Thioesters in Biochemistry: Exploring Their Roles in Metabolism, Siderophore Synthesis, and Compound Formation

Published: 2023-12-30
Thioesters in Biochemistry: Exploring Their Roles in Metabolism, Siderophore Synthesis, and Compound Formation
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Categories:  Biology Science Healthcare
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Introduction

Thioesters are described as esters in which the oxygen atom that links them is replaced by sulfur. They include dehydration products between a thiol and a carboxylic acid. They are regarded as common intermediates in biochemistry and involve compounds with a functional group of R–S–CO–R. thioesters are analogous to the carboxylate esters where sulfur in them is responsible for linking carboxylate ester (Hirschbeck et al. 2019).. They include products of esterification of thiol and carboxylic acid. They include key intermediates for natural products such as siderophores and carbazoles.

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A thioester is described as a molecule that has a group C-S-CO-C and is similar to esters but has sulfur rather than oxygen as the linking atoms. Thioesters are made just like esters from carboxylic acids (Jabarullah et al., 2019). During the synthesis process, alcohol is replaced with a thiol. Thioesters are regarded as very essential, especially in biochemistry (Lara et al., p. 11). They are typically made in the body at the time of reactions making fatty acids.

Thioesters are also seen as important since they serve as intermediates in ATP production. ATP refers to the molecule that offers energy to the human body. Thioesters are obligatory intermediaries in numerous primary processes where the ATP is either utilized or regenerated (Krink-Koutsoubelis et al., 2018). They are included during the synthesis of overall esters such as those established in certain complex lipids. Besides, they take part in the synthesis of several other cellular elements such as fatty acids, peptides, terpenes, sterols, porphyrins, among others. Besides, thioesters are typically formed as primary intermediates in numerous, especially ancient processes resulting in ATP assembly. It is established that thioester is closer than ATP to the given process that yields or utilizes energy.

Thioesters are also found to be an essential class of organosulfur compounds whose fundamental role occurs in the construction of biological, pharmaceutical, natural, and industrial products. Therefore, thioesters synthesis is regarded as among the considerably essential tasks in organosulfur chemistry. Thiols’ esterification is regarded as among the best and significantly common approaches for thioesters’ synthesis.

Thioesters are well-known intermediate in several biosynthetic reactions such as degradation and formation of mevalonate, fatty acids, and a precursor to steroids. They include acetoacetyl-CoA, malonyl-CoA, cinnamoyl-CoA, and propionyl-CoA. The formation of acetyl-CoA allows the continuation of acetogenesis. In addition, lignin biosynthesis that consists of a massive fraction of land biomass on Earth continues through a thioester derivative, including caffeic acid. Such thioesters normally arise analogously to other thioesters prepared synthetically. The existing variation, in this case, is that ATP is the dehydrating agent. Additionally, thioesters are perceived to play a key role, especially in the tagging of proteins with ubiquitin that tags proteins to allow degradation (Tsuchiya et al., 2017). Sulfur atom oxidation in the thioesters is usually postulated during the bioactivation of antithrombotic prodrugs clopidogrel, ticlopidine, and prasugrel.

Carbazoles are some of the thioesters, and they function as a representation of an essential class of heterocycles. They depict varied biological operations, including antitumor, antimicrobial, antihistaminic, and antiepileptic (Wei et al., 2019). They can also include activities such as analgesic, antidiarrhea, and pancreatic lipase inhibition properties.

Siderophores include small and high-affinity iron-chelating compounds. They are secreted by microorganisms, including fungi and bacteria, and their function includes mainly the transportation of iron across cell membranes (Wilson et al.). However, a broadening range of siderophore roles has been recently appreciated.

The other importance of siderophores are such that they benefit some pathogenic bacteria, especially in iron acquisition (Golonka et al., 2019). They are also one of the robust binders to Fe3+ known, where enterobactin is among the siderophores (Petrik et al., 2017). As a result of the property, siderophores shave attracted significant interest from medical science, especially in metal chelation therapy. One of the siderophores, such as deferoxamine B, has gain ed massive application while treating poisoning from iron and thalassemia. In addition to siderophores, some pathogenic bacteria generate semaphores or possess receptors that function in binding directly to scheme or iron proteins (Albelda-Berenguer, 2019 ).

The next importance of thioesters can be examined by looking at the role played by coenzyme A, alongside other thiol groups, especially the formation of thioesters. Acyl group chemistry and multiple derivatives occupy a crucial place in organic chemistry. Besides, it is essential during reactions of metabolism. In contrast to acyl derivatives applied in organic synthesis, the thioester is found to play a key role in metabolism. The majority of well-known thioesters are dependent on phosphopantetheine, which refers to the biochemically active pantothenate from, which involves coenzyme A (Gout, 2018; Sibon & Strauss, 2016).

Several reasons explain why thioesters are used in metabolism. Given the occurrence of thioesters in multiple reactions, thioesters usually serve in metabolism due to their ability to depict effectiveness as acylating agents. The agents refer to a molecule with the ability to transfer the acyl group to different species. For instance, acyl group transfer from CoA to water generates acetic acid (Gout, 2018; ttps://doi.org/10.1021/acssynbio.7b00466). The process explains acetyl CoA hydrolysis.

The second reason for preferring thioesters is that they are good alkylating agents. Stabilization of carbanion outcome by resonance is seen to make hydrogen attached to α-carbon of a thioester perceived as more acidic. The primary impact it allows thioester to become more nucleophilic. As a result, they can function as an alkylating agent.

It is established that certain biomolecules usually function as carriers of acyl groups, including coenzyme A and acyl carrier protein (Gout, 2018). The acyl protein serves in the precipitation of fatty acids synthesis as they help to shuttle of the expanding acyl chain between active enzymatic sites. Besides, non-ribosomal synthesis of protein requires the formation of aminoacyl thioester.

Biochemical essential thiols depended on phosphopantetheine involve acyl carrier protein and coenzyme A (Gout, 2018; Srinivasan et al. 2015)). Thioesters established through the combination of identified thiols with certain species that bear acyl groups, including fatty acids, possess key functions in metabolism. It is established that Phosphopantetheine consists of pantothenate, 2-mercaptoethylamine, and one phosphate group (Kramer, Ă–zkaya & KĂĽmmerli, 2019). Pantothenate is regarded as a vitamin and ought to be involved in the diet to it should be sufficiently acquired via a synthetic operation of the intestinal flora.

The next importance of thioesters is explained by exploring its reactions. They take part in multiple reactions. The mechanism features typically attack at the carbonyl carbon to generate a tetrahedral transition condition. The process has the potential to cause thiol exchange or lead to conversion to acyl phosphate.

Conclusion

Thioesters are almost close to the esters, but use sulfur as the linking atoms. The formation of thioesters includes a combination of thiol and carboxylic acid. They have several functions, including metabolism in the body of humans. The discussion also includes siderophores and carbazoles and their functions and importance. Thioesters include include acetoacetyl-CoA, malonyl-CoA, cinnamoyl-CoA, and propionyl-CoA.

References

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Golonka, R., San Yeoh, B., & Vijay-Kumar, M. (2019). The iron tug-of-war between bacterial siderophores and innate immunity. Journal of innate immunity, 11(3), 249-262.

Gout, I. (2018). Coenzyme A, protein CoAlation and redox regulation in mammalian cells. Biochemical Society transactions, 46(3), 721-728. https://doi.org/10.1042/BST20170506

Jabarullah, N. H., Jermsittiparsert, K., Melnikov, P. A., Maseleno, A., Hosseinian, A., & Vessally, E. (2020). Methods for the direct synthesis of thioesters from aldehydes: a focus review. Journal of Sulfur Chemistry, 41(1), 96-115. https://doi.org/10.1080/17415993.2019.1658764

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Petrik, M., Zhai, C., Haas, H., & Decristoforo, C. (2017). Siderophores for molecular imaging applications. Clinical and translational imaging, 5(1), 15-27.

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Sibon, O. C., & Strauss, E. (2016). Coenzyme A: to make it or uptake it?. Nature reviews Molecular cell biology, 17(10), 605-606. https://doi.org/10.1038/nrm.2016.110

Tsuchiya, Y., Peak-Chew, S. Y., Newell, C., Miller-Aidoo, S., Mangal, S., Zhyvoloup, A., ... & Szabadkai, G. (2017). Protein CoAlation: a redox-regulated protein modification by coenzyme A in mammalian cells. Biochemical Journal, 474(14), 2489-2508. https://doi.org/10.1042/BCJ20170129

Wei, X., Zhu, M. J., Cheng, Z., Lee, M., Yan, H., Lu, C., & Xu, J. J. (2019). AggregationInduced Electrochemiluminescence of Carboranyl Carbazoles in Aqueous Media. Angewandte Chemie, 131(10), 3194-3198.

Wilson, B. R., Bogdan, A. R., Miyazawa, M., Hashimoto, K., & Tsuji, Y. (2016). Siderophores in iron metabolism: from mechanism to therapy potential. Trends in molecular medicine, 22(12), 1077-1090.

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