The X-ray structure of the papillomavirus helicase in complex with its molecular matchmaker E2

Abbate, Eric A.; Berger, James M.; Botchan, Michael R.

doi:10.1101/gad.1220104

Cited by 147 publications

(179 citation statements)

References 60 publications

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“…3B, lanes [7][8][9][10][11][12][13][14][15][16][17][18]. Two other substitutions with long aliphatic side chains, H513M and H513L, also displayed helicase activity (Fig.…”

Section: Resultsmentioning

confidence: 99%

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The roles of the residues on the channel β-hairpin and loop structures of simian virus 40 hexameric helicase

Shen

Gai

Patrick

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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Simian virus 40 large tumor antigen is required for DNA unwinding during viral replication. The helicase-active form of large tumor antigen is a ring-shaped hexamer͞double hexamer, which has a positively charged hexameric channel for interacting with DNA. On the hexameric channel surface are six ␤-hairpin structures and loops, emanating from each of the six subunits. At the tips of the ␤-hairpin and the loop structures are two ring-shaped residues, H513 and F459, respectively. Additionally, two positively charged residues, K512 and K516, are near the tip of the ␤-hairpin. The positions of these ring-shaped and positively charged residues suggest that they may play a role in binding DNA for helicase function. To understand the roles of these residues in helicase function, we obtained a set of mutants and examined various activities, including oligomerization, ATPase, DNA binding, and helicase activities. We found that substitution of these residues by Ala abolished helicase activity. Extensive mutagenesis showed that substitutions by ring-shaped residues (W and Y) at position F459 and by residues with hydrophobic or long aliphatic side chains (W, Y, F, L, M, and R) at position H513 supported helicase activity. Our study demonstrated that the four residues (F459, H513, K512, and K516) play a critical role in interacting with DNA for helicase function. The results suggest a possible mechanism to explain how these residues, as well as the ␤-hairpin and the loop structures on which the residues reside, participate in binding and translocating DNA for origin melting and unwinding.AAA ϩ ͉ molecular machine ͉ replication ͉ large T antigen S imian virus 40 (SV40) large tumor antigen (LTag) is an efficient molecular machine that unwinds dsDNA (1-4). It belongs to AAA ϩ protein family and the helicase superfamily III (5, 6). LTag contains 708 residues and has four functional domains: DnaJ homology (residue 1-80), origin-DNA binding (residues 131-250), helicase (residues 260-627), and a host range domains (2, 4) ( Fig. 1). The helicase domain and a longer LTag construct (residues 131-627) have helicase activity similar to that of the full-length protein (7).LTag assembles into a double hexamer (dHex) at the origin through sequence-specific interactions via origin-DNA binding (2,8). However, the non-sequence-specific interaction with DNA via the helicase domain also plays an important role in the dHex assembly and helicase activity (9, 10). Based on high-resolution structures and previous biochemical͞genetic data, a looping model for dsDNA unwinding by a dHex helicase was proposed (11)(12)(13)(14). In this model, strand separation occurs within the wide chamber of the helicase domain when DNA is pulled inside the dHex helicase, and the separated ssDNA loops out from a side channel on the wall of the helicase chamber (12,14). Even though this model reconciled many observations, it did not offer a detailed view of how dsDNA is pulled inside the hHex for strand separation.The crystal structures of LTag at various nucleotide-bo...

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“…3B, lanes [7][8][9][10][11][12][13][14][15][16][17][18]. Two other substitutions with long aliphatic side chains, H513M and H513L, also displayed helicase activity (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…8) (11,(17)(18)(19). However, some AAA ϩ hexameric protein machines, e.g., NSF and p97 for membrane fusion (20)(21)(22), do not possess a similar ␤-hairpin structure.…”

Section: Discussionmentioning

confidence: 99%

The roles of the residues on the channel β-hairpin and loop structures of simian virus 40 hexameric helicase

Shen

Gai

Patrick

et al. 2005

Proc. Natl. Acad. Sci. U.S.A.

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“…A prime candidate for the interaction with the TA bp is a ␤-hairpin structure, which is highly conserved in E1 and other papovavirus initiator proteins (1,18). Our previous studies have demonstrated that H507 at the tip of this ␤-hairpin is required for DT formation and for template melting (28).…”

Section: Discussionmentioning

confidence: 99%

“…Structural studies of E1 and T-Ag have provided important information about the domain structure, how these proteins oligomerize, and how they bind and hydrolyze nucleotides (1,10,13,18). Biochemical analysis has demonstrated that one particular form of E1, a double trimer (DT), generates permanganate reactivity in the ori in the presence of ADP, indicating that the DT provides template melting activity (28).…”

mentioning

confidence: 99%

ATP-Dependent Minor Groove Recognition of TA Base Pairs Is Required for Template Melting by the E1 Initiator Protein

Schuck

Stenlund

2007

J Virol

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Template melting is an essential step in the initiation of DNA replication, but the mechanism of template melting is unknown for any replicon. Here we demonstrate that melting of the bovine papillomavirus type 1 ori is a sequence-dependent process which relies on specific recognition of TA base pairs in the minor groove by the E1 initiator. We show that correct template melting is a prerequisite for the formation of a stable double hexamer with helicase activity and that ori mutants that fail to melt correctly are defective for ori unwinding and DNA replication in vivo. Our results also indicate that melting of the DNA is achieved by destabilization of the double helix along its length through multiple interactions with E1, each of which is responsible for melting of a few base pairs, resulting in the extensive melting that is required for initiation of DNA replication.Template melting is an essential step in the initiation of replication of double-stranded DNA. In spite of its fundamental importance for DNA replication, the melting process is almost entirely uncharacterized. For Escherichia coli, the initiator DnaA has long been known to melt OriC, as can be detected by the use of single-stranded DNA (ssDNA)-specific nucleases (6, 32). The mechanism by which the DNA is melted is unknown, but it is established that melting is dependent on nucleotide binding by DnaA (for a review, see reference 16). For eukaryotes, although the origin recognition complex has been identified as the factor that marks the replicator (2), an activity that can melt the DNA in preparation for replication has still not been identified. Viral initiator proteins such as the simian virus 40 (SV40) large T antigen (T-Ag) and the papillomavirus E1 protein have long been known to melt their respective origins of DNA replication, as detected by oxidation with KMnO 4 (4,5,14,22,24,25). However, little information exists about which forms of these proteins execute melting, which parts of the polypeptide are responsible for the melting activity, and whether this process is DNA sequence dependent (5, 27).The E1 proteins from papillomaviruses are ϳ70-kDa polypeptides which, in addition to DNA melting activity, have DNA helicase activity (19,20,30,33,35,37,38,40) and also bind DNA. DNA binding by E1 is the result of two different DNA binding activities. Site-specific DNA binding is provided by the E1 DNA binding domain (DBD), which recognizes and binds to two pairs of E1 binding sites (E1 BS) in the origin of replication (7-9, 11, 15, 17, 31, 36). The E1 helicase domain binds DNA with low sequence specificity, and this activity is required for the ability of the E1 helicase domain to contact the DNA sequences flanking the E1 BS, including a region that has been termed the A/T-rich region (34).Recent advances in the study of E1 and T-Ag have opened up the melting process for more detailed study. Structural studies of E1 and T-Ag have provided important information about the domain structure, how these proteins oligomerize, and how they bind and hydro...

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“…The full-length E2 protein is a sequence-specific DNAbinding protein implicated in the control of viral DNA replication (Stenlund 2003;Abbate et al 2004), transcription (Hou et al 2002), cell cycle progression (Hwang et al 1993), apoptosis (Blachon et al 2005), senescence (Goodwin and DiMaio 2001), and viral genome maintenance and segregation (Abroi et al 2004;Botchan 2004;McBride et al 2004;Van Tine et al 2004;You et al 2004). Like many cellular transcription factors with different functional modules, E2 contains a C-terminal DNA-binding domain linked to the N-terminal transactivation domain by a flexible hinge.…”

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confidence: 99%

Brd4 links chromatin targeting to HPV transcriptional silencing

et al. 2006

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The E2 protein encoded by human papillomaviruses (HPVs) inhibits expression of the viral E6 oncoprotein, which, in turn, regulates p53 target gene transcription. To identify cellular proteins involved in E2-mediated transcriptional repression, we isolated an E2 complex from human cells conditionally expressing HPV-11 E2. Surprisingly, the double bromodomain-containing protein Brd4, which is implicated in cell cycle control and viral genome segregation, was found associated with E2 and conferred on E2 the ability to inhibit AP-1-dependent HPV chromatin transcription in an E2-binding site- [Keywords: HPV; E2; AP-1; Brd4; chromatin transcription; gene silencing] Supplemental material is available at http://www.genesdev.org.

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The X-ray structure of the papillomavirus helicase in complex with its molecular matchmaker E2

Cited by 147 publications

References 60 publications

The roles of the residues on the channel β-hairpin and loop structures of simian virus 40 hexameric helicase

The roles of the residues on the channel β-hairpin and loop structures of simian virus 40 hexameric helicase

ATP-Dependent Minor Groove Recognition of TA Base Pairs Is Required for Template Melting by the E1 Initiator Protein

Brd4 links chromatin targeting to HPV transcriptional silencing

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