Serologic evaluation of human microcystin exposure.

Microcystins are among the most commonly detected toxins associated with cyanobacteria blooms worldwide. Two episodes of intravenous microcystin exposures occurred among kidney dialysis patients during 1996 and 2001. Analysis of serum samples collected during these episodes suggests that microcystins are detectable as free and bound forms in human serum. Our goal was to characterize the biochemical evidence for human exposure to microcystins, to identify uncertainties associated with interpretation of these observed results, and to identify research needs. We analyzed serum samples using enzyme-linked immunosorbent assay (ELISA) methods to detect free microcystins, and gas chromatography/mass spectrometry (GC/MS) to detect 2-methyl-3-methoxy-4-phenylbutyric acid (MMPB). MMPB is derived from both free and protein-bound microcystins by chemical oxidation, and it appears to represent total microcystins present in serum. We found evidence of free microcystins in patient serum for more than 50 days after the last documented exposure. Serum concentrations of free microcystins were consistently lower than MMPB quantification of total microcystins: free microcystins as measured by ELISA were only 8-51% of total microcystin concentrations as detected by the GC/MS method. After intravenous exposure episodes, we found evidence of microcystins in human serum in free and protein-bound forms, though the nature of the protein-bound forms is uncertain. Free microcystins appear to be a small but variable subset of total microcystins present in human serum. Research is needed to elucidate the human toxicokinetics of microcystins, in part to determine how observed serum concentrations can be used to estimate previous microcystin exposure.

Identification, purification, and molecular cloning of a putative plastidic glucose translocator.

During photosynthesis, part of the fixed carbon is directed into the synthesis of transitory starch, which serves as an intermediate carbon storage facility in chloroplasts. This transitory starch is mobilized during the night. Increasing evidence indicates that the main route of starch breakdown proceeds by way of hydrolytic enzymes and results in glucose formation. This pathway requires a glucose translocator to mediate the export of glucose from the chloroplasts. We have reexamined the kinetic properties of the plastidic glucose translocator and, using a differential labeling procedure, have identified the glucose translocator as a component of the inner envelope membrane. Peptide sequence information derived from this protein was used to isolate cDNA clones encoding a putative plastidic glucose translocator from spinach, potato, tobacco, Arabidopsis, and maize. We also present the molecular characterization of a candidate for a hexose transporter of the plastid envelope membrane. This transporter, initially characterized more than 20 years ago, is closely related to the mammalian glucose transporter GLUT family and differs from all other plant hexose transporters that have been characterized to date.

Characterization and subcellular localization of debranching enzyme and endoamylase from leaves of sugar beet.

Sugar beet leaves (Beta vulgaris L.) contained up to five endoamylases, two exoamylases, and a single debranching enzyme. Four of the endoamylases and the debranching enzyme were present in the chloroplast. The chloroplastic starch-debranching enzyme and an apoplastic endoamylase were copurified from mature leaves of sugar beet by 35 to 50% ammonium sulfate precipitation and chromatography on diethylaminoethyl-Sephacryl, beta-cyclodextrin Sepharose 6B, and Sephadex G-150. The debranching enzyme, which was purified to homogeneity, had a molecular mass of 100 kilodaltons and a pH optimum of 5.5. It showed a high activity with pullulan as a substrate, low activity with soluble starch and amylopectin, and no activity with native starch grains isolated from sugar beet leaves. The endoamylase, which was partially purified, had a molecular mass of 43,000 kilodaltons, a pH optimum of 6.5, required calcium for activity and thermal stability, and showed an ability to hydrolyze native starch grains.

Effect of N-(Phosphonomethyl)glycine on Carbon Assimilation and Metabolism during a Simulated Natural Day.

The effects of N-(phosphonomethyl)glycine (glyphosate) on the regulation of carbon assimilation, metabolism, and translocation were studied in leaves of sugar beet (Beta vulgaris L., Klein E-type multigerm) under a light regimen that began with gradually increasing irradiance as generally occurs on a natural day. Soon after application, glyphosate caused a marked increase in ribulose bisphosphate and a decrease in phosphoglyceric acid. The response is most simply explained by direct inhibition of ribulose bisphosphate carboxylase activity. The extent of inhibition was small, and the carbon assimilation rate did not decrease. As predicted, photosynthesis declined within an hour after glyphosate was applied to leaves under gradually increasing light. Inhibition resulted from a decrease in ribulose bisphosphate due to depletion of carbon from the photosynthetic carbon reduction cycle. Photoinhibition, a light-dependent limitation of photosynthetic capacity, appeared to be necessary for marked glyphosate-induced inhibition of photosynthesis. As a result, photosynthesis rate increased with irradiance until it exceeded 400 micromoles per square meter per second but then declined as the light level increased beyond 500 micromoles per square meter per second. Glyphosate changed the allocation of newly fixed carbon between starch and sucrose for export. Changes in the levels of ribulose bisphosphate and phosphoglyceric acid produced important effects on the regulation of carbon assimilation and metabolism.

Carbon Assimilation and Leaf Water Status in Sugar Beet Leaves during a Simulated Natural Light Regimen.

Carbon assimilation and leaf water status were studied in sugar beet (Beta vulgaris L., Klein E-type multigerm) leaves during a light period in which illumination either increased rapidly to full irradiance or changed gradually in a sinusoidal manner as generally occurs during a natural day. A light regimen that simulated the light of a natural day was produced by adjusting irradiance with a neutral-density filter under the control of a computer. Under this light regimen, photosynthesis, transpiration, and stomatal conductance followed the irradiance pattern very closely and ribulose bisphosphate carboxylase was nearly fully activated. When illumination was increased rapidly at the beginning of a light period, transpiration also increased quickly, causing leaves to wilt to some extent. The activation state of ribulose bisphosphate carboxylase increased to only 52%, but ribulose bisphosphate level was nearly twice as high as during the simulated natural day. In spite of the differences in activation state and ribulose bisphosphate levels, photosynthesis rates were very similar under both regimens. Nevertheless, differences in parameters between leaves under the two irradiance regimens can affect how a plant responds to internal or external factors, and therefore, the rate at which irradiance increases at the beginning of a light period is an important consideration when interpreting data.

Regulation of photosynthetic carbon reduction cycle by ribulose bisphosphate and phosphoglyceric Acid.

The activation states of a number of chloroplastic enzymes of the photosynthetic carbon reduction cycle and levels of related metabolites were measured in leaves of sugar beet (Beta vulgaris L., Klein E-type multigerm) under slowly changing irradiance during a day. The activation states of both phosphoribulokinase and NADP(+)-glyceraldehyde-3-phosphate dehydrogenase increased early in the light period and remained constant during the middle of the day. Initial ribulose 1,5-bisphosphate carboxylase activity was already about one third of the midday level, did not change for the first 2 hours, but then increased in parallel with the rate of carbon fixation. Because the activation states increased by turns, first phosphoribulokinase and NADP(+)-glyceraldehyde-3-phosphate dehydrogenase and later ribulose 1,5-bisphosphate carboxylase, the ratios of the activation states changed remarkably. Levels of ribulose bisphosphate and phosphoglycerate, which were high enough to affect enzyme reaction rates and changed in concert with activation state, indicate that these metabolites are involved in feedback/feedforward regulation of enzymes of carbon assimilation. This regulatory sequence is able to explain how the reaction rates for the enzymes of carbon assimilation are adjusted to maintain their activities in balance with each other and with the flux of carbon fixation.

Inhibition of ribulose 1,5-bisphosphate carboxylase/oxygenase by 2-carboxyarabinitol-1-phosphate.

In some plants, 2-carboxy-d-arabinitol 1-phosphate (CA 1P) is tightly bound to catalytic sites of ribulose, 1,5-bisphosphate carboxylase/oxygenase (rubisco). This inhibitor's tight binding property results from its close resemblance to the transition state intermediate of the carboxylase reaction. Amounts of CA 1P present in leaves varies with light level, giving CA 1P characteristics of a diurnal modulator of rubisco activity. Recently, a specific phosphatase was found that degrades CA 1P, providing a mechanism to account for its disappearance in the light. The route of synthesis of CA 1P is not known, but could involve the branched chain sugar, hamamelose. There appear to be two means for diurnal regulation of the number of catalytic sites on rubisco: carbamylation mediated by the enzyme, rubisco activase, and binding of CA 1P. While strong evidence exists for the involvement of rubisco activase in rubisco regulation, the significance of CA 1P in rubisco regulation is enigmatic, given the lack of general occurrence of CA 1P in plant species. Alternatively, CA 1P may have a role in preventing the binding of metabolites to rubisco during the night and the noncatalytic binding of ribulose bisphosphate in the light.

Sources of Carbon for Export from Spinach Leaves throughout the Day.

Rates of net carbon exchange, export, starch, and sucrose synthesis were measured in leaves of spinach (Spinacia oleracea L.) throughout a 14-hour period of sinusoidal light to determine the sources of carbon contributing to export. Net carbon exchange rate closely followed light level, but export remained relatively constant throughout the day. In the morning when photosynthesis was low, starch degradation provided most of the carbon for export, while accumulated sucrose was exported during the evening. At high photosynthesis rate, the regulatory metabolite fructose 2,6-bisphosphate was low, allowing more of the newly fixed carbon to flow to sucrose through cytosolic fructose bisphosphatase. When the rate of sucrose synthesis exceeded the rate of export from the leaf, sucrose accumulated and soon thereafter sucrose synthesis declined. A decreasing sucrose synthesis rate resulted in additional carbon moving to the synthesis of starch, which was maintained throughout the remainder of the day. The declining sucrose synthesis rate coincided with decreasing activity of sucrose phosphate synthase present in gel-filtered leaf extracts. A rise in the leaf levels of uridine diphosphoglucose and fructose 6-phosphate throughout the day was consistent with this declining activity.

Photosynthesis, Carbohydrate Metabolism, and Export in Beta vulgaris L. and Phaseolus vulgaris L. during Square and Sinusoidal Light Regimes.

Rates of photosynthesis, sucrose synthesis, starch accumulation and degradation were measured in sugar beet (Beta vulgaris L.) and bean (Phaseolus vulgaris L.) plants under a square-wave light regime and under a sinusoidal regime that simulated the natural daylight period. Photosynthesis rate increased in a measured manner in direct proportion to the increasing light level. In contrast to this close correspondence between photosynthesis and light, a lag in photosynthesis rate was seen during the initial hour under square-wave illumination. The leaf appeared to be responding to limits set by carbon metabolism rather than by gas exchange or light reactions. Under the sinusoidal regime starch degradation occurred during the first and last 2 hours of the photoperiod, likely in response to photosynthesis rate rather than directly to light level. Starch broke down when photosynthesis was below a threshold rate and accumulated above this rate. Under square-wave illumination, accumulation of starch did not begin until irradiance was at full level for an hour or more and photosynthesis was at or near its maximum. Under a sinusoidal light regime, sucrose synthesis rate comprised carbon that was newly fixed throughout the day plus that from starch degradation at the beginning and end of the day. Synthesis of sucrose from recently fixed carbon increased with increasing net carbon fixation rate while its formation from degradation of starch decreased correspondingly. The complementary sources of carbon maintained a relatively steady rate of sucrose synthesis under the changing daytime irradiance.

Leaf Carbon Metabolism and Metabolite Levels during a Period of Sinusoidal Light.

Photosynthesis rate, internal CO(2) concentration, starch, sucrose, and metabolite levels were measured in leaves of sugar beet (Beta vulgaris L.) during a 14-h period of sinusoidal light, which simulated a natural light period. Photosynthesis rate closely followed increasing and decreasing light level. Chloroplast metabolite levels changed in a manner indicating differential activation of enzymes at different light levels. Starch levels declined during the first and last 2 hours of the photoperiod, but increased when photosynthesis rate was greater than 50% of maximal. Sucrose and sucrose phosphate synthase levels were constant during the photoperiod, which is consistent with a relatively steady rate of sucrose synthesis during the day as observed previously (BR Fondy et al. [1989] Plant Physiol 89: 396-402). When starch was being degraded, glucose 1-phosphate level was high and there was a large amount of glucose 6-phosphate above that in equilibrium with fructose 6-phosphate, while fructose 6-phosphate and triose-phosphate levels were very low. Likewise, the regulatory metabolite, fructose, 2,6-bisphosphate was high, indicating that little carbon could move to sucrose from starch by the triose-phosphate pathway. These data cast doubt upon the feasibility of significant carbon flow through the triose-phosphate pathway during starch degradation and support the need for an additional pathway for mobilizing starch carbon to sucrose.

Glyphosate effects on carbon assimilation, ribulose bisphosphate carboxylase activity, and metabolite levels in sugar beet leaves.

Application of a 17-millimolar solution of glyphosate (GLP) to sugarbeet (Beta vulgaris L.) leaves resulted in an immediate and rapid decline in the level of ribulose bisphosphate (RuBP). Phosphoglyceric acid level began to decrease about 2 hours following the decline in RuBP level. Photosynthesis rate declined linearly with RuBP level, but only when the RuBP level had decreased to about twice the RuBP carboxylase active site concentration. This occurred about 4 hours following GLP-application. At this time starch synthesis also declined abruptly. The activation state of RuBP carboxylase did not change for 8 hours following GLP application and then decreased slightly from 70 to 50% when the RuBP level fell below the RuBP carboxylase active-site concentration. Triose-phosphate, hexose-phosphate, and adenylate energy charge did not change for 8 hours following GLP-application. These data indicate that GLP induced a depletion of carbon or phosphate or both from the photosynthetic carbon reduction cycle, reducing the rate of regeneration of RuBP, photosynthesis, and starch synthesis, while having little effect upon the rate of sucrose synthesis and transport.

Species variation in the predawn inhibition of ribulose-1,5-bisphosphate carboxylase/oxygenase.

The activity of ribulose-1,5-bisphosphate carboxylase/oxygenase was measured in extracts of leaves collected before dawn (predawn activity, pa) and at midday (midday activity, ma). Twenty-three of the 37 species examined showed a pa/ma ratio (

Binding of a Phosphorylated Inhibitor to Ribulose Bisphosphate Carboxylase/Oxygenase during the Night.

The activity of ribulose-1,5-bisphosphate carboxylase/oxygenase was measured at various times during the purification of the enzyme from leaves of Nicotiana tabacum which were collected either 1 hour before the start of the photoperiod (predawn) or in the middle of the photoperiod (midday). The activity of the enzyme in extracts of the predawn leaves (0.8 units/mg enzyme) was consistently about 2-fold lower than that measured in extracts of midday leaves (1.7 units/mg enzyme). The activity of the predawn enzyme was increased to that of the midday enzyme following removal of CO(2) and Mg(2+) (deactivation), (NH(4))(2)SO(4) precipitation, or incubation in SO(4) (2-) (18 millimolar required for one-half maximal increase). Following purification to >95% homogeneity, the predawn enzyme was found to have approximately 0.5 moles of bound organic phosphate per mole of enzyme active sites, while the midday enzyme had only approximately 0.08 moles of bound organic phosphate per mole of enzyme active sites. Deactivation of the predawn enzyme or treatment with 0.2 molar SO(4) (2-) resulted in the removal of most of the bound organic phosphate. These findings support the hypothesis that following the night period about 50% of the enzyme is catalytically inactive because of the tight-binding of a small molecular weight, phosphorylated inhibitor at the active site.

Crystalline ribulose bisphosphate carboxylase/oxygenase of high integrity and catalytic activity from Nicotiana tabacum.

Crystalline tobacco (Nicotiana tabacum L.) ribulose-1,5-bisphosphate carboxylase/oxygenase (EC 4.1.1.39) was prepared using a procedure which protected the enzyme from hydrolysis by endogenous proteases. Leaves were extracted in a buffered medium containing casein, leupeptin, and high concentrations of MgSO4 and NaHCO3. After filtration through ion-exchange resin to remove contaminants, the enzyme was concentrated by precipitation with polyethylene glycol and crystal formation was induced by low-salt dialysis. The crystalline enzyme had a measured specific activity of 1.7 mumol CO2 mg protein-1 min-1, and about 93% of the enzyme could be activated with Mg2+ and CO2. Crystalline enzyme prepared in the absence of casein exhibited an activity which was only one-third of this rate and only about 70% of the enzyme could be activated with Mg2+ and CO2. Casein-extracted enzyme was resolved into distinct bands corresponding to the large (55,000) and small (14,000) subunits by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The large subunit of enzyme prepared according to the latter procedure was found to be composed of five different polypeptides of slightly decreasing molecular weight. Only about one-third of the large subunits were of the 55,000 molecular weight type. No differences between the two preparations were observed in the Km (CO2) and apparent Km (ribulose bisphosphate).

Activation state of ribulose bisphosphate carboxylase in soybean leaves.

Conditions for extraction and assay of ribulose-1,5-bisphophate carboxylase present in an in vivo active form (initial activity) and an inactive form able to be activated by Mg(2+) and CO(2) (total activity) were examined in leaves of soybean, Glycine max (L.) Merr. cv Will. Total activity was highest after extracts had preincubated in NaHCO(3) (5 millimolar saturating) and Mg(2+) (5 millimolar optimal) for 5 minutes at 25 degrees C or 30 minutes at 0 degrees C before assay. Initial activity was about 70% of total activity. K(act) (Mg(2+)) and K(act) (CO(2)) were approximately 0.3 millimolar and 36 micromolar, respectively. The carry-over of endogenous Mg(2+) in the leaf extract was sufficient to support considerable catalytic activity. While Mg(2+) was essential for both activation and catalysis, Mg(2+) levels greater than 5 millimolar were increasingly inhibitory of catalysis. Similar inhibition by high Mg(2+) was also observed in filtered, centrifuged, or desalted extracts and partially purified enzyme. Activities did not change upon storage of leaves for up to 4 hours in ice water or liquid nitrogen before homogenization, but were about 20% higher in the latter. Activities were also stable for up to 2 hours in leaf extracts stored at 0 degrees C. Initial activity quickly deactivated at 25 degrees C in the absence of high CO(2). Total activity slowly declined irreversibly upon storage of leaf homogenate at 25 degrees C.

Effect of irradiance during growth of Glycine max on photosynthetic capacity and percent activation of ribulose 1,5-bisphosphate carboxylase.

The initial (in vivo) and total (activity present after preincubation with CO2 and Mg(2+)) activities of ribulose bisphosphate carboxylase were both assayed in extracts of leaves of soybean (Glycine max) plants which had been grown under 4 different irradiance levels. The total carboxylase activity per unit leaf area decreased with decreased irradiance during growth but was not different on a dry weight basis. The initial activity as a percentage of the total activity was unchanged (approximately 95%) except in leaves of plants grown at the lowest irradiance (74%). When the plants grown at the lowest irradiance were exposed to high irradiance, the initial activity was increased to 93% of the total. Light saturated rates of photosynthesis per unit leaf area were lower and saturated at lower irradiance for plants grown at lower irradiances. Initial carboxylase activity was correlated closely (r(2)=0.84) with leaf photosynthesis rate on a dry weight basis.

Energy-dependent Loading of Amino Acids and Sucrose into the Phloem of Soybean.

Radioactive sucrose, l-leucine, l-glutamate, and gamma-aminobutyrate were applied exogenously to abraded areas of soybean leaves. The three amino acids were translocated with similar velocities and mass transfer rates on a molar basis, although they were metabolized differently in the sink tissue. The concentration dependence of leucine translocation showed a triphasic saturation response, while sucrose translocation showed a biphasic saturation response to increasing concentration. Apparent K(m) and V(max) for leucine and sucrose loading in the phloem differed. Both leucine and sucrose translocation were inhibited by uncouplers, high K(+), and p-chloromercuribenzenesulfonic acid. Treatment with 0.8 m sorbitol had little effect on sucrose translocation but stimulated leucine translocation, indicating an apoplastic route of loading for leucine. No effect on mass transfer rates was observed when sucrose and amino acids were applied exogenously together. These data provide evidence that phloem loading of amino acids and sucrose is mediated by different and separate carriers, both being dependent on an energy-requiring mechanism.

Low root temperature effects on soybean nitrogen metabolism and photosynthesis.

The influences of low root temperature on soybeans (Glycine max [L.] Merr. cv. Wells) were studied by germinating and maintaining plants at root temperatures of 13 and 20 C through maturity. At 42 days from the beginning of imbibition, 13 and 20 C plants were switched to 20 and 13 C, respectively. Plants were harvested after 63 days. Control plants (13 C) did not nodulate, whereas those switched to 20 C did and at harvest had C(2)H(2) reduction rates of 0.2 micromoles per minute per plant. Rates of C(2)H(2) reduction decreased rapidly in plants switched from 20 to 13 C; however, after 2 days, rates recovered to original levels (0.8 micromoles per minute per plant) and then began a slow decline until harvest. Arrhenius plots of C(2)H(2) reduction by whole plants indicated a large increase in the energy of activation below the inflection at 15 C. Highest C(2)H(2) reduction rates (1.6 micromoles per minute per plant) were at 58 days for the 20 C control. Root respiration rates followed much the same pattern as C(2)H(2) reduction in the 20 C control and transferred plants. At harvest, roots from 13 C-treated plants had the highest activities for malate dehydrogenase, glutamate oxaloacetate transaminase, and phosphoenolpyruvate carboxylase. Roots from transferred plants had intermediate activities and those from the 20 C treatment the lowest activities. Newly formed nodules from plants switched from 13 to 20 C had much higher glutamate dehydrogenase than glutamine synthetase activity.Photosynthetic rates on a leaf area basis were about three times as high in the 20 C control as compared to 13 C control plants. Photosynthetic rates of plants switched from 20 to 13 C decreased to less than half the original rate within 2 days. Photosynthetic rates of plants switched from 13 to 20 C recovered to rates near those of the 20 C control plants within 2 weeks. All leaf enzymes assayed at harvest, with the exception of nitrate reductase, were highest in activity in the 20 C control plants.

Oxygen inhibition of photosynthesis and stimulation of photorespiration in soybean leaf cells.

The occurrence of photorespiration in soybean (Glycine max [L.] Merr.) leaf cells was demonstrated by the presence of an O(2)-dependent CO(2) compensation concentration, a nonlinear time course for photosynthetic (14)CO(2) uptake at low CO(2) and high O(2) concentrations, and an O(2) stimulation of glycine and serine synthesis which was reversed by high CO(2) concentration. The compensation concentration was a linear function of O(2) concentration and increased as temperature increased. At atmospheric CO(2) concentration, 21% O(2) inhibited photosynthesis at 25 C by 27%. Oxygen inhibition of photosynthesis was competitive with respect to CO(2) and increased with increasing temperature. The Km (CO(2)) of photosynthesis was also temperature-dependent, increasing from 12 mum CO(2) at 15 C to 38 mum at 35 C. In contrast, the Ki (O(2)) was similar at all temperatures. Oxygen inhibition of photosynthesis was independent of irradiance except at 10 mm bicarbonate and 100% O(2), where inhibition decreased with increasing irradiance up to the point of light saturation of photosynthesis. Concomitant with increasing O(2) inhibition of photosynthesis was an increased incorporation of carbon into glycine and serine, intermediates of the photorespiratory pathway, and a decreased incorporation into starch. The effects of CO(2) and O(2) concentration and temperature on soybean cell photosynthesis and photorespiration provide further evidence that these processes are regulated by the kinetic properties of ribulose-1,5-diphosphate carboxylase with respect to CO(2) and O(2).

pH Dependence of Photosynthesis and Photorespiration in Soybean Leaf Cells.

The effect of pH on the kinetics of photosynthesis, O(2) inhibition of photosynthesis, and photorespiration was examined with mesophyll cells isolated from soybean (Glycine max [L.] Merr.) leaves. At constant, subsaturating bicarbonate concentration (0.5 mm), O(2) inhibition of photosynthesis increased with increasing pH because high pH shifts the CO(2)-bicarbonate equilibrium toward bicarbonate, thereby reducing the CO(2) concentration. At constant, substrating CO(2) concentrations, cell photorespiration decreased with increasing pH. This was indicated by decreases in the CO(2) compensation concentration, O(2) inhibition of photosynthesis, and glycine synthesis. Km(CO(2)) values for isolated cell photosynthesis and in vitro ribulose-1, 5-diphosphate carboxylase activity decreased with increasing pH, while the Ki(O(2)) for both systems was similar at all pH values. The responses to pH of the corresponding kinetic constants of cell photosynthesis and in vitro RuDP carboxylase with respect to CO(2) and O(2) were identical. This provides additional evidence that the relative rates of photosynthesis and photorespiration in C(3) plants are determined by the kinetic properties of RuDP carboxylase.