Abstract
The production of recombinant proteins using microbial cell factories is frequently associated with the formation of inclusion bodies (IBs). These proteinaceous entities can be sometimes a reservoir of stable and active protein, might display good biocompatibility, and are produced efficiently and cost-effectively. Thus, these submicrometric particles are increasingly exploited as functional biomaterials for biotechnological and biomedical purposes. The fusion of aggregation-prone sequences to the target protein is a successful strategy to sequester soluble recombinant polypeptides into IBs. Traditionally, the use of these IB-tags results in the formation of amyloid-like scaffolds where the protein of interest is trapped. This amyloid conformation might compromise the protein’s activity and be potentially cytotoxic. One promising alternative to overcome these limitations exploits the coiled-coil fold, composed of two or more α-helices and widely used by nature to create supramolecular assemblies. In this review, we summarize the state-of-the-art of functional IBs technology, focusing on the coiled-coil-assembly strategy, describing its advantages and applications, delving into future developments and necessary improvements in the field.
Highlights
The use of microorganisms as cell factories to produce biological products, often leads to the formation of insoluble protein deposits in their cytoplasm (Villaverde and Carrió, 2003)
We describe the assembly of cell component-free artificial inclusion bodies (IBs)
The first coiled-coil domain used to obtain functional IBs α-Helical Inclusion Bodies was the tetramerization domain of the cell surface protein tetrabrachion (TDoT) of Staphylothermus marinus, a righthanded and parallel tetramer consisting of an 11-residues repeat, which has been extensively exploited for building up catalytic IBs (Stetefeld et al, 2000; Diener et al, 2016; Kloss et al, 2018a, Kloss et al, 2018b; Jäger et al, 2018, Jäger et al, 2019; Lamm et al, 2020)
Summary
The use of microorganisms as cell factories to produce biological products (as therapeutic proteins), often leads to the formation of insoluble protein deposits in their cytoplasm (Villaverde and Carrió, 2003). In this mini-review, we illustrate recent advances in the field of functional IBs, discussing their biotechnological and biomedical applications, with particular emphasis on the uses of the new class of coiled-coil IBs. We describe the assembly of cell component-free artificial IBs. PROTEIN INCLUSION BODIES AS AN UNEXPECTED SOURCE OF ACTIVE PROTEIN
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