flavoprotein
简明释义
英[ˌfleɪvəʊˈprəʊtiːn]美[ˌfleɪvoʊˈproʊtiːn]
n. [生化] 黄素蛋白
英英释义
单词用法
依赖于黄素蛋白的 | |
黄素蛋白代谢 | |
黄素蛋白酶 | |
黄素蛋白合成 | |
黄素蛋白结构 | |
黄素蛋白功能 | |
黄素蛋白活性 | |
黄素蛋白家族 |
同义词
反义词
| 非黄素蛋白 | Non-flavoprotein enzymes do not contain flavin as a cofactor. | 非黄素蛋白酶不含有黄素作为辅因子。 | |
| 简单蛋白 | Simple proteins are composed only of amino acids without any cofactors. | 简单蛋白仅由氨基酸组成,没有任何辅因子。 |
例句
1.An example of a flavoprotein undergoing a one-electron transfer is with the microsomal NADPH-cytochrome P450 reductase.
的一个经历一个单电子转移黄素蛋白的例子是与微粒NADPH-细胞色素P 450还原酶。
2.An example of a flavoprotein undergoing a one-electron transfer is with the microsomal NADPH-cytochrome P450 reductase.
的一个经历一个单电子转移黄素蛋白的例子是与微粒NADPH-细胞色素P 450还原酶。
3.In plants, flavoproteins are involved in the process of photosynthesis.
在植物中,黄素蛋白参与光合作用的过程。
4.Some flavoproteins act as antioxidants, protecting cells from oxidative stress.
一些黄素蛋白作为抗氧化剂,保护细胞免受氧化应激的影响。
5.The enzyme lactate dehydrogenase is a type of flavoprotein that plays a crucial role in anaerobic respiration.
乳酸脱氢酶是一种类型的黄素蛋白,在厌氧呼吸中发挥着至关重要的作用。
6.Researchers have discovered that certain flavoproteins can help in the treatment of metabolic disorders.
研究人员发现某些黄素蛋白可以帮助治疗代谢紊乱。
7.The presence of flavoproteins in the mitochondria is essential for cellular energy production.
线粒体中存在的黄素蛋白对细胞能量产生至关重要。
作文
Flavoproteins are a fascinating class of proteins that play crucial roles in various biological processes. These proteins are characterized by their ability to bind flavin, a type of vitamin B2 derivative, which is essential for their function. The presence of flavin in these proteins gives them their name, as 'flavo' refers to the yellow color associated with flavin compounds. In this essay, I will discuss the significance of flavoprotein (黄素蛋白) in cellular respiration, metabolism, and their potential applications in biotechnology.One of the most important functions of flavoprotein (黄素蛋白) is in cellular respiration. They are involved in electron transport chains, which are critical for the production of adenosine triphosphate (ATP), the energy currency of the cell. For instance, succinate dehydrogenase, a well-known flavoprotein (黄素蛋白), plays a vital role in the citric acid cycle by facilitating the conversion of succinate to fumarate while transferring electrons to the electron transport chain. This process not only generates ATP but also contributes to the overall efficiency of cellular respiration.In addition to their role in energy production, flavoprotein (黄素蛋白) is also involved in various metabolic pathways. They participate in the oxidation-reduction reactions that are necessary for the metabolism of carbohydrates, fats, and proteins. For example, flavoprotein (黄素蛋白) such as acyl-CoA dehydrogenase is essential for the beta-oxidation of fatty acids, a process that breaks down fatty acids to produce energy. This highlights the importance of flavoprotein (黄素蛋白) in maintaining metabolic homeostasis and supporting the energy needs of the organism.Moreover, flavoprotein (黄素蛋白) has garnered attention in the field of biotechnology due to its unique properties. Researchers have been exploring the use of flavoprotein (黄素蛋白) in various applications, including biosensors and biocatalysis. The ability of these proteins to catalyze specific reactions under mild conditions makes them attractive candidates for industrial processes. For instance, flavoprotein (黄素蛋白) can be utilized in the development of biosensors for detecting environmental pollutants or food contaminants, providing a more sustainable approach to monitoring and ensuring safety.Furthermore, the study of flavoprotein (黄素蛋白) has implications for understanding human health. Deficiencies in certain flavoprotein (黄素蛋白) can lead to metabolic disorders, highlighting their importance in nutrition and health. Additionally, research into the therapeutic potential of flavoprotein (黄素蛋白) has opened new avenues for drug development, particularly in targeting diseases related to mitochondrial dysfunction.In conclusion, flavoprotein (黄素蛋白) is an essential component of many biological systems, playing key roles in energy production and metabolism. Their unique properties make them valuable in both scientific research and practical applications in biotechnology. As we continue to explore the functions and potential of flavoprotein (黄素蛋白), we may uncover new insights that could benefit various fields, from medicine to environmental science. Understanding and harnessing the power of flavoprotein (黄素蛋白) will undoubtedly contribute to advancements in health and technology in the future.
黄素蛋白是一类迷人的蛋白质,在各种生物过程中发挥着至关重要的作用。这些蛋白质的特点是能够结合黄素,这是一种维生素B2衍生物,对其功能至关重要。黄素在这些蛋白质中的存在使它们得名,因为“flavo”指的是与黄素化合物相关的黄色。本文将讨论flavoprotein(黄素蛋白)在细胞呼吸、代谢中的重要性以及它们在生物技术中的潜在应用。flavoprotein(黄素蛋白)最重要的功能之一是在细胞呼吸中。它们参与电子传递链,这对腺苷三磷酸(ATP)的产生至关重要,ATP是细胞的能量货币。例如,琥珀酸脱氢酶是一种著名的flavoprotein(黄素蛋白),在柠檬酸循环中发挥着至关重要的作用,通过促进琥珀酸转化为富马酸,同时将电子转移到电子传递链中。这个过程不仅生成ATP,还提高了细胞呼吸的整体效率。除了在能量生产中的作用外,flavoprotein(黄素蛋白)还参与各种代谢途径。它们参与氧化还原反应,这些反应对于碳水化合物、脂肪和蛋白质的代谢是必要的。例如,flavoprotein(黄素蛋白)如酰基辅酶A脱氢酶对于脂肪酸的β-氧化至关重要,这一过程分解脂肪酸以产生能量。这突显了flavoprotein(黄素蛋白)在维持代谢稳态和支持生物体能量需求方面的重要性。此外,flavoprotein(黄素蛋白)因其独特的性质而受到生物技术领域的关注。研究人员一直在探索flavoprotein(黄素蛋白)在各种应用中的使用,包括生物传感器和生物催化。由于这些蛋白质能够在温和条件下催化特定反应,使它们成为工业过程的有吸引力的候选者。例如,flavoprotein(黄素蛋白)可用于开发检测环境污染物或食品污染物的生物传感器,提供了一种更可持续的方法来监测和确保安全。此外,研究flavoprotein(黄素蛋白)对理解人类健康具有重要意义。某些flavoprotein(黄素蛋白)的缺乏可能导致代谢紊乱,突显了它们在营养和健康中的重要性。此外,研究flavoprotein(黄素蛋白)的治疗潜力为药物开发打开了新的途径,特别是在针对与线粒体功能障碍相关的疾病方面。总之,flavoprotein(黄素蛋白)是许多生物系统的重要组成部分,在能量生产和代谢中发挥着关键作用。它们独特的性质使它们在科学研究和生物技术的实际应用中具有价值。随着我们继续探索flavoprotein(黄素蛋白)的功能和潜力,我们可能会发现新的见解,这些见解可能有益于各个领域,从医学到环境科学。理解和利用flavoprotein(黄素蛋白)的力量无疑将为未来健康和技术的进步做出贡献。
