生物淋洗修复钒污染土壤的性能与机理研究

【目的】土壤重金属污染问题日益受到关注,其中钒污染逐渐成为研究热点。淋洗是土壤修复的重要手段,但存在污染大、成本高的缺点。生物淋洗技术因其经济高效且环保的特点能够应用于土壤的修复,但其对钒污染土壤的修复,认识仍非常有限。【方法】本研究采用嗜酸性氧化亚铁硫杆菌对钒污染土壤进行了生物淋洗试验,通过影响因素试验探究了钒的最佳浸出条件,并应用扫描电子显微镜-能量色散X射线谱分析了钒在淋洗过程中的变化,最后对代谢产物进行了解析。【结果】微生物次生代谢产物能促进土壤中钒的溶出。氧化亚铁硫杆菌对土壤钒的浸出效率较高,生物淋洗20 d后土壤中钒的浸出率达到27.4%,进一步的影响因素试验表明,在固体浓度为3%、接种体积为10%、初始pH值为1.8、初始Fe²⁺的浓度为3.0 g/L的条件下,土壤中钒的浸出效果最佳。SEM-EDS分析证实生物淋洗后土壤中钒含量减少,其中以非残渣态形式存在的钒更容易被浸出。代谢组学分析显示氧化亚铁硫杆菌在浸出过程中产生了大量代谢产物来应对重金属胁迫。【结论】生物淋洗技术能够有效地实现土壤钒污染的修复,本研究为钒污染土壤提供了一种环境友好的修复方式。     

Temporal dynamics of soil bacterial network regulate soil resistomes

Soil bacteria are diverse and form complicated ecological networks through various microbial interactions, which play important roles in soil multi-functionality. However, the seasonal effects on the bacterial network, especially the relationship between bacterial network topological features and soil resistomes remains underexplored, which impedes our ability to unveil the mechanisms of the temporal-dynamics of antibiotic resistance genes (ARGs). Here, a field investigation was conducted across four seasons at the watershed scale. We observed significant seasonal variation in bacterial networks, with lower complexity and stability in autumn, and a wider bacterial community niche in summer. Similar to bacterial communities, the co-occurrence networks among ARGs also shift with seasonal change, particularly with respect to the topological features of the node degree, which on average was higher in summer than in the other seasons. Furthermore, the nodes with higher betweenness, stress, degree, and closeness centrality in the bacterial network showed strong relationships with the 10 major classes of ARGs. These findings highlighted the changes in the topological properties of bacterial networks that could further alter antibiotic resistance in soil. Together, our results reveal the temporal dynamics of bacterial ecological networks at the watershed scale, and provide new insights into antibiotic resistance management under environmental changes.     

TaTPP-7A positively feedback regulates grain filling and wheat grain yield through T6P-SnRK1 signalling pathway and sugar–ABA interaction

Grain size and filling are two key determinants of grain thousand-kernel weight (TKW) and crop yield, therefore they have undergone strong selection since cereal was domesticated. Genetic dissection of the two traits will improve yield potential in crops. A quantitative trait locus significantly associated with wheat grain TKW was detected on chromosome 7AS flanked by a simple sequence repeat marker of Wmc17 in Chinese wheat 262 mini-core collection by genome-wide association study. Combined with the bulked segregant RNA-sequencing (BSR-seq) analysis of an F₂ genetic segregation population with extremely different TKW traits, a candidate trehalose-6-phosphate phosphatase gene located at 135.0 Mb (CS V1.0), designated as TaTPP-7A, was identified. This gene was specifically expressed in developing grains and strongly influenced grain filling and size. Overexpression (OE) of TaTPP-7A in wheat enhanced grain TKW and wheat yield greatly. Detailed analysis revealed that OE of TaTPP-7A significantly increased the expression levels of starch synthesis- and senescence-related genes involved in abscisic acid (ABA) and ethylene pathways. Moreover, most of the sucrose metabolism and starch regulation-related genes were potentially regulated by SnRK1. In addition, TaTPP-7A is a crucial domestication- and breeding-targeted gene and it feedback regulates sucrose lysis, flux, and utilization in the grain endosperm mainly through the T6P-SnRK1 pathway and sugar–ABA interaction. Thus, we confirmed the T6P signalling pathway as the central regulatory system for sucrose allocation and source–sink interactions in wheat grains and propose that the trehalose pathway components have great potential to increase yields in cereal crops.     

High-temperature stress in crops: male sterility,yield loss and potential remedy approaches

Global food security is one of the utmost essential challenges in the 21st century in providing enough food for the growing population while coping with the already stressed environment. High temperature (HT) is one of the main factors affecting plant growth, development and reproduction and causes male sterility in plants. In male reproductive tissues, metabolic changes induced by HT involve carbohydrates, lipids, hormones, epigenetics and reactive oxygen species, leading to male sterility and ultimately reducing yield. Understanding the mechanism and genes involved in these pathways during the HT stress response will provide a new path to improve crops by using molecular breeding and biotechnological approaches. Moreover, this review provides insight into male sterility and integrates this with suggested strategies to enhance crop tolerance under HT stress conditions at the reproductive stage.     

Eu3+-activated red phosphor Ca3YAl3B4O15 with low thermal quenching behaviour

This paper reports a sequence of a Ca₃YAl₃B₄O₁₅:xEu³⁺ red phosphor prepared using a high-temperature solid-state reaction. At the excitation of 396 nm, the samples emitted intense red emission centred at ~623 nm, which could be attributed to the ⁵D₀→⁷F₂ transition of the Eu³⁺ ion. The results showed that the optimum Eu³⁺ doping concentration of Ca₃YAl₃B₄O₁₅:Eu³⁺ phosphor was x = 80 mol%, and the concentration quenching mechanism of Ca₃YAl₃B₄O₁₅:Eu³⁺ red phosphor belonged to the exchange coupling between Eu³⁺ ions. The Commission Internationale de l'éclairage (CIE) coordinates and colour purity of Ca₃Y_0.2Al₃B₄O₁₅:0.8Eu³⁺ were calculated as (0.6375, 0.3476) and 95.5%, respectively. Moreover, the red emission of the obtained phosphor Ca₃YAl₃B₄O₁₅:0.8Eu³⁺ exhibited a low thermal quenching behaviour with an intensity retention rate of 92.85% at 150°C. The above results manifest that the Eu³⁺-activated Ca₃YAl₃B₄O₁₅ phosphor is predicted to be a promising red luminescent component for white light-emitting diodes.     

花生种子萌发早期胚轴细胞DNA合成的特点

花生种子吸胀6h后胚轴DNA中有~3H-胸苷掺入。咖啡因和羟基脲均对6～12h的~3H—胸苷掺入具强烈的抑制作用;当12～24h时,咖啡因的抑制作用较大;但30h以后,羟基脲的抑制作用超过咖啡因。双链DNA放射性从种子吸胀9h后迅速上升,单链DNA放射性在吸胀12h后出现一个明显的峰。但在吸胀12h后,单链DNA形成和存在的时间是短暂的。     

烟草耐盐愈伤组织变异体对盐渍的适应性

用组织培养及逐步增加,NaCl浓度的方法,筛选出烟草耐盐愈伤组织变异体。能耐盐(2％ NaCl)的愈伤组织在2％ NaCl中继代29次,再移入无盐培养基中培养11和20代后不能保持提高的耐盐性,分别退化到只耐1.5％与1.0％ NaCl的水平。耐2％ NaCl愈伤组织产生的再生植株自交后代,其萌发种子、幼苗及成长植株均未能表现出耐盐性,说明用选择胁迫方法所筛选出的耐盐细胞系,其耐盐性的提高属于生理适应性。     

NO2胁迫下三角梅叶片形态解剖结构和最优光响应模型研究

植物的形态结构和光合作用能够反映植物对城市空气污染的响应特性。探究城市道路机动车尾气中的典型污染物NO₂气体,对植物叶片的生理光合响应特性。以二年生三角梅（Bougainvillea spectabilis）幼苗为对象,利用智能化人工熏气室模拟熏气（NO₂体积分数分别为0 μL/L （自然空气）、4 μL/L,8 μL/L,记作CK、T1、T2）,观察NO₂胁迫后三角梅的叶片形态、微观结构和光合特征。结果表明：（1）通过叶片形态观察发现,与CK相比,低浓度T1组叶片变化不明显,随着NO₂气体胁迫浓度的增加,高浓度T2组叶片逐渐出现失水、叶表面有明显的水渍状或烧灼状黄色斑点。（2）通过叶片微观结构解剖发现,高浓度NO₂胁迫后气孔皱缩程度增加,气孔开度减小;叶绿体结构变形,尤其是类囊体结构疏松,膨胀等变化。（3）叶片光合特性分析发现,T1和T2组的NO₂胁迫导致光饱和点（LSP）和最大净光合速率（P_nmax）下降、光补偿点（LCP）增加,表观量子效率（AQE）和暗呼吸速率（Rd）在4种光响应模型中变化规律存在一定的差异性。（4）4种光响应模型中,CK组决定系数（R²）越高,均方根误差（RMSE）越低,精度最高,尤以叶子飘等机理模型为最优,拟合效果最好,其次是直角双曲线模型。研究结果表明三角梅可通过自身的形态变化、调整光合特征参数,较好地适应不同浓度的NO₂,尤其是高浓度急性胁迫下,该研究结果有助于促进不同道路绿地三角梅的推广应用,对探究三角梅的景观效益和生态效益,揭示其对环境异质性的适应机制具有重要意义。     

来源于嗜热氢化杆菌的新型对苯二甲酸双(羟乙)酯水解酶的表达纯化与酶学性质

石化来源的聚对苯二甲酸乙二酯(polyethylene terephthalate,PET)被广泛用于矿泉水瓶、食品包装和纺织品等领域,因其在自然界中不易分解,大量使用后的PET废弃物造成了严重的环境污染与资源浪费。使用生物酶法对PET废弃物进行解聚,并对解聚产物进行升级循环利用是进行塑料污染治理的重要方向之一,其中关键的是PET水解酶的解聚效率。对苯二甲酸双(羟乙基)酯(bis(hydroxyethyl)terephthalate,BHET)是PET生物酶解的中间产物,其累积是限制PET水解酶催化效率的一个重要因素,BHET水解酶和PET水解酶的联用能提升PET的整体水解效率。来源于嗜热氢化杆菌(Hydrogenobacter thermophilus)的双烯内酯酶(HtBHETase)对BHET有显著水解效果,将该酶在大肠杆菌(Escherichia coli)中进行重组表达并纯化后,对其酶学性质进行了研究。结果显示,HtBHETase对短碳链的酯类如对硝基苯酚乙酸酯催化活性较高,HtBHETase以BHET为底物时的最适反应pH值和最适反应温度分别为5.0和55℃;该酶有较好的热稳定性,经80℃的条件处理1 h仍能保持80%以上活性,显示出了良好的热稳定性,HtBHETase有在PET塑料生物解聚中使用的潜力,本研究为推动生物酶法降解PET提供了新的参考。     

生物可降解塑料单体二元羧酸的生物合成研究进展北大核心CSCD

塑料是最重要的聚合物材料之一,需求量巨大,但存在处理困难、污染大等缺点。环境友好型的生物可降解塑料有望成为目前塑料的替代品,以满足社会各界对于塑料制品日益增长的需求。二元羧酸是生物可降解塑料中重要的单体之一,可降解性强,应用广泛,并且可以通过全生物法合成。因此,本文重点选取了几种比较有代表性的二元羧酸,总结它们的生物合成途径以及其代谢改造手段,以期为中长链等复杂二元羧酸的生物法合成提供借鉴。