NtcA, LexA and heptamer repeats involved in the multifaceted regulation of DNA repair genes recF, recO and recR in the cyanobacterium Nostoc PCC7120.

Regulation of DNA repair genes in cyanobacteria is an unexplored field despite some of them exhibiting high radio-resistance. With RecF pathway speculated to be the major double strand break repair pathway in Nostoc sp. strain PCC7120, regulation of recF, recO and recR genes was investigated. Bioinformatic approach-based identification of promoter and regulatory elements was validated using qRT-PCR analysis, reporter gene and DNA binding assays. Different deletion constructs of the upstream regulatory regions of these genes were analysed in host Nostoc as well as heterologous system Escherichia coli. Studies revealed: (1) Positive regulation of all three genes by NtcA, (2) Negative regulation by LexA, (3) Involvement of contiguous heptamer repeats with/without its yet to be identified interacting partner in regulating (i) binding of NtcA and LexA to recO promoter and its translation, (ii) transcription or translation of recF, (4) Translational regulation of recF and recO through non-canonical and distant S.D. sequence and of recR through a rare initiation codon. Presence of NtcA either precludes binding of LexA to AnLexA-Box or negates its repressive action resulting in higher expression of these genes under nitrogen-fixing conditions in Nostoc. Thus, in Nostoc, expression of recF, recO and recR genes is intricately regulated through multiple regulatory elements/proteins. Contiguous heptamer repeats present across the Nostoc genome in the vicinity of start codon or promoter is likely to have a global regulatory role. This is the first report detailing regulation of DSB repair genes in any algae.

Thymidylate kinase (TMK) of the photosynthetic, nitrogen-fixing cyanobacterium Nostoc sp. strain PCC7120: Biophysical, biochemical and physiological characterisation.

Thymidylate kinase (TMK/TMPK) is an important enzyme in DNA biosynthesis and catalyses the conversion of dTMP to dTDP. Due to its therapeutic potential, the focus has been on characterizing the TMK proteins of pathogens and human origin, with very little information available on the TMK proteins of photosynthetic organisms and agriculturally important nitrogen-fixing organisms. In this work we report the characterisation of TMK in an evolutionarily ancient organism, cyanobacteria. The TMK protein of the photosynthetic, nitrogen-fixing cyanobacterium Nostoc PCC7120 (AnTMK) was found to have low conformational stability, which related to its low Tm of ~46 °C confirmed by Differential Scanning Fluorimetry (DSF) and Differential Scanning Calorimetry (DSC) techniques. The AnTMK protein exhibited substrate specificity for dTMP and ATP with Km of 20.74 ± 1.47 µM and 20.17 ± 2.96 µM respectively. The enzyme kinetics data and the positive co-operativity observed between dTMP and ATP binding correlated well with the data obtained from Isothermal Titration Calorimetry (ITC). Homology model of the enzyme suggested that the binding mode of substrate nucleotides to the enzyme is conserved. When overexpressed constitutively in Nostoc PCC7120 (Antmk+), it supported faster growth measured in terms of chlorophyll a content under normal growth conditions, but exhibited lower photosynthetic efficiency. Compared to the vector control recombinant Nostoc AnpAM, the Antmk + cells exhibited higher photoinhibition at higher light irradiance with more open reaction centres and lower dissipation of heat, indicative of damage to photosynthetic machinery. This indicated that the TMK is likely to have a significant role in photosynthetic organisms.

Rec(F/O/R) proteins of the nitrogen-fixing cyanobacterium Nostoc PCC7120: In silico and expression analysis.

The high radioresistance of Nostoc sp. strain PCC7120 is indicative of a robust DNA repair pathway. In the absence of NHEJ pathway and the canonical RecBCD proteins, the RecF pathway proteins are expected to play an important role in double strand break repair in this organism. The RecF, RecO and RecR proteins which are central to the RecF pathway have not been characterised in the ancient cyanobacteria, several of which are known to be radioresistant. The characterisation of these proteins was initiated through a mix of in silico, expression and complementation analysis. Differential expression of the recF, recO and recR genes was observed both at the transcript and the protein level under normal growth condition, which did not change significantly upon exposure to DNA damage stresses. Expression of RecR as a 23 kDa protein in vivo in Nostoc PCC7120 confirmed the re-annotation of the initiation codon of the gene (alr4977) to a rare initiation codon 'GTT' 267 bases upstream of the annotated initiation codon. Of the three proteins, Nostoc RecO and RecR proteins could complement the corresponding mutations in Escherichia coli, but not RecF. The Nostoc RecO protein exhibited low sequence and structural homology with other bacterial RecO protein, and was predicted to have a longer loop region. Phylogenetic as well as sequence analysis revealed high conservation among bacterial RecR proteins and least for RecO. In silico analysis revealed a comparatively smaller interactome for the Nostoc RecF, RecO and RecR proteins compared to other bacteria, with RecO predicted to interact with both RecF and RecR. The information gathered can form a stepping stone to further characterise these proteins in terms of deciphering their interactome, biochemical and physiological activities. This would help in establishing their importance in RecF pathway of DSB repair in Nostoc PCC7120.

Double strand break (DSB) repair in Cyanobacteria: Understanding the process in an ancient organism.

Cyanobacterial species, Anabaena/Nostoc and Chroococcidiopsis are highly radio-resistant indicating the presence of a robust DNA repair system. However, unlike the establishment of multiple DNA repair pathways in the radio-resistant Deinococcus, research on DNA repair in cyanobacteria has lagged far behind. Being ancient organisms, it is likely that the DNA repair mechanisms have evolved from cyanobacteria to the modern day bacteria. This review focuses on identifying and collating information on the major DNA repair proteins in cyanobacteria including re-annotation of recR and ndk, using Anabaena/Nostoc sp. strain PCC7120 as a model organism. Unlike most other bacteria, the DNA repair genes of cyanobacteria are not clustered in operons. Though the functional characterisation of most DNA repair proteins is lacking in cyanobacteria, a bioinformatic approach using sequences of DNA repair proteins from Anabaena PCC7120, has helped identify the possible protein-protein interactions, and build probable pathways of double strand break (DSB) repair. The emerging picture can be used as a guide to discern the biochemical and physiological roles of the different DNA repair proteins in Anabaena or Synechocystis, which can be manipulated genetically and establish the different DNA repair pathways in cyanobacteria, and their evolution with time.

Regulation of multiple abiotic stress tolerance by LexA in the cyanobacterium Anabaena sp. strain PCC7120.

The paradigm of involvement of LexA in regulation of only SOS-response in bacteria through the down-regulation of DNA repair genes was challenged in the unicellular cyanobacterium, Synechocystis PCC6803, wherein it was originally shown not to be associated with DNA repair and later also involved in management of carbon-starvation through up-regulation of C-metabolism genes. In the filamentous cyanobacterium, Anabaena sp. strain PCC7120, global stress management role for LexA and a consensus LexA-binding box (AnLexA-box) has been established using a LexA-overexpressing recombinant strain, AnlexA+. High levels of LexA rendered Anabaena cells sensitive to different DNA damage and oxidative stress-inducing agents, through the transcriptional down-regulation of the genes involved in DNA repair and alleviation of oxidative stress. LexA overexpression enhanced the ability of Anabaena to tolerate C-depletion, induced by inhibiting photosynthesis, by up-regulating genes involved in C-fixation and down-regulating those involved in C-breakdown, while maintaining the overall photosynthetic efficiency. A consensus LexA-binding box, AnLexA-box [AGT-N4-11-ACT] was identified upstream of both up- and down-regulated genes using a subset of Anabaena genes identified on the basis of proteomic analysis of AnlexA+ strain along with a few DNA repair genes. A short genome search revealed the presence of AnLexA box in at least 40 more genes, with functional roles in fatty acid biosynthesis, toxin-antitoxin systems in addition to DNA repair, oxidative stress, metal tolerance and C-metabolism. Thus, Anabaena LexA modulates the tolerance to multitude of stresses through transcriptional up/down-regulation of their functional genes directly by binding to the AnLexA Box present in their promoter region.

The SbcC and SbcD homologs of the cyanobacterium Anabaena sp. strain PCC7120 (Alr3988 and All4463) contribute independently to DNA repair.

The ubiquitous SbcCD exonuclease complex has been shown to perform an important role in DNA repair across prokaryotes and eukaryotes. However, they have remained uncharacterized in the ancient and stress-tolerant cyanobacteria. In the cyanobacterium Anabaena sp. strain PCC7120, SbcC and SbcD homologs, defined on the basis of the presence of corresponding functional domains, are annotated as hypothetical proteins, namely Alr3988 and All4463 respectively. Unlike the presence of sbcC and sbcD genes in a bicistronic operon in most organisms, these genes were distantly placed on the chromosome in Anabaena, and found to be negatively regulated by LexA. Both the genes were found to be essential in Anabaena as the individual deletion mutants were non-viable. On the other hand, the proteins could be individually overexpressed in Anabaena with no effect on normal cell physiology. However, they contributed positively to enhance the tolerance to different DNA damage-inducing stresses, such as mitomycin C and UV- and γ-radiation. This indicated that the two proteins, at least when overexpressed, could function independently and mitigate the damage caused due to the formation of DNA adducts and single- and double-strand breaks in Anabaena. This is the first report on possible independent in vivo functioning of SbcC and SbcD homologs in any bacteria, and the first effort to functionally characterize the proteins in any cyanobacteria.

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.

LexA protein of cyanobacterium Anabaena sp. strain PCC7120 exhibits in vitro pH-dependent and RecA-independent autoproteolytic activity.

The LexA protein of the nitrogen-fixing cyanobacterium, Anabaena sp. strain PCC7120 exhibits a RecA-independent and alkaline pH-dependent autoproteolytic cleavage. The autoproteolytic cleavage of Anabaena LexA occurs at pH 8.5 and above, stimulated by the addition of Ca(2+) and in the temperature range of 30-57°C. Mutational analysis of Anabaena LexA protein indicated that the cleavage occurred at the peptide bond between Ala-84 and Gly-85, and optimal cleavage required the presence of Ser-118 and Lys-159, as also observed for LexA protein of Escherichia coli. Cleavage of Anabaena LexA was affected upon deletion of three amino acids, (86)GLI. These three amino acids are unique to all cyanobacterial LexA proteins predicted to be cleavable. The absence of RecA-dependent cleavage at physiological pH, which has not been reported for other bacterial LexA proteins, is possibly due to the absence of RecA interacting sites on Anabaena LexA protein, corresponding to the residues identified in E. coli LexA, and low cellular levels of RecA in Anabaena. Exposure to SOS-response inducing stresses, such as UV-B and mitomycin C neither affected the expression of LexA in Anabaena nor induced cleavage of LexA in either Anabaena 7120 or E. coli overexpressing Anabaena LexA protein. Though the LexA may be acting as a repressor by binding to the LexA box in the vicinity of the promoter region of specific gene, their derepression may not be via proteolytic cleavage during SOS-inducing stresses, unless the stress induces increase in cytoplasmic pH. This could account for the regulation of several carbon metabolism genes rather than DNA-repair genes under the regulation of LexA in cyanobacteria especially during high light induced oxidative stress.

The hypothetical protein 'All4779', and not the annotated 'Alr0088' and 'Alr7579' proteins, is the major typical single-stranded DNA binding protein of the cyanobacterium, Anabaena sp. PCC7120.

Single-stranded DNA binding (SSB) proteins are essential for all DNA-dependent cellular processes. Typical SSB proteins have an N-terminal Oligonucleotide-Binding (OB) fold, a Proline/Glycine rich region, followed by a C-terminal acidic tail. In the genome of the heterocystous nitrogen-fixing cyanobacterium, Anabaena sp. strain PCC7120, alr0088 and alr7579 are annotated as coding for SSB, but are truncated and have only the OB-fold. In silico analysis of whole genome of Anabaena sp. strain PCC7120 revealed the presence of another ORF 'all4779', annotated as a hypothetical protein, but having an N-terminal OB-fold, a P/G-rich region and a C-terminal acidic tail. Biochemical characterisation of all three purified recombinant proteins revealed that they exist either as monomer or dimer and bind ssDNA, but differently. The All4779 bound ssDNA in two binding modes i.e. (All4779)35 and (All4779)66 depending on salt concentration and with a binding affinity similar to that of Escherichia coli SSB. On the other hand, Alr0088 bound in a single binding mode of 50-mer and Alr7579 only to large stretches of ssDNA, suggesting that All4779, in all likelihood, is the major typical bacterial SSB in Anabaena. Overexpression of All4779 in Anabaena sp. strain PCC7120 led to enhancement of tolerance to DNA-damaging stresses, such as γ-rays, UV-irradiation, desiccation and mitomycinC exposure. The tolerance appears to be a consequence of reduced DNA damage or efficient DNA repair due to increased availability of All4779. The ORF all4779 is proposed to be re-annotated as Anabaena ssb gene.

Characterization of two naturally truncated, Ssb-like proteins from the nitrogen-fixing cyanobacterium, Anabaena sp. PCC7120.

Single-stranded (ss) DNA-binding (Ssb) proteins are vital for all DNA metabolic processes and are characterized by an N-terminal OB-fold followed by P/G-rich spacer region and a C-terminal tail. In the genome of the heterocystous, nitrogen-fixing cyanobacterium, Anabaena sp. strain PCC 7120, two genes alr0088 and alr7579 are annotated as ssb, but the corresponding proteins have only the N-terminal OB-fold and no P/G-rich region or acidic tail, thereby rendering them unable to interact with genome maintenance proteins. Both the proteins were expressed under normal growth conditions in Anabaena PCC7120 and regulated differentially under abiotic stresses which induce DNA damage, indicating that these are functional genes. Constitutive overexpression of Alr0088 in Anabaena enhanced the tolerance to DNA-damaging stresses which caused formation of DNA adducts such as UV and MitomycinC, but significantly decreased the tolerance to γ-irradiation, which causes single- and double-stranded DNA breaks. On the other hand, overexpression of Alr7579 had no significant effect on normal growth or stress tolerance of Anabaena. Thus, of the two truncated Ssb-like proteins, Alr0088 may be involved in protection of ssDNA from damage, but due to the absence of acidic tail, it may not aid in repair of damaged DNA. These two proteins are present across cyanobacterial genera and unique to them. These initial studies pave the way to the understanding of DNA repair in cyanobacteria, which is not very well documented.