{"title":"用于糖尿病治疗的生物合成人胰岛素及其类似物的演变。","authors":"Dileep Francis, Aksa Mariyam Chacko, Anagha Anoop, Subramani Nadimuthu, Vaishnavi Venugopal","doi":"10.1016/bs.apcsb.2024.06.004","DOIUrl":null,"url":null,"abstract":"<p><p>Hormones play a crucial role in maintaining the normal human physiology. By acting as chemical messengers that facilitate the communication between different organs, tissues and cells of the body hormones assist in responding appropriately to external and internal stimuli that trigger growth, development and metabolic activities of the body. Any abnormalities in the hormonal composition and balance can lead to devastating health consequences. Hormones have been important therapeutic agents since the early 20th century, when it was realized that their exogenous supply could serve as a functional substitution for those hormones which are not produced enough or are completely lacking, endogenously. Insulin, the pivotal anabolic hormone in the body, was used for the treatment of diabetes mellitus, a metabolic disorder due to the absence or intolerance towards insulin, since 1921 and is the trailblazer in hormone therapeutics. At present the largest market share for therapeutic hormones is held by insulin. Many other hormones were introduced into clinical practice following the success with insulin. However, for the six decades following the introduction the first therapeutic hormone, there was no reliable method for producing human hormones. The most common source for hormones were animals, although semisynthetic and synthetic hormones were also developed. However, none of these were optimal because of their allergenicity, immunogenicity, lack of consistency in purity and most importantly, scalability. The advent of recombinant DNA technology was a game changer for hormone therapeutics. This revolutionary molecular biology tool made it possible to synthesize human hormones in microbial cell factories. The approach allowed for the synthesis of highly pure hormones which were structurally and biochemically identical to the human hormones. Further, the fermentation techniques utilized to produce recombinant hormones were highly scalable. Moreover, by employing tools such as site directed mutagenesis along with recombinant DNA technology, it became possible to amend the molecular structure of the hormones to achieve better efficacy and mimic the exact physiology of the endogenous hormone. The first recombinant hormone to be deployed in clinical practice was insulin. It was called biosynthetic human insulin to reflect the biological route of production. Subsequently, the biochemistry of recombinant insulin was modified using the possibilities of recombinant DNA technology and genetic engineering to produce analogues that better mimic physiological insulin. These analogues were tailored to exhibit pharmacokinetic and pharmacodynamic properties of the prandial and basal human insulins to achieve better glycemic control. The present chapter explores the principles of genetic engineering applied to therapeutic hormones by reviewing the evolution of therapeutic insulin and its analogues. 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引用次数: 0
摘要
荷尔蒙在维持人体正常生理机能方面起着至关重要的作用。荷尔蒙作为化学信使,促进人体不同器官、组织和细胞之间的交流,帮助人体对内外刺激做出适当的反应,从而引发人体的生长、发育和新陈代谢活动。荷尔蒙组成和平衡的任何异常都会对健康造成破坏性影响。自 20 世纪初人们意识到外源性激素可以替代内源性激素的功能以来,激素一直是重要的治疗药物。胰岛素是人体内最重要的合成代谢激素,自 1921 年以来一直被用于治疗糖尿病(一种因缺乏胰岛素或对胰岛素不耐受而导致的代谢紊乱),是激素疗法的先驱。目前,胰岛素占据治疗激素的最大市场份额。在胰岛素取得成功后,许多其他激素也被引入临床实践。然而,在第一种治疗性激素问世后的六十年里,一直没有生产人体激素的可靠方法。最常见的激素来源是动物,尽管也开发出了半合成和合成激素。然而,由于其过敏性、免疫原性、纯度不一致以及最重要的可扩展性,这些方法都不是最佳选择。DNA 重组技术的出现改变了激素疗法的格局。这一革命性的分子生物学工具使得在微生物细胞工厂中合成人类激素成为可能。这种方法可以合成在结构上和生物化学上与人类激素完全相同的高纯度激素。此外,用于生产重组激素的发酵技术具有高度可扩展性。此外,通过使用定点突变等工具和 DNA 重组技术,还可以修改激素的分子结构,以获得更好的功效,并模仿内源性激素的确切生理结构。第一个应用于临床的重组激素是胰岛素。它被称为生物合成人胰岛素,以反映其生物生产途径。随后,利用 DNA 重组技术和基因工程的可能性,对重组胰岛素的生物化学进行了改造,以生产出更好地模拟生理性胰岛素的类似物。这些类似物被定制为具有餐前和基础人胰岛素的药代动力学和药效学特性,以实现更好的血糖控制。本章通过回顾治疗用胰岛素及其类似物的演变过程,探讨了应用于治疗激素的基因工程原理。本章还重点介绍了重组类似物如何更好地控制糖尿病。
Evolution of biosynthetic human insulin and its analogues for diabetes management.
Hormones play a crucial role in maintaining the normal human physiology. By acting as chemical messengers that facilitate the communication between different organs, tissues and cells of the body hormones assist in responding appropriately to external and internal stimuli that trigger growth, development and metabolic activities of the body. Any abnormalities in the hormonal composition and balance can lead to devastating health consequences. Hormones have been important therapeutic agents since the early 20th century, when it was realized that their exogenous supply could serve as a functional substitution for those hormones which are not produced enough or are completely lacking, endogenously. Insulin, the pivotal anabolic hormone in the body, was used for the treatment of diabetes mellitus, a metabolic disorder due to the absence or intolerance towards insulin, since 1921 and is the trailblazer in hormone therapeutics. At present the largest market share for therapeutic hormones is held by insulin. Many other hormones were introduced into clinical practice following the success with insulin. However, for the six decades following the introduction the first therapeutic hormone, there was no reliable method for producing human hormones. The most common source for hormones were animals, although semisynthetic and synthetic hormones were also developed. However, none of these were optimal because of their allergenicity, immunogenicity, lack of consistency in purity and most importantly, scalability. The advent of recombinant DNA technology was a game changer for hormone therapeutics. This revolutionary molecular biology tool made it possible to synthesize human hormones in microbial cell factories. The approach allowed for the synthesis of highly pure hormones which were structurally and biochemically identical to the human hormones. Further, the fermentation techniques utilized to produce recombinant hormones were highly scalable. Moreover, by employing tools such as site directed mutagenesis along with recombinant DNA technology, it became possible to amend the molecular structure of the hormones to achieve better efficacy and mimic the exact physiology of the endogenous hormone. The first recombinant hormone to be deployed in clinical practice was insulin. It was called biosynthetic human insulin to reflect the biological route of production. Subsequently, the biochemistry of recombinant insulin was modified using the possibilities of recombinant DNA technology and genetic engineering to produce analogues that better mimic physiological insulin. These analogues were tailored to exhibit pharmacokinetic and pharmacodynamic properties of the prandial and basal human insulins to achieve better glycemic control. The present chapter explores the principles of genetic engineering applied to therapeutic hormones by reviewing the evolution of therapeutic insulin and its analogues. It also focuses on how recombinant analogues account for the better management of diabetes mellitus.
期刊介绍:
Published continuously since 1944, The Advances in Protein Chemistry and Structural Biology series has been the essential resource for protein chemists. Each volume brings forth new information about protocols and analysis of proteins. Each thematically organized volume is guest edited by leading experts in a broad range of protein-related topics.