川西亚高山暗针叶林不同恢复阶段红桦、 岷江冷杉土壤种子损耗特征

在川西亚高山米亚罗林区海拔3 100—3 600 m阴坡、半阴坡,以立地条件基本一致的箭竹和藓类林型不同恢复阶段(20—40年生的箭竹-阔叶林、藓类-阔叶林,50年生的箭竹-针阔混交林、藓类-针阔混交林、160—200年生的箭竹-暗针叶老龄林、藓类暗针叶老龄林)的群落为研究对象,于种子成熟散落前(8月)采集土壤样品,应用网筛分选法结合体视显微镜挑选种子,实验室发芽试验法和四唑染色法对种子生活力进行测定,分析了土壤内先锋树种红桦(Betula albo-sinensis)和顶极树种岷江冷杉(Abiesfaxoniana)的残余种子总数、组分及其分布格局;采用样方法调查了红桦和岷江冷杉的1年生幼苗密度。结果表明:1)随着森林的恢复,红桦的残余种子总数、外形完整种子数、发育不全种子数、空粒种子数和腐烂种子数呈减少的趋势,而岷江冷杉则相反。箭竹林型不同恢复阶段红桦的残余种子总数、外形完整种子数、发育不全种子数、空粒种子数和腐烂种子数总体上大于藓类林型相应恢复阶段。岷江冷杉的残余种子总数、外形完整种子数、发育不全种子数、空粒种子数、腐烂种子数的最大值均出现在藓类-暗针叶老林龄;2)在阔叶林和针阔混交林阶段,红桦和岷江冷杉的种子组分所占比例最高的分别为腐烂种子和发育不全种子,在暗针叶老龄林阶段,红桦的腐烂种子和空粒种子的比例位居前列,而岷江冷杉的外形完整种子比例最大;3)随着土层深度的增加,红桦和岷江冷杉的外形完整种子数、发育不全种子数、空粒种子数和腐烂种子数均呈减少的趋势。红桦和岷江冷杉不同组分的种子在枯枝落叶层所占地比例在72.85%—94.28%;4)红桦的1年生幼苗密度随着森林的恢复逐渐减小,而岷江冷杉的1年生幼苗密度随着森林的恢复逐渐增大。在8月份,土壤中已经不存在红桦和岷江冷杉有生活力的种子,两种植物的种子只能形成短暂土壤种子库。     

凋落物和根系输入对南亚热带季风常绿阔叶林土壤养分的影响

植被凋落物和根系输入在调节森林土壤元素生物地球化学循环中扮演着关键作用。目前仍然不清楚凋落物和根系输入对热带原始林土壤主要元素含量的调控作用。针对该研究现状,以中国南亚热带季风常绿阔叶林为研究对象,通过开展凋落物与根系输入改变的控制试验（6个处理,每处理4次重复：对照、凋落物加倍、凋落物去除、断根、断根+凋落物加倍、断根+去除凋落物）,探讨了凋落物和断根处理对土壤可溶性离子、土壤酸中和能力（ANC）和阳离子交换量（CEC）的短期影响。凋落物与根系处理半年后的结果显示：（1）凋落物去除与加倍处理都显著增加了0-40 cm土壤NO₃^-含量,并且凋落物去除效应大于添加效应;去除凋落物增加了表层土壤（0-20 cm） Ca²⁺、Mg²⁺、Na⁺的含量。（2）断根处理显著增加0-40 cm土壤NO₃^-和表层土壤Ca²⁺、Mg²⁺含量。（3）断根和去除凋落物交互处理显著增加了0-40 cm土壤NO₃^-和表层土壤Ca²⁺、Mg²⁺、K⁺含量,产生了叠加效应。（4）凋落物和断根处理并没有改变土壤pH,但降低了土壤酸中和能力（除凋落物加倍外）,其降低的原因主要与阳离子交换量的降低和NO₃^-含量的增加有关。这些结果表明,土壤养分离子的可利用性（尤其是NO₃^-和Ca²⁺、Mg²⁺）和酸缓冲能力对凋落物和根系输入改变响应敏感,森林植物及其凋落物对土壤养分保留和缓冲性能具有重要调节作用。在人为干扰和气候变化加剧背景下,该研究可为森林生态系统可持续管理提供重要的理论参考。此外,植被凋落物和根系输入改变引起的长期生态学效应仍值得进一步关注。     

基于县域尺度珠江-西江经济带广西段土地利用变化对生态系统服务价值的影响研究

土地利用方式改变着区域生态系统服务供给的潜在能力,进而对区域生态环境和经济可持续发展产生重要影响。以我国珠江-西江经济带广西段为例,测算1990年、2005年和2018年3期土地利用变化（LUC）和生态系统服务价值（ESV）,进而利用ESV损益流向表和双变量空间自相关模型探讨LUC影响下ESV的时空特征。结果表明：（1）28年间研究区ESV总值变化不大,近年来ESV相比2005年有所降低,建设用地面积增幅最大,耕地和林地面积先减少后增多,以林地与耕地相互转移为主;（2）林地是研究区最重要的生态用地,维持生物多样性、水文调节、保持土壤、气体调节和气候调节构成研究区ESV的主体;生态系统服务价值强度（ESVI）高值区主要分布在桂西北、桂东和桂北,低值区分布在地势较为平坦的桂中丘陵平原区;各区县ESVI呈显著空间正自相关性（P<0.05）,空间集聚程度较高,高-高聚集、低-低聚集分别与生态系统服务价值强度高值、低值区域高度重合;（3）研究期间林地与耕地之间的相互转移是ESV增减的主要原因;3个时期土地利用程度与ESVI的双变量空间自相关图具有相似的空间特征,呈现出显著空间负自相关模式（P<0.05）。     

Differential expression of insulin-like growth factor-I and insulin-like growth factor binding protein-1 in the diabetic rat

Summary Multiple factors contribute to the growth retardation which is a characteristic feature of uncontrolled diabetes. In this report we have examined the effects of streptozotocin-induced (STZ) diabetes on expression of insulin-like growth factor-I (IGF-I) and insulin-like growth factor binding protein-1 (IGFBP-1) in various tissues. As early as 7 days after STZ administration there was a modest reduction in IGF-I mRNA abundance. The reduction (10–30%) was of similar magnitude in each of the 7 tissues examined; liver, kidney, lung, diaphragm, quadraceps, heart and adipose tissue. However, the reduction achieved statistical significance only in the lung (p < 0.05) and diaphragm (p < 0.01). A further reduction in IGF-I mRNA abundance was seen in many tissues, 32 and 91 days after STZ administration. In contrast to the decrease in IGF-I mRNA, IGFBP-1 mRNA was significantly increased in the liver and kidney of diabetic rats. IGFBP-1 mRNA was detectable at only very low levels in other tissues but was increased in diabetic rats compared non-diabetic rats. In diabetic rats, a highly significant correlation (R = 0.75, p < 0.001) between hepatic IGFBP-1 mRNA and glucose was observed whereas there was no significant correlation between serum glucose and hepatic IGF-I mRNA abundance (R = 0.24, p = NS). Treatment of diabetic rats with insulin resulted in a small, non significant increase in hepatic and renal IGF-I mRNA and a significant decrease in renal IGFBP-1 mRNA abundance. The observations reported here are consistent with the hypothesis that diminished IGF-I expression and inhibition of available IGF-1 by increased levels of IGFBP-1 may explain the impaired growth seen in diabetic animals.     

Effects of Electrode Material on the Voltage of a Tree-Based Energy Generator

The voltage between a standing tree and its surrounding soil is regarded as an innovative renewable energy source. This source is expected to provide a new power generation system for the low-power electrical equipment used in forestry. However, the voltage is weak, which has caused great difficulty in application. Consequently, the development of a method to increase the voltage is a key issue that must be addressed in this area of applied research. As the front-end component for energy harvesting, a metal electrode has a material effect on the level and stability of the voltage obtained. This study aimed to preliminarily ascertain the rules and mechanisms that underlie the effects of electrode material on voltage. Electrodes of different materials were used to measure the tree-source voltage, and the data were employed in a comparative analysis. The results indicate that the conductivity of the metal electrode significantly affects the contact resistance of the electrode-soil and electrode-trunk contact surfaces, thereby influencing the voltage level. The metal reactivity of the electrode has no significant effect on the voltage. However, passivation of the electrode materials markedly reduces the voltage. Suitable electrode materials are demonstrated and recommended.     

模拟氮沉降增加对南亚热带主要森林土壤动物的早期影响

对模拟氮沉降增加条件下3种南亚热地带代表性森林(季风常绿阔叶林、针阔混交林和马尾松纯林)内土壤动物群落的早期响应特征进行了比较研究.试验采用模拟的方法,人为构建了一个氮沉降增加梯度系列,即对照、低氮处理(50kg·hm^-2·yr^-1)、中氮处理(100kg·hm^-2·yr^-1)和高氮处理(150kg·hm^-2·yr^-1).结果表明,不同林分对氮沉降增加的响应不同;季风林与针叶林表现了两种截然相反的变化趋势,前者反映的是负向效应,土壤动物的3项指标均明显下降,而后者则反映出明显的正向效应,使得针叶林土壤动物的各项指标达到混交林,甚至季风林的水平;氮沉降增加对混交林则没有表现出明显的作用.不同氮沉降增加水平所产生的效应也不完全相同.在季风林内,参比对照,中氮处理往往表现出显著的负向效应(P＜0.05),而低氮处理反应不明显;在针叶林内,氮处理的正向效应随着处理的加强而持续上升,尤其是对于土壤动物类群数指标,这种持续性均达到了显著性水平(P＜0.05).可以认为,这些结果反映了森林生态系统对氮饱和的响应机制.     

Correlation between leaf litter and fine root decomposition among subtropical tree species

Sampling disturbance has been shown to rapidly increase net nitrification rates in some forest soils. To gain insight on mechanisms, we investigated both gross and net rates of ammonification and nitrification in intact cores and mixed composite samples. Using the isotope pool dilution method, we studied samples from two northeastern USA watersheds, Brush Brook and Sleepers River in Vermont, where previous work had found high net nitrification rates. Gross ammonification was usually not significantly different between intact cores and mixed samples. However, gross and net nitrification rates in mixed samples were similar (mean ～24?µmol N?kg^?1?hr^?1 or ～8 mg N kg^?1 d^?1) and significantly higher than in intact cores (7.7 and 3.4?µmol N kg^?1?h^?1 for means of gross and net respectively). Nitrate consumption was decreased somewhat by disturbance but did not account for the large differences in net rates. Because there were similar gross ammonification rates in both treatments, increased nitrification in these disturbed soils must be a result of an increase in the utilization of ammonium by the ammonia oxidizers at the expense of other ammonium consumption pathways. Different mechanisms may operate in different soils; increased nitrification appears to be the primary pathway in these soils with high N cycling rates.     

Soil-atmosphere exchange of greenhouse gases in subtropical plantations of indigenous tree species

Indigenous broadleaf plantations are increasingly developing as a prospective silvicultural management approach for substituting in place of large pure conifer plantations in subtropical China. However, little information is known about the effects of tree species conversion on soil-atmosphere greenhouse gas (GHG) exchanges. Four adjacent monospecific plantations were selected in subtropical China to examine the effects of tree species on soil-atmosphere exchanges of N₂O, CH₄ and CO₂. One coniferous plantation was composed of Pinus massoniana (PM), and the three broadleaf plantations were Castanopsis hystrix (CH), Michelia macclurei (MM) and Mytilaria laosensis (ML). We found that mean soil N₂O and CO₂ emissions in the PM plantation were 4.34 μg N m^?2?h^?1 and 43.25 mg C m^?2?h^?1, respectively, lower than those in the broadleaf plantations (>5.25 μg N m^?2?h^?1 and >56.38 mg C m^?2?h^?1). The PM plantation soil had higher mean CH₄ uptake (39.03 μg C m^?2?h^?1) than the broadleaf plantation soils (<32.67 μg C m^?2?h^?1). Variations in soil N₂O emissions among tree species could be primarily explained by the differences in litter C:N ratio and soil total N stock. Differences in soil CH₄ uptake among tree species could be mostly attributed to the differences in mean soil CO₂ flux and water filled pore space (WFPS). Litter C:N ratio could largely account for variations in soil CO₂ emissions among tree species. This study confirms that there is no GHG benefit of converting PM plantation to broadleaf plantations in subtropical China. Therefore, the future strategy of tree species selection for substituting in place of large coniferous plantations in subtropical China needs to consider the potential effects of tree species on soil-atmosphere GHG exchanges.     

Substrate stoichiometry determines nitrogen fixation throughout succession in southern Chinese forests

The traditional view holds that biological nitrogen (N) fixation often peaks in early‐ or mid‐successional ecosystems and declines throughout succession based on the hypothesis that soil N richness and/or phosphorus (P) depletion become disadvantageous to N fixers. This view, however, fails to support the observation that N fixers can remain active in many old‐growth forests despite the presence of N‐rich and/or P‐limiting soils. Here, we found unexpected increases in N fixation rates in the soil, forest floor, and moss throughout three successional forests and along six age‐gradient forests in southern China. We further found that the variation in N fixation was controlled by substrate carbon(C) : N and C : (N : P) stoichiometry rather than by substrate N or P. Our findings highlight the utility of ecological stoichiometry in illuminating the mechanisms that couple forest succession and N cycling.     

Effects of Experimental Nitrogen and Phosphorus Addition on Litter Decomposition in an Old-Growth Tropical Forest

The responses of litter decomposition to nitrogen (N) and phosphorus (P) additions were examined in an old-growth tropical forest in southern China to test the following hypotheses: (1) N addition would decrease litter decomposition; (2) P addition would increase litter decomposition, and (3) P addition would mitigate the inhibitive effect of N addition. Two kinds of leaf litter, Schima superba Chardn. & Champ. (S.S.) and Castanopsis chinensis Hance (C.C.), were studied using the litterbag technique. Four treatments were conducted at the following levels: control, N-addition (150 kg N ha⁻¹ yr⁻¹), P-addition (150 kg P ha⁻¹ yr⁻¹) and NP-addition (150 kg N ha⁻¹ yr⁻¹ plus 150 kg P ha⁻¹ yr⁻¹). While N addition significantly decreased the decomposition of both litters, P addition significantly inhibited decomposition of C.C., but did not affect the decomposition of S.S. The negative effect of N addition on litter decomposition might be related to the high N-saturation in this old-growth tropical forest; however, the negative effect of P addition might be due to the suppression of “microbial P mining”. Significant interaction between N and P addition was found on litter decomposition, which was reflected by the less negative effect in NP-addition plots than those in N-addition plots. Our results suggest that P addition may also have negative effect on litter decomposition and that P addition would mitigate the negative effect of N deposition on litter decomposition in tropical forests.