Growth kinetics and nitrogenase induction inFrankia sp. HFPArI 3 grown in batch culture

Summary Kinetics of growth and nitrogenase induction inFrankia sp. Ar13 were studied in batch culture. Growth on defined medium with NH ₄ ⁺ as the N source displayed typical batch culture kinetics; however, a short stationary phase was followed by autolysis. Removal of NH ₄ ⁺ arrested growth and initiated vesicle differentiation. Vesicle numbers increased linearly and were paralleled by a rise in nitrogenase (acetylene reduction) activity. Nitrogenase activity (10 nM C₂H₄·mg protein^–1·min^–1) was sufficient to support growth on N₂ and protein levels rose in parallel with nitrogenase induction. Optimal conditions for vesicle and nitrogenase induction were investigated. Maximum rates of acetylene reduction were obtained with 5 to 10 mM K₂ HPO₄/KH₂PO₄, 0.1 mM CaCl₂ and MgSO₄. The optimum pH for acetylene reduction and respiration was around 6.7. The amount (5 to 10 g protein/ml) and stage (exponential) of growth of the ammonium-grown inoculum strongly influenced the subsequent development of nitrogenase activity. Propionate was the most effective carbon source tested for nitrogenase induction. Respiration in propionate-grown cells was stimulated by CO₂ and biotin, suggesting that propionate is metabolized via the propionyl CoA pathway.     

Regulation of nitrogenase levels in Anabaena sp. ATCC 33047 and other filamentous cyanobacteria

Incubation in the dark of photoautotrophically grown N₂-fixing heterocystous cyanobacteria leads to a loss of nitrogenase activity. Original levels of nitrogenase activity are rapidly regained upon re-illumination of the filaments, in a process dependent on de novo protein synthesis. Ammonia, acting indirectly through some of its metabolic derivatives, inhibits the light-promoted development of nitrogenase activity in filaments of Anabaena sp. ATCC 33047 and several other cyanobacteria containing mature heterocysts. The ammonia-mediated control system is also operative in N₂-fixing filaments in the absence of any added source of combined nitrogen, with the ammonia resulting from N₂-fixation already partially inhibiting full expression of nitrogenase. High nitrogenase levels, about two-fold higher than those in normal N₂-fixing Anabaena sp. ATCC 33047, are found in cell suspensions which have been treated with the glutamine synthetase inhibitor l-methionine-d,l-sulfoximine or subjected to nitrogen starvation. Filaments treated in either way are insensitive to the ammonia-promoted inhibition of nitrogenase development, although this insensitivity is only transitory for the nitrogen-starved filaments, which become ammonia-sensitive once they regain their normal nitrogen status.Abbreviations Chl chlorophyll - EDTA ethylenediaminetetraacetic acid - MSX l-methionine-d,l-sulfoximine     

Detection of pectolytic activity andpel homologous sequences inFrankia

Using a cup-plate pectin agar assay, pectolytic activity was detected in nodule filtrates obtained fromAlnus rugosa (DuRoi) Spreng,A. glutinosa (L.) Gaertn andA. crispa (Ait.) Pursh seedlings after infection with twoFrankia strains (ACN1 ^AG , CpI1). Pectolytic activity was also detected in cultures filtrates of the same twoFrankia isolates afterin vitro-cultivation on Qmod pectin liquid medium. When Southern blots of Frankia total DNAs from 3 isolates ofF. alni subsp.Pommerii (ACN1 ^AG , ArI3, and CPX32b) and 3 isolates ofF. elaeagni (EUN1 pec, SCN 10a and TX31e ^HR ) were hybridized withPelBDA probes fromErwinia chrysanthemi, positive signals were found in all 7 Frankiae tested.     

Concurrent evolution of nitrogenase genes and 16S rRNA in Rhizobium species and other nitrogen fixing bacteria

It was known that nitrogenase genes and proteins are well conserved even though they are present in a large variety of phylogenetically diverse nitrogen fixing bacteria. This has lead to the speculation, among others, that nitrogen fixation (nif) genes were spread by lateral gene transfer relatively late in evolution. Here we report an attempt to test this hypothesis.We had previously established the complete nucleotide sequences of the three nitrogenase genes from Bradyrhizobium japonicum, and have now analyzed their homologies (or the amino acid sequence homologies of their gene products) with corresponding genes (and proteins) from other nitrogen fixing bacteria. There was a considerable sequence conservation which certainly reflects the strict structural requirements of the nitrogenase iron-sulfur proteins for catalytic functioning. Despite this, the sequences were divergent enough to classify them into an evolutionary scheme that was conceptually not different from the phylogenetic positions, based on 16S rRNA homology, of the species or genera harboring these genes. Only the relation of nif genes of slow-growing rhizobia (to which B. japonicum belongs) and fast-growing rhizobia was unexpectedly distant. We have, therefore, performed oligonucleotide cataloguing of their 16S rRNA, and found that there was indeed only a similarity of S _AB=0.53 between fast- and slowgrowing rhizobia.In conclusion, the results suggest that nif genes may have evolved to a large degree in a similar fashion as the bacteria which carry them. This interpretation would speak against the idea of a recent lateral distribution of nif genes among microorganisms.     

Comparative physiology of nitrogenase activity and vesicle development for Frankia strains CpI1, ACN1 ag,EAN1pec and EUN1f

The relationship between nitrogen fixation and development of a specialized cell structure, called the vesicle, was studied using four Frankia isolates. Nitrogenase activity was repressed in all four strains during growth with ammonia. Strain CpI1 formed no vesicles during NH₄ growth. Strains ACN1 ^ag , EAN1_pec and EUN1_f produced low numbers of vesicles in the presence of ammonia. Following transfer to nitrogen-free media, a parallel increase in nitrogenase activity and vesicle numbers occurred with all four isolates. Appearance of nitrogenase activity was more rapid in those strains that possessed some vesicles at the time of shift to N₂ as a nitrogen source. The ratio of vesicle numbers to level of nitrogenase activity varied widely among the four strains and in response to different growth conditions and culture age of the individual strains. Optimum conditions of temperature, carbon and energy source, nitrogen source and availability of iron and molybdenum were different for each of the four strains. Those conditions that significantly reduced nitrogenase activity were always associated with decreased numbers of vesicles.     

Conservation of nif sequences in Frankia

Summary Southern blots of Frankia total DNAs were hybridized with nifHDK probes from Rhizobium meliloti, Klebsiella pneumoniae and Frankia strain Arl3. Differences between strains were noted in the size of the hybridizing restriction fragments. These differences were more pronounced among Elaeagnus-compatible strains than among Alnus- or Casuarina-compatible strains. Gene banks constructed for Frankia strains EUN1f, HRN18a, CeD and ACoN24d were used to isolate nif-hybridizing restriction fragments for subsequent mapping and comparisons. The nifH zone had the highest sequence conservation and the nifH and nifD genes were found to be contiguous. The complete nucleotide sequence of the nifH open reading frame (ORF) from Frankia strain Arl3 is 861 bp in length and encodes a polypeptide of 287 amino acids. Comparisons of these nucleic acid and amino acid sequences with other published nifH sequences suggest that Frankia is most similar to Anabaena and Azotobacter spp. and K. pneunoniae and least similar to the Gram-positive Clostridium pasteurianum and to the archaebacterium Methanococcus voltae.     

Primary structure and expression of a gene homologous to nifH (nitrogenase Fe protein) from the archaebacterium Methanococcus voltae

Summary In Methanococcus voltae, a 3.0 kbp HindIII fragment carrying homology to nifH was recently cloned. In Escherichia coli maxicells, the fragment directed the synthesis of a 30 K polypeptide encoded by the region homologous to nifH. Plasmids carrying the fragment did not complement Klebsiella pneumoniae nifH mutants and did not inhibit the nitrogen fixation of a Nif⁺ strain. The complete nucleotide sequence of the nifH homologous region was determined. It contained an open reading frame (ORFnifH) of 834 bp encoding 278 amino acid residues (mol. wt. 30,362). The ORFnifH was surrounded by regions of very high A+T content as observed with other mc. voltae genes. The region upstream from ORFnifH contained potential prokaryotic-like promoters and a potential ribosome binding site located 5 bp preceding the translation initiation codon. Using a translational fusion to lacZ of a DNA fragment carrying the putative promoter region and the 5 end of ORFnifH, it was shown in E. coli that (i) a promoter activity was effectively carried by the cloned fragment and (ii) this activity was not significantly modified by the presence of nifA or ntrC products provided by multicopy plasmids. Though the codon usage was characteristic of Mc. voltae, ORFnifH was very similar to eubacterial nifH genes, in particular the position of the cysteine residues was highly conserved. These data confirmed the high conservation of nifH sequences. S_AB values (binary matching coefficients) of 0.5 were found with eubacterial nifH genes at the nucleotide or amino acid level suggesting that the mc. voltae ORFnifH sequence was distantly related to eubacterial nifH sequences.     

Oxygen protection of nitrogenase in Frankia sp. HFPArI3

O₂ protection of nitrogenase in a cultured Frankia isolate from Alnus rubra (HFPArI3) was studied in vivo. Evidence for a passive gas diffusion barrier in the vesicles was obtained by kinetic analysis of in vivo O₂ uptake and acetylene reduction rates in response to substrate concentration. O₂ of NH ₄ ⁺ -grown cells showed an apparent K _m O₂ of approximately 1M O₂. In N₂-fixing cultures a second K _m O₂ of about 215 M O₂ was observed. Thus, respiration remained unsaturated by O₂ at air-saturation levels. In vivo, the apparent K _m for acetylene was more than 10-fold greater than reported in vitro values. These data were inter oreted as evidence for a gas diffusion barrier in the vesicles but not vegetative filaments of Frankia sp. HFPArI3.     

Nitrogen fixation in strains ofAzotobacter chroococcum bearing deletions of a cluster of genes coding for nitrogenase

Strains of the obligately aerobic nitrogen fixing organismAzotobacter chroococcum were constructed which contained defined chromosomal deletions in which the nitrogenase structural genenifHDK cluster (nifH for the polypeptide of the Fe-protein component of nitrogenase andnifD andnifK for the alpha and beta subunits respectively of the MoFe-protein component of the enzyme) was replaced by a kanamycin resistance gene. N₂ fixation was nevertheless observed in deletion strains though only in a molybdenum-deficient medium or in spontaneously arising tungstate-resistant derivatives. In comparison with the parent strain growing in molybdenum-sufficient medium, diazotrophic growth was slow and the nitrogenase activity in vivo was characterised by disproportionately low rates of C₂H₂-reduction compared to H₂-evolution and relative insensitivity of H₂-evolution to inhibition by C₂H₂. The findings show reiteration of functional structural genes for nitrogenase inA. chroococcum consistent with our previous observation of twonifH genes in this organism and detection in this work of a secondnifK-like sequence in the genomes of both parent and deletion strains whenA. chroococcum nifK DNA was used as a probe.     

Immunological characterization of nitrogenase in the filamentous non-heterocystous cyanobacterium Oscillatoria limosa

The filamentous non-heterocystous cyanobacterium Oscillatoria limosa was subjected to Western blot analyses using two antisera raised against the small subunit (Fe-protein) of the nitrogenase complex. Two polypeptides were recognized in nitrogen-fixing cultures irrespective of the antiserum used while no bands were detectable in nitrate-grown cultures. The apparent molecular weights of the two polypeptides were approximately 40.5 and 39.5 kDa respectively, with the former, probably an inactive form, dominating. In situ immunogold electron microscopy was used to reveal the cellular and subcellular localization on the Fe-protein. All cells of the trichomes of nitrogen-fixing O. limosa showed a dense label. The label was homogeneously distributed throughout the cytoplasm including the thylakoid area. Nitrate-grown cultures contained a very low label.Abbreviations SDS sodium dodecyl sulfate - PAGE polyacrylamide gel electrophoresis This study was supported by the Swedish Natural Science Research Counsil and the M. and M. Wallenberg Fund (to B. Bergman). We are grateful to Dr. S. Nordlund (University of Stockholm, Sweden) for providing us with the antiserum of Rhodospirillum rubrum nitrogenase and to Drs. S. Reich and P. Böger (University of Konstanz, FRG) for the antiserum of Anabaena variabilis. Skilful technical assistence by K. Östlund and E. Danielsson is gratefully acknowledged. We would also like to thank M. Villbrandt (University of Oldenburg, FRG) for providing cultures of Oscillatoria limosa and Dr. P. Lindblad for valuable discussions and suggestions.To whom correspondence should be addressed.     

Regulation of nitrogenase activity by covalent modification in Chromatium vinosum

Nitrogenase in Chromatium vinosum was rapidly, but reversibly inhibited by NH ₄ ⁺ . Activity of the Fe protin component of nitrogenase required both Mn²⁺ and activating enzyme. Activating enzyme from Rhodospirillum rubrum could replace Chromatium chromatophores in activating the Chromatium Fe protein, and conversely, a protein fraction prepared from Chromatium chromatophores was effective in activating R. rubrum Fe protein. Inactive Chromatium Fe protein contained a peptide covalently modified by a phosphate-containing molecule, which migrated the same in SDS-polyacrylamide gels as the modified subunit of R. rubrum Fe protein. In sum, these observations suggest that Chromatium nitrogenase activity is regulated by a covalent modification of the Fe protein in a manner similar to that of R. rubrum.Abbreviation HEPES N-2-hydroxyethyl piperazine-N-2-ethanesulfonic acid     

Organic acids and prolonged nitrogenase activity by non-growing,free-living Rhizobium japonicum

Rhizobium japonicum 61-A-101 grew and fixed nitrogen more effectively on media containing an organic acid and a pentose sugar than on media containing only one of these carbon sources. Peak specific activities in the range 10–15 nmol C₂H₄ · h^-1 · mg protein^-1 were found for these organisms in a spot of growth about 1 cm diameter on agar surfaces exposed to air. Increasing concentrations of the organic acids (succinate or malonate) in a medium containing arabinose resulted in longer lasting activity. The inclusion of a third carbon source, glycerol, gave activity which remained at the maximum from about the 8 to the 18 day after inoculation although no growth of the bacteria occurs during the last 8 or 10 days. At low concentration of organic acid l-arabinose was a much better carbon source for supporting nitrogenase activity of these organisms that the d-form. Both organic acids affected the morphology of the bacteria. Higher concentrations, especially of malonate, gave swollen and distorted cells. When bacteria growing on organic acid-containing agar plates were suspended and plated after appropriate dilution on yeast extract — mannitolglycerol agar there was heterogeneity of colony form, with up to 90% microcolonies after growth on high malonate concentrations. The effects of malonate may be correlated with characteristics of the bacteroid form inside the nodule which contains relatively high concentrations of organic acids, especially malonate.     

Lipid composition and nitrogenase activity of symbioticFrankia (Alnus incana) in response to different oxygen concentrations

Summary The role ofFrankia vesicle envelope lipids in regulating oxygen diffusion of symbiotic nitrogen fixation inAlnus incana was examined. Total lipids of symbioticFrankia (vesicle clusters) that had been adapted to oxygen tensions of 5,21, or 40 kPa were analyzed with a normal phase HPLC system. During the oxygen treatment, nitrogenase activity was measured as hydrogen evolution in an open flow-through system. When plants were transferred to low oxygen (5 kPa) or high oxygen (40 kPa), nitrogenase activity dropped initially. Activity recovered in both treatments with a rate comparable to the controls (21 kPa O₂). Both lipid content and lipid composition of vesicle clusters were affected by the oxygen treatments. With increasing oxygen tension, the vesicle cluster lipid content increased. This correlated with structural data (fluorescence microscopy and TEM) which showed a thicker vesicle envelope at higher oxygen tension. Three hopanoid lipids, bacteriohopanetetrol (bht) and two isomers of phenylacetyl monoester of bht, made up approximately 80% of the vesicle cluster lipids. With changing oxygen concentrations, the ratio of the two bht esters changed whereas the relative proportion of bht remained fairly constant. Therefore, in theFrankia-Alnus incana symbiosis, adaptation to different ambient oxygen tensions occurs at least partly by increasing the thickness of theFrankia vesicle envelope and by changing its lipid composition.Abbreviations dw dry weight - bht bacteriohopanetetrol - SE standard error - TEM transmission electron microscopy Dedicated to the memory of Professor John G. Torrey     

Effect of spring flooding on endophyte differentiation,nitrogenase activity,root growth and shoot growth inMyrica gale

Summary Spring flooding was investigated as a possible limiting factor in the development of nitrogenase activity, root growth, and shoot growth inMyrica gale. Dormant, one year oldMyrica gale plants were placed in a greenhouse in early April and given three treatments: control (not flooded), flooded-water (flooded with water to 2.5 cm above the soil level) and flooded-peat (flooded with water-saturated peat to 4.0 cm above the soil level). Nitrogenase activity was absent at budbreak but appeared concurrently with the differentiation of vesicles by theFrankia sp. endophyte. Flooding delayed the onset of nitrogenase activity, substantially reduced the specific nitrogenase activity of the nodules, and also severely limited the production of the new nodule biomass. Consequently by 67 days past budbreak nitrogenase activity was much greater in the control plants (5.55±0.42 mol C₂H₄/plant.h; ± SE; N=9) than in the flooded-water (1.18±0.29) and flooded-peat (0.15±0.05) plants. Production of new secondary roots was substantially reduced in the flooded plants but adventitious roots were rapidly produced along the flooded portion of the stem in the better aerated zone near the surface. New nodules formed on several adventitious roots by 67 days indicating that the plants are able to replace their largely nonfunctional deeply flooded nodules with new nodules in the aerobic zone. Initially shoot growth was unaffected by flooding but by 67 days the flooded plants had substantially less leaf biomass, lower leaf and stem nitrogen concentrations, and less total shoot nitrogen content than the control plants.     

Growth,acetylene reduction activity and localization of nitrogenase in relation to vesicle formation in Frankia strains Cc1.17 and Cp1.2

A comparative study was conducted on the effect of NH₄Cl on growth, vesicle formation and formation of nitrogenase of Frankia strains Cc1.17 and Cp1.2, derived from root nodules of Colletia cruciata and Comptonia peregrina, respectively. On a medium without combined nitrogen (P-N), both strains formed spherical cells, called vesicles, like many other Frankia strains. Data are presented on the number of vesicles per mg protein, after cultivation in media with sodium propionate as C-source without combined nitrogen (P-N) or with 0.2 g NH₄Cl/l (P+N). Strain Cp1.2 as may other Frankia strains, showed on P+N medium a very strong reduction of vesicle formation of 99% relative to the number of vesicles formed on P-N medium, after 11 days growth. However, in strain Cc11.17 this reduction was only 70%. The occurence of relatively large numbers of vesicles in P+N media has not yet been reported for other Frankia strains. No acetylene reduction activity was found in NH ₄ ⁺ -grown cells. The regulation of induction of nitrogenase in Frankia by NH₄Cl was tested by immuno-gelectrophoresis using antisera against nitrogenase of Rhizobium leguminosarum PRE. The component I of the enzyme showed crossreactivity while the component II had only a weak crossreaction. The experiments indicated that no nitrogenase was detectable in the NH ₄ ⁺ -grown cells. For the localization of nitrogenase, relative amounts of the enzyme were compared in whole cells and vesicle-enriched fractions. Western blots showed a significant enrichment of nitrogenase in the vesicle fractions, which indicated that most of the nitrogenase was localized in the vesicle.     

Effects of oxygen and chloramphenicol on Frankia nitrogenase activity

The kinetics of asymbiotic nitrogenase activity in three strains of the actinomycete Frankia were studied. Decay rates for enzyme activity were determined by adding chloramphenicol to active acetylene-reducing cells and measuring the time required for all activity to cease. Synthesis rates were measured by bubbling oxygen through actively-reducing cells (which totally destroyed all activity) and then measuring the time required for activity to return to normal. Decay rates (t _1/2) for these three strains were approximately 30 to 40 min. Synthesis rates were slower and initial nitrogenase activities were recorded about 110 min (DDB 011610) or 210 min (DDB 020210 and WgCc1.17) after return to air-equilibrated cultures. Frankia strain WgCc1.17 showed a greater sensitivity to oxygen and nitrogenase activity was totally lost when cells were bubbled only with atmospheric concentrations of oxygen. The results presented here indicate that nitrogenase activity turnover time is relatively rapid, on the order of minutes rather than hours or days. However, regulation of nitrogenase activity will differ from one strain to another and asmmbiotic characterization will be useful for understanding nitrogenase regulation in the bacterial-plant symbiosis.Contribution no. 879 from the Battelle-Kettering Laboratory     

Phylogeny of the Drosophila obscura species group deduced from mitochondrial DNA sequences

Approximately 2 kb corresponding to different regions of the mtDNA of 14 different species of the obscura group of Drosophila have been sequenced. In spite of the uncertainties arising in the phylogenetic reconstruction due to a restrictive selection toward a high mtDNA A+T content, all the phylogenetic analysis carried out clearly indicate that the obscura group is formed by, at least, four well-defined lineages that would have appeared as the consequence of a rapid phyletic radiation. Two of the lineages correspond to monophyletic subgroups (i.e., afftnis and pseudoobscura), whereas the obscura subgroup remains heterogeneous assemblage that could be reasonably subdivided into at least two complexes (i.e., subobscura and obscura).     

Activity and expression of nitrogenase in Rhodobacter capsulatus under aerobiosis in the dark and in the light

Rhodobacter capsulatus was grown chemotrophically in the dark in oxygen-regulated chemostat culture and in the presence of limiting amounts of fixed N. When the oxygen partial pressure was varied, in situ nitrogen fixation occurred only at 1% of air saturation of the medium. By contrast, nitrogenase proteins and their activity measured in the absence of oxygen could be detected up to 30% of air saturation. This revealed that expression of nitrogenase is much less sensitive toward oxygen than the in situ function of the enzyme. At oxygen partial pressures > 1% of air saturation, the degree of modification of the Fe protein of nitrogenase was increased. Light was of no stimulatory effect on both the activity and the expression of nitrogenase. This holds true for growth at 1% or 5% of air saturation. At 5% of air saturation, however, high illumination enhanced the inhibitory effect of oxygen on nitrogenase formation.     

Effect of nitrogen starvation on ammonium-inhibition of nitrogenase activity in Azotobacter chroococcum

When Azotobacter chroococcum cells grown in batch culture under N₂-fixing conditions were transferred to a medium lacking a nitrogen source, the cellular C/N ratio, the amount of alginic acid released into the external medium and the rate of endogenous respiration increased appreciably after 6 h to the exclusion of dinitrogen, whereas nitrogenase activity did not undergo any significant change. Nitrogen deficiency caused a decrease in the ammonium inhibition of nitrogenase activity from 95% inhibition at zero time to 14% after 6 h incubation under dinitrogen starvation, with no difference in the rate of ammonium utilization by N₂-fixing and N₂-starved cells being observed. This suggests that a balance of nitrogen and carbon assimilation is necessary for the ammonium inhibition of nitrogenase activity in A. chroococcum to take place.