Algorithm for computing oxygen dissociation curve with pH,PCO2, and CO in sheep blood

By extending the study of Samaja and Gattinoni¹, an algorithm is described for computing the oxygen dissociation curve with variations in pH, PCO₂, and CO in homozygous HbB sheep blood. The difference in the values of O₂ pressure at 50% saturation in presence of CO computed from the present algorithm and Hill's equation does not exceed 0.5%. It is shown that O₂ affinity increases as the concentration of CO or pH increases or PCO₂ decreases. The algorithm is convenient for representing the oxygen dissociation curve with variation in pH, PCO₂ and the concentration of CO in modelling oxygen transport in sheep blood even under hypoxic conditions.     

Mechanism of Excitation of Aplysia Neurons by Carbon Dioxide

The abdominal ganglion of Aplysia californica was perfused with artificial seawater equilibrated at different P_COCO2's and pH's for 5 min or less. 5% CO₂ dropped perfusate pH from 8.0 to 6.5 and produced depolarization and increased discharge rate in visceromotor neurons. Half the giant cells studied had a similar response, whereas the other half were hyperpolarized. Pacemaker neurons showed little, if any, response to such changes in pH or CO₂. Membrane conductance of responsive cells was always increased. The effect of CO₂ occurred even when synaptic transmission was blocked by low calcium and high magnesium, and therefore must have been a direct result of CO₂ or the concomitant fall in pH. When extracellular pH was lowered to 6.5 using HCl or H₂SO₄ and no CO₂, the same effects were observed. Also, local application of HCl or H₂SO₄ to the external surface of the cell soma elicited depolarization and spike discharge. When extracellular pH was held constant by continual titration, 5–50% CO₂ had no effect. Intracellular pH was probably decreased at least one pH unit under these circumstances. Thus CO₂ per se, decreased intracellular pH, and increased bicarbonate ion were without effect. It is concluded that CO₂ acts solely through a decrease in extracellular pH.     

Growth ofClostridium thermoaceticum on H2/CO2 or CO as energy source

The type strain Fontaine ofClostridium thermoaceticum proliferated on H₂/CO₂ as energy source and was culturally adapted to grow on 100% CO in the headspace. The doubling times at 55°C on CO or H₂/CO₂ were 16 and 18 h, respectively. Under these conditions, the substrate-product transformation stoichiometries observed were: 4H₂+2.1CO₂→0.9 acetate and 4CO→2CO₂+1.1 acetate. It is concluded thatC. thermoaceticum has a single carbon growth physiology.     

Control of Carbon and Electron Flow in Clostridium acetobutylicum Fermentations: Utilization of Carbon Monoxide to Inhibit Hydrogen Production and to Enhance Butanol Yields

Extracts prepared from non-solvent-producing cells of Clostridium acetobutylicum contained methyl viologen-linked hydrogenase activity (20 U/mg of protein at 37°C) but did not display carbon monoxide dehydrogenase activity. CO addition readily inhibited the hydrogenase activity of cell extracts or of viable metabolizing cells. Increasing the partial pressure of CO (2 to 10%) in unshaken anaerobic culture tube headspaces significantly inhibited (90% inhibition at 10% CO) both growth and hydrogen production by C. acetobutylicum. Growth was not sensitive to low partial pressures of CO (i.e., up to 15%) in pH-controlled fermentors (pH 4.5) that were continuously gassed and mixed. CO addition dramatically altered the glucose fermentation balance of C. acetobutylicum by diverting carbon and electrons away from H₂, CO₂, acetate, and butyrate production and towards production of ethanol and butanol. The butanol concentration was increased from 65 to 106 mM and the butanol productivity (i.e., the ratio of butanol produced/total acids and solvents produced) was increased by 31% when glucose fermentations maintained at pH 4.5 were continuously gassed with 85% N₂-15% CO versus N₂ alone. The results are discussed in terms of metabolic regulation of C. acetobutylicum saccharide fermentations to achieve maximal butanol or solvent yield.     

The new facultatively chemolithoautotrophic, moderately halophilic, sulfate-reducing bacterium Desulfovermiculus halophilus gen. nov., sp. nov., isolated from an oil field

The new mesophilic, chemolithoautotrophic, moderately halophilic, sulfate-reducing bacterium strain 11-6, could grow at a NaCl concentration in the medium of 30–230 g/l, with an optimum at 80–100 g/l. Cells were vibrios motile at the early stages of growth. Lactate, pyruvate, malate, fumarate, succinate, propionate, butyrate, crotonate, ethanol, alanine, formate, and H₂/CO₂ were used in sulfate reduction. Butyrate was degraded completely, without acetate accumulation. In butyrate-grown cells, a high activity of CO dehydrogenase was detected. Additional growth factors were not required. Autotrophic growth occurred, in the presence of sulfate, on H₂/CO₂ or formate without other electron donors. Fermentation of pyruvate and fumarate was possible in the absence of sulfate. Apart from sulfate, sulfite, thiosulfate, and elemental sulfur were able to serve as electron acceptors. The optimal growth temperature was 37°C; the optimum pH was 7.2. Desulfoviridin was not detected. Menaquinone MK-7 was present. The DNA G+C content was 55.2 mol %. Phylogenetically, the bacterium represented a separate branch within the cluster formed by representatives of the family Desulfohalobiaceae in the class Deltaproteobacteria. The bacterium was assigned to a new genus and species, Desulfovermiculus halophilus gen. nov., sp. nov. The type strain is 11-6^T (= VKM B-2364), isolated from the highly mineralized formation water of an oil field.     

Catabolic Activities of Neisseria meningitidis: Utilization of Succinate

Two strains of Saccharomycopsis guttulata, JB-1 and JB-3, isolated from stomach contents of domestic rabbits, were grown under different gas phases, and their growth rates were compared. Strain JB-1 grew exponentially at a maximal growth rate under a continuous gas phase of 15% CO₂, 2% O₂ in nitrogen. High cell yields with low cell granulation were obtained. The growth rates were almost the same between oxygen concentrations of 0.25 and 20% at 15% CO₂. Poor growth and early cell granulation occurred in the absence of oxygen at 15% CO₂. Growth increased at 2% O₂ in direct proportion to the carbon dioxide concentration up to 10 to 15% CO₂. A very high carbon dioxide content (e.g. 98%) was somewhat inhibitory. Cell granulation always occurred during the maximal stationary phase in media at pH 4, but was relatively slight at pH 5.6 or higher. Strain JB-3 responded to various gas phases in a similar manner except that it grew slowly in the absence of oxygen at 15% CO₂ (pH 4). The effect of an optimal gas phase on the growth of strain JB-1 was examined in relation to other environmental conditions. In the presence of 15% CO₂, 2% O₂, this strain grew exponentially in yeast autolysate-Proteose Peptone-glucose medium at 37 C at pH 2, 4, and 5.6 at approximately the same rate; the growth rate was somewhat lower at pH 6.2. Under similar conditions, strain JB-1 grew at 30 C and pH 4 at one-sixth its maximal growth rate. Cell granulation was greatly reduced at this temperature. With adequate CO₂ strain JB-1 also grew at a reduced rate in a yeast autolysate medium previously reported not to support growth. Results indicate that continuous gassing with an optimal gas phase increases the growth rate to the extent that the growth rate surpasses the death rate by a significant margin; as a result, granulated cells can be avoided almost entirely in the log phase.     

Inhibition of the growth of two blue-green algae species (Microsystis aruginosa and Anabaena spiroides) by acidification treatments using carbon dioxide

The effect of pH adjusted by aeration with carbon dioxide (CO₂) on the growth of two species of blue-green algae, Microcystis aeruginosa and Anabaena spiroides, was investigated. Three conditions (pH 5.5, 6.0 and 6.5) were found to have significant inhibitory effects on the growth of the two algae species when acidification treatment was conducted during the logarithmic phase. Differences in the inhibition effect of acidification existed between the two species algae. The tolerance of M. aeruginosa to these conditions was also investigated. The results indicated that M. aeruginosa was inhibited significantly, but not dead at pH 6.5, whereas death occurred at pH 5.5 and 6.0. The greatest inhibitory effect of acidification treatment conducted during the stable breeding phase of M. aeruginosa occurred at pH 5.5, while no inhibitory effect was found at pH 6.5.     

CO2- and Anaerobiosis-Induced Changes in Physiology and Gene Expression of Different Listeria monocytogenes Strains

Although carbon dioxide (CO₂) is known to inhibit growth of most bacteria, very little is known about the cellular response. The food-borne pathogen Listeria monocytogenes is characterized by its ability to grow in high CO₂ concentrations at refrigeration temperatures. We examined the listerial responses of different strains to growth in air, 100% N₂, and 100% CO₂. The CO₂-induced changes in membrane lipid fatty acid composition and expression of selected genes were strain dependent. The acid-tolerant L. monocytogenes LO28 responded in the same manner to CO₂ as to other anaerobic, slightly acidic environments (100% N₂, pH 5.7). An increase in the expression of the genes encoding glutamate decarboxylase (essential for survival in strong acid) as well as an increased amount of branched-chain fatty acids in the membrane was observed in both atmospheres. In contrast, the acid-sensitive L. monocytogenes strain EGD responded differently to CO₂ and N₂ at the same pH. In a separate experiment with L. monocytogenes 412, an increased isocitrate dehydrogenase activity level was observed for cells grown in CO₂-containing atmospheres. Together, our findings demonstrate that the CO₂-response is a partly strain-dependent complex mechanism. The possible links between the CO₂-dependent changes in isocitrate dehydrogenase activity, glutamate metabolism and branched fatty acid biosynthesis are discussed.     

Dark metabolism of carbon monoxide in lettuce leaf discs

In the dark, leaf tissue of crisphead lettuce (Lactuca sativa L.) metabolized ¹⁴CO to ¹⁴CO₂ and acid-stable products. Tissue incubated at 2.5°C for 3.5 hours and 48 hours converted about 1% and 17%, respectively, of the applied ¹⁴CO to ¹⁴CO₂, and incorporated about 0.04% and 0.6% of the ¹⁴C in acid-stable products. Examination of soluble acid-stable products from ¹⁴CO and ¹⁴CO₂-treated leaf tissue revealed that the labeling patterns of both treatments were identical during the 3.5-hour and the 48-hour incubation periods. Malate, citrate, and aspartate together comprised 70% or more of the soluble radioactivity from both treatments. Incorporation of radioactivity from CO into soluble acid-stable products during a 3-hour incubation period at 2.5°C was inhibited 90% by adding 3% nonradioactive CO₂. These results indicate that in head lettuce in the dark ¹⁴CO is metabolized primarily to ¹⁴CO₂ which is the precursor of acid-stable products. In leaf discs at 2.5°C, the apparent K_m for CO oxidation to CO₂ was 5.3 microliters per liter and the V_max was 9.7 nanoliters per gram per hour. The mitochondrial fraction of the leaf homogenate was the most active fraction to oxidize CO to CO₂, and this activity was heat-labile and cyanide-sensitive.     

Continuous real-time monitoring of metabolic parameters in growing bacterial cultures

Continuous monitoring of a bacterial culture for pH, growth, CO₂, and NH₃ has been accomplished by means of in situ probes. Changes in the metabolic parameters of Proteus cultures generally occurred about an hour before changes in growth were observed. The time of maximum CO₂ production preceded that of NH₃ elaboration by this organism; however, the sequence was reversed when urea was added to the medium. This type of in situ monitoring system has great potential for the study of the metabolism of growing organisms as well as for the early detection of growth in liquid culture.     

Effect of Triacontanol on Chlamydomonas: I. Stimulation of Growth and Photosynthetic CO(2) Assimilation

Treatment of Chlamydomonas reinhardtii cells, cultured at 5% CO₂, with 1 to 1000 micrograms triacontanol (TRIA) per liter resulted in 21 to 35% increases in cell density, 7 to 31% increases in total chlorophyll, and 20 to 100% increases in photosynthetic CO₂ assimilation. The increase in CO₂ fixation with TRIA treatment occurred before, and was independent of, increases in total chlorophyll or cell number. Chlamydomonas cells responded to a broad range of TRIA concentrations that were at least one order of magnitude above the optimum concentration established for higher plants. The necessity for larger concentrations of TRIA may be due to destabilizing effects of Ca²⁺ and K⁺ present in the Chlamydomonas growth medium. These ions caused flocculation of the colloidally dispersed TRIA in apparent competition with binding of [¹⁴C]TRIA to Chlamydomonas cells. Octacosanol inhibited the effect of TRIA on photosynthetic CO₂ assimilation. TRIA treatment did not alter the distribution of ¹⁴C-label among photosynthetic products. The effect of TRIA on photosynthetic CO₂ assimilation increased with time after treatment up to 3 days. Chlamydomonas cells that had been grown at low-CO₂ (air) did not respond to TRIA, and transfer of high-CO₂ (5%) grown cells that had responded to TRIA to a low-CO₂ atmosphere resulted in a loss of the effect of TRIA. The effect of pH on photosynthetic CO₂ assimilation indicated that CO₂ is probably the species of inorganic carbon utilized by control and TRIA-treated Chlamydomonas cells.     

THE EFFECT OF pH ON GROWTH, PROTEIN SYNTHESIS, AND LIPID-RICH PARTICLES OF CULTURED MAMMALIAN CELLS

A simple procedure has been established for controlling and measuring the pH of media in which the bicarbonate-carbonic acid system is the predominant buffer. The HCO^-₃ concentration was maintained at 22.5 mM and the H₂CO₃ concentration was varied by equilibrating the media with 0.5 to 40 per cent CO₂ in air. The curve relating extracellular pH to 3 day cell growth was similar for glass-attached HeLa and Chang liver cells. Maximum growth occurred over a pH range of 7.38 to 7.87. Cell growth declined precipitously on the alkaline side and more gradually on the acid side of the optimal pH range. Comparable pH growth curves were also obtained with newly isolated cells from rat liver and skeletal muscle. It was shown that the effect of pH on growth was independent of the CO₂ concentration and that the essential nutrients in the medium were stable over the pH range studied. Although alkalosis depressed the 3 day cell population, cells exposed to a pH of 8.0 to 8.2 grew at the maximal rate for the first 12 to 24 hours. Growth then ceased abruptly and the cells entered a steady state with respect to net protein synthesis. This was followed by cytoplasmic retraction and cell death. Increasing the concentrations of calcium or magnesium in the medium failed to prevent the effects of alkalosis. Moreover, the increase in CO^-₃ concentration of the media and the concomitant decrease in Ca⁺⁺ ion concentration that occur at high pH were eliminated as determining factors in the growth failure and death. While acidosis had a less pronounced effect on the 3 day cell population, its effect on the growth rate was immediate. The increase in cell generation time was proportional to the H⁺ ion concentration. In each of the cell lines studied, acidosis was accompanied by a striking increase in the number of cytoplasmic perinuclear granules. These granules which stain supravitally with Janus green are extracted from fixed cells with lipid solvents. They maintain their identity in cell homogenates and may be isolated from the other subcellular structures by differential centrifugation; at 100,000 g they form a distinct layer at the top of the supernatant fraction. On the basis of their physical and chemical properties, these granules have been called lipid-rich particles. The accumulation of lipid-rich particles in acidosis was independent of the growth rate and the CO₂ concentration.     

Strong shift from HCO3 − to CO2 uptake in Emiliania huxleyi with acidification: new approach unravels acclimation versus short-term pH effects

Effects of ocean acidification on Emiliania huxleyi strain RCC 1216 (calcifying, diploid life-cycle stage) and RCC 1217 (non-calcifying, haploid life-cycle stage) were investigated by measuring growth, elemental composition, and production rates under different pCO₂ levels (380 and 950 μatm). In these differently acclimated cells, the photosynthetic carbon source was assessed by a ¹⁴C disequilibrium assay, conducted over a range of ecologically relevant pH values (7.9–8.7). In agreement with previous studies, we observed decreased calcification and stimulated biomass production in diploid cells under high pCO₂, but no CO₂-dependent changes in biomass production for haploid cells. In both life-cycle stages, the relative contributions of CO₂ and HCO₃ ^? uptake depended strongly on the assay pH. At pH values ≤ 8.1, cells preferentially used CO₂ (≥ 90 % CO₂), whereas at pH values ≥ 8.3, cells progressively increased the fraction of HCO₃ ^? uptake (~45 % CO₂ at pH 8.7 in diploid cells; ~55 % CO₂ at pH 8.5 in haploid cells). In contrast to the short-term effect of the assay pH, the pCO₂ acclimation history had no significant effect on the carbon uptake behavior. A numerical sensitivity study confirmed that the pH-modification in the ¹⁴C disequilibrium method yields reliable results, provided that model parameters (e.g., pH, temperature) are kept within typical measurement uncertainties. Our results demonstrate a high plasticity of E. huxleyi to rapidly adjust carbon acquisition to the external carbon supply and/or pH, and provide an explanation for the paradoxical observation of high CO₂ sensitivity despite the apparently high HCO₃ ^? usage seen in previous studies.     

Ribulose bisphosphate oxygenase activity from freshly ruptured spinach chloroplasts

Suspensions of freshly lysed spinach chloroplasts, in which ribulose bisphosphate carboxylase displays an in vivo K_m [CO], exhibited a ribulose bisphosphate-dependent uptake of oxygen. The kinetic properties of this oxygenase activity were examined at air levels of CO₂ (10 μm) and O₂ (240 μm). The pH optimum was 8.6–8.8 and the K_M [ribulose bisphosphate] was 45 μm. At 240 μm O₂, the oxygenase activity is inhibited one-half by 25 μm CO₂. The apparent K_m(O₂) is large, somewhere between 1 and 2 atm. The phosphoglycolate phosphatase activity of the chloroplasts was in great excess, suggesting that phosphoglycolate formed by the oxygenase would be quickly hydrolyzed to glycolate for possible metabolism by photorespiration.A comparison of the pH dependence of both the carboxylase and oxygenase activities at air levels of CO₂ and O₂ suggests that the pH of the chloroplast stroma could regulate their relative activities and that the oxygenase activity is sufficient to account for glycolate production during photosynthesis. It is predicted that at pH 7.8, about 40% of the carbon assimilated by the Calvin cycle would go through glycolate.     

The effect of elevated CO2 concentration and soil pH on the relationship between plant growth and rhizosphere denitrification potential

The effect of CO₂ concentration on plant growth and the size of the rhizosphere denitrifier population was investigated for ryegrass grown at 3 different soil pH values (pH 4.3, 5.9 and 7.0). Soil microcosms were planted with ryegrass and maintained under constant growth conditions at either ambient (450ppm) or elevated (720ppm) CO₂ concentration. At harvest, the rhizosphere soil was collected and subjected to a potential denitrification assay to provide an estimate of the size of the denitrifier population present. Ryegrass dry matter production varied across the pH range studied and contrary to other studies, elevated CO₂ concentration did not consistently increase growth. Plant growth was reduced by ≈ 35% and 23% at pH 4.3 and pH 5.9, respectively, under elevated CO₂ concentration. At pH 7.0, however, plant growth was increased by ≈ 45% under elevated CO₂. Potential denitrification rates within the rhizosphere followed a similar pattern to plant growth in the different treatments, suggesting that plant growth and the size of denitrifier population within the rhizosphere are coupled. This study investigates the relationship between plant growth and rhizosphere denitrification potential, thereby providing an estimate of the size of the denitrifier population under increased CO₂ concentration and soil pH.     

Plasmodium falciparum: microaerophilic requirements in human red blood cells.

The respiratory requirements of Plasmodium falciparum were studied in vitro in continuous cultivation. The cultures were held in petri dishes containing the parasites incubated in different gas mixtures for periods of 72 to 144 hr with daily media changes. Atmospheres were combinations of 0.5 to 21% O₂ mixed with 1 to 5% CO₂ diluted with N₂. Gas concentrations and the pH of media were measured with an $\text{O}{}_2\text{CO}{}_2$ analyzer. Best growth was realized in all cases at 3% O₂ and 1 to 2% CO₂. The culture appeared to be selfperpetuating in O₂ concentrations as low as 0.5% providing the CO₂ was not over 2%. Oxygen concentrations of 21% proved deleterious to growth. The parasite however, failed to grow in the highly reducing atmosphere of anaerobic “Brewer Jars,” suggesting that P. falciparum is an obligate microaerophile.     

Uptake of inorganic carbon by isolated chloroplasts from air-adapted dunaliella

Neither Dunaliella cells grown with 5% CO₂ nor their isolated chloroplasts had a CO₂ concentrating mechanism. These cells primarily utilized CO₂ from the medium because the K_(0.5) (HCO₃⁻) increase from 57 micromolar at pH 7.0 to 1489 micromolar at pH 8.5, where as the K_(0.5) CO₂ was about 12 micromolar over the pH range. After air adaptation for 24 hours in light, a CO₂ concentrating mechanism was present that decreased the K_0.5 (CO₂) to about 0.5 micromolar and K_0.5 (HCO₃⁻) to 11 micromolar at pH 8. These K_0.5 values suggest that air-adapted cells preferentially concentrated CO₂ but could also use HCO₃⁻ from the medium. Chloroplasts isolated from air-adapted cells had a K_(0.5) for total inorganic carbon of less than 10 micromolar compared to 130 micromolar for chloroplasts from cells grown on high CO₂. Chloroplasts from air-adapted cells, but not CO₂-grown cells, concentrate inorganic carbon internally to 1 millimolar in 60 seconds from 240 micromolar in the medium. Maximum uptake rates occurred after preillumination of 45 seconds to 3 minutes. The CO₂ concentrating mechanism by chloroplasts from air-adapted cells was light dependent and inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) or flurocarbonyl-cyamidephenylhydrazone (FCCP). Phenazine-methosulfate at 10 micromolar to provide cyclic phosphorylation partially reversed the inhibition by DCMU but not by FCCP. One to 0.1 millimolar vanadate, an inhibitor of plasma membrane ATPase, inhibited inorganic carbon accumulation by isolated chloroplasts. Vanadate had no effect on CO₂ concentration by whole cells, as it did not readily cross the cell plasmalemma. Addition of external ATP to the isolated chloroplast only slightly stimulated inorganic carbon uptake and did not reverse vanadate inhibition by more than 25%. These results are consistent with a CO₂ concentrating mechanism in Dunaliella cells which consists in part of an inorganic carbon transporter at the chloroplast envelope that is energized by ATP from photosynthetic electron transport.     

CO Metabolism in the Acetogen Acetobacterium woodii

The Wood-Ljungdahl pathway allows acetogenic bacteria to grow on a number of one-carbon substrates, such as carbon dioxide, formate, methyl groups, or even carbon monoxide. Since carbon monoxide alone or in combination with hydrogen and carbon dioxide (synthesis gas) is an increasingly important feedstock for third-generation biotechnology, we studied CO metabolism in the model acetogen Acetobacterium woodii. When cells grew on H₂-CO₂, addition of 5 to 15% CO led to higher final optical densities, indicating the utilization of CO as a cosubstrate. However, the growth rate was decreased by the presence of small amounts of CO, which correlated with an inhibition of H₂ consumption. Experiments with resting cells revealed that the degree of inhibition of H₂ consumption was a function of the CO concentration. Since the hydrogen-dependent CO₂ reductase (HDCR) of A. woodii is known to be very sensitive to CO, we speculated that cells may be more tolerant toward CO when growing on formate, the product of the HDCR reaction. Indeed, addition of up to 25% CO did not influence growth rates on formate, while the final optical densities and the production of acetate increased. Higher concentrations (75 and 100%) led to a slight inhibition of growth and to decreasing rates of formate and CO consumption. Experiments with resting cells revealed that the HDCR is a site of CO inhibition. In contrast, A. woodii was not able to grow on CO as a sole carbon and energy source, and growth on fructose-CO or methanol-CO was not observed.     

The relationships between relative growth rate,meristematic potential and compensatory growth of semiarid-land shrubs

The submersed macrophyte Vallisneria americana was grown for seven weeks in a greenhouse to test for differences in the ability of three different sediments to support growth stimulation in response to CO₂ enrichment at low pH. Plants accumulated 21- to 24-fold greater biomass at 10 × ambient CO₂ concentrations than at ambient CO₂ on all sediments. At both CO₂ levels, plants grown on sediment from an acidified lake accumulated ca. 81%, and those grown on oligotrophic lake sediment ca. 47% as much biomass as plants grown on alkaline lake sediment. Despite striking CO₂ and sediment effects on biomass accumulation, there was no significant interaction (using log-transformed data) between CO₂ and sediment effects, indicating that all sediments allowed similar proportionate growth responses to CO₂ enrichment. Plants grown on the less fertile sediments showed greater relative allocation to horizontal versus vertical growth by producing more rosette-bearing stolons in relation to plant height (leaf length) than plants grown on relatively fertile, alkaline lake sediment. Tissue analysis suggested that sediment effects on Vallisneria growth could be attributed neither to mineral putrient (nitrogen and phosphorus) limitation nor to aluminum toxicity in these low pH treatments. In any case, CO₂ availability can be an important regulator of submersed macrophyte growth at low pH on a variety of sediment types, including those from oligotrophic and acidic lakes.     

Adaptation to Low CO(2) Level in a Mutant of Anacystis nidulans R(2) which Requires High CO(2) for Growth

The mutant E₁ of Anacystis nidulans R₂ requires high CO₂ concentration for growth but was able to adapt to low CO₂ concentration. This was exhibited by the increased ability to accumulate inorganic carbon within the cells and the large increase in the amount of a 42-kilodalton polypeptide located in the cytoplasmic membrane. The adaptation occurred in E₁ cells at an extracellular CO₂ concentration as high as 0.3%, which was 8 times the concentration for maximal adaptation in R₂ cells. The ability of E₁ cells to exhibit low CO₂ characteristics at a higher CO₂ concentration was attributed to lower intracellular CO₂ concentration.