造纸废水对芦苇实生苗生长特性及根系活力的影响

以室内水培的芦苇实生苗为材料,研究6种不同化学需氧量(CODcr)浓度造纸废水处理对芦苇生长指标和根系活力的影响,为利用造纸废水修复自然环境中芦苇实生苗种群提供理论依据。结果表明:(1)不同浓度造纸废水对芦苇各器官鲜(干)重有显著的促进作用,并以中等浓度(300mg.L-1)最为明显;随着造纸废水浓度的增加,废水对芦苇各器官鲜(干)重的促进作用有所减弱,这种减弱幅度在芦苇不同器官上存在差异。(2)高浓度造纸废水导致芦苇根生物量比、根状茎生物量比降低,但影响二者降低的废水浓度存在差异;低浓度造纸废水导致芦苇茎生物量比下降,并使叶生物量比增加。(3)随着造纸废水浓度的增加,芦苇的根系活力呈先上升后下降的趋势,并以CODcr浓度为300mg.L-1时的芦苇的根系活力最强,CODcr浓度为900mg.L-1时最弱。可见,低浓度造纸废水促进了芦苇的生长和根系活力,高浓度废水促进作用减弱甚至会抑制根系活力,并以CODcr浓度为300mg.L-1时芦苇实生苗生长最好。     

Variability of Cenococcum colonization and its ecophysiological significance for young conifers at alpine-treeline

* Plants establishing in environments that are marginal for growth could be particularly sensitive to mycorrhizal associations. We investigated ectomycorrhizal colonization and its significance for young conifers growing at, or above, their normal limits for growth, in the alpine-treeline ecotone. * Colonization of seedlings (<1 yr old) and juveniles (2- to 10-yr-old) of Picea engelmannii and Abies lasiocarpa by Cenococcum geophilum was determined in a field study, and effects of Cenococcum on Picea seedling ecophysiology were investigated in a glasshouse. * Colonization by Cenococcum was c. 20-fold greater for juveniles than seedlings, and approximately 4-fold greater adjacent compared with approximately 7 m away from trees. Juveniles of Picea were more colonized at timberline than Abies, and the opposite relationship was observed in forest. Colonization enhanced seedling water potential, but not phosphorus concentrations or photosynthesis. * These landscape and age-dependent variations in colonization correspond well with known variations in conifer physiology and establishment near timberline. Facilitation of seedling establishment by older trees at alpine-treeline may include a below-ground, mycorrhizal component that complements previously reported effects of trees on the microclimate and ecophysiology of seedlings.     

Demonstration of plant adaptation syndrome in plants and possible molecular mechanisms of its realization under conditions of anaerobic stress

Electron-microscopic examination of mitochondrial membrane ultrastructure in detached leaves of four-day-old wheat (Triticum aestivum L.) seedlings incubated under conditions of strict anoxia in the presence of exogenous glucose and cycloheximide or in the absence of these compounds revealed a paradoxical phenomenon: in the absence of exogenous glucose and cycloheximide, even a short-term (15–30 min) anaerobiosis resulted in a pathological destruction of mitochondria (swelling and the loss of cristae); however, a longer uninterrupted anaerobiosis (3–4 h) did not induce further mitochondria degradation but, in contrast, resulted in the recovery of their initial ultrastructure. Irreversible mitochondria degradation was observed only during subsequent still longer leaf anaerobic treatment (24–48 h). When, under conditions of strict anoxia, leaves were fed with glucose to stimulate glycolysis and ethanolic fermentation, we did not observe any signs of early destruction of mitochondrial ultrastructure and their swelling. Blockage of anaerobic protein synthesis with cycloheximide resulted in early destruction and subsequent irreversible degradation of mitochondria without any indications of their structural recovery. Based on the results of the experiments, we concluded that cell energy metabolism controlled byboth the presence of utilizable carbohydrates and also by the induction of anaerobic protein synthesis played a key role during early mitochondria destruction under extreme conditions of anaerobic stress, their subsequent recovery, and irreversible degradation during continuous long-term strict anoxia.     

24-表油菜素内酯对低氧胁迫下黄瓜根系抗氧化系统及无氧呼吸酶活性的影响

用营养液水培,研究了根际低氧胁迫下24-表油菜素内酯(EBR)对2个抗低氧能力不同的黄瓜品种根系中抗氧化系统及无氧呼吸酶活性的影响。结果表明,在低氧胁迫下,EBR处理显著提高了低氧胁迫下2品种黄瓜幼苗根系SOD、POD及ADH活性,降低了O2-·、H2O2和MDA含量、LDH活性及‘中农八号’根系PDC活性,而对‘绿霸春四号’根系PDC及2个品种CAT活性无明显影响,表明外源EBR处理通过促进低氧胁迫下根系中抗氧化酶和ADH活性的提高,降低LDH活性及ROS含量,增强植株抗低氧胁迫的能力。     

Seedling establishment,underground kinetics,and clonal reiteration: How do Potentilla inclinata and Inula ensifolia get their multifunctional subterranean systems?

The development of a seedling into an adult plant comprises various underground processes. Time-lapse photography (TLP) makes them visible. This is documented for Potentilla inclinata (Rosaceae) and Inula ensifolia (Asteraceae).After germination, P. inclinata develops a taproot system. Contraction phenomena pull the basal part of the shoot at least 10 mm into the soil. Later, several adventitious roots are generated, and thus the root system changes to a fibrous one. This is followed by cloning without separation of the ramets.Seedlings of I. ensifolia develop a weak primary root. At an early stage, adventitious roots are formed at the leaf rosette. This fibrous root system exerts a strong pulling effect on the shoot. After one vegetation period the basis of the rosette is approx. 30 mm under the soil surface. Cloning includes the formation of many new horizontal shoots, which conquer new sites.These two examples show three functional steps common in the developmental progress of subterranean systems: (I) establishment of the seedling, (II) innovation and survival of the young plant, and (III) reiteration (cloning and dispersal). However, to accomplish these basic development steps the diversity of subterranean systems is enhanced by different organographical components.Furthermore, the development of subterranean systems is a dynamic process consisting of two kinetic processes: the vertical movement during seedling establishment, which brings the innovation buds to a safe soil position, and the horizontal movement during dispersal, which conquers new sites.     

Ecophysiological traits associated with drought in Mediterranean tree seedlings: individual responses versus interspecific trends in eleven species

Species differ regarding their drought tolerance and individuals of a given species can modify their morphology and physiology in response to drought. However, since evolutionary and ecological selective pressures differ, individual and interspecific responses to drought might not match. We determined summer survival and a number of ecophysiological variables in two factorial experiments with seedlings of eleven tree species present in Mediterranean ecosystems, grown under slowly imposed water stress and control conditions. Plants experiencing drought exhibited reduced growth, low specific leaf area, chlorophyll content, and photosynthetic rate when compared to the controls, and species-specific drought tolerance was associated with an analogous set of trait values. However, while species with high leaf area ratio and shoot-root ratio exhibited greater drought tolerance, drought induced the reversed response within species. Contrary to expectations, water use efficiency was lower in drought-tolerant species and decreased in water-stressed individuals compared to the control plants. There was a distinctive phylogenetic signal in the functional grouping of species, with oaks, pines, and other genera being clearly different from each other in their drought tolerance and in their functional responses to drought. However, all relationships between ecophysiological variables and drought tolerance were significant after accounting for phylogenetic effects, with the exception of the relationship between drought tolerance and photochemical efficiency. Our results show that drought tolerance is not achieved by a single combination of trait values, and that even though evolutionary processes and individual responses tend to render similar results in terms of functional traits associated with drought, they do not necessarily match.     

Analysis of proteomic changes in roots of soybean seedlings during recovery after flooding

A proteomic approach was used to identify proteins involved in post-flooding recovery in soybean roots. Two-day-old soybean seedlings were flooded with water for up to 3 days. After the flooding treatment, seedlings were grown until 7 days after sowing and root proteins were then extracted and separated using two-dimensional polyacrylamide gel electrophoresis (2-DE). Comparative analysis of 2-D gels of control and 3 day flooding-experienced soybean root samples revealed 70 differentially expressed protein spots, from which 80 proteins were identified. Many of the differentially expressed proteins are involved in protein destination/storage and metabolic processes. Clustering analysis based on the expression profiles of the 70 differentially expressed protein spots revealed that 3 days of flooding causes significant changes in protein expression, even during post-flooding recovery. Three days of flooding resulted in downregulation of ion transport-related proteins and upregulation of proteins involved in cytoskeletal reorganization, cell expansion, and programmed cell death. Furthermore, 7 proteins involved in cell wall modification and S-adenosylmethionine synthesis were identified in roots from seedlings recovering from 1 day of flooding. These results suggest that alteration of cell structure through changes in cell wall metabolism and cytoskeletal organization may be involved in post-flooding recovery processes in soybean seedlings.     

水杨酸和茉莉酸甲酯对丹参幼苗叶片显微结构、光合及非结构糖积累的影响

研究了水杨酸(SA)和茉莉酸甲酯(MeJA)处理对丹参(Salvia miltiorrhiza Bunge)幼苗叶片显微结构、叶片光合能力及幼苗中非结构糖积累的影响.结果显示:SA处理增加了丹参幼苗叶片气孔密度;叶肉细胞排列紧密、体积减小,叶肉细胞内叶绿体数目减少,但叶绿体体积增大,叶绿体基粒片层结构的数目增加;叶片中叶绿素a、b含量、叶气孔导度、蒸腾速率以及净光合速率均增加;同时,幼苗根中和叶片中酸性转化酶活性降低,幼苗地上部分蔗糖含量及可溶性糖总量显著高于对照.MeJA处理减少了叶片气孔密度,气孔发育畸形;叶肉细胞间隙增大,栅栏细胞层数减少,叶肉细胞内叶绿体数目减少,叶绿体体积减小,叶绿体基粒片层结构被破坏;叶片中叶绿素a及类胡萝卜素含量、叶片的净光合速率低于对照,叶气孔导度、蒸腾速率增强;同时,幼苗根中及叶中酸性转化酶活性增加,幼苗根中蔗糖含量及可溶性糖总量显著低于对照.可见,SA处理能促进植物叶片显微结构发育,增强叶片光合能力,抑制蔗糖降解并促进蔗糖积累;而MeJA处理则破坏了植物叶片显微结构,降低了叶片光合能力,促进了蔗糖降解并减少蔗糖积累.