生物土壤结皮对准噶尔盆地5种荒漠植物幼苗生长与元素吸收的影响

生物土壤结皮广泛分布于许多干旱和半干旱地区, 它影响土壤物理过程、水文、侵蚀和养分循环过程, 从而影响植物种子萌发与生长发育。该文以新疆准噶尔盆地腹地的古尔班通古特沙漠的生物土壤结皮为研究对象, 分析了生物土壤结皮对准噶尔盆地5种荒漠植物(白梭梭(Haloxylon persicum)、蛇麻黄(Ephedra distachya)、角果藜(Ceratocarpus arenaarius)、涩芥(Malcolmia africana)和狭果鹤虱(Lappula semiglabra))的生长及其对元素吸收的影响。结果表明: 1)相对于裸沙而言, 生物土壤结皮显著促进了荒漠植物的生长速率, 并增加了草本植物地上和地下的生物量, 但对灌木的生物量无显著影响; 2)生物土壤结皮使部分一年生草本植物的开花和结实期提前, 这可能有利于荒漠植物在有限的环境资源下快速完成生活史, 并繁衍后代; 3)生物土壤结皮能够影响荒漠植物对土壤中营养元素的吸收, 具体表现在生物土壤结皮显著促进了5种植物对N的吸收, 增加了荒漠植物在N贫乏的荒漠生态系统的适应能力, 而对P和K的吸收均没有影响。生物土壤结皮对荒漠植物对元素吸收的影响因种而异, 对不同的植物有不同的影响。荒漠植物对Mg、Mn和Cu的吸收受生物土壤结皮的影响最小。     

黄土丘陵区藓结皮人工培养方法试验研究

以陕北黄土丘陵区自然发育的藓结皮为繁殖材料,通过室内人工培养研究了藓类植物孢子繁殖法(孢子法)、植物碎片营养繁殖(断茎法)以及生物结皮团块粉碎(碎皮法)接种等不同方法对藓结皮形成发育的影响,并对不同培养温度和土壤含水量条件下的藓结皮生长发育进行比较分析.结果表明,(1)相同培养条件下,碎皮法接种有利于藓结皮盖度的形成,在20℃、光照5 230 lx、光周期12 h/d条件下,经80 d培养,藓结皮盖度、密度分别达到76%和59株/cm2,且显著高于其他方法.(2)不同的接种量对藓结皮形成发育影响显著,采用碎皮法,接种量在500～750 g/m2水平下藓结皮的盖度和藓类植物的密度生长较高.(3)温度显著影响藓结皮的形成和发育,在试验条件下,17℃有利于藓结皮盖度、藓类植株密度和株高的生长.(4)土壤含水量只有>60%田间持水量时才有藓结皮形成,当土壤含水量达到超饱和含水量,并在近地面处有水汽存在时则更有利于藓结皮的形成和发育.     

灌丛移除对荒漠齿肋赤藓越冬过程中生理生化特性的影响

灌丛和生物土壤结皮镶嵌分布是古尔班通古特沙漠一种重要的地表覆被类型, 灌丛的存在不仅为小型动物提供了庇护场所, 也为隐花植物及部分草本植物创造了良好的生存条件。然而在初冬时期移除灌丛是否会影响这些隐花植物的越冬及生长还不得而知。该研究通过模拟放牧及鼠害, 移除50%双穗麻黄(Ephedra distachya)灌丛、移除全部双穗麻黄灌丛及自然对照, 测定齿肋赤藓(Syntrichia caninervis)植株脯氨酸、可溶性糖和可溶性蛋白含量, 以及丙二醛(MDA)含量和超氧化物歧化酶(SOD)、过氧化物酶(POD)和过氧化氢酶(CAT) 3种抗氧化酶活性, 并测定原位光化学效率, 探讨初冬灌丛丧失对荒漠藓类植物越冬的影响。结果表明, 在积雪期3种处理下齿肋赤藓的游离脯氨酸和可溶性糖含量之间差异并不显著, 但去灌丛后其MDA含量、POD、SOD和CAT 3种抗氧化酶活性均显著高于自然灌丛下齿肋赤藓的相关生理指标。即使是在融雪期, 去灌丛下齿肋赤藓的可溶性糖含量及POD和CAT活性仍显著高于自然灌丛, 而可溶性蛋白明显较低, 这可能是由于灌丛的丧失造成的温度波动加剧了冬季低温对藓类植物的伤害。灌丛的部分移除(50%)对齿肋赤藓的生理生化特性影响不显著, 就积雪融化期叶绿素荧光活性持续时间而言, 与自然灌丛和移除50%灌丛相比, 完全移除灌丛的齿肋赤藓植株叶绿素荧光活性持续时间显著缩短。这可能是由于灌丛移除导致其UV-B辐射增加及“湿岛效应”消失所致, UV-B辐射的增加加剧了对植物的伤害, 而春季融雪期保水能力的下降也是其叶绿素荧光活性时间缩短的重要原因。     

The influence of biological soil crusts on 15N translocation in soil and vascular plant in a temperate desert of northwestern China

Aims Desert ecosystems are often characterized by patchy distribution of vascular plants, with biological soil crusts (BSC) covering interplant spaces. However, few studies have comprehensively examined the linkage between BSC and vascular plants through nitrogen (N) or element translocation. The objective of this study was to evaluate the ecological roles of BSC on N translocation from soil to the dominant herb Erodium oxyrrhynchum Bieb. (Geraniaceae) in a temperate desert in China.Methods Isotopes (including 15 N-Glu, 15 N-NH 4 Cl and 15 N-NaNO 3) were used as a tracer to detect translocation of N in two types of desert soil (BSC covered; bare) to the dominant herb E. oxyrrhynchum. Three different forms of 15 N-enriched N compounds were applied as a point source to small patches of BSC and to bare soil. And we measured isotopes (14 N and 15 N) and obtained the concentration of labeled- 15 N in both vascular plants and soils at different distances from substrate applicationImportant findings Plants of E. oxyrrhynchum growing in BSC-covered plots accumulated more δ 15 N than those growing in the bare soil. Similarly, soil from BSC-covered plots showed a higher concentration of labeled-N irrespective of form of isotope, than did the bare soil. The concentration of dissolved organic N (15 N-Glu) in E. oxyrrhynchum was higher than that of dissolved inorganic N (15 N-NH 4 Cl and 15 N-NaNO 3). Soil covered by BSC also accumulated considerably more dissolved organic N than bare soil, whereas the dominant form of 15 N concentrated in bare soil was dissolved inorganic N. Correlation analysis showed that the concentration of labeled-N in plants was positively related to the concentration of labeled-N in soils and the N% recorded in E. oxyrrhynchum. Our study supports the hypothesis that BSC facilitates 15 N translocation in soils and vascular plants in a temperate desert of northwestern China.     

Lichen acclimation to changing environments: Photobiont switching vs. climate‐specific uniqueness in Psora decipiens

Unraveling the complex relationship between lichen fungal and algal partners has been crucial in understanding lichen dispersal capacity, evolutionary processes, and responses in the face of environmental change. However, lichen symbiosis remains enigmatic, including the ability of a single fungal partner to associate with various algal partners. Psora decipiens is a characteristic lichen of biological soil crusts (BSCs), across semi‐arid, temperate, and alpine biomes, which are particularly susceptible to habitat loss and climate change. The high levels of morphological variation found across the range of Psora decipiens may contribute to its ability to withstand environmental change. To investigate Psora decipiens acclimation potential, individuals were transplanted between four climatically distinct sites across a European latitudinal gradient for 2 years. The effect of treatment was investigated through a morphological examination using light and SEM microscopy; 26S rDNA and rbcL gene analysis assessed site‐specific relationships and lichen acclimation through photobiont switching. Initial analysis revealed that many samples had lost their algal layers. Although new growth was often determined, the algae were frequently found to have died without evidence of a new photobiont being incorporated into the thallus. Mycobiont analysis investigated diversity and determined that new growth was a part of the transplant, thus, revealing that four distinct fungal clades, closely linked to site, exist. Additionally, P. decipiens was found to associate with the green algal genus Myrmecia, with only two genetically distinct clades between the four sites. Our investigation has suggested that P. decipiens cannot acclimate to the substantial climatic variability across its environmental range. Additionally, the different geographical areas are home to genetically distinct and unique populations. The variation found within the genotypic and morpho‐physiological traits of P. decipiens appears to have a climatic determinant, but this is not always reflected by the algal partner. Although photobiont switching occurs on an evolutionary scale, there is little evidence to suggest an active environmentally induced response. These results suggest that this species, and therefore, other lichen species, and BSC ecosystems themselves may be significantly vulnerable to climate change and habitat loss.     

Global change and biological soil crusts: effects of ultraviolet augmentation under altered precipitation regimes and nitrogen additions

Biological soil crusts (BSCs), a consortium of cyanobacteria, lichens, and mosses, are essential in most dryland ecosystems. As these organisms are relatively immobile and occur on the soil surface, they are exposed to high levels of ultraviolet (UV) radiation and atmospheric nitrogen (N) deposition, rising temperatures, and alterations in precipitation patterns. In this study, we applied treatments to three types of BSCs (early, medium, and late successional) over three time periods (spring, summer, and spring–fall). In the first year, we augmented UV and altered precipitation patterns, and in the second year, we augmented UV and N. In the first year, with average air temperatures, we saw little response to our treatments except quantum yield, which was reduced in dark BSCs during one of three sample times and in Collema BSCs two of three sample times. There was more response to UV augmentation the second year when air temperatures were above average. Declines were seen in 21% of the measured variables, including quantum yield, chlorophyll a, UV‐protective pigments, nitrogenase activity, and extracellular polysaccharides. N additions had some negative effects on light and dark BSCs, including the reduction of quantum yield, β‐carotene, nitrogenase activity, scytonemin, and xanthophylls. N addition had no effects on the Collema BSCs. When N was added to samples that had received augmented UV, there were only limited effects relative to samples that received UV without N. These results indicate that the negative effect of UV and altered precipitation on BSCs will be heightened as global temperatures increase, and that as their ability to produce UV‐protective pigments is compromised, physiological functioning will be impaired. N deposition will only ameliorate UV impacts in a limited number of cases. Overall, increases in UV will likely lead to lowered productivity and increased mortality in BSCs through time, which, in turn, will reduce their ability to contribute to the stability and fertility of soils in dryland regions.     

黄土高原三种耐干藓营养繁殖的季节差异及机理

苔藓植物在园林绿化、水土保持等方面的应用日益增加,目前藓类植物营养繁殖的影响因素鲜见报道,限制了其应用研究。本研究以黄土高原常见的耐干藓(扭口藓、土生对齿藓、短叶对齿藓)为对象,研究了3种藓春、夏、秋、冬季营养繁殖能力(以活力指数表征)差异及其叶绿素、可溶性糖、可溶性蛋白质、丙二醛(MDA)含量等生理指标变化,探索了耐干藓营养繁殖的季节差异与其生理特征之间的关系。结果表明: 1)藓类繁殖具有明显的季节差异,3种藓夏季活力指数均低于其他3个季节,平均较秋、冬、春季分别下降56.1%、48.4%、10.1%;相同季节的活力指数具有明显的年际变化。2)3种藓繁殖能力具有明显的种间差异,以短叶对齿藓最高,扭口藓最低,且后者的繁殖能力季节和年际变化最大。3)3种藓不同季节生理特征差异显著,其中夏季MDA含量高于其他季节,可溶性糖和可溶性蛋白质含量低于其他季节。4)耐干藓的营养繁殖季节变化主要与可溶性糖含量有关。本研究明确了藓类营养繁殖能力随季节变化的规律,指出可溶性糖含量是影响藓类营养繁殖的关键因素,可为藓类植物保护和人工培养提供科学依据。     

Population dynamics of Echinops gmelinii Turcz. at different successional stages of biological soil crusts in a temperate desert in China

• The effects of biological soil crusts (BSC) on vascular plant growth can be positive, neutral or negative, and little information is available on the impacts of different BSC successional stages on vascular plant population dynamics.
• We analysed seedling emergence, survival, plant growth and reproduction in response to different BSC successional stages (i.e. habitats: bare soil, cyanobacteria, lichen and moss crusts) in natural populations of Echinops gmelinii Turcz. in the Tengger Desert of northwest China. The winter annual E. gmelinii is a dominant pioneer herb after sand stabilisation.
• During the early stages of BSC succession, the studied populations of E. gmelinii were characterised by high density, plant growth and fecundity. As the BSC succession proceeded beyond moss crusts, the fecundity decreased sharply, which limited seedling recruitment. Differences in seedling survival among the successional stages were not evident, indicating that BSC have little effect on survival in arid desert regions. Moreover, E. gmelinii biomass allocation exhibited low plasticity, and only reproductive allocation was sensitive to the various habitats. Our results further suggest that the negative effects of BSC succession on population dynamics are primarily driven by increasing topsoil water‐holding capacity and decreasing rain water infiltration into deeper soil.
• We conclude that BSC succession drives population dynamics of E. gmelinii, primarily via its effect on soil moisture. The primary cause for E. gmelinii population decline during the moss‐dominated stage of BSC succession is decreased fecundity of individual plants, with declining seed mass possibly reducing the success of seedling establishment.

     

Effects of chemical substances on the rapid cultivation of moss crusts in a phytotron from the Loess Plateau,China

In this study, typical moss crusts, which were dominated by the species Didymodon vinealis (Brid.) Zand., were collected from the Loess Plateau and a 65-day cultivation experiment was performed to study the effects of five kinds of nutrient solutions (Knop, Murashige-Skoog (MS), Benecke, Part and Hoagland), two kinds of carbohydrates (glucose and sucrose) and three kinds of plant growth regulators (thidiazuron (TDZ), 6-benzylaminopurine (6-BA) and naphthaleneacetic acid (NAA)) on the coverage, plant density, and plant height of moss crusts. The main conclusions are as follows. (1) All Knop, MS, Benecke, Part and Hoagland nutrient solutions improved the coverage and plant density of moss crusts to different degrees and the promotional effects of the Hoagland nutrient solution were most significant. (2) Glucose and sucrose could promote the formation of moss crusts, but they inhibited the development of moss crusts at concentrations greater than 10?g/L. (3) With an increase in concentration, the effects of TDZ on the development of moss crusts changed from “enhanced” to “inhibited”. Regardless of whether the concentration was high or low, 6BA had no significant effects on the growth of moss crusts, and NAA reduced the development of moss crusts. Results suggest that nutrient solutions (e.g. Hoagland), low concentration carbohydrates solutions, and some plant growth regulators (e.g. 1?mg/L TDZ) enhance the development of moss crusts in Loess Plateau under the appropriate environmental conditions.     

Physical and chemical conditions in an hypersaline spring in the Namib Desert

Hosabes is a small mineralized spring lying in a gypsous crust in the central Namib Desert on the south-western coast of Africa. It is fed by virtually fresh groundwater that wells to the surface at this and other similar fracture lines. The extremely high rates of evaporation and solar radiation result in intense concentration of the salts and the formation of strong salinity and therefore density gradients in the deeper parts of the system. These in turn produce a solar pond effect with a reversed temperature gradient; temperatures reach 50°C within the water column. The deeper parts of the system appear to be monomictic. Although the surrounding crust is largely gypsous, the water in the spring is dominated by NaCl as a result of precipitation of CaS0₄ in the highly concentrated water.