Abstract
The DNA-binding AT-rich interactive domain (ARID) exists in a wide range of proteins throughout eukaryotic kingdoms. ARID domain-containing proteins are involved in manifold biological processes, such as transcriptional regulation, cell cycle control and chromatin remodeling. Their individual domain composition allows for a sub-classification within higher mammals. ARID is categorized as binder of double-stranded AT-rich DNA, while recent work has suggested ARIDs as capable of binding other DNA motifs and also recognizing RNA. Despite a broad variability on the primary sequence level, ARIDs show a highly conserved fold, which consists of six α-helices and two loop regions. Interestingly, this minimal core domain is often found extended by helices at the N-and/or C-terminus with potential roles in target specificity and, subsequently function. While high-resolution structural information from various types of ARIDs has accumulated over two decades now, there is limited access to ARID-DNA complex structures. We thus find ourselves left at the beginning of understanding ARID domain target specificities and the role of accompanying domains. Here, we systematically summarize ARID domain conservation and compare the various types with a focus on their structural differences and DNA-binding preferences, including the context of multiple other motifs within ARID domain containing proteins.
Highlights
DNA-binding proteins (DBPs) control a plethora of biological processes, such as transcriptional regulation and DNA replication (Luscombe et al 2000)
The structured DNA-binding domains (DBDs) are often interspersed by intrinsically disordered regions (IDRs) that are involved in protein-protein interactions (PPIs) (Liu et al 2006; Minezaki et al 2006) or modulate the transition from non-specific to specific DNA-binding (Doucleff and Clore 2008)
This overview mainly concentrates on the human Arid proteins, yet we include the available structural information of Arids from Saccharomyces cerevisiae (Swi1), D. melanogaster (Dri and Kdm5) and Arabidopsis thaliana (Arid4) for comparison (Table 1, Figure 1)
Summary
DNA-binding proteins (DBPs) control a plethora of biological processes, such as transcriptional regulation and DNA replication (Luscombe et al 2000). DBPs comprise one or more DNA-binding domains (DBDs) that recognize either single-stranded (ss) or double-stranded (ds) DNA. Highly specific transcription factors (TFs) precisely recognize short, conserved motifs within promoters of their target genes, where specificity is mainly driven by a combination of DNA sequence and shape, i.e. groove width and bending (Slattery et al 2014). One of the most common structured DNA-binding elements is the evolutionary highly conserved helix-turnhelix (HTH) motif, present in a large number of repressor and activator proteins [e.g. summarized in (Aravind et al 2005)]. Among the HTH-comprising DBDs, the AT-rich interactive domain (ARID) is one of the most ancient representatives, and found across eukaryotic kingdoms.
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