The RecQ DNA helicases： Jacks-of-all-trades or master-tradesmen？

Homologous recombination occurs when a damaged chromosome uses an intact homologous chromosome as a template for its repair. The main steps of recombination are most readily illustrated for the repair of a DNA doublestrand-break （DSB）. First, DSB-ends are processed to form single-stranded tails, which assemble into nucleoprotein complexes comprising an oligomeric filament of a RecA-family protein （Rad51 in eukaryotes） and associated factors. Rad51 filaments catalyze homologous pairing and strand-exchange between a DSB-end and a double-stranded template to form a joint molecule intermediate. This structure allows de novo priming of DNA synthesis to restore sequences that were lost or damaged at the site of the original lesion. Recombination also underpins chromosome replication by facilitating the repair of broken replication forks. In this case, joint molecule formation allows rep- lication to reinitiate. At the final step of recombination, strand-exchange ＂Holliday＂ junctions that connect the involved chromosomes are resolved so that segregation can ensue. Joint molecule resolution can occur with one of two outcomes： a crossover, in which chromosome arms are exchanged; or a noncrossover without exchange.     

A fresh look at an antiviral helicase

In order to survive, all organisms must guard against viral infections. Recognition of viruses is accomplished via multiple sensors. Many mammalian proteins can recognize viral products, such as double-stranded RNA （dsRNA）, yet few of them are known to induce interferon, the central antiviral messenger. Since interferon is indispensable for successful antiviral defense [1], the interferon-inducing sensors have been of particular interest. However, a clear understanding of such sensors has been elusive, and the first well-established sensor family, the toll-like receptors （TLRs）, was described relatively recently [2]. Antiviral TLRs are positioned in the endosomes, where they report the appearance of viral genetic material （DNA, single-and double-stranded RNA）. However, the question of potential virus sensors in the cytoplasm was left open. Given the particular effectiveness ofintracellular dsRNA at inducing interferon, it was suspected that dsRNA-binding sensor molecules would be found in the cytoplasm.[第一段]     

Preface

<正>Viral infections remain a global threat to world health in the twenty-first century. They are caused by both DNA and RNA viruses and can manifest as acute or chronic infections, in some cases causing epidemics or even global pandemics.Persistent viral infections lead to host immunodeficiency and the development of ～12% of human cancers worldwide.     

The revolution of the biology of the genome

Sequence data of entire eukaryotic genomes and their detailed comparison have provided new evidence on genome evolution. The major mechanisms involved in the increase of genome sizes are polyploidization and gene duplication.Subsequent gene silencing or mutations, preferentially in regulatory sequences of genes, modify the genome and permit the development of genes with new properties. Mechanisms such as lateral gene transfer, exon shuffling or the creation of new genes by transposition contribute to the evolution of a genome, but remain of relatively restricted relevance.Mechanisms to decrease genome sizes and, in particular, to remove specific DNA sequences, such as blocks of satellite DNAs, appear to involve the action of RNA interference (RNAi). RNAi mechanisms have been proven to be involved in chromatin packaging related with gene inactivation as well as in DNA excision during the macronucleus development in ciliates.     

A natural communication system on genome evolution

正The central dogma of molecular biology describes the flow of genetic information from DNA via RNA to protein and duplication from ancestral to descendent DNA(Crick,1958).However,the genetic information could not be quantified and mathematically modeled.So it differs from the"information"formulated by Shannon and used in information and coding theories(Shannon,1949).Although physicists have suggested that life absorbs negative entropy(or information)from the environment(Schrodinger et al.,1944),no physical     

Validation of the diagnostic potential of mtDNA copy number derived from whole genome sequencing

正Diagnosis of mitochondrial DNA(mt DNA)disorders has traditionally been focused on the presence of point mutations and large deletions.However,deviations in mitochondrial abundance or mt DNA copy number can also be associated with many physiological and pathological conditions(Bai and Wong,2005).For example,reduced mt DNA copy number could be a result of defective mt DNA biosynthesis or mt DNA replication and is associated     

Nuclear DNA helicase II (RNA helicase A) binds to an F-actin containing shell that surrounds the nucleolus

Nuclear DNA helicase II (NDH II), alternatively named RNA helicase A (RHA), is an F-actin binding protein that is particularly enriched in the nucleolus of mouse cells. Here, we show that the nucleolar localization of NDH II of murine 3T3 cells depended on an ongoing rRNA synthesis. NDH II migrated out of the nucleolus after administration of 0.05 microg/ml actinomycin D, while nucleolin and the upstream binding factor (UBF) remained there. In S phase-arrested mouse cells, NDH II was frequently found at the nucleolar periphery, where it was accompanied by newly synthesized nucleolar RNA. Human NDH II was mainly distributed through the whole nucleoplasm and not enriched in the nucleoli. However, in the human breast carcinoma cell line MCF-7, NDH II was also found at the nucleolar periphery, together with the tumor suppressor protein p53. Both NDH II and p53 were apparently attached to the F-actin-based filamentous network that surrounded the nucleoli. Accordingly, this subnuclear structure was sensitive to F-actin depolymerizing agents. Depolymerization with gelsolin led to a striking accumulation of NDH II in the nucleoli of MCF-7 cells. This effect was abolished by RNase, which extensively released nucleolus-bound NDH II when added together with gelsolin. Taken together, these results support the idea that an actin-based filamentous network may anchor NDH II at the nucleolar periphery for pre-ribosomal RNA processing, ribosome assembly, and/or transport.     

DNA-dependent protein kinase (DNA-PK) phosphorylates nuclear DNA helicase II/RNA helicase A and hnRNP proteins in an RNA-dependent manner

An RNA-dependent association of Ku antigen with nuclear DNA helicase II (NDH II), alternatively named RNA helicase A (RHA), was found in nuclear extracts of HeLa cells by immunoprecipitation and by gel filtration chromatography. Both Ku antigen and NDH II were associated with hnRNP complexes. Two-dimensional gel electrophoresis showed that Ku antigen was most abundantly associated with hnRNP C, K, J, H and F, but apparently not with others, such as hnRNP A1. Unexpectedly, DNA-dependent protein kinase (DNA-PK), which comprises Ku antigen as the DNA binding subunit, phosphorylated hnRNP proteins in an RNA-dependent manner. DNA-PK also phosphorylated recombinant NDH II in the presence of RNA. RNA binding assays displayed a preference of DNA-PK for poly(rG), but not for poly(rA), poly(rC) or poly(rU). This RNA binding affinity of DNA-PK can be ascribed to its Ku86 subunit. Consistently, poly(rG) most strongly stimulated the DNA-PK-catalyzed phosphorylation of NDH II. RNA interference studies revealed that a suppressed expression of NDH II altered the nuclear distribution of hnRNP C, while silencing DNA-PK changed the subnuclear distribution of NDH II and hnRNP C. These results support the view that DNA-PK can also function as an RNA-dependent protein kinase to regulate some aspects of RNA metabolism, such as RNA processing and transport.     

Werner syndrome helicase (WRN), nuclear DNA helicase II (NDH II) and histone gammaH2AX are localized to the centrosome

Werner syndrome helicase (WRN) was found in the centrosome of human cells, both in interphase and in mitosis. Nuclear DNA helicase II (NDH II), also called RNA helicase A (RHA), an interaction partner of WRN, was also present in the centrosome. NDH II localized to the centrosome in interphase but left the centrosome with the ongoing progression of mitosis. The localization of NDH II to the centrosome was hardly affected by cytochalasin D that depolymerizes actin filaments. In contrast, treatment by the microtubules disrupting agent nocodazole strikingly detached NDH II from the centrosome, which was in contrast to WRN that remained there under this condition. Treatment of cells with the DNA damaging agent 4-nitroquinoline-1-oxide (4NQO) released NDH II, but not WRN from the centrosome. Surprisingly, the double-stranded DNA break repair-induced histone variant gammaH2AX was also found in centrosomes of interphase and mitotic cells. Following DNA damage by 4NQO, gammaH2AX left the centrosome with similar kinetics as NDH II. In vitro pull-down assays confirmed a direct physical interaction between these two proteins. Since NDH II associated with gammaH2AX after DNA damage, we suggest that complex formation between NDH II and gammaH2AX may occur in pre-assembled complexes at the centrosome, which are subsequently recruited to sites of damaged DNA for inducing the repair process.     

Re-localization of nuclear DNA helicase II during the growth period of bovine oocytes

Nuclear DNA helicase II (NDH II) is the bovine homolog of human RNA helicase A. The aim of this study was to compare NDH II localization between somatic cells (bovine embryonal fibroblasts) and female germ cells (oocytes), with the main focus on the dynamic changes in the redistribution of NDH II during the growth phase of the bovine oocytes. The fine granular staining of NDH II was spread in the whole nucleoplasm of fibroblasts, excluding the reticulated nucleoli. In contrast, the large reticulated nucleoli of the growing oocytes isolated from early antral follicles exhibited strong positivity for NDH II together with the immunostaining signals of upstream binding factor (UBF) and RNA polymerase I subunit (PAF53), documenting the high synthetic activity of these nucleoli. At the time of termination of oocyte growth, NDH II was preferentially located at the nucleolar periphery together with proteins of fibrillar centres. In fully grown oocytes, NDH II was still present in the thin periphery shell around the compact nucleolar core. The semiquantitative RT-PCR revealed that the average signal of NDH II mRNA in fully grown oocytes was only at 40% level in comparison with growing oocytes. Western blot analysis further confirmed that a 140 kD NDH II protein was abundant in growing oocytes, while the signal was substantially weaker in fully grown oocytes. The significant decrease in NDH II gene expression and in NDH II mRNA translation correlates with a termination of the oocyte growth. Altogether, the results demonstrate that NDH II expression parallels the activity of ribosomal RNA biosynthesis in the bovine growing oocytes.     

Solution structures of the double-stranded RNA-binding domains from RNA helicase A

RNA helicase A (RHA) is a highly conserved protein with multifaceted functions in the gene expression of cellular and viral mRNAs. RHA recognizes highly structured nucleotides and catalytically rearranges the various interactions between RNA, DNA, and protein molecules to provide a platform for the ribonucleoprotein complex. We present the first solution structures of the double-stranded RNA-binding domains (dsRBDs), dsRBD1 and dsRBD2, from mouse RHA. We discuss the binding mode of the dsRBDs of RHA, in comparison with the known dsRBD structures in their complexes. Our structural data provide important information for the elucidation of the molecular reassembly mediated by RHA.