DEAD-box基因家族在拟南芥生长发育中的作用

在RNA代谢过程中,需要许多蛋白和核酸的参与,其中一类蛋白就是RNA解旋酶。RNA解旋酶通过水解ATP获得能量来参与RNA代谢的多个方面,包括核内转录、pre-mRNA的剪切、核糖体发生、核质运输、蛋白质翻译、RNA降解、细胞器内基因的表达。DEAD-box蛋白家族是RNA解旋酶中最大的亚家族,它具有9个保守结构域,因motifyⅡ的保守氨基酸序列Asp-Glu-Ala-Asp(DEAD)而命名。该家族在酵母、拟南芥(Arabidopsis thaliana Heynh.)和人类基因组中都有较多的家庭成员。近年来,研究者对拟南芥DEAD-box蛋白家族的结构和功能进行了一些研究,本文着重总结DEAD-box基因家族对拟南芥生长发育的影响。     

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.     

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.     

Unwinding RNA in Saccharomyces cerevisiae: DEAD-box proteins and related families.

Members of the RNA-helicase family are defined by several evolutionary conserved motifs. They are found in all organisms - from bacteria to humans - and many viruses. The minimum number of RNA helicases present within a eukaryotic cell can be predicted from the complete sequence of the Saccharomyces cerevisiae genome. Recent progress in the functional analysis of various family members has given new insights into, and confirmed the significance of these proteins for, most cellular RNA metabolic processes.     

The newly discovered Q motif of DEAD-box RNA helicases regulates RNA-binding and helicase activity

DEAD-box proteins are the most common RNA helicases, and they are associated with virtually all processes involving RNA. They have nine conserved motifs that are required for ATP and RNA binding, and for linking phosphoanhydride cleavage of ATP with helicase activity. The Q motif is the most recently identified conserved element, and it occurs approximately 17 amino acids upstream of motif I. There is a highly conserved, but isolated, aromatic group approximately 17 amino acids upstream of the Q motif. These two elements are involved in adenine recognition and in ATPase activity of DEAD-box proteins. We made extensive analyses of the Q motif and upstream aromatic residue in the yeast translation-initiation factor Ded1. We made site-specific mutations and tested them for viability in yeast. Moreover, we purified various mutant proteins and obtained the Michaelis-Menten parameters for the ATPase activities. We also measured RNA affinities and strand-displacement activities. We find that the Q motif not only regulates ATP binding and hydrolysis but also regulates the affinity of the protein for RNA substrates and ultimately the helicase activity.     

Crystal structure of the BstDEAD N-terminal domain: a novel DEAD protein from Bacillus stearothermophilus

Most cellular processes requiring RNA structure rearrangement necessitate the action of Asp-Glu-Ala-Asp (DEAD) proteins. Members of the family, named originally for the conserved DEAD amino acid sequence, are thought to disrupt RNA structure and facilitate its rearrangement by unwinding short stretches of duplex RNA. BstDEAD is a novel 436 amino acid representative of the DEAD protein family from Bacillus stearothermophilus that contains all eight conserved motifs found in DEAD proteins and is homologous with other members of the family. Here, we describe the 1.85 A resolution structure of the N-terminal domain (residues 1-211) of BstDEAD (BstDEAD-NT). Similar to the corresponding domains of related helicases, BstDEAD-NT adopts a parallel alpha/beta structure with RecA-like topology. In general, the conserved motifs superimpose on closely related DEAD proteins and on more distantly related helicases such as RecA. This affirms the current belief that the core helicase domains, responsible for mechanistic activity, are structurally similar in DEAD proteins. In contrast, however, the so-called Walker A P-loop, which binds the beta- and gamma-phosphates of ATP, adopts a rarely seen "closed" conformation that would sterically block ATP binding. The closed conformation may be indicative of a general regulatory feature among DEAD proteins (and RNA helicases) that differs from that used by DNA helicases. BstDEAD also contains a unique extension of approximately 60 residues at the C terminus that is highly basic, suggesting that it might bind nucleic acids and, in so doing, confer specificity to the helicase activity of the core region.     

Crystal structure of the N-terminal RecA-like domain of a DEAD-box RNA helicase, the Dugesia japonica vasa-like gene B protein

The Dugesia japonica vasa-like gene B (DjVLGB) protein is a DEAD-box RNA helicase of a planarian, which is well known for its strong regenerative capacity. DjVLGB shares sequence similarity to the Drosophila germ-line-specific DEAD-box RNA helicase Vasa, and even higher similarity to its paralogue, mouse PL10. In this study, we solved the crystal structure of the DjVLGB N-terminal RecA-like domain. The overall fold and the structures of the putative ATPase active site of the DjVLGB N-terminal RecA-like domain are similar to those of the previously reported DEAD-box RNA helicase structures. In contrast, the surface structure of the side opposite to the putative ATPase active site is different from those of the other DEAD-box RNA helicases; the characteristic hydrophobic pockets are formed with aromatic and proline residues. These pocket-forming residues are conserved in the PL10-subfamily proteins, but less conserved in the Vasa orthologues and not conserved in the DEAD-box RNA helicases. Therefore, the structural features that we found are characteristic of the PL10-subfamily proteins and might contribute to their biological roles in germ-line development.     

Comprehensive mutational analysis of yeast DEXD/H box RNA helicases required for small ribosomal subunit synthesis

The 17 putative RNA helicases required for pre-rRNA processing are predicted to play a crucial role in ribosome biogenesis by driving structural rearrangements within preribosomes. To better understand the function of these proteins, we have generated a battery of mutations in five putative RNA helicases involved in 18S rRNA synthesis and analyzed their effects on cell growth and pre-rRNA processing. Our results define functionally important residues within conserved motifs and demonstrate that lethal mutations in predicted ATP binding-hydrolysis motifs often confer a dominant negative phenotype in vivo when overexpressed in a wild-type background. We show that dominant negative mutants delay processing of the 35S pre-rRNA and cause accumulation of pre-rRNA species that normally have low steady-state levels. Our combined results establish that not all conserved domains function identically in each protein, suggesting that the RNA helicases may have distinct biochemical properties and diverse roles in ribosome biogenesis.     

Helicase structure and mechanism

Structural information on helicase proteins has expanded recently beyond the DNA helicases Rep and PcrA, and the hepatitis C virus RNA helicase to include UvrB, members of the DEA(D/H)-box RNA helicase family, examples of DnaB-related helicases and RuvB. The expanding database of structures has clarified the structural 'theme and variations' that relate the different helicase families. Furthermore, information is emerging on the functions of the conserved helicase motifs and their participation in the mechanisms by which these proteins catalyze the remodeling of DNA and RNA in ATP-dependent activities.     

RNA helicases--one fold for many functions

RNA helicases are a large group of enzymes that function in virtually all aspects of RNA metabolism. Although RNA helicases share a highly conserved structure, different enzymes display a wide array of biochemical activities, including RNA duplex unwinding, protein displacement from RNA and strand annealing. Recent structural and functional studies have started to illuminate the mechanisms by which this remarkable diversity of functions can be conducted by the conserved helicase fold.     

Selective pharmacological targeting of a DEAD box RNA helicase

RNA helicases represent a large family of proteins implicated in many biological processes including ribosome biogenesis, splicing, translation and mRNA degradation. However, these proteins have little substrate specificity, making inhibition of selected helicases a challenging problem. The prototypical DEAD box RNA helicase, eIF4A, works in conjunction with other translation factors to prepare mRNA templates for ribosome recruitment during translation initiation. Herein, we provide insight into the selectivity of a small molecule inhibitor of eIF4A, hippuristanol. This coral-derived natural product binds to amino acids adjacent to, and overlapping with, two conserved motifs present in the carboxy-terminal domain of eIF4A. Mutagenesis of amino acids within this region allowed us to alter the hippuristanol-sensitivity of eIF4A and undertake structure/function studies. Our results provide an understanding into how selective targeting of RNA helicases for pharmacological intervention can be achieved.     

Unraveling DNA helicases. Motif, structure, mechanism and function.

DNA helicases are molecular 'motor' enzymes that use the energy of NTP hydrolysis to separate transiently energetically stable duplex DNA into single strands. They are therefore essential in nearly all DNA metabolic transactions. They act as essential molecular tools for the cellular machinery. Since the discovery of the first DNA helicase in Escherichia coli in 1976, several have been isolated from both prokaryotic and eukaryotic systems. DNA helicases generally bind to ssDNA or ssDNA/dsDNA junctions and translocate mainly unidirectionally along the bound strand and disrupt the hydrogen bonds between the duplexes. Most helicases contain conserved motifs which act as an engine to drive DNA unwinding. Crystal structures have revealed an underlying common structural fold for their function. These structures suggest the role of the helicase motifs in catalytic function and offer clues as to how these proteins can translocate and unwind DNA. The genes containing helicase motifs may have evolved from a common ancestor. In this review we cover the conserved motifs, structural information, mechanism of DNA unwinding and translocation, and functional aspects of DNA helicases.