Response of the Endophytic Diazotroph Gluconacetobacter diazotrophicus on Solid Media to Changes in Atmospheric Partial O2 Pressure

Gluconacetobacter diazotrophicus is an N₂-fixing endophyte isolated from sugarcane. G. diazotrophicus was grown on solid medium at atmospheric partial O₂ pressures (pO₂) 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 pO₂ (5 to 60 kPa). Nitrogenase activity was measured by H₂ evolution in N₂-O₂ and in Ar-O₂, and respiration rate was measured by CO₂ evolution in N₂-O₂. To validate the use of H₂ production as an assay for nitrogenase activity, a non-N₂-fixing (Nif⁻) mutant of G. diazotrophicus was tested and found to have a low rate of uptake hydrogenase (Hup⁺) activity (0.016± 0.009 μmol of H₂ 10¹⁰ cells⁻¹ h⁻¹) when incubated in an atmosphere enriched in H₂. However, Hup⁺ activity was not detectable under the normal assay conditions used in our experiments. G. diazotrophicus fixed nitrogen at all atmospheric pO₂ tested. However, when the assay atmospheric pO₂ was below the level at which the colonies had been grown, nitrogenase activity was decreased. Optimal atmospheric pO₂ for nitrogenase activity was 0 to 20 kPa above the pO₂ at which the bacteria had been grown. As atmospheric pO₂ 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 pO₂ was increased, respiration rate increased marginally. A large single-step increase in atmospheric pO₂ from 20 to 60 kPa caused a rapid 84% decrease in nitrogenase activity. However, upon returning to 20 kPa of O₂, 80% of nitrogenase activity was recovered within 10 min, indicating a “switch-off/switch-on” O₂ protection mechanism of nitrogenase activity. Our study demonstrates that colonies of G. diazotrophicus can fix N₂ at a wide range of atmospheric pO₂ and can adapt to maintain nitrogenase activity in response to both long-term and short-term changes in atmospheric pO₂.     

N(2) fixation by bacteria associated with maize roots at a low partial o(2) pressure

Nitrogen fixation by bacteria associated with roots of intact maize plants was measured by exposing the roots to N(2) at a partial O(2) pressure (pO(2)) of 2 or 10 kPa. The plants were grown in a mixture of Weswood soil and sand and then transferred to plastic cylinders containing an N-free plant nutrient solution. The solution was sparged continuously with a mixture of air and N(2) at a pO(2) of 2 or 10 kPa. Acetylene reduction was measured after the roots were exposed to the low pO(2) overnight. The air-N(2) atmosphere in the cylinders was then replaced with an O(2)-He atmosphere at the same pO(2), and the roots were exposed to 20 kPa of N(2) for 20 to 22 h. Incorporation of N into the roots was 200 times greater at 2 kPa of O(2) than at 10 kPa of O(2). Adding l-malate (1 g of C liter) to the nutrient solution increased root-associated nitrogenase activity, producing a strong N label which could be traced into the shoots. Fixed N was detected in the shoots within 5 days after the plants were returned to unfertilized soil. In a similar experiment with undisturbed plants grown in fritted clay, movement of fixed N into the shoots was evident within 4 days after the roots were exposed to N(2) at 2 kPa of O(2). Inoculation with Azospirillum lipoferum yielded no significant differences in shoot dry weight, total nitrogen content, percent nitrogen, or N enrichment of plant tissues. Inoculated plants did exhibit greater root dry weight than uninoculated plants, however.     

Nitrogenase activity in Alnus incana root nodules. Responses to O(2) and short-term N(2) deprivation

O(2) and host-microsymbiont interactions are key factors affecting the physiology of N(2)-fixing symbioses. To determine the relationship among nitrogenase activity of Frankia-Alnus incana root nodules, O(2) concentration, and short-term N(2) deprivation, intact nodulated roots were exposed to various O(2) pressures (pO(2)) and Ar:O(2) in a continuous flow-through system. Nitrogenase activity (H(2) production) occurred at a maximal rate at 20% O(2). Exposure to short-term N(2) deprivation in Ar:O(2) carried out at either 17%, 21%, or 25% O(2) caused a decline in the nitrogenase activity at 21% and 25% O(2) by 12% and 25%, respectively. At 21% O(2), nitrogenase activity recovered to initial activity within 60 min. The decline rate was correlated with the degree of inhibition of N(2) fixation. Respiration (net CO(2) evolution) decreased in response to the N(2) deprivation at all pO(2) values and did not recover during the time in Ar:O(2). Increasing the pO(2) from 21% to 25% and decreasing the pO(2) from 21% to 17% during the decline further decreased rather than stimulated nitrogenase activity, showing that the decline was not due to O(2) limitation. The decline was possibly due to a temporary disturbance in the supply of reductant to nitrogenase with a partial O(2) inhibition of nitrogenase at 25% O(2). These results are consistent with a fixed O(2) diffusion barrier in A. incana root nodules, and show that A. incana nodules differ from legume nodules in the response of the nitrogenase activity to O(2) and N(2) deprivation.     

Influence of carbon and nitrogen sources on growth, nitrogenase activity, and carbon metabolism of Gluconacetobacter diazotrophicus

The effects of different carbon and nitrogen sources on the growth, nitrogenase activity, and carbon metabolism of Gluconacetobacter diazotrophicus were investigated. The amino acids asparagine, aspartic acid, and glutamic acid affected microbial growth and nitrogenase activity. Several enzymatic activities involved in the tricarboxylic acid cycle were affected by the carbon source used. In addition, glucose and gluconate significantly increased the oxygen consumption (respiration rate) of whole cells of G. diazotrophicus grown under aerobic conditions. Enzymes responsible for direct oxidation of glucose and gluconate were especially active in cells grown with sucrose and gluconate. The presence of amino acids in the apoplastic and symplastic sap of sugarcane stems suggests that these compounds might be of importance in the regulation of growth and nitrogenase activity during the symbiotic association. The information obtained from the plant-bacterium association together with the results of other biochemical studies could contribute to the development of biotechnological applications of G. diazotrophicus.     

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。     

Energy generation by extracellular aldose oxidation in N(2)-fixing Gluconacetobacter diazotrophicus

Gluconacetobacter diazotrophicus PAL3 was grown in a chemostat with N(2) and mixtures of xylose and gluconate. Xylose was oxidized to xylonate, which was accumulated in the culture supernatants. Biomass yields and carbon from gluconate incorporated into biomass increased with the rate of xylose oxidation. By using metabolic balances it is demonstrated that extracellular xylose oxidation led N(2)-fixing G. diazotrophicus cultures to increase the efficiency of energy generation.     

Oxygen relations of nitrogen fixation in cyanobacteria.

The enigmatic coexistence of O2-sensitive nitrogenase and O2-evolving photosynthesis in diazotrophic cyanobacteria has fascinated researchers for over two decades. Research efforts in the past 10 years have revealed a range of O2 sensitivity of nitrogenase in different strains of cyanobacteria and a variety of adaptations for the protection of nitrogenase from damage by both atmospheric and photosynthetic sources of O2. The most complex and apparently most efficient mechanisms for the protection of nitrogenase are incorporated in the heterocysts, the N2-fixing cells of cyanobacteria. Genetic studies indicate that the controls of heterocyst development and nitrogenase synthesis are closely interrelated and that the expression of N2 fixation (nif) genes is regulated by pO2.     

Uptake hydrogenase activity and ATP formation in Rhizobium leguminosarum bacteroids.

The role of uptake hydrogenase was studied in Rhizobium leguminosarum bacteroids from the nodules of Pisum sativum L. cv. Homesteader. Uptake hydrogenase activity, measured by the 3H2 uptake method, was dependent on O-consumption and was similar to H2 uptake measured by gas chromatography. Km for O2 of 0.0007 atm (0.0709 kPa) and a Km for H2 of 0.0074 atm (0.7498, kPa) were determined. H2 increased the rate of endogenous respiration by isolates with uptake hydrogenase (Hup+) but had no effect on an isolate lacking uptake hydrogenase (Hup-). A survey of 14 Hup+ isolates indicated a wide range of H2 uptake activities. Four of the isolates tested had activities similar to or higher than those found in two Hup+ Rhizobium japonicum strains. H2 uptake was strongly coupled to ATP formation in only 5 of the 14 isolates. H2 increased the optimal O2 level of C2H2 reduction by 0.01 atm and permitted enhanced C2H2 reduction at O2 levels above the optimum in both a coupled and an uncoupled isolate. At suboptimal O2 concentrations a small enhancement of C2H2 reduction by H2 was seen in two out of three isolates in which H2 oxidation was coupled to ATP formation. Thus, the main function of uptake hydrogenase in R. leguminosarum appears to be in the protection of nitrogenase from O2 damage.     

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.     

Role of Oxygen in the Limitation and Inhibition of Nitrogenase Activity and Respiration Rate in Individual Soybean Nodules

Although infected cell O2 concentration (Oi) is known to limit respiration and nitrogenase activity in legume nodules, techniques have not been available to measure both processes simultaneously in an individual legume nodule. Consequently, details of the relationship between nitrogenase activity and Oi are not fully appreciated. For the present study, a probe was designed that allowed open circuit measurements of H2 evolution (nitrogenase activity) and CO2 evolution (respiration rate) in a single attached soybean nodule while simultaneously monitoring fractional oxygenation of leghemoglobin (and thereby Oi) with a nodule oximeter. Compared to measurements of whole nodulated roots, use of the probe led to inhibition of nitrogenase activity in the single nodules. During oximetry measurements, total nitrogenase activity (TNA; peak H2 evolution in Ar/O2) in the single nodules was 16% of that in whole nodulated roots and 48% of nodulated root activity when Oi was not being measured simultaneously. This inhibition did not affect the nodules' ability to regulate Oi, because exposure to Ar/O2 (80:20, v/v) caused nitrogenase activity and respiration rate to decline, and this decline was linearly correlated with a concurrent decrease in Oi. When the nodules were subsequently exposed to a linear increase in external pO2 from 20 to 100% O2 at 2.7% O2/min, fractional leghemoglobin oxygenation first increased gradually and then more rapidly, reaching saturation at a pO2 between 76 and 100% O2. Plots of nitrogenase activity and respiration rate against Oi showed that rates increased with Oi up to a value of 57 nM, with half-maximal rates being attained at Oi values between 10 and 14 nM O2. The maximum nitrogenase activity achieved during the increase in pO2 (potential nitrogenase activity) was 30 to 57% of that measured in intact nodulated roots, showing that O2 limitation of nitrogenase activity could account for a significant proportion of the inhibition of TNA associated with the use of the probe. However, some factor(s) in addition to O2 must have limited the activity of single nodules at both subsaturating and saturating Oi. At Oi values greater than about 57 nM, nitrogenase activity and nodule respiration were inhibited, but, because this inhibition has been shown previously to be readily reversible when the Oi was lowered, it was not attributed to direct O2 inactivation of the nitrogenase protein. These results indicate that maximum nitrogenase activity in legume nodules is supported by a narrow range of Oi values. Possible biochemical mechanisms are discussed for both O2 limitation of nitrogenase activity at low Oi and inhibition of nitrogenase activity at high Oi.     

Augmented rates of respiration and efficient nitrogen fixation at nanomolar concentrations of dissolved O2 in hyperinduced Azoarcus sp. strain BH72.

Azoarcus sp. strain BH72 is an aerobic diazotrophic bacterium that was originally found as an endophyte in Kallar grass. Anticipating that these bacteria are exposed to dissolved O2 concentrations (DOCs) in the nanomolar range during their life cycle, we studied the impact of increasing O2 deprivation on N2 fixation and respiration. Bacteria were grown in batch cultures, where they shifted into conditions of low pO2 upon depletion of O2 by respiration. During incubation, specific rates of respiration (qO2) and efficiencies of carbon source utilization for N2 reduction increased greatly, while the growth rate did not change significantly, a phenomenon that we called "hyperinduction." To evaluate this transition from high- to low-cost N2 fixation in terms of respiratory kinetics and nitrogenase activities at nanomolar DOC, bacteria which had shifted to different gas-phase pO2s in batch cultures were subjected to assays using leghemoglobin as the O2 carrier. As O2 deprivation in batch cultures proceeded, respiratory Km (O2) decreased and Vmax increased. Nitrogenase activity at nanomolar DOC increased to a specific rate of 180 nmol of C2H4 min-1 mg of protein-1 at 32 nM O2. Nitrogenase activity was proportional to respiration but not to DOC in the range of 12 to 86 nM O2. Respiration supported N2 fixation more efficiently at high than at low respiratory rates, the respiratory efficiency increasing from 0.14 to 0.47 mol of C2H4 mol of O2 consumed-1. We conclude that (i) during hyperinduction, strain BH72 used an increasing amount of energy generated by respiration for N2 fixation, and (ii) these bacteria have a high respiratory capacity, enabling them to develop ecological niches at very low pO2, in which they may respire actively and fix nitrogen efficiently at comparatively high rates.     

Effect of oxygen on batch and continuous cultures of a nitrogen-fixing Arthrobacter sp.

Growth, acetylene reduction, and respiration rate were studied in batch and continuous cultures of Arthrobacter fluorescents at different oxygen partial pressures. The optimum pO2 values for growth and acetylene reduction were 0.05 and 0.025 atm, respectively, but microorganisms can tolerate higher pO2 values. The growth of cultures provided with combined nitrogen was dependent on oxygen availability, and strict anaerobic conditions did not support growth. Acetylene reduction of a population grown in continuous culture and adapted to low pO2 (0.02 atm) was much more sensitive to oxygenation than that of a population adapted to high pO2 (0.4 atm). Their maximum nitrogenase activity, at their optimal pO2 values, were quite different. The respiratory activity of nitrogen-fixing cultures increased with increasing oxygen tensions until a pO2 of 0.2 atm. At higher pO2 values, the respiration rate began to decrease.     

Nitrogenase proteins from Gluconacetobacter diazotrophicus, a sugarcane-colonizing bacterium

Gluconacetobacter diazotrophicus Pal-5 grew well and expressed nitrogenase activity in the absence of NH4+ and at initial O2 concentrations greater than 5% in the culture atmosphere. G. diazotrophicus nitrogenase consisted of two components, Gd1 and Gd2, which were difficult to separate but were purified individually to homogeneity. Their compositions were very similar to those of Azotobacter vinelandii nitrogenase, however, all subunits were slightly smaller in size. The purified Gd1 protein contained a 12:1 Fe/Mo ratio as compared to 14:1 found for Av1 purified in parallel. Both Gd2 and Av2 contained 3.9 Fe atoms per molecule. Dithionite-reduced Gd1 exhibited EPR features at g=3.69, 3.96, and 4.16 compared with 3.64 and 4.27 for Av1. Gd2 gave an S=1/2 EPR signal identical to that of Av2. A Gd1 maximum specific activity of 1600 nmol H2 (min mg of protein)(-1) was obtained when complemented with either Gd2 or Av2, however, more Av2 was required. Gd2 had specific activities of 600 and 1100 nmol H2 (min mg protein)(-1) when complemented with Av1 and Gd1, respectively. The purified G. diazotrophicus nitrogenase exhibited a narrowed pH range for effective catalysis compared to the A. vinelandii nitrogenase, however, both exhibited maximum specific activity at about pH 7. The Gd-nitrogenase was more sensitive to ionic strength than the Av-nitrogenase.     

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.     

Nif- Hup- mutants of Rhizobium japonicum.

Two H2 uptake-negative (Hup-) Rhizobium japonicum mutants were obtained that also lacked symbiotic N2 fixation (acetylene reduction) activity. One of the mutants formed green nodules and was deficient in heme. Hydrogen oxidation activity in this mutant could be restored by the addition of heme plus ATP to crude extracts. Bacteroid extracts from the other mutant strain lacked hydrogenase activity and activity for both of the nitrogenase component proteins. Hup+ revertants of the mutant strains regained both H2 uptake ability and nitrogenase activity.     

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 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.     

A functional relationship between leghaemoglobin and nitrogenase based on novel measurements of the two proteins in legume root nodules

A combination of physiological and structural measurements made on nodulated cowpea and soybean plants cultured with roots in different pO(2) permitted the expression of data in various ways. Values of leghemoglobin concentration and nitrogenase activity from the two legumes were expressed conventionally either on a per plant or per gram nodule fresh weight basis, and where microscopy was done, on the basis of nitrogenase-containing, N(2)-fixing units (i.e. per bacteroid, per infected cell, or per gram infected tissue). In both legumes, acetylene reduction, N fixed and ureide content expressed on the basis of whole plants or per nitrogenase-containing units were very significantly correlated with values of leghaemoglobin concentrations expressed in a similar manner. The use of mathematical correlations in this study involving leghaemoglobin concentrations and various indices of N(2) fixation indicated a strong functional relationship between the two proteins in symbiotic legumes. These findings confirm previous suggestions that leghaemoglobin and the nitrogenase complex are two proteins closely associated with N(2)-fixing efficiency in legume root nodules.     

Separating the effects of hypobaria and hypoxia on lettuce: growth and gas exchange

The objectives of this research were to determine the influence of hypobaria (reduced atmospheric pressure) and reduced partial pressure of oxygen (pO2) [hypoxia] on carbon dioxide (CO2) assimilation (C(A)), dark-period respiration (DPR) and growth of lettuce (Lactuca sativa L. cv. Buttercrunch). Lettuce plants were grown under variable total gas pressures [25 and 101 kPa (ambient)] at 6, 12 or 21 kPa pO2)(approximately the partial pressure in air at normal pressure). Growth of lettuce was comparable between ambient and low total pressure but lower at 6 kPa pO2 (hypoxic) than at 12 or 21 kPa pO2. The specific leaf area of 6 kPa pO2 plants was lower, indicating thicker leaves associated with hypoxia. Roots were most sensitive to hypoxia, with a 50-70% growth reduction. Leaf chlorophyll levels were greater at low than at ambient pressure. Hypobaria and hypoxia did not affect plant water relations. While hypobaria did not adversely affect plant growth or C(A), hypoxia did. There was comparable C(A) and a lower DPR in low than in ambient total pressure plants under non-limiting CO2 levels (100 Pa pCO2, nearly three-fold that in normal air). The C(A)/DPR ratio was higher at low than at ambient total pressure, particularly at 6 kPa pO2- indicating a greater efficiency of C(A)/DPR in low-pressure plants. There was generally no significant interaction between hypoxia and hypobaria. We conclude that lettuce can be grown under subambient pressure ( congruent with25% of normal earth ambient total pressure) without adverse effects on plant growth or gas exchange. Furthermore, hypobaric plants were more resistant to hypoxic conditions that reduced gas exchange and plant growth.