国家二级保护植物翅果油树营养器官结构的研究

系统研究了国家二级保护植物翅果油树(Elaeagnus mollis Diels)营养器官的结构,结果表明:根表皮外有2.4～36.7μm的粘液质层,对着韧皮部的内皮层细胞含有黑色物质,与粘液质层的形成有关.茎的皮层中有一层排列整齐紧密的椭圆形细胞,类似于内皮层.髓细胞中含有大量的針晶.次生木质部为典型的环孔材,具有多列同型射线.栅栏组织发达,叶细胞含有大量針晶,栅栏组织与海绵组织之比为1.96,具有旱生结构特性.     

披针叶胡颓子中的一个新木脂素

从披针叶胡颓子（Elaeagnus lanceolata）的干燥枝叶中分离得到19个化合物,其中isoamericanol B（1）为一新化合物,经波谱学方法鉴定其结构为rel-（7′Z）-（7β,8α）-3-methoxy-4,9′-dihydroxy-3′,7-epox-y-8,4′-oxyneolign-7′-ene。     

沙枣花蜜腺的发育解剖学研究

沙枣的花蜜腺位于花柱基部的筒状花盘上,属花盘蜜腺,其蜜腺位于花盘外方,由分履表皮和产蜜组织组成。分泌表皮具有角质层和变态的气孔器。产蜜组织在发育过程中,其液泡和淀粉粒都随着蜜腺的发育呈现一定的消长规律,最后形成的蜜汁由盘状蜜腺表面的气孔泌出。     

羊奶果根瘤内生菌的亚显微结构

羊奶果是桤木型根瘤。根瘤的横切面是轴对称的圆形结构,含菌细胞分散于皮层组织中。随着根瘤的发育,内生菌也有不同的形态结构。侵染初期的内生菌是一种分枝、具隔膜的菌丝体。幼龄菌丝中含有电子半透明的颗粒,成熟菌丝没有这种颗粒。成熟菌丝顶端会臌大形成具隔膜的椭圆球状泡囊,直径比菌丝大。不同发育时期的泡囊,其形态结构也有差异。     

翅果油树根瘤超微结构及其内生菌的观察

作者用光学显微镜,透射电镜和扫描电镜对翅果油树(Eldaeagnus mollis D.)根瘤侵染细胞的超微结构及其内生菌的形态进行了观察研究。翅果油树根瘤中的内生菌具有五种不同的发育形态:菌丝、固氮泡囊、孢囊、孢囊孢子和拟类菌体。内生菌的这些不同形态以及它们在共生固氮中的作用,本文也作了讨论。     

山西翅果油树的适生区预测及其对气候变化的响应

研究濒危物种生境在气候变化下的响应对保护物种多样性和保持生态系统功能完整性具有重要意义.本文选取我国特有濒危植物翅果油树为研究对象,以该物种73个野外调查数据和35个环境因子为基础,应用最大熵模型对山西翅果油树当前的适生分布区进行预测;进而结合政府间气候变化专门委员会第五次评估报告发布的气候模式数据,探讨未来不同气候情景下山西翅果油树分布格局的变化趋势.结果表明:受试者工作特征曲线分析法的AUC值为0.987,表明模型的模拟精度很好且预测可靠性高;刀切法检验结果显示,降水量季节变化、温度年变化范围、年均温、等温线、表层土p H值和年降水量是影响翅果油树分布的主要环境因子,其累积贡献率达到了94.8%;当前,山西翅果油树的适生区主要集中在山西省吕梁山南部和中条山地带;未来不同气候情景下,到21世纪70年代翅果油树适生区面积均有不同幅度的缩减,低浓度情景(RCP 2.6)下呈先增后减趋势,中高浓度情景(RCP 4.5和RCP8.5)下响应较敏感且呈先减后增趋势.两个不同适生区的空间分布格局对气候变化也有不同的响应,吕梁山南部表现出纬度方向的轻微波动,而中条山地带则是海拔方向的迁移.     

Distribution and N2-fixing activity of Frankia strains in relation to soil depth

The qualitative and quantitative distribution of Frankia strains infective on Elaeagnus angustifolia L. from different depths in the same soil (10–20 cm; 30–40 cm; 50–60 cm) were compared. The soil samples collected from a natural stand devoid of Elaeagnaceae were planted with Elaeagnus angustifolia L. seedlings. All plants became nodulated, demonstrating that Frankia strains were present at least down to 60 cm in the soil. The decreased density of Frankia strains was correlated to the decline of soil organic matter content with soil depth. DNA extracted from nodules produced on Elaeagnus angustifolia L. seedlings were polymerase chain reaction (PCR) characterized by amplifying the nif D-K intergenic spacer (IGS), using the polymerase chain reaction (PCR) followed by restriction fragment length polymorphism (RFLP) analysis. This showed the presence of seven nif-Hae III profiles within this Frankia community. Diversity of Frankia strains was maintained throughout the soil column, but the relative distribution of strains varied. Some nif-Hae III profiles were only found in the deeper soil, suggesting different selective advantages to withstand the constraints of soil depth. ¹⁵N₂ experiments indicated that all the strains tested had N₂-fixing activity. However, efficiency was not significantly different among nodules of different nif-Hae III profiles. Therefore, N₂-fixing activity does not seem to be the main factor responsible for the different distribution of Frankia strains at different soil depths.     

Autumnal changes in tissue nitrogen of autumn olive,black alder and eastern cottonwood

Two experiments were conducted to determine patterns of N change in tissues of autumn olive (Elaeagnus umbellata Thunb.) and black alder (Alnus glutinosa [L.] Gaertn.) during autumn in central Illinois, U.S.A. In the first study leaf nitrogen concentrations of autumn olive decreased 40% at an infertile minespoil site and 39% at a fertile prairie site throughout autumn whereas nitrogen concentrations in respective bark samples increased by 39% and 37%. Salt-extractable protein concentrations increased in bark and decreased in leaves over the sampling period. Free amino acid concentrations of autumn olive leaves decreased over the course of the experiment from peak concentrations in August. Asparagine, glutamic acid and proline were major constituents of the free amino acid pools in leaves. Total phosphorus concentrations of autumn olive leaves declined by 40–46% during autumn while bark concentrations of P did not significantly change.In the second experiment non-nodulated seedlings of alder receiving a low level of N-fertilization did not exhibit net resorption of leaf N during autumn whereas foliar N concentration of contrasting nonactinorhizal cottonwood plants (Populus deltoides Bartr. ex. Marsh) under the same fertilization regime decreased by 27% after the first frost. A gradual but significant decrease of 38% in foliar N concentration of nodulated alder seedlings grown under a low N-fertilization regime was associated with the cessation of nitrogenase activity during autumn in nodules. Compared with the low N fertilization regime, the higher level of N-fertilization resulted in smaller autumnal decreases of foliar N concentration in nodulated alder (17%) and in cottonwood (20%); but there was no decrease in foliar N concentration in non-nodulated alder. The higher level of N-fertilization promoted a greater accumulation of N in the roots than in the bark of both tree species after the first frost.Our results suggest that black alder lackingFrankia symbionts does not exhibit net leaf N resorption and that autumnal decreases in leaf N ofFrankia-nodulated black alder result primarily from declining foliar N import relative to export due to low temperature inhibition of N₂ fixation. In contrast, autumn olive exhibited greater and more precipitous autumnal declines in foliar N concentration than those of alder, and the pattern of N decline was unaffected by site fertility.     

Isolation and characterization of Frankia from nodules of actinorhizal plants of Pakistan

Frankia strains have been isolated from actinorhizal nodules of Alnus (2 strains), Casuarina (5 strains), Coriaria (1 strain), Datisca (3 strains), Elaeagnus (1 strain) and Hippophae (1 strain). The isolates were characterized for their growth on various carbon and nitrogen sources, nitrogen-fining ability in culture and nodulation of seedlings of the original host plant.     

The acetylene reduction assay inactivates root nodule uptake hydrogenase in some actinorhizal plants

Actinorhizal nodules do not usually evolve H₂ due to the action of an uptake hydrogenase. We have found that nodules of several Frankia symbioses evolved large amounts of H₂ gas when returned to air following exposure to 10 kPa C₂HT₂ during an acetylene reduction assay. Increased H₂ evolution in air persisted for several days when intact root systems of Alnus incana (L.) Moench (inoculated with Frankia UGL 011101) were treated with 10 kPa C.H₂ for 1 h. Full recovery of uptake hydrogenase activity required 4 to 8 days. Studies with crude homogenates of nodules of the same plants showed that hydrogenase (measured amperometrically with phenazine metho-sulfate as electron acceptor) was directly affected, since activity in treated nodules was only 10% of that in untreated nodules. A survey of actinorhizal symbioses revealed variation in the effect of an acetylene reduction assay on hydrogen metabolism. Nodules of three species, including Alnus rubra Bong, inoculated with Frankia HFPArD. showed complete inactivation of hydrogenase. H₂ evolution in air was 25% of the C₂H₂ reduction rate and H, evolution in Ar/O₂ was equal to the QH₂ reduction rate. Two symbioses, Ceanothus americanus L. (soil inoculant) and Batista glomerata Baill. (soil inoculant) showed no change following an acetylene reduction assay. A third group of symbioses showed an intermediate response.