Metabolic changes in the snake head fish Channa punctatus chronically exposed to endosulfan

The chronic toxic effects of a commonly used pesticide endosulfan on the carbohydrate metabolism of the fresh water telcost fish Channa punctatus were investigated. The fish were exposed to a sub-lethal concentration (0.2 μg l^?1) for 15, 30, and 60 days. The levels of glucose, total plasma proteins, lactic acid and haemoglobin in the blood, glycogen and lactic acid contents of liver and muscles were also measured. Alterations in the activities of hexokinase, lactate dehydrogenase and pyruvate dehydrogenase in the glycolytic pathway, and succinate dehydrogenase in the citric acid cycle were examined in the liver, kidney, intestine, brain, gills and muscles. The results showed that 30 and 60 days of exposure produced more significant changes in different parameters in comparison to 15 days. There was a decrease in blood glucose and total plasma proteins but lactic acid and haemoglobin levels were higher in endosulfan exposed fish than in control fish. Glycogen and lactic acid contents of the liver and muscles were depleted. The activity of hexokinase in liver, kidney and intestine was inhibited after 60 days of exposure but in muscles the enzyme activity was elevated. Glucose-6-phosphatasc was inhibited in all the tissues. Lactate dehydrogenase, pyruvate dehydrogenase and succinate dehydrogenase activities decreased in the liver, kidney, brain and gills after 30 and 60 days of exposure. In the muscles, the activities of lactate dehydrogenase and pyruvate dehydrogenase were elevated while succinate dehydrogenase was inhibited. The study showed that formation of glycogen and its breakdown were impaired in the liver. In the muscles, the rate of glycolysis increased probably due to pesticide induced muscular excitment.     

Effect of sublethal concentrations of mercury on the composition of liver,muscles and ovary of Notopterus notopterus

The present investigation was undertaken to evaluate the effect of sublethal concentrations (0.088 and 0.044 mg 1^?1, i.e., 1/5th and 1/10th fraction of 96 h LC₅₀) of mercuric chloride on Ca, inorganic phosphate, water content, ash, glycogen, Fe, total protein, lipid contents and vitamin A, C, D, and E of liver, muscles and ovary of the freshwater fish Notopterus notopterus exposed for 30 days. The results obtained indicate that Ca, inorganic phosphate, water, ash, glycogen, Fe, total protein contents and vitamin D decreased significantly or insignificantly in these tissues of the Hg exposed fishes. However, lipid content increased in liver and muscles, but decreased in the ovaries. Vitamin A and D increased in the liver but decreased in the muscles and ovaries. Moreover, vitamin E increased in all the tissues of the fish exposed to 0.088 mg 1^?1 and decreased in the fish exposed to 0.044 mg 1^?1 of Hg concentrations.     

Solvent Retention Capacity Values in Relation to Hard Winter Wheat and Flour Properties and Straight‐Dough Breadmaking Quality

Solvent retention capacity (SRC) was investigated in assessing the end use quality of hard winter wheat (HWW). The four SRC values of 116 HWW flours were determined using 5% lactic acid, 50% sucrose, 5% sodium carbonate, and distilled water. The SRC values were greatly affected by wheat and flour protein contents, and showed significant linear correlations with 1,000‐kernel weight and single kernel weight, size, and hardness. The 5% lactic acid SRC value showed the highest correlation (r = 0.83, P < 0.0001) with straight‐dough bread volume, followed by 50% sucrose, and least by distilled water. We found that the 5% lactic acid SRC value differentiated the quality of protein relating to loaf volume. When we selected a set of flours that had a narrow range of protein content of 12–13% (n = 37) from the 116 flours, flour protein content was not significantly correlated with loaf volume. The 5% lactic acid SRC value, however, showed a significant correlation (r = 0.84, P < 0.0001) with loaf volume. The 5% lactic acid SRC value was significantly correlated with SDS‐sedimentation volume (r = 0.83, P < 0.0001). The SDS‐sedimentation test showed a similar capability to 5% lactic acid SRC, correlating significantly with loaf volume for flours with similar protein content (r = 0.72, P < 0.0001). Prediction models for loaf volume were derived from a series of wheat and flour quality parameters. The inclusion of 5% lactic acid SRC values in the prediction model improved R² = 0.778 and root mean square error (RMSE) of 57.2 from R² = 0.609 and RMSE = 75.6, respectively, from the prediction model developed with the single kernel characterization system (SKCS) and near‐infrared reflectance (NIR) spectroscopy data. The prediction models were tested with three validation sets with different protein ranges and confirmed that the 5% lactic acid SRC test is valuable in predicting the loaf volume of bread from a HWW flour, especially for flours with similar protein contents.     

Variability of phenotypic and morphological characteristics of some Lathyrus sativus L. and Lathyrus cicera L. accessions and nutritional traits of their seeds

The object of the study comprised 54 grass pea (Lathyrus sativus) accessions originating from Czech Republic, Hungary, Slovak Republic, Poland, Ukraine and Russia together with 18 red pea (Lathyrus cicera) accessions from Greece, Spain and Italy. The plants were grown under the same conditions in Poland. Some phenological and morphological traits of plants as well as some seed morphological properties and nutritive value were investigated. Lathyrus sativus seeds contained more protein (average 300?g vs. 255?g?kg^?1 dry matter (DM)), whereas the differences in the average contents of the other basic nutrients between both these species as well as between particular accessions were not substantial. Except for a low level of methionine, the protein of both species showed fairly high concentration of other exogenic amino acids (EAAI around 63–64%). Fat of both L. sativus and L. cicera seeds was found to contain a high level of polyunsaturated fatty acids (66.9 and 58.6%, respectively), mainly linoleic (57.4 and 47.2%, respectively). The researched L. sativus accessions had a quite low level of β-ODAP (733?mg with a range of 0.583–1.340?mg?kg^?1 DM). Slightly higher content of this ANF (1,168?mg with 911–1,349?mg?kg ^?1 DM) in L. cicera seeds was noted. Average tannin concentration in the L. sativus and L. cicera accessions reached 3.3 and 6.4?g?kg^?1 DM, respectively. Average content of this ANF in L. sativus significantly correlated with the colour of both, flowers and seeds; with generally, a darker colour associated with higher levels of tannins.     

Microbial growth efficiencies across a soil moisture gradient assessed using C-acetic acid vapor and N-ammonia gas

One integrative measurement of microbial activity in soils is the efficiency by which microbes convert assimilated carbon (C) into biomass C. This efficiency, called the microbial growth efficiency (Y), is a key physiological characteristic that regulates soil carbon sequestration, nutrient immobilization, and greenhouse gas emissions. Changes in rainfall patterns and soil water content as the result of global climate change have the potential to influence microbial activity and lead to changes in Y and thus, nutrient cycling at the ecosystem level. Unfortunately, little information is available on how environmental variables such as soil moisture influence Y. We have developed a new method for injecting ¹³C-labeled carbon as acetic acid vapor into soil that will allow measurement of microbial growth efficiency (as Y_C) without increasing soil moisture content. We compare Y determined with this new approach with an alternate method where injected ¹⁵N-labeled ammonia gas is used to quantify microbial N immobilization, and microbial growth efficiency is calculated based on microbial C:N and respiration rate (as Y_N). We also include injections of a solution containing labeled ammonium and acetate in our experiment to compare the results of our vapor methods with more commonly employed liquid-based methods. The ¹³C-acetic acid vapor, which was supplied to soils with soil moisture content ranging from 0.05 to 0.21 g H₂O g⁻¹ soil, was readily assimilated and respired by microbes. Between 0.10 and 0.21 g H₂O g⁻¹ soil (−0.60 to −0.04 MPa), values of Y_C averaged 0.46, and were significantly lower than values of Y_N, with average values of 0.58. Over this range, soil moisture content had no significant effect on either Y_C or Y_N. However, at the lowest soil moisture content (0.05 g H₂O g⁻¹ soil; <−6.0 MPa), Y_C and Y_N diverged substantially, suggesting that in very dry soils, constraints on microbial growth cause differential uptake of C and N resources.     

不同氮素水平下冬小麦叶片酚酸类物质代谢对FACE的响应

利用开放式空气CO2浓度升高(Free Air Carbon-dioxide Enrichment, FACE)平台, 研究了低氮(LN)和常氮(NN)水平下, 大气CO2浓度升高对冬小麦叶片酚酸类物质代谢的影响.结果表明, CO2浓度升高对小麦叶片水杨酸、对羟基苯甲酸、肉桂酸、阿魏酸和香草酸含量的影响随供氮水平的不同而有所差异.低氮下小麦通过提高叶片苯丙氨酸解氨酶(PAL)活性(30.1%)而使其含量均显著增加, 增幅分别达33.7%、119.6%、26.7%、39.9%和28.6%; 而常氮下PAL活性和酚酸类含量变化均未达显著水平.可见, 大气CO2浓度升高对冬小麦酚酸类物质代谢的影响受氮水平的调控, 在未来CO2浓度升高条件下, 选择适宜的施肥水平将显得更为重要.此外, 总酚含量与水杨酸、对羟基苯甲酸、肉桂酸、阿魏酸和香草酸等含量变化趋势基本一致, 且总酚含量变化的79.6%～151.4%是由这几种酚酸含量变化引起的, 说明CO2浓度升高使水杨酸、对羟基苯甲酸、肉桂酸、阿魏酸和香草酸等含量增加是总酚含量增加的直接原因.低氮条件下大气CO2浓度升高将通过改变酚酸类物质代谢而间接影响小麦与伴生杂草的关系.     

Reducing Steep Time by Adding Lactic Acid During Countercurrent Steeping of Corn with Different Initial Moisture Contents

Reducing corn steep time by adding lactic acid instead of relying on in situ fermentation was studied. Corn at two initial moisture levels (15 and 20%) was steeped for 18 hr in a countercurrent steep system. The initial SO₂ target concentration in steepwater was 2,000 or 3,000 ppm, while the initial lactic acid concentration in steepwater was 0, 0.28, or 0.55%. Adding lactic acid under all steeping conditions decreased steepwater pH, accelerated SO₂ absorption, and increased the amount of solids released from corn. Adding lactic acid during steeping also increased the first grind slurry density and made germ skimming easier than when no lactic acid was added. Starch yields for the hybrid used in this study under all steep conditions were comparable to those from 24‐hr steeping, except when steeping corn with an initial moisture content of 15% in ≈2,000 ppm of SO₂ alone. For the 20% moisture corn, adding lactic acid to fresh steepwater significantly improved the starch yield at ≈2,000 ppm of SO₂ for 18‐hr steeping. At ≈3,000 ppm of SO₂, adding lactic acid did not increase the starch yield for the hybrid used. The protein content in starch was significantly lower when lactic acid was added. Pasting properties of starch were not affected by adding lactic acid. The hybrid used in this study had an initial moisture content of 20% and could be wet‐milled without affecting starch yield, starch protein content, and pasting properties.     

Spatial and seasonal variations in soil respiration in a temperate deciduous forest with fluctuating water table

Our objectives were to determine both spatial and temporal variations in soil respiration of a mixed deciduous forest, with soils exhibiting contrasting levels of hydromorphy. Soil respiration (R_S) showed a clear seasonal trend that reflected those of soil temperature (T_S) and soil water content (W_S), especially during summer drought. Using a bivariate model (RMSE=1.03), both optimal soil water content for soil respiration (W_SO) and soil respiration at both 10 °C and optimal soil water content (R_S10) varied among plots, ranging, respectively, from 0.25 to 0.40 and from 2.30 to 3.60 μmol m⁻² s⁻¹. Spatial variation in W_SO was related to bulk density and to topsoil N content, while spatial variation in R_S10 was related to basal area and the difference in pH measured in water or KCl suspensions. These results offer promising perspectives for spatializing ecosystem carbon budget at the regional scale.     

EFFECTS OF PHYTOHORMONES ON PROLINE CONTENT AND ANTIOXIDANT ENZYMES OF VARIOUS WHEAT CULTIVARS UNDER SALINITY STRESS

Salinity stress is one of the important agricultural problems in the world. A factorial experiment based on completely randomized design with four replications was conducted to evaluate the effects of phytohormones (gibberellic acid and abscisic acid) on the activity of antioxidant enzymes (peroxidase, superoxide dismutase and catalase), rubisco activity and content, and proline in three wheat cultivars (Gascogen, Zagros, and Kuhdasht) under control and salinity stress (3.5 and 7 dS m^?1). The results showed that salinity stress (3.5 and 7 dS m^?1) decreased the activity of catalase, rubisco, carboxylase, but increased peroxidase, superoxide dismutase activity and proline content. Gibberellic acid caused 58.03% increased in rubisco carboxylase activity in Zagros at 7 dS m^?1 in comparison with abscisic acid under salinity stress compared with the control plants in Kuhdasht. Activity of superoxide dismutase in Kuhdasht cultivar at 7 dS m^?1 salinity level showed 76.43% increased in Gascogen under salinity stress compared with the control plants with gibberellic acid application. The highest proline content as an osmolyte was found in Zagros at 7 dS m^?1 salinity level with abscisic acid (194 μmol g^?1 DM) application. Peroxidase activity increased 83.31% and catalase activity decreased 61.27% compared with the control plants in Zagros. Gibberellic acid application significantly prevented reduction in rubisco content under salinity stress. In conclusion, increased in peroxidase and superoxide dismutase activity and proline content decreased the adverse effects of salinity stress on studied cultivars. Also, the foliage spray of gibberellic acid enhanced and improved the growth condition. In this experiment, Zagros cultivar showed more tolerance to salinity stress than the other two cultivars.     

Nitrogen compounds in atmospheric precipitation

The paper presents results of a stoichiometric calculation of a nitrogen (N) compounds in precipitation of World Meteorological Organization's Global Atmosphere Watch (WMO GAW) stations. Long-term trends of ammonium sulphate ((NH₄)₂SO₄) and ammonium nitrate (NH₄NO₃) contents i the North-West of Russia as well as in Byelorussia, Scandinavia, Western and Eastern Europe during the periods of 1958–1990 and 1972–1985 were investigated. A relatively, steady annual trend for the mean NH₄NO₃ concentrations was found typical of pure regions (5–15μeq^* 1^?1). The concentrations in industrial regions are from 4 to 5 times higher than the background close to natural. The analysis of the trend for (NH₄)₂SO₄ content in precipitation shows a wide range of a variations of mean annual concentrations with an explicit tendency to their significant decrease in some European regions in the mid-eighties. Nitric acid (HNO₃) has not been discovered in precipitation from the European WMO GAW stations while calculations based on the US data revealed its remarkable content and tendency to its increase. Nitric acid and ammonium sulphate are not contained in precipitation over ocean, ammonium nitrate is present in insignificant amounts.     

Elevated CO2 Accelerates Phosphorus Depletion by Common Bean (Phaseolus vulgaris) in Association with Altered Leaf Biochemical Properties

Phosphorus(P) is a major limiting factor for plant productivity in many ecosystems and agriculture. The projected increase in atmospheric CO_2 is likely to result in changes in plant mineral consumption and growth. We studied P depletion by common bean(Phaseolus vulgaris) cultured hydroponically under ambient(377 ± 77 μmol mol~(-1)) or elevated(650 ± 32 μmol mol~(-1)) CO_2 in media of low or high P. Under elevated CO_2 compared to ambient CO_2, the maximum P depletion rate increased by 98% at low P and250% at high P, and P was depleted about 2–5 weeks sooner; leaf acid phosphatase(APase) activity and chlorophyll content both increased significantly; root-to-shoot ratio increased significantly at high P, although it was unaffected at low P; lateral root respiration rate showed no change, suggesting that CO_2 did not affect P depletion via metabolic changes to the roots; the total biomass at final harvest was significantly higher at both low and high P. Our data showed that the increased rate and amount of P depletion during plant growth under elevated CO_2 occurred in association with alterations in leaf biochemical properties, i.e., enhanced activities of leaf APase and increased leaf chlorophyll content.     

Remediation of Metal Contaminated Soil by Organic Metabolites from Fungi I—Production of Organic Acids

Investigations were made on living strains of fungi in a bioremediation process of three metal (lead) contaminated soils. Three saprotrophic fungi (Aspergillus niger, Penicillium bilaiae, and a Penicillium sp.) were exposed to poor and rich nutrient conditions (no carbon availability or 0.11 M d-glucose, respectively) and metal stress (25 µM lead or contaminated soils) for 5 days. Exudation of low molecular weight organic acids was investigated as a response to the metal and nutrient conditions. Main organic acids identified were oxalic acid (A. niger) and citric acid (P. bilaiae). Exudation rates of oxalate decreased in response to lead exposure, while exudation rates of citrate were less affected. Total production under poor nutrient conditions was low, except for A. niger, for which no significant difference was found between the poor and rich control. Maximum exudation rates were 20 µmol oxalic acid g^?1 biomass h^?1 (A. niger) and 20 µmol citric acid g^?1 biomass h^?1 (P. bilaiae), in the presence of the contaminated soil, but only 5 µmol organic acids g^?1 biomass h^?1, in total, for the Penicillium sp. There was a significant mobilization of metals from the soils in the carbon rich treatments and maximum release of Pb was 12% from the soils after 5 days. This was not sufficient to bring down the remaining concentration to the target level 300 mg kg^?1 from initial levels of 3,800, 1,600, and 370 mg kg^?1in the three soils. Target levels for Ni, Zn, and Cu, were 120, 500, and 200 mg kg^?1, respectively, and were prior to the bioremediation already below these concentrations (except for Cu Soil 1). However, maximum release of Ni, Zn, and Cu was 28%, 35%, and 90%, respectively. The release of metals was related to the production of chelating acids, but also to the pH-decrease. This illustrates the potential to use fungi exudates in bioremediation of contaminated soil. Nonetheless, the extent of the generation of organic acids is depending on several processes and mechanisms that need to be further investigated.     

Physicochemical Properties of Maize Starch Obtained from Intermittent Milling and Dynamic Steeping (IMDS) Under Various Steeping Conditions

Physicochemical properties of maize starch obtained under different steeping conditions by intermittent milling and dynamic steeping process (IMDS) were studied. Brazilian dent maize (hybrid XL 606) was milled using a 2×2×3 factorial experimental design with two lactic acid levels (0.0 and 0.55%, v/v), two SO₂ levels (0.05 and 0.1%, w/v), and three temperatures (52, 60, and 68°C). Properties of starch obtained by conventional wet‐milling process (36 hr at 52°C, 0.55% lactic acid, and 0.2% SO₂) were used for comparison. Starch protein content and solubility increased with presence of lactic acid, while swelling power decreased. Higher SO₂ concentration (0.1%) had the same effect as lactic acid on some properties. Steeping temperatures of 60 and 68°C increased solubility and most of the thermal properties but reduced swelling power, suggesting stronger starch annealing during IMDS at these temperatures. Some thermal changes on starch granules were visualized by scanning electron microscopy (SEM) at 60 and 68°C. Amylose content as well as pasting properties were affected by steeping factors and interactions. Starches from IMDS and conventional wet‐milling processes were similar in most properties, indicating that IMDS provides starch with quality similar to that from conventional milling.     

Urea hydrolysis in soils: Factors influencing the effectiveness of phenylphosphorodiamidate as a retardant

Studies to determine the factors influencing the effectiveness of phenylphosphorodiamidate (PPD) to retard urea hydrolysis in soils showed that the inhibitory effect of PPD on hydrolysis of urea by soil urease increased markedly with the amount of PPD added and decreased markedly with time and with increase in temperature from 10 to 40°C. They also showed that the ability of PPD to retard urea hydrolysis in 15 surface soils selected to obtain a wide range in properties was significantly correlated with organic C content (r = ?0.68⁷), total N content (r = ?0.74⁷), cation-exchange capacity (r = ?0.65⁷), sand content (r=0.66⁷), clay content (r = ?0.64⁷) and surface area (r = ?0.60¹), but was not significantly correlated with pH, silt content, urease activity or CaCO₃ equivalent. Multiple-regression analyses indicated that the effectiveness of PPD to retard urea hydrolysis in soils tends to increase with decrease in soil organic-matter content.     

The acid buffer capacity of some finnish forest soils: Results of acid addition laboratory experiments

Batch acid addition experiments were carried out to determine the acid buffer capacities (amount of acid required to lower soil pH by one unit) of forest soils. Samples of O, E, B (or BC), and C horizons taken from 29 podzolic profiles in southern Finland were used in the experiments. Subsamples of soil were equilibrated for 24 h with NaCl solution containing additions of HCl acid. Cation exchange, mineral dissolution (weathering), and the protonation of organic matter all appeared to have been involved in the buffering of the acid additions. For the O horizon samples, most of the cations released in response to the acid additions were base cations. For the mineral soil samples, most of the cations released were Al³⁺ ions. With the exception of a few samples, the added acid was not fully neutralised and pH was lowered even with the lowest addition treatment. However, the acid addition treatments corresponded to many times the regional annual acid deposition load (1.6–2.0 cmol(c) m^?2). Calculated acid buffer capacities (cmol(c) kg^?1 pH^?1) ranged from 9.8 to 40.8 for O horizon soil samples and from 0.1 (C horizon) to 5.2 (E horizon) for the mineral soil samples. Total acid buffer capacities for a profile (to a depth of 50 cm) ranged from 500 to 2349, with a mean value of 1091 cmol(c) m^?2 pH^?1. It is concluded that, in addition to CEC and base saturation, acid buffer capacity is a useful measure to describe the ecological effects of acid deposition on soil.     

Optimization of arsenic and pentachlorophenol removal from soil using an experimental design methodology

Purpose

In this study, a soil-washing process was investigated for arsenic (As) and pentachlorophenol (PCP) removal from polluted soils. This research first evaluates the use of chemical reagents (HCl, HNO₃, H₂SO₄, lactic acid, NaOH, KOH, Ca(OH)₂, and ethanol) for the leaching of As and PCP from polluted soils.

Materials and methods

A Box–Behnken experimental design was used to optimize the main operating parameters for soil washing. A laboratory-scale leaching process was applied to treat four soils polluted with both organic ([PCP] _i ?=?2.5–30 mg kg^?1) and inorganic ([As] _i ?=?50–250 mg kg^?1, [Cr] _i ?=?35–220 mg kg^?1, and [Cu] _i ?=?80–350 mg kg^?1) compounds.

Results and discussion

Removals of 72–89, 43–62, 52–68, and 64–98 % were obtained for As, Cr, Cu, and PCP, respectively, using the optimized operating conditions ([NaOH]?=?1 N, [cocamidopropylbetaine] _i ?=?2 % w w^?1, t?=?2 h, T?=?80 °C, and PD?=?10 %).

Conclusions

The use of NaOH, in combination with the surfactant, is efficient in reducing both organic and inorganic pollutants from soils with different levels of contamination.     

Effects of Two Different Ozone Exposure Regimes on Chlorophyll and Sucrose Content of Leaves and Yield Parameters of Sugar Beet (Beta Vulgaris L.) and Rape (Brassica Napus L.)

Sugar beet (Beta vulgaris cv. Loretta) and rape (Brassica napus cv. Licolly) plants were exposed under equaldose conditions in closed fumigation chambers under twodifferent ozone (O₃) pattern: Var₁₃₀ (17:00–09:00 h: 40 μg O₃ m^-3; 09:00–17:00 h: 130μgO₃ m^-3) and Var₂₂₀ (16:00-12:00 h: 40 μgO₃ m^-3; 12:00–16:00 h: 220μg O₃ m^-3).Control plants were exposed under carbon filtered airconditions (ozone free, CF-control). Sugar beet plants wereexposed four weeks each during 6-leaf-stage and lateralgrowth respectively. Rape plants were exposed for 14 daysduring flowering (f) or as young plants (y). In between andafter the end of exposure, plants were kept in carbonfiltered air (CF; < 10 μg O₃ m^-3). With respect to sucrose and chlorophyll content of leaves andseed weight, rape plants were most sensitive duringflowering. Under equal dose conditions, the most pronouncedeffects on chlorophyll and sucrose content of leaves as wellas fresh weight of taproots (CF: 100%; Var₁₃₀: 97%;Var₂₂₀: 83%) and of rape seeds (CF: 100%; y:Var₁₃₀: 122%; Var₂₂₀: 99%; f: Var₁₃₀: 84%;Var₂₂₀: 78%) were detected after exposure under shorttime high ozone peak conditions (Var₂₂₀). Howeverglucose content in taproots (CF: 100%; Var₁₃₀: 43%;Var₂₂₀: 79%) and fatty acid content in rape seeds wasaffected most after exposure to moderate ozone peaks(Var₁₃₀). Var₁₃₀-plants seem to recover better fromozone stress than Var₂₂₀-plants, but glucose content oftaproots and fatty acid content of rape seeds indicate long-lastingeffects especially in Var₁₃₀-plants.Although experiments were conducted in a closed chambersystem it can be concluded, that current ozone concentrationscan induce adverse effects on these crops.     

Effect of fulvic acids on lead-induced oxidative stress to metal sensitive Vicia faba L. plant

Lead (Pb) is a ubiquitous environmental pollutant capable to induce various morphological, physiological, and biochemical functions in plants. Only few publications focus on the influence of Pb speciation both on its phytoavailability and phytotoxicity. Therefore, Pb toxicity (in terms of lipid peroxidation, hydrogen peroxide induction, and photosynthetic pigments contents) was studied in Vicia faba plants in relation with Pb uptake and speciation. V. faba seedlings were exposed to Pb supplied as Pb(NO₃)₂ or complexed by two fulvic acids (FAs), i.e. Suwannee River fulvic acid (SRFA) and Elliott Soil fulvic acid (ESFA), for 1, 12, and 24?h under controlled hydroponic conditions. For both FAs, Pb uptake and translocation by Vicia faba increased at low level (5?mg?l^?1), whereas decreased at high level of application (25?mg?l^?1). Despite the increased Pb uptake with FAs at low concentrations, there was no influence on the Pb toxicity to the plants. However, at high concentrations, FAs reduced Pb toxicity by reducing its uptake. These results highlighted the role of the dilution factor for FAs reactivity in relation with structure; SRFA was more effective than ESFA in reducing Pb uptake and alleviating Pb toxicity to V. faba due to comparatively strong binding affinity for the heavy metal.     

Effect of <Emphasis Type="SmallCaps">l</Emphasis>-lactic acid from whey wastes on enzyme activities and bacterial diversity of soil

The l-lactic acid obtained from a whey waste valorization process decreased pH and increased phosphate solubilization of a Plagic Antrosol soil. This behavior was reversible due to the complete and rapid degradation of lactic acid by soil microorganisms, leading to a strong soil biological stimulation. Both dehydrogenase (DHA) and acid phosphomonoesterase (APA) activities were also significantly stimulated, due to the stimulation of microbial activity, whereas the β-glucosidase activity was unaffected. There was also a shift in bacterial biodiversity with growth of bacterial strains using lactic acid as a C source. The bacteria enriched belonged to the plant growth-promoting bacteria (PGPb), such as Rhizobium and Azotobacter genus, involved in N₂ fixation, and Pseudomonas and Bacillus genera, involved in phosphorous bioavailability. We conclude that lactic acid application improves fertility parameters on soils. Further research at field scale is needed to confirm these results.     

Effect of humic acid on copper adsorption by Kaolin

Varying amounts of humic acid (Na-salt; 0 to 10 ppm) were first equilibrated with a dilute suspension of H⁺ -Kaolin and then with spiked (high activity radioactive ⁶⁴Cu) water. After filtration, through a 0.45 µm Millipore membrane, the amount of radioactivity on the filter and the filtrate was measured separately using a Gamma ray well counter. Adsorption of Cu (expressed as distribution coefficient — K _d ) was plotted against humic acid concentration. K _d values decreased sharply upto 1 ppm humic acid concentration and thereafter remained constant up to 10 ppm.