不同种植方式下温度升高对水稻产量及同化物转运的影响

【目的】气候变暖对水稻生产系统的影响备受关注,研究不同种植方式下,水稻产量及其形成对气候变化的响应规律,为水稻种植区划、栽培措施和品种调整提供依据。【方法】 2017—2018年以南粳9108和南粳46为供试品种,模拟机插秧移栽和机械化直播2种种植方式,以常温（NT）为对照,于始穗期进行中度升温（平均增加2℃,MT）和极端高温胁迫（平均增加5℃,HT）,研究不同种植方式下温度升高对不同水稻品种的产量及其构成、同化物转运、光合生产特性的影响。【结果】在中度升温和极端高温胁迫下,南粳9108和南粳46产量降幅均为移栽<直播,长生育期品种南粳46产量降幅较小。穗干物重增长速率表现为NT>MT>HT,水稻茎叶向穗的干物质转运量、转运率均随着温度升高而递减,且南粳9108下降趋势大于南粳46。穗后21 d至成熟期,剑叶SPAD值总体随着温度的升高而增加,差异达极显著水平;剑叶净光合速率穗后14—21 d均以极端高温胁迫处理下最小,而到穗后35 d以极端高温胁迫处理下最大。剑叶气孔导度、蒸腾速率均呈NT>MT>HT趋势,生育后期差异更显著。通径分析表明,产量各构成因子对产量的影响程度为结实率>千粒重>穗数>每穗粒数,温度处理对产量各构成因子的影响都表现为负效应,且以结实率影响最大（-0.819）。相关分析表明,不同种植方式下受中度升温、极端高温胁迫后,成熟期干物质总重量、茎叶干物质转运量与产量构成因子（穗数除外）,一、二次枝梗籽粒结实率都呈极显著正相关。【结论】始穗期2—5℃升温均显著降低粳稻结实率,从而导致水稻产量降低。从光合物质特性究其原因是由于温度升高降低了干物质向穗的转运率和穗干物质积累速率,从而导致生育后期水稻剑叶SPAD值增加,延长叶片持绿时间,抑制“源”向“库”转移。从气候变暖应对措施来看,选择采用移栽种植方式和长生育期品种易于表现出对极端高温胁迫逆境较好的抗性。     

3种植物对镉污染土壤修复的试验研究

为探究植物修复技术在济源镉(Cd)污染土壤的应用特征和效果,笔者以不同Cd污染程度的实际土壤为对象,采用盆栽试验,对比三叶鬼针草、黑麦和印度芥菜对Cd的耐受、富集、转移能力及修复效率。结果表明:污染组植物的生物量无显著下降,供试植物均具有较强的Cd耐性。3类植物富集特征不同,地上部分富集Cd浓度顺序依次是:三叶鬼针草印度芥菜黑麦。3种植物中黑麦地下部分Cd含量最高,轻、重度污染组的Cd含量分别达到11.95、28.56 mg/L。三叶鬼针草对Cd具有较强的转移能力,其中在轻度污染土壤中转移系数(TF=2.23)最大。此外,三叶鬼针草修复效率最高,轻、重度污染组分别为2.04%、1.59%。综上所述,三叶鬼针草的生物量、富集转运系数和修复效率均高于黑麦和印度芥菜。因此,三叶鬼针草可作为济源Cd污染土壤修复植物之一,为当地土壤Cd污染治理提供理论参考和技术依据。     

普通小麦大赖草易位系T3AS·3AL-7Lr#1S的分子细胞遗传学鉴定

大赖草对赤霉病具有较好的抗性,将大赖草赤霉病抗性基因转入普通小麦,对拓宽小麦赤霉病抗性基础有重要意义。本研究在获得抗赤霉病普通小麦-大赖草异附加系基础上,采用1 200 R ⁶⁰Co-γ射线处理小麦-大赖草二体附加系DA7Lr花粉,授予已去雄的普通小麦中国春,对其后代(M₁)种子根尖细胞有丝分裂中期染色体进行GISH分析,获得了1株具有1条普通小麦-大赖草易位染色体的植株,让其自交,对自交后代中具有2条易位染色体植株的花粉母细胞减数分裂中期Ⅰ进行观察,发现2条易位染色体形成了稳定的环状二价体,表明该植株为纯合体。利用顺序GISH-双色FISH分析,结合C-分带、小麦D基因组专化探针Oligo-pAs1-2和B基因组专化探针Oligo-pSc119.2-2,进一步鉴定出该普通小麦-大赖草易位系为T3AS·3AL-7Lr#1S,且筛选出了可追踪该易位系的3个EST-STS分子标记BE591127、BQ168298和BE591737。该易位系的育成为小麦赤霉病遗传改良提供了新种质。     

Sulfur uptake and translocation in maize (zea mays) grown in a high pH soil treated with elemental sulfur

A glasshouse experiment was conducted to elucidate the influence of elemental sulfur (S) application rates (0, 0.5, 1.0, and 2.0 g S kg^?1 soil) on the release and uptake of S at 0, 20, and 40 days after incubation. Results showed that there was a progressive upward trend in maize leaves, stem, and root S content with application of elemental S. However, maize production followed a nonlinear model. Plants grown in untreated soils suffer from S deficiency and addition of elemental S at a rate of 0.5 g S kg^?1 soil alleviated S deficiency. The decrease in maize performance due to the highest S application rate was not related to S toxicity. The greatest leave, stem, and root productions were obtained at S concentrations of 0.41, 0.58, and 0.2%, respectively. Overall, application of elemental S at a rate of 0.5 g S kg^?1 soil is recommended for maize performance improvement.     

Dynamics of nitrogen translocation from mature leaves to new shoots and related gene expression during spring shoots development in tea plants (Camellia sinensis L.)

The contribution of N remobilization is crucial for new shoots growth and quality formation during spring tea shoots development. However, the translocation mechanism of N from source leaves to sink young shoots is not well understood. In the present study, ¹⁵N urea was applied to mature tea leaves one week before bud break to track N remobilization in a field experiment. The dynamic changes in plant ¹⁵N abundance, contents of amino acids, and the expression levels of genes related to N metabolism and translocation were followed during the 18‐d development of new spring shoots until three expanding young leaves. The results showed that during the growth of new shoots the amount of ¹⁵N in the shoots increased, whereas the N_dff (N derived from ¹⁵N‐urea) in mature leaves decreased, showing that the foliar‐applied N in mature leaves was readily exported to new shoots. This process was found to be accompanied by decline of chlorophylls. In the mature leaves, expression CsATG18a and CsSAG12 involved in autophagy was dramatically induced (> 4‐fold) at approximately nine days after the bud breaking. The genes involved in the transformation of amino acids, including primarily CsGDH2, CsGDH4, CsGLT3, CsGS1;3, and CsASN2 were upregulated by > 3‐fold after bud breaking. The expression levels of CsATG8A, CsATG9, CsSAG12, CsGS1;1, CsGDH1, and CsAAP6 correlated negatively with the N_dff in mature leaves, but positively with ¹⁵N amount and total N amount in new shoots, suggesting these genes played important roles in N export from mature leaves. In the new shoots, the expression of most genes showed two defined peaks, one on six days and one on 12 days after bud breaking. The expression of CsGS2, CsASN3, CsGLT1, and CsAAP4 positively correlated with the ¹⁵N amount and total N amount in new shoots. These genes might be involved in the transport and re‐assimilation of N from mature leaves. The overall results demonstrated that the translocation of ¹⁵N from mature leaves to new spring shoots was regulated by the genes involved in autophagy, protein degradation, amino acid transformation and transport.     

秸秆覆盖方式和施氮量对河套灌区夏玉米氮利用及产量影响

为探究夏玉米氮素转运利用规律、产量及土壤NO3－-N含量分布对秸秆覆盖方式和施氮量的响应，在河套灌区开展2a不同秸秆覆盖方式（秸秆表覆B处理、秸秆深埋S处理）和不同施氮水平（不施氮N0、低氮N1、中氮N2、高氮N3）的田间试验，以传统耕作模式为对照（CK处理）。结果表明：在0～100 cm土层，各处理NO3－-N含量随施氮量增加而增大，成熟期B和CK处理随土层加深呈先减后增趋势，而S处理呈先增后减趋势；B处理提高0～20 cm土层NO3－-N含量，而S处理提高20～40 cm土层NO3－-N含量（P<0.05）；秸秆覆盖可减少0～100 cm土层NO3－-N累积损失量，且显著提高氮肥利用率及夏玉米氮素转运量对籽粒产量的贡献率，SN2处理效果较佳。相比CK处理，成熟期的SN2处理2 a平均NO3－-N累积损失量降低39.6%，氮肥利用率较提高28.5%，夏玉米氮素转运量对籽粒产量的贡献率提高32.1%，增产9.3%。综合分析，秸秆深埋配施中氮效果较佳，可实现河套灌区夏玉米提效增产的目标，并减少深层土壤NO3－-N累积损失量，为优化河套灌区夏玉米耕作施氮模式和缓解农业面源污染提供参考。     

香根草对污染土壤水溶态重金属组分胁迫响应研究

为探讨香根草对污染土壤中水溶态重金属组分在时间尺度上的胁迫响应,以Pb和Cu复合污染土壤为研究对象,通过种子萌发试验和水培试验,模拟重金属水溶态组分对香根草种子萌发、幼苗生长情况及重金属积累特性的影响。结果表明,Pb和Cu水溶态组分显著降低香根草幼苗的根长、株高、鲜质量和干质量。其中,根长受抑制作用最显著,在第60 d,处理组根长比对照组低43.6%;香根草幼苗的重金属耐性指数(MTI)总体上随生长时间增加呈上升趋势,第60 d的MTI为70.2%;香根草幼苗可显著富集Pb和Cu,且主要累积在根部,其转运系数(TF)低至0.02和0.10,根部最大积累量分别达到763 mg·kg~(-1)和235 mg·kg~(-1),表明香根草属于根部积累性植物。由此可见,香根草幼苗对水溶态重金属组分的耐受能力随其生长时间的增加而逐渐增强,利用香根草进行重金属的植物固定具有较大潜力。     

Stimulation in the movement and uptake of phosphorus in response to magnetic P solution and arbuscular mycorrhizal fungi in Ocimum basilicum

A greenhouse experiment was conducted to assess the effects of magnetic field, arbuscular mycorrhizal fungi (AMF), and phosphorus (P) concentration in the nutrient solution (0, 5, 10, 20, or 40 mg L^?1) on the mobility and accumulation of P in soil and plant tissues of basil (Ocimum basilicum L.). The experiment was designed as a factorial combination and treatments were arranged in a completely randomized design with four replicates. Magnetic field increased water-soluble P in the soil and P concentration in plant shoot by 30.0% and 13.0%, respectively, in comparison to the control. The application of magnetic field and inoculation of AMF at 10 mg P L^?1 increased the P translocation efficiency by 23.3% and 17.8%, respectively. Overall, our results demonstrated that the use of magnetic field and AMF could be an effective tool for enhancing of uptake and movement efficiency of P even at low concentrations.