alanyl
简明释义
n. [有化] 丙氨酰(基)
英英释义
Alanyl is a term referring to the amino acid alanine when it is in its acylated form, often used in biochemical contexts. | Alanyl是指氨基酸丙氨酸在其酰化形式下的术语,常用于生物化学领域。 |
单词用法
铵基团 | |
铵肽 | |
铵侧链 | |
铵-赖氨酸 | |
铵-谷氨酸 | |
铵化合物 |
同义词
反义词
| 甘氨酸基 | 甘氨酸基常用于肽的合成。 | ||
| 丝氨酸基 | 丝氨酸基可以在各种蛋白质和酶中找到。 |
例句
1.CONCLUSION: It is safe and effective to use alanyl-glutamine dipeptide via peripheral vein TPN in patients after gastrointestinal operation.
结论:丙氨酰谷氨酰胺双肽在胃肠道术后经周围静脉tpn应用安全、有效。
2.Objective To explore the method of chemical synthesis of L-alanyl-L-glutamine dipeptide.
目的探讨l -丙氨酰- L -谷氨酰胺双肽的化学合成方法。
3.OBJECTIVE:To investigate the safety and efficacy of alanyl-glutamine dipeptide administered via peripheral vein total parenteral nutrition(TPN)in patients after gastrointestinal operation.
目的:观察胃肠道术后患者在经周围静脉全肠外营养(TPN)中应用丙氨酰谷氨酰胺双肽的安全性和有效性。
4.Objective To evaluate the value of alanyl glutamine in the treatment of aged patients with acute exacerbation of chronic obstructive pulmonary disease (AECOPD).
目的探讨丙氨酰谷氨酰胺对慢性阻塞性肺疾病急性加重期患者(AECOPD)的治疗作用。
5.OBJECTIVE:To investigate the safety and efficacy of alanyl-glutamine dipeptide administered via peripheral vein total parenteral nutrition(TPN)in patients after gastrointestinal operation.
目的:观察胃肠道术后患者在经周围静脉全肠外营养(TPN)中应用丙氨酰谷氨酰胺双肽的安全性和有效性。
6.Researchers discovered that adding alanyl (丙氨酸) to the culture medium improves cell growth.
研究人员发现,在培养基中添加alanyl(丙氨酸)可以改善细胞生长。
7.The peptide sequence contains an alanyl (丙氨酸) residue that is crucial for its stability.
该肽序列包含一个alanyl(丙氨酸)残基,对其稳定性至关重要。
8.In biochemistry, alanyl (丙氨酸) is often used as a building block for synthesizing larger molecules.
在生物化学中,alanyl(丙氨酸)通常用作合成更大分子的构建块。
9.In the synthesis of proteins, alanyl (丙氨酸) plays a vital role in forming peptide bonds.
在蛋白质的合成中,alanyl(丙氨酸)在形成肽键中发挥着重要作用。
10.The enzyme's active site includes an alanyl (丙氨酸) which is essential for its catalytic activity.
该酶的活性位点包括一个alanyl(丙氨酸),这是其催化活性所必需的。
作文
In the world of biochemistry, understanding amino acids is crucial for grasping the complexities of life. One such amino acid is alanyl, which is derived from alanine. Alanyl plays a significant role in various biological processes, including protein synthesis and metabolism. It is essential to comprehend how alanyl interacts with other amino acids and contributes to the formation of proteins that are vital for cellular function. The structure of alanyl consists of an amino group, a carboxyl group, and a side chain that distinguishes it from other amino acids. This unique structure allows alanyl to participate in peptide bonds, linking together to form polypeptides and proteins. The incorporation of alanyl into proteins can influence their stability, activity, and overall function. For instance, the presence of alanyl in a protein can affect its folding pattern, thereby impacting how it interacts with other molecules in the cell.Moreover, alanyl is involved in energy production. During metabolic processes, alanyl can be converted into glucose through gluconeogenesis, providing a vital energy source for the body. This conversion is particularly important during periods of fasting or intense exercise when the body requires additional energy. Understanding the metabolic pathways involving alanyl can help researchers develop strategies to enhance athletic performance or manage conditions like diabetes.In addition to its metabolic functions, alanyl has been studied for its potential therapeutic applications. Research has shown that alanyl supplementation may improve muscle recovery after exercise, making it a popular choice among athletes. Furthermore, alanyl is being investigated for its role in reducing fatigue and improving overall physical performance. These findings highlight the importance of alanyl not only in basic biology but also in applied health sciences.In conclusion, alanyl is more than just an amino acid; it is a vital component of life that impacts various physiological processes. From its role in protein synthesis to its involvement in energy metabolism and potential therapeutic benefits, understanding alanyl is essential for anyone studying biology or medicine. As we continue to explore the intricate workings of amino acids like alanyl, we gain deeper insights into the fundamental principles that govern life itself.
在生物化学的世界中,理解氨基酸对于掌握生命的复杂性至关重要。其中一个氨基酸是alanyl,它源自丙氨酸。Alanyl在蛋白质合成和代谢等多种生物过程中发挥着重要作用。理解alanyl如何与其他氨基酸相互作用,并对细胞功能至关重要的蛋白质的形成作出贡献,是非常必要的。Alanyl的结构由一个氨基、一个羧基和一个侧链组成,这使其与其他氨基酸区别开来。这种独特的结构使得alanyl能够参与肽键的形成,将氨基酸连接在一起,形成多肽和蛋白质。Alanyl在蛋白质中的存在会影响其稳定性、活性和整体功能。例如,alanyl在蛋白质中的存在可以影响其折叠模式,从而影响其与细胞内其他分子的相互作用。此外,alanyl还参与能量产生。在代谢过程中,alanyl可以通过糖异生转化为葡萄糖,为身体提供重要的能量来源。这种转化在禁食或剧烈运动期间尤其重要,因为身体需要额外的能量。理解涉及alanyl的代谢途径可以帮助研究人员制定增强运动表现或管理糖尿病等疾病的策略。除了其代谢功能外,alanyl还因其潜在的治疗应用而受到研究。研究表明,alanyl补充可能改善运动后的肌肉恢复,使其成为运动员的热门选择。此外,alanyl正在被研究其在减少疲劳和改善整体身体表现方面的作用。这些发现突显了alanyl在基础生物学和应用健康科学中的重要性。总之,alanyl不仅仅是一个氨基酸;它是生命的重要组成部分,影响着各种生理过程。从其在蛋白质合成中的作用,到其在能量代谢中的参与,以及潜在的治疗益处,理解alanyl对于任何学习生物学或医学的人来说都是至关重要的。随着我们继续探索像alanyl这样的氨基酸的复杂运作,我们获得了对支配生命本身的基本原理的更深刻见解。
