拟南芥室内培养技术

本文报道了室内培养拟南芥的一些简便易行的改进技术.采用我们改进的营养土、蛭石、素沙混合培养介质和直播方式培养拟南芥,并根据其生物学特性在温度、空气湿度、土壤水分和光照等方面给予适当管理,能培养出生长更健壮、更好地满足实验要求的拟南芥植株.此外还介绍了播种、浇水、生育期调节、种子保存、病虫害防治和防混杂等环节的一些技巧措施.与其他培养方法相比,此法不仅简便、效果好,而且适合较简易的培养条件.     

拟南芥在新疆干旱地区的室内栽种及遗传转化

目的：结合新疆夏季干燥炎热、干旱少雨,冬季严寒漫长,春秋季节短促的气候特点,栽种满足实验要求的拟南芥植株并建立有效的转基因体系。方法：对拟南芥生长培养基质、光照条件、湿度等方面进行改进,并利用农杆菌介导法对拟南芥进行功能基因的转化。结果：获得拟南芥生长适合的栽种条件：培养基质为蛭石：珍珠岩（3：1）,浇1／2MS营养液;光周期前4周8h光照;4周后16h光照;湿度为40％（60％,并通过基因转化获得了阳性植株。结论：为新疆地区以拟南芥开展转基因植物功能研究奠定了良好的研究基础。     

东北地区拟南芥室内栽培技术

结合东北地区气候特点摸索出一套适合拟南芥生长的室内栽培方法。采用土壤育苗法和基质育苗法培养拟南芥,并根据其生物学特性在温度、光照、肥水管理、病虫害防治等方面给予适当管理,能培养出生长健壮、满足实验要求的拟南芥植株,为拟南芥在东北地区种植提供参考资料。     

2-吗啉乙磺酸(MES)对拟南芥幼苗生长的影响

本实验研究0.05% MES对野生型拟南芥生长的影响。结果表明,含有MES的培养基pH变化较小,其培养10 d的拟南芥幼苗干重、鲜重、叶绿素含量和含水量均高于对照组,而叶片PAL和POD活性却低于对照组,说明MES通过影响培养基的pH变化促进拟南芥生长。     

不同培养条件对拟南芥根细胞膜片钳记录的影响

本文以沙培养法、蛭石培养法、土培养法、水培养法和MS培养基等不同的方法培养拟南芥(Arabidopsis thaliana),分析了不同培养方法对根生长发育的影响,并分别分离根的原生质体。在膜片钳记录中对不同来源的根原生质体状态进行了比较。结果表明,土培养法分离的原生质体最适于膜片钳记录。     

一种适于营养胁迫研究的拟南芥水培方法

水培法可通过更换营养液来控制根际营养成分,成为植物营养学研究的最佳培养方式。由于根际通气和微生物滋生等问题,拟南芥(Arabidopsis thaliana)的水培技术始终无法被广泛应用。该文利用Eppendorf离心管管盖和离心管盒,将拟南芥种子在琼脂上萌发和植株水培有机结合,通过控制营养液用量和液体深度,增加营养液表面积,解决了水培过程中根系通气问题。利用离心管管盖作为支撑材料,降低了琼脂水分蒸发,并减少琼脂的用量和厚度,从而实现琼脂和营养液的快速平衡,为拟南芥培养和营养胁迫研究提供了一个简单且经济的水培方法。     

拟南芥蛋白质组研究中双向电泳技术条件的优化

双向电泳技术是蛋白质组学研究中的关键技术,是目前分辨率最高的工具之一.而提高双向电泳图蛋白质点的数目和分辨率,可以提高蛋白质组技术平台的信息完整性.通过对拟南芥双向电泳技术过程中的适当改进,如蛋白质的提取与溶解方法、上样量和聚丙烯酰胺凝胶浓度,加入硫脲,硫代硫酸钠等,对拟南芥双向电泳技术进行了优化,提高了双向电泳图谱的蛋白质点数目与分辨率.     

拟南芥六个新的small RNAs 的克隆和功能预测

以模式植物拟南芥为例, 建立了一种克隆small RNA 分子的技术平台, 为今后开展small RNA 分子的生物学功能研究提供技术支撑。通过用抗病信号分子水杨酸(SA) 处理拟南芥叶片后, 进行small RNA 分子群体的分离与接头连接、PCR 扩增、T - 载体克隆与检测、测序分析和生物信息学分析等一系列实验, 成功地克隆了一些small RNAs, 并对其表达和功能进行了分析。     

不同培养条件对拟南芥根细胞膜片钳记录的影响

本文以沙培养法、蛭石培养法、土培养法、水培养法和MS培养基等不同的方法培养拟南芥(Arabidopsis thaliana),分析了不同培养方法对根生长发育的影响,并分别分离根的原生质体.在膜片钳记录中对不同来源的根原生质体状态进行了比较.结果表明,土培养法分离的原生质体最适于膜片钳记录.     

拟南芥GH3.9基因的过表达及其表型分析

为研究GH3.9基因在植物生长发育过程中的作用,利用RT-PCR成功克隆到GH3.9基因,该基因全长为1 750bp。通过构建pEGAD-GH3.9过表达载体转化拟南芥,获得过表达GH3.9基因纯系转基因株系GH3.9ox-3和GH3.9ox-7。对拟南芥野生型(WT)和转基因株系(GH3.9ox-3和GH3.9ox-7)幼苗用不同光强和光质进行处理,结果显示:在蓝光、红光、远红光等不同光照强度下培养,过表达株系幼苗下胚轴的生长均明显受到抑制,且较野生型明显;采用不同光周期处理拟南芥幼苗,过表达幼苗下胚轴的伸长明显低于野生型;对成年植株表型进行观察,发现过表达株系植株矮小、雄蕊变短、果荚短小。研究表明:GH3.9基因参与了拟南芥生长发育调控,过表达GH3.9基因对拟南芥生长有抑制作用。     

植物耐盐相关基因：SOS基因家族研究进展

土壤盐渍化是影响农业生产和生态环境的一个非常重要的非生物胁迫因素,也是现代生物科学迫切需要解决的问题。利用拟南芥研究植物耐盐相关基因成为该领域的研究热点。几年来,该领域研究成果斐然。本文就SOS基因家族的三个耐盐基因SOS1、SOS2和SOS3的克隆、功能及相互关系作一概要的评述。 Abstract:The soil salination is a significant abiotic stress for agricultural production and ecological environment. The research on salt tolerance represents an important part for basic plant biology. Genetic analysis of salt tolerance genes in Arabidopsis has become a central issue in this research areas. In recent years, efforts from some laboratories in the world have led to some significant progresses in this field. In this paper, we will review the progress in salt tolerance genes SOS(salt overly sensitive):SOS1,SOS2 and SOS3.     

Morphological and physiological traits of three major Arabidopsis thaliana accessions

Arabidopsis is currently the most studied organism in plant biology. Its short life cycle and small genome size have rendered it one of the principal model systems. Additionally, numerous large T-DNA insertion mutant collections are available. The advent of molecular biology and the completion of the Arabidopsis genome sequence have contributed to helping researchers discover a large variety of mutants identified for their phenotypes. Yet, it is important to consider that natural phenotypic variations exist and appear in natural ecotypes, differing greatly in several traits. Although there are a vast number of ecotypes available, only a few have been extensively studied, and some have been created in laboratories. In order to identify new phenotypic differences, we chose to study the differences observed between three ecotypes: Columbia (Col-0), Landsberg erecta (Laer-0) and Wassilewskija (Ws-0). Our research focuses on observable morphological traits throughout plant growth and development along the entire plant life cycle. We then attempted to shed some light on phenotypic discrepancies through the study of the class III peroxidase protein family, which is involved in many aspects of plant growth and tissue differentiation. Both morphological and molecular aspects reveal that there are major variations between ecotypes, hence indicating a possibly interesting heterotic effect in the F1 from crosses between different Arabidopsis ecotypes.     

DC research in Australia

Australian researchers have contributed significantly to the understanding of DC biology and clinical application over the past 25 years. Active DC research programs are in place in all major centers, pursuing the key questions of DC phylogeny, physiology and clinical applicability. Pre-clinical and clinical research include the pathophysiology of DC in malignancy, autoimmunity, chronic viral infection, chronic renal failure and transplantation medicine. In addition, Australian laboratories have uncovered some of the subtle complexities of DC subsets, often utilizing novel investigational tools discovered in their laboratories. Above all, Australian DC research has benefited from the existence of a potent culture of active collaboration, which has led to key interactions between cellular immunologists, clinician scientists and clinical researchers. These collaborations have led to the emergence of DC research programs that extend from in vitro and animal models of DC biology through each step of clinical translation and into active clinical trials.     

基因芯片技术在拟南芥研究中的应用

基因芯片是研究生物大分子功能的新技术,目前此技术已经广泛地应用到植物研究中。拟南芥是植物分子生物学领域的模式植物,通过对其基因结构及功能的详尽研究,可以更好地理解和认识遗传上更为复杂的高等植物的生长和发育过程。本综述了基因芯片在模式植物拟南芥研究中的应用。     

In vitro Cell Migration and Invasion Assays

Migration is a key property of live cells and critical for normal development, immune response, and disease processes such as cancer metastasis and inflammation. Methods to examine cell migration are very useful and important for a wide range of biomedical research such as cancer biology, immunology, vascular biology, cell biology and developmental biology. Here we use tumor cell migration and invasion as an example and describe two related assays to illustrate the commonly used, easily accessible methods to measure these processes. The first method is the cell culture wound closure assay in which a scratch is generated on a confluent cell monolayer. The speed of wound closure and cell migration can be quantified by taking snapshot pictures with a regular inverted microscope at several time intervals. More detailed cell migratory behavior can be documented using the time-lapse microscopy system. The second method described in this paper is the transwell cell migration and invasion assay that measures the capacity of cell motility and invasiveness toward a chemo-attractant gradient. It is our goal to describe these methods in a highly accessible manner so that the procedures can be successfully performed in research laboratories even just with basic cell biology setup.     

Chlamydomonas and Arabidopsis. A dynamic duo

A translational biology perspective on Chlamydomonas and Arabidopsis might be expected to focus on those genes, cellular components, or biological processes found first in Chlamydomonas and subsequently studied in Arabidopsis. There are indeed many such examples. There are also examples that flow from Arabidopsis to Chlamydomonas in terms of initial discovery and subsequent study. However, the differences can also be illuminating. In this brief essay, we make a case for the pairing of Chlamydomonas and Arabidopsis as model organisms that bracket a major subset of photosynthetic eukaryotes, the green plants (Mishler, 2000). By analogy with the yeast-mouse dyad, this green pair has tremendous potential as we enter an era of renewed interest in comparative biology.     

Results and recommendations

In the first phase of a collaborative study by the International Programme on Chemical Safety (PRCS), four coded chemicals, i.e. azidoglycerol (AG, 3-azido-1,2-propanediol), methyl nitrosurea (MNU), sodium azide (NaN₃) and maleic hydrazide (MH), and ethyl methanesulfonate (EMS) as a positive control were tested in four plant bioassays, namely the Arabidopsis embryo and chlorophyll mutation assay, the Tradescantia stamen hair assay (Trad-SH assay), the Tradescantia micronucleus assay (Trade-MCN), and the Vicia faba root tip assay. Seventeen laboratories from diverse regions of the world participated with four to six laboratories each using one plant assay. For the Arabidopsis assay, laboratories were in agreement with MNU and AG giving positive responses and NaN₃ giving a negative response. With the exception of one laboratory which reported MH as weakly mutagenic, no mutagenic response was reported for MH by the other laboratories. For the Vicia faba assay, all laboratories reported a positive response for MNU, AG, and MH, whereas two of the six laboratories reported a negative response for NaN₃. For the Trad-SH assay, MH was reported as giving a positive response and a positive response was also observed for MNU with the exception of one laboratory. NaN₃, which exhibited a relatively high degree of toxicity, elicited a positive response in three of the five laboratories. AG was found positive in only one of the two laboratories which tested this chemical. For the Trad-MCN assay, MNU and MH were reported as positive by all laboratories, while four out of five laboratories reported NaN₃ to be positive. Only one of three laboratories reported AG to be positive. The major sources of variability were identified and considered to be in the same range as found in similar studies on other test systems. Recommendations were made for minor changes in methodology and for initiating the second phase of this study.