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.     

RNA helicase-related genes of Plasmodium falciparum and Plasmodium cynomolgi

RNA helicases play many essential roles including cell development and growth. Using degenerate oligonucleotide primers designed to amplify DNA fragments flanked by the highly conserved helicase motifs VLDEAD and YIHRIG and genomic DNAs from the malarial parasites as a template, we have cloned two putative RNA helicase genes (546 and 540 bp) from P. falciparum and one gene (546 bp) from P. cynomologi. Southern blot analysis revealed that these could be multiple and single-copy genes in P. falciparum and P. cynomolgi, respectively. Several members of the RNA helicase gene family share sequence identity with malarial parasite's helicases ranging from 30 to 76%, suggesting that they are functionally related. The discovery of such a multitude of putative RNA helicase genes in malarial parasites suggested that RNA helicase activities may be involved in many essential biological processes. Further characterization of these helicases may also help in designing parasite-specific inhibitors/drugs which specifically inhibit the parasite's growth without affecting the host.     

蕨类植物问荆DEAD-box RNA解旋酶基因的克隆与分析

DEAD-box RNA解旋酶参与RNA多方面的代谢,在植物生长发育和逆境反应中起重要作用。本研究从蕨类植物问荆（Equisetum arvense）中克隆到一条DEAD-box RNA解旋酶c DNA全长序列,命名为EaRH1,并在Gen Bank注册登记（KJ734026）。序列分析显示：该c DNA全长3 230 bp,包含一个从487 bp到2 799 bp编码770个氨基酸的开放读码框,其对应的蛋白序列包含9个保守模块结构。EaRH1与其它物种DEAD-box RNA解旋酶蛋白序列比对结果显示：模块Ⅰa、Ⅱ和Ⅲ序列几乎完全相同,模块Q、Ⅰ和Ⅳ序列存在一些差异。EaRH1与江南卷柏（Selaginella moellendorffii）基因组一条假定序列相似度高达69%,其中相似度最高的区域集中在包含9个保守模块的结构域。系统进化树分析显示：EaRH1与拟南芥（Arabidopsis thaliana）DEAD-box RNA解旋酶At3g22320在氨基酸序列上有相对较高的同源性。序列结构比较和进化分析可推测出EaRH1可能参与植物体生长发育、miRNA生物合成、与RNA结合蛋白的相互作用和非生物胁迫应答。本文的研究为探索问荆DEAD-box RNA解旋酶的进一步功能提供参考。     

蕨类植物问荆DEAD box RNA解旋酶基因的克隆与分析

DEAD box RNA解旋酶参与RNA多方面的代谢,在植物生长发育和逆境反应中起重要作用。本研究从蕨类植物问荆(Equisetum arvense)中克隆到一条DEAD box RNA解旋酶cDNA全长序列,命名为EaRH1,并在GenBank注册登记（KJ734026）。序列分析显示：该cDNA全长3230bp,包含一个从487bp到2799bp编码770个氨基酸的开放读码框,其对应的蛋白序列包含9个保守模块结构。EaRH1与其它物种DEAD box RNA 解旋酶蛋白序列比对结果显示：模块Ⅰa、Ⅱ和Ⅲ序列几乎完全相同,模块Q、Ⅰ和 Ⅳ序列存在一些差异。EaRH1与江南卷柏(Selaginella moellendorffii)基因组一条假定序列相似度高达69%,其中相似度最高的区域集中在包含9个保守模块的结构域。系统进化树分析显示：EaRH1与拟南芥(Arabidopsis thaliana)DEAD box RNA解旋酶At3g22320在氨基酸序列上有相对较高的同源性。序列结构比较和进化分析可推测出EaRH1可能参与植物体生长发育、miRNA生物合成、与RNA结合蛋白的相互作用和非生物胁迫应答。本文的研究为探索问荆DEAD box RNA解旋酶的进一步功能提供参考。     

Crystallographic structure of the amino terminal domain of yeast initiation factor 4A, a representative DEAD-box RNA helicase

The eukaryotic translation initiation factor 4A (elF4A) is a representative of the DEAD-box RNA helicase protein family. We have solved the crystallographic structure of the amino-terminal domain (residues 1-223) of yeast elF4A. The domain is built around a core scaffold, a parallel alpha-beta motif with five beta strands, that is found in other RNA and DNA helicases, as well as in the RecA protein. The amino acid sequence motifs that are conserved within the helicase family are localized to the beta strand-->alpha helix junctions within the core. The core of the amino terminal domain of elF4A is amplified with additional structural elements that differ from those of other helicases. The phosphate binding loop (the Walker A motif) is in an unusual closed conformation. The crystallographic structure reveals specific interactions between amino acid residues of the phosphate binding loop, the DEAD motif, and the SAT motif, whose alteration is known to impair coupling between the ATPase cycle and the RNA unwinding activity of elF4A.     

A suppressor of yeast spp81/ded1 mutations encodes a very similar putative ATP-dependent RNA helicase

The spp81/ded1 mutations were isolated as suppressors of a Saccharomyces cerevisiae pre-mRNA splicing mutation, prp8-1. The SPP81/DED1 gene encodes a putative ATP-dependent RNA helicase. While attempting to clone the wild-type SPP81/DED1 gene we isolated plasmids which were able to suppress the cold-sensitive growth defect of spp81 mutants. These plasmids encoded a gene (named DBP1) which mapped to chromosome XVI and not to the SPP81/DED1 locus on chromosome XV. The cloned gene suppressed the defect of spp81/ded1 mutants when present on both high and low copy-number plasmids but complemented spp81/ded1 null mutants only when present on high copy-number plasmids. In contrast to the SPP81/DED1 gene the DBP1 gene was not essential for cell viability. The nucleotide sequence of the DBP1 gene revealed that it also encoded a putative ATP-dependent RNA helicase which showed considerable similarity at the amino acid level to the SPP81/DED1 protein.     

Molecular cloning and characterization of a putative nuclear DEAD box RNA helicase in the spruce budworm, Choristoneura fumiferana

RNA helicases play important roles in cellular processes such as pre-mRNA splicing, rRNA processing, ribosomal biogenesis, and translation. A full-length DEAD box RNA helicase cDNA (CfrHlc113) was isolated from the spruce budworm, Choristoneura fumiferana. CfrHlc113 contained the eight functional motifs, which are highly conserved in the DEAD box RNA helicase family, and an arginine-serine-aspartate (RSD) domain at its N-terminal end. CfrHlc113 was highly homologous to Rattus norvegicus HEL117 and human prp5 genes, both of which are suggested to be involved in RNA splicing. The results of Northern and Western blotting showed that expression of the CfrHlc113 gene was low or undetectable in eggs, larvae, pupae, and adults. High levels of expression were, however, detected in the three in vitro cultured cell lines, CF-203, CF-124T, and CF-70, which were developed from the midgut, ovaries, and neonate larvae, respectively. Immunocytochemistry revealed that CfrHlc113 protein was present exclusively in the nuclei of these cell lines.     

Comprehensive mutational analysis of yeast DEXD/H box RNA helicases involved in large ribosomal subunit biogenesis

DEXD/H box putative RNA helicases are required for pre-rRNA processing in Saccharomyces cerevisiae, although their exact roles and substrates are unknown. To characterize the significance of the conserved motifs for helicase function, a series of five mutations were created in each of the eight essential RNA helicases (Has1, Dbp6, Dbp10, Mak5, Mtr4, Drs1, Spb4, and Dbp9) involved in 60S ribosomal subunit biogenesis. Each mutant helicase was screened for the ability to confer dominant negative growth defects and for functional complementation. Different mutations showed different degrees of growth inhibition among the helicases, suggesting that the conserved regions do not function identically in vivo. Mutations in motif I and motif II (the DEXD/H box) often conferred dominant negative growth defects, indicating that these mutations do not interfere with substrate binding. In addition, mutations in the putative unwinding domains (motif III) demonstrated that conserved amino acids are often not essential for function. Northern analysis of steady-state RNA from strains expressing mutant helicases showed that the dominant negative mutations also altered pre-rRNA processing. Coimmunoprecipitation experiments indicated that some RNA helicases associated with each other. In addition, we found that yeasts disrupted in expression of the two nonessential RNA helicases, Dbp3 and Dbp7, grew worse than when either one alone was disrupted.     

The DEAD box RNA helicase VBH-1 is required for germ cell function in C. elegans

Vasa and Belle are conserved DEAD box RNA helicases required for germ cell function. Homologs of this group of proteins in several species, including mammals, are able to complement a mutation in yeast (DED1) suggesting that their function is highly conserved. It has been proposed that these proteins are required for mRNA translation regulation, but their specific mechanism of action is still unknown. Here we describe functions of VBH-1, a C. elegans protein closely related to Belle and Vasa. VBH-1 is expressed specifically in the C. elegans germline, where it is associated with P granules, the C. elegans germ plasm counterpart. vbh-1(RNAi) animals produce fewer offspring than wild type because of defects in oocyte and sperm production, and embryonic lethality. We also find that VBH-1 participates in the sperm/oocyte switch in the hermaphrodite gonad. We conclude that VBH-1 and its orthologs may perform conserved roles in fertility and development.     

The motif V of plum pox potyvirus CI RNA helicase is involved in NTP hydrolysis and is essential for virus RNA replication.

The plum pox potyvirus (PPV) protein CI is an RNA helicase whose function in the viral life cycle is still unknown. The CI protein contains seven conserved sequence motifs typical of RNA helicases of the superfamily SF2. We have introduced several individual point mutations into the region coding for motif V of the PPV CI protein and expressed these proteins in Escherichia coli as maltose binding protein fusions. Mutations that abolished RNA helicase activity also disturbed NTP hydrolysis. No mutations affected the RNA binding capacity of the CI protein. These mutations were also introduced in the PPV genome making use of a full-length cDNA clone. Mutant viruses carrying CI proteins with reduced RNA helicase activity replicated very poorly in protoplasts and were unable to infect whole plants without rapid pseudoreversion to wild-type. These results indicate that motif V is involved in the NTP hydrolysis step required for potyvirus RNA helicase activity, and that this activity plays an essential role in virus RNA replication inside the infected cell.     

D-E-A-D protein family of putative RNA helicases

RNA metabolism plays a central role in cell growth. It is essential to regulate RNA synthesis, processing, stability and degradation. Conformational changes in RNA are key elements in regulating cellular processes. Recently, an increasing number of putative RNA helicases from different organisms ranging from Escherichia coli to humans and viruses have been identified. They are involved in diverse cellular functions such as RNA splicing, ribosome assembly, initiation of translation, spermatogenesis, embryogenesis, and cell growth and division. Based on sequence homologies these proteins were grouped in a family, the D-E-A-D box protein family (D-E-A-D = Asp-Glu-Ala-Asp). Some of the better characterized members have been shown to possess ATP-binding and hydrolysing activities as well as ATP-dependent RNA helicase activities. Most of the genes encoding such proteins have been isolated from yeast, on which we will focus in this review. From sequence data, three of the members form a subfamily, the D-E-A-H subfamily.     

Cloning and characterization of a human DEAH-box RNA helicase, a functional homolog of fission yeast Cdc28/Prp8.

During the splicing process, spliceosomal snRNAs undergo numerous conformational rearrangements that appear to be catalyzed by proteins belonging to the DEAD/H-box superfamily of RNA helicases. We have cloned a new RNA helicase gene, designated DBP2 (DEAH-boxprotein), homologous to the Schizosaccaromyces pombe cdc28(+)/prp8(+) gene involved in pre-mRNA splicing and cell cycle progression. The full-length DBP2 contains 3400 nucleotides and codes for a protein of 1041 amino acids with a calculated mol. wt of 119 037 Da. Transfection experiments demonstrated that the GFP-DBP2 gene product, transiently expressed in HeLa cells, was localized in the nucleus. The DBP2 gene was mapped by FISH to the MHC region on human chromosome 6p21.3, a region where many malignant, genetic and autoimmune disease genes are linked. Because the expression of DBP2 gene in S.pombe prp8 mutant cells partially rescued the temperature-sensitive phenotype, we conclude that DBP2 is a functional human homolog of the fission yeast Cdc28/Prp8 protein.     

p68 RNA helicase: identification of a nucleolar form and cloning of related genes containing a conserved intron in yeasts.

The human p68 protein is an RNA-dependent ATPase and RNA helicase which was first identified because of its immunological cross-reaction with a viral RNA helicase, simian virus 40 large T antigen. It belongs to a recently discovered family of proteins (DEAD box proteins) that share extensive regions of amino acid sequence homology, are ubiquitous in living organisms, and are involved in many aspects of RNA metabolism, including splicing, translation, and ribosome assembly. We have shown by immunofluorescent microscopy that mammalian p68, which is excluded from the nucleoli during interphase, translocates to prenucleolar bodies during telophase. We have cloned 55% identical genes from both Schizosaccharomyces pombe and Saccharomyces cerevisiae and shown that they are essential in both yeasts. The human and yeast genes contain a large intron whose position has been precisely conserved. In S. cerevisiae, the intron is unusual both because of its size and because of its location near the 3' end of the gene. We discuss possible functional roles for such an unusual intron in an RNA helicase gene.     

Hepatitis C virus core protein interacts with cellular putative RNA helicase

The nucleocapsid core protein of hepatitis C virus (HCV) has been shown to trans-act on several viral or cellular promoters. To get insight into the trans-action mechanism of HCV core protein, a yeast two-hybrid cloning system was used for identification of core protein-interacting cellular protein. One such cDNA clone encoding the DEAD box family of putative RNA helicase was obtained. This cellular putative RNA helicase, designated CAP-Rf, exhibits more than 95% amino acid sequence identity to other known RNA helicases including human DBX and DBY, mouse mDEAD3, and PL10, a family of proteins generally involved in translation, splicing, development, or cell growth. In vitro binding or in vivo coimmunoprecipitation studies demonstrated the direct interaction of the full-length/matured form and C-terminally truncated variants of HCV core protein with this targeted protein. Additionally, the protein's interaction domains were delineated at the N-terminal 40-amino-acid segment of the HCV core protein and the C-terminal tail of CAP-Rf, which encompassed its RNA-binding and ATP hydrolysis domains. Immunoblotting or indirect immunofluorescence analysis revealed that the endogenous CAP-Rf was mainly localized in the nucleus and to a lesser extent in the cytoplasm, and when fused with FLAG tag, it colocalized with the HCV core protein either in the cytoplasm or in the nucleus. Similar to other RNA helicases, this cellular RNA helicase has nucleoside triphosphatase-deoxynucleoside triphosphatase activity, but this activity is inhibited by various forms of homopolynucleotides and enhanced by the HCV core protein. Moreover, transient expression of HCV core protein in human hepatoma HuH-7 cells significantly potentiated the trans-activation effect of FLAG-tagged CAP-Rf or untagged CAP-Rf on the luciferase reporter plasmid activity. All together, our results indicate that CAP-Rf is involved in regulation of gene expression and that HCV core protein promotes the trans-activation ability of CAP-Rf, likely via the complex formation and the modulation of the ATPase-dATPase activity of CAP-Rf. These findings provide evidence that HCV may have evolved a distinct mechanism in alteration of host cellular gene expression regulation via the interaction of its nucleocapsid core protein and cellular putative RNA helicase known to participate in all aspects of cellular processes involving RNA metabolism. This feature of core protein may impart pleiotropic effects on host cells, which may partially account for its role in HCV pathogenesis.     

Interaction of the plant glycine-rich RNA-binding protein MA16 with a novel nucleolar DEAD box RNA helicase protein from Zea mays

The maize RNA-binding MA16 protein is a developmentally and environmentally regulated nucleolar protein that interacts with RNAs through complex association with several proteins. By using yeast two-hybrid screening, we identified a DEAD box RNA helicase protein from Zea mays that interacted with MA16, which we named Z. maysDEAD box RNA helicase 1 (ZmDRH1). The sequence of ZmDRH1 includes the eight RNA helicase motifs and two glycine-rich regions with arginine-glycine-rich (RGG) boxes at the amino (N)- and carboxy (C)-termini of the protein. Both MA16 and ZmDRH1 were located in the nucleus and nucleolus, and analysis of the sequence determinants for their cellular localization revealed that the region containing the RGG motifs in both proteins was necessary for nuclear/nucleolar localization The two domains of MA16, the RNA recognition motif (RRM) and the RGG, were tested for molecular interaction with ZmDRH1. MA16 specifically interacted with ZmDRH1 through the RRM domain. A number of plant proteins and vertebrate p68/p72 RNA helicases showed evolutionary proximity to ZmDRH1. In addition, like p68, ZmDRH1 was able to interact with fibrillarin. Our data suggest that MA16, fibrillarin, and ZmDRH1 may be part of a ribonucleoprotein complex involved in ribosomal RNA (rRNA) metabolism.