Drosophila RecQ4 Has a 3��-5�� DNA Helicase Activity That Is Essential for Viability

Members of the RecQ family of proteins are highly conserved DNA helicases that have important functions in the maintenance of genomic stability. Deficiencies in RecQ4 have been linked to human diseases including Rothmund-Thomson, RAPADILINO, and Baller-Gerold syndromes, all of which are characterized by developmental defects, tumor propensity, and genetic instability. However, there are conflicting results shown in the literature regarding the DNA helicase activity of RecQ4. We report here the expression of Drosophila melanogaster RecQ4 with a baculoviral vector and its purification to near homogeneity. The purified protein has a DNA-dependent ATPase activity and is a 3′-5′ DNA helicase dependent on hydrolysis of ATP. The presence of 5′-adenylyl-β,γ-imidodiphosphate (AMPPNP), a nonhydrolyzable ATP analog, promotes stable complex formation between RecQ4 and single-stranded DNA. Drosophila RecQ4 can also anneal complementary single strands; this activity was reduced in the presence of AMPPNP, possibly because of the stable protein-DNA complex formed under such conditions. A point mutation of the highly conserved lysine residue in the helicase domain, although retaining the wild type level of annealing activity, inactivated ATPase and helicase activities and eliminated stable complex formation. These results suggest that the helicase domain alone is responsible for the DNA unwinding action of the Drosophila enzyme. We generated a null recq4 mutant that is homozygous lethal, which we used to test the genetic function of the helicase-dead mutant in flies. Complementation tests showed that the helicase-dead mutant recq4 transgenes are incapable of rescuing the null mutation, demonstrating that the helicase activity has an essential biological function.     

Sensitivity of RECQL4-deficient fibroblasts from Rothmund–Thomson syndrome patients to genotoxic agents

RECQ helicase protein-like 4 (RECQL4) is a member of the human RECQ family of DNA helicases. Two-thirds of patients with Rothmund–Thomson syndrome (RTS) carry biallelic inactivating mutations in the RECQL4 gene. RTS is an autosomal recessive disorder characterized by poikiloderma, sparse hair, small stature, skeletal abnormalities, cataracts, and an increased risk of cancer. Mutations in two other RECQ helicases, BLM and WRN, are responsible for the cancer predisposition conditions Bloom and Werner syndromes, respectively. Previous studies have shown that BLM and WRN-deficient cells demonstrate increased sensitivity to hydroxyurea (HU), camptothecin (CPT), and 4-nitroquinoline 1-oxide (4NQO). Little is known about the sensitivity of RECQL4-deficient cells to these and other genotoxic agents. The purpose of this study was to determine if RTS cells display any distinct cellular phenotypes in response to DNA damaging agents or replication blocks that could provide insight into the molecular function of the RECQL4 protein. Our results show that primary fibroblasts from RTS patients carrying two deleterious RECQL4 mutations, compared to wild type (WT) fibroblasts, have increased sensitivity to HU, CPT, and doxorubicin (DOX), modest sensitivity to other DNA damaging agents including ultraviolet (UV) irradiation, ionizing radiation (IR), and cisplatin (CDDP), and relative resistance to 4NQO. The RECQ family of DNA helicases has been implicated in the regulation of DNA replication, recombination, and repair. Because HU, CPT, and DOX exert their effects primarily during S phase, these results support a greater role for the RECQL4 protein in DNA replication as opposed to repair of exogenous damage. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Identification of new RECQL4 mutations in Caucasian Rothmund-Thomson patients and analysis of sensitivity to a wide range of genotoxic agents

Rothmund-Thomson syndrome (RTS), a rare recessive autosomal disorder, presents genome instability and clinical heterogeneity with growth deficiency, skin and bone defects, premature aging symptoms and cancer susceptibility. A subset of RTS patients presents mutations of the RECQL4 gene, member of the RecQ family of DNA helicases, including the RECQL2 (BLM) and RECQL3 (WRN) genes, defective in the cancer prone Bloom and Werner syndromes, respectively. Analysis of the RECQL4 gene in six clinically diagnosed RTS patients shows five patients, including two siblings, with eight mutations mainly located in the helicase domain, three patients presenting two mutations. The alterations include four missense mutations, one nonsense mutation and the same frameshift deletion, g.2881delG in exon 9 found in three patients. Seven RECQL4 polymorphisms, two being new, have also been identified. Primary RTS fibroblasts from these RTS patients show no sensitivity to a wide variety of genotoxic agents including ionizing or ultraviolet irradiation, nitrogen mustard, 4NQO, 8-MOP, Cis-Pt, MMC, H2O2, HU, or UV plus caffeine which could be related to the RECQL4 alterations identified here. This is in contrast with the DNA damage sensitive Bloom and Werner cells and highlights the complexity of the numerous RecQ protein functions implicated in the different cellular pathways required for maintaining genomic integrity.     

Nuclear import and retention domains in the amino terminus of RECQL4

Mutations in a human RecQ helicase homologue, RECQL4, have been identified in patients with Type II Rothmund-Thomson syndrome (RTS) with osteosarcoma predisposition, RAPADILINO syndrome, and Baller-Gerold syndrome. A role in DNA replication initiation has been demonstrated and mapped to the amino terminus upstream of the helicase domain; however, no nuclear localization signal (NLS) has been identified by sequence analysis. Here, we show both endogenous and green fluorescent protein (GFP)-tagged RECQL4 are nuclear and cytoplasmic in transformed cell lines. Using GFP-tagged constructs we identified a major nuclear localization domain within amino acids (aa) 363-492 (exons 5-8) sufficient for nuclear localization of GFP and necessary for nuclear localization of RECQL4 as GFP-RECQL4 deleted for aa 363-492 is entirely cytoplasmic. Additional mapping within this domain revealed that a conserved block of 22 basic amino acids (aa 365-386; exons 5-6) is sufficient for nuclear localization of GFP, but not required for nuclear import of RECQL4. Conversely, even though the region encoded by exon 7-8 is not sufficient for nuclear import of GFP, GFP-RECQL4 deleted for exon 7 (aa 420-463), a mutation found in all reported patients with RAPADILINO syndrome, is cytoplasmic. Nuclear localization of the exon 7 deletion construct is increased in cells treated with leptomycin B suggesting that exon 7 encodes a domain required for nuclear retention of RECQL4. This retention activity is partially conveyed by a conserved VLPLY motif (aa 450-454) in exon 7 of the human sequence. In summary, unlike other RecQ proteins with carboxyl terminal NLS, RECQL4 nuclear localization and retention activities are amino terminal. This location would provide nuclear transport of putative truncated proteins encoded by RTS mutant alleles consistent with the proposed essential replication function in the amino terminus of RECQL4.     

UAP56 is an important regulator of protein synthesis and growth in cardiomyocytes

UAP56, an ATP dependent RNA helicase that also has ATPase activity, is a DExD/H box protein that is phylogenetically grouped with the eukaryotic initiation factor eIF4A, the prototypical member of the DExD/H box family of helicases. UAP56, also known as BAT1, is an essential RNA splicing factor required for spliceosome assembly and mRNA export but its role in protein synthesis is not known. Here we demonstrate that UAP56 regulates protein synthesis and growth in cardiomyocytes. We found that wild-type (WT) UAP56 increased serum induced protein synthesis in HeLa cells. UAP56 mutants lacking ATPase and/or helicase activity inhibited protein synthesis compared with WT UAP56, suggesting that the ATPase and RNA helicase activity of UAP56 is important for protein synthesis. UAP56 siRNA inhibited phenylephrine (PE) induced protein synthesis in cardiomyocytes and inhibited PE induced cardiomyocyte hypertrophy. Our data demonstrate that UAP56 is an important regulator of protein synthesis and plays an important role in the regulation of cardiomyocyte growth.     

The RECQL4 protein,deficient in Rothmund–Thomson syndrome is active on telomeric D-loops containing DNA metabolism blocking lesions

Telomeres are critical for cell survival and functional integrity. Oxidative DNA damage induces telomeric instability and cellular senescence that are associated with normal aging and segmental premature aging disorders such as Werner Syndrome and Rothmund–Thomson Syndrome, caused by mutations in WRN and RECQL4 helicases respectively. Characterizing the metabolic roles of RECQL4 and WRN in telomere maintenance is crucial in understanding the pathogenesis of their associated disorders. We have previously shown that WRN and RECQL4 display a preference in vitro to unwind telomeric DNA substrates containing the oxidative lesion 8-oxoguanine. Here, we show that RECQL4 helicase has a preferential activity in vitro on telomeric substrates containing thymine glycol, a critical lesion that blocks DNA metabolism, and can be modestly stimulated further on a D-loop structure by TRF2, a telomeric shelterin protein. Unlike that reported for telomeric D-loops containing 8-oxoguanine, RECQL4 does not cooperate with WRN to unwind telomeric D-loops with thymine glycol, suggesting RECQL4 helicase is selective for the type of oxidative lesion. RECQL4's function at the telomere is not yet understood, and our findings suggest a novel role for RECQL4 in the repair of thymine glycol lesions to promote efficient telomeric maintenance.     

The N-terminal region of RECQL4 lacking the helicase domain is both essential and sufficient for the viability of vertebrate cells. Role of the N-terminal region of RECQL4 in cells

Rothmund-Thomson syndrome (RTS) is a rare genetic disorder characterized by premature aging, developmental abnormalities, and a predisposition to cancer. RTS is caused by mutations in the RECQL4 gene, which encodes one of the five human RecQ helicases. To identify the cellular functions of RECQL4, we generated a chicken DT40 cell line in which RECQL4 expression could be turned off by doxycycline (Dox). Upon exposure to Dox, cells stopped growing and underwent apoptosis. The cells could be rescued by expression of the N-terminal region of RECQL4 (amino acids 1-496), which lacks the helicase domain and has sequence similarity to yeast Sld2, which plays an essential function in the initiation of DNA replication in Saccharomyces cerevisiae. Smaller fragments of the N-terminal region of RECQL4 did not rescue the cells from lethality. RECQL4 gene knockout cells complemented with RECQL4 (1-496) showed relatively high sensitivity to DNA damaging agents that induce double strand breaks and cross-links, suggesting that the C-terminal region including the helicase domain of RECQL4 is involved in the repair of certain types of DNA lesions.     

The Rb/E2F pathway and Ras activation regulate RecQ helicase gene expression

Disruption of the Rb (retinoblastoma protein)/E2F cell-cycle pathway and Ras activation are two of the most frequent events in cancer, and both of these mutations place oncogenic stress on cells to increase DNA replication. In the present study, we demonstrate that these mutations have an additive effect on induction of members of the RecQ DNA helicase family. RecQ activity is important for genomic stability, initiation of DNA replication and telomere maintenance, and mutation of the BLM (Bloom's syndrome gene), WRN (Werner's syndrome gene) or RECQL4 (Rothmund-Thomson syndrome gene) family members leads to premature aging syndromes characterized by genetic instability and telomere loss. RecQ family members are frequently overexpressed in cancers, and overexpression of BLM has been shown to cause telomere elongation. Concomitant with induction of RecQ genes in response to Rb family mutation and Ras activation, we show an increase in the number of telomeric repeats. We suggest that this induction of RecQ genes in response to common oncogenic mutations may explain the up-regulation of the genes seen in cancers, and it may provide a means for transformed cells to respond to an increased demand for DNA replication.     

Helicase motif Ia is involved in single-strand DNA-binding and helicase activities of the herpes simplex virus type 1 origin-binding protein,UL9

UL9 is a multifunctional protein essential for herpes simplex virus type 1 (HSV-1) replication in vivo. UL9 is a member of the superfamily II helicases and exhibits helicase and origin-binding activities. It is thought that UL9 binds the origin of replication and unwinds it in the presence of ATP and the HSV-1 single-stranded DNA (ssDNA)-binding protein. We have previously characterized the biochemical properties of mutants in all helicase motifs except for motif Ia (B. Marintcheva and S. Weller, J. Biol. Chem. 276:6605-6615, 2001). Structural information for other superfamily I and II helicases indicates that motif Ia is involved in ssDNA binding. By analogy, we hypothesized that UL9 motif Ia is important for the ssDNA-binding function of the protein. On the basis of sequence conservation between several UL9 homologs within the Herpesviridae family and distant homology with helicases whose structures have been solved, we designed specific mutations in motif Ia and analyzed them genetically and biochemically. Mutant proteins with residues predicted to be involved in ssDNA binding (R112A and R113A/F115A) exhibited wild-type levels of intrinsic ATPase activity and moderate to severe defects in ssDNA-stimulated ATPase activity and ssDNA binding. The S110T mutation targets a residue not predicted to contact ssDNA directly. The mutant protein with this mutation exhibited wild-type levels of intrinsic ATPase activity and near wild-type levels of ssDNA-stimulated ATPase activity and ssDNA binding. All mutant proteins lack helicase activity but were able to dimerize and bind the HSV-1 origin of replication as well as wild-type UL9. Our results indicate that residues from motif Ia contribute to the ssDNA-binding and helicase activities of UL9 and are essential for viral growth. This work represents the successful application of an approach based on a combination of bioinformatics and structural information from related proteins to deduce valuable information about a protein of interest.     

Intrinsic ssDNA annealing activity in the C-terminal region of WRN

Werner syndrome (WS) is a rare autosomal recessive disorder in humans characterized by premature aging and genetic instability. WS is caused by mutations in the WRN gene, which encodes a member of the RecQ family of DNA helicases. Cellular and biochemical studies suggest that WRN plays roles in DNA replication, DNA repair, telomere maintenance, and homologous recombination and that WRN has multiple enzymatic activities including 3' to 5' exonuclease, 3' to 5' helicase, and ssDNA annealing. The goal of this study was to map and further characterize the ssDNA annealing activity of WRN. Enzymatic studies using truncated forms of WRN identified a C-terminal 79 amino acid region between the RQC and the HRDC domains (aa1072-1150) that is required for ssDNA annealing activity. Deletion of the region reduced or eliminated ssDNA annealing activity of the WRN protein. Furthermore, the activity appears to correlate with DNA binding and oligomerization status of the protein.     

Conserved helicase domain of human RecQ4 is required for strand annealing-independent DNA unwinding

Humans have five members of the well conserved RecQ helicase family: RecQ1, Bloom syndrome protein (BLM), Werner syndrome protein (WRN), RecQ4, and RecQ5, which are all known for their roles in maintaining genome stability. BLM, WRN, and RecQ4 are associated with premature aging and cancer predisposition. Of the three, RecQ4's biological and cellular roles have been least thoroughly characterized. Here we tested the helicase activity of purified human RecQ4 on various substrates. Consistent with recent results, we detected ATP-dependent RecQ4 unwinding of forked duplexes. However, our results provide the first evidence that human RecQ4's unwinding is independent of strand annealing, and that it does not require the presence of excess ssDNA. Moreover, we demonstrate that a point mutation of the conserved lysine in the Walker A motif abolished helicase activity, implying that not the N-terminal portion, but the helicase domain is solely responsible for the enzyme's unwinding activity. In addition, we demonstrate a novel stimulation of RecQ4's helicase activity by replication protein A, similar to that of RecQ1, BLM, WRN, and RecQ5. Together, these data indicate that specific biochemical activities and protein partners of RecQ4 are conserved with those of the other RecQ helicases.     

RECQL5 plays co-operative and complementary roles with WRN syndrome helicase

Humans have five RecQ helicases, whereas simpler organisms have only one. Little is known about whether and how these RecQ helicases co-operate and/or complement each other in response to cellular stress. Here we show that RECQL5 associates longer at laser-induced DNA double-strand breaks in the absence of Werner syndrome (WRN) protein, and that it interacts physically and functionally with WRN both in vivo and in vitro. RECQL5 co-operates with WRN on synthetic stalled replication fork-like structures and stimulates its helicase activity on DNA fork duplexes. Both RECQL5 and WRN re-localize from the nucleolus into the nucleus after replicative stress and significantly associate with each other during S-phase. Further, we show that RECQL5 is essential for cell survival in the absence of WRN. Loss of both RECQL5 and WRN severely compromises DNA replication, accumulates genomic instability and ultimately leads to cell death. Collectively, our results indicate that RECQL5 plays both co-operative and complementary roles with WRN. This is an early demonstration of a significant functional interplay and a novel synthetic lethal interaction among the human RecQ helicases.     

The N-terminal region of RECQL4 lacking the helicase domain is both essential and sufficient for the viability of vertebrate cells: Role of the N-terminal region of RECQL4 in cells

Rothmund-Thomson syndrome (RTS) is a rare genetic disorder characterized by premature aging, developmental abnormalities, and a predisposition to cancer. RTS is caused by mutations in the RECQL4 gene, which encodes one of the five human RecQ helicases. To identify the cellular functions of RECQL4, we generated a chicken DT40 cell line in which RECQL4 expression could be turned off by doxycycline (Dox). Upon exposure to Dox, cells stopped growing and underwent apoptosis. The cells could be rescued by expression of the N-terminal region of RECQL4 (amino acids 1-496), which lacks the helicase domain and has sequence similarity to yeast Sld2, which plays an essential function in the initiation of DNA replication in Saccharomyces cerevisiae. Smaller fragments of the N-terminal region of RECQL4 did not rescue the cells from lethality. RECQL4 gene knockout cells complemented with RECQL4 (1-496) showed relatively high sensitivity to DNA damaging agents that induce double strand breaks and cross-links, suggesting that the C-terminal region including the helicase domain of RECQL4 is involved in the repair of certain types of DNA lesions.     

RecQ family helicases in genome stability: Lessons from gene disruption studies in DT40 cells

Cells of all living organisms have evolved complex mechanisms to maintain genome stability. There is increasing evidence that spontaneous genomic instability occurs primarily during DNA replication. RecQ DNA helicases function during DNA replication and are essential for the maintenance of genome stability. In human cells, there exist five RecQ DNA helicases, and mutations of three of these helicases, encoded by the BLM, WRN and RECQL4 genes, give rise to the cancer predisposition disorders, Bloom syndrome (BS), Werner syndrome (WS), and Rothmund-Thomson syndrome (RTS), respectively. Individuals suffering from WS and RTS also show premature aging phenotypes. Although the two remaining helicases, RECQL1 and RECQL5, have not yet been associated with heritable human diseases, a single nucleotide polymorphism of RECQL1 is associated with reduced survival of pancreatic cancer, and RecQl5 knockout mice show a predisposition to cancer. Here, we review the functions eukaryotic RecQ helicases, focusing primarily on BLM in the maintenance of genome stability through various pathways of nucleic acid metabolism and with special reference to DNA replication.     

The human RecQ helicases BLM and RECQL4 cooperate to preserve genome stability

Bacteria and yeast possess one RecQ helicase homolog whereas humans contain five RecQ helicases, all of which are important in preserving genome stability. Three of these, BLM, WRN and RECQL4, are mutated in human diseases manifesting in premature aging and cancer. We are interested in determining to which extent these RecQ helicases function cooperatively. Here, we report a novel physical and functional interaction between BLM and RECQL4. Both BLM and RECQL4 interact in vivo and in vitro. We have mapped the BLM interacting site to the N-terminus of RECQL4, comprising amino acids 361-478, and the region of BLM encompassing amino acids 1-902 interacts with RECQL4. RECQL4 specifically stimulates BLM helicase activity on DNA fork substrates in vitro. The in vivo interaction between RECQL4 and BLM is enhanced during the S-phase of the cell cycle, and after treatment with ionizing radiation. The retention of RECQL4 at DNA double-strand breaks is shortened in BLM-deficient cells. Further, depletion of RECQL4 in BLM-deficient cells leads to reduced proliferative capacity and an increased frequency of sister chromatid exchanges. Together, our results suggest that BLM and RECQL4 have coordinated activities that promote genome stability.     

大肠杆菌RecQ解旋酶的表达纯化和生物学活性研究

RecQ家族解旋酶是DNA解旋酶中高度保守的一个重要家族,在维持染色体的稳定性中起着重要的作用.人类RecQ家族解旋酶突变会导致几种与癌症有关的疾病.本研究旨在诱导大肠杆菌RecQ解旋酶体外表达,并应用生物化学和生物物理学技术研究大肠杆菌RecQ解旋酶的生物学活性. 体外诱导表达获得纯度达90% 以上并具有高活性的大肠杆菌重组RecQ解旋酶,其可溶性好;经生物学活性分析显示具有DNA结合活性、ATP依赖的DNA解链活性、DNA依赖的ATP酶活性. 较之双链DNA（dsDNA）,大肠杆菌RecQ解旋酶更容易与单链DNA(ssDNA)结合( P<0.01 ),但与长度不同的dsDNA的结合特性有差异(P<0.01)而与ssDNA没有差异(P>0.05);大肠杆菌RecQ解旋酶对3种dsDNA的解链速率不同(P<0.05);大肠杆菌RecQ解旋酶的ATP酶活性与辅助因子ssDNA长度也呈正相关(P<0.01). 这些研究结果将有助于阐明大肠杆菌RecQ解旋酶的分子作用机制,并为研究RecQ解旋酶家族其它成员的结构与功能提供帮助.