不同水体营养状态对（韰）和（鱼康 鱼良）白鱼生长性能的影响

和白鱼分别是抚仙湖的外来鱼类和土著鱼类.本实验比较研究了水体营养状态对二者生长性能的影响.实验鱼养殖在低、中、高三种营养状态的水体中.其中低营养状态水体组又是每一种鱼中、高营养水体组的对照.水体营养状态对韰和鏮鋃白鱼摄食率、生长速度、饵料转化效率、蛋白贮积率没有显著影响.不同营养状态水体组实验鱼的体蛋白、脂肪、灰分和能量含量没有显著差异.富营养化对两种鱼生长性能的影响是不同的.特定生长率、饵料转化效率、蛋白贮积率和能量贮积率的种间差异值均随着水体营养状态的提高而加大.与对照组相比,较高营养状态水体中的摄食率、特定生长率、饵料转化效率、蛋白贮积率和能量贮积率的增加率低于鏮鋃白鱼,或者降低率高于鏮鋃白鱼.实验结果说明,高营养状态对生长性能的负面影响较大;对于湖泊水体的富营养化,外来鱼类在生长性能方面不一定比土著鱼类具有优势.     

不同水体营养状态对can和鱇[鱼良]白鱼生长性能的影响

can和鱇[鱼良]白鱼分别是抚仙湖的外来鱼类和土著鱼类。本实验比较研究了水体营养状态对二者生长性能的影响。实验鱼养殖在低、中、高三种营养状态的水体中。其中低营养状态水体组又是每一种鱼中、高营养水体组的对照。水体营养状态对can和鱇[鱼良]白鱼摄食率、生长速度、饵料转化效率、蛋白贮积率没有显著影响。不同营养状态水体组实验鱼的体蛋白、脂肪、灰分和能量含量没有显著差异。富营养化对两种鱼生长性能的影响是不同的。特定生长率、饵料转化效率、蛋白贮积率和能量贮积率的种间差异值均随着水体营养状态的提高而加大。与对照组相比,较高营养状态水体中can的摄食率、特定生长率、饵料转化效率、蛋白贮积率和能量贮积率的增加率低于鱇[鱼良]白鱼,或者降低率高于鱇[鱼良]白鱼。实验结果说明,高营养状态对can生长性能的负面影响较大;对于湖泊水体的富营养化,外来鱼类在生长性能方面不一定比土著鱼类具有优势。     

浙江南部近海小黄鱼资源分布及其与环境因子的关系

根据2015—2016年浙江南部近海4个航次的底拖网资源调查数据,利用广义可加模型分析了调查期内小黄鱼资源的分布特征及其与环境因子的关系.结果表明:浙江南部近海的小黄鱼资源主要集中在鱼山渔场,夏季为小黄鱼资源的高产期,站点平均资源密度达到500.74 kg·h^-1·km^-2.不同季节影响小黄鱼资源密度及其分布的环境因子各不相同.其中,环境因子对秋季小黄鱼资源密度的影响效果并不显著.春季,小黄鱼主要分布于水深较浅的高盐水域;夏季,水温和盐度均与小黄鱼资源密度呈负相关关系,小黄鱼主要分布于中温高盐的鱼山海域;冬季,水温与资源密度呈正相关,小黄鱼栖息于水温适宜的外侧站点水域.总体上,小黄鱼资源的分布特征符合其洄游习性,但个别环境因子与资源密度的关系难以解释,仍需进一步研究.研究结果有助于了解浙江南部近海小黄鱼群体的生活习性,以及对小黄鱼资源的养护和管理.     

南亚热带退化生态系统恢复和重建的生态学理论和应用

退化生态系统的恢复与重建是一项十分复杂的系统工程,其功能和动态过程涉及物质、能量、空间、时间和多样性等基本的生态变量。在南亚热带的气候生态因子中,既有光、温、水充裕的有利一面,也有秋旱、台风和暴雨等不利的因素,但总的来说,影响退化生态系统恢复的主导生态因子是土壤因子,如土壤肥力和土壤水份。极度退化的生态系统的恢复与重建,第一步就是控制水土流失,提高土壤肥力和土壤理化结构,这还需要工程措施和生物措施相结合．退化生态系统的植被的恢复与重建,最有效和最省力的是顺从生态系统的演替发展规律来进行,生态系统演替理论是指导退化生态系统重建的重要的理论基础．退化生态系统恢复与重建的优化结构的构建,依赖于对空间、生物、能量生态学原理的理解。种群密度制约、种群空间分布格局、边缘效应、生态位分化、食物链、生物多样性等原理均对生态系统结构的构建有指导意义．而生态系统的群体发展,则受物质定律的影响．     

南宁市植物群落结构特征与局地小气候效应关系分析

着重探讨植物群落结构特征与生态小气候因子间的相关性。结果表明:(1)在林荫处,植物群落总冠幅盖度、总密度、群落重要值均与温度成极显著的负相关;植物群落群落重要值还与相对湿度达到显著正相关。(2)在林隙处,植物群落总平均株高与光照强度成显著正相关,与风速成极显著负相关。(3)植物群落结构特征与其小气候生态效应间的相关性是:总平均株高与遮光效应值达到极显著的正相关,与挡风效应值亦达到显著的正相关。另外,总冠幅盖度与降温效应值成极显著的正相关。同时,总密度与降温效应值亦成极显著的正相关。特别是群落重要值与降温、增湿、挡风、遮光等生态效应值都成显著甚至极显著的正相关。通过分析与探讨南宁市植物群落结构和小气候因子间的相关性机理,可为科学地进行城市绿化、生态城市建设提供理论依据。     

群体感应与病原菌致病性研究进展

群体感应是细菌根据细胞密度变化进行基因表达调控的一种生理行为。当细菌密度达到临界阈值时能释放一些特定的自诱导信号分子,从而调节本种群或同环境中其他种群的群体行为。细菌群体感应参与包括人类、动植物、病原菌在内的多种生物的生物学功能调节,如生物膜的形成、毒力因子的产生、病原菌的耐药性等。深入研究病原菌群体感应系统的调控机制,将提高对病原菌发病机制的认识,有利于以群体感应作为防治疾病策略的研究。系统阐述了群体感应系统的组成类型、群体感应与病原菌致病性的关系,及其在抑制病原菌致病方面的应用。     

长期不同施肥方式对稻田杂草群落的影响

利用太湖地区农业科学研究所31年的长期肥料定位试验田,分别于2011—2012年水稻抽穗期、结实期和收获期进行了杂草群落调查,并对杂草种群分布与土壤养分因子进行冗余分析。结果表明:随着水稻的生育进程,田间杂草密度增大,而氮磷肥的配施也能有效减少试验区田间杂草的密度;牛毛毡、鸭舌草、耳叶水苋和水蕨是水稻生长期的主要杂草类型;在施入磷肥的处理中,莎草科杂草密度减少甚至消失,鸭舌草密度则增加,耳叶水苋和水蕨则是在没有施肥的处理生长最好;氮磷配施减少群落丰富度的同时能增加群落的均匀度,人为干预相对最少的处理方式有利于群落结构的稳定发展。抽穗期RDA结果显示,第1、第2排序轴特征值分别为0.901和0.080,土壤全P、有效磷、全氮、碱解氮与第1排序轴相关系数分别为-0.887、-0.816、-0.810和-0.794。太湖地区稻麦两熟制条件下,长期不同施肥方式显著影响稻田杂草的群落组成,土壤养分库的差异性影响田面杂草密度和优势种群分布,影响稻田中杂草分布的土壤养分因子主要为氮、磷和有机质,土壤钾含量对杂草的总体分布影响相对较小。     

基于广义可加模型的珠江口中华白海豚栖息地偏向性研究

基于2013年12月—2014年9月珠江口水域20个站位的10类海水水质因子数据(p H、深度、表层水温、盐度、溶解氧、叶绿素a、化学需氧量、活性磷酸盐、无机氮、活性硅酸盐),结合珠江口水域中华白海豚Sousa chinensis的密度分布,首次利用广义可加模型(GAM)分析了珠江口中华白海豚密度分布与海水水质因子的关系。结果表明:建立的模型运行良好,GAM对中华白海豚密度分布的总偏差解释率达86.3%。影响中华白海豚密度分布的主要水质因子为深度、化学需氧量、活性磷酸盐以及盐度。中华白海豚主要栖息于水深15 m以内,盐度10‰~30‰之间的水域。化学需氧量和活性磷酸盐与其密度分布的相关性提示环境污染因子对其密度分布造成了一定的影响。     

刺槐和侧柏人工林有效根系密度分布规律研究

通过分层分段挖掘法 ,对 13龄刺槐、侧柏人工林 ,根区有效根长密度和根重密度的空间分布进行了研究 .结果表明 ,尽管刺槐根系分布深度是侧柏的 2倍多 ,但平均有效根长密度只有侧柏的 4 4 .5 % .在垂直方向上 ,两树种有效根系主要分布在 0～ 6 0 cm土层内 ,然而最大有效根长密度却均位于距地表 0～ 30 cm以内 .其中 ,刺槐 0～30 cm区域内有效根长占总有效根长的 5 1.5 8% ,侧柏占 5 8.38% ;刺槐有效根干重占总有效根干重的 6 3.0 1% ,侧柏占 71.0 9% ;两树种根系密度分布均随土层深度增加而呈指数形式递减 .在水平方向上 ,刺槐有效根系密度呈二次抛物线型分布、最大有效根长或根密度以距树干 30～ 90 cm处最大 ;侧柏有效根系密度则随着距主干距离的增大而减小 .非线性参数拟合分析表明 ,采用 RD=EXP A+BX +CZ 函数模型 ,能较好地反映人工林根系密度的空间分布     

森林植被恢复与环境生态因子互作关系研究进展

植被恢复是遏制生态环境恶化、改善脆弱生态系统的有效措施。植被同环境之间的关系极为复杂, 森林植被群落的恢复与重建, 在一定程度上改善了原有生境条件, 而不断被改变的环境生态因子反过来又影响着森林植被群落类型的演变。从土壤、群落、小气候3个方面综述了森林植被恢复与环境生态因子的互作关系, 针对现存问题, 认为今后应将微观的机理研究与宏观的动态研究相结合, 从不同尺度增强对植被退化、土壤、群落、小气候环境等因子互作关系的内在调控机理研究。     

Influence of Host Plant Structure and Microclimate on the Abundance and Behavior of a Tephritid Fly

Microclimate and host plant architecture significantly influence the abundance and behavior of insects. However, most research in this field has focused at the invertebrate assemblage level, with few studies at the single-species level. Using wild Solanum mauritianum plants, we evaluated the influence of plant structure (number of leaves and branches and height of plant) and microclimate (temperature, relative humidity, and light intensity) on the abundance and behavior of a single insect species, the monophagous tephritid fly Bactrocera cacuminata (Hering). Abundance and oviposition behavior were signficantly influenced by the host structure (density of foliage) and associated microclimate. Resting behavior of both sexes was influenced positively by foliage density, while temperature positively influenced the numbers of resting females. The number of ovipositing females was positively influenced by temperature and negatively by relative humidity. Feeding behavior was rare on the host plant, as was mating. The relatively low explanatory power of the measured variables suggests that, in addition to host plant architecture and associated microclimate, other cues (e.g., olfactory or visual) could affect visitation and use of the larval host plant by adult fruit flies. For 12 plants observed at dusk (the time of fly mating), mating pairs were observed on only one tree. Principal component analyses of the plant and microclimate factors associated with these plants revealed that the plant on which mating was observed had specific characteristics (intermediate light intensity, greater height, and greater quantity of fruit) that may have influenced its selection as a mating site.     

Grain yield and kernel weight of two maize genotypes differing in nitrogen use efficiency at various levels of nitrogen and carbohydrate availability during flowering and grain filling

Grain yield per plant (GYP) and mean kernel weight (KW) of maize (Zea mays L.) are sensitive to changes in the environment during the lag phase of kernel growth (the time after pollination in which the potential kernel size is determined), and during the phase of linear kernel growth. The aim of this study was to assess genotypic differences in the response to environmental stresses associated with N and/or carbohydrate shortage at different phases during plant development. The rate and timing of N and carbohydrate supply were modified by application of fertilizer, shading, and varying the plant density at sowing, at silking or at 14 d after silking. The effects of these treatments on the photosynthetic capacity, grain yield and mean kernel weight were investigated in two hybrids differing in N use efficiency. The total above-ground biomass and grain yield per plant of the efficient hybrid responded little to altered environmental conditions such as suboptimal N supply, enhanced inter-plant competition, and shading for 14 d during flowering, when compared to the less efficient genotype. We conclude that grain yields in the efficient genotype are less sensitive not only to N stress, but also to carbohydrate shortage before grain filling. Shading of N deficient plants from 14 d after silking to maturity did not significantly reduce grain yield in the non-efficient genotype, indicating complete sink limitation of grain yield during grain filling. In the efficient genotype, in contrast, grain yield of N-deficient plants was significantly reduced by shading during grain filling. The rate of photosynthesis declined with decreasing foliar N content. No genotypic differences in photosynthesis were observed at high or low foliar N contents. However, at high plant density and low N supply, the leaf chlorophyll content after flowering in the efficient genotype was higher than that in the non-efficient genotype. Obviously, the higher source capacity of the efficient genotype was not due to higher photosynthetic N use efficiency but due to maintenance of high chlorophyll contents under stressful conditions. In the efficient genotype, the harvest index was not significantly affected by N fertilization, plant density, or shading before the grain filling period. In contrast, in the non-efficient genotype the harvest index was diminished by N deficiency and shading during flowering. We conclude that the high yielding ability of the efficient genotype under stressful conditions was associated with formation of a high sink capacity of the grains under conditions of low carbohydrate and N availability during flowering and with maintenance of high source strength during grain filling under conditions of high plant density and low N availability.     

Planting density effects on assimilation and partitioning of photosynthates during grain filling in the late-sown wheat

Leaf blades of the late-sown winter wheat produced the major portion, i.e., more than 60 %, of the total ¹⁴C-photosynthates at grain filling, but ear (rachis and glumes) only about 15 %, sheaths about 11 %, and stem internodes about 11 %. The change of plant density in this experiment had little influence on the ¹⁴CO2-photoassimilation of the ear (rachis and glumes), flag leaf lamina, sheaths and stem internodes, but markedly affected photosynthesis of the second, the third and lower leaves. The photosynthetic rate [expressed as specific radioactivity, s-¹ kg-¹(d.m.)] and the amount of ¹⁴CO₂ photosynthates decreased significantly in the second, the third and other lower leaves at a high plant density. Upon grain-filling of the late-sown wheat, the grain was the major importer of photosynthates. Yet partitioning to the stem internodes depended on the plant density. Stem was the importer of photosynthates at a low plant density, but the exporter at a high plant density. In plants at a low plant density a fairly large proportion of photosynthates was distributed into the roots. The middle and lower above-ground parts of the late-sown wheat at a high plant density decreased or lost their function early. As a result, the plant senesced earlier. However, the grain setting, filling and yielding were restricted. An appropriately low plant density was suitable for prolonging the function of the middle and lower organs, delaying the senescence of plant, increasing the source supply for grain filling, and improving the grain yield. This revised version was published online in August 2006 with corrections to the Cover Date.     

洞庭丘岗平原区农村鼠类群落演替的观察

本文描述和分析了洞庭丘岗平原区鼠类群落的演替趋势及演替原因。80年代以前,该地房舍区鼠类群落组成以黄胸鼠及小家鼠为主,种群数量均较低。80年代初期,种植业、饲养业大发展,农户贮粮及防鼠设施未跟上,致使褐家鼠数量激增。80年代中后期,贮粮和住房条件改善,并经常使用敌鼠钠盐灭鼠,褐家鼠的种群数量下降,室内鼠类组成正向以小家鼠为主的方向演替。80年代初期农田区褐家鼠的比例亦上升,中期回归到以黑线姬鼠为主的状态。预测今后小家鼠和黑线姬鼠的比例将进一步上升,成为今后主要防治对象。     

Developing a Multilayered Integrated Numerical Model of Surface Physics – Growing Plants Interaction (MINoSGI)

This paper describes a Multilayered Integrated Numerical Model of Surface Physics – Growing Plants Interaction (MINoSGI), which represents interactions between the dynamics of forest ecosystems and microclimate. Aiming at a large‐scale study in the future, we describe forest dynamics by using area‐averaged prognostic equations for thedistributions of plant density and plant weight with respect to plant height classes, instead of individual‐based treatments for small‐scale forest patches. Growth and mortality of plants are modelled based on the carbon balance of each plant height class. The area‐averaged microclimate (e.g., light, wind speed, temperature, humidity, CO₂ concentration) within the forest canopy is simulated by a one‐dimensional multilayer canopy model, which includes most of the physical and physiological processes that control the forest microclimate. Owing to its multilayered framework, a direct specification is possible for the difference in the growing environment among plants of different size and species. Given hourly meteorological conditions, the model outputs energy, water, CO₂ and momentum fluxes to and from a forest, of which the structure changes through competition among plants. The model's performance was tested by comparing its outputs with observed data on the development of plant size distribution taken over a 5‐year period in an evergreen coniferous (Cryptomeria japonica) forest. The model produced realistic estimates of the total biomass increments during the period. The ratio of net primary production to gross primary production (=0.45) was consistent with previous estimates for temperate forests. The bimodal seasonal pattern in net ecosystem production was similar to the seasonal trend in the CO₂ flux measured over a forest of the same species. Although some limitations due to the one‐dimensional representation of microclimate were noticeable, the model adequately simulated distributions of annual growth rate, plant weight and diameter across plant height classes. Since the basic equations can be extended to include the effect of spatial variability with marginal increase of computational costs, the present model framework is feasible for large‐scale studies.     

Thermal gradients as control factors for leaf size variations at different altitudes in mountains

The two parameters of leaf dimension namely, length and width, show inverse correlation with the third parameter, the thickness. A thermal diffusion model is proposed which explains the inverse relationship between these and envisages that while leaf length and width are directly influenced by the microclimate the thickness is affected by the microclimate through endoclimate and energy balance in the leaves. The significance of the model is discussed in the light of its importance in assessing the survival range of plant species along the altitudinal gradient.     

水分亏缺对蚕豆光合特性影响的初步研究

本文报道了蚕豆现蕾至饱荚期不同时间土壤水分亏缺情况下的光合特性、光合产量及蚕豆水分亏缺敏感期。蚕豆现蕾后给予土壤干旱处理,光合速率、叶绿素含量、叶面积、气孔开度、生物产量及籽粒产量下降,但气孔密度和呼吸速率增加。水分亏缺使叶片光饱和点由50kLx降至30kLx,气孔开度日变化呈单峰(9—11时)曲线。始荚至盛荚期对土壤干旱最敏感,此期是蚕豆灌水的关键时期。     

不同株行距配置对夏大豆群体结构及光截获的影响

以田间试验(2006—2007年)为基础,分析了地上部干物质、叶面积指数(LAI)、光合有效辐射(PAR)、光能利用率和植株形态指标变化特征,夏大豆‘鲁豆4号’(Glycine maxcv.Ludou 4)在同一密度(3.09×105株/hm2)下设5种株行距配置方式,即行距×株距分别为18 cm×18 cm(A)、27 cm×12 cm(B)、36 cm×9 cm(C)、45 cm×7.2 cm(D)、54 cm×6 cm(E)。结果表明,大豆在生育期间干物质变化因株行距不同而产生差异,2006和2007生长季的各处理干物质分别在播种后第70天和90天达到最高,播种后第80天和100天时,A处理比E处理分别高21.6%和34.0%;不同层次干物质积累重心随行距加大有上移趋势。各处理LAI随行距扩大、株距减少有下降趋势,其中,A和B处理LAI表现较稳定,LAI相对较高且时间较长。光能利用率随行距加大有降低趋势,A和B处理显著高于E处理(P0.05)。夏大豆在不同株行距配置下,株粒数、百粒重与产量相关系数分别为0.941*和0.926*(2006年),0.995*和0.892*(2007年),随行距变小PAR透射率降低、截获率和光能利用率上升而产量增加,A和B处理产量显著高于E处理(P0.05)。说明夏大豆在雨养农业条件下,植株相对均匀分布可改善群体结构和增强光截获,进而提高群体光能利用率和产量。     

Canopy Apparent Photosynthetic Characteristics and Yield of Two Spike-Type Wheat Cultivars in Response to Row Spacing under High Plant Density

In northern China, large-spike wheat (Triticum aestivum L) is considered to have significant potential for increasing yields due to its greater single-plant productivity despite its lower percentage of effective tillers, and increasing the plant density is an effective means of achieving a higher grain yield. However, with increases in plant density, the amount of solar radiation intercepted by lower strata leaves is decreased and the rate of leaf senescence is accelerated. Row spacing can be manipulated to optimize the plant spatial distribution under high plant density, therefore improving light conditions within the canopy. Consequently, field experiments were conducted from 2010 to 2012 to investigate whether changes in row spacing under high plant density led to differences in canopy apparent photosynthesis (CAP), individual leaf photosynthesis and grain yield. Two different spike-type winter wheat cultivars, Jimai22 (a small-spike cultivar as a control cultivar) and Wennong6 (a large-spike cultivar), were grown at a constant plant density of 3,600,000 plants ha^–1 (a relatively higher plant density) over a wide range of row spacing as follows: 5-cm row spacing (R₀), 15-cm row spacing (R₁), 25-cm conventional row spacing (R₂), and 35-cm row spacing (R₃). The two-year investigations revealed that increased row spacing exhibited a significantly higher light transmission ratio (LT), which improved light conditions within the canopy; however, excessive light leakage losses in R₂ and R₃ treatments were not favorable to improved irradiation energy utilization efficiency. Aboveground biomass accumulation was influenced by row spacing. Two spike-type wheat accumulated greater biomass under 15-cm row spacing compared to other row spacing treatments, although a markedly improved photosynthetic rate (P_N), effective quantum yield of photosystem II (Φ_PSII) and maximal efficiency of photosystem II photochemistry (F_v/F_m) in the penultimate and third leaves were observed in R₂ and R₃ treatments. At the same time, a longer duration of CAP and green leaf area was maintained in R₁ during grain filling. Compared with conventional row spacing, Wennong6 in R₁ treatment obtained 21.0% and 19.1% higher grain yield in 2011 and 2012, respectively, while for Jimai22 it increased by 11.3% and 11.4%, respectively. A close association of yield with CAP and LAI at mid-grain filling was observed. In conclusion, for the tested growing conditions, decreasing the row spacing to an optimal distance (15 cm) maintained a longer duration of LAI and CAP during grain filling, made a better coordination of group and individual leaf photosynthesis, and accumulated higher aboveground biomass, leading to a greater grain yield. In addition, Wennong6 had a more rational canopy architecture than Jimai22 (improved LT and higher LAI) and CAP under 15-cm row spacing, leading to a higher grain yield, which indicated that the large-spike type cultivar has the potential to obtain higher yields by increasing plant density through optimum row spacing allocation (15 cm).     

涡度相关法研究土壤水分状况对沙地杨树人工林生态系统能量分配和蒸散日变化的影响

为了解位于北京大兴区林场杨树人工林在不同的土壤水分环境条件下的水汽交换过程和能量的分配差异及其与环境因子关系,运用涡度相关（Eddy covariance,EC）法开路系统、常规微气象观测系统及土壤热通量板等设施对生态系统生长季内典型水分胁迫和无水分胁迫条件下蒸散日变化、能量分配以及与各环境因子的关系进行了测定分析和比较。结果表明,在水分严重胁迫日（以7月7日为例）,蒸散日变化过程为单峰曲线,全天（24h）蒸散量为2.4mm;而在无水分胁迫典型日（以7月25日为例）,蒸散日变化过程呈多峰曲线,全天蒸散量为4．5mm。能量平衡分析显示,无水分胁迫条件下潜热通量（LE）占净辐射通量（Rn）的比例远高于水分胁迫条件下潜热通量占净辐射通量的比例,说明水分充足时,能量的大部分用于蒸散。水分胁迫条件下蒸散速率与各环境因子的相关性均低于无水分胁迫条件下蒸散速率与环境因子的相关性。水分胁迫条件下,蒸散速率主要与净辐射和下垫面因子关系显著,而与其它因子的相关性较小;无水分胁迫条件下,蒸散速率与下垫面土体含水量和各气象因子均表现出较强的相关性。大气温度对于两个典型日蒸散速率的影响均很小;土壤含水量与水分胁迫日的蒸散速率几乎没有相关性,反应出土壤水分含量低至对蒸散几乎没有贡献了。