A polyketide-synthase-like gene is involved in the synthesis of heterocyst glycolipids in Nostoc punctiforme strain ATCC 29133

A Tn5-1063-derived mutant of Nostoc punctiforme strain ATCC 29133 was unable to fix N₂ in air although it reduced acetylene in the absence of O₂. Mutant strain UCD 307 formed cells morphologically similar to heterocysts, but it failed to synthesize the characteristic heterocyst glycolipids. Sequence analysis around the site of insertion revealed an ORF of 3,159 base pairs, termed hglE. hglE putatively encodes a 115.4-kDa protein containing two domains with conserved amino acid sequences identified with acyl transferase and the chain length factor variation of β-ketoacyl synthase active sites. These active sites are characteristic of polyketide and fatty acid synthases. The N. punctiforme strain 29133 hglE gene is transcribed only under nitrogen-limiting growth conditions. The hglE gene, or similar sequences, was found in all other heterocyst-forming cyanobacteria surveyed and was absent in unicellular Synechococcus sp. strain PCC 7942. Based on these results, we propose that the synthesis of heterocyst glycolipids follows a pathway characteristic of polyketide synthesis and involves similar large, multienzyme complexes. Received: 4 November 1996 / Accepted: 6 January 1997     

Biochemical and Genetic Evidence for Participation of DevR in a Phosphorelay Signal Transduction Pathway Essential for Heterocyst Maturation in Nostoc punctiforme ATCC 29133

In a test of the hypothesis that DevR is a response regulator protein that functions in a phosphorelay signal transduction system involved in heterocyst development in Nostoc punctiforme ATCC 29133, purified affinity-tagged DevR was shown to be phosphorylated in vitro by the noncognate sensor kinase EnvZ. Site-directed mutagenesis was used to generate N. punctiforme mutants with single amino acid substitutions at the putative phosphorylation site of DevR. These mutants exhibited a Fox- phenotype like the original devR insertion mutant UCD 311, consistent with a phosphotransferase role for DevR.     

Physiological sources of reductant for nitrogen fixation activity in Nostoc sp. strain UCD 7801 in symbiotic association with Anthoceros punctatus.

Pure cultures of the symbiotic cyanobacterium-bryophyte association with Anthoceros punctatus were reconstituted by using Nostoc sp. strain UCD 7801 or its 3-(3,4-dichlorophenol)-1,1-dimethylurea (DCMU)-resistant mutant strain, UCD 218. The cultures were grown under high light intensity with CO2 as the sole carbon source and then incubated in the dark to deplete endogenous reductant pools before measurements of nitrogenase activities (acetylene reduction). High rates of light-dependent acetylene reduction were obtained both before starvation in the dark and after recovery from starvation, regardless of which of the two Nostoc strains was reconstituted in the association. Rates of acetylene reduction by symbiotic tissue with the wild-type Nostoc strain decreased 99 and 96% after 28 h of incubation in the dark and after reexposure to light in the presence of 5 microM DCMU, respectively. Supplementation of the medium with glucose restored nitrogenase activity in the dark to a rate that was 64% of the illuminated rate. In the light and in the presence of 5 microM DCMU, acetylene reduction could be restored to 91% of the uninhibited rate by the exogenous presence of various carbohydrates. The rate of acetylene reduction in the presence of DCMU was 34% of the uninhibited rate of tissue in association with the DCMU-resistant strain UCD 218. This result implies that photosynthates produced immediately by the cyanobacterium can supply at least one-third of the reductant required for nitrogenase activity on a short-term basis in the symbiotic association. However, high steady-state rates of nitrogenase activity by symbiotic Nostoc strains appear to depend on endogenous carbohydrate reserves, which are presumably supplied as photosynthate from both A. punctatus tissue and the Nostoc strain.     

Two mutations that block heterocyst differentiation have different effects on akinete differentiation in Nostoc ellipsosporum

Evident differentiation of vegetative cells into hetero-cysts in Anabaena sp. strain PCC 7120 is prevented by Insertions in genes hetR and hetP. Nostoc ellipsosporum possesses single copies of genes that hybridize with hetR and hetP. In mutant NE2 of N. ellipsosporum, in which hetR is interrupted by an insert, and in a double recombinant of wild-type N. ellipsosporum with a plasmid that bears an interrupted copy of hetR, neither heterocysts nor akinetes are formed. When an intact copy of hetR from Anabaena sp. strain PCC 7120 was added to NE2 the ability to form both heterocysts and akinetes was restored, in contrast to the hetR mutant, a hetP mutant of N. ellipsosporum could form akinetes, but heterocyst formation was blocked. Use of luxAB, encoding luciferase, as a reporter, and use of luxC, luxD and luxE to generate aldehyde (a substrate for the luciferase reaction), permitted visualization of the expression of hetR at the level of single cells; hetR was expressed in akinetes.     

The Anabaena sp. strain PCC 7120 asr1734 gene encodes a negative regulator of heterocyst development

The novel asr1734 gene of Anabaena (Nostoc) sp. strain PCC 7120 inhibited heterocyst development when present in extra copies. Overexpression of asr1734 inhibited heterocyst development in several strains including the wild type and two strains that form multiple contiguous heterocysts (Mch phenotype): a PatS null mutant and a hetR(R223W) mutant. Overexpression of asr1734 also caused increased nblA messenger RNA levels, and increased loss of autofluorescence in vegetative cells throughout filaments after nitrogen or sulphur depletion. Unlike the wild type, an asr1734 knockout mutant formed 5% heterocysts after a nitrogen shift from ammonium to nitrate, and formed 15% heterocysts and a weak Mch phenotype after step-down to medium lacking combined nitrogen. After nitrogen step-down, the asr1734 mutant had elevated levels of ntcA messenger RNA. A green fluorescent protein reporter driven by the asr1734 promoter, P(asr1734)-gfp, was expressed specifically in differentiating proheterocysts and heterocysts after nitrogen step-down. Strains overexpressing asr1734 and containing P(hetR)-gfp or P(patS)-gfp reporters failed to show normal patterned upregulation 24 h after nitrogen step-down even though hetR expression was upregulated at 6 h. Apparent orthologues of asr1734 are found only in two other filamentous nitrogen-fixing cyanobacteria, Anabaena variabilis and Nostoc punctiforme.     

Cell Wall Amidase AmiC1 Is Required for Cellular Communication and Heterocyst Development in the Cyanobacterium Anabaena PCC 7120 but Not for Filament Integrity

Filamentous cyanobacteria of the order Nostocales display typical properties of multicellular organisms. In response to nitrogen starvation, some vegetative cells differentiate into heterocysts, where fixation of N(2) takes place. Heterocysts provide a micro-oxic compartment to protect nitrogenase from the oxygen produced by the vegetative cells. Differentiation involves fundamental remodeling of the Gram-negative cell wall by deposition of a thick envelope and by formation of a neck-like structure at the contact site to the vegetative cells. Cell wall-hydrolyzing enzymes, like cell wall amidases, are involved in peptidoglycan maturation and turnover in unicellular bacteria. Recently, we showed that mutation of the amidase homologue amiC2 gene in Nostoc punctiforme ATCC 29133 distorts filament morphology and function. Here, we present the functional characterization of two amiC paralogues from Anabaena sp. strain PCC 7120. The amiC1 (alr0092) mutant was not able to differentiate heterocysts or to grow diazotrophically, whereas the amiC2 (alr0093) mutant did not show an altered phenotype under standard growth conditions. In agreement, fluorescence recovery after photobleaching (FRAP) studies showed a lack of cell-cell communication only in the AmiC1 mutant. Green fluorescent protein (GFP)-tagged AmiC1 was able to complement the mutant phenotype to wild-type properties. The protein localized in the septal regions of newly dividing cells and at the neck region of differentiating heterocysts. Upon nitrogen step-down, no mature heterocysts were developed in spite of ongoing heterocyst-specific gene expression. These results show the dependence of heterocyst development on amidase function and highlight a pivotal but so far underestimated cellular process, the remodeling of peptidoglycan, for the biology of filamentous cyanobacteria.     

Metabolic adaptations in a H2 producing heterocyst-forming cyanobacterium: potentials and implications for biological engineering

Nostoc punctiforme ATCC 29133 is a photoautotrophic cyanobacterium with the ability to fix atmospheric nitrogen and photoproduce hydrogen through the enzyme nitrogenase. The H(2) produced is reoxidized by an uptake hydrogenase. Inactivation of the uptake hydrogenase in N. punctiforme leads to increased H(2) release but unchanged rates of N(2) fixation, indicating redirected metabolism. System-wide understanding of the mechanisms of this metabolic redirection was obtained using complementary quantitative proteomic approaches, at both the filament and the heterocyst level. Of the total 1070 identified and quantified proteins, 239 were differentially expressed in the uptake hydrogenase mutant (NHM5) as compared to wild type. Our results indicate that the inactivation of uptake hydrogenase in N. punctiforme changes the overall metabolic equilibrium, affecting both oxygen reduction mechanisms in heterocysts as well as processes providing reducing equivalents for metabolic functions such as N(2) fixation. We identify specific metabolic processes used by NHM5 to maintain a high rate of N(2) fixation, and thereby potential targets for further improvement of nitrogenase based H(2) photogeneration. These targets include, but are not limited to, components of the oxygen scavenging capacity and cell envelope of heterocysts and proteins directly or indirectly involved in reduced carbon transport from vegetative cells to heterocysts.     

Regulation of expression of glutamine synthetase in a symbiotic Nostoc strain associated with Anthoceros punctatus.

A characteristic of N2-fixing cyanobacteria in symbiotic associations appears to be release of N2-derived NH4+. The specific activity of the primary ammonium-assimilating enzyme, glutamine synthetase (GS), was found to be three- to fourfold lower in Nostoc sp. strain 7801 grown in symbiotic association with the bryophyte Anthoceros punctatus than in free-living Nostoc sp. strain 7801. Quantitative immunological assays with antisera against GS purified from Nostoc sp. strain 7801 and from Escherichia coli indicated that similar amounts of the GS protein were present in symbiotic (50 micrograms mg-1) and free-living (68 micrograms mg-1) cultures. The conclusion from these experiments is that GS is regulated by a posttranslational mechanism in Anthoceros-associated Nostoc sp. strain 7801. However, the results of comparative catalytic and immunological experiments between N2- and NH4+-grown free-living Nostoc sp. strain 7801 implied control of GS synthesis. A correlation was not observed between the level of GS expression and the extent of symbiotic heterocyst differentiation in Nostoc sp. strain 7801 associated with A. punctatus.     

Molecular evolution of PAS domain-containing proteins of filamentous cyanobacteria through domain shuffling and domain duplication.

When the entire genome of a filamentous heterocyst-forming N2-fixing cyanobacterium, Anabaena sp. PCC 7120 (Anabaena) was determined in 2001, a large number of PAS domains were detected in signal-transducing proteins. The draft genome sequence is also available for the cyanobacterium, Nostoc punctiforme strain ATCC 29133 (Nostoc), that is closely related to Anabaena. In this study, we extracted all PAS domains from the Nostoc genome sequence and analyzed them together with those of Anabaena. Clustering analysis of all the PAS domains gave many specific pairings, indicative of evolutionary conservations. Ortholog analysis of PAS-containing proteins showed composite multidomain architecture in some cases of conserved domains and domains of disagreement between the two species. Further inspection of the domains of disagreement allowed us to trace them back in evolution. Thus, multidomain proteins could have been generated by duplication or shuffling in these cyanobacteria. The conserved PAS domains in the orthologous proteins were analyzed by structural fitting to the known PAS domains. We detected several subclasses with unique sequence features, which will be the target of experimental analysis.     

Increased heterocyst frequency by patN disruption in Anabaena leads to enhanced photobiological hydrogen production at high light intensity and high cell density

The effects of increasing the heterocyst-to-vegetative cell ratio on the nitrogenase-based photobiological hydrogen production by the filamentous heterocyst-forming cyanobacterium Anabaena sp. PCC 7120 were studied. Using the uptake hydrogenase-disrupted mutant (ΔHup) as the parent, a deletion-insertion mutant (PN1) was created in patN, known to be involved in heterocyst pattern formation and leading to multiple singular heterocysts (MSH) in Nostoc punctiforme strain ATCC 29133. The PN1 strain showed heterocyst differentiation but failed to grow in medium free of combined-nitrogen; however, a spontaneous mutant (PN22) was obtained on prolonged incubation of PN1 liquid cultures and was able to grow robustly on N₂. The disruption of patN was confirmed in both PN1 and PN22 by PCR and whole genome resequencing. Under combined-nitrogen limitation, the percentage of heterocysts to total cells in the PN22 filaments was 13–15 and 16–18% under air and 1% CO₂-enriched air, respectively, in contrast to the parent ΔHup which formed 6.5–11 and 9.7–13% heterocysts in these conditions. The PN22 strain exhibited a MSH phenotype, normal diazotrophic growth, and higher H₂ productivity at high cell concentrations, and was less susceptible to photoinhibition by strong light than the parent ΔHup strain, resulting in greater light energy utilization efficiency in H₂ production on a per unit area basis under high light conditions. The increase in MSH frequency shown here appears to be a viable strategy for enhancing H₂ productivity by outdoor cultures of cyanobacteria in high-light environments.

     

Arrangement of nitrogenase structural genes in an aerobic filamentous nonheterocystous cyanobacterium.

Members of the marine filamentous, nonheterocystous cyanobacterial genus Trichodesmium not only are capable of fixing nitrogen aerobically in the light but when grown under a light-dark cycle will fix nitrogen only during the light phase. In this study, we constructed a restriction map of the structural nitrogen fixation genes (nifHDK) in Trichodesmium sp. strain NIBB 1067. We found that the organization of the nif genes in Trichodesmium sp. strain NIBB 1067 is contiguous, as found in other nonheterocystous cyanobacteria and in heterocysts. Furthermore, the nif gene arrangement was identical when the cultures were grown with combined nitrogen or under nitrogen-fixing conditions. Therefore, no gene rearrangements occur, such as those that occur during the development of heterocysts in heterocystous species.     

Characterization of genes for a second Mo-dependent nitrogenase in the cyanobacterium Anabaena variabilis.

Anabaena variabilis ATCC 29413 is a filamentous heterocystous cyanobacterium that fixes nitrogen under a variety of environmental conditions. Under aerobic growth conditions, nitrogen fixation depends upon differentiation of heterocysts and expression of either a Mo-dependent nitrogenase or a V-dependent nitrogenase in those specialized cells. Under anaerobic conditions, a second Mo-dependent nitrogenase gene cluster, nifII, was expressed in vegetative cells long before heterocysts formed. A strain carrying a mutant gene in the nifII cluster did not fix nitrogen under anaerobic conditions until after heterocysts differentiated. The nifII cluster was similar in organization to the nifI cluster that is expressed in heterocysts and that includes nifBSUHDKENXW as well as three open reading frames that are conserved in both cyanobacterial nif clusters.     

Cellular differentiation and nitrogenase activity in the cyanobacteriumAnabaena

Nitrogenase activity at periods of differentiation of heterocysts and akinetes was assayed by the acetylene reduction technique. There was no nitrogenase activity in ammoniumgrown, non-heterocystousAnabaena sp.; the activity appeared only after a lag-phase of about 17 – 21 h after the ammonium-grown culture had been transferred to medium free of combined nitrogen. This activity started appearing as the proheterocysts were developing to mature heterocysts. Maximum nitrogenase activity was attained with exponential phase of culture and mature heterocysts. This activity gradually decreased with the differentiation of akinetes. Only insignificant nitrogenase activity was observed in old cultures in which most cells had matured into akinetes.     

A TolC-like protein is required for heterocyst development in Anabaena sp. strain PCC 7120

The filamentous cyanobacterium Anabaena sp. strain PCC 7120 forms heterocysts in a semiregular pattern when it is grown on N2 as the sole nitrogen source. The transition from vegetative cells to heterocysts requires marked metabolic and morphological changes. We show that a trimeric pore-forming outer membrane beta-barrel protein belonging to the TolC family, Alr2887, is up-regulated in developing heterocysts and is essential for diazotrophic growth. Mutants defective in Alr2887 did not form the specific glycolipid layer of the heterocyst cell wall, which is necessary to protect nitrogenase from external oxygen. Comparison of the glycolipid contents of wild-type and mutant cells indicated that the protein is not involved in the synthesis of glycolipids but might instead serve as an exporter for the glycolipid moieties or enzymes involved in glycolipid attachment. We propose that Alr2887, together with an ABC transporter like DevBCA, is part of a protein export system essential for assembly of the heterocyst glycolipid layer. We designate the alr2887 gene hgdD (heterocyst glycolipid deposition protein).