农杆菌介导的高效玉米遗传转化体系的建立

为了建立玉米高频再生及高效遗传转化体系, 对影响玉米胚性愈伤组织诱导的11个因素及影响胚性愈伤分化的9个因素用正交实验方法进行研究。结果显示, 基因型对胚性愈伤诱导有极显著影响。6-BA、培养基、AgNO3、2,4-D、ABA对胚性愈伤诱导的影响达到显著水平。多重比较分析显示ABA 2 mg/L每间隔1代添加对胚性愈伤诱导率有显著影响。在影响分化的因素中, 基因型和6-BA浓度表现出极强的主效应, NAA、培养基、KT、2,4-D对分化产生显著影响。Southern blotting 分析表明, 25 mg/L潮霉素选择压下抗性愈伤率作为转化体系优化指标是可靠的。在影响转化效率的因素中, acetosyringone (AS)使用浓度因基因型不同而表现出敏感度差异, 共培养温度24~25℃、农杆菌浓度和浸泡时间0.7 OD×15 min, 以及pH值5.5~6.2是最高转化率的优选组合。在整合后的玉米遗传转化体系中, 黄早4和综31自交系以抗性愈伤率为指标的GUS基因稳定转化率分别达到48.6%和46.2%。     

Ammonium Transformation in a Nitrogen-Rich Tidal Freshwater Marsh

The fate and transport of watershed-derived ammonium in a tidal freshwater marsh fringing the nutrient rich Scheldt River, Belgium, was quantified in a whole ecosystem ¹⁵N labeling experiment. In late summer (September) we added ¹⁵N-NH₄⁺ to the flood water entering a 3477 m² tidal freshwater marsh area, and traced the ammonium processing and retention in four subsequent tide cycles. In this paper we present the results for the water-phase components of the marsh system and compare them to a similar experiment conducted in spring/early summer (May). Changes in concentration and isotopic enrichment of NO₃⁻ + NO₂⁻, N₂O, N₂, NH₄⁺ and suspended particulate nitrogen (SPN) were measured in concert with a mass balance study. All analyzed N-pools were labeled, and 49% of the added ¹⁵NH₄⁺ was retained or transformed. The most important pool for ¹⁵N was nitrate, accounting for 17% of ¹⁵N-transformation. N₂, N₂O and SPN accounted for 2.4, 0.02 and 1.4%, respectively. The temporal and spatial patterns of ¹⁵N transformation in the water phase component of the system were remarkably similar to those observed in May, indicating good reproducibility of the whole ecosystem labeling approach, but the absolute ammonium transformation rate was 3 times higher in May. While the marsh surface area was crucial for nitrification in May this was less pronounced in September. Denitrification, on the other hand, appeared more important in September compared to May.     

Inheritance and expression of introduced DNA in transgenic onion plants (Allium cepa)

Transgenic onion plants (Allium cepa) containing the Cauliflower mosaic virus 35s promoter (CaMV35s) and gfp gene construct encoding the visual green fluorescent reporter protein from pBINm gfp ER and the CaMV35s‐bar gene construct encoding resistance to the herbicide phosphinothricin from pCAMBlA3301 were produced by Agrobacterium‐mediated transformation. These plants weregrown to maturity and selfed in order to determine the expression and inheritance of the transgenes. CaMV35s regulation in onion, as observed by GFP expression, was essentially constitutive, and profiles of regulation were typical of those observed in dicotyledonous plants. Inhibition of CaMV35s regulated gene expression was only observed in one transformant. Both the expression of GFP and tolerance to phosphinothricin appeared to be inherited in a Mendelian fashion. Levels of expression in F1 offspring varied, presumably due to environmental and genetic factors. However, it appeared that copy number did strongly influence GFP protein production and expression. In the majority of plants there were no obvious detrimental phenotypic effects caused by the transgene, the integration event, or Somaclonal variation due to the need to perform tissue culture.     

Bacterial translocation motors investigated by single molecule techniques

Translocation of DNA and protein fibers through narrow constrictions is a ubiquitous and crucial activity of bacterial cells. Bacteria use specialized machines to support macromolecular movement. A very important step toward a mechanistic understanding of these translocation machines is the characterization of their physical properties at the single molecule level. Recently, four bacterial transport processes have been characterized by nanomanipulation at the single molecule level, DNA translocation by FtsK and SpoIIIE, DNA import during transformation, and the related process of a type IV pilus retraction. With all four processes, the translocation rates, processivity, and stalling forces were remarkably high as compared with single molecule experiments with other molecular motors. Although substrates of all four processes proceed along a preferential direction of translocation, directionality has been shown to be controlled by distinct mechanisms.     

Ultrastructural changes in major organelles during spermatial differentiation inBangia (Rhodophyta)

Summary The major organelles within the cells of maleBangia atropurpurea (Roth) C. Ag. filaments undergo a series of ultrastructural transformations during the production of spermatia. Initially, thylakoids within the large axial chloroplast develop a reticulate pattern commencing at the central pyrenoid region. Subsequent changes involve loss of lobes and diminution of volume through division; chloroplasts in final stages contain a few dilated, distorted thylakoids and many plastoglobuli. During differentiation the large nucleolus disappears from the nucleus and four masses of chromatin aggregate near the nuclear envelope. Furrows originating from the nuclear envelope form double membranes around each of the chromatin masses and most of the nucleoplasm is eliminated. Several types of fibrillar vesicles are formed during the process and large floridean starch reserves are utilized. Multilamellar bodies and microbody-like structures occur within the cells during certain phases of spermatiogenesis.     

84K杨PagC3H3基因表达模式分析

木质素作为木材的主要组成成分,通常是由3种单体聚合而成,在其生物合成过程中,共有10个酶家族参与负责将苯丙胺酸转化为单体木质素,其中C3H是在对-香豆酰辅酶A（p-coumaroyl CoA）到咖啡酰辅酶A（caffeoyl CoA）的羟基化过程和G/S单体形成中的关键控制酶类,探究PagC3H3基因表达模式,对于进一步了解该基因功能具有重要意义。该研究通过定量PCR对PagC3H3基因的组织特异性表达进行分析;克隆得到了长度为2 035 bp的PagC3H3的启动子序列,预测含有多个顺式作用元件;同时,将获得的PagC3H3的启动子序列构建植物表达载体pBI121-PagC3H3pro：：GUS,进行拟南芥瞬时转化,结果显示PagC3H3基因在84K杨的根、中部茎节和基部茎节中的表达量较高;瞬时转化拟南芥,GUS染色表明：在下胚轴和根中GUS活性较强,由此推测PagC3H3基因在木质素合成过程中发挥作用。     

农杆菌介导的Pr基因对非洲菊遗传转化的研究

采用农杆菌介导法将Pr基因转入非洲菊(Gerbera hybrida),建立适合于农杆菌介导的基因遗传转化受体系统,获得再生植株。经PCR和GUS染色检测,Pr基因成功转入非洲菊幼苗。     

pFGC5941的改造及拟南芥NAC1和SIP1双基因反义表达载体的构建和遗传转化

拟南芥中的SIP1基因编码的蛋白与拟南芥盐胁迫应答中的关键蛋白SOS2存在互作关系,而NAC1为拟南芥中介导生长素信号促进其侧根发生的蛋白。本研究中我们将SIP1基因和NAC1正义基因以及SIP1基因和NAC1反义基因分别整合到一个经改造的具有2个35S启动子的可用于双基因表达的载体pFGC5941S中,构建了两个双基因表达载体pFGC5941S SIP1 NAC1 sense和pFGC5941S SIP1 NAC1 anti。并将这两个载体通过农杆菌介导的方法转化到野生型拟南芥中,共获得15株转基因植株。对这些转基因植株进行盐胁迫实验发现,在含75mmol·L-1 NaCl的MS培养基上,相比于野生型,pFGC5941S SIP1 NAC1 sense转基因植株主根增长,侧根数量明显增多,而pFGC5941S SIP1 NAC1 anti转基因植株长势与野生型苗相似。由此我们推测可能只有当SIP1和NAC1同时过表达时,才会促进盐胁迫下拟南芥侧根的发育。     

Efficient genome editing and gene knockout in Setaria viridis with CRISPR/Cas9 directed gene editing by the non-homologous end-joining pathway

The CRISPR/Cas9 system has been used for genome editing in several organisms, including higher plants. This system induces site-specific mutations in the genome based on the nucleotide sequence of engineered guide RNAs. The complex genomes of C4 grasses makes genome editing a challenge in key grass crops like maize (Zea mays), sorghum (Sorghum bicolor), Brachiaria spp., switchgrass (Panicum virgatum), and sugarcane (Saccharum spp.). Setaria viridis is a diploid C4 grass widely used as a model for these C4 crop plants. Here, an optimized CRISPR/Cas9 binary vector that exploits the non-homologous end joining (NHEJ) system was used to knockout a green fluorescent protein (gfp) transgene in S. viridis accession A10.1. Transformation of embryogenic callus by A. tumefaciens generated ten glufosinate-ammonium resistant transgenic events. In the T0 generation, 60% of the events were biallelic mutants in the gfp transgene with no detectable accumulation of GFP protein and without insertions or deletions in predicted off-target sites. The gfp mutations generated by CRISPR/Cas9 were stable and displayed Mendelian segregation in the T1 generation. Altogether, the system described here is a highly efficient genome editing system for S. viridis, an important model plant for functional genomics studies in C4 grasses. Also, this system is a potential tool for improvement of agronomic traits in C4 crop plants with complex genomes.     

玉竹生物活性成分C对小鼠免疫功能的影响

研究玉竹生物活性成分C对小鼠细胞免疫功能的影响,并探讨其作用机制.采用MTT比色法和CFSE检测小鼠淋巴细胞转化情况,流式细胞术检测对αβT和γδT细胞增殖及CD4+ αβT细胞/CD8+αβT细胞比值的影响,ELISA法检测脾细胞培养上清中Th1细胞因子IFN-γ和Th2细胞因子IL-4的分泌水平.结果显示,玉竹生物活性成分C在一定浓度范围内可促进小鼠脾αβT细胞增殖,其中以1 000μg/mL的浓度作用最强.1 000 μg/mL浓度的玉竹生物活性成分C具有降低CD4+ αβT细胞与CD8+ αβT细胞比值,提高CD8+αβT细胞教量的作用.1 000 μg/mL浓度的玉竹生物活性成分C能有效刺激小鼠脾淋巴细胞释放细胞因子IFN-γ,而对IL-4的产生没有明显的影响.本研究为开发玉竹生物活性成分C提供实验依据.