3.5: Domains, Motifs, and Folds in Protein Structure

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The structures of two different proteins in Figure 3.13 share a common domain: the PH (Pleckstrin Homology) domain.

Screen Shot 2022-05-12 at 2.54.21 AM.png — Figure 3.13: The pleckstrin homology (PH) domains shown here in pink (arrows) are examples of common domains in two different proteins. By virtue of these common PH domains, both proteins can interact with cell-signaling factors that have roles in intercellular communication.

These two (and many other) proteins have this domain, allowing them to bind a molecule of phosphatidyl-inositol triphosphate, which is generated as part of a common cell-signaling pathway. The implication of this common domain is that a cell’s signaling pathways allow it to respond to different signals that lead to the same response, albeit under different conditions and probably at different times. Proteins are typically described as consisting of several distinct substructures, discussed here.

A domain is an element of the protein’s overall structure that is stable and often folds independently of the rest of the protein chain. Like the PH domain above, many domains are not unique to the protein products of one gene but instead appear in a variety of proteins. Proteins sharing more than a few common domains are encoded by members of evolutionarily related genes comprising gene families. Genes for proteins that share only one or a few domains may belong to gene superfamilies. Superfamily members can have one function in common, but the rest of their sequences are otherwise unrelated.

Domain names often derive from their prominent biological function in the protein they belong to (e.g., the calcium-binding domain of calmodulin) or from their discoverers (the PH domain). The domain-swapping that gives rise to gene families and superfamilies is a natural genetic event. Because protein domains can also be swapped on purpose by genetic engineering, we can make chimeric proteins with novel functions.

137-2 Protein Domain Structure and Function

Protein motifs are small regions of protein 3D structure or of amino-acid sequence shared among different proteins. They are recognizable regions of protein structure that may (or may not) be defined by a unique chemical or biological function.

Supersecondary structure refers to a combination of secondary-structure features, such as beta-alpha-beta units or the helix-turn-helix motif. They may also be referred to as structural motifs. See Supersecondary structure for examples.

A protein fold refers to a general aspect of protein architecture, like helix bundle, beta-barrel, Rossmann fold, or other “folds” provided in the Structural Classification of Proteins database. Look at Protein Folds to read more about these structures.

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