Regulation of the Nitrogen Fixation Genes in the Heterocystous Cyanobacterium Anabaena sp. Strain PCC 7120

Kumar, Krithika

2011 December 1900

Many multicellular cyanobacteria produce specialized nitrogenfixing heterocysts. During diazotrophic growth of Anabaena (Nostoc) sp. strain PCC 7120, a regulated developmental pattern of single heterocysts separated by about 10 to 20 photosynthetic vegetative cells is maintained along filaments. Heterocyst structure and metabolic activity function together to accommodate oxygensensitive nitrogen fixation, catalyzed by nitrogenase. In this work, we show that the promoter of the nifHDK genes that encode nitrogenase, lies upstream from the intergenic region between nifH and nifU. Excision of the fdxN element is required for transcription of the nifHDK genes. Fluorescence microscopy of reporter strain PnifHDgfp, in the chromosomal nif locus indicated that expression of nifHDK is blocked in mutants that are unable to excise the fdxN element after nitrogen deprivation. We proposed that a promoter upstream of the element, likely PnifB, is required for transcription of the nifHDK genes. Indeed, the PnifHDgfp reporter at an ectopic site did not show GFP fluorescence. A PnifBgfp reporter was expressed specifically in heterocysts indicating that a promoter for the nifB gene lies in the intergenic region upstream of nifB. A stem loop structure located in the intergenic region between nifH and nifU may act as a processing site for production of nifHDK transcripts. We also provide evidence that DevH, a transcriptional regulator, is involved in regulating the nifBfdxNnifSUHDK genes. DevH is a protein belonging to the cAMP receptor protein (CRP) family of proteins that are widespread in bacteria and regulate genes in response to a gamut of physiological conditions. We show that DevH binds specifically to the nifB upstream region but not to the immediate upstream region of nifH. We predict that DevH binds to an NtcAlike binding site upstream of nifB and functions as an activator of the nifBfdxNnifSUHDK genes. Finally, we show that sigE, which is expressed at 16 hours after nitrogen deprivation, is required for normal expression of some heterocyst specific genes, including nifHDK. A sigE mutant shows delayed and reduced expression of nifHDK and some middle and late genes. We hypothesize that DevH in concert with SigE upregulates the expression of nifHDK in heterocysts after nitrogen deprivation.

Anabaena PCC 7120

cyanobacterium

heterocysts

nif

Characterization of the DNA-Binding Properties of the Cyanobacterial Transcription Factor NtcA

Wisén, Susanne

January 2003

<p>Nitrogen is an essential building block of proteins and nucleic acids and, therefore, crucial for the biosphere. Nearly 79 % of the air consists of nitrogen, but in the form of nitrogen gas (N₂), which cannot be utilized by most organisms. Nitrogen-fixing microorganisms such as cyanobacteria have a central role in supplying biologically useful nitrogen to the biosphere. Therefore, it is important to achieve further understanding of control mechanisms involved in nitrogen fixation and related processes. </p><p>This thesis concerns different molecular aspects of the transcription factor NtcA from the heterocystous cyanobacterium <i>Anabaena</i> PCC 7120. Apart from performing oxygenic photosynthesis, <i>Anabaena</i> PCC 7120 is also capable of fixing nitrogen. NtcA is a protein regulating transcription of a wide range of genes and in particular genes involved in cyanobacterial global nitrogen control. NtcA binds as a dimer to the promoter regions of target genes such as those involved in nitrogen fixation and heterocyst differentiation. </p><p>NtcA from <i>Anabaena</i> PCC 7120 was heterologously expressed in <i>E. coli</i> and a high yield of recombinant protein was achieved through purification by Ni-IMAC chromatography. The purified NtcA was used to examine DNA binding motifs preferred by NtcA <i>in vitro </i>using a semi-random library of DNA sequences. The preferred binding sequence for NtcA is TGTA – N₈ – TACA and at least five of the bases in the palindromic binding site are necessary for binding. Differences in the consensus sequence in vivo may reflect variations in the structural conformation of NtcA under various physiological conditions. </p><p>Since an earlier study suggested redox-regulated NtcA-DNA binding the role of the two cysteine residues of NtcA were investigated. Binding studies using three mutants, Cys157Ala, Cys164Ala, and Cys157Ala / Cys164Ala, demonstrated that all these NtcA variants bind to DNA with a slightly higher affinity in the presence of the reducing agent DTT. The studies indicate that the binding mechanism is not dependent on a conformational change of NtcA caused by breaking of intra-molecular disulfide bonds. </p><p>Crystallization followed by structural studies rendered a partial crystal structure of NtcA. The structure verifies that NtcA is a dimeric protein. Each subunit has three domains: the N-terminal domain, a dimerization helix connecting the N-terminal domain with the C-terminal domain, as well as making up the dimer interface, and a C-terminal domain including the DNA binding helix-turn-helix motif.</p><p>Furthermore, an NtcA binding site was found in the promoter region of the<i> hupSL</i> gene, encoding an uptake hydrogenase in <i>Nostoc punctiforme</i> (ATCC 29133), indicating that yet another gene is transcriptionally controlled by NtcA, thereby further emphasizing the multifaceted role of NtcA in cyanobacteria.</p>

Biochemistry

NtcA

transcription regulation

cyanobacteria

redox regulation

DNA binding

nitrogen fixation

Anabaena PCC 7120

Biokemi

Biochemistry

Biokemi

Characterization of the DNA-Binding Properties of the Cyanobacterial Transcription Factor NtcA

Wisén, Susanne

January 2003

Nitrogen is an essential building block of proteins and nucleic acids and, therefore, crucial for the biosphere. Nearly 79 % of the air consists of nitrogen, but in the form of nitrogen gas (N2), which cannot be utilized by most organisms. Nitrogen-fixing microorganisms such as cyanobacteria have a central role in supplying biologically useful nitrogen to the biosphere. Therefore, it is important to achieve further understanding of control mechanisms involved in nitrogen fixation and related processes. This thesis concerns different molecular aspects of the transcription factor NtcA from the heterocystous cyanobacterium Anabaena PCC 7120. Apart from performing oxygenic photosynthesis, Anabaena PCC 7120 is also capable of fixing nitrogen. NtcA is a protein regulating transcription of a wide range of genes and in particular genes involved in cyanobacterial global nitrogen control. NtcA binds as a dimer to the promoter regions of target genes such as those involved in nitrogen fixation and heterocyst differentiation. NtcA from Anabaena PCC 7120 was heterologously expressed in E. coli and a high yield of recombinant protein was achieved through purification by Ni-IMAC chromatography. The purified NtcA was used to examine DNA binding motifs preferred by NtcA in vitro using a semi-random library of DNA sequences. The preferred binding sequence for NtcA is TGTA – N8 – TACA and at least five of the bases in the palindromic binding site are necessary for binding. Differences in the consensus sequence in vivo may reflect variations in the structural conformation of NtcA under various physiological conditions. Since an earlier study suggested redox-regulated NtcA-DNA binding the role of the two cysteine residues of NtcA were investigated. Binding studies using three mutants, Cys157Ala, Cys164Ala, and Cys157Ala / Cys164Ala, demonstrated that all these NtcA variants bind to DNA with a slightly higher affinity in the presence of the reducing agent DTT. The studies indicate that the binding mechanism is not dependent on a conformational change of NtcA caused by breaking of intra-molecular disulfide bonds. Crystallization followed by structural studies rendered a partial crystal structure of NtcA. The structure verifies that NtcA is a dimeric protein. Each subunit has three domains: the N-terminal domain, a dimerization helix connecting the N-terminal domain with the C-terminal domain, as well as making up the dimer interface, and a C-terminal domain including the DNA binding helix-turn-helix motif. Furthermore, an NtcA binding site was found in the promoter region of the hupSL gene, encoding an uptake hydrogenase in Nostoc punctiforme (ATCC 29133), indicating that yet another gene is transcriptionally controlled by NtcA, thereby further emphasizing the multifaceted role of NtcA in cyanobacteria.

Biochemistry

NtcA

transcription regulation

cyanobacteria

redox regulation

DNA binding

nitrogen fixation

Anabaena PCC 7120

Biokemi

Biochemistry

Biokemi

Biophysical characterization of heterocyst differentiation regulators, HetR and PatS, from the cyanobacterium, Anabaena sp. strain PCC 7120 and structural biology of bacterial proteins from the Northeast Structural Genomics Consortium

Feldmann, Erik A.

25 July 2012

No description available.

Biochemistry

Biophysics

Chemistry

Developmental Biology

Anabaena PCC 7120

Nostoc

HetR

PatS

heterocyst differentiation

structural genomics

NESG

EPR spectroscopy

ITC calorimetry

multidimensional NMR spectroscopy

protein NMR