促进绿色未来的全球木材科学与技术研究进展——国际林联第25届世界大会木材议题综述

国际林业研究组织联盟（IUFRO）第25届世界大会于2019年在巴西召开。文中从木材生长、木材性质与质量、木材识别、木材加工利用和木文化5个方面分别论述了这次大会在木材科学与技术领域的国际最新研究热点与进展，以反映全球木材科学的研究现状，并梳理学科发展方向。木材形成、木材质量、木材高附加值利用、木材识别新技术等议题依然是木材科学与技术领域的未来研究热点。     

中国粮食安全现状与应对策略

粮食是人类生存与发展的基础，粮食安全目前已经纳入国家战略，在世界贸易摩擦不断加剧的新形势下，保障国家粮食安全是长期艰巨的任务。分析了我国粮食生产现状及存在的问题，并针对粮食总量和质量上存在的问题提出了应对策略。提出了加强耕地保护与环境治理，建立粮食加工监管全程追溯系统，深化粮食科研院所改革，构建上下协同、功能互补和配置高效的粮食科技协同创新体系，持续推进粮食品种与区域结构调整，开展粮食增产模式攻关等方法，从而促进粮食安全保障能力稳步提升。      

博斯腾湖沉积物氨氧化细菌的筛选与鉴定

为了解干旱区淡水湖泊沉积物微生物在氨氧化中的功能,利用铵盐培养基对博斯腾湖不同深度沉积物进行驯化培养,结合水环境因子分析混合菌株产亚硝酸盐能力,从中分离纯化氨氧化细菌并对其氨转化能力进行试验。结果表明,6个采样位点12个样品中,11号位点深层沉积物(20～40 cm)混合菌株能有效利用铵盐产生亚硝酸盐,且连续6 d稳定维持其质量浓度高达20 mg/L以上。进而,从该混合菌液中分离得到30株单菌,其中有2株呈现出明显的氨氧化细菌特性。通过16S rRNA基因序列比对及形态学分析分别鉴定其为弯曲芽孢杆菌(Bacillus flexus)和赤红球菌(Rhodococcus ruber)。     

云南籽粒苋种质资源的表型多样性分析

为了系统分析云南籽粒苋种质资源的表型遗传多样性。采用遗传多样性指数、主成分分析、相关分析和聚类分析对104份云南籽粒苋种质资源的30个表型性状进行研究。结果表明,遗传多样性指数最高的质量性状和数量性状分别是主花序形状(1.68)和主花序长度(2.07)。前10个主成分累计贡献率达到73.944%,单株鲜体重与第3、第6、第9主成分极显著正相关,单株粒重与第9主成分极显著正相关。聚类分析将104份种质划分为5类,第Ⅰ类群可为间套种亲本材料,第Ⅱ和Ⅲ类群可为大粒亲本材料,第Ⅳ类群可为优质饲用亲本材料,第Ⅴ类群可为观赏类亲本材料。云南籽粒苋种质资源表型性状具有丰富的遗传多样性,有较大的开发利用潜力。     

黄瓜花叶病毒浙江白术分离物全基因组序列测定与分析

正白术(Atractylodes macrocephala Koidz.)为菊科(Compositae)苍术属(Atractylodes)多年生草本植物,其根茎入药具补脾健胃、燥湿利水、止汗安胎等功效,在我国广泛栽培,并以于术(浙江临安于潜)品质最佳[1]。近年来白术生产由于品种单一,长期连作等因素导致病毒病害日趋严重。据报道,黄瓜花叶病毒(Cucumber mosaic virus,CMV)~([2])、蚕豆萎蔫病毒2号(Broad bean wilt virus 2,     

田菁种子内生菌的分离及其对萌发的影响

植物-微生物联合修复是改良盐碱地的重要生物策略，其中获得有效的微生物菌株是关键所在。为了获得更多的植物促生菌菌种资源，以滩涂耐盐植物田菁种子为材料分离可培养内生菌。分离纯化得到了79株菌，主要集中分布在Bacillus、Azorhizobium、Cellulosimicrobium三个属。菌株SC45、SC59、SC60、SC24、SC5、SC17六株菌可分泌吲哚乙酸（indole-3-acetic acid，IAA）。SC45、SC59、SC60具有溶解无机磷能力，其中SC60分解无机磷能力最高为（207.9±14.29 ）mg·L-1，且SC45具有产铁载体能力。种子萌发试验结果显示，与对照相比，SC45、SC60、SC59、SC17对田菁种子的活力系数分别可提高13.3%、14.1%、29.9%、26.7%。且SC60和SC17菌株浸种可显著促进胚根的发育，胚根占比提高了29.5%和13%。上述结果表明，Bacillus SC60可分泌IAA和溶解无机磷，提高种子活力，促进胚根发育，可作为田菁促生菌应用于农业生产。     

苦荞粒形相关性状的遗传分析

利用籽粒大小差异较大的2个苦荞品种的杂交后代开展了与产量具有密切关系的粒形相关性状的遗传规律及其性状间的相关性分析。结果表明,F₂和F₃群体的粒长、粒宽、长宽比和千粒重表现值范围都超过亲本的表现值,并且粒长、粒宽和长宽比的变异系数均小于10%,千粒重的变异系数大于10%。另外,粒长、粒宽、长宽比和千粒重的加性方差均大于显性方差,广义遗传率在F₂和F₃代中分别为0.77~0.82和0.82~0.85,固定遗传率都达到0.80以上。粒形性状间的相关性分析结果表明,粒长、粒宽和千粒重相互间都存在极显著的正相关,粒宽和千粒重,粒长和长宽比的遗传相关系数较大。以上结果表明,具有较高遗传率的粒形相关性状可以在后代早期进行选择,但由于这些性状是数量性状而且受多个基因的控制,因此建议继续繁殖后代到基因型稳定,同时考虑性状间的相关性选拔最为有效。     

Responses of subshrub sagebrush rangeland in North-Western China to changes in livestock numbers and rainfall over 10 years (2004–2013)

Seriphidium transiliense, or subshrub sagebrush, is one of the most important forage resources for livestock in many arid lands, but such resources have been threatened by overgrazing for a long time. A 2013 vegetation survey of an original sagebrush rangeland (2400?ha) in the Tianshan Mountains revealed that nearly half of the area once under sagebrush has been replaced by annual species. This is due to the continual and rapid increase in livestock numbers over the past 30?years. Three smaller sites with different grazing scenarios: no grazing (Site N), a decline (Site 1), and an increase (Site 2) in livestock numbers, were selected to monitor recent changes (from 2004 to 2013) in vegetation biomass and the degree of dominance by sagebrush. Supplanting happened at Site 2 but little occurred at Site 1. There were significant differences between Site 2 and Site 1 in standing biomass in Spring and Summer, but no significant differences in Summer between Site 1 and Site N. The supplanting of sagebrush marks the completion of a dynamic process – in which rainfall plays a crucial role – of damage to sagebrush from heavy grazing in drought years and its rehabilitation by light grazing in some good years. Plant biomass loss was greatest when the land was first subjected to heavy grazing. Sagebrush tends to exist as a sole-dominant species rather than a companion species in sagebrush communities. This suggests that sagebrush continued to survive in pockets where grazing pressure had declined.     

Isolation and Characterization of GhLEA3 Gene from Upland Cotton and Its Expression in Response to Low Temperature Stress

[Objective] Based on the analysis of cotton GhLEA3 gene structure and its expression model in chilling stress, we investigated the resistance function of GhLEA3 in response to cold stress. [Method] We cloned GhLEA3 from upland cotton by homologous sequence cloning way. We analyzed the properties of the GhLEA3, and constructed phylogenetic tree by bioinformatics analysis. We constructed the transient expression vector 35S∷GhLEA3-GFP by In-Fusion connection technology and studied the subcellular localization of GhLEA3. The expression of GhLEA3 gene in leaves of TM-1 at three-leaf stage under low temperature stress treatments (4 ℃, 24 h) was performed. Agrobacterium tumefaciens mediated floral dipping method was used to transform the gene with expression vector 35S∷GhLEA3-GFP into Arabidopsis thaliana wild type. Low temperature germination experiment at 4 ℃ was conducted to verify germination ability of the transgenic Arabidopsis thaliana T₃ seed. The transgenic Arabidopsis seedlings were treated at 4 ℃(low temperature), and all the leaves were taken to measure their electrical conductivity. [Result] The coding sequence of GhLEA3 gene is 1 218 bp, which encodes 405 amino acids. GhLEA3 protein includes 4 functional domains of PF02987. Phylogenetic analysis showed that the similarity of amino acid sequences between upland cotton GhLEA3 and Arabidopsis thaliana AtLEA3 was 52.6%. GhLEA3 might be mainly localized in vacuoles and small vesicles. GhLEA3 was up-regulated in leaves after low temperature treatment. The germination rate of transgenic Arabidopsis thaliana of T₃ generation at low temperature was significantly higher than that of wild type, and its electrical conductivity of leaves after low temperature treatment was significantly lower than that of wild type. [Conclusion] GhLEA3 belonged to the member of LEA3 family. Phylogenetic analysis showed that GhLEA3 had the closest relationship with AtLEA3. GhLEA3 was induced by low temperature stress and may play an important role in improving cold resistance.