江汉平原棉花合理施氮量研究

采用田间小区试验研究了江汉平原棉花合理施氮量。结果表明,在施用90 kg/hm~2 P2O5、180 kg/hm~2K2O和3 kg/hm~2持力硼基础上,利用线性+平台模型得到棉花中高产量水平下的合理施氮量为280 kg/hm~2。在不明显减产的条件下,从提高氮肥当季利用率、尽量降低氮肥投入的角度,可以将氮肥用量降低到240kg/hm~2左右,在此施氮水平下仍然可能通过改进田间管理措施获得高产。因此,江汉平原棉花氮肥减量空间为20~60 kg/hm~2。     

甜菜氮肥的合理施用

综述文献关于氮肥对甜菜的生长、吸收分配规律、生理生化及产质量的影响可知,甜菜生长需要多种营养元素,其中氮素尤为重要,不合理施用氮肥对甜菜的产质量带来很多负面影响;造成资源浪费、环境污染,影响人类健康。提出合理施氮、用氮的途径与策略:第一,因地、因品种、因时制宜,根据测土资料及不同甜菜基因型差异确定施肥种类、配比;根据作物不同生长时期的需肥规律及不同生态条件需要,按需供肥。第二,肥要在水的作用下才能发挥作用、才能更好发挥作用,区域配肥技术与灌溉技术相结合的水肥一体化精准精细灌水施肥技术是甜菜生产高效用肥的必然发展趋势。第三,作物不同养分间具有协同和相互影响作用,因此根据同等重要原则应有机配比。第四,为了提高肥效及利用率,施用缓控释肥,有机无机肥配施,施用微生物肥、生态肥等发挥微生物的促进、协同作用。第五,常规育种与转基因技术结合培育氮素养分高效利用品种。第六,利用现代监测技术手段及应用甜菜生长模型尤其是CERES-Beet模型监测氮等养分的转化、吸收等动态。     

奶山羊CIDEa基因的克隆、序列分析与组织表达

为获得奶山羊CIDEa基因序列并检测其在乳腺组织中的表达,采用RT-PCR技术从奶山羊乳腺组织扩增CIDEa基因序列,利用生物信息学软件对其进行预测分析,并采用荧光定量PCR检测CIDEa在干奶期和不同泌乳时期乳腺组织中的表达。结果表明:通过克隆测序得到奶山羊CIDEa基因CDS区660 bp,编码219个氨基酸,与GenBank公布的绵羊、牛、人和猪的核苷酸序列同源性分别为99%、96%、85%、85%。奶山羊CIDEa蛋白属于碱性、不稳定亲水蛋白,不存在跨膜结构和信号肽;蛋白主要定位在细胞质、线粒体和细胞核。CIDEa蛋白结构主要由α螺旋、β折叠和不规则卷曲组成。奶山羊CIDEa在泌乳前期、盛期和中期乳腺组织中表达量均显著高于干奶期(P<0.05)。说明CIDEa可能参与奶山羊乳腺的泌乳过程,为进一步研究其在奶山羊乳腺组织中的功能及对乳品质的调控作用奠定基础。     

Effect of the particle size on the ammonia removal rate and the bacterial community composition of bioflocs

The total ammonia nitrogen (TAN) removal efficiency and bacterial community composition of bioflocs with <50-μm particle size, > 50-μm particle size and un-sieved bioflocs were investigated in the current study. The initial ratio of dissolved organic carbon to TAN (DOC/TAN) in the three groups were about 14:1. No significant difference was found in the removal rate of TAN, average concentrations of TAN and nitrite nitrogen among the three groups (P > 0.05). The C/N (w/w) ratio of the > 50-μm bioflocs was significantly higher than those of the other groups. No significant differences were found in the crude protein content in the bioflocs among the three groups. The development of the bacterial community compositions of the bioflocs was analyzed by Illumina MiSeq sequencing analyses. Most OTUs were shared among the three groups at all the sampled time points. With the increase in the relative abundance of phylum Firmicutes, that of phylum Proteobacteria, Chorolexi, and Bacteroidetes decreased in all the three groups. The phylum Firmicutes and genus Bacillus were predominant in all the sampled time points. At the end of the experiment, genus Bacillus accounted for 81% in the < 50-μm group, 82% in the > 50-μm group, and 75% in the un-sieved group.     

Dynamic change of mineral nutrient content in different plant organs during the grain filling stage in maize grown under contrasting nitrogen supply

The introduction of new hybrids and integrated crop-soil management has been causing maize grain yield to increase. However, less attention has been paid on the nutrient concentration of the grain; this aspect is of great importance to supplying calories and nutrients in the diets of both humans and animals worldwide. Increasing the retranslocation of nutrients from vegetative organs to grain can effectively increase the nutrient concentration of grain and general nutrient use efficiency. The present study involved monitoring the dynamic change of macro- and micronutrients in different organs of maize during the grain filling stage. In addition, the mobility of different elements and their contribution to grain nutrient content were evaluated in a 2-year experiment under low (LN, no N supplied) and high N (HN, 180 kg N ha⁻¹) supply. Under HN supply, the net remobilization efficiency (RE) of the vegetative organs as a whole (calculated as nutrient remobilization amount divided by nutrient content at silking) of N, P, K, Mn, and Zn were 44%, 60%, 13%, 15%, and 25%, respectively. The other nutrients (Mg, Ca, Fe, Cu, and B) showed a net accumulation in the vegetative organs as a whole during the grain filling stage. Among the different organs, N, P, and Zn were remobilized more from the leaves (RE of 44%, 51% and 43%, respectively) and the stalks (including leaf sheaths and tassels) (RE of 48%, 71% and 43%, respectively). K was mainly remobilized from the leaves with RE of 51%. Mg, Ca, Fe, Mn, and Cu were mostly remobilized from the stalks with the RE of 23%, 9%, 10%, 42%, and 28%, respectively. However, most of the remobilized Mg, Ca, Fe, Mn, Cu, and Zn were translocated to the husk and cob, which seemingly served as the buffer sink for these nutrients. The REs of all the nutrients except for P, K, and Zn were vulnerable to variations in conditions annually and were reduced when the grain yield and harvest index were lower in 2014 compared with 2013. Under LN stress, the RE was reduced in P and Zn in 2013, increased in Cu and unchanged in other nutrients. The concentration of these nutrients in the grain was either unchanged (P, K, Ca, Zn, and B) or decreased (N, Mg, Fe, Mn, and Cu). It is concluded that grain N, P, K, Mn, and Zn, but not Mg, Ca, Fe, Cu, and B concentration, can be improved by increasing their remobilization from vegetative organs. However, enhancing the senescence of maize plant via LN stress seems unable to increase grain mineral nutrient concentration. Genetic improvement aiming to increase nutrient remobilization should take into account the organ-specific remobilization pattern of the target nutrient.     

供氮方式对冬马铃薯氮肥利用效率及氮素去向的影响

以马铃薯费乌瑞它为试材,采用田间微区~(15)N示踪技术,研究施N量160kg·hm~(-2)全部基施(T1)、55%基施+45%在齐苗期追施(T2)、55%基施+30%在齐苗期追施+15%在现蕾期追施(T3)3种方式,对冬马铃薯氮肥利用效率及去向的影响。结果表明:马铃薯吸收的N约46%~52%来源于当季施用的氮肥,48%~54%来自土壤和种薯;肥料N利用率为35.16%~39.99%,残留率为47.71%~51.78%,损失率为8.23%~15.50%。3种施氮方式下,肥料N主要残留在0~15cm土层。随施氮时间后移,肥料N残留在0~15cm土层呈上升趋势,在15~45cm土层呈下降趋势。施氮方式对马铃薯干物质积累总量和块茎干物质积累量影响不明显,但T3肥料N利用率、肥料N残留率明显大于T1、T2。因此,综合经济效益和环境效益,T3施氮方式的效果较为理想。本研究为马铃薯氮素养分的有效管理提供了指导依据。     

建兰‘岭南奇蝶’种子无菌萌发与离体繁殖技术

以建兰‘岭南奇蝶’种子为外植体,开展兰花的离体繁殖技术研究。结果表明,用0.1%Hg Cl2处理25~30 min能达到较好的灭菌效果,污染率低至7.5%;添加0.5~3.0 mg·L~(-1)NAA及0.5~1.5 mg·L~(-1)IBA有利于‘岭南奇蝶’根状茎增殖生长,增殖倍数达5.25;根状茎的最适分化培养基为1/2 MS+3.0 mg·L~(-1)6-BA,分化率达63.6%;有机添加物香蕉和土豆对‘岭南奇蝶’的壮苗生根有明显的促进作用,苗高度及平均根数与对照组相比均显著增加,生根率均达100%。     

八仙花组织培养繁殖技术

以八仙花的茎段、茎尖、叶片为外植体,在MS培养基中加入不同质量分数的6-苄基腺嘌呤（6-BA）和吲哚丁酸（IBA）进行增殖培养.结果表明：适宜八仙花外植体表面灭菌的方法是利用0.1%氯化汞（HgC l2）灭菌7 m in;不同类型的八仙花外植体在初代培养时的增殖效果不同,茎尖在培养过程中首先伸长生长,然后陆续长出侧芽,表明八仙花的茎尖是比较适合用来进行增殖培养的外植体;继代培养以MS＋6-BA 1.0 mg.L-1＋IBA0.12 mg.L-1为较适宜的增殖培养基;侧芽在1/2 MS＋IBA 0.2 mg.L-1培养基中生根率和单苗根数量均较高,说明1/2 MS＋IBA 0.2 mg.L-1为较好的不定根诱导培养基.