典型冷暖季沉水植物凋落物分解特性及沉积物微生物群落变化

为研究湿地沉水植物腐败分解对水体的污染状况,选择典型沉水植物金鱼藻（暖季植物）和菹草（冷季植物）进行了为期60 d的凋落物分解实验。结果表明金鱼藻和菹草凋落物分解规律相似,0—15 d快速分解,15—60 d缓慢分解,60 d凋落物失重率分别达到60.43%和66.72%。菹草的有机物释放量明显高于金鱼藻,N和P释放量相反,分解释放的N主要是NH4+-N和有机氮。三维荧光光谱（Excitation-Emission Matrix Spectroscopy, EEMs）结合平行因子分析法解析出一种类色氨酸物质C2和3种类腐殖质物质C1、C3、C4,易降解的类色氨酸有机物先增加后减少,难降解的类富里酸和类腐殖酸有机物逐渐增加。EEMs和四种组分的最大荧光强度百分比表明,溶解性有机物（Dissolved organic matter, DOM）在0—15 d以易降解有机物为主,15—60 d以难降解有机物为主。两种植物凋落物分解释放的DOM含量及特性不同,整体上呈低腐殖化特征,可能是水中难降解DOM的一个重要来源。植物凋落物的分解促进了沉积物中微生物的丰富度,降低了微生物的多样性;参与分解的主要微生物包括4 d时的Pseudomonas属（26%—35%）、15 d和30 d时的Malikia属（>8%）和Bacillus属（2.6%—9%）,分解难降解有机物的微生物逐渐增加,如Flavobacterium属;沉积物中微生物群落结构的变化受营养物质可利用性变化的影响。分析发现植物凋落物分解对水质的影响具有阶段性,0—15 d,N和P释放量增加暂时导致了水质恶化;15—60 d,N和P释放量降低,难降解有机物含量逐渐增加,可能会加剧水体甚至是沉积物的腐殖化程度。因此,在植物衰亡期应及时打捞或者做好植物平衡收割管理,避免因植物大量腐败导致水质恶化。     

植物精气研究进展

植物精气作为一种重要的生态保健旅游资源,具有杀菌、消毒、治病等多种保健功能。本文对植物精气的发现、生物合成途径、植物精气释放的环境影响因素以及植物精气对人体健康的影响进行了综述,并简要介绍了植物精气的提取分离方法以及它的实际应用情况。从已有的研究可以看出,各国研究工作者对植物精气的组成成分及其含量、药用机理、影响因素等方面进行了广泛的研究,并取得了一定的成果,但是有关植物精气是否对人体产生有害的影响、植物精气对人体有益的最佳含量和最佳时间、树种配置的最佳效果以及如何充分利用植物精气等问题仍有待深入研究。     

Fluorescence characterization and microbial degradation of dissolved organic matter leached from salt marsh plants in the Yellow River Delta

盐沼植被是沿海水体中溶解有机物(Dissolved Organic Matter, DOM)的重要贡献者。然而,不同盐沼植物释放DOM的动力学特征尚缺乏系统研究和比较。黄河三角洲湿地是中国东海岸面积最大,保护最完善的沿海生态系统之一。本论文研究了2016年10月从黄河三角洲(Yellow River Delta, YRD)盐沼中采集的三种常见沼泽植物(芦苇(Phragmites australis),碱蓬(Suaeda salsa)和獐茅(Aeluropus littoralis)的DOM释放过程。通过测定溶解有机碳(Dissolved Organic Carbon, DOC)和溶解氮(Dissolved Nitrogen, DN)发现,植物叶片释放的DOM浓度远高于其根和茎。在27天的培养期内,平均有15%的生物碳和30%的生物氮以DOC和DN的形式通过植物叶片释放。从植物中释放的DOM非常不稳定,在27天的培养期内,细菌共消耗了92.4%–98.1%的DOC和88.0%–94.6%的DN。植物释放DOM的荧光特性表明,发色溶解的有机物(Chromophoric Dissolved Organic Matter, CDOM)是DOM的主要组分,而类蛋白组分是植物释放CDOM的主要组分。细菌的降解作用改变了DOM的荧光性质和化学组成。上述的室内研究结果得到了实地调查的充分支撑,表明在深秋时期黄河口湿地有大量DOM溢出。本研究结果表明,盐沼植物释放的DOM是沼泽和沿海水域DOC和DN的重要来源,而且易降解DOC和DN为黄河口湿地和邻近沿海水域中的微生物群落提供了重要的食物来源。     

植物挥发性有机物合成与代谢途径及其释放与感知调控机制的研究进展CSCD

植物释放的挥发性有机物(biogenic volatile organic compounds,BVOCs)是具有低沸点、易挥发的低分子量亲脂性化合物,在植物发育的整个过程中,它们通常通过不同底物的几个独立途径由不同的酶催化合成,并受关键基因及转录因子等调控代谢,随后在植物细胞内和细胞之间移动而被释放出来,最终作为植物内部信号被植物感知从而进行传递交流,影响着植物各种生理反应。本文对植物BVOCs参与合成及代谢途径的调控机制、释放的细胞生理和理化性质及植物对BVOCs的感知调控进行分析和解读,以期为BVOCs的合成与代谢、释放与被感知机制的进一步研究提供参考。     

森林生物挥发性有机物释放速率研究进展

森林是生态系统中主要的BVOC(生物挥发性有机物)来源.BVOC对于大气环境质量、对流层化学以及全球碳循环平衡都具有十分重要的作用.综述了森林BVOC释放的季节性和日变化特征,并对其影响因子(生境差异、环境变化、树木发育阶段、生理状况和外来干扰等)进行了分析,同时还进一步阐述了森林BVOC释放的生态学意义,并在树种选择和植物配置等方面,为生态保健型森林旅游资源的开发和城市森林建设提出了几点建议.     

植物的硫营养

植物硫营养是生产中值得注意研究的问题。本文内容共分六部分。首先讨论了植物的含硫量和含硫有机物及其功能,其次讨论了植物根系对SO_4~(2-)的吸收和叶片对SO_2的吸收以及硫在植物体内的运输,再次讨论了硫化氢的释放,最后分别讨论了硫营养与氮代谢的关系,硫对光合作用的影响以及硫与生长的关系。     

田间植物对捕食螨的影响Ⅰ：猎物寄主植物的影响

捕食螨是重要的生物防治因子,影响捕食螨发挥生物防治效果的因素很多,猎物寄主植物在捕食螨的产卵、取食定位等行为活动中起着重要作用。本文主要从化学生态学、形态结构和植物营养的角度综合分析了植物自身释放的挥发物、植物受机械损伤后释放的挥发物和植物受猎物为害后释放的挥发物对捕食螨的取食定位影响,猎物寄主植物形态结构以及猎物寄主植物花粉和汁液等营养物作为捕食螨的替代食物对捕食螨的影响,同时阐述其研究趋势和前景。     

北京地区侧柏和垂柳释放有益挥发性有机物组分日动态变化特征

以侧柏(Platycladus orientalis)和垂柳(Salix babylonica)为研究对象,采用动态顶空套袋采集法和自动热脱附-气相色谱/质谱联用技术来分析这些植物释放的挥发性有机物(VOCs)的组成和释放模式。选择不同的时间和天气条件下的样本进行采集,并记录相关信息。通过对原始数据的分析,确定有益挥发性有机物(BVOCs)的成分和相对百分含量。研究结果显示,侧柏和垂柳在不同季节释放的BVOCs成分主要包括醇类、醛类、烯烃类等其他类化合物,这些有益BVOCs在植物的生理和生态功能中扮演着重要的角色,对于深入了解植物与环境之间的相互作用具有重要意义。侧柏和垂柳释放BVOCs成分在不同季节会有所变化。其次,研究分析了侧柏和垂柳在不同季节中有益BVOCs成分的含量和变动趋势。侧柏在不同季节的释放模式呈现出明显的差异。春季的释放模式呈现出“单峰单谷”曲线,夏季的释放模式呈现出“单峰”曲线,而秋季的释放模式呈现出“双峰单谷”曲线。这表明侧柏在不同季节中的挥发物释放存在明显的季节性变化。相比之下,垂柳的释放模式在不同季节中相对稳定,呈现出一致的“单峰型”曲线。这说明垂柳的挥发物释放...     

湿地植物根系泌氧及其在自然基质中的扩散效应研究进展

湿地植物根系径向泌氧(ROL)是构造根际氧化-还原异质微生态系统的核心要素,其扩散层为好氧、厌氧微生物提供了良好生境并促进其代谢活动,使湿地植物根际成为有机物降解、物质循环及生命活动最为强烈的场所,已有成果证明湿地植物根系ROL的强弱与污染物的去除效果密切相关。因此,开展湿地植物根系ROL及其在自然基质中的扩散效应研究,对于了解湿地植物根系ROL机理及其根际氧环境特征,进而发挥湿地植物的污染去除功能具有十分重要的意义。基于此,首先归纳了湿地植物根系ROL特征及其受影响机制的研究现状,而后从种属差异、时空分布及对微生物的影响等方面对根系ROL在自然基质中的扩散效应国内外研究成果进行了总结,最终根据研究现状与不足对今后的研究方向进行了简要展望。创新之处在于:1)提出影响根系氧供给及氧输送释放通道的环境、生物等因素,阐述了其对根系ROL的影响机制;2)着重阐述了目前研究较少提及的根系ROL扩散效应测定方法。     

苯并[α]芘对不同修复潜力羊茅属植物的根系分泌物中几种低分子量有机物的影响

根系分泌物是植物与土壤间进行物质交换和信息传递的重要载体,是植物响应外界胁迫的重要途径,也是构成根际微生态特征的关键因素。根系分泌物与有机污染物的植物修复密切相关,研究胁迫条件下不同修复潜力植物间根系分泌物的释放特征有助于揭示植物修复的内在机制。该文借助根际袋土培试验研究了苯并[α]芘(Ba P)胁迫下5种羊茅属(Festuca)植物根系不同生长期(30–70天)几种低分子量有机物的分泌特征。结果表明:1)Ba P浓度在10.25–161.74 mg·kg~(–1)范围内时,待试植物能有效地促进土壤中Ba P的去除,其修复潜力依次为苇状羊茅(F.arundinacea)草原羊茅(F.chelungkiangnica)≥毛稃羊茅(F.rubra subsp.arctica)≥贫芒羊茅(F.sinomutica)细芒羊茅(F.stapfii)。2)Ba P胁迫增强了植物根系对可溶性糖的分泌:随着胁迫强度的增大、胁迫期的延长,其分泌量变化呈"先升后降"趋势。3)Ba P胁迫促进了植物根系低分子量有机酸的释放,植物的修复潜力越大,有机酸高峰值出现时的胁迫浓度越高;组成成分较稳定,草酸、乙酸、乳酸和苹果酸为主要组分(97.34%),在修复潜力较强植物的根系分泌物中检测出微量的反丁烯二酸。4)Ba P胁迫对氨基酸种类影响不大,但对分泌量影响较大。其中,苏氨酸、丝氨酸、甘氨酸、丙氨酸的分泌量随Ba P胁迫强度的增强而剧增;脯氨酸、羟脯氨酸和天冬氨酸近乎以加和效应甚至协同效应的形式参与植物对Ba P胁迫的应激反应:参与应激组分的分泌量随胁迫强度的增强而剧增,植物的修复潜力越强,参与的组分越多。可见Ba P胁迫下,5种羊茅属植物根系分泌物中几种低分子量有机物的释放特征与植物自身的修复潜力有关:修复潜力越强,释放量越多且成分也越复杂,并呈现出较强的环境适应性及生理可塑性。     

环境因子对植物释放挥发性化合物的影响

对近年来有关环境因子与植物释放挥发性化合物关系的研究进展进行了综合和概括。本文主要包括3类挥发性化合物。（1）异戊二烯是由叶绿体产生并且直接释放到大气中的C5化合物。（2）单萜类化合物是一类环状或非环状的C10化合物,它在植物体内合成后首先贮存于体内的特殊结构中（如树脂道、油腺）,然后由此通过气孔向大气中释放。（3）含氧挥发性化合物以各种形式释放到大气中。它包括醇、醛、酮、酯和有机酸。本文的重点是前两者, 主要阐述了二方面内容：(1)植物挥发性化合物的生物合成和释放机理。(2)环境因子（如温度、光照、水分胁迫、营养、CO2浓度、空气湿度）及植物的发育阶段、机械损伤和昆虫取食等对植物挥发性化合物合成与释放的影响机制。     

On the induction of volatile organic compound emissions by plants as consequence of wounding or fluctuations of light and temperature

Among the volatile organic compounds (VOCs) emitted by plants, some are characteristic of stress conditions, but their biosynthesis and the metabolic and environmental control over the emission are still unclear. We performed experiments to clarify whether (1) the emission following wounding can occur at distance from the wounding site, from VOC pools subjected to metabolic signals; and (2) the emission of biogenic VOCs generated by membrane damage (e.g. consequent to wounding or ozone exposure) can also be induced by exposure to high light and high temperature, recurrent in nature. In Phragmites australis, leaf cutting caused large and rapid bursts of acetaldehyde both at the cutting site and on parts of the cut leaf distant from the cutting site. This emission was preceded by a transient stomatal opening and did not occur in conditions preventing stomatal opening. This suggests the presence of a large pool of leaf acetaldehyde whose release is under stomatal control. VOCs other than isoprene, particularly acetaldehyde and (E)-2-hexenal, one of the C-6 compounds formed by the denaturation of membrane lipids, were released by leaves exposed to high temperature and high light. The high-temperature treatment (45 degrees C) also caused a rapid stimulation and then a decay of isoprene emission in Phragmites leaves. Isoprene recovered to the original emission level after suspending the high-temperature treatment, suggesting a temporary deficit of photosynthetically formed substrate under high temperature. Emission of C-6 compounds was slowly induced by high temperature, and remained high, indicating that membrane denaturation occurs also after suspending the high-temperature treatment. Conversely, the emission of C-6 compounds was limited to the high-light episode in Phragmites. This suggests that a membrane denaturation may also occur in conditions that do not damage other important plant processes such as the photochemistry of photosynthesis of photoinhibition-insensitive plants. In the photoinhibition-sensitive Arabidopsis thaliana mutant NPQ1, a large but transient emission of (E)-2-hexenal was also observed a few minutes after the high-light treatment, indicating extensive damage to the membranes. However, (E)-2-hexenal emission was not observed in Arabidopsis plants fumigated with isoprene during the high-light treatment. This confirms that isoprene can effectively protect cellular membranes from denaturation. Our study indicates that large, though often transient, VOC emissions by plants occur in nature. In particular, we demonstrate that VOCs can be released by much larger tissues than those wounded and that even fluctuations of light and temperature regularly observed in nature can induce their emissions. This knowledge adds information that is useful for the parameterization of the emissions and for the estimate of biogenic VOC load in the atmosphere.     

Drought effects on volatile organic compound emissions from Scots pine stems

Tree stems have been identified as sources of volatile organic compounds (VOCs) that play important roles in tree defence and atmospheric chemistry. Yet, we lack understanding on the magnitude and environmental drivers of stem VOC emissions in various forest ecosystems. Due to the increasing importance of extreme drought, we studied drought effects on the VOC emissions from mature Scots pine (Pinus sylvestris L.) stems. We measured monoterpenes, acetone, acetaldehyde and methanol emissions with custom-made stem chambers, online PTR-MS and adsorbent sampling in a drought-prone forest over the hot-dry summer of 2018 and compared the emission rates and dynamics between trees in naturally dry conditions and under long-term irrigation (drought release). The pine stems were significant monoterpene sources. The stem monoterpene emissions potentially originated from resin, based on their similar monoterpene spectra. The emission dynamics of all VOCs followed temperature at a daily scale, but monoterpene and acetaldehyde emission rates decreased nonlinearly with drought over the summer. Despite the dry conditions, large peaks of monoterpene, acetaldehyde and acetone emissions occurred in late summer potentially due to abiotic or biotic stressors. Our results highlight the potential importance of stem emissions in the ecosystem VOC budget, encouraging further studies in diverse environments.     

Methanol as a signal triggering isoprenoid emissions and photosynthetic performance in <Emphasis Type="Italic">Quercus ilex</Emphasis>

Several volatile organic compounds (VOCs) have been reported as having a communication role between plants and also between plants and animals. We aimed to test whether methanol, a short-chain oxygenated VOC, could also have a signalling role between plants. We monitored photosynthetic performance and VOC exchange rates of Quercus ilex L. saplings before and after two different treatments: (a) clipping of some leaves to simulate an attack by herbivores and (b) fumigation with gaseous methanol for 5 h to simulate the amount of methanol a plant could receive from surrounding plants if those had been already attacked by herbivores. The clipping treatment enhanced the photosynthetic rates, the chlorophyll a to b ratio and the carotenoid to chlorophyll ratio of non-clipped leaves, suggesting an activation of plant protective metabolism. Also, a small but interesting systemic (in non-clipped leaves) increase in methanol emission rates was observed, which agrees with the possibility that methanol may act as a signalling cue. The methanol fumigation treatment induced an increase in the actual photochemical efficiency of PSII and also in the carotenoid to chlorophyll ratio. Methanol fumigation also promoted a 14% increase in the monoterpene emission rate, 1 day after the treatment, a similar response to the ones induced by other signalling VOCs. The enhanced monoterpene emissions could add to the blend of VOCs emitted after stress and be part of further signalling pathways, thus forwarding the message started by methanol. This study suggests that clipping and methanol fumigation at natural concentrations elicit significant neighbour plant physiological responses and further BVOC emissions.     

Why only some plants emit isoprene

Isoprene (2‐methyl‐1,3‐butadiene) is emitted from many plants and it appears to have an adaptive role in protecting leaves from abiotic stress. However, only some species emit isoprene. Isoprene emission has appeared and been lost many times independently during the evolution of plants. As an example, our phylogenetic analysis shows that isoprene emission is likely ancestral within the family Fabaceae (= Leguminosae), but that it has been lost at least 16 times and secondarily gained at least 10 times through independent evolutionary events. Within the division Pteridophyta (ferns), we conservatively estimate that isoprene emissions have been gained five times and lost two times through independent evolutionary events. Within the genus Quercus (oaks), isoprene emissions have been lost from one clade, but replaced by a novel type of light‐dependent monoterpene emissions that uses the same metabolic pathways and substrates as isoprene emissions. This novel type of monoterpene emissions has appeared at least twice independently within Quercus, and has been lost from 9% of the individuals within a single population of Quercus suber. Gain and loss of gene function for isoprene synthase is possible through relatively few mutations. Thus, this trait appears frequently in lineages; but, once it appears, the time available for evolutionary radiation into environments that select for the trait is short relative to the time required for mutations capable of producing a non‐functional isoprene synthase gene. The high frequency of gains and losses of the trait and its heterogeneous taxonomic distribution in plants may be explained by the relatively few mutations necessary to produce or lose the isoprene synthase gene combined with the assumption that isoprene emission is advantageous in a narrow range of environments and phenotypes.     

Release of lipoxygenase products and monoterpenes by tomato plants as an indicator of Botrytis cinerea-induced stress

Changes in emission of volatile organic compounds (VOCs) from tomato induced by the fungus Botrytis cinerea were studied in plants inoculated by spraying with suspensions containing B. cinerea spores. VOC emissions were analysed using on-line gas chromatography–mass spectrometry, with a time resolution of about 1 h, for up to 2 days after spraying. Four phases were delimited according to the starting point and the applied day/night rhythm of the experiments. These phases were used to demonstrate changes in VOC flux caused by B. cinerea infestation. Tomato plants inoculated with B. cinerea emitted a different number and amount of VOCs after inoculation compared to control plants that had been sprayed with a suspension without B. cinerea spores. The changes in emissions were dependent on time after inoculation as well as on the severity of infection. The predominant VOCs emitted after inoculation were volatile products from the lipoxygenase pathway (LOX products). The increased emission of LOX products proved to be a strong indicator of a stress response, indicating that VOC emissions can be used to detect plant stress at an early stage. Besides emission of LOX products, there were also increases in monoterpene emissions. However, neither increased emission of LOX products nor of monoterpenes is specific for B. cinerea attack. The emission of LOX products is also induced by other stresses, and increased emission of monoterpenes seems to be the result of mechanical damage induced by secondary stress impacts on leaves.     

Controls on isoprene emission from trees in a subtropical dry forest

Isoprene emission from vegetation is the single most important source of photochemically active reduced compounds to the atmosphere. We present the first controlled-environment measurements of isoprene emission from leaves of tropical forest trees. Our studies were conducted in the Guanica State Forest in Puerto Rico. We report the effects of temperature and light variations on biogenic isoprene emissions during 1995. Maximum emission rates varied among species from 0 to 268 nmol m^?2 s^?1. Values at the upper end of this range of maximum emission rates are 2–3 times higher than values reported from any temperate taxa. Isoprene emission showed strong sensitivity to light and temperature variations. In contrast to temperate plants, whose emissions tend to saturate at a light intensity of ～1000 μmol m^?2 s^?1, emissions from the tropical species increased with light intensity up to 2500 μmol m^?2 s^?1. The temperature optima for emissions from these plants were similar to those previously reported for temperate plants: ～40 °C. The high maximum emission rates and lack of light saturation indicate that estimates of isoprene emission from tropical forests need to be revised upwards.     

Factors Affecting the Emission of Monoterpenes from Red Pine (Pinus densiflora)

The mechanism of monoterpene emission from Pinus densiflora was studied using an environmentally controlled gas cabinet. It was found that monoterpene emission rate increases exponentially with temperature and is also influenced by light. These observations were explained reasonably by a mechanism whereby monoterpene emission rate depends on the monoterpene amount in the leaf oil and its saturated vapor pressure.     

ISOPRENE SYNTHASE GENES FORM A MONOPHYLETIC CLADE OF ACYCLIC TERPENE SYNTHASES IN THE TPS‐B TERPENE SYNTHASE FAMILY

Many plants emit significant amounts of isoprene, which is hypothesized to help leaves tolerate short episodes of high temperature. Isoprene emission is found in all major groups of land plants including mosses, ferns, gymnosperms, and angiosperms; however, within these groups isoprene emission is variable. The patchy distribution of isoprene emission implies an evolutionary pattern characterized by many origins or many losses. To better understand the evolution of isoprene emission, we examine the phylogenetic relationships among isoprene synthase and monoterpene synthase genes in the angiosperms. In this study we identify nine new isoprene synthases within the rosid angiosperms. We also document the capacity of a myrcene synthase in Humulus lupulus to produce isoprene. Isoprene synthases and (E)‐β‐ocimene synthases form a monophyletic group within the Tps‐b clade of terpene synthases. No asterid genes fall within this clade. The chemistry of isoprene synthase and ocimene synthase is similar and likely affects the apparent relationships among Tps‐b enzymes. The chronology of rosid evolution suggests a Cretaceous origin followed by many losses of isoprene synthase over the course of evolutionary history. The phylogenetic pattern of Tps‐b genes indicates that isoprene emission from non‐rosid angiosperms likely arose independently.     

Human-induced changes in US biogenic volatile organic compound emissions: evidence from long-term forest inventory data

Volatile organic compounds (VOCs) emitted by woody vegetation influence global climate forcing and the formation of tropospheric ozone. We use data from over 250 000 re‐surveyed forest plots in the eastern US to estimate emission rates for the two most important biogenic VOCs (isoprene and monoterpenes) in the 1980s and 1990s, and then compare these estimates to give a decadal change in emission rate. Over much of the region, particularly the southeast, we estimate that there were large changes in biogenic VOC emissions: half of the grid cells (1°× 1°) had decadal changes in emission rate outside the range ?2.3% to +16.8% for isoprene, and outside the range 0.2–17.1% for monoterpenes. For an average grid cell the estimated decadal change in heatwave biogenic VOC emissions (usually an increase) was three times greater than the decadal change in heatwave anthropogenic VOC emissions (usually a decrease, caused by legislation). Leaf‐area increases in forests, caused by anthropogenic disturbance, were the most important process increasing biogenic VOC emissions. However, in the southeast, which had the largest estimated changes, there were substantial effects of ecological succession (which decreased monoterpene emissions and had location‐specific effects on isoprene emissions), harvesting (which decreased monoterpene emissions and increased isoprene emissions) and plantation management (which increased isoprene emissions, and decreased monoterpene emissions in some states but increased monoterpene emissions in others). In any given region, changes in a very few tree species caused most of the changes in emissions: the rapid changes in the southeast were caused almost entirely by increases in sweetgum (Liquidambar styraciflua) and a few pine species. Therefore, in these regions, a more detailed ecological understanding of just a few species could greatly improve our understanding of the relationship between natural ecological processes, forest management, and biogenic VOC emissions.