大西洋鲑性腺分化及热休克的影响

大西洋鲑性腺分化发生在孵出45－63天，约495－693度日。经热休克处理获得三倍体稚鱼，性腺在分化之前明显大于正常二倍体。雌性三倍体稚鱼性腺在细胞学分化时受抑，初级卵母细胞不能发育；雄性三倍体稚鱼性腺在细胞学分化阶段生长明显减慢，初级精母细胞尚能发育。     

亚洲淡水养鱼学术讨论会论文摘要选登——光周期和温度对鲤科鱼类排卵的影响

<正> 为研究在产卵季节(5—6月)光周期和温度对鲤鱼排卵的影响,我们对此进行了一系列的试验。使用成熟雌鱼作试验对象并确定试验期间排卵的时间和卵母细胞的成熟度(采用卵母细胞透明剂和组织学观察)。当温度从14—16℃提高到18—24℃时,在整个试验中都处于自然光线下的那组鱼在所有试验中都能排卵。当处于14—16℃自然     

促性腺激素诱发大西洋鲑卵黄发生期卵巢滤泡释放性类固醇激素的离体研究

提要应用大麻哈鱼(Oncovhynchus keta)促性腺激素(GTH)诱发大西洋鲑(Salmosalar)卵黄发生期的离体卵巢滤泡(直径为3．4毫米)产生性类固醇激素的研究表明，不论用0．1或1微克／毫升GTH刺激，经培育10天后，未出现卵母细胞卵核消失的现象，卵核偏位也不明显。对培养液中17α，20β-双羟孕酮(17α20βP)的积累浓度测定结果，仅1微克／毫升GTH组含少量的17α20βP；0．1微克／毫升GTH组，培养液中雌二醇的积累浓度明显高于对照组和1微克／毫升GTH组，并为后者的两倍。除雌二醇外，孕酮，17α-羟孕酮，17α20βP，雄烯二酮和睾酮的产生，都呈现对GTH剂量的依赖关系，1微克／毫升GTH组的产生量明显高于0．1微克／毫升GTH组和对照组。离体研究的结果表明，处于卵黄发生期的卵巢滤泡对低剂量(0．1微克／毫升)和高剂量(1微克／毫升)GTH的反应不同。低浓度的GTH，引起性类固醇激素生物合成的途径沿着形成雌二醇的方向进行，雄激素被芳香化成雌激素，雌二醇再而刺激肝脏合成卵黄物质的前体，从而促进卵黄发生。高浓度的GTH，有抑制雌二醇合成的作用，而是促使卵母细胞向着最终成熟的方向发展，使性类固醇生物合成的途径转向形成大量雄激素和孕激素，特别是17α20βP。这与已充分生长和卵黄积累完成的卵巢滤泡离体试验的结果一致，与活体观察以上各种性类固醇激素的变化一致。     

在美国爱荷华州叶面杀真菌剂对侵染Phomopsis spp．大豆的影响

2008--2009年在爱荷华州的2个地点,在大豆[Glycinemax（L．）]R3、R5和R3＋R5期进行了杀真菌剂唑菌胺酯（嗜球果伞素）和戊唑醇（苯三唑）施用试验研究,评价了大豆田间茎和种子被Phomopsis spp．侵染的发病率、产量和种子品质。结果表明,2008--2009年在R3＋R5时期和2008年在R5时期施用唑菌胺酯后,大豆茎Phomopsis spp．发病率降低,较对照未施药剂茎Phomopsis spp．发病率大约降低三分之二。     

Experiences with Rice Grown on Permanent Raised Beds: Effect of Crop Establishment Techniques on Water Use,Productivity, Profitability and Soil Physical Properties

In recent years, conventional rice production technologies have been leading to deterioration of soil health and declining farm profitability due to high inputs of water and labor. Conservation agriculture(CA) based resource-conserving technologies i.e. zero-tillage(ZT), raised-bed planting and direct-seeded rice(DSR) have shown promise as alternatives to conventional production technologies to overcome these problems. Present study was undertaken during 2009–2012 to establish an understanding of how permanent raised bed cropping system could be practiced to save water at the field application level to improve water productivity and also have the capability to enhance productivity, profitability and soil physical quality. The results showed that among different crop establishment techniques, conventional-tilled puddle transplanted rice(CT-TPR) required 14%-25% more water than other techniques. Compared with the CT-TPR system, zero till direct-seeded rice(ZT-DSR) consumed 6%–10% less water with almost equal system productivity and demonstrated higher water productivity. Wide raised beds saved about 15%–24% water and grain yield decrease of about 8%. Direct-seeded rice after ZT or reduced tillage or on unpuddled soil provided more net income than CT-TPR. The CTTPR system had higher bulk density and penetration resistance due to compaction caused by the repeated wet tillage in rice. The steady-state infiltration rate and soil aggregation( 0.25 mm) were higher under permanent beds and ZT and lower in the CT-TPR system. Under CT-TPR, soil aggregation was static across seasons, whereas it improved under no-till and permanent beds. Similarly, mean weight diameter of aggregates was higher under ZT and permanent beds and increased over time. The study reveals that to sustain the rice productivity, CA-based planting techniques can be more viable options. However, the long-term effects of these alternative technologies need to be studied under varying agro-ecologies in western Uttar Pradesh, India.     

Biosurfactant-assisted phytoremediation of potentially toxic elements in soil: Green technology for meeting the United Nations Sustainable Development Goals

Biosurfactants are biomolecules produced by microorganisms, low in toxicity, biodegradable, and relatively easy to synthesize using renewable waste substrates. Biosurfactants are of great importance with a wide and versatile range of applications, including the bioremediation of contaminated sites. Plants may accumulate soil potentially toxic elements(PTEs), and the accumulation efficacy may be further enhanced by the biosurfactants produced by rhizospheric microorganisms. Occasionally, the growth of bacteria slows down in adverse conditions, such as highly contaminated soils with PTEs. In this context,the plant's phytoextraction capacity could be improved by the addition of metal-tolerant bacteria that produce biosurfactants. Several sources, categories,and bioavailability of PTEs in soil are reported in this article, with the focus on the cost-effective and sustainable soil remediation technologies, where biosurfactants are used as a remediation method. How rhizobacterial biosurfactants can improve PTE recovery capabilities of plants is discussed, and the molecular mechanisms in bacterial genomes that support the production of important biosurfactants are listed. The status and cost of commercial biosurfactant production in the international market are also presented.     

Rhizosphere microbiomes can regulate plant drought tolerance

Beneficial root-associated rhizospheric microbes play a key role in maintaining host plant growth and can potentially allow drought-resilient crop production. The complex interaction of root-associated microbes mainly depends on soil type, plant genotype, and soil moisture. However, drought is the most devastating environmental stress that strongly reduces soil biota and can restrict plant growth and yield. In this review, we discussed our mechanistic understanding of drought and microbial response traits. Additionally, we highlighted the role of beneficial microbes and plant-derived metabolites in alleviating drought stress and improving crop growth. We proposed that future research might focus on evaluating the dynamics of root-beneficial microbes under field drought conditions. The integrative use of ecology, microbial, and molecular approaches may serve as a promising strategy to produce more drought-resilient and sustainable crops.     

Reduced tillage with residue retention improves soil labile carbon pools and carbon lability and management indices in a seven-year trial with wheat-mung bean-rice rotation

Soil total organic carbon (TOC) is a composite indicator of soil quality with implications for crop production and the regulation of soil ecosystem services. Research reports on the dynamics of TOC as a consequence of soil management practices in subtropical climatic conditions, where microbial carbon (C) loss is high, are very limited. The objective of our study was to evaluate the impact of seven years of continuous tillage and residue management on soil TOC dynamics (quantitative and qualitative) with respect to lability and stratification under an annual wheat-mung bean-rice cropping sequence. Composite soil samples were collected at 0-15 and 15-30 cm depths from a three-replicate split-plot experiment with tillage treatment as the main plots and crop residue levels as the sub-plots. The tillage treatments included conventional tillage (CT) and strip tillage (ST). Residue levels were high residue level (HR), 30% of the plant height, and low residue level (LR), 15%. In addition to TOC, soil samples were analyzed for particulate organic C (POC), permanganate oxidizable C (POXC), basal respiration (BR), specific maintenance respiration rate (qCO₂), microbial biomass C (MBC), potentially mineralizable C (PMC), and TOC lability and management indices. The ST treatment significantly increased the TOC and labile C pools at both depths compared with the CT treatment, with the effect being more pronounced in the surface layer. The HR treatment increased TOC and labile C pools compared with the LR treatment. The ST + HR treatment showed significant increases in MBC, metabolic quotient (qR), C pool index (CPI), C lability index (CL_I), and C management index (CMI), indicating improved and efficient soil biological activities in such systems compared with the CT treatment. Similarly, the stratification values, a measure of soil quality improvement, for POC and MBC were > 2, indicating improved soil quality in the ST + HR treatment compared with the CT treatment. The ST + HR treatment not only significantly increased the contents of TOC pools, but also their stocks. The CMI was correlated with qCO₂, BR, and MBC, suggesting that these are sensitive indicators of early changes in TOC. The qCO₂ was significantly higher in the CT + LR treatment and negatively correlated with MBC and CMI, indicating a biologically stressed soil condition in this treatment. Our findings highlight that medium-term reduced tillage with HR management has profound consequences on soil TOC quality and dynamics as mediated by alterations in labile C pools.     

Effect of indaziflam on microbial activity and nitrogen cycling processes in an orchard soil

Indaziflam is a preemergent herbicide widely used for the control of weeds in pecan (Carya illinoinensis) orchards in the southwestern region of the United States. Given the paucity of data regarding the effect of indaziflam on the biochemical properties of soils supporting pecan production, this study was conducted to evaluate the effects of different application rates of indaziflam on soil microbial activity, diversity, and biochemical processes related to nitrogen (N) cycling. During two consecutive growing seasons (2015 and 2016), soil samples were obtained from experimental mesocosms consisting of soil-filled pots where pecan saplings were grown and treated with indaziflam applied at two different rates (25 and 50 g active ingredient (ai) ha^-1, with the higher rate being slightly lower than the recommended field application rate of 73.1 g ai ha^-1). Soil samples were collected approximately one week before and one week after herbicide application for determination of soil microbial biomass and diversity, N mineralization, and β-glucosaminidase activity. Soil samples collected from the control mesocosms without herbicide application were treated in the laboratory with two rates of indaziflam (75 and 150 g ai ha^-1) to determine the immediate effect on microbial activity. No significant effect of herbicide treatment on soil respiration and microbial biomass was detected. The results showed a slight to moderate decrease in microbial diversity (7% in 2015 and 44% in 2016). However, decreased β-glucosaminidase activity with herbicide treatment was observed in soils from the mesocosms (33%) and soils treated with indaziflam in the laboratory (45%). The mineral N pool was generally dominated by ammonium after indaziflam application, which was consistent with the drastic decrease (75%) in nitrification activity measured in the laboratory experiment. The results of this study indicate that indaziflam, even when applied at higher than recommended rates, has limited effects on soil microbial activity, but may affect N cycling processes.