Influence of sodium humate on the crop plants inoculated with bacteria of agricultural importance

Summary The dry-matter yield and nitrogen uptake of berseem (Trifolium alexand-drinum), yield, nitrogen uptake, nodulation and leghaemoglobin content of dhaincha (Sesbania aculeata) inoculated with specific rhizobia were appreciably influenced by the application of sodium humate to soil under green house conditions. Even the application of sodium humate alone without bacterial inoculation had good growth stimulating influence on both the crops, and this effect was further improved by the application of inorganic nitrogen to dhaincha plants. A fair increase in the yield and phosphorus up-take of wheat (Triticum vulgare) inoculated withAzotobacter and/orBacillus spp. was also recorded with the addition of the humic material to the soil. The greatest effect was observed on the plants inoculated withAzotobacter andBacillus spp. together.     

Survival and Reproduction of Some Nematodes as Affected by Muck and Organic Acids

Fulvic, humic, acetic, N-bulyric, formic, lactic, and propionic acids were inhibitory to the survival or reproduction of Aphelenchus avenae, Aphelenchoides goodeyi, Helicotylenchus pseudorobustus, Meloidogyne hapla or Xiphinema americanum. Reproduction of H. pseudorobustus and M. hapla significantly increased with increasing amounts of muck added to sand, and with the initial amount of nematode inoculum. All acids except humic and fulvic were lethal, in vitro, to all nematode species tested. When A. goodeyi was treated with fulvic acid, reproduction was reduced significantly when compared with sodium humate or water treatments. Treatment of H. pseudorobustus with fulvic acid (pH 3.5) resulted in a greater reduction in reproduction in soil than did treatment with humic acid (pH 3.5).     

Effect of aldrin on nodulation,nitrogen fixation and yield of bengal gram (Cicer arietinum)

Summary The effect of aldrin on nodulation (nodule number and their dry weight) in bengal gram (Cicer arietinum) was not very clear. Aldrin decreased nitrogen fixation and yield at the concentration of 1, 5 and 10 ppm in soil. The application of farm yard manure eliminated completely the adverse effects on yield and partially, the adverse effects on nitrogen fixation. There was an increase in yield with the application of aldrin along with farm yard manure. Nodulation and nitrogen fixation at 1 ppm level of aldrin were more than control in presence of FYM. re]19760102     

Effects of a soil fulvic acid on the growth and nutrient content of cucumber (Cucumis sativus) plants

Summary Cucumber (Cucumis sativus) plants were grown in Hoagland solution to which 20 to 2000 ppm of a soil fulvic acid (FA) were added. The addition of 100 to 300 ppm of FA produced highly significant increases in the growth and development of above and below ground plant parts, in the uptake of nutrient elements (N, P, K, Ca, Mg, Cu, Fe and Zn), and in the formation of numbers of flowers per plant. Effects of adding 500 and more ppm of FA were less beneficial.     

Effect of a formulation of urea,thiourea and humate on nitrogen availability and yield of wheat

Summary Urea was mineralized completely in 15 days when applied at concentrations of 50 and 30 ppm nitrogen (N) in the soil. Humate showed no effect whereas thiourea with and without humate delayed nitrate formation by 30 days.In pot-culture experiment, humate at 1.0 ppm concentration increased the grain yield of wheat but not significantly. Urea (25 ppm N) and thiourea (5 ppm N) increased the grain yield significantly. This effect was stimulated by humate treatment. re]19760629     

The effects of pH and aluminium toxicity on the growth and symbiotic development of cowpeas (Vigna unguiculata (L.) Walp)

Summary The interaction of pH (4 or 6), aluminium (0 or 16 ppm at pH 4) and N source (symbiotic or combined) on the growth and nutrient status of cowpea (Vigna unguiculata) was studied in a glasshouse experiment.Low pH significantly decreased the growth of the plants dependent on symbiotic nitrogen fixation but at pH 4 the addition of 16 ppm Al further depressed growth in both nitrogen regimes. Al-ions appear to exert their effect primarily on the root system, as shown by the reduction in total length and fresh weight. The symbiotic development of the plants was affected by low pH but more markedly by the Al treatment.Shoot nitrogen concentrations were reduced from ca. 2.6% at pH 6 to 1.8% and 0.9% at pH 4 without and with aluminium respectively. Calcium concentration was decreased by low pH and further by Al in both nitrogen regimes.In all Al-treated plants, the aluminium was mainly accumulated in the roots and was associated with an increase in their phosphorus concentration.     

Effect of a soil fulvic acid on stem elongation in peas

Summary Previously observed marked stimulating effects on root initiation produced by a naturally occurring fulvic acid, prompted a further study of the growth reactions of plants exposed for short durations to high concentrations of this acid. Fulvic acid concentrations up to 4000 ppm were found to inhibit stem elongation in dark grown Alaska pea stems in the presence and absence of added IAA by 46% and 33% respectively. Concentrations higher than 4000 ppm produced toxic reactions which increased sharply at pH 4.0 and lower and at pH 7.0 and higher. The fulvic acid appeared to block the uptake of GA₃ in Laxton's Progress No 9 peas when the two substances were applied simultaneously to the leaves, but when these substances were applied separately the fulvic acid had no effect on GA₃-stimulated growth. Contribution No.114 of the Food Research Institute; No.291 Soil Research Institute, Canada Department of Agriculture, Ottawa, Ontario.     

Heterotrophic growth and nutritional aspects of the diatom Cyclotella cryptica (Bacillariophyceae): effect of nitrogen source and concentration

To investigate the nutritional value of the diatom Cyclotella cryptica Reimann, Lewin, and Guillard as an alternative feed for the use in the aquaculture industry, the heterotrophic growth characteristics, total fatty acids, and the resultant fatty acid profile of the microalga were studied when cultivated with sodium nitrate, ammonium chloride, or urea. All three nitrogen sources supported growth under heterotrophic conditions, and their uptake affected the pH of the cultivation medium, even when buffered. The use of sodium nitrate or urea resulted in a significant increase in the pH of the cultivation media, whereas the use of ammonium chloride caused a minor decrease in the pH of the cultivation media. The maximum specific growth rate was highest when urea and ammonium chloride were supplied at a low concentration; however, the total fatty acid content was not significantly affected (P = 0.101) by the nitrogen source when supplied at 10.7 mM nitrogen. The total fatty acid content and fatty acid profile of C. cryptica was more affected by the growth phase (predominately influenced by the initial nitrogen concentration) than by the source of nitrogen.     

Regeneration from rhizome fragments of Agropyron repens

Experiments were done with rhizome fragments of Agropyron repens with or without ‘late spring dormancy’. Increasing concentrations of KN0₃ from 1 to 210 ppm successively increased the percentage of buds released from dormancy, but the restriction of shoot extension was significantly lessened only when concentrations of nitrogen were 50 ppm or more. Solutions of sodium nitrite, ammonium chloride and glutamic acid with equal nitrogen contents were equally effective in releasing buds from dormancy. Larger amounts of nitrogen were required to stimulate growth in basal buds, than in apical buds. GA₃, and chilling at – 2 ^oC slightly increased the percentage of buds growing but did not significantly affect the amount of extension growth, while ethephon (2-chloroethylphosphonic acid) had no effect. The restoration of regenerative capacity was associated with increased utilization of rhizome sugars. In single-node rhizome fragments with ‘late spring dormancy’, chilling for 2 wk slightly increased the regenerative capacity but chilling for longer periods decreased it, possibly because respiration during the protracted period of chilling depleted rhizome reserves. Chilling also increased the utilization of rhizome carbohydrates during subsequent growth. Node position affected regenerative capacity: buds from the apical end of the rhizomes were found to have the highest regenerative capacity, this being associated with their greater nitrogen content. Because the name ‘late spring dormancy’ seems to be inappropriate for this phenomena, the term ‘Restricted Regenerative Capacity’ is proposed.     

Synthesis,characterization and swelling behaviors of sodium alginate-g-poly(acrylic acid)/sodium humate superabsorbent

A novel sodium alginate-g-poly(acrylic acid)/sodium humate superabsorbent was prepared by graft copolymerization with sodium alginate, acrylic acid and sodium humate in aqueous solution, using N,N’-methylenebisacrylamide as a crosslinker and ammonium persulfate as an initiator. The effects of crosslinker, sodium alginate and sodium humate content on water absorbency of the superabsorbent were studied. The swelling behavior in solutions of various pH and the swelling kinetics in saline solutions (5 mmol/L NaCl and CaCl₂) were also investigated. The results from IR analysis showed that both sodium alginate and sodium humate react with the acrylic acid monomer during the polymerization process. The introduction of sodium humate into the sodium alginate-g-poly(acrylic acid) system could enhance the water absorbency and the superabsorbent containing 10 wt% sodium humate acquired the highest water absorbency (1380 g/g in distilled water and 83 g/g in 0.9 wt% NaCl solution).     

Tolerance of Australian tropical and subtropical Acacias to acid soil

Two glasshouse experiments were conducted to refine screening procedures and to rank 36 native Acacia species for acid-soil tolerance. The first experiment showed that nitrogen fixation was more sensitive to soil acidity than plant growth per se. This suggests that, in screening experiments where acid soil tolerant rhizobia are not available, inorganic nitrogen should be supplied in determining the species' intrinsic ability to tolerate soil acidity and to avoid confounding sensitivity to acid soil with ineffectiveness of Rhizobium/Bradyrhizobium. The second experiment enabled us to rank 36 species into 4 classes of differing tolerance to acid soil. This experiment also indicated that the ranking order of species differed with the soil type, suggesting the need to use more than one soil type in screening experiments in order to obtain a better and more reliable ranking of species for tolerance to acid soil.     

Influence of soluble humic substances on the growth of Algæ and blue-green Algæ

A stimulatory effect of soluble humic acid and sodium humate of soft coal origin on the growth of green algæChlorella andScenedesmus was established. On the contrary, the growth of blue-green algæ was not affected by humic substances. For green microorganisms soluble humic substances act more as a fertilizer than a bacteriostatic substance. The possibility of application of soluble humic substances as selective fertilizer of algæ at the expense of blue-green algæ at concentrations up to 300 mg/L is discussed.     

Contribution of bacterial cell nitrogen to soil humic fractions

Summary Living cells ofSerratia marcescens, uniformly labelled with¹⁵N, were added to samples of maple (Acer saccharum) and black spruce (Picea mariana) forest soils. After different periods of incubation from zero time to 100 days, the soils were subjected to alkali-acid and phenol extraction to provide humic acid, fulvic acid, humin and humoprotein fractions. Significant amounts of the cell nitrogen were recovered in the humic and fulvic acids immediately after addition. After incubation, less cell, nitrogen appeared in the humic acid and more in the fulvic acid. The amount of cell nitrogen recovered in the humin fraction increased with incubation. Roughly 5 to 10 per cent of the added cell nitrogen was found as amino acid nitrogen from humoprotein in a phenol extract of the humic acid. The data are consistent with the occurrence of co-precipitation of biologically labile biomass nitrogen compounds with humic polymers during the alkaline extraction procedure involved in the humic-fulvic fractionation.     

Nodulation and growth ofLeucaena leucocephala (Lam.) de Wit as affected by inoculation and N fertilizer

Leonard jar, pot and field experiments examined the effects of inoculation and the influence of nitrogen fertilizer on nodulation, nitrogen fixation and growth ofLeucaena leucocephala (Lam.) de Wit at IITA, Ibadan, Nigeria. Leucaena responded to both inoculation and/or nitrogen application. Shoot growth and total N and P of inoculated plants were comparable to those of the highest N treatment, and the values were about 55% greater than those of uninoculated ones. Field data indicated that toal N yields of inoculated leucaena were increased by 50% with 40 or 80 kg ha^–1 of N fertilizer. However, N fertilizer depressed N fixation by 56% as was expected from nodule mass data. N-fixation was delayed for about 8 weeks in the plots without N. Application of small amounts of N starter (20 ppm) proved to be beneficial to satisfy the plant need during the early stage of leucaena growth. The rhizobial strains IRc 1045 and IRc 1050 were effective, competitive and survived well in the field one year after their establishment.     

Influence of humic, fulvic and hydrophilic acids on the growth, photosynthesis and respiration of the dinoflagellate Prorocentrum minimum (Pavillard) Schiller

Blooms of the dinoflagellate Prorocentrum minimum often occur in coastal regions characterized by variable salinity and elevated concentrations of terrestrially derived dissolved organic carbon (DOC). Humic, fulvic and hydrophilic acid fractions of DOC were isolated from runoff entering lower Narragansett Bay immediately after a rainfall event and the influence of these fractions upon P. minimum growth, cell yield, photosynthesis and respiration was examined. All organic fractions stimulated growth rates and cell yields compared with controls (no organic additions), but the extent of stimulation varied with the fraction and its molecular weight. Greatest stimulations were observed with humic and fulvic acids additions; cell yields were more than 2.5 and 3.5 times higher than with hydrophilic acid additions while growth rates were 21 and 44% higher, respectively. Responses to additions of different molecular weight fractions of each DOC fraction suggest that growth rate effects were attributable to specific molecular weight fractions: the >10,000 fraction of humic acids, both the >10,000 and <500 fractions of fulvic acids and the <10,000 fraction of hydrophilic acids. The form and concentration of nitrogen (as NO₃⁻ or NH₄⁺) present also influenced P. minimum response to DOC; 10–20 μg ml⁻¹ additions of fulvic acid had no effect upon growth rates in the presence of NH₄⁺ but significantly increased growth rates in the presence of NO₃⁻, a relationship probably related to fulvic acid effects upon trace metal bioavailability and subsequent regulation of the biosynthesis of enzymes required for NO₃⁻ assimilation. The influence of DOC additions on P. minimum respiration and production rates also varied with the organic fraction and its concentration. Production rates ranged from 1.1 to 3.4 pg O₂ cell⁻¹ h⁻¹, with highest rates observed upon exposure to fulvic and hydrophilic acid concentrations of >10 μm ml⁻¹. Low concentrations (5–10 μg ml⁻¹) of humic acid had no statistically significant effect upon production, but exposure to concentrations >25 μg ml⁻¹ resulted in a 30% decrease in O₂ evolution, probably due to light attenuation by the highly colored humic acid fraction. Respiration rates ranged from 1.2 to 2.7 pg O₂ cell⁻¹ h⁻¹ and were elevated upon exposure to both fulvic and hydrophilic acids, but not to humic acid. These results demonstrate that terrestrially derived DOC fractions play an active role in stimulation of P. minimum growth via direct effects upon growth, yield and photosynthesis as well as via indirect influences such as interactions with nitrogen and effects upon light attenuation.     

Evidence for the induction of catechol-1,2-oxygenase by fulvic acid

Summary The effect of fulvic acid on the growth of a benzoate-metabolizing Arthrobacter sp. has been studied. The Arthrobacter grew exponentially with benzoate and fulvic acid but if fulvic acid was omitted then growth was progressively slower and catechol accumulated. These results indicated that fulvic acid enhanced the synthesis of catechol-1,2-oxygenase. Catechol-1,2-oxygenase activity measurements support this suggestion. re]19750822     

NITROGEN FIXATION RATE AND CHLOROPHYLL CONTENT OF THE LICHEN PELTIGERA CANINA EXPOSED TO SULFUR DIOXIDE

In general, the rate of nitrogen fixation decreased when the lichen Peltigera canina (L.) Willd. was exposed to sulfur dioxide gas at levels from 0.1 to 500 ppm; at 30 ppm, however, nitrogen fixation was stimulated. Chlorophyll content decreased as level of sulfur dioxide increased.     

Boron,an essential micro-element forAzotobacter chroococcum

Summary 1. It was shown that boron is an essential micro-element forAzotobacter chroococcum.2. Multiplication, CO₂ production, N fixation and pigmentation are closely related to the boron content of the culture medium. Of these, pigmentation is most susceptible to slight boron deficiency; with an easily assimilable carbon source (mannite, glucose) nitrogen fixation seems to be more susceptible than multiplication to boron deficiency.3. With increasing gifts of boron, the CO₂ production curves in quartz sand with nutrients as well as in liquid cultures follow each other at regular sequences.4. The optimum boron content for normal development ofAzotobacter amounts toca 2 ppm in liquid cultures, to 5 ppm in quartz sand cultures, whereas in soils sometimes 8 ppm B are tolerated, without noticeable loss of activity.     

Growth, nutrition, and nitrogen fixation in grey alder at varied rate of nitrogen addition

Seedlings of grey alder (Alnus incana Moench), nodulated or unnodulated, were investigated at varied relative addition rate of nitrogen. Nitrogen fixation alone, without addition of mineral nitrogen, resulted in an almost optimum nitrogen status but only about half the maximum relative growth rate, probably mainly because of energy costs of nodulation and fixation. The growth deficit due to nodulation was much more than can be explained by the theoretical energy requirement for the amount of nitrogen fixed. Thus, the nitrogen fixation process was not very efficiently used. The nitrogen fixation rate was strongly stimulated by increasing nitrogen addition rate up to high levels. The fixation rate decreased rapidly close to optimum (maximum relative growth rate) and was negligible at maximum growth. A feed-back of mineral nitrogen on photosynthesis increased fixation rate with time, and the relative importance of fixation over mineral nitrogen nutrition increased. However, nitrogen fixation, also at maximum rate, supplied only a small proportion of the nitrogen amount required for maximum growth. The optimum nutrient solutions contained comparatively high nitrogen concentrations to secure free access to nitrogen. The nodules were damaged by this treatment, and it is concluded that the nitrogen additions must be adjusted to the current consumption of the plants to avoid an increased external nitrogen concentration. Strong linear regressions were found between relative growth rate, nitrogen status expressed as percentage content of fresh weight, and relative growth rate in unnodulated seedlings. There was a greater variability in nodulated seedlings than in unnodulated ones, because of the nitrogen fixation. The reactions of unnodulated grey alder were largely the same as previously reported for birch seedlings, but the maximum growth capacity was lower in grey alder. During an initial period of change in the internal nitrogen status, deficiency symptoms appeared, especially in unnodulated seedlings. As in birch, the leaves turned green again at stable nitrogen status, independent of level. The results are in sharp contrast to data from the literature where the external nitrogen concentration was used as the driving variable for the internal nitrogen status. The measured fixation rates for grey alder are much higher than those previously reported. Still, the maximum fixation rate observed is small compared to the total nitrogen uptake rate required for maximum growth, in contrast to reported relationships. These comparisons indicate that increased external nitrogen concentration obscures the real relations between mineral and fixed nitrogen, on one hand because of rapid inhibition of nitrogen fixation and, on the other hand, because of failure to obtain stable optimum nutrition and maximum growth by means of this treatment variable.     

Fluoride‐sensitivity of growth and acid production of oral Actinomyces: comparison with oral Streptococcus

Actinomyces are predominant oral bacteria; however, their cariogenic potential in terms of acid production and fluoride sensitivity has not been elucidated in detail and compared with that of other caries‐associated oral bacteria, such as Streptococcus. Therefore, this study aimed to elucidate and compare the acid production and growth of Actinomyces and Streptococcus in the presence of bicarbonate and fluoride to mimic conditions in the oral cavity. Acid production from glucose was measured by pH‐stat at pH 5.5 and 7.0 under anaerobic conditions. Growth rate was assessed by optical density in anaerobic culture. Although Actinomyces produced acid at a lower rate than did Streptococcus, their acid production was more tolerant of fluoride (ID_{acid production} 50 = 110–170 ppm at pH 7.0 and 10–13 ppm at pH 5.5) than that of Streptococcus (ID_{acid production} 50 = 36–53 ppm at pH 7.0 and 6.3–6.5 ppm at pH 5.5). Bicarbonate increased acid production by Actinomyces with prominent succinate production and enhanced their fluoride tolerance (ID_{acid production} 50 = 220–320 ppm at pH 7.0 and 33–52 ppm at pH 5.5). Bicarbonate had no effect on these variables in Streptococcus. In addition, although the growth rate of Actinomyces was lower than that of Streptococcus, Actinomyces growth was more tolerant of fluoride (ID_growth 50 = 130–160 ppm) than was that of Streptococcus (ID_growth 50 = 27–36 ppm). These results indicate that oral Actinomyces are more tolerant of fluoride than oral Streptococcus, and bicarbonate enhances the fluoride tolerance of oral Actinomyces. Because of the limited number of species tested here, further study is needed to generalize these findings to the genus level.