杨树基因组AMT转运蛋白的生物信息学特性

本研究中,通过隐马尔科夫模型(HMM)和杨树蛋白质库搜索,共找到17个杨树铵转运体蛋白(PtAMTs).利用生物信息学方法,我们对杨树家族17条AMT蛋白序列的系统发生和AMT基因组定位进行分析,然后对其氨基酸组成成分、理化性质以及二级结构进行预测和分析,同时还分析了杨树与拟南芥、水稻、番茄、百脉根和欧洲油菜的AMT基因家族之间的联系.二级结构预测结果发现不同成员间氨基酸数目、氨基酸序列间的疏水性存在一定的差异;α-螺旋和无规则卷曲为主要二级结构组成部分.同源性比对分析表明,PtAMT基因家族主要分为2个亚家族,AMT1 (11个成员)和AMT2 (6个成员),基因结果分析表明AMT2亚家族成员不含内含子.杨树AMT蛋白的亚细胞定位分析表明PtAMT主要定位于膜结构上.电子表达图谱分析结果表明:只有XP_002309151和 XP_002334025基因有对应的EST序列,并有相应的电子表达谱,并主要在花蕾表达.     

珍稀濒危植物珙桐过氧化物酶活性和丙二醛含量

采用比色法测定了不同年龄级、部位和叶位珙桐叶的过氧化物酶(POD)活性和丙二醛（MDA）含量,以探讨珙桐的生理生态适应性。结果表明：不同年龄级同一生长时期珙桐叶的POD活性和MDA含量不同,同年龄级同层的POD活性随叶位增大先升后降,MDA含量随叶位增大逐渐升高;同叶位不同层及同层不同叶位的珙桐叶的POD活性和MDA含量不同。珙桐叶POD活性和MDA含量对生长期敏感,同年龄级同叶位的珙桐叶随叶片的生长、衰老,POD活性和MDA含量逐渐升高,即珙桐叶POD活性和MDA含量受生物和非生物因子影响显著,且不同年龄级、叶位、层次存在差异。     

Mycorrhizal synthesis of four ectomycorrhizal fungi in potted <Emphasis Type="Italic">Populus maximowiczii</Emphasis> seedlings

Ectomycorrhizal (ECM) syntheses between four ECM fungi, Laccaria amethystina, Hebeloma mesophaeum, Thelephora terrestris, and Tomentella sp., and Populus maximowiczii seedlings that are known to form ECM at a denuded area of Mt. Usu were performed in volcanic debris in a controlled growth chamber. The percentage of ECM colonization and seedling growth were determined 3 months after inoculation. Seedlings were successfully colonized by the inoculated ECM fungi with low contamination ratios. Seedling height and biomass were larger in the inoculated seedlings than in the control, although the effects of inoculation on seedling growth varied with the ECM fungus.     

Low level expression of prokaryotic tzs gene enhances growth performance of transgenic poplars

We modulated the level of a hormone gene expression in poplars using either 35S promoter (p35S) of cauliflower mosaic virus (CaMV) or aux promoter (pAUX) of A. rhizogenes. The transgenic poplars (Populus alba × P. tremula var. glandulosa), in which the bacterial trans-zeatin secretion (tzs) gene was attached either to the 35S promoter or to the aux promoter, were compared for their performance in tissue culture as well as in nursery. Northern blot analysis of total RNA probed with tzs coding region showed that the total tzs mRNA expression by p35S was approximately 200–300-fold higher than that driven by pAUX. In contrast, the cellular zeatin content of p35S-tzs transgenic poplars was merely 13-fold of those found in pAUX-tzs plants. Due to different levels of cellular zeatin levels, the two types of transgenic poplars showed different morphogenetic as well as growth responses. The p35S-tzs transgenic plants showed morphological characteristics typical of those treated with cytokinin in culture. These include multiple axillary shoot formation, thick stems, narrow leaves and absence of roots. In contrast, the pAUX-tzs plants had slightly higher cellular cytokinin levels than did control plants and showed a lower degree of cytokinin-related phenotypes, including a few axillary shoots in root-inducing media. Since p35S-tzs did not develop roots, only pAUX-tzs transgenic poplars could be transplanted to the nursery where they resumed a close-to-normal growth. Nevertheless, pAUX-tzs plants transferred to the nursery developed cytokinin-related phenotypes, including greater number of shoots, smaller leaves and slightly retarded growth in height, but with a high total biomass.     

Anaerobic ethylene glycol degradation by microorganisms in poplar and willow rhizospheres

Although aerobic degradation of ethylene glycol is well documented, only anaerobic biodegradation via methanogenesis or fermentation has been clearly shown. Enhanced ethylene glycol degradation has been demonstrated by microorganisms in the rhizosphere of shallow-rooted plants such as alfalfa and grasses where conditions may be aerobic, but has not been demonstrated in the deeper rhizosphere of poplar or willow trees where conditions are more likely to be anaerobic. This study evaluated ethylene glycol degradation under nitrate-, and sulphate-reducing conditions by microorganisms from the rhizosphere of poplar and willow trees planted in the path of a groundwater plume containing up to 1.9 mol l⁻¹ (120 g l⁻¹) ethylene glycol and, the effect of fertilizer addition when nitrate or sulphate was provided as a terminal electron acceptor (TEA). Microorganisms in these rhizosphere soils degraded ethylene glycol using nitrate or sulphate as TEAs at close to the theoretical stoichiometric amounts required for mineralization. Although the added nitrate or sulphate was primarily used as TEA, TEAs naturally present in the soil or CO₂ produced from ethylene glycol degradation were also used, demonstrating multiple TEA usage. Anaerobic degradation produced acetaldehyde, less acetic acid, and more ethanol than under aerobic conditions. Although aerobic degradation rates were faster, close to 100% disappearance was eventually achieved anaerobically. Degradation rates under nitrate-reducing conditions were enhanced upon fertilizer addition to achieve rates similar to aerobic degradation with up to 19.3 mmol (1.20 g) of ethylene glycol degradation l⁻¹ day⁻¹ in poplar soils. This is the first study to demonstrate that microorganisms in the rhizosphere of deep rooted trees like willow and poplar can anaerobically degrade ethylene glycol. Since anaerobic biodegradation may significantly contribute to the phytoremediation of ethylene glycol in the deeper subsurface, the need for “pump and treat” or an aerobic treatment would be eliminated, hence reducing the cost of treatment.     

Putative involvement of Thioredoxin h in early response to gravitropic stimulation of poplar stems

Gravity perception and gravitropic response are essential for plant development. In herbaceous species, it is widely accepted that one of the primary events in gravity perception involves the displacement of amyloplasts within specialized cells. However, the early signaling events leading to stem reorientation are not fully known, especially in woody species in which primary and secondary growth occur. Thirty-six percent of the identified proteins that were differentially expressed after gravistimulation were established as potential Thioredoxin targets. In addition, Thioredoxin h expression was induced following gravistimulation. In situ immunolocalization indicated that Thioredoxin h protein co-localized with the amyloplasts located in the endodermal cells. These investigations suggest the involvement of Thioredoxin h in the first events of signal transduction in inclined poplar stems, leading to reaction wood formation.     

Effect of Mn toxicity on morphological and physiological changes in two <Emphasis Type="Italic">Populus cathayana</Emphasis> populations originating from different habitats

The cuttings of Populus cathayana were exposed to four different manganese (Mn) concentrations (0, 0.1, 0.5 and 1 mM) in a greenhouse to investigate the toxicity of Mn and the detoxifying responses of woody plants. Two contrasting populations of P. cathayana, which were from wet and dry climate regions in western China, respectively, were examined in our study. The results showed that high concentration of Mn caused significant decrease in shoot height, biomass accumulation, and leaf number and leaf areas. Injuries to the anatomical features of leaves were also found as the reduced thickness of palisade and spongy parenchyma, the decreased density in the conducting tissue and the collapse and split in the meristematic tissue in the central vein. Moreover, Mn treatments caused the accumulation of hydrogen peroxide (H₂O₂), and then resulted in oxidative stress indicated by the oxidation of proteins and DNA. Many physiological responses were employed to cope with the toxicity of Mn, including the increase in the contents of non-protein thiol (NP-SH), phytochelatins (PCs) and phenolics compounds and the stimulated activities of guaiacol peroxidase (GPX) and polyphenol oxidase (PPO) for the chelation of Mn and for the antioxidation of reactive oxygen species. The population from dry climate habitat showed a lower leaf concentration of Mn, higher contents of the chelators, and higher activities of GPX and PPO than did the wet climate population at the same Mn treatment, thereby possessing a superior Mn tolerance. In both populations, most of the Mn was accumulated in the shoot, which is favorable regarding phytoremediation.     

唐古特白刺研究现状与建议

唐古特白刺(Nitraria tangutorum Bobr.)是白刺属中较进化的植物种,众多克隆株系形成"白刺包",具有重要的生态防护价值,其浆果状核果也具有较高的经济利用价值.由于种内异交和种间杂交,唐古特白刺种内变异十分丰富,其中表现最为明显的是果实性状变异.而果色、果味、果序重等性状差异,对于生产成本、加工工艺以及产品质量等都有较大影响,从而限制了白刺果的产业化开发.开展种质资源、优树选择、杂交和倍性育种等方面的研究,对唐古特白刺进行遗传改良,选育高产、味佳、核小、色泽美观且生态价值高的果用与生态兼用型白刺品种,并进一步使其无性系化、种植园化,则是推动沙区白刺资源开发、利用以及当地生态与经济发展的关键.