Pb和Cd对森林土壤细菌功能多样性及群落结构的影响

重金属的毒性系数（The Toxic Factor,TF）是评价重金属潜在生态风险指数（potential ecological risk index,RI）的关键参数。为了探究基于Hakanson提出的TF值是否适用于重金属对土壤微生物的生态风险评估,以TF值为5和30的铅（Pb）和镉（Cd）构建土壤微宇宙试验,构建不同的RI水平（100、200和400）,通过Biolog-ECO板和高通量测序技术分析了Pb和Cd分别对细菌功能多样性及群落结构的影响。结果表明,对照处理（CK）的细菌丰度、功能多样性（Shannon指数,Simpson指数和McIntosh指数）和基因多样性（ACE和Chao1指数）均大于Pb、Cd污染的土壤,随着RI水平的升高,Pb和Cd污染土壤中细菌的丰度、功能多样性（Shannon指数和McIntosh指数）和基因多样性（Chao1指数和ACE指数）呈下降趋势。相同RI水平下,Pb污染土壤中细菌群落的丰度、平均颜色变化率（AWCD）、功能多样性指数、OTUs数和基因多样性指数均显著大于Cd污染（P<0.05）;6大类碳源利用率及主成分（PCA）分析表明,Pb污染土壤中细菌对糖类和羧酸的利用率均显著大于Cd污染（P<0.05）,在不同RI水平和重金属比例下,碳源利用模式而有所不同。同一RI水平下,相对于Pb污染,Cd污染土壤中变形菌门的相对丰度较为丰富,而绿弯菌门的相对丰度稀少;Pb和Cd污染土壤中慢生根瘤菌属、鞘脂单胞菌属、链霉菌属和norank_f__Roseiflexaceae等不同属细菌相对丰度表现出差异性。上述结果表明Hakanson提出的TF值并不适用于评估重金属Pb和Cd对土壤微生物的潜在生态风险。     

纳塔栎和柳叶栎对铅锌矿区污染土壤的修复潜力分析:田间试验

通过野外调查、采样和实验室分析方法,研究优新景观树种纳塔栎（Quercus nuttallii）和柳叶栎（Quercus phellos）对湖南郴州Pb、Zn矿区复合污染土壤的适应性和修复潜力。试验设计A、B、E区种植1年生纳塔栎,C、D区种植1年生柳叶栎,1年后测量株高、地径、生物量等生长指标,随机采集植物全株及根际土壤,测试植物根际土壤和树木组织中的重金属含量。试验结果：Pb、Zn矿区土壤受到重金属Cd、Pb、Zn和As的复合污染,不同区域的土壤表现出污染异质性,采用单污染指数（Pi）和内梅罗指数（P_N）评价不同地块的污染程度,A区尾矿库（P_N=20.08）和B区（P_N=3.14）为重度复合污染,C区（P_N=2.43）为中度复合污染,D区（P_N=1.55）和E区（P_N=1.07）为轻微污染。纳塔栎和柳叶栎在以上不同污染地块均能正常生长,株高、地径和生物量与复合污染指数（内梅罗指数）及重金属含量呈负相关。其中纳塔栎对Cd的生物富集系数（BCF）在A、B、E区分别为6.27-8.37、3.67-4.38、42.93-52.75,高于C、D区柳叶栎对Cd的生物富集系数1.79-2.15、0.89-1.07。B-E区Zn的转运系数（TF）在1.79-2.28之间,A区Zn的转运系数为0.43。结论：纳塔栎和柳叶栎表现出较强的重金属耐性,对Cd具有较高的生物富集能力,对Zn具有较高的转运能力。其中纳塔栎对重金属积累能力较强,可作为亚热带地区铅锌矿区Cd、Pb、Zn、As复合污染土壤的植被恢复及生态修复候选树种。     

美洲大蠊内生菌的分离鉴定及酶活性、抑菌作用测定

分离美洲大蠊内生细菌并测定菌体的淀粉、纤维素降解酶活性及抑菌特性。对虫体表面消毒,以LB和高氏一号培养基分离虫体内部细菌并进行16S rRNA基因序列分析。变色圈法测定降解酶活性,抑菌圈法测定抑菌活性。结果共分离到11株细菌,4株属于链霉菌属(Streptomyces),6株分别属于肠杆菌属(Enterbacter)、变形菌属(Proteus）、肠球菌属（Enterococcus）、沙雷氏菌属（Serratia）、芽胞杆菌属（Bacillus）和漫游球菌属（Vagococcus）。另有1株菌在NCBI中与肠杆菌的相似度最高, 为95%,可能代表着一个潜在的新种。4株链霉菌均有淀粉和纤维素降解能力。有3株菌对青枯雷尔氏菌有抑制效果。研究结果表明,美洲大蠊内生菌具有某些功能,甚至含有尚未发现的新菌种,是重要的菌种资源。     

新疆特色药食两用植物恰玛古内生放线菌的分离与鉴定

恰玛古（Qamgur, Brassica rapa L.）内生菌的研究主要集中在内生真菌,内生放线菌的研究报道较少。通过研究新疆药食两用植物恰玛古内生放线菌多样性,以期发现产新活性物质的放线菌或新种放线菌,为研究微生物药物奠定基础。从恰玛古根、茎和叶三个部位分离培养获得内生放线菌,对其菌落与个体形态进行观察,并利用序列测定方法进行鉴定,以获取其分类地位。从恰玛古三个部位共分离得到17株内生放线菌,其中12株为革兰氏阳性杆菌,3株为革兰氏阳性球菌,2株为革兰氏阳性丝状菌;17株内生放线菌分属于红球菌属（Rhodococcus）、拟诺卡氏菌属（Nocardiopsis）、链霉菌属（Streptomyces）、短杆菌属（Brevibacterium）、小短杆菌属（Brachybacterium）、两面神菌属（Janibacter）和微杆菌属（Microbacterium）。从新疆药食两用植物恰玛古中分离获得17株内生放线菌以稀有放线菌为主。     

基于Illumina MiSeq测序技术对冰川棘豆(Oxytropis glacialis)不同组织内生菌多样性的研究

植物内生菌（Endophyte）在宿主植物组织中的分布规律是内生菌对外界适应的重要机制。基于Illumina MiSeq测序技术,对适应青藏高原极端环境的主要疯草植物-冰川棘豆叶和根组织中的内生菌16S rRNA、ITS rDNA进行高通量测序和生物信息学分析,通过明晰内生菌在冰川棘豆组织中的菌群结构、功能以及环境之间的关系,探讨了组织间内生菌的分布特征对冰川棘豆适应极端环境的可能影响。分析结果表明,冰川棘豆组织间共有菌属丰度占菌属总丰度90%以上,不同组织间形成了保守性内生细菌和特异性内生真菌共存的群落结构特点,植物组织结构和环境的影响可能为推动内生菌选择合适的组织生态位定植提供动力,其中土壤含水量显著影响内生细菌（R²=0.241,P=0.024）和内生真菌（R²=0.223,P=0.031）的组间Beta多样性,土壤pH值显著影响内生真菌（R²=0.571,P < 0.001）Alpha多样性丰富度指数,而环境因素对组织间存在显著差异的内生菌功能和营养型解释并不显著。综合认为,保守性与差异性的内生菌菌群结构和功能为植物不同组织适应极端环境提供帮助,这有利于冰川棘豆的生存与扩散。     

多株功能菌种混合培养条件的响应面优化及其生长关系

对3种具有土壤中多种重金属污染修复和病虫害防治功能的光合细菌（Photosynthetic bacteria,PSB,包括Rhodobacter sphaeroides H菌株、Rhodopseudomonas palustris N菌株和Rhodospirillium rubrum M菌株）、枯草芽胞杆菌（Bacillus subtilis, BS）和植物乳酸杆菌（Lactobacillus plantarum, LP）进行混合培养,利用单因素和响应面试验优化培养基配方以及培养条件。确定功能菌混合培养的最佳条件：以光合细菌培养基为基础培养基,外加碳源为10 g/L蔗糖、氮源为1.25 g/L硫酸铵、培养温度为31.5 ℃、初始pH值为7.1、接种量为接种后的初始培养活菌数1.90×10⁹cfu/mL、培养时间为28.0 h。通过功能菌的加性模型法、生长动力学以及混合培养的生长关系分析表明,光合细菌、枯草芽胞杆菌和植物乳酸杆菌的生长均存在互惠互利关系。     

响应面分析法优化沙雷氏菌(Serratia sp.) AXJ-M对己烯雌酚的降解

[背景] 环境雌激素已成为目前干扰人类和动物内分泌系统而影响健康和生殖的一类新型环境污染物,利用微生物的降解作用修复被其污染的环境具有重要的现实意义。[目的] 以实验室保藏的一株己烯雌酚（Diethylstilbestrol,DES）降解菌沙雷氏菌（Serratia sp.） AXJ-M为对象,开展其对DES的降解特性及降解条件优化的实验研究。[方法] 利用单因素试验、Plackett-Burman因素筛选、最陡爬坡试验和Box-Behnken设计相结合的方法优化Serratia sp.AXJ-M对DES的降解条件。[结果] （NH₄）₂SO₄、ZnCl₂、胰蛋白胨被分别选做无机氮源、额外金属离子和外加营养物质时,对DES降解有明显的促进作用。利用Plackett-Burman实验确定（NH₄）₂SO₄浓度、DES浓度、pH值为影响菌株AXJ-M降解DES的主要因素。在此基础上,采用最陡爬坡试验和Box-Behnken设计,确定菌株AXJ-M在（NH₄）₂SO₄浓度1.48 g/L、ZnCl₂浓度0.02 g/L、温度30℃、pH 7.19、DES浓度119.5 mg/L、接种量3%（体积分数）下培养7 d,菌株AXJ-M对DES的降解率达到76.89%,较未优化前提高了17.38%。[结论] Serratia sp.AXJ-M具有较高的DES降解能力,该菌可为生物修复受DES或其他人工合成雌激素污染的环境提供优良的微生物资源。     

异源表达德氏乳杆菌保加利亚亚种TCS1调控酸适应基因提高乳酸乳球菌NZ9000耐酸性

[目的] 在乳酸乳球菌NZ9000中异源表达德氏乳杆菌保加利亚亚种中由双组分系统TCS1（JN675228/JN675229）调控的与酸适应相关基因,进而探究德氏乳杆菌保加利亚亚种应对酸胁迫的机制。[方法] 通过逆转录聚合酶链式反应和十二烷基硫酸钠-聚丙烯酰胺凝胶电泳验证由德氏乳杆菌保加利亚亚种TCS1调控的与酸适应相关基因中腺嘌呤磷酸核糖转移酶（aprt）、D-丙氨酸-D-丙氨酸连接酶（ddl）、寡肽ABC转运蛋白（oppDII）和延伸因子Ts（tsf）在乳酸乳球菌NZ9000中的表达情况。酸处理实验验证基因表达对宿主菌酸胁迫耐受能力的影响。并采用酵母双杂交验证双组分系统TCS1与表达的酸适应相关基因之间的互作关系及具体的互作部位。[结果] 结果表明,乳酸乳球菌NZ9000中成功表达了aprt、ddl、oppDII和tsf。aprt、ddl基因使重组菌对酸胁迫的抗性分别提高了75倍和114倍。oppDII和tsf基因的表达对重组菌株的耐酸能力没有明显影响。酵母双杂交实验表明TCS1中的组氨酸蛋白激酶HPK1与Ddl之间存在相互作用,且HPK1-C结构域是二者相互作用的关键区域。[结论] aprt和ddl过表达菌株酸刺激的适应能力显著高于对照菌株,该研究结果可为德氏乳杆菌保加利亚亚种及类似菌株耐酸性特性的获得策略提供参考。     

蚯蚓两种抗菌肽的分离纯化及部分性质

经硫酸铵沉淀、超滤、阳离子交换分离和反相快速蛋白质液相色谱（FPLC）分析,得到了两种新的蚯蚓抗菌肽F-1与F-2,经电喷雾离子源质谱（ESI-MS）测定,其相对分子质量为535.27和519.27.串联质谱（MS/MS）数据表明F-1的肽序列为Ac-Ala-Met-Val-Ser-Ser,F-2的肽序列为Ac-Ala-Met-Val-Gly-Thr.最小抑菌浓度（MIC）实验表明,F-1与F-2对鹑鸡肠球菌(Enterococcus gallinarum)、绿脓杆菌(Pseudomonas pyocyanea)、鲍氏不动杆菌(Acinetobacter baumanii)、土生克雷伯氏菌（Klebsiella terrigena）的最小抑菌浓度分别为11.4 mg/L和12.85 mg/L,对粪肠球菌(Enterococcus faecalis)的最小抑菌浓度分别为22.8 mg/L和25.68 mg/L.对真菌白色念株菌（Candida albicans）没有表现为完全的抑制作用.     

西藏青稞根际细菌群落结构及多样性

【目的】分析西藏不同种植区青稞根际土壤细菌群落结构及其影响因素，揭示特定环境下根际细菌生物标志物，为发掘研究优异根际促生菌及其作用提供参考。【方法】采用16S rRNA基因高通量测序技术和数据统计分析，比较了西藏5个市青稞种植区根际土壤细菌群落组成和结构差异，分析了青稞根际细菌生物标志物及群落结构变化的驱动因素。【结果】通过测序45个根际土壤样品获得10 715个操作分类单元（operational taxonomic units，OTUs），共43门、1 244属、2 783种，其中放线菌门（Actinobacteriota）、变形菌门（Proteobacteria）、绿弯菌门（Chloroflexi）、酸杆菌门（Acidobacteriota）、拟杆菌门（Bacteroidota）、厚壁菌门（Firmicutes）、芽单胞菌门（Gemmatimonadota）、粘球菌门（Myxococcota）和髌骨细菌门（Patescibacteria）为优势菌门，相对丰度占比94.92%-96.56%。五个市的根际细菌群落结构存在明显的差异，组间差异大于组内差异（R=0.226 9，P=0.001），其中放线菌门、绿弯菌门、酸杆菌门、拟杆菌门和髌骨细菌门丰度存在显著性差异（P<0.05）。五个市青稞根际土壤存在潜在生物标志物，拉萨和山南只有3个和6个特有细菌进化支，共现网络更为复杂、OTUs间联系更为紧密。变形菌门、绿弯菌门、放线菌门和酸杆菌门是青稞根际土壤中主要的关键细菌门，内生菌门、Methylomirabilota和蓝细菌分别是林芝市、日喀则市和山南市的特有关键类群。青稞根际细菌群落结构的变化主要与环境因子pH、全钾（total potassium，TK）、速效钾（available potassium，AK）、碳磷比（C：P）和海拔有关，其中TK是影响根际土壤细菌群落最重要的因子（r²=0.621 4，P=0.001）。【结论】西藏青稞根际细菌多样性丰富，5市间存在显著差异，且不同生长区青稞根际具有特有的生物标志物，为进一步研究特有根际细菌在青稞生长和环境适应中的作用，发掘优异根际促生菌提供参考。     

Cerebral interneurons controlling fictive feeding in Limax maximus

Summary Initiation and modulation of fictive feeding by cerebral to buccal interneurons (CBs) was examined in an isolated CNS preparation of Limax maximus. Three CBs which are phasically active during fictive feeding, CB₁, CB₃ and CB₄, will reliably trigger bouts of fictive feeding when activated alone or in pairs. Another phasic CB, CB_EC, is not effective for triggering feeding. One CB which is tonically active during fictive feeding, CB_ST, drives fictive feeding in 50% of preparations when activated alone and enhances triggering of feeding when co-activated with phasic CBs. The metacerebral giant cell (MGC) was found to be capable of triggering fictive feeding in preparations with an intact subcerebral commissure. The MGC was especially effective at increasing the effectiveness of other CBs for initiation of feeding. Short high-frequency bursts of phasic CB or MGC action potentials are capable of resetting ongoing fictive feeding. Resetting effects of CB action potentials are relatively independent of the phase of the bite-cycle in which they are activated. CB₄ phase-advances the bite-cycle while the other phasic CBs phase-delay the bite cycle. Moderate frequency stimulation of CB₄ speeds up the bite rate while moderate frequency stimulation of CB₃ slows biting. All CBs, except the tonic CB, CB_DL, increase the intensity of buccal motor neuron bursting during feeding. The excitatory effects of phasic CBs and the tonic CB, CB_EPSP, on fictive feeding persist for many seconds after the offset of stimulation. CBs form both monosynaptic excitatory and monosynaptic inhibitory connections with different BG motor neurons.Abbreviations BG buccal ganglion - BR buccal root - CB cerebral-buccal interneuron - CBC cerebral-buccal connective - CPG central pattern generator - FB fast burster neuron - FMP feeding motor program - IBI interbite interval - MGC metacerebral giant cell     

Effects of modified carbon black nanoparticles on plant-microbe remediation of petroleum and heavy metal co-contaminated soils

Abstract

Little is known about the effect of modified carbon black nanoparticles (MNCB) on the availability of heavy metals and petroleum degradation in petroleum and heavy metals co-contaminated soils. The overall objective of this study was to investigate the simultaneous effect of MNCB on heavy metal immobilization and petroleum biodegradation in co-contaminated soil in plant and plant-microbe combined remediation. The results showed that the petroleum degradation increased by 50% in petroleum-Cd co-contaminated soil and 65% in petroleum-Ni co-contaminated soil in plant-microbe combined remediation, comparing with the plant remediation and the application of MNCB did not show significant improvement on petroleum degradation in both plant and plant-microbe combined remediation. MNCB could significantly reduce the availability of heavy metals in soil and the uptakes of Cd and Ni by Suaeda salsa by roughly 18 and 10% and improve the growth of plant by alleviating the growth inhibition caused by heavy metals. The application of Bacillus subtilis and Sphingobacterium multivorum (heavy metal tolerant bacteria) inhibited the biomass of Suaeda salsa by enhancing the petroleum degradation. It could be concluded that MNCB played a major role in immobilizing the heavy metals and bacteria dominated the petroleum degradation in petroleum-metal co-contaminated soil.     

Waste Water Bacterial Isolates Resistant to Heavy Metals and Antibiotics

Sewage water of Casablanca, an industrial city in Morocco, was studied for microorganisms resistant to heavy metals. Isolates were purified and collected on agar slants to be screened for resistance to heavy metals, including mercury in vitro. The strains that showed high resistance to heavy metals were also studied for their resistance to antibiotics and aromatic hydrocarbons. Results indicated that the strains most resistant to all tested products belonged to Ps. fluorescens, Ps. aeruginosa, Klebsiella pneumoniae, Proteus mirabilis, and Staphylococcus sp. These strains exhibit high minimal inhibitory concentrations for heavy metals such as cadmium (2 mm) or mercury (1.2 mm). Growth of Ps. fluorescens and Klebsiella pneumoniae in the presence of heavy metals was also determined, and the growth curves indicated that mercury, copper, and zinc present a slight inhibitory action, while cadmium and silver could have a potent inhibitory action on growth compared with the controls. These studies also investigated growth in media containing aromatic compounds as the sole source of carbon. The results demonstrate that these strains could be good candidates for remediation of some heavy metals and aromatic compounds in heavily polluted sites. Received: 23 December 1999 / Accepted: 6 April 2000     

Competition alters plant species response to nickel and zinc

Phytoextraction can be a cost-efficient method for the remediation of contaminated soils. Using species mixtures instead of monocultures might improve this procedure. In a species mixture, an effect of heavy metals on the species' performance can be modified by the presence of a co-occuring species. We hypothesised that (a) a co-occuring species can change the effect of heavy metals on a target species, and (b) heavy metal application may modifiy the competitive behaviour between the plants. We investigated these mechanisms in a greenhouse experiment using three species to serve as a model system (Carex flava, Centaurea angustifolia and Salix caprea). The species were established in pots of monocultures and mixtures, which were exposed to increasing concentrations of Ni and Zn, ranging from 0 to 2,500 mg/kg. Increased heavy metal application reduced the species' relative growth rate (RGR); the RGR reduction being generally correlated with Ni and Zn concentrations in plant tissue. S. caprea was an exception in that it showed considerable Zn uptake but only moderate growth reduction. In two out of six cases, competitors significantly modified the influence of heavy metals on a target species. The interaction can be explained by an increased uptake of Zn by one species (in this case S. caprea) that reduced the negative heavy metal effect on a target species (C. flava). In two further cases, increasing heavy metal application also altered competitive effects between the species. The mechanisms demonstrated in this experiment could be of relevance for the phytoextraction of heavy metals. The total uptake of metals might be maximised in specific mixtures, making phytoextraction more efficient.     

Proteomic analysis of the response of the plant growth-promoting bacterium Pseudomonas putida UW4 to nickel stress

Background  

Plant growth-promoting bacteria can alleviate the inhibitory effects of various heavy metals on plant growth, via decreasing levels of stress-induced ethylene. However, little has been done to detect any mechanisms specific for heavy metal resistance of this kind of bacteria. Here, we investigate the response of the wild-type plant growth-promoting bacterium Pseudomonas putida UW4 to nickel stress using proteomic approaches. The mutant strain P. putida UW4/AcdS^-, lacking a functional 1-aminocyclopropane-1-carboxylic acid deaminase gene, was also assessed for its response to nickel stress.     

Biotransformation of Heavy Metals from Soil in Synthetic Medium Enriched with Glucose and Shewanella sp. HN-41 at Various pH

The biotransformation of heavy metals from contaminated soil was examined using a facultative anaerobic bacterium Shewanella sp. HN-41. The experiments were carried out to assess the influence of glucose at various pH on the transformation of heavy metals from soil thorough solubilization. A preliminary study on the transformation of heavy metals from soil was first performed using a defined medium supplemented with glucose at 10, 20, and 30 mM to select the effective concentration. Among the three concentrations examined, glucose at 30 mM leached a highest level of metal ions. Therefore, 30 mM glucose was used as the representative carbon source for the subsequent experiments in a defined medium at various pH (5, 6, 7, 8, and 9). The organism HN-41 was not influenced by pH ranging from acidic to neutral and was able to metabolize all the metal elements from contaminated soil. The level of Fe, Cr, As, Mn, Pb, and Al solubilization ranged from 3 to 7664 mg kg^?1 at various initial pH. The rate of metal solubilization was found to be low at neutral pH compared with acidic and alkaline. These results are expected to assist in the development of heavy metal transformation processes for the decontamination of heavy metal-contaminated soil.     

Effects of heavy metals on enzyme synthesis in substrate-amended river sediments

Summary The effects of heavy metals in diverse substrateamended river sediments were studied. Cd²⁺, Pb²⁺ and Zn²⁺ generally had a marked inhibitory effect on the synthesis of amylase, cellulase and urease, on numbers of substrate-hydrolysing bacteria, in all sediments studied. Inhibition increased with increasing metal concentration, and amylase was particularly sensitive. Pb²⁺ generally had the least effect. We conclude that enzyme synthesis measurements are useful in determining the effects of heavy metals on the degradation of organic pollutants in river sediments.     

Cardiac Myosin-binding protein C modulates the tuning of the molecular motor in the heart

Cardiac myosin binding protein C (cMyBP-C) is an important regulator of cardiac contractility. Its precise effect on myosin cross-bridges (CBs) remains unclear. Using a cMyBP-C^−/− mouse model, we determined how cMyBP-C modulates the cyclic interaction of CBs with actin. From papillary muscle mechanics, CB characteristics were provided using A. F. Huxley's equations. The probability of myosin being weakly bound to actin was higher in cMyBP-C^−/− than in cMyBP-C^+/+. However, the number of CBs in strongly bound, high-force generated state and the force generated per CB were lower in cMyBP-C^−/−. Overall CB cycling and the velocity of CB tilting were accelerated in cMyBP-C^−/−. Taking advantage of the presence of cMyBP-C in cMyBP-C^+/+ myosin solution but not in cMyBP-C^−/−, we also analyzed the effects of cMyBP-C on the myosin-based sliding velocity of actin filaments. At baseline, sliding velocity and the relative isometric CB force, as determined by the amount of α-actinin required to arrest thin filament motility, were lower in cMyBP-C^−/− than in cMyBP-C^+/+. cAMP-dependent protein kinase-mediated cMyBP-C phosphorylation further increased the force produced by CBs. We conclude that cMyBP-C prevents inefficient, weak binding of the myosin CB to actin and has a critical effect on the power-stroke step of the myosin molecular motor.     

Cigarette Butt Decomposition and Associated Chemical Changes Assessed by 13C CPMAS NMR

Cigarette butts (CBs) are the most common type of litter on earth, with an estimated 4.5 trillion discarded annually. Apart from being unsightly, CBs pose a serious threat to living organisms and ecosystem health when discarded in the environment because they are toxic to microbes, insects, fish and mammals. In spite of the CB toxic hazard, no studies have addressed the effects of environmental conditions on CB decomposition rate. In this study we investigate the interactive effects of substrate fertility and N transfer dynamics on CB decomposition rate and carbon quality changes. We carried out an experiment using smoked CBs and wood sticks, used as a slow decomposing standard organic substrate, incubated in both laboratory and field conditions for two years. CB carbon quality changes during decomposition was assessed by ¹³C CPMAS NMR. Our experiment confirmed the low degradation rate of CBs which, on average, lost only 37.8% of their initial mass after two years of decomposition. Although a net N transfer occurred from soil to CBs, contrary to our hypothesis, mass loss in the medium-term (two years) was unaffected by N availability in the surrounding substrate. The opposite held for wood sticks, in agreement with the model that N-rich substrates promote the decomposition of other N-poor natural organic materials with a high C/N ratio. As regards CB chemical quality, after two years of decomposition ¹³C NMR spectroscopy highlighted very small changes in C quality that are likely to reflect a limited microbial attack.     

Enhancement of heavy metal tolerance and accumulation efficiency by expressing Arabidopsis ATP sulfurylase gene in alfalfa

Abstract

Transgenic alfalfa (Medicago sativa L.) plants overexpressing the Arabidopsis ATP sulfurylase gene were generated using Agrobacterium-mediated genetic transformation to enhance their heavy metal accumulation efficiency. The ATP sulfurylase gene was cloned from Arabidopsis, following exposure to vanadium (V) and lead (Pb), and transferred into an Agrobacterium tumefaciens binary vector. This was co-cultivated with leaf explants of the alfalfa genotype Regen SY. Co-cultivated leaf explants were cultured on callus and somatic embryo induction medium, followed by regeneration medium for regenerating complete transgenic plants. The transgenic nature of the plants was confirmed using PCR and southern hybridization. The expression of Arabidopsis ATP sulfurylase gene in the transgenic plants was evaluated through RT-PCR. The selected transgenic lines showed increased tolerance to a mixture of five heavy metals and also demonstrated enhanced metal uptake ability under controlled conditions. The transgenic lines were fertile and did not exhibit any apparent morphological abnormality. The results of this study indicated an effective approach to improve the heavy metal accumulation ability of alfalfa plants which can then be used for the remediation of contaminated soil in arid regions.