鼠李糖脂的表面化学和生物合成及其在垃圾堆肥中的应用展望

鼠李糖脂是生物表面活性剂中一类非常重要而应用广泛的微生物发酵产物,在环境污染修复中需求量越来越多。针对近十年来国内外对鼠李糖脂生物表面活性剂的研究,较系统地总结了其化学结构、性质、生物合成机理及产量调节方法,及大规模生产鼠李糖脂的基础研究工作,并对其在城市生活垃圾堆肥中的应用做了展望。     

微生物合成鼠李糖脂的高产优化策略研究进展

鼠李糖脂是当前研究和应用最热门的生物表面活性剂之一,广泛应用于石油开采、环境修复、农业等领域.与化学表面活性剂相比,鼠李糖脂较低的合成产量导致其生产成本相对较高,限制了鼠李糖脂的大规模推广应用.因此,开展鼠李糖脂的高产优化调控研究,对于推动鼠李糖脂的研究与应用具有重要意义.本文简要介绍了鼠李糖脂的生物合成与影响因素;重...     

表面活性剂对绿色木霉产纤维素酶影响

利用绿色木霉,以稻草为唯一碳源,采用液态发酵的方法,分别加入生物表面活性剂鼠李糖脂和化学表面活性剂Tween 80,重点研究了生物表面活性剂对绿色木霉产纤维素酶的影响。实验分析了加入不同浓度的表面活性剂时滤纸酶活、羧甲基纤维素酶活、微晶纤维素酶活及酶液的表面张力随时间的变化情况。结果表明,添加鼠李糖脂能够促进绿色木霉产酶,分别使滤纸酶活、羧甲基纤维素酶活、微晶纤维素酶活最大提高了1.08倍,1.6倍和1.03倍。与Tween 80相比,鼠李糖脂促进产酶的效果明显优于Tween 80。     

响应曲面法优化铜绿假单胞菌DN1的产鼠李糖脂条件

鼠李糖脂是近年来具有广阔应用前景的生物表面活性剂之一,因应用范围广和环境友好等特点,使其成为潜在的合成表面活性剂的替代品。本研究以一株能产生鼠李糖脂的铜绿假单胞菌(Pseudomonas aeruginosa)DN1为研究对象,采用Plackett-Burman设计和响应曲面方法(RSM)对其产鼠李糖脂的发酵条件进行优化。Plackett-Burman试验设计表明,磷酸盐、C/N比和p H值对鼠李糖脂的产量具有显著影响。在此基础上,采用RSM对3个显著因素的最佳水平范围进行研究,结果表明当磷酸盐为1.71 g/L、C/N比为15.5、p H值为6.5时,其理论最佳鼠李糖脂产量为40.4 g/L,与实测鼠李糖脂产量39.84 g/L非常接近。摇瓶优化后的鼠李糖脂产量较优化前的22.9 g/L提高了73.97%。     

鼠李糖脂粗提物对植物病原真菌的抑菌作用

生物表面活性剂对植物真菌病害的防控效应受到广泛关注.鼠李糖脂是由铜绿假单胞菌合成的一种阴离子生物表面活性剂,作为植物病原真菌抑制剂的开发潜力较大,但目前对其抑菌谱和抑菌能力还缺乏全面的评价.本研究收集了 29种常见的植物病原真菌,依据真菌Ainsworth系统分类法评价不同分类地位的病原真菌对鼠李糖脂抑制作用的敏感性....     

一株铜绿假单胞菌及其产生的鼠李糖脂特性研究

研究高效代谢表面活性剂的菌种,并对菌种和表面活性剂的理化性质进行分析。采用菌种16S rDNA序列分析对菌种进行鉴定,采用紫外光谱扫描、色谱柱层析、薄层层析、单糖分析对生物表面活性剂的种类进行鉴定,并对表面活性剂的理化性质进行研究。从油田采出水中筛选出一株高效代谢生物表面活性剂的菌株T-1,经16S rDNA鉴定为铜绿假单胞菌属(Pseudomonas aeruginosa)。该菌种以甘油和大豆油为碳源的培养基培养4 d后,其发酵液表面张力30.216 mN/m,EI24为100%。根据表面活性剂的红外光谱分析并结合薄层分析,可确定T-1样品中含有糖脂类物质,进一步的表面活性剂的单糖分析显示水解终产物为单一的鼠李糖,最终确定其产物为鼠李糖脂,苯酚-硫酸法测定其鼠李糖脂产率为5.2 g/L,从发酵液提取的棕黄色生物表面活性剂粗品,其表观临界胶束浓度为45 mg/L,该鼠李糖脂对环境(耐温、耐酸碱、耐盐)具有较强的适应性。该表面活性剂对恶劣环境具有较强的耐受性,可应用于微生物采油等用途。     

铜绿假单胞菌中鼠李糖脂生物合成的研究进展*

鼠李糖脂因其具有环境友好和卓越的物理化学特性,而有望成为化学合成表面活性剂的替代物。近年来鼠李糖脂得到了广泛的研究,其目的是利用低价的可再生资源进行大规模生产,但目前的研究成果仍不足以选育出更具商业竞争力的鼠李糖脂过量合成菌株。为此,进一步理解鼠李糖脂生物合成的复杂基因调控网络,探索降低生产成本的发酵工艺势在必行。综述了铜绿假单胞菌中鼠李糖脂的生物合成途径、群体感应对主要基因的调控、鼠李糖脂在生物膜形成中所发挥的作用,以及发酵优化对鼠李糖脂产量的影响。有助于加深对鼠李糖脂生物合成的认识,为提高鼠李糖脂产量提供重要参考信息。     

基因工程微生物合成鼠李糖脂表面活性剂的研究进展

鼠李糖脂是一类重要的生物表面活性剂。相比于化学合成的表面活性剂,其具有更优秀的理化性质及环境友好等特点,被广泛应用于微生物采油、环境污染修复等工程中。目前,鼠李糖脂的工业生产主要采用铜绿假单胞菌这一具有致病性的天然合成菌株,与此同时,受菌株遗传背景的限制,优化发酵过程等方法在产量提升方面遇到了一些瓶颈问题。利用基因工程方法对菌株进行改良有望进一步提高鼠李糖脂生产的安全性、产量、产物性能等多项指标,因此受到了越来越广泛的关注。本文综述了近年来利用基因工程方法优化鼠李糖脂生物合成的最新进展,讨论了异源合成、代谢通路改造、基因表达优化、蛋白质工程、底盘工程等多种策略的应用,并展望了一系列可行的研究方向。     

铜绿假单胞菌中鼠李糖脂生物合成的研究进展*

鼠李糖脂因其具有环境友好和卓越的物理化学特性,而有望成为化学合成表面活性剂的替代物。近年来鼠李糖脂得到了广泛的研究,其目的是利用低价的可再生资源进行大规模生产,但目前的研究成果仍不足以选育出更具商业竞争力的鼠李糖脂过量合成菌株。为此,进一步理解鼠李糖脂生物合成的复杂基因调控网络,探索降低生产成本的发酵工艺势在必行。综述了铜绿假单胞菌中鼠李糖脂的生物合成途径、群体感应对主要基因的调控、鼠李糖脂在生物膜形成中所发挥的作用,以及发酵优化对鼠李糖脂产量的影响。有助于加深对鼠李糖脂生物合成的认识,为提高鼠李糖脂产量提供重要参考信息。     

生物表面活性剂对多环芳烃增溶及脱附作用

用生物表面活性剂鼠李糖脂可以较好地脱附土壤及水溶液中的多环芳烃,以有利于多环芳烃的进一步生物降解或化学降解。研究了鼠李糖脂对多环芳烃增溶及脱附的各种最佳条件。     

Process integration possibilities for biodiesel production from palm oil using ethanol obtained from lignocellulosic residues of oil palm industry

In this paper, integration possibilities for production of biodiesel and bioethanol using a single source of biomass as a feedstock (oil palm) were explored through process simulation. The oil extracted from Fresh Fruit Bunches was considered as the feedstock for biodiesel production. An extractive reaction process is proposed for transesterification reaction using in situ produced ethanol, which is obtained from two types of lignocellulosic residues of palm industry (Empty Fruit Bunches and Palm Press Fiber). Several ways of integration were analyzed. The integration of material flows between ethanol and biodiesel production lines allowed a reduction in unit energy costs down to 3.4%, whereas the material and energy integration leaded to 39.8% decrease of those costs. The proposed integrated configuration is an important option when the technology for ethanol production from biomass reaches such a degree of maturity that its production costs be comparable with those of grain or cane ethanol.     

Rhamnolipid surfactants: an update on the general aspects of these remarkable biomolecules

Pseudomonas strains are able to biosynthesize rhamnose-containing surfactants also known as rhamnolipids. These surface-active compounds are reviewed with respect to chemical structure, properties, biosynthesis, and physiological role, focusing on their production and the use of low-cost substrates such as wastes from food industries as alternative carbon sources. The use of inexpensive raw materials such as agroindustrial wastes is an attractive strategy to reduce the production costs associated with biosurfactant production and, at same time, contribute to the reduction of environmental impact generated by the discard of residues, and the treatment costs. Carbohydrate-rich substrates generated low rhamnolipid levels, whereas oils and lipid-rich wastes have shown excellent potential as alternative carbon sources.     

Abatement cost of wood‐based energy products at the production level on afforested and reforested lands

We combined economic and life‐cycle analyses in an integrated framework to ascertain greenhouse gas (GHG) intensities, production costs, and abatement costs of GHG emissions for ethanol and electricity derived from three woody feedstocks (logging residues only, pulpwood only, and pulpwood and logging residues combined) across two forest management choices (intensive and nonintensive) and 31 harvest ages (year 10–year 40 in steps of 1 year) on reforested and afforested lands at the production level for slash pine (Pinus elliottii) in the Southern United States. We assumed that wood chips and wood pellets will be used to produce ethanol and generate electricity, respectively. Production costs and GHG intensities of ethanol and electricity were lowest for logging residues at the optimal rotation age for both forest management choices. Opportunity cost related with the change in rotation age was a significant determinant of the variability in the overall production cost. GHG intensity of feedstocks obtained from afforested land was lower than reforested land. Relative savings in GHG emissions were higher for ethanol than electricity. Abatement cost of GHG emissions for ethanol was lower than electricity, especially when feedstocks were obtained from a plantation whose rotation age was close to the optimal rotation age. A carbon tax of at least $25 and $38 Mg^?1 CO₂e will be needed to promote production of ethanol from wood chips and electricity from wood pellets in the US, respectively.     

Inulinase production in a batch bioreactor using agroindustrial residues as the substrate: experimental data and modeling

The production of inulinase employing agroindustrial residues as the substrate is a good alternative to reduce production costs and to minimize the environmental impact of disposing these residues in the environment. This study focused on the use of a phenomenological model and an artificial neural network (ANN) to simulate the inulinase production during the batch cultivation of the yeast Kluyveromyces marxianus NRRL Y-7571, employing a medium containing agroindustrial residues such as molasses, corn steep liquor and yeast extract. It was concluded that due to the complexity of the medium composition it was rather difficult to use a phenomenological model with sufficient accuracy. For this reason, an alternative and more cost-effective methodology based on ANN was adopted. The predictive capacity of the ANN was superior to that of the phenomenological model, indicating that the neural network approach could be used as an alternative in the predictive modeling of complex batch cultivations.     

Projections of the availability and cost of residues from agriculture and forestry

By‐products of agricultural and forestry processes, known as residues, may act as a primary source of renewable energy. Studies assessing the availability of this resource offer little insight on the drivers and constraints of the available potential as well as the associated costs and how these may vary across scenarios. This study projects long‐term global supply curves of the available potential using consistent scenarios of agriculture and forestry production, livestock production and fuel use from the spatially explicit integrated assessment model IMAGE. In the projections, residue production is related to agricultural and forestry production and intensification, and the limiting effect of ecological and alternative uses of residues are accounted for. Depending on the scenario, theoretical potential is projected to increase from approximately 120 EJ yr^?1 today to 140–170 EJ yr^?1 by 2100, coming mostly from agricultural production. To maintain ecological functions approximately 40% is required to remain in the field, and a further 20–30% is diverted towards alternative uses. Of the remaining potential (approximately 50 EJ yr^?1 in 2100), more than 90% is available at costs <10By‐products of agricultural and forestry processes, known as residues, may act as a primary source of renewable energy. Studies assessing the availability of this resource offer little insight on the drivers and constraints of the available potential as well as the associated costs and how these may vary across scenarios. This study projects long‐term global supply curves of the available potential using consistent scenarios of agriculture and forestry production, livestock production and fuel use from the spatially explicit integrated assessment model IMAGE. In the projections, residue production is related to agricultural and forestry production and intensification, and the limiting effect of ecological and alternative uses of residues are accounted for. Depending on the scenario, theoretical potential is projected to increase from approximately 120 EJ yr^?1 today to 140–170 EJ yr^?1 by 2100, coming mostly from agricultural production. To maintain ecological functions approximately 40% is required to remain in the field, and a further 20–30% is diverted towards alternative uses. Of the remaining potential (approximately 50 EJ yr^?1 in 2100), more than 90% is available at costs <10$₂₀₀₅ GJ^?1. Crop yield improvements increase residue productivity, albeit at a lower rate. The consequent decrease in agricultural land results in a lower requirement of residues for erosion control. The theoretical potential is most sensitive to baseline projections of agriculture and forestry demand; however, this does not necessarily affect the available potential which is relatively constant across scenarios. The most important limiting factors are the alternative uses. Asia and North America account for two‐thirds of the available potential due to the production of crops with high residue yields and socioeconomic conditions which limit alternative uses.     

Potential synergies and challenges in refining cellulosic biomass to fuels,chemicals, and power

Lignocellulosic biomass such as agricultural and forestry residues and dedicated crops provides a low-cost and uniquely sustainable resource for production of many organic fuels and chemicals that can reduce greenhouse gas emissions, enhance energy security, improve the economy, dispose of problematic solid wastes, and improve air quality. A technoeconomic analysis of biologically processing lignocellulosics to ethanol is adapted to project the cost of making sugar intermediates for producing a range of such products, and sugar costs are predicted to drop with plant size as a result of economies of scale that outweigh increased biomass transport costs for facilities processing less than about 10,000 dry tons per day. Criteria are then reviewed for identifying promising chemicals in addition to fuel ethanol to make from these low cost cellulosic sugars. It is found that the large market for ethanol makes it possible to achieve economies of scale that reduce sugar costs, and coproducing chemicals promises greater profit margins or lower production costs for a given return on investment. Additionally, power can be sold at low prices without a significant impact on the selling price of sugars. However, manufacture of multiple products introduces additional technical, marketing, risk, scale-up, and other challenges that must be considered in refining of lignocellulosics.     

Biogas as a resource-efficient vehicle fuel

There are currently strong incentives for increased use of renewable fuels in the transport sector worldwide. However, some bioethanol and biodiesel production routes have limitations with regard to resource efficiency and reduction of greenhouse gases. More efficient biofuel systems are those based on lignocelluloses and novel conversion technologies. A complementary strategy to these is to increase the production of biogas from the digestion of organic residues and energy crops, or from byproducts of ethanol and biodiesel production. Compared with other biomass-based vehicle fuels available so far, biogas often has several advantages from an environmental and resource-efficiency perspective. This provides the motivation for further technological development aiming to reduce costs and thereby increased economic competitiveness of biogas as a vehicle fuel.     

Transformation of vegetable waste into value added products: (A) the upgrading concept; (B) practical implementations

Waste can contain many reusable substances of high value. Depending on there being an adequate technology this residual matter can be converted into commercial products either as raw material for secondary processes, as operating supplies or as ingredients of new products. Numerous valuable substances in food production are suitable for separation and recycling at the end of their life cycle, even though present separation and recycling processes are not absolutely cost efficient. In Part A a need statement is visualised--based on a holistic concept of food production--for the vegetable industry, recording occurrence, quantities and utilisation of the residual products. A literature survey, covering more than 160 articles from all over the world, plus our own investigations summarises the latest knowledge in the above-mentioned field and outline prospects for future economic treatment of vegetable 'co-products'. The main goal of a clean production process is demonstrated by three practical implementations in Part B: 1. Upgrading of vegetable residues for the production of novel types of products: multifunctional food ingredients in fruit juice and bakery goods. 2. Bioconversion via solid-state fermentation: vegetable residues as an exclusive substrate for the generation of fruity food flavours. 3. Conversion of vegetable residues into operating supplies: bioadsorbents for waste water treatment. The investigations are promising with regard to future application in the mentioned industrial branch. The outlined concept can be naturally transferred to several areas of industrial food production. The intentions of this research area are located at the development of techniques, which fulfil the conditions of environmental protection with costs to a minimum. The prospect of several new niche markets is worthwhile indeed.     

Economic Analysis of the Potential of Cellulosic Biomass Available in France from Agricultural Residue and Energy Crops

The objective of this research is to evaluate the feasibility and locations of using cellulosic biomass both from crop residues and from dedicated energy crops to supply 200-million-liter-biodiesel plants in France. The estimation of the potential amount of agricultural residue available in 2015 in each region of France is calculated. The residues considered in this study come from cereal straw and corn stover. Results show that eight out of the twenty one French regions have enough agricultural residues available to supply at least one 200 million liter biofuel plant. Region Centre has the largest potential, with enough residues to supply three to five plants. Finally, cost of supplying one biodiesel plant of 200 million liters in the region Centre is estimated. Results show that collection of biomass will be effective in an area with a radius of 58 Km to 168 Km depending of the raw material considered and its abundance. The cost of supplying a plant with miscanthus is much higher than with residues only. Thus, crop residues appear to offer a lower cost to produce biodiesel in the near term compared to a dedicated crop. Results show that production of biofuel from cellulosic biomass should not be limited by the supply of raw material, but costs of conversion to liquid fuels clearly will play a key role in the development of cellulosic biofuels. Energy prices and policies will have a significant impact on second generation biofuel development.     

鸡球虫重组疫苗的研究进展

球虫病是由艾美耳球虫引起的一种对家禽危害极为严重的全球性寄生虫病,目前仍以药物防治为主。由于球虫抗药株的不断出现、研制新药的费用昂贵和药物残留的日趋严重,使得球虫疫苗研究成为近年的热点。采用ＤＮＡ重组技术获得的重组疫苗逐渐受到人们的重视,发展很快。综述近年来家禽球虫重组疫苗的研究情况,探讨重组疫苗的利用前景、存在问题和解决途径。