Mutational Engineering of the Cyanobacterium <Emphasis Type="Italic">Nostoc muscorum</Emphasis> for Resistance to Growth-Inhibitory Action of LiCl and NaCl

The effect of NaCl on two vital processes of cyanobacterial metabolism, viz. N₂ fixation and oxygenic photosynthesis, was studied in the cyanobacterium Nostoc muscorum grown diazotrophically. An increase in NaCl concentration suppressed the formation of heterocyst and adversely affected the nitrogenase activity in the parent, whereas in Li⁺-R and Na⁺-R mutants NaCl stress did not cause any adverse effect. The rate of photosynthetic O₂-evolution was also adversely affected by the NaCl stress, but the magnitude was less than that of nitrogenase activity. L-Proline, the well-known osmoprotectant, provided protection to the cyanobacterium against NaCl stress. The parent strain utilized L-proline as a nitrogen source and suppressed heterocyst formation and nitrogenase activity, while mutants showed normal heterocyst frequency and nitrogenase activity. Therefore, it may be that the proline metabolism is altered as a result of mutation. The intracellular levels of proline in the parent were enhanced about threefold in the medium containing 1 mol m⁻³ proline, while in mutants there was no significant increase in the intracellular level of proline. In the medium containing both NaCl and proline, the intracellular level of proline was enhanced in the parent as well as in both mutant strains. This suggests that the parent strain possessed both normal proline uptake and salt-induced proline uptake systems, whereas the mutant strains were defective in normal proline uptake and had only salt-induced proline uptake. The over-accumulation of proline in the presence of NaCl stress is due either to the loss of proline oxidase activity or to the accumulation of exogenous proline. Received: 10 July 2002 / Accepted: 13 August 2002     

Evidence for a sodium-dependent proline and glycine-betaine uptake in the cyanobacterium Nostoc muscorum

The cyanobacterium Nostoc muscorum is able to utilized proline and glycine-betaine as a nitrogen source under unstressed growth conditions. This cyanobacterium when grow in modified Chu No. 10 medium (without Na+) unable to utilized proline and glycine-betaine as a nitrogen source. Spontaneously occurring mutant clones defective in Na+ transport (Na+-R) were isolated and analyzed for proline and glycine-betaine utilization. The mutant phenotype showed normal heterocyst frequency and nitrogenase activity even in the medium containing 1 mM proline or 1 mM glycine-betaine, indicates the role of Na+ for proline/glycine-betaine uptake. The Na+-R mutant showed 100% survival at pH 11 and was simultaneously able to uptake and utilize proline/glycine-betaine at higher alkaline pH. This indicates that proline and glycine-betaine uptake systems are more efficient at higher alkaline pH. Since, the hypersaline environments are rich in Na+ contents and have alkaline pH, therefore it is suggested that the origin and evolution of specific compatible solutes may not depend only on the osmoregulatory role they play, but also on the other ecological factors operating simultaneously in the organism's niche.     

Evidence for a sodium-dependent proline and glycine-betaine uptake in the cyanobacterium <Emphasis Type="Italic">Nostoc muscorum</Emphasis>

The cyanobacterium Nostoc muscorum is able to utilized proline and glycine-betaine as a nitrogen source under unstressed growth conditions. This cyanobacterium when grow in modified Chu No. 10 medium (without Na⁺) unable to utilized proline and glycine-betaine as a nitrogen source. Spontaneously occurring mutant clones defective in Na⁺ transport (Na⁺-R) was isolated and analyzed for proline and glycine-betaine utilization. The mutant phenotype showed normal heterocyst frequency and nitrogenase activity even in the medium containing 1 mM proline or 1 mM glycine-betaine, indicates the role of Na⁺ for proline/glycine-betaine uptake. The Na⁺-R mutant showed 100% survival at pH 11 and was simultaneously able to uptake and utilize proline/glycine-betaine at higher alkaline pH. This indicates that proline and glycinebetaine uptake systems are more efficient at higher alkaline pH. Since, the hypersaline environments are rich in Na⁺ contents and have alkaline pH, therefore it is suggested that the origin and evolution of specific compatible solutes may not depend only on the osmoregulatory role they play, but also on the other ecological factors operating simultaneously in the organism’s niche.     

Differential response of NaCl-Resistant mutants of the cyanobacterium Nostoc muscorum to salinity and osmotic stresses

Summary In the parent strain of Nostoc muscorum, the percentage survival, nitrogenase activity and oxygenic photosynthesis were severely impaired by NaCl (ionic) and sucrose (non-ionic) stresses. Spontaneously occurring NaCl-Resistant mutant clones of the cyanobacterium N. muscorum were found to exhibit differential responses under ionic and non-ionic stresses. One of the mutants (NaCl-R) was found to show resistance in terms of percentage survival, nitrogenase activity and oxygenic photosynthesis under saline (ionic) as well as osmotic (non-ionic) stresses and showing compatible solute strategy for such adaptation. Another mutant (Na⁺-R) was found to show resistance only to salinity stress and showed an enhanced Na⁺-efflux system driven by H⁺. The Na⁺-R mutant differed from the NaCl-R mutant strain in the sense that it was sucrose sensitive.     

Genetically modified cyanobacteriumNostoc muscorum overproducing proline in response to salinity and osmotic stresses

In the parentNostoc muscorum an active proline oxidase enzyme is required to assimilate exogenous proline as a fixed nitrogen source. Cyanobacterial mutants, resistant to growth inhibitory action of proline analogue L-azetidine-2-carboxylate (Ac-R), were deficient in proline oxidase activity, and were over-accumulators of proline. Proline over-accumulation, resulting either from mutational acquisition of the Ac-R phenotype, or from salinity-induced uptake of exogenous proline, confirmed enhanced salinity/osmotic tolerance in the mutant strain. The nitrogenase activity and photosynthetic O₂ evolution of the parent were sensitive to both salinity as well as osmotic stresses than of Ac-R mutant strain. In addition, the mutation to Ac-resistant phenotype showed no alteration in salinity inducible potassium transport system in the cyanobacterium.     

Isolation and characterization of a metronidazole-resistant (Mtn-R) mutant strain of Nostoc muscorum affected in ammonium regulation of heterocyst formation and uptake hydrogenase activity

Abstract The metronidazole-resistant ( Mtn-R ) mutant strain of N. muscorum produced drug-resistant NADPH: ferredoxin (Fd) oxidoreductase and showed derepression of heterocyst formation and uptake hydrogenase activity in NH₄⁺-medium. The observation of NH₄⁺-repression in regulation of nitrogenase activity alone in the mutant strain suggests, that heterocyst formation and nitrogenase activity are regulated by two separate NH₄⁺-repression control systems, one specific for heterocyst and uptake hydrogenase and the other for nitrogenase. The partial drug-resistant NADPH: Fd oxidoreductase enzymatic activity seems to be the reason for drug-resistant growth of the cyanobacterium in N₂-medium and NH₄⁺-medium.     

Response to NaCl of nitrate assimilation and nitrogenase activity of the cyanobacterium Anabaena sp. PCC 7120 and its mutants

The presence of NaCl in the nutrient solution promoted nitrate uptake in parent Anabaena sp. PCC 7120, mutants SP7 (defective in nitrate reductase activity) and SP17 (partially defective in nitrate reductase activity), but not in the mutant SP9 (defective in nitrate transport and reduction). Nitrate reductase activity of the parent and mutant SP17 increased with increasing concentration of nitrate in saline medium, while mutants SP7 and SP9 did not respond to the altered salinity. Although Na⁺ was not required for nitrate reductase activity, its presence in the nutrient solution enhanced nitrate reduction. Complete removal of Na⁺ from the nutrient solution markedly reduced nitrogenase activity in all the strains, while raising the concentration of NaCl to 50 mmol l⁻¹ or above, was equally toxic to nitrogenase activity. External NaCl at 200 mmol l⁻¹ brought down the nitrogenase activity to the same residual level as observed without Na^+.     

Synthesis of nitrogenase in mutants of the cyanobacterium Anabaena sp. strain PCC 7120 affected in heterocyst development or metabolism.

Mutants of Anabaena sp. strain PCC 7120 that are incapable of sustained growth with air as the sole source of nitrogen were generated by using Tn5-derived transposons. Nitrogenase was expressed only in mutants that showed obvious morphological signs of heterocyst differentiation. Even under rigorously anaerobic conditions, nitrogenase was not synthesized in filaments that were unable to develop heterocysts. These results suggest that competence to synthesize nitrogenase requires a process that leads to an early stage of visible heterocyst development and are consistent with the idea that synthesis of nitrogenase is under developmental control (J. Elhai and C. P. Wolk, EMBO J. 9:3379-3388, 1990). We isolated mutants in which differentiation was arrested at an intermediate stage of heterocyst formation, suggesting that differentiation proceeds in stages; those mutants, as well as mutants with aberrant heterocyst envelopes and a mutant with defective respiration, expressed active nitrogenase under anaerobic conditions only. These results support the idea that the heterocyst envelope and heterocyst respiration are required for protection of nitrogenase from inactivation by oxygen. In the presence of air, such mutants contained less nitrogenase than under anaerobic conditions, and the Fe-protein was present in a posttranslationally modified inactive form. We conclude that internal partial oxygen pressure sufficient to inactivate nitrogenase is insufficient to repress synthesis of the enzyme completely. Among mutants with an apparently intact heterocyst envelope and normal respiration, three had virtually undetectable levels of dinitrogenase reductase under all conditions employed. However, three others expressed oxygen-sensitive nitrogenase activity, suggesting that respiration and barrier to diffusion of gases may not suffice for oxygen protection of nitrogenase in these mutants; two of these mutants reduced acetylene to ethylene and ethane.     

Anabaena sp. strain PCC 7120 gene devH is required for synthesis of the heterocyst glycolipid layer

In response to deprivation for fixed nitrogen, the filamentous cyanobacterium Anabaena sp. strain PCC 7120 provides a microoxic intracellular environment for nitrogen fixation through the differentiation of semiregularly spaced vegetative cells into specialized cells called heterocysts. The devH gene is induced during heterocyst development and encodes a product with characteristics of a trans-acting regulatory protein. A devH mutant forms morphologically distinguishable heterocysts but is Fox(-), incapable of nitrogen fixation in the presence of oxygen. We demonstrate that rearrangements of nitrogen fixation genes take place normally in the devH mutant and that it is Fix(+), i.e., has nitrogenase activity under anoxic conditions. The Fox(-) phenotype was shown by ultrastructural studies to be associated with the absence of the glycolipid layer of the heterocyst envelope. The expression of glycolipid biosynthetic genes in the mutant is greatly reduced, and heterocyst glycolipids are undetectable.     

Isolation and characterization of salinity resistant mutant of a nitrogen-fixing cyanobacterium, Anabaena doliolum

D.V. SINGH. A.K. TRIPATHI AND H.D. KUMAR. 1991. Sodium chloride, up to 20 mmol/l concentration, had a positive effect on acetylene reducing activity and photosynthetic oxygen evolution of a paddy field cyanobacterium, Anabaena doliolum. Beyond 20 mmol/l level of salinity adverse effects appeared. A mutant resistant to 200 mmol/l NaCl was isolated by nitrosoguanidine mutagenesis. The mutant, NaCl-R₂₀₀, showed about 20–25% more nitrogenase activity and photosynthetic oxygen evolution than the parent. Better capacity of nitrogen fixation and photosynthesis possibly could help the mutant in synthesis of osmotic stabilizer to resist the salinity stress.     

A high constitutive catalase activity confers resistance to methyl viologen-promoted oxidative stress in a mutant of the cyanobacterium Nostoc punctiforme ATCC 29133

A spontaneous methyl viologen (MV)-resistant mutant of the nitrogen-fixing cyanobacterium Nostoc punctiforme ATCC 29133 was isolated and the major enzymatic antioxidants involved in combating MV-induced oxidative stress were evaluated. The mutant displayed a high constitutive catalase activity as a consequence of which, the intracellular level of reactive oxygen species in the mutant was lower than the wild type (N. punctiforme) in the presence of MV. The superoxide dismutase (SOD) activity that consisted of a SodA (manganese-SOD) and a SodB (iron-SOD) was not suppressed in the mutant following MV treatment. The mutant was, however, characterised by a lower peroxidase activity compared with its wild type, and its improved tolerance to externally added H₂O₂ could only be attributed to enhanced catalase activity. Furthermore, MV-induced toxic effects on the wild type such as (1) loss of photosynthetic performance assessed as maximal quantum yield of photosystem II, (2) nitrogenase inactivation, and (3) filament fragmentation and cell lysis were not observed in the mutant. These findings highlight the importance of catalase in preventing MV-promoted oxidative damage and cell death in the cyanobacterium N. punctiforme. Such oxidative stress resistant mutants of cyanobacteria are likely to be a better source of biofertilisers, as they can grow and fix nitrogen in an unhindered manner in agricultural fields that are often contaminated with the herbicide MV, also commonly known as paraquat.     

Evidence for a role of glutamine synthetase in assimilation of amino acids as nitrogen source in the cyanobacterium Nostoc muscorum.

Methylammonium/ammonium ion, glutamine, glutamate, arginine and proline uptake, and their assimilation as nitrogen sources, was studied in Nostoc muscorum and its glutamine synthetase-deficient mutant. Glutamine served as nitrogen source independent of glutamine synthetase activity. Glutamate was not metabolised as a nitrogen source but still inhibited nitrogenase activity and diazotrophic growth. Glutamine synthetase activity was essential for the assimilation of N2, ammonia, arginine and proline as nitrogen sources but not for the control of their transport, heterocyst formation, and production of ammonia or aminoacid dependent repressor signal for N2-fixing heterocysts. These results also suggest that glutamine synthetase serves as the sole route of ammonia assimilation and glutamine synthesis, and ammonia per se as the repressor signal for N2-fixing heterocysts and methylammonium (ammonium) transport.     

Some characteristics of two morphological mutants of Nostoc linckia induced by nitrosoguanidine.

The blue-green alga Nostoc linckia was treated with nitrosoguanidine and two classes of morphological mutant clones were isolated. One class shows certain abnormal phenotypic features of vegetative cells, spores, and heterocysts. It has increased heterocyst frequency and impaired growth rate. The other class exhibits an altered heterocyst spacing pattern. Both classes of mutants have reduced nitrogenase activity.     

Evidence for ammonia as an inhibitor of heterocyst and nitrogenase formation in the cyanobacterium Anabaena cycadeae

Growth and regulation of heterocyst and nitrogenase by fixed nitrogen sources were studied comparatively in parent and glutamine auxotrophic mutant of Anabaena cycadeae. The parent strain grew well on N2, NH+4 or glutamine while the mutant strain grew on glutamine but not on N2 or NH+4. The total lack of active glutamine synthetase in the mutant strain thus appears to be the reason for its observed lack of growth in N2 or NH+4, which explains why it is a glutamine auxotroph and at the same time shows glutamine synthetase to be the sole primary ammonia assimilating enzyme. NH+4 repression of heterocyst and nitrogenase in the mutant and the parental strains and their derepression by L-methionine-DL-sulfoximine suggest that NH+4 per se and not glutamine synthetase mediated pathway of ammonia assimilation is the initial repressor signal of heterocyst and nitrogenase in A. cycadeae.     

PrpJ, a PP2C-type protein phosphatase located on the plasma membrane, is involved in heterocyst maturation in the cyanobacterium Anabaena sp. PCC 7120

Protein phosphatases play important roles in the regulation of cell growth, division and differentiation. The cyanobacterium Anabaena PCC 7120 is able to differentiate heterocysts specialized in nitrogen fixation. To protect the nitrogenase from inactivation by oxygen, heterocyst envelope possesses a layer of polysaccharide and a layer of glycolipids. In the present study, we characterized All1731 (PrpJ), a protein phosphatase from Anabaena PCC 7120. prpJ was constitutively expressed in both vegetative cells and heterocysts. Under diazotrophic conditions, the mutant DeltaprpJ (S20) did not grow, lacked only one of the two heterocyst glycolipids, and fragmented extensively at the junctions between developing cells and vegetative cells. No heterocyst glycolipid layer could be observed in the mutant by electron microscopy. The inactivation of prpJ affected the expression of hglE(A) and nifH, two genes necessary for the formation of the glycolipid layer of heterocysts and the nitrogenase respectively. PrpJ displayed a phosphatase activity characteristic of PP2C-type protein phosphatases, and was localized on the plasma membrane. The function of prpJ establishes a new control point for heterocyst maturation because it regulates the synthesis of only one of the two heterocyst glycolipids while all other genes so far analysed regulate the synthesis of both heterocyst glycolipids.     

Characterization of an NaCl-sensitive Staphylococcus aureus mutant and rescue of the NaCl-sensitive phenotype by glycine betaine but not by other compatible solutes.

To further study mechanisms of coping with osmotic stress-low water activity, mutants of Staphylococcus aureus with transposon Tn917-lacZ-induced NaCl sensitivity were selected for impaired ability to grow on solid defined medium containing 2 M NaCl. Southern hybridization experiments showed that NaCl-sensitive mutants had a single copy of the transposon inserted into a DNA fragment of the same size in each mutant. These NaCl-sensitive mutants had an extremely long lag phase (60 to 70 h) in defined medium containing 2.5 M NaCl. The osmoprotectants glycine betaine and choline (which is oxidized to glycine betaine) dramatically shortened the lag phase, whereas L-proline and proline betaine, which are effective osmoprotectants for the wild type, were ineffective. Electron microscopic observations of the NaCl-sensitive mutant under NaCl stress conditions revealed large, pseudomulticellular cells similar to those observed previously in the wild type under the same conditions. Glycine betaine, but not L-proline, corrected the morphological abnormalities. Studies of the uptake of L-[14C]proline and [14C]glycine betaine upon osmotic upshock revealed that the mutant was not defective in the uptake of either osmoprotectant. Comparison of pool K+, amino acid, and glycine betaine levels under NaCl stress conditions in the mutant and the wild type revealed no striking differences. Glycine betaine appears to have additional beneficial effects on NaCl-stressed cells beyond those of other osmoprotectants. The NaCl stress protein responses of the wild type and the NaCl-sensitive mutant were characterized and compared by labeling with L-[35 S]methionine and two-dimensional gel electrophoresis. The synthesis of 10 proteins increased in the wild type in response to NaCl stress, whereas the synthesis of these 10 proteins plus 2 others increased in response to NaCl stress in the NaCl-sensitive mutant. Five proteins, three of which were NaCl stress proteins, were produced in elevated amounts in the NaCl-sensitive mutant under unstressed conditions compared to the wild type. The presence of glycine betaine during NaCl stress decreased the production of three NaCl stress proteins in the mutant versus one in the wild type.     

Structure of the Escherichia coli 0104 polysaccharide and its identity with the capsular K9 polysaccharide

Spontaneous mutants of Rhizobium leguminosarum biovar viciae strain C1204b were selected for their ability to tolerate 0.2 M NaCl, a growth-inhibiting level of salt for the parental strain. Transposon-mediated salt-sensitive mutants of strain C1204b were screened for their inability to grow in 0.08 M NaCl. Quantitation of the free-amino acid pools in the mutants grown in NaCl revealed a dramatic increase in glutamine, serine, glutamate and proline, and to a lesser extent alanine and glycine in the salt-tolerant mutants in comparison with the parental strain exposed to NaCl; but only glutamate and proline increased in the salt-sensitive mutants under NaCl stress. Extracellular polysaccharide levels were quantitated for the salt-tolerant mutants and determined to be approximately two-fold higher than for the parental strain. Although the mutations that occurred in the NaCl-tolerant and NaCl-sensitive strains did not interfere with nodule formation, no nitrogenase activity could be observed in the NaCl tolerant mutants as evaluated by acetylene reduction.     

Isolation and characterisation of nitrate reductase mutants and regulation of nitrate reductase and nitrogenase in the cyanobacterium Nostoc muscorum

Summary Chlorate resistant mutants of the cyanobacterium Nostoc muscorum isolated after N-methyl-N-nitro-N-nitrosoguanidine (MNNG) mutagenesis were found to be defective/blocked in nitrate reductase (NR).The parent strain possessed active NR in the presence of nitrogen as nitrate and only basal levels of activity in ammonia and N-free grown cultures. Addition of ammonia suppressed the NR activity in the parent strain whereas addition of L-methionine DL-sulphoximine (MSX) restored NR activity. A similar repression by ammonia, glutamine and derepression with MSX were also observed for nitrogenase synthesis.One class of mutants lacked NR activity (nar ^-) whereas the specific activity of NR was low in another class of mutants (nar ^def). Unlike the parent, the mutants synthesized nitrogenase and differentiated heterocysts in the presence of nitrate nitrogen. Uptake studies of nitrite and ammonia in mutants revealed that they possessed both nitrite reductase and glutamine synthetases (GS) at low levels, and the same level respectively in comparison with the parent.     

Nitrogen fixation in Klebsiella pneumoniae during osmotic stress. Effect of exogenous proline or a proline overproducing plasmid

Osmotic stress, imposed by 0.5 M NaCl or other electrolytes and non-electrolytes, caused over a 100-fold reduction in the whole-cell nitrogen fixation activity of Klebsiella pneumoniae, wild-type strain M5A1. This reduction of nitrogen fixation activity could be reversed by the addition of proline to the culture medium at 0.5 mM concentration. With 0.5 M NaCl, in the presence of proline, nitrogenase activity was 47-fold greater than in the absence of proline. A mutation, originally isolated in Salmonella typhimurium, which resulted in proline over-production and enhanced osmotolerance, was transferred into K. pneumoniae by F' conjugation. Intracellular proline, synthesized at high levels because of the mutation, had similar stimulatory effects on nitrogen fixation under osmotic stress as proline provided exogenously. In the overproducing strain, the cellular level of proline is elevated as much as 125-fold during stress over that seen in the control strain. To determine the mechanism of stimulation of nitrogen fixation by proline during stress, the biosynthesis of nitrogenase polypeptides was studied. Net nitrogenase biosynthesis and the biosynthesis of other unidentified peptides, is strongly inhibited during osmotic stress; proline reverses the inhibition. The role of proline in enhancing nitrogen fixation during osmotic stress is discussed.     

Regulation of cytoplasmic proline levels in Salmonella typhimurium: effect of osmotic stress on synthesis, degradation, and cellular retention of proline.

I investigated the effects of osmotic stress on the synthesis and catabolism of proline in Salmonella typhimurium by measuring the intracellular and extracellular proline levels in various strains. In the wild-type strain, exposure to 0.8 M NaCl did not cause a significant change in the intracellular proline level; however, it brought about a 6.5-fold increase in the intracellular glutamate pool size. These results indicate that gamma-glutamyl kinase is inhibited by proline in wild-type cells in media of normal or elevated osmolarity. I also tested whether proline is subject to turnover in cells wild type with respect to the enzymes of the proline degradation pathway. In strains that were wild type for proline biosynthesis, the loss of the proline catabolic enzymes, due to putA mutations, did not result in a statistically significant increase in the intracellular proline levels. Therefore, in the wild-type strain, proline turnover does not seem to be important for control of the intracellular proline levels. However, in a proline-overproducing mutant, a putA lesion caused a threefold increase in the intracellular proline level and a 6.5-fold increase in the extracellular proline level, indicating that proline is subject to turnover in the overproducing mutant. The proline-overproducing mutants excreted large quantities of the proline into the culture medium; osmotic stress altered the partitioning of proline such that the ratio of intracellular to extracellular levels of proline increased with increased osmotic stress. The increased cellular retention of proline in media of high osmolarity is probably due to the functioning of the ProP and ProU proline transport systems, which are stimulated under conditions of osmotic stress.