影响T-DNA转移的寄主植物细胞因子

在农杆菌介导的植物遗传转化过程中,寄主细胞因子参与农杆菌细胞与寄主细胞的识别与附着、毒性基因的表达以及T-DNA的跨膜运输和整合等过程.文章就这几方面的研究进展进行了综述.     

Cell Surface Proteins of Agrobactevium tumefaciens Involved in the Transfer of T-DNA to the Host

We investigated the taste synergy between L-theanine and the flavour enhancer, inosine 5′-monophosphate (IMP), by using a human sensory evaluation. When L-theanine was added to IMP, only the umami taste was enhanced. We then investigated this synergistic effect of L-theanine in mice by gustatory nerve recording. We confirmed the synergism between L-theanine and IMP for the umami taste.     

T-DNA转移研究进展

植物遗传转化技术近年在农作物性状改良、植物生物反应器利用以及基因功能鉴定等方面得到了广泛的应用.T-DNA转移是植物细胞农杆菌介导遗传转化整合和表达外源基因的基础.农杆菌Ti质粒vir基因编码蛋白、农杆菌一些染色体基因编码蛋白及植物细胞一些基因编码蛋白或因子均参与T-DNA转移.转移过程包括农杆菌对植物细胞的识别、附着,细菌对植物信号物质的感受,细菌vir基因的诱导表达,T复合体的形成,跨膜运输,进核运输和整合等一序列过程.植物细胞因子与农杆菌T-DNA转移相关蛋白的相互作用最近被认为在T-DNA转移过程中起重要作用.     

T-DNA Integration Category and Mechanism in Rice Genome

T-DNA integration is a key step in the process of plant transformation, which is proven to be important for analyzing T-DNA integration mechanism. The structures of T-DNA right borders inserted into the rice (Oryza sativa L.) genome and their flanking sequences were analyzed. It was found that the integrated ends of the T-DNA right border occurred mainly on five nucleotides “TGACA” in inverse repeat (IR) sequence of 25 bp, especially on the third base “A”. However, the integrated ends would sometimes lie inward of the IR sequence, which caused the IR sequence to be lost completely. Sometimes the right integrated ends appeared on the vector sequences rightward of the T-DNA right border, which made the T-DNA, carrying vector sequences, integrated into the rice genome. These results seemingly suggest that the IR sequence of the right border plays an important role in the process of T-DNA integration into the rice genome, but is not an essential element. The appearance of vector sequences neighboring the T-DNA right border suggested that before being transferred into the plant cell from Agrobacterium, the entire T-DNA possibly began from the left border in synthesis and then read through at the right border. Several nucleotides in the T-DNA right border homologous with plant DNA and filler DNAs were frequently discovered in the integrated position of T-DNA. Some small regions in the fight border could match with the plant sequence, or form better matches, accompanied by the occurrence of filler DNA, through mutual twisting, and then the T-DNA was integrated into plant chromosome through a partially homologous recombination mechanism. The appearance of filler DNA would facilitate T-DNA integration. The fragments flanking the T-DNA fight border in transformed rice plants could derive from different parts of the inner T-DNA region; that is, disruption and recombination could occur at arbitrary positions in the entire T-DNA, in which the homologous area was comparatively easier to be disrupted. The structure of flanking sequences of T-DNA integrated in the rice chromosome presented various complexities. These complexities were probably a result of different patterns of recombination in the integrating process. Some types of possible integrating mechanism are detailed.     

Integration of Grafted Neural Progenitor Cells in a Host Hippocampal Circuitry after Ischemic Injury

The induction of development of neurons and glial cells from neural progenitor cells (NPCs) is at present considered a promising strategy for recoverу after ischemic insult-evoked damage to the brain. To estimate whether grafted NPCs can develop morphological properties of the mature neurons and become functionally integrated within a host hippocampal circuitry, immunohistochemical approaches at the light and electron microscopy levels have been used. Ischemic insult in FVB-strain mice was evoked by 20-min-long occlusion of both carotid arteries. One day after occlusion, NPCs from GFP-transgenic fetuses were suboccipitally transplanted into the ischemic brain. We found that 44.7 ± 3.8% (mean ± s.e.m) of the grafted GFP-positive cells differentiated 3 months after transplantation into cells demonstrating morphological features of hippocampal pyramidal neurons. Moreover, grafted cells demonstrated manifestations of rather intense formation of the synapses between host and donor neural cells. Thus, our observations show that the NPC-based transplantation approach may be promising in the treatmen t of ischemic insult.     

转基因植物中T-DNA整合的分子特征及表达

植物中不同转基因方法转化外源基因的T-DNA整合特征既具有共性,又具有特性,使得转基因的遗传在各独立转化体间呈现多样性,另外多种遗传因子和限制因素使受体植物中外源基因的表达存在下降,甚至出现基因沉默等复杂现象。本文主要对农杆菌介导及裸露DNA直接转化转基因植物中T-DNA的分子特征和转基因表达的影响因子进行了介绍和概述。转化体中转基因的遗传稳定性和表达主要取决于转基因在植物基因组中的整合位置、拷贝数及组成结构。因而,通过对具有表达水平各异的转化体进行深入的遗传分析和分子生物学研究以及转化体之间进行的比较研究,将对转基因技术自身的完善、定点整合以及更有效的利用转基因技术都具有十分重要的意义。     

Agrobacterium May Delay Plant Nonhomologous End-Joining DNA Repair via XRCC4 to Favor T-DNA Integration

Agrobacterium tumefaciens is a soilborne pathogen that causes crown gall disease in many dicotyledonous plants by transfer of a portion of its tumor-inducing plasmid (T-DNA) into the plant genome. Several plant factors that play a role in Agrobacterium attachment to plant cells and transport of T-DNA to the nucleus have been identified, but the T-DNA integration step during transformation is poorly understood and has been proposed to occur via nonhomologous end-joining (NHEJ)–mediated double-strand DNA break (DSB) repair. Here, we report a negative role of X-RAY CROSS COMPLEMENTATION GROUP4 (XRCC4), one of the key proteins required for NHEJ, in Agrobacterium T-DNA integration. Downregulation of XRCC4 in Arabidopsis and Nicotiana benthamiana increased stable transformation due to increased T-DNA integration. Overexpression of XRCC4 in Arabidopsis decreased stable transformation due to decreased T-DNA integration. Interestingly, XRCC4 directly interacted with Agrobacterium protein VirE2 in a yeast two-hybrid system and in planta. VirE2-expressing Arabidopsis plants were more susceptible to the DNA damaging chemical bleomycin and showed increased stable transformation. We hypothesize that VirE2 titrates or excludes active XRCC4 protein available for DSB repair, thus delaying the closure of DSBs in the chromosome, providing greater opportunity for T-DNA to integrate.     

T-DNA转移及整合的分子机制研究进展

农杆菌介导的外源基因转化是目前植物转基因应用比较广泛的方法。近年来关于农杆菌介导的整合机制的研究已经取得了很大的进步。研究表明,在VirD2和VirE2协助下,农杆菌转移T-DNA进入植物细胞,这两种蛋白共同协助T-DNA完成转移、核定位及在植物基因组中的整合。近年来关于拟南芥突变体的研究表明,被转化植物的宿主基因在T-DNA转移及整合过程中发挥主要的作用。通过对现有研究成果详细讨论了Vir’蛋白(VirD2和VirE2)及植物基因在农杆菌介导植物转化中的作用,详细讨论了依靠VirD2蛋白和SDSA(synthesis-dependent strand-annealing)整合的两类不同的整合模式,根据最新的研究成果阐述了以基因组的双链断裂修复为基础的整合模型,并提出新的观点。     

Transfer of T-DNA from Agrobacterium to the plant cell.

Agrobacterium tumefaciens is the causative agent of crown gall, a disease of dicotyledonous plants characterized by a tumorous phenotype. Earlier in this century, scientific interest in A. tumefaciens was based on the possibility that the study of plant tumors might reveal mechanisms that were also operating in animal neoplasia. In the recent past, the tumorous growth was shown to result from the expression of genes coded for by a DNA segment of bacterial origin that was transferred and became stably integrated into the plant genome. This initial molecular characterization of the infection process suggested that Agrobacterium might be used to deliver genetic material into plants. The potential to genetically engineer plants generated renewed interest in the study of A. tumefaciens. In this review, we concentrate on the most recent advances in the study of Agrobacterium-mediated gene transfer, its relationship to conjugation, DNA processing and transport, and nuclear targeting. In the following discussion, references for earlier work can be found in more comprehensive reviews (Hooykaas and Schilperoort, 1992; Zambryski, 1992; Hooykaas and Beijersbergen, 1994).     

Host and T-DNA determinants of cytokinin autonomy in tobacco cells transformed byAgrobacterium tumefaciens

The hormone autonomy of tobacco (Nicotiana tabacum L.) cells transformed byAgrobacterium tumefaciens containing mutations attmr (the “rooty” locus) of the pTiT37 plasmid has been examined. These cells require cytokinin, but not auxin for continuous growth in culture, indicating that the function of thetmr locus is to specify or induce cytokinin autonomy. Examination of tissues from plants regenerated from cells transformed by the mutant bacteria showed that the auxin independent phenotype is suppressed, but can be reinitiated in culture by exposure to an exogenous supply of auxin. In addition the developmental state of the cells from such regenerated plants can exert a profound influence on their cytokinin autonomy phenotype.     

T-DNA插入突变在植物功能基因组学中的应用

T-DNA插入突变在植物功能基因组学研究中发挥着重要作用,广泛应用于大规模植物基因功能分析,是分离新基因、研究基因功能的有效工具。我们简单介绍了T-DNA插入突变的原理,详细论述了3种T-DNA插入突变载体的应用,并综述了利用T-DNA插入突变克隆新基因的方法,同时指出了T-DNA插入突变存在的问题及其发展方向。     

Molecular Structure and Regulatory Potential of a T-DNA Integration Site in Petunia

The genomic structure surrounding a T-DNA integration site in a transgenic petunia plant, which shows deregulation of a root-specific promoter, was investigated. We have already demonstrated that T-DNA integration in this transformant (P13) had occurred close to a scaffold/matrix attachment region (S/MAR). A major question regarding the observed promoter leakiness was whether the T-DNA had integrated into the centre or at the border of the Petun-SAR and whether other regulatory elements are located within this genomic region. While small rearrangements were shown to occur during T-DNA integration in agreement with other reports, we find indications of the presence of a SINE retroposon – an apparent landmark for recombinogenic targets – at the integration site. Binding assays to both plant and animal nuclear scaffolds, supported by biomathematical analyses, reveal that the T-DNA is definitely located at the border of a strong S/MAR, which is in agreement with current models on the structure of integration sites. These results, together with a developmentally regulated leaf-specific enhancer effect of the Petun-SAR on gene expression in transgenic tobacco plants, indicate that the Petun-SAR demarcates the right border of a chromatin domain with genes predominantly active in leaves.     

转Xa21基因水稻中T-DNA整合的遗传定位

利用转抗白叶枯病基因Xa21的水稻材料,通过TAIL－PCR方法扩增T－DNA整合的侧翼序列。从中筛选属于水稻基因组DNA的T－DNA整合的侧翼序列作为探针,将外源基因整合位点定位到窄叶青／京系17DH群体构建的水稻分子连锁图谱上。共获得属于水稻基因组DNA的T－DNA侧翼序列22个,其中的19个序列在定位群体的两个亲本之间显示RFLP多态性,分别定位在水稻基因组的第3,4,5,7,9,10,11和12染色体上。带有转基因Xa21的T－DNA整合的定位为研究外源基因在不同染色体位点的位置效应和稳定遗传打下基础。     

Cryptococcal Cell Morphology Affects Host Cell Interactions and Pathogenicity

Cryptococcus neoformans is a common life-threatening human fungal pathogen. The size of cryptococcal cells is typically 5 to 10 µm. Cell enlargement was observed in vivo, producing cells up to 100 µm. These morphological changes in cell size affected pathogenicity via reducing phagocytosis by host mononuclear cells, increasing resistance to oxidative and nitrosative stress, and correlated with reduced penetration of the central nervous system. Cell enlargement was stimulated by coinfection with strains of opposite mating type, and ste3 a Δ pheromone receptor mutant strains had reduced cell enlargement. Finally, analysis of DNA content in this novel cell type revealed that these enlarged cells were polyploid, uninucleate, and produced daughter cells in vivo. These results describe a novel mechanism by which C. neoformans evades host phagocytosis to allow survival of a subset of the population at early stages of infection. Thus, morphological changes play unique and specialized roles during infection.     

Early Events in Parvovirus Replication: Lack of Integration by Minute Virus of Mice into Host Cell DNA

Viral DNA sequences were not detected in high-molecular-weight host DNA until well after the onset of viral DNA replication.     

Integration,expression and inheritance of two linked T-DNA marker genes in transgenic lettuce

T-DNA integration and stability were assessed in Agrobacterium-derived transgenic lettuce lines carrying a chimaeric CaMV 35S promoter-driven gus-intron gene and a chimaeric nos.nptII.nos gene. T-DNA integration was predominantly complex in transgenic plants derived from an A. tumefaciens strain carrying the supervirulent plasmid ToK47. Truncation of the right side of the T-DNA was observed in first seed generation R₁ plants from one line. Complex T-DNA integration patterns did not always correlate with low transgene expression. Despite a high T-DNA copy number, ca. 30% of the lines analysed showed high transgene expression in the R₁ generation. High transgene expression was stable at least to the R₄ seed generation in selected high-expressing lines. Transgene expression was lost in the R₂ generation in a low expressing line, while complete, heritable transgene silencing from the R₀ to R₂ generations was also observed in another line. A 50-fold variation in -glucuronidase (GUS) activity and a 16-fold variation in NPTII protein content were observed between R₁ plants derived from different R₀ parents. Reactivation of transgene expression with 5-azacytidine in partially silenced lines indicated that low expression was associated with DNA methylation.