cyanobacteria

The psbA2 gene of a unicellular cyanobacterium, Microcystis aeruginosa K-81, encodes a D1 protein homolog in the reaction center of photosynthetic Photosystem II. The expression of the psbA2 transcript has been shown to be light-dependent as assessed under light and dark (12/12 h) cycling conditions. We aligned the 5'-untranslated leader regions (UTRs) of psbAs from different photosynthetic organisms and identified a conserved sequence, UAAAUAAA or the 'AU-box', just upstream of the SD sequences. To clarify the role of 5'-upstream cis-elements containing the AU-box for light-dependent expression of psbA2, a series of deletion and point mutations in the region were introduced into the genome of heterologous cyanobacterium Synechococcus sp. strain PCC 7942, and psbA2 expression was examined. A clear pattern of light-dependent expression was observed in recombinant cyanobacteria carrying the K-81 psbA2 -38/+36 region (which includes the minimal promoter element and a light-dependent cis-element with the AU-box), +1 indicating the transcription start site. A constitutive pattern of expression, in which the transcripts remained almost stable under dark conditions, was obtained in cells harboring the -38/+14 region (the minimal element), indicating that the +14/+36 region with the AU-box is important for the observed light-dependent expression. Point mutations analyses within the AU-box also revealed that changes in number, direction and identity (as assayed by adenine/uridine nucleotide substitutions) influenced the light-dependent pattern of expression. The level of psbA2 transcripts increased markedly in CG- or deletion-box mutants in the dark, strongly indicating that the AU- (AT-) box acts as a negative cis-element. Furthermore, characterization of transcript accumulation in cells treated with rifampicin suggests that psbA2 5'-mRNA is unstable in the dark, supporting the view that the light-dependent expression is controlled at the post-transcriptional level. We discuss various mechanisms that may lead to altered mRNA stability such as the binding of factor(s) or ribosomes to the 5'-UTR and possible roles of the AU-box motif and the SD sequence.

Light-dependent and rhythmic psbA transcripts in homologous/heterologous cyanobacterial cells

The psbA2 gene exhibits light-dependent and rhythmic expression in a unicellular cyanobacterium, Microcystis aeruginosa (Synechocystis) K-81. To further understand the psbA2 expression, biological analyses were performed in homologous and heterologous cyanobacterial cells. The results of the experiments using the K-81 cells revealed that (i) the light-dependent expression appeared on transcriptional and/or post-transcriptional level(s) under light/dark cycles, (ii) circadian-rhythmic transcripts were also observed under the control of an endogenous clock. To assess whether light-dependent and rhythmic psbA2 expression occurs in heterologous cyanobacterium, Synechococcus sp. strain PCC 7942, the K-81 psbA2 5'-upstream region of which the promoter and its around sequences share with those of PCC 7942 psbAII, was fused to the bacterial lacZ reporter gene, introduced into the genome of PCC 7942 and the psbA2 transcripts were directly investigated by primer extension. The K-81 psbA2 specific transcripts were also light-dependent and rhythmic in PCC 7942, strongly demonstrating that a common regulatory mechanism exists per se for the psbA2 expression in both strains. Furthermore, psbA2 expression in the recombinant PCC 7942 strain, AG400 in which the region from -404 to +111 of psbA2 is fused to lacZ, exhibited clear rhythmicity, while very little or no rhythmicity was observed in AG429 (-38 to +14, the only promoter region), suggesting that the region(s) around the promoter was essentially required for clear rhythmic expression.

Specific recognition of the cyanobacterial psbA promoter by RNA polymerases containing principal sigma factors

The psbA2 gene of a unicellular cyanobacterium, Microcystis aeruginosa K-81, encodes a D1 protein homolog in the reaction center of photosynthetic Photosystem II. To clarify the promoter recognition by a sigma factor of RNA polymerase, in vivo and in vitro analyses were performed for the photosynthetic gene. Although the specific transcript from the psbA2 promoter, whose sequence is of Escherichia coli consensus type, was observed in both cyanobacterium K-81 and E. coli cells, the expression was light-dependent in K-81 whereas it was constitutive in E. coli under the conditions of light and darkness (L/D). The specific psbA2-dependent transcripts were also detected in vitro by RNA polymerases containing the principal sigma factors, E. coli sigma70 and K-81 sigmaA1 (constitutively exists in K-81 grown under L/D cycles). Furthermore, a series of promoter fragments were constructed to confirm minimal cis elements for the in vitro psbA2 transcription. A -80 to +6 or -38 to +46 region, the sequences of which consisted of a core promoter (-38 to +6), was identified as the potential minimal cis element using the RNA polymerase fraction (*EsigmaA1) containing sigmaA1 partially purified from K-81. These results suggest that the psbA2 transcription with the minimal sequence was induced by the RNA polymerase (EsigmaA1) containing the principal sigma factor, sigmaA1, under both light and dark conditions in K-81.

A new sigma factor homolog in a cyanobacterium: cloning, sequencing, and light-responsive transcripts of rpoD2 from Microcystis aeruginosa K-81

We isolated an rpoD2 gene encoding the potential sigma factor of RNA polymerase from the cyanobacterium Microcystis aeruginosa K-81, which can perform photosynthesis. The deduced amino acid sequence of RpoD2 (sigmaA2) exhibits extensive homology to other eubacterial RpoD proteins. This gene possessed multiple 5'-end transcripts, expressed specifically under light (P(L)), dark (P(D)), or constitutively light/dark (P(C)) conditions during exponential cell growth.