Does soil aging affect the N2O mitigation potential of biochar? A combined microcosm and field study

The application of biochar as a soil amendment to improve soil fertility has been suggested as a tool to reduce soil‐borne CO₂ and non‐CO₂ greenhouse gas emissions, especially nitrous oxide (N₂O). Both laboratory and field trials have demonstrated N₂O emission reduction by biochar amendment, but the long‐term effect (>1 year) has been questioned. Here, we present results of a combined microcosm and field study using a powdered beech wood biochar from slow pyrolysis. The field experiment showed that both CO₂ and N₂O emissions were still effectively reduced by biochar in the third year after application. However, biochar did not influence the biomass yield of sunflower for biogas production (Helianthus annuus L.). Biochar reduced bulk density and increased soil aeration and thus reduced the water‐filled pore space (WFPS) in the field, but was also able to suppress N₂O emission in the microcosms experiment conducted at constant WFPS. For both experiments, biochar had limited impact on soil mineral nitrogen speciation, but it reduced the accumulation of nitrite in the microcosms. Extraction of soil DNA and quantification of functional marker genes by quantitative polymerase chain reaction showed that biochar did not alter the abundance of nitrogen‐transforming bacteria and archaea in both field and microcosm experiments. In contradiction to previous experiments, this study demonstrates the long‐term N₂O emission suppression potential of a wood biochar and thus highlights its overall climate change mitigation potential. While a detailed understanding of the underlying mechanisms requires further research, we provide evidence for a range of biochar‐induced changes to the soil environment and their change with time that might explain the often observed N₂O emission suppression.     

向日葵种质资源的随机扩增多态性ＤＮＡ（ＲＡＰＤ）研究

采用ＲＡＰＤ方法对我国２１个向日葵（Helianthus annuus L.)基因型和１１个国外引进向日葵因型进行分析,构建了它们的方图谱。从８０个随机引物中筛选出的２５个有效引物共产生１８８条ＤＮＡ片段,大小分布在０．２６－１．９８kb之间,其中１６４例带具有遗传多态性,约占总数的８７．２％,平均每个引物扩增的ＤＮＡ带数为７．５２条。３２个向日葵的遗传相似性分析表明,各基因型间的Ｎei氏相似性系数分布在０．３９８７．０８５３１之间,平均相似性系数为０．６２８１。１１个国外向日葵基因型的Ｎei氏相似性系数分布在０．７１３４－０．８５３１之间,平均相似性系数为０．７８２８,说明国外基因型之间的遗传基础比较狭窄。２１个国内向日葵基因型的Ｎei氏相似性系数分布在０．４７５０－０．８２０６,平均相似性系数为０．６４７８,说明国内向日葵基因型之间的遗传多态性较为丰富。通过非加权算术平均数聚类（ＵＰＧＭＡ）的方法,给制了３２个向日葵基因型之间的遗传关系树图。３２个向日葵基因明显地聚成Ａ、Ｂ两大类群。２１个国内向日葵基因型聚成了Ａ１、Ａ２两个亚类,Ａ１组包括：Ｘ１０、陕西向日葵、Ｄ－Ｓ１２、长岭向日葵６、黑２－Ｓ２－２、Ｔ－Ｃ０８、长岭葵花４、白葵３号、ＢＨ－１０、Ｊ－Ｓ－Ｂ１、张掖白子葵、Ｃ１０１－Ｓ４－３Ｓ４等１２个基因型;Ａ２组包括：ＬＫ３０５－Ｓ８、ＬＫ、ＣＳ－７、长岭葵花Ｓ２－Ｓ２、辉南７－Ｓ１－３、辉南、ＣＹ－ＸＸ１９－ＸＸ２、吉葵１１２、吉葵１１６等９个基因型。１１个国外向日葵基因型划分为Ｂ１、Ｂ２两个亚类,Ｂ１组包括ＬＧ１２０２８Ｑ、ＬＧ９０２３Ｒ、ＣＲＮ１４３、ＳＦ９９０３、ＳＦ９９０２、Ｓ－３３２２、ＳＨ３３２、ＳＨ４１、ＳＦＰ９００１、ＣＲＮ１４４５等１０个法国基因型;Ｂ２组织有来自美国的Ｇ１０１一个材料。     

Effect of heat treatments on stability of altemariol, alternariol monomethyl ether and tenuazonic acid in sunflower flour

A study was carried out to evaluate the effect of heat treatment on the stability of alternariol (AOH), alternariol monomethyl ether (AME) and tenuazonic acid (TeA) in sunflower flour and the effectiveness of this treatment by a biological assay in rats. The concentrations of AOH and AME remained constant during heating at 100°C for up to 90 minutes while TeA concentration decreased with time to 50% after 90 minutes. The most effective treatment in reducing AOH and AME levels was heating at 121°C for 60 minutes. Histopathological evaluation in the biological assay in rats fed withAlternaria toxins showed marked atrophy and fusion of villi in the intestines and liver cell damage; these lesions were less severe in rats fed heat-treated sunflower flour in line with the reduced toxin content. However, a lower weight gain and a noticeable renal damage in rats were produced when they fed decontaminated flour.     

向日葵对苯胺废水的光合生理响应及净化效果

为探讨向日葵对苯胺废水的耐受性及其应用于苯胺污染废水植物修复的可行性,采用水培试验方法,以美国油葵1号为材料,研究了不同苯胺浓度胁迫对向日葵光合和叶绿素荧光参数的影响,以及向日葵对苯胺的吸收、积累和净化效果。研究发现:100 mg/L的苯胺对向日葵的净光合速率(P_n)、气孔导度(L_s)和蒸腾速率(T_r)有显著的促进作用,而对生长与叶绿素荧光相关参数无显著的影响。当苯胺浓度升高到200—400 mg/L时,向日葵的鲜重、净光合速率(P_n)、实际光化学效率(Φ_(PSⅡ)),最大光化学效率(F_v/F_m)以及光化学淬灭系数(qP)比对照组显著降低,而胞间CO_2浓度(C_i)显著升高,NPQ呈现出先升高后降低的趋势,并在苯胺浓度为200 mg/L时达到最大值。综合分析表明,当苯胺浓度升高到200 mg/L到400 mg/L时,苯胺对向日葵的净光合速率的抑制以非气孔因素为主。当苯胺浓度为500 mg/L时,导致向日葵死亡。另外,向日葵对100 mg/L苯胺废水中苯胺的去除率最高,达到80.97%。苯胺主要在向日葵的地上部分积累,随着苯胺浓度的升高,向日葵中叶片苯胺的浓度逐渐升高,茎中的苯胺含量变化不显著,而根中的苯胺含量较低。     

向日葵rRNA基因克隆及其染色体定位研究

该研究以内葵杂3号三交种为材料,采用同源序列法克隆了5SrRNA和18SrRNA基因并进行了序列测定,测得片段长度分别为515bp和1808bp。以5SrRNA、18SrRNA和45SrRNA基因为探针,分别与内葵杂3号三交种染色体进行荧光原位杂交（FISH）分析。结果表明：45SrRNA和18SrRNA基因均得到3对杂交信号且位点分布相同,分别位于第3对和第10对染色体及第2对随体染色体的短臂末端;5SrRNA基因的信号位点共有2对,分布在第7对和第10对染色体短臂端部。     

内蒙古巴彦淖尔地区向日葵螟的种群动态与生活史

为了制定科学、有效的向日葵螟Homoeosoma nebulellum Denis et Schiffermüller（鳞翅目：螟蛾科）测报和防治对策,通过野外调查和室内饲养观察对内蒙古巴彦淖尔地区向日葵螟的发生为害规律及生活史进行了研究。结果表明：当地向日葵螟的寄主有菊科的向日葵Helianthus annuus L.、茼蒿Chrysanthemum coronarium Mill.、刺儿菜Cephalanoplos segetum（Beg.） Kitam和苣荬菜Sonchus brachyotus DC.,其中苣荬菜作为向日葵螟的寄主在我国是首次报道。应用性信息素监测结合田间调查的结果表明,当地向日葵螟一年发生2代,其中越冬幼虫4月下旬开始化蛹,5月中旬开始羽化,但此时羽化的成虫由于缺乏开花寄主而无法产卵为害。第1代幼虫在6月末为害茼蒿、7月下旬开始为害开花的向日葵。第1代幼虫于7月下旬开始羽化产卵形成第2代,其中有9.2%的老熟幼虫直接滞育越冬。第2代幼虫自8月中旬起为害晚开花的向日葵,9月中旬老熟后陆续入土越冬,至10月上旬收获时仍有30.0%的幼虫未老熟而随收获的葵花盘转至筛选出的杂质中越冬。在24℃,RH 70%和L16∶D8光照条件下测定第2代向日葵螟卵、幼虫和蛹的发育历期分别为4.2、15.9和11.1 d,雌、雄蛾寿命分别为14.9 d和15.1 d.综合观察结果,绘制了巴彦淖尔地区向日葵螟的生活史表。     

Short-term effects of boron, germanium and high light intensity on membrane permeability in boron deficient leaves of sunflower

With the ultimate purpose of clarifying the mechanism for aluminium (Al) toxicity and for Al tolerance, we tried to isolate cDNAs whose expression is induced by Al treatment and phosphate (P_i) starvation. We performed P_i starvation and Al treatment (two-step treatment) on suspension-cultured cells of Nicotiana tabacum L. cv. Samsun and then constructed a cDNA library using poly(A)⁺-RNA derived from the treated cells. Four independent cDNA clones (pAL 111, 139, 141 and 142) were isolated from the library by differential screening. Northern blot hybridization analysis indicated that the expression of these clones was induced by P_i starvation. Furthermore, we found that pAL 111 and pAL 142 are also induced by Al treatment. The complete cDNA sequencing of these 4 clones was determined. The results indicated that pAL111 is identical to the parA gene of N. tabacum, which is described as an auxin-regulated gene and that pAL142 is highly homologous to the parB gene of N. tabacum whose product has glutathione S-transferase (GST, EC 2.5.1.18) activity. Furthermore, we found a cysteine-rich domain in the amino acid sequence of pAL139. No DNA and deduced amino acid sequences homologous to the pAL141 were found.     

向日葵螟幼虫的空间分布型及抽样技术

欧洲向日葵螟Homoeosoma nebulellum Denis et Schiffermüller是向日葵上的主要害虫,本文利用6种聚集指标对向日葵螟幼虫的空间分布型进行了测定,结果表明其呈现聚集分布。样本平均数(m)与方差(S2)的对数值的关系式为:lgS2=lg0.2130+0.5639lgm,显示向日葵螟幼虫的空间分布随密度的升高而趋向均匀分布。Iwao的m*-m回归方程为:m*=8.1177+0.1447m,显示该虫在田间分布的基本成分是个体群,个体间相互吸引,个体群的空间分布型为均匀分布。对聚集原因进行分析,得出λ<2,表明向日葵螟幼虫的聚集是由于环境作用所引起的。用Iwao的理论抽样数模型计算出向日葵螟幼虫的理论抽样数模型为:D=0.1时,n=911.77/m-85.53,D=0.2时,n=227.94/m-21.38。采用m*-m关系的序贯抽样模型制定出食葵田间的序贯抽样模型为:T1(n),T0(n)=7.40n±4.54n,油葵田间的序贯抽样模型为:T1(n),T0(n)=10.05n±2.29n。     

Lipid composition of plasma membranes isolated from sunflower seedlings grown under water-stress

Plasma membranes were isolated by aqueous two-phase-partitioning from sunflower ( Helianthus annuus cv. Isabel) seedlings grown both under field irrigation and dryland conditions. Water-stressed plants showed a decrease in the leaf water potential and in the osmotic potential at full turgor, with the turgor pressure remaining at positive values. Dryland conditions also induced a reduction in the bulk modulus of elasticity. Plasma membranes of irrigated plants were characterized by high contents of phospholipids (68% of total lipids), free sterols (15. 7%) and glycolipids (9. 1%), mainly glycosphingolipids and steryl glycosides. Diacylglycerols, triacylglycerols and free fatty acids were also present. The major phospholipids were phosphatidylcholine and phosphatidylethanolamine with smaller amounts of phosphatidylinositol and phosphatidylglycerol. Following water stress, the plasma membranes showed a reduction of about 24 and 31% in total lipids and phospholipids, respectively. Also the amounts of glycolipids and diacylglycerols decreased significantly upon water stress. There was no change in free fatty acids, however, and triacylglycerols and free sterols increased. As a consequence, the free sterol to phospholipid molar ratio increased from 0. 4 to 0. 7 under water deficit conditions. The ratio of phosphatidylcholine to phosphatidylethanolamine increased from 1. 1 (control plants) to 1. 6 (water-stressed plants), while phosphatidic acid rose to 4% of total phospholipids. Dehydration did not result in any substantial change in the unsaturation level of the individual lipid classes, however. The results show that dryland conditions resulted in a marked alteration in the lipid composition of the sunflower leaf plasma membrane     

Effects of timing and supply of nitrogen on nitrogen remobilization from vegetative organs and redistribution to developing seeds of sunflower

A glasshouse study was made of the distribution of ¹⁵N among vegetative organs of sunflower and its later remobilization and redistribution to seeds, as influenced by the developmental stage at which ¹⁵N was provided, and by the N status of the plants. Plants of Hysun 30 sunflower were grown in sand culture and provided with K¹⁵NO₃ for a 3-day period at: (a) 3 days before the end of floret initiation; (b) 3 days before anthesis; (c) the start of anthesis; (d) full anthesis; and (e) 8 days after full anthesis. The plants were grown on a range of N supply rates, from severely deficient to more than adequate for maximum growth. Nitrogen-15 was distributed to all parts of the plant at the end of the ¹⁵N uptake periods. With the exception of the most N-stressed plants, subsequent remobilization of ¹⁵N from roots, stems and leaves occurred irrespective of the time the ¹⁵N was taken up. However, the percentage redistribution to seeds of ¹⁵N taken up at the end of floret initiation was less than for ¹⁵N taken up at anthesis. Remobilization of ¹⁵N from leaves and roots was higher (70%) for ¹⁵N taken up during and after anthesis than for ¹⁵N taken up at the end of floret initiation (45%), except for plants grown on the lowest N supply. By contrast, remobilization of ¹⁵N from the stem was lower for ¹⁵N taken up after full anthesis (40%) than before or during anthesis (>70%). The proportion of ¹⁵N remobilized from the top third of the stem was less than that from the bottom third, and decreased with increasing plant N status. Nitrogen-15 taken up over the 3-day supply periods during anthesis contributed from 2 to 11% of the total seed N at maturity; the contribution to seeds was greatest for plants grown on the highest N supply. Nitrogen taken up just before and during anthesis contributed most of the N accumulated in mature seeds of plants grown on an adequate N supply, but N taken up between the end of floret initiation and just before anthesis, or after full anthesis seemed to make an equally important contribution to mature seeds as N taken up during anthesis for plants grown on a very low N supply. It was concluded that the development of florets and seeds of sunflower is supported by N taken up by the plant between the end of floret initiation and anthesis, and by N redistributed from vegetative organs. Unless soil N is so low as to impair early growth, split applications of N fertilizer would be best made just before the end of floret initiation (‘star stage’) and just before anthesis.