接种固氮菌对甘蔗组培苗氮营养生理特性的影响

[目的]研究接种固氮菌对甘蔗组培苗氮营养生理特性的影响。[方法]将2种内生固氮菌B16L与B8R接种到甘蔗栽培品种G16、R16与R22的组培苗中,研究这些组培苗的氮营养生理特性的变化。[结果]于分蘖期和拔节期的测定结果表明,R16与R22+1叶的叶绿素含量、Ca2+-ATP酶活性处理均大于对照,G16+1叶的Ca2+-ATP酶活性处理低于对照。相对于分蘖期,拔节期不同品种的处理与对照的+1叶的叶绿素含量、Ca2+-ATP酶活性都有所升高。不同品种的处理与对照+1叶的硝态氮含量没有规律变化。[结论]接种内生固氮菌改善了R16与R22健康组培苗的一些氮营养生理特性,但对G16的影响不大。     

Diazotroph community structure and abundance in wheat–fallow and wheat–pea crop rotations

Biological input of nitrogen (N) from the atmosphere by free-living diazotrophs can help alleviate fertilizer use in agricultural systems. In this study, we investigated the effect of N fertilizer and winter pea (Pisum sativum L.) crop on the community structure and abundance of free-living diazotrophs in a two year study of dryland winter wheat (Triticum aestivum L.) no-till production system in Eastern Oregon, USA. Based on quantification of the nifH gene, diazotroph abundance was strongly influenced by plant species and the crop year in which the soil samples were collected. A greater amount of nifH copies was recovered in 2012 compared to 2011 either as copies per gram soil or normalized to the abundance of bacterial 16S rRNA genes. The quantity of genes was greater under pea than wheat in 2012 although no difference was observed in the preceding year. The nifH gene abundance was positively correlated to ammonium concentration in 2011 and bacterial abundance in 2012. Nitrogen application did not influence diazotroph abundance in the top 0–5 cm; however the abundance was reduced by application at the lower 5–10 cm depth under wheat crop. The diazotroph community structure appeared to be influenced more by N fertilization rather than plant species with the exception of wheat in 2012. Changes in the community structure over the two years were greater for fertilized than unfertilized soil. Collectively, these data suggest that year-to-year variability had a greater influence on diazotroph communities rather than specific parameters of plant species, fertilization, total N, total organic C, or soil pH. Multi-year studies are necessary to define the specific drivers of diazotroph abundance, community structure and function.     

Phosphorus ameliorates crop productivity,photosynthetic efficiency,nitrogen-fixation,activities of the enzymes and content of nutraceuticals of Lablab purpureus L.

Hyacinth bean (Lablab purpureus L.) serves as a good source of vegetable proteins in human diet. Its seeds and pods contain as much as 20–28% protein. Besides, it contains tyrosinase enzyme, which has potential use in the treatment of hypertension. Phosphorus deficiency causes a serious yield and quality constraint of beans at Aligarh, Western Uttar Pradesh, India. To address the problem, a pot experiment was conducted to study the effect of basal phosphorus application on the agricultural performance of this medicinal legume. The plants were grown in pots containing soil supplied with five levels of phosphorus viz. 0, 25, 50, 75 and 100 mg P kg⁻¹ soil as potassium dihydrogen orthophosphate (KH₂PO₄). The growth and other physiological attributes, leaf nutrient contents, nodule-nitrogen and leghemoglobin content were studied at 60, 90 and 120 days after sowing (DAS), photosynthesis and other related parameters were measured at 90 DAS and yield and quality attributes were recorded at harvest (150 DAS). Nitrate reductase and carbonic anhydrate activities, leaf-N, -P, -K and -Ca contents and nodule-nitrogen and leghemoglobin contents reached the maximum extent at 60 DAS. At 90 and 120 DAS, the values decreased significantly. Chlorophyll content, carotenoids content, and photosynthesis were at maximum level at 90 DAS. At various growth stages, phosphorus application at 75 mg P kg⁻¹ soil resulted in maximum amelioration of most of the parameters studied. It increased the seed-yield by 38.3%, seed-protein content by 14.9% and seed-carbohydrate content by 5.0%, relative to the control. It was concluded that there was a hidden hunger of hyacinth bean for phosphorus owing to soil-phosphorus deficiency that was ameliorated effectively by its basal dressing at 75 mg P kg⁻¹ soil.     

Interactions between the salt marsh grass Spartina patens, arbuscular mycorrhizal fungi and sediment bacteria during the growing season

The interaction between the salt marsh plant Spartina patens, arbuscular mycorrhizal fungi (AMF) and bacteria in salt marsh sediment was examined in a long-term arbuscular mycorrhizas (AM) suppression study by applying the systemic fungicide benomyl to field-collected sediment cores with and without S. patens plants. Microbial populations were sampled four times corresponding to major plant phenological stages (dormancy, vegetative growth, reproduction, and senescence) previously linked to changes in microbial populations under field conditions. Benomyl-treatment of soil cores significantly suppressed AM colonization on S. patens, keeping values relatively consistent throughout the growing season (11.5%) whereas plants in non-treated cores experienced seasonal increases and declines in AM colonization (26.6% during vegetative growth to 11.5% during dormancy). Soil physicochemical parameters were not affected by benomyl application. In unvegetated cores, no benomyl- or seasonal effects were displayed by cell numbers and specific biomass of DAPI-stained organisms, members of the domain bacteria and here especially members of the α-, β-, γ- and δ-subdivisions of proteobacteria that were the most abundant bacterial groups. In vegetated cores, the microbial community as well as specific bacterial populations were at least twice as large in terms of number and biomass than in samples from unvegetated cores with significant seasonal changes for DAPI-stained cells, for members of the domain bacteria and for members of the α- and γ-subdivisions of proteobacteria. In benomyl-treated cores, the population of γ-subdivision of proteobacteria was significantly smaller than in non-treated cores, and a positive association was found between this bacterial group and root length colonized by AM suggesting that AM-suppression can affect populations of specific soil bacterial populations in salt marsh sediment. Benomyl-treatment had no effect on the diversity of N-fixing bacteria as evidenced by PCR-RFLP analysis, but seasonal changes were noted in vegetated cores with populations during active plant growth substantially different from populations during dormancy and senescence.     

Effect of nitrogen on the yield response of Pennisetum americanum,Triticum aestivum and Zea mays to inoculation with Azospirillum brasilense under temperate conditions

Summary A nitrate-respiring strain, a denitrifying strain, and a non-nitrogen-fixing strain of Azospirillum brasilense were compared for their effect on the growth of pearl millet (Pennisetum americanum), wheat (Triticum aestivum) and maize (Zea mays) under temperate conditions in nitrogen-limited pot cultures. Increases in yield of Z. mays shoots occurred with all three strains when inoculation coincided with the addition of low levels of combined nitrogen. The inoculation of A. brasilense did not show any effect on the yield of P. americanum and T. aestivum. Increased numbers of A. brasilense became associated with Z. mays roots following the addition of low levels of combined nitrogen. Low and very variable rates of acetylene reduction activity were observed from excised roots of inoculated Z. mays plants without preincubation. Results indicate that inoculation of cereals with A. brasilense under temperate conditions has only a limited effect on plant growth.     

禾本科草坪草固氮菌株筛选及部分特性初步研究

从西安和兰州两地多年生禾本科草坪草根际分离到固氮菌株302株,通过气相色谱仪,利用乙炔还原法最终筛选出10个固氮酶活性较高的菌株。研究发现,菌株X4固氮酶活性最高,达180.20 nmolC2H4/h.m l,与其他菌株相比差异极显著(P<0.01),L9最小为37.78 nmol C2H4/h.m l。比较西安和兰州两地多年生草地的固氮酶活性,西安地区不同草地的差异较大,最高者是最低者的4.5倍左右。单从固氮酶活性来看,西安地区草地有开发潜力的优良菌株相对较多,如X4和X1,而兰州地区的相对较少。分离到的固氮菌70%都有溶磷能力,溶磷圈直径比(D/d)在1.044~2.729之间,其中L7菌株溶解有机磷和无机磷能力相对较好,X1和L5溶解无机磷的能力相对较好,X4和X2溶解有机磷较好。菌株大部分都有分泌生长素能力,但差异较大,分泌IAA浓度最高的是X2,达22.3mg/L,其次为X3菌株。     

Triacontanol stimulates nitrogen-fixation,enzyme activities,photosynthesis, crop productivity and quality of hyacinth bean (Lablab purpureus L.)

Hyacinth bean (Lablab purpureus L.) serves as a good source of vegetable proteins in human diet, and its seeds and pods contain as much as 20–28% protein. The bean contains tyrosinase enzyme, which has potential use for the treatment of hypertension. However, plant biological yield appears to be comparatively low in Aligarh soil in this region of India (Western Uttar Pradesh). A hypothesis was designed to address whether foliar application of triacontanol (TRIA) could enhance the crop productivity as well as crop quality. TRIA is known to be a potent plant growth promoting substance for many agricultural and horticultural crops. The hyacinth bean plants grown in soil containing pots, were sprayed with five concentrations of TRIA (10⁻⁰ (Control), 10⁻⁸, 10⁻⁷, 10⁻⁶ and 10⁻⁵ M) at 15-day intervals. The plant fresh and dry weights, leaf-area, number and dry weight of nodules per plant, total chlorophyll and carotenoid content, nitrate reductase activity, carbonic anhydrase activity, nodule-nitrogen content, leghemoglobin content and leaf N, P, K and Ca contents were analyzed at 60, 90 and 120 days after sowing (DAS). Net photosynthetic rate, transpiration rate and stomatal conductance were measured only at 90 DAS. The protein content plus carbohydrate and tyrosinase activity were analyzed in the seeds. Foliar spray of 10⁻⁶ M TRIA significantly stimulated most of the studied attributes. At the highest concentration (10⁻⁵ M TRIA), values of all attributes were significantly decreased at all three stages. For example, 10⁻⁶ M TRIA increased seed-yield and -protein content by 56.3 and 14.5%, respectively when compared to unsprayed plants. TRIA also stimulated the activity of tyrosinase when compared to the control plants.     

Short-term effects of forest restoration management on non-symbiotic nitrogen-fixation in western Montana

Forest restoration treatments involving selection harvest and prescribed fire have been applied throughout the Rocky Mountain West with only a limited understanding of how these treatments influence plant community composition and soil processes. Forest restoration treatments, especially those involving fire, have the potential to reduce N capital on site. Unfortunately there has been only limited effort to investigate the effects of forest restoration treatments on forest ecosystem N inputs, especially free living N-fixation in soil and woody residues. Recent studies have highlighted the potential for decaying woody roots to serve as hot spots for N-fixation. The fire and fire surrogates (FFS) study site at Lubrecht Experimental Forest in Western Montana provided a unique opportunity to investigate the effect of restoration treatments on N-fixation. We set out to examine how prescribed fire, selection harvest, and a combination of both influence free living N-fixing bacteria that colonize decomposing woody roots, mineral soil, and soil crusts. Soil, root, and soil crust samples were collected from replicated treatment plots in August 2005 and soil samples were recollected in May 2006 just following snowmelt. Acetylene reduction assays were run on all samples, and extractable inorganic N and potentially mineralizable N (PMN) were measured in mineral soil. While restoration treatments caused an increase in dead roots associated with stumps and fire killed trees, N-fixation rates were nearly non-existent in these root systems. Nitrogen-fixation rates were not significantly influenced by treatments in decomposing woody roots or in mineral soil, but were slightly greater (P < 0.10) in soil crusts when the control stand was compared to treated plots. Nitrogen-fixation rates were also greater in mineral soil than in roots. Soil collected in August exhibited greater rates of N-fixation than soil collected in May which we attributed to higher moisture and an increase in available N following spring thaw. Average rates of free living N-fixation across the treatment plots at Lubrecht were low (0.26 kg N ha⁻¹ year⁻¹), but over time we estimate that these sources, along with the sparse population of symbiotic N-fixing plants and wet N deposition, would replenish soil N lost through fire or harvesting in approximately 40–100 years.