Factors affecting growth and nitrogen fixation of Spirillum lipoferum.

Spirillum lipoferum grows vigorously on malate, succinate, lactate, or pyruvate, moderately on galactose or acetate, and poorly on glucose or citrate. It reduces 15N2. Acetylene reduction rates decrease rapidly when the pH of the culture rises above 7.8. The organism is highly aerobic and had doubling times as low as 2 h when grown on NH4+. However, S. lipoferum reduces N2 well only under microaerophilic conditions. The optimal pO2 for acetylene reduction by stagnant cultures was 0.006 to 0.02 atm depending upon the cell density; aerated cultures grew well at dissolved O2 concentration corresponding to a pO2 of about 0.008 atm. Shaking S. lipoferum with air temporarily inactivates its nitrogenase; reactivation is inhibited by chloramphenicol. The organism assimilated 20 to 24 mg of N/g of organic acid oxidized during growth. The strains studied can be placed in two groups based upon their morphology and physiological characteristics.     

Ecological distribution of Spirillum lipoferum Beijerinck.

A survey in various countries revealed that the N2-fixing Spirillum lipoferum Beijerinck is a very common root and soil inhabitant in the tropics. More than half of the grass root and soil samples collected in tropical countries (four African countries and Brazil) contained abundant S. lipoferum populations, while less than 10% of the samples collected in temperate South Brazil, Kenya, and the U.S.A. contained the organism. There is a pronounced vegetation effect. Panicum maximum seems the most favorable among the forage grasses, while few positive samples were found under virgin tropical forest. Legume roots contained less S. lipoferum than adjacent soils. More than 80% of the samples from cereal roots (maize, sorghum, wheat, and rye) grown in fields fertilized with PK and Mo, in Rio de Janeiro State, were positive. Maize and sorghum grown under similar conditions in Wisconsin contained less than 10% of positive samples, but when maize fields were inoculated 90% of the root samples contained S. lipoferum. Alluvial soils were more favorable than eroded hill soils. Occurrence in soil was strongly pH-dependent with a pH around 7, being optimal (correlation coefficient r = 0.90). Sporadic occurrence was observed even in soils with pH 4.8. Surface-sterilized P. maximum roots collected from soils with pH ranging from 4.8 to 7.2 contained high S. lipoferum numbers which did not correlate with soil pH (r = 0.41). Amendment with malate of acid soils was not very effective in increasing nitrogenase (N2-ase) activity, but in two soils with pH above 6.4, high N2-ase activity was obtained after 16 to 48 h of incubation. In two soils from a temperate climate region, inoculation with S. lipoferum increased N2-ase activity produced through malate amendment.     

Regulation of nitrogenase activity by oxygen in Azospirillum brasilense and Azospirillum lipoferum.

The nitrogenase activity of the microaerophilic bacteria Azospirillum brasilense and A. lipoferum was completely inhibited by 2.0 kPa of oxygen (approximately 0.02 atm of O2) in equilibrium with the solution. The activity could be partially recovered at optimal oxygen concentrations of 0.2 kPa. In contrast to the NH4+ switch off, no covalent modification of the nitrogenase reductase (Fe protein) was involved, as demonstrated by Western-blotting and 32P-labeling experiments. However, the inhibition of the nitrogenase activity under anaerobic conditions was correlated with covalent modification of the Fe protein. In contrast to the NH4+ switch off, no increase in the cellular glutamine pool and no modification of the glutamine synthetase occurred under anaerobic switch-off conditions. Therefore, a redox signal, independent of the nitrogen control of the cell, may trigger the covalent modification of the nitrogenase reductase of A. brasilense and A. lipoferum.     

Ammonium inhibition of nitrogenase activity in Herbaspirillum seropedicae.

The effect of oxygen, ammonium ion, and amino acids on nitrogenase activity in the root-associated N2-fixing bacterium Herbaspirillum seropedicae was investigated in comparison with Azospirillum spp. and Rhodospirillum rubrum. H. seropedicae is microaerophilic, and its optimal dissolved oxygen level is from 0.04 to 0.2 kPa for dinitrogen fixation but higher when it is supplied with fixed nitrogen. No nitrogenase activity was detected when the dissolved O2 level corresponded to 4.0 kPa. Ammonium, a product of the nitrogenase reaction, reversibly inhibited nitrogenase activity when added to derepressed cell cultures. However, the inhibition of nitrogenase activity was only partial even with concentrations of ammonium chloride as high as 20 mM. Amides such as glutamine and asparagine partially inhibited nitrogenase activity, but glutamate did not. Nitrogenase in crude extracts prepared from ammonium-inhibited cells showed activity as high as in extracts from N2-fixing cells. The pattern of the dinitrogenase and the dinitrogenase reductase revealed by the immunoblotting technique did not change upon ammonium chloride treatment of cells in vivo. No homologous sequences were detected with the draT-draG probe from Azospirillum lipoferum. There is no clear evidence that ADP-ribosylation of the dinitrogenase reductase is involved in the ammonium inhibition of H. seropedicae. The uncoupler carbonyl cyanide m-chlorophenylhydrazone decreased the intracellular ATP concentration and inhibited the nitrogenase activity of whole cells. The ATP pool was not significantly disturbed when cultures were treated with ammonium in vivo. Possible mechanisms for inhibition by ammonium of whole-cell nitrogenase activity in H. seropedicae are discussed.     

柱孢鱼腥藻固氮酶防氧的呼吸保护

柱孢鱼腥藻生长在缺氮情况下,发现其固氮活性增加的同时也减少了对氧的敏感性。缺氮生长细胞的乙炔还原活性给氧抑制一半时的氧分压(pO_2)是0.5atm.,而有氮生长细胞的半抑制浓度为0.35atm.。这表明蓝藻有可能通过增加呼吸耗氧而提高了它的固氮酶活性。呼吸作用与固氮酶活性之间存在着密切的关系。无论在有氮、缺氮还是光诱导固氮酶形成的情况下,其固氮活性均随着呼吸速率的变化而变化。本研究结果,支持了柱孢鱼腥藻固氮酶的主要防氧手段是呼吸保护的观点。     

Methods for Growing Spirillum lipoferum and for Counting It in Pure Culture and in Association with Plants

Methods are described for growing Spirillum lipoferum in quantities sufficient to serve as inoculant in field trials of its associative N₂-fixing ability with higher plants and as a source of cells for the preparation of nitrogenase, cytochromes, respiratory enzymes, etc. A heavy inoculum of S. lipoferum grown on NH₄⁺ was transferred to a medium of minimal nitrogen content, and initial rapid growth at the expense of residual combined nitrogen was replaced later by slower growth on N₂. Conversion to N₂ fixation was prompt upon exhaustion of fixed nitrogen; growth on N₂ was most rapid at a pO₂ of 0.005 to 0.007 atm. Numbers of S. lipoferum can be estimated by diluting soil, crushed roots, or other material, and inoculating diluted samples into a stagnant semisolid medium. Development of a characteristic subsurface layer of organisms and demonstration the these organisms can reduce C₂H₂ are presumptive evidence that they are S. lipoferum. With most-probable-number tables the observations can be converted to numbers of S. lipoferum in the samples. The most-probable-number method indicated that numbers of S. lipoferum may increase 100-fold or more in roots of maize removed from the plant and incubated for 24 h at 30°C at a pO₂ initially adjusted to 0.01 atm.     

Mechanism of Carbamyl Phosphate Inhibition of Nitrogenase of Clostridium pasteurianum

Carbamyl phosphate caused a maximal inhibition of 50% of the in vitro nitrogenase activity measured by acetylene reduction and dinitrogen reduction. The addition of 1 mM carbamyl phosphate to a N(2)-fixing culture caused a rapid decrease of 30% of the acetylene reduction activity and also repression of nitrogenase biosynthesis. However, carbamyl phosphate had no effect on the reductant-dependent adenosine triphosphate hydrolysis and H(2) evolution reactions catalyzed by nitrogenase. Studies on the binding of carbamyl phosphate to nitrogenase and each of its two components (azoferredoxin and molybdoferredoxin) indicated that optimal binding was obtained only in the presence of an operating nitrogenase system. Moreover, the binding seemed to be on the molybdoferredoxin component rather than azoferredoxin. From a Scatchard plot and a reciprocal plot of the data, the values of n = 2 and dissociation constant (K) of approximately 5 x 10(-5) M were obtained. The value for the dissociation constant was of the same order of magnitude as the endogenous level of carbamyl phosphate in a N(2)-fixing cell. The carbamyl phosphate pool in NH(3)-grown cells was twice that of N(2)-fixing cells.     

Role of molybdenum in dinitrogen fixation by Clostridium pasteurianum.

The role of Mo in the activity and synthesis of the nitrogenase components of Clostridium pasteurianum has been studied by observing the competition of Mo with its structural analogue W. Clostridial cells when fixing N2 appeared strictly dependent upon the available Mo, showing maximal N2-fixing activity at molybdate concentrations in the media of 10 muM. Cells grown in media with 3 times 10(-6) muM Mo, although showing good growth, had only 15% as much N2-fixing activity. In the presence of W the synthesis of both nitrogenase components, molybdoferredoxin and azoferredoxin, was affected. Attempts to produce nitrogenase in W-grown cells by addition of high molybdenum to the media in the presence of inhibitors of protein synthesis showed that Mo incorporation into a possible inactive preformed apoenzyme did not occur. Unlike other molybdoenzyme-containing cells, in which W either is incorporated in place of Mo to yield inactive protein or initiates the production of apoprotein, C. pasteurianum forms neither a tungsten substituted molybdoferredoxin nor an apoprotein. It is concluded that in C. pasteurianum molybdenum is an essential requirement for both the biosynthesis and activity of its nitrogenase.     

Effect of O2 on vesicle formation, acetylene reduction, and O2-uptake kinetics in Frankia sp. HFPCcI3 isolated from Casuarina cunninghamiana

The effect of the partial pressure of oxygen (PO2) on the formation of vesicles, which are thought to be the site of N2 fixation in Frankia, was studied in HFPCcI3, an effective isolate from Casuarina cunninghamiana. Unlike other actinorhizal root nodules, vesicles are not produced by the endophyte in Casuarina nodules. However, in culture under aerobic conditions, large, phase-bright vesicles are formed in HFPCcI3 within 20 h following removal of NH+4 from the culture medium and reach peak numbers within 72 to 96 h. In vivo acetylene reduction activity parallels vesicle formation. Optimum rates of acetylene reduction in short-term assays occurred at 20% O2 (0.2 atm (1 atm = 101.325 kPa] in the gas phase. O2 uptake (respiration) determined polarographically showed diffusion-limited kinetics and remained unsaturated by O2 until 300 microM O2. In contrast, respiration in NH+4-grown cells was saturated by O2 between 8 and 10 microM O2. These results indicate the presence of a diffusion barrier associated with the vesicles. Vesicle development was repressed in cells incubated in N-free media sparged with gas mixtures with PO2 between 0.001 and 0.003 atm. Nitrogenase was induced under these conditions, but acetylene reduction was extremely O2 sensitive. The kinetics of O2 uptake as a function of dissolved O2 concentration in avesicular cells were similar to those in NH+4-grown cells indicating the lack of a diffusion barrier. These results demonstrate that vesicle formation and the development of the O2 protection mechanisms of nitrogenase are regulated by ambient PO2 in HFPCcI3.     

In vivo energetics and control of nitrogen fixation: changes in the adenylate energy charge and adenosine 5'-diphosphate/adenosine 5'-triphosphate ratio of cells during growth on dinitrogen versus growth on ammonia.

The effects of the intracellular energy balance and adenylate pool composition on N2 fixation were examined by determining changes in the energy charge (EC) and the ADP/ATP (D/T) ratio of cells in chemostat and batch cultures of Clostridium pasteurianum, Klebsiella pneumoniae, and Azotobacter vinelandii. When cells of C. pasteurianum, K. pneumoniae, and A. vinelandii in sucrose-limited chemostats were examined, in all cases the EC increased greater than or equal to 15% when the nitrogen source was switched from N2 to NH3 and decreased greater than or equal to 15% when the nitrogen source was switched from NH3 to N2. The D/T ratio of the same cultures decreased greater than or equal to 70% when they were switched from N2 to NH3. In such cultures the adenylate pools remained constant when the cells were grown on either NH3 or N2. In nitrogen (NH3)-limited cultures, the adenylate pool was two- to threefold higher than the adenylate pool in sucrose-limited cultures, and the nitrogenase content of such cells was two- to threefold greater than the nitrogenase content of sucrose-limited N2-fixing cells. The EC and D/T ratio of cells from batch cultures of C. pasteurianum growing on NH3 in the presence of N2 were 0.82 and 0.83, respectively, but when the NH3 was consumed and the cells were switched to a nitrogen-fixing metabolism, the EC and D/T ratio changed to 0.70 and 0.90, respectively. Conversely, when NH3 was added to N2-fixing cultures the EC and D/T ratio changed within 1.5 h the EC and D/T ratio of NH3-grown cells. The nitrogen content of N2-fixing cells to which NH3 was added decreased at a rate greater could be accounted for by cell growth in the absence of further synthesis. This decay of nitrogenase activity (with a half-life about 1.2 to 1.4 h) suggests that some type of inactivation of nitrogenase occurs during repression. The nitrogenase of whole cells was estimated to be operating at about 32% of its theoretical maximum activity during steady-state N2-fixing conditions. Similarities in the data from chemostat and batch cultures of both aerobic and anaerobic N2-fixing organisms suggest that low EC and high D/T ratio are normal manifestations of an N2-fixing physiology.     

甘蔗茎内两个内生菌株16S rRNA 序列分析及其生长特性

从两个甘蔗品种GT11和RB86-7515表面灭菌的茎中分离到两株具有固氮活性的菌株,分别编号为B11S和B8S.利用16S rRNA序列分析对其进行鉴定,并对两个菌株的生物学特性进行了比较.结果表明:B11S菌株与Stenotrophomonas maltophili菌株处在同一个分支,其序列与多个Stenotrophomonas maltophili菌株的序列相似性都达到98%以上,菌株B8S与多个土壤杆菌属细菌的序列相似性达到100%;两个菌株在温度31℃、pH为6左右时生长量最高;温度31℃、pH为6.5～7.0时固氮酶活性最高;相同浓度的蔗糖生长量大于葡萄糖,且表达固氮酶活性也最强;添加一定量的氮素有利于细菌生长和固氮酶活性的表达,但随着N含量的增加,抑制作用越来越明显.     

Response of the endophytic diazotroph Gluconacetobacter diazotrophicus on solid media to changes in atmospheric partial O(2) pressure

Gluconacetobacter diazotrophicus is an N(2)-fixing endophyte isolated from sugarcane. G. diazotrophicus was grown on solid medium at atmospheric partial O(2) pressures (pO(2)) of 10, 20, and 30 kPa for 5 to 6 days. Using a flowthrough gas exchange system, nitrogenase activity and respiration rate were then measured at a range of atmospheric pO(2) (5 to 60 kPa). Nitrogenase activity was measured by H(2) evolution in N(2)-O(2) and in Ar-O(2), and respiration rate was measured by CO(2) evolution in N(2)-O(2). To validate the use of H(2) production as an assay for nitrogenase activity, a non-N(2)-fixing (Nif(-)) mutant of G. diazotrophicus was tested and found to have a low rate of uptake hydrogenase (Hup(+)) activity (0.016 +/- 0.009 micromol of H(2) 10(10) cells(-1) h(-1)) when incubated in an atmosphere enriched in H(2). However, Hup(+) activity was not detectable under the normal assay conditions used in our experiments. G. diazotrophicus fixed nitrogen at all atmospheric pO(2) tested. However, when the assay atmospheric pO(2) was below the level at which the colonies had been grown, nitrogenase activity was decreased. Optimal atmospheric pO(2) for nitrogenase activity was 0 to 20 kPa above the pO(2) at which the bacteria had been grown. As atmospheric pO(2) was increased in 10-kPa steps to the highest levels (40 to 60 kPa), nitrogenase activity decreased in a stepwise manner. Despite the decrease in nitrogenase activity as atmospheric pO(2) was increased, respiration rate increased marginally. A large single-step increase in atmospheric pO(2) from 20 to 60 kPa caused a rapid 84% decrease in nitrogenase activity. However, upon returning to 20 kPa of O(2), 80% of nitrogenase activity was recovered within 10 min, indicating a "switch-off/switch-on" O(2) protection mechanism of nitrogenase activity. Our study demonstrates that colonies of G. diazotrophicus can fix N(2) at a wide range of atmospheric pO(2) and can adapt to maintain nitrogenase activity in response to both long-term and short-term changes in atmospheric pO(2).     

Structural basis for VO<Superscript>2+</Superscript>-inhibition of nitrogenase activity: (B) pH-sensitive inner-sphere rearrangements in the <Superscript>1</Superscript>H-environment of the metal coordination site of the nitrogenase Fe–protein identified by ENDOR spectroscopy

The nitrogenase Fe-protein is the specific ATP-activated electron donor to the active site-containing nitrogenase MoFe-protein. It has been previously demonstrated that different VO(2+)-nucleotide coordination environments exist for the Fe-protein that depend on pH and are distinguishable by EPR spectroscopy. After having studied the nitrogenase 31P and 23Na superhyperfine structure for this system by electron nuclear double resonance (ENDOR) spectroscopy (Petersen et al. 2008 in J Biol Inorg Chem. doi:10.1007/s00775-008-0360-0), we here report on the 1H-interactions with the nucleotide-bound metal center after substitution of the natural diamagnetic metal Mg2+ with paramagnetic oxo-vanadium(IV). ENDOR spectra show a number of resonances arising from interactions of the VO2+ ion with protons. In the presence of reduced Fe-protein and VO2+ ADP, at least three sets of nonexchangeable protons are detected. At low pH the superhyperfine couplings of most of these are consistent with proton interactions originating from the nucleotide. There is no indication of 1H-resonances that exchange in D2O at neutral pH and could be assigned to inner-sphere hydroxyl coordination. Exchangeable hydroxyl protons in the inner coordination sphere with reduced Fe-protein are only found in the low pH form; based on their hyperfine tensor components these have been assigned to an axially coordinated hydroxyl water molecule. The pH-dependent alterations of the proton couplings that exchange in D2O suggest that they are partially caused by a rearrangement in the local hydroxyl coordination environment of the metal center. These rearrangements especially affect the apical metal position, where an axially coordinated water present at low pH is absent at neutral pH. Oxidation of the Fe-protein induced substantial changes in the electron-nucleus interactions. This indicates that the oxidation state of the iron-sulfur cluster has an important effect on the metal coordination environment at the nucleotide binding site of the Fe-protein. The distinct VO(2+)-nucleotide coordination structures with ADP and ATP and the redox state of the [4Fe-4S] cluster imply that VO2+ has a critical influence on the switch regions of the regulatory protein, and, taken together, this provides a plausible explanation for the inhibitory action of VO2+.     

Effects of phenoxy acid herbicides and glyphosate on nitrogenase activity (acetylene reduction) in root-associated Azospirillum, Enterobacter and Klebsiella

Abstract Nitrogenase activity (C₂H₂ reduction) in root-associated Azospirillum lipoferum, Klebsiella pneumoniae, Enterobacter agglomerans and Pseudomonas sp. isolated from roots of Finnish grasses was assayed in the presence of glyphosate, the phenoxy acid herbicides 2-methyl-4-chlorophenoxy acetic acid (MCPA), 2,4-dichlorophenoxy acetic acid (2,4-D), (±)-2-(2-methyl-4-chlorophenoxy)propionic acid (mecoprop) and (±)-2-(2,4-dichlorophenoxy)propionic acid (dichlorprop), and the commercial products Roundup, Nurmikko-Hedonal, Mepro, and Dipro. In the presence of the phenoxy acid herbicides the nitrogenase activity of K. pneumoniae was significantly inhibited, but that of E. agglomerans was stimulated. With the exception of Mepro and mecoprop no phenoxy acid herbicides inhibited the nitrogenase activity of A. lipoferum and none that of Pseudomonas sp. Nurmikko-Hedonal considerably stimulated the nitrogenase activity of E. agglomerans , and Pseudomanas sp. On the other hand, the nitrogenase activity of both K. pneumoniae and E. agglomerans was considerably repressed by glyphosate and Roundup, which also inhibited the growth of the bacteria. These chemicals had no effect on the growth of A. lipoferum and Pseudomonas sp., but stimulated their nitrogenase activity.     

Salinity effects on growth,photosynthetic parameters,and nitrogenase activity in estuarine planktonic cyanobacteria

Salinity has been suggested as being a controlling factor for blooms of N2-fixing cyanobacteria in estuaries. We tested the effect of salinity on the growth, N2 fixation, and photosynthetic activities of estuarine and freshwater isolates of heterocystous bloom-forming cyanobacteria. Anabaena aphanizomenoides and Anabaenopsis sp. were isolated from the Neuse River Estuary, North Carolina, and Cylindrospermopsis raciborskii from Lakes Dora and Griffin, central Florida. Salinity tolerance of these cyanobacteria was compared with that of two Nodularia strains from the Baltic Sea. We measured growth rates, N2 fixation (nitrogenase activity), and CO2 fixation at salinities between 0 and 20 g L(-1) NaCl. We also examined photosynthesis-irradiance relation-ships in response to salinity. Anabaenopsis maintained similar growth rates in the full range of salinities from 2 to 20 g L(-1) NaCl. Anabaena grew at up to 15 g L-', but the maximum salinity 20 g L(-1) NaCl was inhibitory. The upper limit for salinity tolerance of Cylindrospermopsis was 4 g L(-1) NaCl. Nodularia spp. maintained similar growth rates in the full range of salinities from 0 to 20 g L(-1) . Between 0 and 10 g L(-1), the growth rate of Nodularia spumigena was slower than that of the Neuse Estuary strains. In most strains, the sensitivity of nitrogenase activity and CO2 fixation to salinity appeared similar. Anabaenopsis, Anabaena, and the two Nodularia strains rapidly responded to NaCl by increasing their maximum photosynthetic rates (Pmn). Overall, both Neuse River Estuary and Baltic Sea strains showed an ability to acclimate to salt stress over short-(24 h) and long-term (several days to weeks) exposures. The study suggested that direct effect of salinity (as NaCl in these experiments) on cyanobacterial physiology does not alone explain the low frequency and magnitude of blooms of N2-fixing cyanobacteria in estuaries.     

Diurnal Nitrogenase Modification in the Cyanobacterium Anabaena variabilis*

The nitrogen-fixing cyanobacterium Anabaena variabilis (ATCC 29413) was cultivated as continuous culture under a 12 h: 12 h light-dark cycle. In the light, photosynthetic activity resulted in a continuous increase in cellular glycogen content, followed by an almost complete dissimilation of the polysaccharide during the dark period. Nitrogenase activity, assayed by the acetylene reduction technique, was low at the end of the dark period and increased quickly upon illumination to reach a maximum after 4 to 6 h of light. The activity rapidly declined after darkening the culture. Increase and decrease of activity were accompanied by a change in the electrophoretic mobility of the Fe-protein of nitrogenase (dinitrogenase reductase) indicative of enzyme modification being involved in the diurnal control of nitrogenase activity. Modification and demodification of the Fe-protein were not coupled to the cell cycle since they followed darkening and illumination when the light or dark periods were changed. Addition of fructose increased nitrogenase activity even in darkness and caused demodification of the Fe-protein. Ammonium chloride supplied at the onset of illumination slowed down the increase of nitrogenase activity. A delayed inhibition of the enzyme was accompanied by partial Feprotein modification only. The reaction was completed after transfer to darkness. The function of enzyme modification in maintaining a constant C: N ratio is discussed and a dominating role of carbohydrate supply in this regulation is indicated by the reported findings.     

Posttranslational regulatory system for nitrogenase activity in Azospirillum spp.

The mechanism for "NH4+ switch-off/on" of nitrogenase activity in Azospirillum brasilense and A. lipoferum was investigated. A correlation was established between the in vivo regulation of nitrogenase activity by NH4Cl or glutamine and the reversible covalent modification of dinitrogenase reductase. Dinitrogenase reductase ADP-ribosyltransferase (DRAT) activity was detected in extracts of A. brasilense with NAD as the donor molecule. Dinitrogenase reductase-activating glycohydrolase (DRAG) activity was present in extracts of both A. brasilense and A. lipoferum. The DRAG activity in A. lipoferum was membrane associated, and it catalyzed the activation of inactive nitrogenase (by covalent modification of dinitrogenase reductase) from both A. lipoferum and Rhodospirillum rubrum. A region homologous to R. rubrum draT and draG was identified in the genomic DNA of A. brasilense as a 12-kilobase EcoRI fragment and in A. lipoferum as a 7-kilobase EcoRI fragment. It is concluded that a posttranslational regulatory system for nitrogenase activity is present in A. brasilense and A. lipoferum and that it operates via ADP-ribosylation of dinitrogenase reductase as it does in R. rubrum.     

Effect of ammonia on the synthesis and function of the N 2 -fixing enzyme system in Clostridium pasteurianum

The N(2)-fixing system of Clostridium pasteurianum operates under regulatory controls; no activity is found in cultures growing on excess NH(3). The conditions which are necessary for the synthesis and function of this system were studied in whole cells by using acetylene reduction as a sensitive assay for the presence of the N(2)-fixing system. Nitrogenase of N(2)-fixing cultures normally can fix twice as much N(2) as is needed to maintain the growth rate. When cultures that have grown for four or more generations on NH(3) exhaust NH(3) from the medium, a diauxic lag of about 90 min ensues before growth is resumed on N(2). Neither N(2)-fixing nor acetylene reduction activity can be detected before growth is resumed on N(2). N(2) is not a necessary requirement for this synthesis since under argon that contains less than 10(-8)m N(2), the N(2)-fixing system is made. If NH(3) is added to N(2)-dependent cultures, synthesis of the enzyme system is abruptly stopped, but the enzyme already present remains stable and functional for at least 6 hr (over three generations). Cultures grown under argon in a chemostat controlled by limiting ammonia have derepressed nitrogenase synthesis. If the argon is removed and replaced by N(2), partial repression of nitrogenase occurs.     

NITROGENASE CONFINED TO RANDOMLY DISTRIBUTED TRICHOMES IN THE MARINE CYANOBACTERIUM TRICHODESMIUM THIEBAUTII1

Nitrogenase reductase (Fe-protein) was detected in the marine planktonic cyanobacterium Trichodesmium. The molecular weight was about 38 kD, as shown by western blotting using anti -Rhodospirillum rubrum nitrogenase reductase antiserum. The enzyme was confined to a limited number (ca. 10–40%) of randomly distributed trichomes in the Trichodesmium colonies, as shown by immunogold localization and transmission electron microscopy. Associated microorganisms had little or no nitrogenase. Nitrogenase showed a diel cycle in localization: present throughout the cytoplasm of cells in N₂-fixing (daytime) colonies but at the periphery of non-N₂-fixing (nighttime) colonies. This structural arrangement of N₂-fixing trichomes and nitrogenase is novel and different from the previously held paradigm for this and other diazotrophic cyanobacteria.     

Enumeration, isolation, and characterization of n(2)-fixing bacteria from seawater

Marine pelagic N(2)-fixing bacteria have not, in general, been identified or quantified, since low or negligible rates of N(2) fixation have been recorded for seawater when blue-green algae (cyanobacteria) are absent. In the study reported here, marine N(2)-fixing bacteria were found in all samples of seawater collected and were analyzed by using a most-probable-number (MPN) method. Two different media were used which allowed growth of microaerophiles, as well as that of aerobes and facultative anaerobes. MPN values obtained for N(2)-fixing bacteria ranged from 0.4 to 1 x 10 per liter for water collected off the coast of Puerto Rico and from 2 to 5.5 x 10 per liter for Chesapeake Bay water. Over 100 strains of N(2)-fixing bacteria were isolated from the MPN tubes and classified, yielding four major groups of NaCl-requiring bacteria based on biochemical characteristics. Results of differential filtration studies indicate that N(2)-fixing bacteria may be associated with phytoplankton. In addition, when N(2)-fixing bacteria were inoculated into unfiltered seawater and incubated in situ, nitrogenase activity could be detected within 1 h. However, no nitrogenase activity was detected in uninoculated seawater or when bacteria were incubated in 0.2-mum-filtered (phytoplankton-free) seawater. The ability of these isolates to fix N(2) at ambient conditions in seawater and the large variety of N(2)-fixing bacteria isolated and identified lead to the conclusion that N(2) fixation in the ocean may occur to a greater degree than previously believed.