Genome-wide analysis of transcription factor E2F1 mutant proteins reveals that N- and C-terminal protein interaction domains do not participate in targeting E2F1 to the human genome

Previous studies of E2F family members have suggested that protein-protein interactions may be the mechanism by which E2F proteins are recruited to specific genomic regions. We have addressed this hypothesis on a genome-wide scale using ChIP-seq analysis of MCF7 cell lines that express tagged wild type and mutant E2F1 proteins. First, we performed ChIP-seq for tagged WT E2F1. Then, we analyzed E2F1 proteins that lacked the N-terminal SP1 and cyclin A binding domains, the C-terminal transactivation and pocket protein binding domains, and the internal marked box domain. Surprisingly, we found that the ChIP-seq patterns of the mutant proteins were identical to that of WT E2F1. However, mutation of the DNA binding domain abrogated all E2F1 binding to the genome. These results suggested that the interaction between the E2F1 DNA binding domain and a consensus motif may be the primary determinant of E2F1 recruitment. To address this possibility, we analyzed the in vivo binding sites for the in vitro-derived consensus E2F1 motif (TTTSSCGC) and also performed de novo motif analysis. We found that only 12% of the ChIP-seq peaks contained the TTTSSCGC motif. De novo motif analysis indicated that most of the in vivo sites lacked the 5' half of the in vitro-derived consensus, having instead the in vivo consensus of CGCGC. In summary, our findings do not provide support for the model that protein-protein interactions are involved in recruiting E2F1 to the genome, but rather suggest that recognition of a motif found at most human promoters is the critical determinant.     

Rb-independent induction of apoptosis by bovine papillomavirus type 1 E7 in response to tumor necrosis factor alpha

Bovine papillomavirus type 1 (BPV-1) is a small DNA virus that causes fibropapillomas of the host. BPV-1 has served as the prototype for studies of the molecular biology of the papillomaviruses. BPV-1 efficiently induces anchorage-independent growth and focus formation in murine C127 cells. The transforming properties of BPV-1 primarily reside in two genes, E5 and E6. Each of these genes is sufficient to transform cells. Although no independent transformation activity has been detected for E7, it was shown to be required for full transformation of C127 by BPV-1. We investigated the biological activities of BPV-1 E7 in several assays. Our results indicate that expression of BPV-1 E7 sensitizes cells to tumor necrosis factor alpha (TNF)-induced apoptosis. The TNF-induced apoptosis in E7-expressing cells was accompanied by increased release of arachidonic acid, indicating that phospholipase A(2) was activated. Unlike the E7 proteins from the cancer-related human papillomaviruses, the BPV-1 E7 protein does not associate efficiently with the retinoblastoma protein (pRB) in vitro, nor does it significantly affect the pRB levels in cultured cells. Furthermore, BPV-1 E7 sensitizes Rb-null cells to TNF-induced apoptosis. These studies indicate that BPV-1 E7 can sensitize cells to apoptosis through mechanisms that are independent of pRB.     

DNA binding specificity of the bovine papillomavirus E1 protein is determined by sequences contained within an 18-base-pair inverted repeat element at the origin of replication.

Bovine papillomavirus type 1 (BPV-1) DNA replicates episomally and requires two virally expressed proteins, E1 and E2, for this process. Both proteins bind to the BPV-1 genome in the region that functions as the origin of replication. The binding sequences for the E2 protein have been characterized previously, but little is known about critical sequence requirements for E1 binding. Using a bacterially expressed E1 fusion protein, we examined binding of the BPV-1 E1 protein to the origin region. E1 strongly protected a 28-bp segment of the origin (nucleotides 7932 to 15) from both DNase I and exonuclease III digestion. Additional exonuclease III protection was observed beyond the core region on both the 5' and 3' sides, suggesting that E1 interacted with more distal sequences as well. Within the 28-bp protected core, there were two overlapping imperfect inverted repeats (IR), one of 27 bp and one of 18 bp. We show that sequences within the smaller, 18-bp IR element were sufficient for specific recognition of DNA by E1 and that additional BPV-1 sequences beyond the 18-bp IR element did not significantly increase origin binding by E1 protein. While the 18-bp IR element contained sequences sufficient for specific binding by E1, E1 did not form a stable complex with just the isolated 18-bp element. Formation of a detectable E1-DNA complex required that the 18-bp IR be flanked by additional DNA sequences. Furthermore, binding of E1 to DNA containing the 18-bp IR increased as a function of overall increasing fragment length. We conclude that E1-DNA interactions outside the boundaries of the 18-bp IR are important for thermodynamic stabilization of the E1-DNA complex. However, since the flanking sequences need not be derived from BPV-1, these distal E1-DNA interactions are not sequence specific. Comparison of the 18-bp IR from BPV-1 with the corresponding region from other papillomaviruses revealed a symmetric conserved consensus sequence, T-RY--TTAA--RY-A, that may reflect the specific nucleotides critical for E1-DNA recognition.     

Interaction of the Bovine Papillomavirus E6 Protein with the Clathrin Adaptor Complex AP-1

The E6 gene of the bovine papillomavirus type 1 (BPV-1) is expressed in fibropapillomas caused by BPV-1 and in tissue culture cells transformed by BPV-1. It encodes one of the two major oncoproteins of BPV-1. In this study, we demonstrate an interaction between the BPV-1 E6 protein and AP-1, the TGN (trans-Golgi network)-specific clathrin adaptor complex. AP-1 is a four-subunit protein complex required for clathrin-mediated cellular transport from the TGN. The AP-1/E6 interaction was observed in vitro and in cells. The E6 binding site on AP-1 was mapped to the N-terminal trunk domain of the γ subunit. BPV-1 E6 preferentially associated with membrane-bound AP-1 in cells but not with free cytosolic AP-1. BPV-1 E6 was further shown to be recruited to isolated Golgi membranes and to copurify with clathrin-coated vesicles. The recruitment of BPV-1 E6 to Golgi membranes was AP-1 independent, but the E6 interaction with AP-1 was required for its association with clathrin-coated vesicles. Furthermore, AP-1 proteins could compete with BPV-1 E6 for binding to Golgi membranes, suggesting that the recruitment of BPV-1 E6 and AP-1 to Golgi membranes involves a common factor. Taken together, our results suggest that cytosolic BPV-1 E6 is first recruited to the TGN, where it is then recognized by membrane-bound AP-1 and subsequently recruited into TGN-derived clathrin-coated vesicles. We propose that BPV-1 E6, through its interaction with AP-1, can affect cellular processes involving clathrin-mediated trafficking pathway.     

Functional Mapping of the DNA Binding Domain of Bovine Papillomavirus E1 Protein

Bovine papillomavirus type 1 (BPV-1) requires viral proteins E1 and E2 for efficient DNA replication in host cells. E1 functions at the BPV origin as an ATP-dependent helicase during replication initiation. Previously, we used alanine mutagenesis to identify two hydrophilic regions of the E1 DNA binding domain (E1DBD), HR1 (E1(179-191)) and HR3 (E1(241-252)), which are critical for sequence-specific recognition of the papillomavirus origin. Based on sequence and structure, these regions are similar in spacing and location to DNA binding regions A and B2 of T antigen, the DNA replication initiator of simian virus 40 (SV40). HR1 and A are both part of extended loops which are supported by residues from the HR3 and B2 alpha-helices. Both elements contain basic residues which may contact DNA, although lack of cocrystal structures for both E1 and T antigen make this uncertain. To better understand how E1 interacts with origin DNA, we used random mutagenesis and a yeast one-hybrid screen to select mutations of the E1DBD which disrupt sequence-specific DNA interactions. From the screen we selected seven single point mutants and one double point mutant (F175S, N184Y/K288R, D185G, V193M, F237L, K241E, R243K, and V246D) for in vitro analysis. All mutants tested in electrophoretic mobility shift assays displayed reduced sequence-specific DNA binding compared to the wild-type E1DBD. Mutants D185G, F237L, and R243K were rescued in vitro for DNA binding by the replication enhancer protein E2. We also tested the eight mutations in full-length E1 for the ability to support DNA replication in Chinese hamster ovary cells. Only mutants D185G, F237L, and R243K supported significant DNA replication in vivo which highlights the importance of E1DBD-E2 interactions for papillomavirus DNA replication. Based on the specific point mutations examined, we also assigned putative roles to individual residues in DNA binding. Finally, we discuss sequence and spacing similarities between E1 HR1 and HR3 and short regions of two other DNA tumor virus origin-binding proteins, SV40 T antigen and Epstein-Barr virus nuclear antigen 1 (EBNA1). We propose that all three proteins use a similar DNA recognition mechanism consisting of a loop structure which makes base-specific contacts (HR1) and a helix which primarily contacts the DNA backbone (HR3).     

N‐terminal processing of affinity‐tagged recombinant proteins purified by IMAC procedures

The ability of a new class of metal binding tags to facilitate the purification of recombinant proteins, exemplified by the tagged glutathione S‐transferase and human growth hormone, from Escherichia coli fermentation broths and lysates has been further investigated. These histidine‐containing tags exhibit high affinity for borderline metal ions chelated to the immobilised ligand, 1,4,7‐triazacyclononane (tacn). The use of this tag‐tacn immobilised metal ion affinity chromatography (IMAC) system engenders high selectivity with regard to host cell protein removal and permits facile tag removal from the E. coli‐expressed recombinant protein. In particular, these tags were specifically designed to enable their efficient removal by the dipeptidyl aminopeptidase 1 (DAP‐1), thus capturing the advantages of high substrate specificity and rates of cleavage. MALDI‐TOF MS analysis of the cleaved products from the DAP‐1 digestion of the recombinant N‐terminally tagged proteins confirmed the complete removal of the tag within 4‐12 h under mild experimental conditions. Overall, this study demonstrates that the use of tags specifically designed to target tacn‐based IMAC resins offers a comprehensive and flexible approach for the purification of E. coli‐expressed recombinant proteins, where complete removal of the tag is an essential prerequisite for subsequent application of the purified native proteins in studies aimed at delineating the molecular and cellular basis of specific biological processes. Copyright © 2015 John Wiley & Sons, Ltd.     

A set of epitope-tagging integration vectors for functional analysis in Saccharomyces cerevisiae

Functional analysis of genes from Saccharomyces cerevisiae has been the major goal after determination of genome sequences. Even though several tools for molecular-genetic analyses have been developed, only a limited number of reliable genetic tools are available to support functional assay at protein level. Epitope tagging is a powerful tool for detecting, purifying, and functional studying of proteins. But systematic tagging systems developed with integration vectors are not available. Here, we have constructed a set of integration vectors allowing a translational fusion of interested proteins to the four different epitope tags (HA, Myc, Flag, and GFP). To confirm function and expression of C-terminal-tagged proteins, we used Cdc11, a component of the septin filament that encircles the mother bud neck and consists of five major proteins: Cdc3, Cdc10, Cdc11, Cdc12, and Sep7. The tagged version of Cdc11 expressed under its endogenous promoter was found to be physiologically functional, as evidenced by localization at the neck and suppression of the growth defect associated with the temperature-sensitive mutation of cdc11-6. The expressed proteins were efficiently detected with antibodies against Cdc11 or the epitopes. When immunoprecipitated with anti-Myc antibody, each septin protein tagged with Myc was effectively copurified with other septin components, indicating formation of a stable septin complex. Because the modules of the tags were located under the same array of eighteen restriction sites on integration vectors containing four different markers (HIS3, TRP1, LEU2, or URA3), this tagging system provides efficient multiple tagging and stable expression of a gene of interest.     

The human papillomavirus type 6 and 16 E5 proteins are membrane-associated proteins which associate with the 16-kilodalton pore-forming protein.

The human papillomavirus (HPV) E5 proteins are predicted from DNA sequence analysis to be small hydrophobic molecules, and the HPV type 6 (HPV-6) and HPV-11 E5 proteins share several structural similarities with the bovine papillomavirus type 1 (BPV-1) E5 protein. Also similar to the BPV-1 E5 protein, the HPV-6 and HPV-16 E5 proteins exhibit transforming activity when assayed on NIH 3T3 and C127 cells. In this study, we expressed epitope-tagged E5 proteins from both the "low-risk" HPV-6 and the "high-risk" HPV-16 in order to permit their immunologic identification and biochemical characterization. While the HPV-6 and HPV-16 E5 proteins fail to form disulfide-linked dimers and oligomers, they did resemble the BPV-1 E5 protein in their intracellular localization to the Golgi apparatus, endoplasmic reticulum, and nuclear membranes. In addition, the HPV E5 proteins also bound to the 16-kDa pore-forming protein component of the vacuolar ATPase, a known characteristic of the BPV-1 E5 protein. These studies reveal a common intramembrane localization and potential cellular protein target for both the BPV and HPV E5 proteins.