混播比例对三江源人工草地植被和土壤养分特征的影响

建植混播人工草地是修复三江源黑土滩退化草地的有效措施，但不同混播比例下植被和土壤养分特征的变化尚不明确。以垂穗披碱草、中华羊茅和青海草地早熟禾分别按1∶1∶1（M₄），2∶1∶1（M₅），1∶2∶1（M₆），1∶1∶2（M₇），2∶2∶1（M₈），2∶1∶2（M₉）和1∶2∶2（M₁₀）建植混播人工草地，并以各组分单播为对照，研究生产力、物种多样性、超产效应、多样性净效应（包括互补效应和选择效应）和土壤养分特征的变化，并采用多准则决策模型-TOPSIS进行综合评价，以筛选最佳混播比例，以期为三江源退化草地生态修复提供科学依据。结果表明：混播处理地上生物量显著高于中华羊茅和青海草地早熟禾单播的生物量，但显著低于垂穗披碱草单播处理，混播处理地上生物量在M₅、M₈、M₉和M₁₀处理较高。而地下生物量在混播处理间无显著差异。混播处理中，仅M₅、M₈、M₉和M₁₀处理存在超产，达40.4~71.1 g·m^-2。M₄和M₆处理的多样性净效应均小于0，说明由于物种竞争导致群落减产。而M₇~M₁₀混播处理的多样性净效应均大于0，说明物种生态位的互补使得群落高产。M₈和M₉处理中互补效应和选择效应共同主导了超产效应，而M₅和M₁₀处理中主要由互补作用主导超产效应。表层土壤的有机质、全氮、全磷、速效磷和速效钾含量在M₆、M₇和M₁₀混播处理中较高。TOPSIS模型综合评价表明，M₁₀混播处理不但可保持较高的生产力，还可显著提高土壤的养分含量，是三江源区人工草地建植的理想混播比例。     

浙江遂昌毛竹鞭笋丰产培育技术

为了发挥毛竹林生产潜力，增加竹农经济收入，在多年实践研究的基础上总结出一套毛竹鞭笋丰产培育技术。研究认为：在毛竹笋材两用林中采挖鞭笋，不会影响整体的竹鞭鞭径和竹鞭总量生长；毛竹林地覆盖稻草和砻糠能显著提高第3年的鞭笋产量；培育高产鞭笋的最佳施肥时间为每年的5月；鞭笋采收时间为5-10月。毛竹鞭笋丰产培育技术可在毛竹笋材两用林经营中推广应用。     

油草混播种类对油菜生产和草地生产性能的影响

为筛选与门源油菜混播效益最高的牧草种类,解决油菜连作障碍问题,提高青藏高原高海拔区土地的生产能力,本研究采用油菜混播箭筈豌豆、青稞和燕麦的方式,分时段取样,探究了油菜混播不同牧草对在不同时段牧草自身生产能力的影响,并通过土地当量比判断各混播组合的优劣。研究表明油菜-燕麦混播处理在7月6日时表现干重最高,单位面积达174.48 g；在7月21日表现为鲜重和鲜干比最高,在8月15日时表现为株高显著高于单作油菜(p＜0.05),较单作油菜高97.02%；鲜重最高,达2817.00 g。在9月11日,油菜-青稞和油菜-燕麦混播处理的株高显著高于单作油菜(p＜0.05),分别较单作油菜高64.33%和99.68%,以油菜-青稞混播处理的干重最高,达589.00 g,较单作油菜处理高147.51%。油菜-箭筈豌豆混播和油菜-燕麦混播有产量优势,油菜-燕麦混播的土地当量比最高,为1.11,土地利用效果最好。     

糜子愈伤诱导及再分化最适条件研究

研究旨在应用组织培养技术探究愈伤诱导及再分化的最适条件,以期为糜子建立遗传转化体系奠定基础。采用5种不同类型的糜子品种研究愈伤诱导及再分化的最适条件。利用植物激素2,4-二氯苯氧乙酸(2,4-D)诱导茎尖愈伤组织,筛选出发芽率高,愈伤组织诱导率高,染菌率低的品种,并对诱导愈伤最适激素浓度及配比进行了鉴定。结果显示,冀黍2号出芽率高、愈伤组织诱导率高、染菌率低,适宜进行组织培养；2,4-D对冀黍2号愈伤诱导效果最好,最适浓度为2.5mg/L,诱导率达86.67%,淡黄色块状,结构紧密,质地较硬,继代培养后形成的胚性愈伤组织状态更好。再分化过程中,2,4-D浓度为2.5mg/L+TDZ浓度为3.5mg/L时出现明显的嫩芽。该试验获得冀黍2号愈伤诱导及再分化的最适条件,可为糜子再生体系的构建提供参考。     

Effects of dietary lipid-to-carbohydrate ratio on growth and carbohydrate metabolism in juvenile cobia (Rachycentron canadum)

This experiment was conducted to investigate the effects of dietary lipid-to-carbohydrate ratio on growth and carbohydrate metabolism in juvenile cobia (Rachycentron canadum). Six isonitrogenous diets were prepared to vary in lipid-to-carbohydrate ratio (g/g) as follows: D1, 2.26; D2, 1.31; D3, 0.78; D4, 0.47; D5, 0.34; and D6, 0.23. Cobias were fed to satiety for 8 weeks. The weight gain and protein efficiency ratio in D1 group were significantly lower than those in other groups (P < 0.05), accompanied by a lower level of feed conversion ratio (P < 0.05). Protein retention efficiency in D4 and D6 and whole body protein in D4 and D5 were significantly higher than those in D1 group (P < 0.05). Survival rate in D4 group was the highest among all groups and was significantly higher than that in D1, D2 and D5 (P < 0.05). In terms of serum triglyceride, D1 and D2 were significantly higher than D6 (P < 0.05). Hepatosomatic index in D3 and D4 was significantly lower than that in D1 (P < 0.05). Fructose-1,6-diphosphatase in D4 was significantly higher than that in D1 and D3 (P < 0.05). Phosphofructokinase in D3 and D4 and malic enzyme in D4 and D5 were significantly higher than those in other groups (P < 0.05). Results indicate that cobia utilizes carbohydrates as energy source more efficiently than it utilizes lipids. The optimal lipid-to-carbohydrate ratio in juvenile cobia diets is 0.47.     

羊肚菌营养袋制作原料的化学成分分析及配方优化

为优化羊肚菌营养袋的原料组成与配比,以食药用菌栽培基质中常用的4种秸秆及谷壳、麦粒、麦麸,通过主成分分析归纳各原料的营养组成属性,设计出9个营养袋配方进行栽培试验,比较出菇产量,得出高产营养袋原料组合为谷壳和麦粒;再以谷壳与麦粒按11种不同的重量比混合制成营养袋进行栽培试验,综合考量制作成本、出菇产量、经济效益等因素后,最终得到高产高效的羊肚菌营养袋配方(重量比)为谷壳19%、麦粒79%、石灰1%、石膏1%。     

Maize/peanut intercropping increases photosynthetic characteristics, ~(13)C-photosynthate distribution,and grain yield of summer maize

Intercropping is used widely by smallholder farmers in developing countries to increase land productivity and profitability. We conducted a maize/peanut intercropping experiment in the 2015 and 2016 growing seasons in Shandong, China. Treatments included sole maize(SM), sole peanut(SP), and an intercrop consisting of four rows of maize and six rows of peanut(IM and IP). The results showed that the intercropping system had yield advantages based on the land equivalent ratio(LER) values of 1.15 and 1.16 in the two years, respectively. Averaged over the two years, the yield of maize in the intercropping was increased by 61.05% compared to that in SM, while the pod yield of peanut was decreased by 31.80% compared to SP. Maize was the superior competitor when intercropped with peanut, and its productivity dominated the yield of the intercropping system in our study. The increased yield was due to a higher kernel number per ear(KNE). Intercropping increased the light transmission ratio(LTR) of the ear layer in the maize canopy, the active photosynthetic duration(APD), and the harvest index(HI) compared to SM. In addition, intercropping promoted the ratio of dry matter accumulation after silking and the distribution of ~(13) C-photosynthates to grain compared to SM. In conclusion, maize/peanut intercropping demonstrated the potential to improve the light condition of maize, achieving enhanced photosynthetic characteristics that improved female spike differentiation, reduced barrenness, and increased KNE. Moreover, dry matter accumulation and ~(13) C-photosynthates distribution to grain of intercropped maize were improved, and a higher grain yield was ultimately obtained.     

黄麻土工布覆盖对花岗岩红壤表土坡面侵蚀特性的影响

[目的]探究黄麻土工布覆盖条件下花岗岩红壤表土坡面侵蚀特性,为花岗岩红壤区坡面土壤侵蚀防治提供科学依据。[方法]通过室内模拟降雨试验,在2个坡度(5°和15°坡度)、3种密度(无覆盖,6 cm×6 cm及3 cm×3 cm网格)的黄麻土工布覆盖条件下,研究极端降雨条件下(90 mm/h)花岗岩红壤表土的坡面侵蚀特性,并观测径流系数、土壤侵蚀速率、泥沙颗粒变化规律及富集率等指标。[结果]坡面径流随降雨历时增加而增加,土壤侵蚀速率则相反,表明侵蚀过程是一个分离受限的过程。和对照组相比,黄麻土工布覆盖在不同试验条件下都具有明显的减流减沙作用。另外,由侵蚀泥沙的粒径分选规律可知,坡面土壤中的黏粒和粉粒大小的颗粒倾向于被优先选择性搬运,其结果致使坡面石英粗颗粒富集,在缓坡(5°)与高密度黄麻土工布覆盖条件下(3 cm×3 cm网格)尤为突出。坡面石英粗颗粒随降雨历时增加不断富集进一步增加了原位坡面的侵蚀抗性,产生了土壤侵蚀速率随降雨历时不断降低的现象。[结论]高密度黄麻土工布的覆盖能够有效地减流减沙,增加原位坡面抗蚀性,是一种有效的水土保持措施,在今后的土壤侵蚀防治和劣地恢复工作中应该被重视。     

Karanj protein isolate prepared from karanj seed cake: Effect on growth,body composition and physiometabolic responses in Labeo rohita fingerlings

A protein isolate was prepared from karanj seed (KPI) with 921.2 g protein/kg seed, which contained a negligible amount of anti‐nutritional factors and a balanced amino acid composition, especially rich in methionine. For 60‐day feeding trial, five isonitrogenous (300 g/kg CP) and isocaloric (15 MJ DE/kg) diets were formulated by replacing soybean protein isolate (SPI) on protein equivalent basis, KPI‐0 (control, 0 g/kg KPI); KPI‐25 (replacing 250 g/kg SPI protein with KPI); KPI‐50 (replacing 500 g/kg SPI protein with KPI); KPI‐75 (replacing 750 g/kg SPI protein with KPI) and KPI‐100 (replacing 1,000 g/kg SPI protein with KPI) for the feeding of L. rohita. The weight gain percentage, specific growth rate, feed conversion ratio and protein efficiency ratio were not significantly (p > .05) varied among the KPI fed and control groups. A significantly higher hepatosomatic index was recorded in the control and KPI‐25 groups compared with other groups. The whole‐body compositions, except ether extract, did not differ significantly (p > .05) among the groups. Digestive (amylase, protease, lipase and alkaline phosphatase) and metabolic enzyme activities (hexokinase, transaminases and lactate dehydrogenase) and glycogen stores were not significantly affected, whereas intestinal alkaline phosphatase differed significantly (p < .05). The RNA–DNA ratio was significantly (p < .05) higher in the KPI‐75 group. Thus, the study revealed that KPI can completely replace SPI protein at 191 g/kg inclusion level in the diets of L. rohita fingerlings.     

Biochar addition mitigates nitrogen loss induced by straw incorporation and nitrogen fertilizer application

Biochar has been shown to be potentially beneficial for enhancing yields and soil properties, and diminishing nitrogen (N) losses. However, it remains unclear how biochar regulates soil carbon (C) and N to mitigate N losses induced by straw mixing with N fertilizer in dryland soils. Therefore, we investigated the effects of straw mixing (S₁), S₁ with biochar (SB) and no straw inputs (S₀), and routine urea application rates (N₁) and 70% of routine rates (N_0.7) on yields and N losses, and identify the relationship between N losses and soil C and N compounds. Results showed that N_0.7 and N₁ were suitable for the maize and wheat seasons, respectively, contributing to mitigating N losses without reducing crop yields. Moreover, in the maize season, N_0.7-SB significantly mitigated the straw-induced NH₃-N and N₂O-N emissions by 106% and 81%, respectively. In the wheat season, N₁-SB reduced the straw-induced NH₃-N and N₂O-N emissions by 35% and 66%, respectively. In addition, N_0.7-SB sharply reduced soil inorganic N (SIN) storage in the maize season. Furthermore, the NH₃-N and N₂O-N emission rates were negatively correlated with dissolved organic carbon/SIN content (0–20 cm) (DOC/SIN_0-20). N losses (N₂O-N and NH₃-N emissions and SIN storage) were positively correlated with SIN_0-20, but negatively correlated with soil organic carbon / SIN_0-20 (SOC/ SIN_0-20). This study provides further evidence that biochar with an appropriate N application rate decreased SIN_0-20 and increased DOC/SIN_0-20, thus reducing SIN storage and the straw-induced gaseous N emissions without decreasing crop yields.