Abstract
The vast majority of our current knowledge about the biochemical and biophysical properties of proteins derives from in vitro studies conducted on isolated globular domains. However, a very large fraction of the proteins expressed in the eukaryotic cell are structurally more complex. In particular, the discovery that up to 40% of the eukaryotic proteins are intrinsically disordered, or possess intrinsically disordered regions, and are highly dynamic entities lacking a well-defined three-dimensional structure, revolutionized the structure–function paradigm and our understanding of proteins. Moreover, proteins are mostly characterized by the presence of multiple domains, influencing each other by intramolecular interactions. Furthermore, proteins exert their function in a crowded intracellular milieu, transiently interacting with a myriad of other macromolecules. In this review we summarize the literature tackling these themes from both the theoretical and experimental perspectives, highlighting the effects on protein folding and function that are played by (i) flanking disordered tails; (ii) contiguous protein domains; (iii) interactions with the cellular environment, defined as quinary structures. We show that, in many cases, both the folding and function of protein domains is remarkably perturbed by the presence of these interactions, pinpointing the importance to increase the level of complexity of the experimental work and to extend the efforts to characterize protein domains in more complex contexts.
Highlights
The majority of the human proteome has a modular nature and is organized in building blocks denoted as protein domains [1]
It may be shallowly stated that small proteins are often found as single-domain units, whereas larger systems tend to consist of multiple domains
In an effort to offer a comprehensive view on this matter, we focus on the effects that are to offer a comprehensive view on this matter, we focus on the effects that are produced in produced in proteinboth domains, both from folding and from a functional perspective
Summary
The majority of the human proteome has a modular nature and is organized in building blocks denoted as protein domains [1]. Due to the complexity of studying larger proteins using standard biophysical techniques, it is, very common to investigate the structural and functional properties of isolated domains. In these cases, general rules are extracted by studying, in detail, the individual domains, while assuming that large proteins behave as beads-on-a-string, Biomolecules 2022, 12, 209. For several studies have unambiguously shown that, in manycharactericases, in modulating theexample, functions of proteins and demand a rigorous experimental disordered protein segments, which can be hardly defined as ‘domains’, appear to be zation [10,11,12,13,14,15,16,17,18,19] This observation clearly complicates our view of protein structure and critical in modulating the functions of proteins and demand a rigorous experimental charchallenges the definition of protein domain, per se.
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