DDX41: a multifunctional DEAD-box protein involved in pre-mRNA splicing and innate immunity.

DEAD-box helicases participate in nearly all steps of an RNA's life. In recent years, increasing evidence has shown that several family members are multitasking enzymes. They are often involved in different processes, which may be typical for RNA helicases, such as RNA export and translation, or atypical, e.g., acting as nucleic acid sensors that activate downstream innate immune signaling. This review focuses on the DEAD-box protein DDX41 and summarizes our current understanding of its roles as an innate immunity sensor in the cytosol and in pre-mRNA splicing in the nucleus and discusses DDX41's involvement in disease.

Allosteric regulation of helicase core activities of the DEAD-box helicase YxiN by RNA binding to its RNA recognition motif.

DEAD-box proteins share a structurally similar core of two RecA-like domains (RecA_N and RecA_C) that contain the conserved motifs for ATP-dependent RNA unwinding. In many DEAD-box proteins the helicase core is flanked by ancillary domains. To understand the regulation of the DEAD-box helicase YxiN by its C-terminal RNA recognition motif (RRM), we investigated the effect of RNA binding to the RRM on its position relative to the core, and on core activities. RRM/RNA complex formation substantially shifts the RRM from a position close to the RecA_C to the proximity of RecA_N, independent of RNA contacts with the core. RNA binding to the RRM is communicated to the core, and stimulates ATP hydrolysis and RNA unwinding. The conformational space of the core depends on the identity of the RRM-bound RNA. Allosteric regulation of core activities by RNA-induced movement of ancillary domains may constitute a general regulatory mechanism of DEAD-box protein activity.

Protein cofactor competition regulates the action of a multifunctional RNA helicase in different pathways.

A rapidly increasing number of RNA helicases are implicated in several distinct cellular processes, however, the modes of regulation of multifunctional RNA helicases and their recruitment to different target complexes have remained unknown. Here, we show that the distribution of the multifunctional DEAH-box RNA helicase Prp43 between its diverse cellular functions can be regulated by the interplay of its G-patch protein cofactors. We identify the orphan G-patch protein Cmg1 (YLR271W) as a novel cofactor of Prp43 and show that it stimulates the RNA binding and ATPase activity of the helicase. Interestingly, Cmg1 localizes to the cytoplasm and to the intermembrane space of mitochondria and its overexpression promotes apoptosis. Furthermore, our data reveal that different G-patch protein cofactors compete for interaction with Prp43. Changes in the expression levels of Prp43-interacting G-patch proteins modulate the cellular localization of Prp43 and G-patch protein overexpression causes accumulation of the helicase in the cytoplasm or nucleoplasm. Overexpression of several G-patch proteins also leads to defects in ribosome biogenesis that are consistent with withdrawal of the helicase from this pathway. Together, these findings suggest that the availability of cofactors and the sequestering of the helicase are means to regulate the activity of multifunctional RNA helicases and their distribution between different cellular processes.

Fluorescence methods in the investigation of the DEAD-box helicase mechanism.

DEAD-box proteins catalyze the ATP-dependent unwinding of RNA duplexes and accompany RNA molecules throughout their cellular life. Conformational changes in the helicase core of DEAD-box proteins are intimately linked to duplex unwinding. In the absence of ligands, the two RecA domains of the helicase core are separated. ATP and RNA binding induces a closure of the cleft between the RecA domains that is coupled to the distortion of bound RNA, leading to duplex destabilization and dissociation of one RNA strand. Reopening of the helicase core occurs after ATP hydrolysis and is coupled to phosphate release and dissociation of the second RNA strand.Fluorescence spectroscopy provides an array of approaches to study intermolecular interactions, local structural rearrangements, or large conformational changes of biomolecules. The fluorescence intensity of a fluorophore reports on its environment, and fluorescence anisotropy reflects the size of the molecular entity the fluorophore is part of. Fluorescence intensity and anisotropy are therefore sensitive probes to report on binding and dissociation events. Fluorescence resonance energy transfer (FRET) reports on the distance between two fluorophores and thus on conformational changes. Single-molecule FRET experiments reveal the distribution of conformational states and the kinetics of their interconversion. This chapter summarizes fluorescence approaches for monitoring individual aspects of DEAD-box protein activity, from nucleotide and RNA binding and RNA unwinding to protein and RNA conformational changes in the catalytic cycle, and illustrates exemplarily how fluorescence-based methods have contributed to understanding the mechanism of DEAD-box helicase-catalyzed RNA unwinding.

The DEAD-box helicase eIF4A: paradigm or the odd one out?

DEAD-box helicases catalyze the ATP-dependent unwinding of RNA duplexes. They share a helicase core formed by two RecA-like domains that carries a set of conserved motifs contributing to ATP binding and hydrolysis, RNA binding and duplex unwinding. The translation initiation factor eIF4A is the founding member of the DEAD-box protein family, and one of the few examples of DEAD-box proteins that consist of a helicase core only. It is an RNA-stimulated ATPase and a non-processive helicase that unwinds short RNA duplexes. In the catalytic cycle, a series of conformational changes couples the nucleotide cycle to RNA unwinding. eIF4A has been considered a paradigm for DEAD-box proteins, and studies of its function have revealed the governing principles underlying the DEAD-box helicase mechanism. However, as an isolated helicase core, eIF4A is rather the exception, not the rule. Most helicase modules in other DEAD-box proteins are modified, some by insertions into the RecA-like domains, and the majority by N- and C-terminal appendages. While the basic catalytic function resides within the helicase core, its modulation by insertions, additional domains or a network of interaction partners generates the diversity of DEAD-box protein functions in the cell. This review summarizes the current knowledge on eIF4A and its regulation, and discusses to what extent eIF4A serves as a model DEAD-box protein.

Conformational changes of DEAD-box helicases monitored by single molecule fluorescence resonance energy transfer.

DEAD-box proteins catalyze the ATP-dependent unwinding of RNA duplexes. The common unit of these enzymes is a helicase core of two flexibly linked RecA domains. ATP binding and phosphate release control opening and closing of the cleft in the helicase core. This movement coordinates RNA-binding and ATPase activity and is thus central to the function of DEAD-box helicases. In most DEAD box proteins, the helicase core is flanked by ancillary N-and C-terminal domains. Here, we describe single molecule fluorescence resonance energy transfer (smFRET) approaches to directly monitor conformational changes associated with opening and closing of the helicase core. We further outline smFRET strategies to determine the orientation of flanking N- and C-terminal domains of DEAD-box helicases and to assess the effects of regulatory proteins on DEAD-box helicase conformation.