arabidopsis
美 
英
例句
Eight of these nine types were common between rice and Arabidopsis, whereas only one, known as F-type cycling, was unique to rice.
这九类中的八个是水稻和拟南芥所共有的,而只有一个,被称为F型细胞周期蛋白,是水稻所特有的。
The S gene of arabidopsis and other plants have been cloned and been shown to produce a glycoprotein with ribonuclease (RNase) activity.
拟南芥和其他植物的S基因已被克隆,并证明它的确合成具有核糖核酸酶(RNase)活性的糖蛋白。
For Arabidopsis, the experimental design necessary to assign flowering time mutants to a specific pathway is described.
描述了需要为拟南芥的一个特定通路分配开花时间突变体的实验设计。
Surprisingly, glutamine synthetase was recently shown to be dual targeted to chloroplasts and mitochondria in Arabidopsis leaves.
令人惊讶的是,谷氨酰胺合成酶最近被证明是双定位叶绿体和线粒体在拟南芥叶片。
The microRNA, miR164, has been implicated in aging in Arabidopsis and was part of a complex genetic chain that changed as leaves aged.
其中MIR164这个微RNA,在Arabidopsis的衰老进程中被确认是一个复杂遗传链条的部分,那链条随着树叶的衰老而变化。
A plant clock model has yet to be proposed, but clock mutants of Arabidopsis are expected to reveal key proteins in the mechanism.
植物时钟模式尚未提出,但时钟拟南芥突变体的预计显示关键蛋白质的机制。
This situation contrasts with that in Arabidopsis, where CLV signaling is the major single pathway in all meristems.
这种情况与拟南芥刚好相反,拟南芥中所有的分生组织都主要受CLV介导的唯一通路所调节。
Extensive documentation of the developmental morphology of Arabidopsis flowers has facilitated the linkage of genes and morphology.
大量文件的发展形态的拟南芥花了便利连锁的基因和形态。
The Arabidopsis floral organ identity gene AGAMOUS (AG) specifies stamen and carpel development as well as floral determinacy.
拟南芥花器官特征基因AGAMOUS(AG)的指定雄蕊和雌蕊发展以及花确定性。
Recently, a study of miRNAs isolated from Arabidopsis showed that here also developmental genes are putative regulatory targets.
最近,研究微RNA分离拟南芥表明,这里还发展基因假定监管目标。
The researchers did close examinations of the genomes of organisms ranging from yeast to fruit flies to the plant Arabidopsis to humans.
研究人员对从酵母菌、果蝇、拟南芥到人类的生物都作了仔细的实验。
The Arabidopsis root has emerged as a highly useful system for identifying and studying cell-expansion-related MAPs.
拟南芥根已经成为一个非常有用的系统,以确定和研究细胞的扩张有关的地图。
This paper mainly introduces the regulatory mechanism of flowering for dicots represented by Arabidopsis and monocots represented by rice.
本文首先阐述了以拟南芥为代表的双子叶植物和以水稻为代表的单子叶植物的开花调控机理及其异同。
The mustard plant Arabidopsis thaliana may be revealing another way in which life exploits RNA's capacity for genetic storage.
阿拉伯芥(Arabidopsisthaliana)这种植物,或许能透露生命利用RNA来储存遗传资讯的另一种方法。
The root hair of Arabidopsis has become a model system for investigations of the patterning and morphogenesis of cells in plants.
在拟南芥根毛已经成为了图案和植物细胞的形态调查模型系统。
Thus a detailed molecular framework for the regulation of flowering time has now been established in Arabidopsis.
因此,一个详细的分子框架调节开花时间现已确定拟南芥。
Cell fate determination in the Arabidopsis epidermis has been extensively studied for over a decade.
细胞命运的决心,以拟南芥表皮已被广泛研究了十多年。
The Arabidopsis genome sequence has given us an inventory of the genes needed to specify a flowering plant.
拟南芥基因组序列已经给我们所需要的指定开花植物的基因清单。
Chapter three talked about the identification and characterization of housekeeping genes in rice and Arabidopsis in the genomic level.
第三章讲述从全基因组水平去寻找和刻画水稻和拟南芥里的看家基因。
The methods in this chapter describe ways to access and utilize Arabidopsis data and genomic resources found in databases.
这一章的方法描述了访问并利用拟南芥数据及数据库中找到的基因组资源的方式。
In particular, lipid metabolism proteins (LMP) and encoding nucleic acids originating from Arabidopsis thaliana are provided.
特别地,提供了拟南芥来源的脂质代谢蛋白(LMP)及其编码核酸。
Fertility of the plants was affected in TO generation transgenic rice and Arabidopsis.
水稻和拟南芥的转化中均得到了转基因植株。
The molecular-characteristics and expression inhibition mechanism of FLC gene in Arabidopsis thaliana were introduced in detail.
介绍了拟南芥FLC基因的分子特征以及基因表达被抑制的分子机理及相关内容。
The invention discloses an aseptic water culture method applicable to Arabidopsis thaliana root system proteomics research.
本发明公开了一种适用于拟南芥根系蛋白质组学研究的无菌水培方法。
Cell Differentiation and Apoptosis Associated with Nectar Secreting during the Nectary Development of Arabidopsis Thaliana L .
蜜腺发育过程中细胞分化、凋亡与泌蜜的关系。
During the past 20 years, the flowering plant Arabidopsis thaliana has been adopted as a model organism by thousands of biologists.
在过去20年来,开花植物拟南芥已通过作为模式生物的数千名生物学家。
Efficient expression of bacterial haloalkane dehalogenase gene in Arabidopsis thaliana.
细菌卤代烷烃脱卤酶基因在拟南芥菜中的高效表达。
Arabidopsis thaliana exons, with 44% of guanine and cytosine base pairs, compared with the two bases within the intron content (32%) more.
拟南芥的外显子,含44%的鸟苷和胞嘧啶碱基,比内含子内这两种碱基的含量(32%)多。
Conserved PcG proteins control multiple aspects of Arabidopsis development and maintain homeotic gene repression.
保守盈科蛋白质控制多个方面的发展,保持拟南芥同源异型基因镇压。
Tissue, Total Protein, Plant Normal, Plant, Arabidopsis.
组织,总蛋白,正常植物拟南芥。
This chapter gives an overview of flowering time analysis, including protocols to measure flowering time in Arabidopsis and wheat.
这一章给出了开花时间分析的一个概述,包括在拟南芥和小麦中测量开花时间的实验方案。
At last, the genetic relationship between Brassica genera and Arabidopsis thaliana was summarized.
最后,文章对芸薹属不同基因组和拟南芥基因组之间的亲缘关系进行了综述。
Arabidopsis thaliana has a few more than us, and rice doubles the number.
拟南芥植物的基因数量比人类稍多,而水稻的基因数量则是人类的一倍。
Ancient genome duplication events have been identified in diverse organisms, such as yeast, vertebrates, and Arabidopsis.
古老的基因组加倍事件已经在多个物种中被确定,包括酵母,脊椎动物以及拟南芥等。
The experiments carried out on the model plant Arabidopsis can easily be adapted to other plants such as rice.
作为实验植物的Arabidopsis很容易与诸如水稻的其它植物相适应。
Stocks of T-DNA-tagged arabidopsis lines are now readily available for research.
用于研究的T-DNA标记的拟南芥品系的商品现在很容易买到。
The growth process of Arabidopsis seedlings has become a model system for researching photomorphogenic mechanism.
拟南芥幼苗生长过程已成为研究植物光信号转导到形态建成机制的模式系统。
Here, we review the transcriptome signatures associated with JA signalling in Arabidopsis thaliana and other plant species.
在这里,我们审查转录签名与茉莉信号拟南芥及其他植物物种。
The ARGOS gene in Arabidopsis plays a key role in controlling plant organ size.
拟南芥ARGOS基因在控制植物器官大小方面起到了重要作用。
CLAVATA signaling restricts stem cell identity in the shoot apical meristem (SAM) in Arabidopsis thaliana.
CLAVATA介导的信号传导通路控制拟南芥地上部顶端分生组织的干细胞属性。
