A new twist on RNA helicases: DExH/D box proteins as RNPases

DExH/D box proteins are required for the major transactions of RNA, including mRNA synthesis, pre-mRNA splicing, ribosome biogenesis, translation and RNA decay. In the popular imagination, DExH/D box proteins have become synonymous with 'RNA helicases', which are enzymes that unwind duplex RNAs in concert with the hydrolysis of nucleoside triphosphates (NTPs). But all DExH/D box proteins may not be RNA helicases and the energy of NTP hydrolysis by DExH/D box proteins may be harnessed for other purposes. Cellular RNAs are associated with proteins, often in large ribonucleoprotein (RNP) complexes. This review focuses on recent progress suggesting a role for DExH/D box proteins as 'RNPases' that use chemical energy to remodel the interactions of RNA and proteins.     

Remodeling of ribonucleoprotein complexes with DExH/D RNA helicases

The DExH/D protein family is the largest group of enzymes in eukaryotic RNA metabolism. DExH/D proteins are mainly known for their ability to unwind RNA duplexes in an ATP-dependent fashion. However, it has become clear in recent years that these DExH/D RNA helicases are also involved in the ATP-dependent remodeling of RNA–protein complexes. Here we review recent studies that highlight physiological roles of DExH/D proteins in the displacement of proteins from RNA. We further discuss work with simple RNA–protein complexes in vitro, which illuminates mechanisms by which DExH/D proteins remove proteins from RNA. Although we are only beginning to understand how DExH/D proteins remodel RNA–protein complexes, these studies have shown that an ‘RNA helicase’ does not per se require cofactors to displace proteins from RNA, that protein displacement does not necessarily involve RNA duplex unwinding, and that not all DExH/D proteins are able to disassemble the same range of ribonucleoproteins.     

eIF4AIII binds spliced mRNA in the exon junction complex and is essential for nonsense-mediated decay

The exon junction complex (EJC), a set of proteins deposited on mRNAs as a consequence of pre-mRNA splicing, is a key effector of downstream mRNA metabolism. We have identified eIF4AIII, a member of the eukaryotic translation initiation factor 4A family of RNA helicases (also known as DExH/D box proteins), as a novel EJC core component. Crosslinking and antibody inhibition studies suggest that eIF4AIII constitutes at least part of the platform anchoring other EJC components to spliced mRNAs. A nucleocytoplasmic shuttling protein, eIF4AIII associates in vitro and in vivo with two other EJC core factors, Y14 and Magoh. In mammalian cells, eIF4AIII is essential for nonsense-mediated mRNA decay (NMD). Finally, a model is proposed by which eIF4AIII represents a new functional class of DExH/D box proteins that act as RNA clamps or 'place holders' for the sequence-independent attachment of additional factors to RNAs.     

Yeast and human mitochondrial helicases

Mitochondria are semiautonomous organelles which contain their own genome. Both maintenance and expression of mitochondrial DNA require activity of RNA and DNA helicases. In Saccharomyces cerevisiae the nuclear genome encodes four DExH/D superfamily members (MSS116, SUV3, MRH4, IRC3) that act as helicases and/or RNA chaperones. Their activity is necessary for mitochondrial RNA splicing, degradation, translation and genome maintenance. In humans the ortholog of SUV3 (hSUV3, SUPV3L1) so far is the best described mitochondrial RNA helicase. The enzyme, together with the matrix-localized pool of PNPase (PNPT1), forms an RNA-degrading complex called the mitochondrial degradosome, which localizes to distinct structures (D-foci). Global regulation of mitochondrially encoded genes can be achieved by changing mitochondrial DNA copy number. This way the proteins involved in its replication, like the Twinkle helicase (c10orf2), can indirectly regulate gene expression. Here, we describe yeast and human mitochondrial helicases that are directly involved in mitochondrial RNA metabolism, and present other helicases that participate in mitochondrial DNA replication and maintenance. This article is part of a Special Issue entitled: The Biology of RNA helicases — Modulation for life.     

The DExH/D protein family database

DExH/D proteins are essential for all aspects of cellular RNA metabolism and processing, in the replication of many viruses and in DNA replication. DExH/D proteins are subject to current biological, biochemical and biophysical research which provides a continuous wealth of data. The DExH/D protein family database compiles this information and makes it available over the WWW (http://www.columbia.edu/ ej67/dbhome.htm ). The database can be fully searched by text based queries, facilitating fast access to specific information about this important class of enzymes.     

The DEAD box proteins DDX5 (p68) and DDX17 (p72): Multi-tasking transcriptional regulators

Members of the DEAD box family of RNA helicases, which are characterised by the presence of twelve conserved motifs (including the signature D-E-A-D motif) within a structurally conserved ‘helicase’ core, are involved in all aspects of RNA metabolism. Apart from unwinding RNA duplexes, which established these proteins as RNA helicases, DEAD box proteins have been shown to also catalyse RNA annealing and to displace proteins from RNA. DEAD box proteins generally act as components of large multi-protein complexes and it is thought that interactions, via their divergent N- and C-terminal extensions, with other factors in the complexes may be responsible for the many different functions attributed to these proteins.     

Backbone tracking by the SF2 helicase NPH-II

Members of the DExH/D family of proteins, a subset of helicase superfamily 2 (SF2), are involved in virtually all aspects of RNA metabolism. NPH-II, a prototypical member of this protein family, exhibits robust RNA helicase activity in vitro. Using a series of modified substrates to explore the unwinding mechanism of NPH-II, we observed that the helicase tracks exclusively on the loading strand, where it requires covalent continuity and specifically recognizes the ribose-phosphate backbone. NPH-II unwinding was unaffected by lesions and nicks on the top strand, which has a minimal role in substrate recognition. NPH-II required physical continuity of phosphodiester linkages on the loading strand, although abasic regions were tolerated. These findings suggest that SF2 helicases are mechanistically distinct from other helicase families that can tolerate breaks in the loading strand and for which bases are the primary recognition determinant.     

The DExH/D box protein HEL/UAP56 is essential for mRNA nuclear export in Drosophila.

Dbp5 is the only member of the DExH/D box family of RNA helicases that is directly implicated in the export of messenger RNAs from the nucleus of yeast and vertebrate cells. Dbp5 localizes in the cytoplasm and at the cytoplasmic face of the nuclear pore complex (NPC). In an attempt to identify proteins present in a highly enriched NPC fraction, two other helicases were detected: RNA helicase A (RHA) and UAP56. This suggested a role for these proteins in nuclear transport. Contrary to expectation, we show that the Drosophila homolog of Dbp5 is not essential for mRNA export in cultured Schneider cells. In contrast, depletion of HEL, the Drosophila homolog of UAP56, inhibits growth and results in a robust accumulation of polyadenylated RNAs within the nucleus. Consequently, incorporation of [35S]methionine into newly synthesized proteins is inhibited. This inhibition affects the expression of both heat-shock and non-heat-shock mRNAs, as well as intron-containing and intronless mRNAs. In HeLa nuclear extracts, UAP56 preferentially, but not exclusively, associates with spliced mRNAs carrying the exon junction complex (EJC). We conclude that HEL is essential for the export of bulk mRNA in Drosophila. The association of human UAP56 with spliced mRNAs suggests that this protein might provide a functional link between splicing and export.     

Mutational analysis of vaccinia virus nucleoside triphosphate phosphohydrolase II, a DExH box RNA helicase.

Vaccinia virus nucleoside triphosphate phosphohydrolase II (NPH-II), a 3'-to-5' RNA helicase, displays sequence similarity to members of the DExH family of nucleic acid-dependent nucleoside triphosphatases (NTPases). The contributions of the conserved GxGKT and DExH motifs to enzyme activity were assessed by alanine scanning mutagenesis. Histidine-tagged versions of NPH-II were expressed in vaccinia virus-infected BSC40 cells and purified by nickel affinity and conventional fractionation steps. Wild-type His-NPH-II was indistinguishable from native NPH-II with respect to RNA helicase, RNA binding, and nucleic acid-stimulated NTPase activities. The K-191-->A (K191A), D296A, and E297A mutant proteins bound RNA as well as wild-type His-NPH-II did, but they were severely defective in NTPase and helicase functions. The H299A mutant was active in RNA binding and NTP hydrolysis but was defective in duplex unwinding. Whereas the NTPase of wild-type NPH-II was stimulated > 10-fold by polynucleotide cofactors, the NTPase of the H299A mutant was nucleic acid independent. Because the specific NTPase activity of the H299A mutant in the absence of nucleic acid was near that of wild-type enzyme in the presence of DNA or RNA and because the Km for ATP was unaltered by the H299A substitution, we regard this mutation as a "gain-of-function" mutation and suggest that the histidine residue in the DExH box is required to couple the NTPase and helicase activities.     

Choosing between DNA and RNA: the polymer specificity of RNA helicase NPH-II

NPH-II is a prototypical member of the DExH/D subgroup of superfamily II helicases. It exhibits robust RNA helicase activity, and a detailed kinetic framework for unwinding has been established. However, like most SF2 helicases, there is little known about its mode of substrate recognition and its ability to differentiate between RNA and DNA substrates. Here, we employ a series of chimeric RNA–DNA substrates to explore the molecular determinants for NPH-II specificity on RNA and to determine if there are conditions under which DNA is a substrate. We show that efficient RNA helicase activity depends exclusively on ribose moieties in the loading strand and in a specific section of the 3′-overhang. However, we also document the presence of trace activity on DNA polymers, showing that DNA can be unwound under extremely permissive conditions that favor electrostatic binding. Thus, while polymer-specific SF2 helicases control substrate recognition through specific interactions with the loading strand, alternative specificities can arise under appropriate reaction conditions.     

Mouse erythroid cells express multiple putative RNA helicase genes exhibiting high sequence conservation from yeast to mammals

RNA secondary structure is a critical determinant of RNA function in ribosome assembly, pre-mRNA splicing, mRNA translation and RNA stability. The ‘DEAD/H’ family of putative RNA helicases may help regulate these processes by utilizing intrinsic RNA-dependent ATPase activity to catalyze conformational changes in RNA secondary structure. To investigate the repertoire of DEAD/H box proteins expressed in mammals, we used PCR techniques to clone from mouse erythroleukemia (MEL) cells three new DEAD box cDNAs with high similarity to known yeast (Saccharomyces cerevisiae) genes. mDEAD2 and mDEAD3 (mouse DEAD box proteins) are >95% identical to mouse PL10 but exhibit differential tissue-specific expression patterns; mDEAD2 and mDEAD3 are also approx. 70% identical (at the aa level) to yeast DED1 and DBP1 proteins. Members of this DEAD box subclass contain C-terminal domains with high content of Arg, Ser, Gly and Phe, reminiscent of the RS domain in several Drosophila and mammalian splicing factors. mDEAD5 belongs to a second class related to translation initiation factors from yeast (TIF1/TIF2) and mammals (eIF-4A); this class contains a novel conserved peptide motif not found in other DEAD box proteins. Northern blotting shows that mDEAD5 is differentially expressed in testis vs. somatic tissues. Thus, mouse erythroid cells produce two highly conserved families of putative RNA helicases likely to play important roles in RNA metabolism and gene expression.     

The DHH1/RCKp54 family of helicases: An ancient family of proteins that promote translational silencing

Translational control is a vital aspect of gene expression. Message specific translational repressors have been known for decades. Recent evidence, however, suggests that a general machinery exists that dampens the translational capacity of the majority of mRNAs. This activity has been best ascribed to a conserved family of RNA helicases called the DHH1/RCKp54 family. The function of these helicases is to promote translational silencing. By transitioning mRNA into quiescence, DHH1/RCKp54 helicases promote either mRNA destruction or storage. In this review we describe the known roles of these helicases and propose a mechanistic model to explain their mode of action. This article is part of a Special Issue entitled: The Biology of RNA helicases — Modulation for life.     

Discriminatory RNP remodeling by the DEAD-box protein DED1

DExH/D proteins catalyze NTP-driven rearrangements of RNA and RNA-protein complexes during most aspects of RNA metabolism. Although the vast majority of DExH/D proteins displays virtually no sequence-specificity when remodeling RNA complexes in vitro, the enzymes clearly distinguish between a large number of RNA and RNP complexes in a physiological context. It is unknown how this discrimination between potential substrates is achieved. Here we show one possible way by which a non-sequence specific DExH/D protein can discriminately remodel similar RNA complexes. We have measured in vitro the disassembly of model RNPs by two distinct DExH/D proteins, DED1 and NPH-II. Both enzymes displace the U1 snRNP from a tightly bound RNA in an active, ATP-dependent fashion. However, DED1 cannot actively displace the protein U1A from its binding site, whereas NPH-II can. The dissociation rate of U1A dictates the rate by which DED1 remodels RNA complexes with U1A bound. We further show that DED1 disassembles RNA complexes with slightly altered U1A binding sites at different rates, but only when U1A is bound to the RNA. These findings suggest that the "inability" to actively displace other proteins from RNA can provide non-sequence specific DExH/D proteins with the capacity to disassemble similar RNA complexes in a discriminatory fashion. In addition, our study illuminates possible mechanisms for protein displacement by DExH/D proteins.     

From RNA helicases to RNPases.

In eukaryotic cells, all aspects of cellular RNA metabolism require putative RNA helicases of the DEAD and DExH protein families (collectively known as DExD/H families). Based on data from biochemical studies of a few of these RNA helicases, they are generally considered to be involved in the unwinding of duplex RNA molecules. However, recent reports provide evidence indicating that these proteins might also be involved in the active disruption of RNA-protein interactions.     

A DExH/D-box protein coordinates the two steps of splicing in a group I intron

Proteins of the DExH/D family are ATPases that can unwind duplex RNA in vitro. Individual members of this family coordinate many steps in ribonucleoprotein enzyme assembly and catalysis in vivo, but it is largely unknown how the action of these co-factors is specified and precisely timed. As a first step to address this question biochemically, we describe the development of a new protein-dependent group I intron splicing system that requires such an ATPase for coordinating successive steps in splicing. While genetic analysis in yeast has shown that at least five nuclear-encoded proteins are required for splicing of the mitochondrial aI5β group I intron, we show that efficient in vitro splicing of aI5β occurs with only two of these co-factors and, furthermore, they fulfill distinct functions in vitro. The Mrs1p protein stabilizes RNA structure and promotes the first step in splicing. In contrast, a DExH/D protein, Mss116p, acts after the first step and, utilizing ATP hydrolysis, specifically enhances the efficiency of exon ligation. An analysis of Mss116p variants with mutations that impair its RNA-stimulated ATP hydrolysis activity or reduce its ability to unwind duplexes show that the efficiency of ATP hydrolysis is a major determinant in promoting exon ligation. These observations suggest that Mss116p acts in aI5β splicing by catalyzing changes in the structure of the RNA/protein splicing intermediate that promote the second step. More broadly, these observations are consistent with a model in which the “functional-timing” of DExH/D-box protein action can be specified by a specific conformation of its substrate due to the “upstream” activity of other co-factors.     

Growth-regulated expression and G0-specific turnover of the mRNA that encodes URH49, a mammalian DExH/D box protein that is highly related to the mRNA export protein UAP56

URH49 is a mammalian protein that is 90% identical to the DExH/D box protein UAP56, an RNA helicase that is important for splicing and nuclear export of mRNA. Although Saccharomyces cerevisiae and Drosophila express only a single protein corresponding to UAP56, mRNAs encoding URH49 and UAP56 are both expressed in human and mouse cells. Both proteins interact with the mRNA export factor Aly and both are able to rescue the loss of Sub2p (the yeast homolog of UAP56), indicating that both proteins have similar functions. UAP56 mRNA is more abundant than URH49 mRNA in many tissues, although in testes URH49 mRNA is much more abundant. UAP56 and URH49 mRNAs are present at similar levels in proliferating cultured cells. However, when the cells enter quiescence, the URH49 mRNA level decreases 3–6-fold while the UAP56 mRNA level remains relatively constant. The amount of URH49 mRNA increases to the level found in proliferating cells within 5 h when quiescent cells are growth-stimulated or when protein synthesis is inhibited. URH49 mRNA is relatively unstable (T_½ = 4 h) in quiescent cells, but is stabilized immediately following growth stimulation or inhibition of protein synthesis. In contrast, there is much less change in the content or stability of UAP56 mRNA following growth stimulation. Our observations suggest that in mammalian cells, two UAP56-like RNA helicases are involved in splicing and nuclear export of mRNA. Differential expression of these helicases may lead to quantitative or qualitative changes in mRNA expression.     

DEAD-box helicases as integrators of RNA,nucleotide and protein binding

DEAD-box helicases perform diverse cellular functions in virtually all steps of RNA metabolism from Bacteria to Humans. Although DEAD-box helicases share a highly conserved core domain, the enzymes catalyze a wide range of biochemical reactions. In addition to the well established RNA unwinding and corresponding ATPase activities, DEAD-box helicases promote duplex formation and displace proteins from RNA. They can also function as assembly platforms for larger ribonucleoprotein complexes, and as metabolite sensors. This review aims to provide a perspective on the diverse biochemical features of DEAD-box helicases and connections to structural information. We discuss these data in the context of a model that views the enzymes as integrators of RNA, nucleotide, and protein binding. This article is part of a Special Issue entitled: The Biology of RNA helicases — Modulation for life.