subcellular
简明释义
英[sʌbˈseljʊlə(r)]美[sʌbˈseljələr]
adj. 亚细胞的
英英释义
与细胞或其组成部分相关或发生的。 |
单词用法
亚细胞定位 | |
亚细胞区室 | |
亚细胞结构 | |
亚细胞分析 | |
亚细胞分级 | |
亚细胞靶向 |
同义词
| 细胞内的 | Intracellular signaling pathways are crucial for cellular communication. | 细胞内信号传导通路对细胞间的交流至关重要。 | |
| 细胞器的 | Organellar functions are essential for maintaining cellular homeostasis. | 细胞器的功能对于维持细胞的稳态是必不可少的。 |
反义词
例句
1.Objective: To study the subcellular photodamage sites of hematoprophyrin monomethyl ether (HMME) PDT in murine lung endothelial cells applying fluorescence probes.
目的:应用荧光探针在光动力疗法研究中检测亚细胞损伤位点。
2.BACKGROUND: Subcellular localization information is one of the key features to protein function research.
背景:亚细胞定位信息是蛋白质功能研究的关键特征之一。
3.Protein subcellular localization is one of the key questions for functional genomics.
植物蛋白质的亚细胞定位是功能基因组学的重要内容。
4.Ischemia preadaptation can evidently reduce subcellular structure injury.
缺血预适应可明显改善亚细胞结构损害。
5.The third chapter gives the prediction of protein subcellular location.
第三章为蛋白质亚细胞定位的预测。
6.We report experiments on two data sets, predicting subcellular localizations and remote homology detections.
我们在关于蛋白质亚细胞定位和远同源性检测的两个不同的数据集上做了实验。
7.Other tools and techniques are now making it possible to dissect these subcellular structures into the molecules and atoms.
其他工艺和技术,现在能使我们剖视这些亚细胞结构达到组成它们的分子和原子的水平。
8.Researchers used advanced imaging techniques to visualize subcellular components in live cells.
研究人员使用先进的成像技术来可视化活细胞中的亚细胞成分。
9.The study focused on the subcellular structures of the cell, revealing new insights into cellular functions.
该研究专注于细胞的亚细胞结构,揭示了细胞功能的新见解。
10.The subcellular analysis revealed that the mitochondria were dysfunctional in the diseased cells.
该亚细胞分析显示,线粒体在病变细胞中功能失常。
11.In this experiment, we analyzed the subcellular distribution of organelles.
在这个实验中,我们分析了细胞器的亚细胞分布。
12.The subcellular localization of proteins is crucial for understanding their function.
蛋白质的亚细胞定位对于理解其功能至关重要。
作文
The study of biology often delves into various levels of organization, from the entire organism down to the smallest units of life. One crucial aspect of this hierarchy is the examination of subcellular structures, which refers to components within a cell that play vital roles in its function and overall health. Understanding these subcellular elements is essential for comprehending how cells operate and interact with their environment.At the subcellular level, we find a variety of organelles, each with specific functions. For instance, mitochondria are known as the powerhouses of the cell, converting nutrients into energy through the process of cellular respiration. Similarly, the endoplasmic reticulum is involved in protein synthesis and lipid production, highlighting the intricate processes that occur within the subcellular framework of a cell.Moreover, the study of subcellular structures is not limited to just organelles. It also includes the examination of macromolecules such as proteins, nucleic acids, and lipids, which are fundamental to cellular processes. These molecules interact in complex ways, influencing everything from gene expression to metabolic pathways. By investigating these subcellular components, scientists can gain insights into the mechanisms of diseases, the effects of drugs, and the potential for new therapeutic approaches.In recent years, advancements in technology have allowed researchers to visualize subcellular structures with unprecedented clarity. Techniques such as electron microscopy and fluorescence microscopy enable scientists to observe the dynamic nature of cells at the subcellular level. This has led to significant discoveries, including the identification of new organelles and the understanding of their roles in cellular health and disease.Furthermore, the field of synthetic biology is increasingly focused on manipulating subcellular components to create novel biological systems. By engineering specific organelles or pathways, researchers aim to design cells that can perform new functions, such as producing biofuels or pharmaceuticals. This intersection of biology and engineering showcases the importance of subcellular studies in driving innovation and addressing global challenges.In conclusion, the exploration of subcellular structures is a vital aspect of biological research that deepens our understanding of life at its most fundamental level. From organelles to macromolecules, each subcellular component plays a unique role in maintaining cellular function. As technology continues to advance, the potential for breakthroughs in our comprehension of subcellular dynamics grows, paving the way for new discoveries that could transform medicine and biotechnology. Thus, the significance of subcellular studies cannot be overstated; they are essential for unlocking the mysteries of life itself.
生物学的研究通常深入探讨不同的组织层次,从整个有机体到生命中最小的单位。其中一个关键方面是对亚细胞结构的研究,这指的是细胞内具有重要功能和整体健康的组成部分。理解这些亚细胞元素对于理解细胞如何运作以及与其环境相互作用至关重要。在亚细胞水平,我们发现各种细胞器,每个细胞器都有特定的功能。例如,线粒体被称为细胞的动力源,通过细胞呼吸过程将营养物质转化为能量。同样,内质网参与蛋白质合成和脂质生产,突显了在细胞的亚细胞框架内发生的复杂过程。此外,亚细胞结构的研究不仅限于细胞器。它还包括对大分子的检查,如蛋白质、核酸和脂质,这些都是细胞过程的基础。这些分子以复杂的方式相互作用,影响从基因表达到代谢途径的方方面面。通过研究这些亚细胞组件,科学家可以深入了解疾病机制、药物影响以及新的治疗方法的潜力。近年来,技术的进步使研究人员能够以前所未有的清晰度可视化亚细胞结构。电子显微镜和荧光显微镜等技术使科学家能够观察细胞在亚细胞水平上的动态特性。这导致了重大发现,包括新细胞器的识别及其在细胞健康和疾病中的作用的理解。此外,合成生物学领域越来越关注操纵亚细胞组件以创建新型生物系统。通过工程化特定的细胞器或途径,研究人员旨在设计能够执行新功能的细胞,例如生产生物燃料或药物。这种生物学与工程学的交叉展示了亚细胞研究在推动创新和应对全球挑战中的重要性。总之,对亚细胞结构的探索是生物研究的重要方面,加深了我们对生命最基本层面的理解。从细胞器到大分子,每个亚细胞组件在维持细胞功能中发挥着独特的作用。随着技术的不断进步,我们对亚细胞动态的理解潜力不断增加,为可能改变医学和生物技术的新发现铺平了道路。因此,亚细胞研究的重要性不容小觑;它们对于揭示生命本身的奥秘至关重要。
