Cloning and expression analysis of the chicken DEAD box gene DDX1

DEAD box proteins are putative RNA unwinding proteins found in organisms ranging from mammals to bacteria. While some DEAD box genes expressed in higher eukaryotes are ubiquitous, others have distribution profiles that suggest a cell-, tissue-, or developmental-specific role. The DEAD box gene, DDX1, was identified by differential screening of a subtracted retinoblastoma cDNA library. A limited survey of human fetal tissues indicated that DDX1 mRNA has a widespread distribution but is not uniformly expressed in all tissues. To further document the spatial and temporal distribution of DDX1 during embryonic development, we cloned the chicken DDX1 cDNA. The predicted amino acid sequence of chicken DDX1 was 93% identical to that of human DDX1. All DEAD box motifs, as well as a SPRY domain, were present in chicken DDX1. Northern and Western blot analyses showed highest levels of DDX1 at early stages of development. Tissue maturation was generally accompanied by a decrease in expression, although DDX1 levels remained elevated in late embryonic retina and brain. In situ hybridization of retinal tissue sections revealed widespread distribution of DDX1 mRNA at early developmental stages with preferential expression in amacrine and ganglion cells of the differentiated tissue. Preferential expression of DDX1 was also observed in specific areas of the brain in older embryos, such as the external granule layer of the cerebellum. These results suggest a specific role for DDX1 in subsets of differentiated cells as well as a more general role in undifferentiated cells.     

人DDX36和小鼠Ddx36基因在成年睾丸组织中的表达研究

果蝇是结构基因组学和功能基因组学研究的最为理想的一种模式生物,采用同源克隆的策略,应用生物信息学分析和实验技术相结合的方法分别从人和小鼠中克隆了同源于果蝇MLE蛋白的新基因DDX36和Ddx36。为进一步研究DDX36和Ddx36基因与精子发生的关系,再应用Northrn blotting,RT-PCR和组织原位杂交技术探讨了DDX36和Ddx36基因的表达情况,结果发现人DDX36和小鼠Ddx36基因在成年睾丸组织中高表达。初步证明DDX36和Ddx36基因在精子发生中亦可能发挥重要作用。     

DEAD box 1 (DDX1) protein binds to and protects cytoplasmic stress response mRNAs in cells exposed to oxidative stress

The integrated stress response is a network of highly orchestrated pathways activated when cells are exposed to environmental stressors. While global repression of translation is a well-recognized hallmark of the integrated stress response, less is known about the regulation of mRNA stability during stress. DEAD box proteins are a family of RNA unwinding/remodeling enzymes involved in every aspect of RNA metabolism. We previously showed that DEAD box 1 (DDX1) protein accumulates at DNA double-strand breaks during genotoxic stress and promotes DNA double-strand break repair via homologous recombination. Here, we examine the role of DDX1 in response to environmental stress. We show that DDX1 is recruited to stress granules (SGs) in cells exposed to a variety of environmental stressors, including arsenite, hydrogen peroxide, and thapsigargin. We also show that DDX1 depletion delays resolution of arsenite-induced SGs. Using RNA immunoprecipitation sequencing, we identify RNA targets bound to endogenous DDX1, including RNAs transcribed from genes previously implicated in stress responses. We show the amount of target RNAs bound to DDX1 increases when cells are exposed to stress, and the overall levels of these RNAs are increased during stress in a DDX1-dependent manner. Even though DDX1’s RNA-binding property is critical for maintenance of its target mRNA levels, we found RNA binding is not required for localization of DDX1 to SGs. Furthermore, DDX1 knockdown does not appear to affect RNA localization to SGs. Taken together, our results reveal a novel role for DDX1 in maintaining cytoplasmic mRNA levels in cells exposed to oxidative stress.     

DDX3 acts as a tumor suppressor in colorectal cancer as loss of DDX3 in advanced cancer promotes tumor progression by activating the MAPK pathway

Objective: The treatment and prognosis of patients with advanced colorectal cancer (CRC) remain a difficult problem. Herein, we investigated the role of DEAD (Asp-Glu-Ala-Asp) box helicase 3 (DDX3) in CRC and proposed potential therapeutic targets for advanced CRC.Methods: The expression of DDX3 in CRC and its effect on prognosis were explored by databases and CRC tissue microarrays. Stable DDX3 knockdown and overexpression cell lines were established with lentiviral vectors. The effects of DDX3 on CRC were investigated by functional experiments in vitro and in vivo. The molecular mechanism of DDX3 in CRC was explored by western blotting. Molecular-specific inhibitors were further used to explore potential therapeutic targets for advanced CRC.Results: The expression of DDX3 was decreased in advanced CRC, and patients with low DDX3 expression had a poor prognosis. In vitro and in vivo experiments showed that low DDX3 expression promoted the proliferation, migration and invasion of CRC. DDX3 loss regulated E-cadherin and β-catenin signaling through the mitogen-activated protein kinase (MAPK) pathway as shown by western blotting. In addition, the MEK inhibitor, PD98059, significantly reduced the increased cell proliferation, migration and invasion caused by knockdown of DDX3.Conclusions: DDX3 acts as a tumor suppressor gene in CRC. DDX3 loss in advanced cancer promotes cancer progression by regulating E-cadherin and β-catenin signaling through the MAPK pathway, and targeting the MAPK pathway may be a therapeutic approach for advanced CRC.     

Association of human DEAD box protein DDX1 with a cleavage stimulation factor involved in 3'-end processing of pre-MRNA

DEAD box proteins are putative RNA helicases that function in all aspects of RNA metabolism, including translation, ribosome biogenesis, and pre-mRNA splicing. Because many processes involving RNA metabolism are spatially organized within the cell, we examined the subcellular distribution of a human DEAD box protein, DDX1, to identify possible biological functions. Immunofluorescence labeling of DDX1 demonstrated that in addition to widespread punctate nucleoplasmic labeling, DDX1 is found in discrete nuclear foci approximately 0.5 microm in diameter. Costaining with anti-Sm and anti-promyelocytic leukemia (PML) antibodies indicates that DDX1 foci are frequently located next to Cajal (coiled) bodies and less frequently, to PML bodies. Most importantly, costaining with anti-CstF-64 antibody indicates that DDX1 foci colocalize with cleavage bodies. By microscopic fluorescence resonance energy transfer, we show that labeled DDX1 resides within a F?rster distance of 10 nm of labeled CstF-64 protein in both the nucleoplasm and within cleavage bodies. Coimmunoprecipitation analysis indicates that a proportion of CstF-64 protein resides in the same complex as DDX1. These studies are the first to identify a DEAD box protein associating with factors involved in 3'-end cleavage and polyadenylation of pre-mRNAs.     

Tau/DDX6 interaction increases microRNA activity

Tauopathies, such as Alzheimer's disease, are characterized by intracellular aggregates of insoluble Tau proteins. Originally described as a microtubule binding protein, recent studies demonstrated additional physiological roles for Tau. The fact that a single protein can regulate multiple cellular functions has posed challenge in terms of understanding mechanistic cues behind the pathology. Here, we used tandem-affinity purification methodology coupled to mass spectrometry to identify novel interaction partners. We found that Tau interacts with DDX6, a DEAD box RNA helicase involved in translation repression and mRNA decay as well as in the miRNA pathway. Our results demonstrate that Tau increases the silencing activity of the miRNA let-7a, miR-21 and miR-124 through DDX6. Importantly, Tau mutations (P301S, P301L) found in the inherited tauopathies, frontotemporal dementia and parkinsonism linked to chromosome 17, disrupt Tau/DDX6 interaction and impair gene silencing by let-7a. Altogether, these data demonstrated a new unexpected role for Tau in regulating miRNA activity.     

Analog sensitive chemical inhibition of the DEAD‐box protein DDX3

Proper maintenance of RNA structure and dynamics is essential to maintain cellular health. Multiple families of RNA chaperones exist in cells to modulate RNA structure, RNA–protein complexes, and RNA granules. The largest of these families is the DEAD‐box proteins, named after their catalytic Asp‐Glu‐Ala‐Asp motif. The human DEAD‐box protein DDX3 is implicated in diverse biological processes including translation initiation and is mutated in numerous cancers. Like many DEAD‐box proteins, DDX3 is essential to cellular health and exhibits dosage sensitivity, such that both decreases and increases in protein levels can be lethal. Therefore, chemical inhibition would be an ideal tool to probe the function of DDX3. However, most DEAD‐box protein active sites are extremely similar, complicating the design of specific inhibitors. Here, we show that a chemical genetic approach best characterized in protein kinases, known as analog‐sensitive chemical inhibition, is viable for DDX3 and possibly other DEAD‐box proteins. We present an expanded active‐site mutant that is tolerated in vitro and in vivo, and is sensitive to chemical inhibition by a novel bulky inhibitor. Our results highlight a course towards analog sensitive chemical inhibition of DDX3 and potentially the entire DEAD‐box protein family.     

The expression of RNA helicase DDX5 is transcriptionally upregulated by calcitriol through a vitamin D response element in the proximal promoter in SiHa cervical cells

Molecular and Cellular Biochemistry - The DEAD box RNA helicase DDX5 is a multifunctional protein involved in the regulatory events of gene expression. Herein, we presented evidence indicating that...     

DDX6 localizes to nuage structures and the annulus of mammalian spermatogenic cells

The localization of DEAD (Asp-Glu-Ala-Asp) box helicase 6 (DDX6) in spermatogenic cells from the mouse, rat, and guinea pig was studied by immunofluorescence (IF) and immunoelectron microscopy (IEM). Spermatogenic cells from these species yielded similar DDX6 localization pattern. IF microscopy results showed that DDX6 localizes to both the nucleus and cytoplasm. In the cytoplasm of spermatogenic cells, diffuse cytosolic and discrete granular staining was observed, with the staining pattern changing during cell differentiation. IEM revealed that DDX6 localized to the five different types of nuage structures and non-nuage structures, including small granule aggregate and late spermatid annuli. Nuclear labeling was strongest in leptotene and zygotene spermatocytes and moderately strong in the nuclear pocket of late spermatids. DDX6 also localized to the surface of outer dense fibers, which comprise of flagella. The results show that DDX6 is present in nuage and non-nuage structures as well as nuclei, suggesting that DDX6 has diverse functions in spermatogenic cells.     

Hepatitis C virus core protein abrogates the DDX3 function that enhances IPS-1-mediated IFN-beta induction

The DEAD box helicase DDX3 assembles IPS-1 (also called Cardif, MAVS, or VISA) in non-infected human cells where minimal amounts of the RIG-I-like receptor (RLR) protein are expressed. DDX3 C-terminal regions directly bind the IPS-1 CARD-like domain as well as the N-terminal hepatitis C virus (HCV) core protein. DDX3 physically binds viral RNA to form IPS-1-containing spots, that are visible by confocal microscopy. HCV polyU/UC induced IPS-1-mediated interferon (IFN)-beta promoter activation, which was augmented by co-transfected DDX3. DDX3 spots localized near the lipid droplets (LDs) where HCV particles were generated. Here, we report that HCV core protein interferes with DDX3-enhanced IPS-1 signaling in HEK293 cells and in hepatocyte Oc cells. Unlike the DEAD box helicases RIG-I and MDA5, DDX3 was constitutively expressed and colocalized with IPS-1 around mitochondria. In hepatocytes (O cells) with the HCV replicon, however, DDX3/IPS-1-enhanced IFN-beta-induction was largely abrogated even when DDX3 was co-expressed. DDX3 spots barely merged with IPS-1, and partly assembled in the HCV core protein located near the LD in O cells, though in some O cells IPS-1 was diminished or disseminated apart from mitochondria. Expression of DDX3 in replicon-negative or core-less replicon-positive cells failed to cause complex formation or LD association. HCV core protein and DDX3 partially colocalized only in replicon-expressing cells. Since the HCV core protein has been reported to promote HCV replication through binding to DDX3, the core protein appears to switch DDX3 from an IFN-inducing mode to an HCV-replication mode. The results enable us to conclude that HCV infection is promoted by modulating the dual function of DDX3.