Sequence-specific DNA binding of the Epstein-Barr virus nuclear antigen (EBNA-1) to clustered sites in the plasmid maintenance region

Latently infected B lymphocytes continuously express an Epstein-Barr Virus nuclear antigen (EBNA-1) required in trans for maintenance of the plasmid state of the EBV genome. Filter binding assays and DNAase I footprinting analyses revealed that the carboxy-terminal domain of EBNA-1 protects binding sites at three different loci in the 172,000 bp EBV genome. Two of these loci correspond to essential elements within an 1800 bp segment defined as the minimal region required for plasmid maintenance (ori-P). Binding to each of 20 X 30 bp tandem repeats in the "sink" locus protects 25 bp centered over a 12 bp palindromic consensus sequence TAGCATATGCTA. The nearby dyad symmetry "origin" locus contains two 46 bp protected regions each encompassing two paired core binding sites. The demonstration of sequence-specific binding at multiple loci suggests that EBNA-1 has pleiotropic functions, which may include control of copy number and segregation of the EBV plasmids as well as initiation of replication.

Truncated mammalian Notch1 activates CBF1/RBPJk-repressed genes by a mechanism resembling that of Epstein-Barr virus EBNA2

The Notch/Lin-12/Glp-1 receptor family participates in cell-cell signaling events that influence cell fate decisions. Although several Notch homologs and receptor ligands have been identified, the nuclear events involved in this pathway remain incompletely understood. A truncated form of Notch, consisting only of the intracellular domain (NotchIC), localizes to the nucleus and functions as an activated receptor. Using both an in vitro binding assay and a cotransfection assay based on the two-hybrid principle, we show that mammalian NotchIC interacts with the transcriptional repressor CBF1, which is the human homolog of Drosophila Suppressor of Hairless. Cotransfection assays using segments of mouse NotchIC and CBF1 demonstrated that the N-terminal 114-amino-acid region of mouse NotchIC contains the CBF1 interactive domain and that the cdc10/ankyrin repeats are not essential for this interaction. This result was confirmed in immunoprecipation assays in which the N-terminal 114-amino-acid segment of NotchIC, but not the ankyrin repeat region, coprecipitated with CBF1. Mouse NotchIC itself is targeted to the transcriptional repression domain (aa179 to 361) of CBF1. Furthermore, transfection assays in which mouse NotchIC was targeted through Gal4-CBF1 or through endogenous cellular CBF1 indicated that NotchIC transactivates gene expression via CBF1 tethering to DNA. Transactivation by NotchIC occurs partially through abolition of CBF1-mediated repession. This same mechanism is used by Epstein-Barr virus EBNA2. Thus, mimicry of Notch signal transduction is involved in Epstein-Barr virus-driven immortalization.

Mediation of Epstein-Barr virus EBNA2 transactivation by recombination signal-binding protein J kappa

The Epstein-Barr virus (EBV) transactivator protein, termed Epstein-Barr virus nuclear antigen 2 (EBNA2), plays a critical role in the regulation of latent viral transcription and in the immortalization of EBV-infected B cells. Unlike most transcription factors, EBNA2 does not bind directly to its cis-responsive DNA element but requires a cellular factor, termed C-promoter binding factor 1 (CBF1). Here, CBF1 was purified and was found to directly interact with EBNA2. CBF1 is identical to a protein thought to be involved in immunoglobulin gene rearrangement, RBPJ kappa. Contrary to previous reports, CBF1-RBPJ kappa did not bind to the recombination signal sequences but instead bound to sites in the EBV C-promoter and in the CD23 promoter.

Collective protein dynamics in relation to function

Several techniques for the analysis of the internal motions of proteins are available - separating large collective motions from small, presumably uninteresting motions. Such descriptions are helpful in the characterization of internal motions and provide insight into the energy landscape of proteins. The real challenge, however, is to relate large collective motions to functional properties, such as binding and regulation, or to folding. These issues have been recently addressed in several papers.

Epstein-Barr virus in AIDS-related primary central nervous system lymphoma

Primary central nervous system lymphoma occurs more often in patients with AIDS. Epstein-Barr virus (EBV) has been detected in these tumours, but the degree of association has not been defined because of both the highly restricted expression of EBV in malignant tissue and the lack of a technique that is reliable in formalin-fixed paraffin-embedded specimens. EBV-transformed lymphocytes contain short non-protein coding EBV transcripts (EBERs), which are expressed in much higher quantity than other EBV-latency transcripts. We describe a new strategy for detection of latent EBV with these transcripts as targets for in-situ hybridisation. 18 cases of AIDS-related primary CNS lymphoma from a consecutive necropsy series together with specimens from 3 further cases were studied. In each case, a strong positive signal over tumour cells indicated abundant expression of the EBV-EBER1 transcript. This 100% association suggests that the pathogenesis of these AIDS-associated lymphomas may differ from the systemic disease in which only 30-50% of tumours are associated with EBV. A pathogenetic role for EBV was further supported by showing expression of a viral protein (the latent membrane protein) that is implicated as an effector for EBV-associated lymphomagenesis. EBV might have a role as a tumour marker in the diagnosis and management of AIDS-related primary CNS lymphoma.

Masking of the CBF1/RBPJ kappa transcriptional repression domain by Epstein-Barr virus EBNA2

Epstein-Barr virus (EBV) nuclear antigen 2 (EBNA2) is a transcriptional activator that is essential for EBV-driven B cell immortalization. EBNA2 is targeted to responsive promoters through interaction with a cellular DNA binding protein, C promoter binding factor 1 (CBF1). A transcriptional repression domain has been identified within CBF1. This domain also interacts with EBNA2, and repression is masked by EBNA2 binding. Thus, EBNA2 acts by countering transcriptional repression. Mutation at amino acid 233 of CBF1 abolishes repression and correlates with a loss-of-function mutation in the Drosophila homolog Su(H).

CIR, a corepressor linking the DNA binding factor CBF1 to the histone deacetylase complex

CBF1 is a member of the CSL family of DNA binding factors, which mediate either transcriptional repression or transcriptional activation. CSL proteins play a central role in Notch signaling and in Epstein-Barr virus-induced immortalization. Notch is a transmembrane protein involved in cell-fate decisions, and the cytoplasmic domain of Notch (NotchIC) targets CBF1. The Epstein-Barr virus-immortalizing protein EBNA2 activates both cellular and viral gene expression by targeting CBF1 and mimicking NotchIC. We have examined the mechanism of CBF1-mediated repression and show that CBF1 binds to a unique corepressor, CBF1 interacting corepressor (CIR). A CIR homolog is encoded by Caenorhabditis elegans, indicating that CIR is evolutionarily conserved. Two CBF1 mutants that were unable to bind CIR did not function as repressors, suggesting that targeting of CIR to CBF1 is an important component of repression. When expressed as a Gal4 fusion protein, CIR repressed reporter gene expression. CIR binds to histone deacetylase and to SAP30 and serves as a linker between CBF1 and the histone deacetylase complex.

Model-free methods of analyzing domain motions in proteins from simulation: a comparison of normal mode analysis and molecular dynamics simulation of lysozyme

Model-free methods are introduced to determine quantities pertaining to protein domain motions from normal mode analyses and molecular dynamics simulations. For the normal mode analysis, the methods are based on the assumption that in low frequency modes, domain motions can be well approximated by modes of motion external to the domains. To analyze the molecular dynamics trajectory, a principal component analysis tailored specifically to analyze interdomain motions is applied. A method based on the curl of the atomic displacements is described, which yields a sharp discrimination of domains, and which defines a unique interdomain screw-axis. Hinge axes are defined and classified as twist or closure axes depending on their direction. The methods have been tested on lysozyme. A remarkable correspondence was found between the first normal mode axis and the first principal mode axis, with both axes passing within 3 A of the alpha-carbon atoms of residues 2, 39, and 56 of human lysozyme, and near the interdomain helix. The axes of the first modes are overwhelmingly closure axes. A lesser degree of correspondence is found for the second modes, but in both cases they are more twist axes than closure axes. Both analyses reveal that the interdomain connections allow only these two degrees of freedom, one more than provided by a pure mechanical hinge.

A new Epstein-Barr virus transactivator, R, induces expression of a cytoplasmic early antigen

Several Epstein-Barr virus (EBV) early promoters respond to a new EBV transactivator encoded by BRLF1, designated R. Transactivation was measured in chloramphenicol acetyltransferase assays on Raji, BHK, and Vero cells that were cotransfected with the transactivator and target promoters linked to the cat gene. The divergent promoter of BamHI-H was particularly responsive to R transactivation. This large promoter region consists of a leftward TATA box for the NotI repeat gene (BHLF1) and a probable rightward TATA box for the EA-R gene (BHRF1) separated by 940 base pairs of unusual sequence complexity. Sequences within this divergent promoter region appear to confer inducibility by EBV transactivators R and Z (BZLF1). The Z transactivator stimulated expression in both the leftward and rightward directions, and R stimulated expression primarily in the rightward direction, but the MS transactivator (BMLF1) had no activity in either direction. The adenovirus E3 promoter also responded to the R transactivator, but several other herpesvirus and human promoters were nonresponsive. When the divergent promoter was linked to the EA-R gene as it is in the EBV genome, the R and Z transactivators also induced the expression of EA-R in cotransfected cells. This cytoplasmic early antigen is encoded by BHRF1 and may be anchored in intracellular membranes by a carboxy-terminal transmembrane region.

Cell differentiation lineage in the prostate

Prostatic epithelium consists mainly of luminal and basal cells, which are presumed to differentiate from common progenitor/stem cells. We hypothesize that progenitor/stem cells are highly concentrated in the embryonic urogenital sinus epithelium from which prostatic epithelial buds develop. We further hypothesize that these epithelial progenitor/stem cells are also present within the basal compartment of adult prostatic epithelium and that the spectrum of differentiation markers of embryonic and adult progenitor/stem cells will be similar. The present study demonstrates that the majority of cells in embryonic urogenital sinus epithelium and developing prostatic epithelium (rat, mouse, and human) co-expressed luminal cytokeratins 8 and 18 (CK8, CK18), the basal cell cytokeratins (CK14, CK5), p63, and the so-called transitional or intermediate cell markers, cytokeratin 19 (CK19) and glutathione-S-transferase-pi (GSTpi). The majority of luminal cells in adult rodent and human prostates only expressed luminal markers (CK8, CK18), while the basal epithelial cell compartment contained several distinct subpopulations. In the adult prostate, the predominant basal epithelial subpopulation expressed the classical basal cell markers (CK5, CK14, p63) as well as CK19 and GSTpi. However, a small fraction of adult prostatic basal epithelial cells co-expressed the full spectrum of basal and luminal epithelial cell markers (CK5, CK14, CK8, CK18, CK19, p63, GSTpi). This adult prostatic basal epithelial cell subpopulation, thus, exhibited a cell differentiation marker profile similar to that expressed in embryonic urogenital sinus epithelium. These rare adult prostatic basal epithelial cells are proposed to be the progenitor/stem cell population. Thus, we propose that at all stages (embryonic to adult) prostatic epithelial progenitor/stem cells maintain a differentiation marker profile similar to that of the original embryonic progenitor of the prostate, namely urogenital sinus epithelium. Adult progenitor/stem cells co-express both luminal cell, basal cell, and intermediate cell markers. These progenitor/stem cells differentiate into mature luminal cells by maintaining CK8 and CK18, and losing all other makers. Progenitor/stem cells also give rise to mature basal cells by maintaining CK5, CK14, p63, CK19, and GSTpi and losing K8 and K18. Thus, adult prostate basal and luminal cells are proposed to be derived from a common pleuripotent progenitor/stem cell in the basal compartment that maintains its embryonic profile of differentiation markers from embryonic to adult stages.

trans-acting requirements for replication of Epstein-Barr virus ori-Lyt

Epstein-Barr virus (EBV) utilizes a completely different mode of DNA replication during the lytic cycle than that employed during latency. The latency origin of replication, ori-P, which functions in the replication of the latent episomal form of the EBV genome, requires only a single virally encoded protein, EBNA-1, for its activity. During the lytic cycle, a separate origin, ori-Lyt, is utilized. Relatively little is known about the trans-acting proteins involved in ori-Lyt replication. We established a cotransfection-replication assay to identify EBV genes whose products are required for replication of ori-Lyt. In this assay, a BamHI-H plasmid containing ori-Lyt was replicated in Vero cells cotransfected with the BamHI-H target, the three EBV lytic-cycle transactivators Zta, Rta, and Mta, and the EBV genome provided in the form of a set of six overlapping cosmid clones. By removing individual cosmids from the cotransfection mixture, we found that only three of the six cosmids were necessary for ori-Lyt replication. Subcloning of the essential cosmids led to the identification of six EBV genes that encode replication proteins. These genes and their functions (either known or predicted on the basis of sequence comparison with herpes simplex virus) are BALF5, the DNA polymerase; BALF2, the single-stranded DNA-binding protein homolog; BMRF1, the DNA polymerase processivity factor; BSLF1 and BBLF4, the primase and helicase homologs; and BBLF2/3, a potential homolog of the third component of the helicase-primase complex. In addition, ori-Lyt replication in this cotransfection assay was also dependent on one or more genes provided by the EBV SalI-F fragment and on the three lytic-cycle transactivators Zta, Rta, and Mta.

SKIP, a CBF1-associated protein, interacts with the ankyrin repeat domain of NotchIC To facilitate NotchIC function

Notch proteins are transmembrane receptors that mediate intercell communication and direct individual cell fate decisions. The activated intracellular form of Notch, NotchIC, translocates to the nucleus, where it targets the DNA binding protein CBF1. CBF1 mediates transcriptional repression through the recruitment of an SMRT-histone deacetylase-containing corepressor complex. We have examined the mechanism whereby NotchIC overcomes CBF1-mediated transcriptional repression. We identified SKIP (Ski-interacting protein) as a CBF1 binding protein in a yeast two-hybrid screen. Both CBF1 and SKIP are highly conserved evolutionarily, and the SKIP-CBF1 interaction is also conserved in assays using the Caenorhabditis elegans and Drosophila melanogaster SKIP homologs. Protein-protein interaction assays demonstrated interaction between SKIP and the corepressor SMRT. More surprisingly, SKIP also interacted with NotchIC. The SMRT and NotchIC interactions were mutually exclusive. In competition binding experiments SMRT displaced NotchIC from CBF1 and from SKIP. Contact with SKIP is required for biological activity of NotchIC. A mutation in the fourth ankyrin repeat that abolished Notch signal transduction did not affect interaction with CBF1 but abolished interaction with SKIP. Further, NotchIC was unable to block muscle cell differentiation in myoblasts expressing antisense SKIP. The results suggest a model in which NotchIC activates responsive promoters by competing with the SMRT-corepressor complex for contacts on both CBF1 and SKIP.

Energy landscape of a native protein: jumping-among-minima model

We have investigated energy landscape of human lysozyme in its native state by using principal component analysis and a model, jumping-among-minima (JAM) model. These analyses are applied to 1 nsec molecular dynamics trajectory of the protein in water. An assumption embodied in the JAM model allows us to divide protein motions into intra-substate and inter-substate motions. By examining intra-substate motions, it is shown that energy surfaces of individual conformational substates are nearly harmonic and mutually similar. As a result of principal component analysis and JAM model analysis, protein motions are shown to consist of three types of collective modes, multiply hierarchical modes, singly hierarchical modes, and harmonic modes. Multiply hierarchical modes, the number of which accounts only for 0.5% of all modes, dominate contributions to total mean-square atomic fluctuation. Inter-substate motions are observed only in a small-dimensional subspace spanned by the axes of multiplyhierarchical and singly hierarchical modes. Inter-substate motions have two notable time components: faster component seen within 200 psec and slower component. The former involves transitions among the conformational substates of the low-level hierarchy, whereas the latter involves transitions of the higher level substates observed along the first four multiply hierarchical modes. We also discuss dependence of the subspace, which contains conformational substates, on time duration of simulation.

Collective variable description of native protein dynamics

The importance of collective motions in proteins, such as hinge-bending motions or motions involving domains, has been recognized. Occurrence of such motions and their experimental and theoretical studies are reviewed. Normal-mode analysis and principal component analysis are powerful theoretical tools for studying such motions. The former is based on the assumption of harmonicity of the dynamics, while the latter is valid even when the dynamics is highly anharmonic. The results of the latter analysis indicate that most important conformational events are taking place in a conformational subspace spanned by a rather small number of principal modes, and this important subspace is also spanned by a small number of normal modes. The normal-mode refinement method of protein X-ray crystallography, which is developed based on the concept of the above important subspace, is discussed.

Detection of EBV gene expression in Reed-Sternberg cells of Hodgkin's disease

EBV DNA has been detected by Southern blot hybridization in 20-25% of Hodgkin's disease tumor specimens and localized to the Reed-Sternberg cells by in situ hybridization. In the present investigation we used a 3H-labelled EBER I anti-sense RNA for in situ hybridization of archival formalin-fixed paraffin-embedded Hodgkin's disease specimens previously shown by Southern Blot hybridization to be EBV-positive. In 6 of 8 specimens neoplastic cells showed an intense signal in virtually all of the tumor cells. The background lymphocytes, eosinophils, plasma cells and histiocytes did not demonstrate significant hybridization. In each case hybridization tended to spare the nucleoli. Hybridization was detected in specimens with histologies of mixed cellularity and nodular sclerosis. The intensity of signal relative to background is better than that in previous studies utilizing 35S-labelled large internal repeat probes for EBV in Reed-Sternberg cells. The exposure time is one week in contrast to the 4-5 weeks reported by others for detection of EBV in Hodgkin's disease. Both increased relative intensity and shorter exposure requirements may be attributed to the very high number of EBER transcripts in the target cells. The demonstration that EBER I is expressed is consistent with a role for EBV in growth regulation of Reed-Sternberg cells and suggests that the virus is not merely a silent passenger in Hodgkin's disease.

Functional domains of Epstein-Barr virus nuclear antigen EBNA-1

The Epstein-Barr virus (EBV)-encoded latency product EBNA-1 is functionally pleiotropic, being required for replication of the episomal form of the EBV genome and having a role in the regulation of latency transcription. EBNA-1 is a direct DNA-binding protein, and both replication and transactivation are dependent on the interaction of EBNA-1 with its cognate DNA recognition sequences. To better understand EBNA-1 function, we have further characterized the DNA-binding domain of EBNA-1 and have examined the contributions of other domains of the protein to EBNA-1 transactivation activity. A Bal31 deletional analysis of the carboxy-terminal region of EBNA-1 identified a core DNA-binding domain located between amino acids 493 and 584. Column chromatographic, sedimentation, and cross-linking studies indicated that EBNA-1 exists in solution as a dimer. Mobility retardation assays using in vitro-translated variants of EBNA-1 showed that the active DNA-binding form of EBNA-1 is also a dimer. In short-term cotransfections, a pFRTK-CAT target containing EBNA-1-binding sites from the EBV origin of plasmid replication, ori-P, was transactivated by a carboxy-terminal EBNA-1 construction (amino acids 450 to 641) that also carried a c-myc nuclear localization signal. These reconstruction experiments demonstrated that a transactivation domain exists within the carboxy-terminal region of EBNA-1, that transactivation is more efficient when a nuclear localization signal is present, and that the natural karyophilic signal lies outside of the carboxy-terminal 191 amino acids. To identify the EBNA-1 nuclear localization signal, small oligonucleotides representing EBNA-1 sequences that encode clusters of basic peptides were transferred into two different vectors expressing cytoplasmic proteins (pyruvate kinase and herpes simplex virus delta IE175 protein) and the cellular locations of the fusion constructions were determined by immunofluorescence staining of transfected cells. In this way we identified a functional nuclear localization signal, Leu-Lys-Arg-Pro-Arg-Ser-Pro-Ser-Ser, encompassing amino acids 379 to 386 of the EBNA-1 protein.

Monoclonal antibody against a 250,000-dalton glycoprotein of Epstein-Barr virus identifies a membrane antigen and a neutralizing antigen

An antibody-secreting hybrid cell line was produced by fusion of mouse myeloma cells with splenocytes from mice immunized with virions of the B95-8 strain of Epstein-Barr Virus (EBV). The monoclonal IgG antibody was shown to have anti-EBV activity by the following criteria: (i) It reacted with the membranes and the cytoplasm of seven different EBV-producing lines, but with no nonproducing line. (ii) The individual cells identified by the murine antibody were shown to be the same cells identified by a human serum having anti-EBV activity. (iii) The antibody significantly reduced the infectivity of two independent strains of EBV (namely, P3HR1K and B95-8). The antigen being recognized was characterized by immunoprecipitations of radiolabeled EBV-producer cell lysates. A single glycoprotein with an estimated molecular weight of 250,000 was identified. It is concluded that neutralization of EBV can be achieved by an IgG-class monoclonal antibody directed against a single antigenic site on a 250,000-dalton glycoprotein, which is a constituent of the EBV virion.

The zta transactivator involved in induction of lytic cycle gene expression in Epstein-Barr virus-infected lymphocytes binds to both AP-1 and ZRE sites in target promoter and enhancer regions

The BZLF1 or zta immediate-early gene of Epstein-Barr virus (EBV) encodes a 33-kilodalton phosphorylated nuclear protein that is a specific transcriptional activator of the EBV lytic cycle when introduced into latently infected B lymphocytes. We have shown previously that the divergent EBV DSL target promoter contains two zta-response regions, one within the minimal promoter and the other in an upstream lymphocyte-dependent enhancer region. In this study, we used footprinting and gel mobility retardation assays to reveal that bacterially synthesized Zta fusion proteins bound directly to six TGTGCAA-like motifs within DSL. Four of the Zta-binding sites lay adjacent to cellular TATA and CAAT factor-binding sites within the minimal promoter, and two mapped within the enhancer region. Single-copy oligonucleotides containing these Zta-binding sites conferred Zta responsiveness to heterologous promoters. In addition, the Zta protein, which possesses a similar basic domain to the conserved DNA-binding region of the c-Fos, c-Jun, GCN4, and CREB protein family, proved to bind directly to the consensus AP-1 site in the collagenase 12-O-tetradecanoylphorbol-13-acetate response element. Cotransfection with zta also trans activated a target reporter gene containing inserted wild-type 12-O-tetradecanoylphorbol-13-acetate response element oligonucleotides. Cellular AP-1 binding activity proved to be low in latently EBV-infected Raji cells but was induced (together with the Zta protein) after activation of the lytic cycle with 12-O-tetradecanoylphorbol-13-acetate. We conclude that EBV may have captured and modified a cellular gene encoding a c-jun-like DNA-binding protein during its evolutionary divergence from other herpesviruses and that this protein is used to specifically redirect transcriptional activity toward expression of EBV lytic-cycle genes in infected cells.

The Epstein-Barr virus Zta transactivator: a member of the bZIP family with unique DNA-binding specificity and a dimerization domain that lacks the characteristic heptad leucine zipper motif

Introduction of the zta gene of Epstein-Barr virus into latently infected B cells leads to induction of the entire lytic cycle program of the virus. The Zta gene product is a sequence-specific DNA-binding protein of 35 kilodaltons that behaves as a specific transcriptional transactivator in transient cotransfection assays. All known Zta-responsive target promoters contain one or more members of a family of consensus-binding sites known as ZREs. On the basis of the presence of limited amino acid similarity within a basic carboxy-terminal domain, Zta has been proposed to be a highly divergent member of the c-Jun/c-Fos/GCN4 family of AP-1-binding proteins. We show here that in vitro-translated Zta and the Jun:Fos proteins have overlapping but distinct target DNA-binding specificies; both recognize canonical AP-1 sites, but only Zta recognizes ZRE sites and only Jun:Fos recognizes CRE sites. The relative binding affinity of Zta for oligonucleotides containing the 7-base-pair c-Fos AP-1 site TGAGTCA was twofold greater than that for the ZRE core motifs TGAGCAA, TG TGCAA, and TGAGTAA, but 10-fold greater than that for TGTGTCA, as measured by gel mobility retardation and competition DNA-binding assays. Cross-linking and cotranslational heterodimerization assays showed that like GCN4, Zta forms a stable homodimer in both its DNA-bound and unbound forms. Furthermore, we show that a potential coiled-coil helical domain adjacent to the basic domain of Zta can substitute for the leucine zipper of c-Fos to produce a DNA-binding protein that has a very stringent target DNA specificity and can only recognize symmetric 9-base-pair AP-1 sites (ATGAGTCAT). Therefore, despite the absence of the repeated heptad leucine zipper motifs, the Zta protein retains the characteristic features of a juxtaposed basic region and an exactly aligned coiled-coil alpha-helical dimerization domain of the bZIP class of transcriptional regulatory factors.

Human herpesvirus 8 LANA interacts with proteins of the mSin3 corepressor complex and negatively regulates Epstein-Barr virus gene expression in dually infected PEL cells

The human herpesvirus 8 (HHV-8) latency-associated nuclear antigen (LANA) is expressed in all latently HHV-8 infected cells and in HHV-8-associated tumors, including primary effusion lymphoma (PEL). To better understand the contribution of LANA to tumorigenesis and to the PEL phenotype, we performed a yeast two-hybrid screen which identified the corepressor protein SAP30 as a LANA binding protein. SAP30 is a constituent of a large multicomponent complex that brings histone deacetylases to the promoter. Glutathione S-transferase affinity assays confirmed interaction between LANA and SAP30 and also demonstrated interactions between LANA and two other members of the corepressor complex, mSin3A and CIR. The corepressors bound to the amino-terminal 340-amino-acid domain of LANA. In transient expression assays, this same domain of LANA mediated repression when targeted to a 5xGal4tk-CAT reporter as a GAL4-LANA fusion. PEL cells have the unusual feature that they are frequently dually infected with both HHV-8 and Epstein-Barr virus (EBV). We found that EBV EBNA-1 expression is downregulated in PEL cells at both the RNA and protein levels. In transient expression assays, LANA repressed activated expression from the EBV Qp and Cp latency promoters. Reduction of endogenous Qp activity could also be demonstrated in EBV-infected Rael cells transfected with a LANA expression plasmid. In contrast to the effect of LANA on EBV latency promoters, LANA activated expression from its own promoter. The data indicate that LANA can mediate transcriptional repression through recruitment of an mSin3 corepressor complex and further that LANA-mediated repression is likely to contribute to the low level of EBV latency gene expression seen in dually infected PEL cells.

Effect of solvent on collective motions in globular protein

Two molecular dynamics simulations on bovine pancreatic trypsin inhibitor (BPTI), have been made, one in vacuum, the other in water, in order to assess the effect of the solvent water on collective motions. Principal component analysis has been performed to determine collective modes, the principal components, which are assumed to behave as effectively independent harmonic oscillators. Projection of the protein's motion in water onto the plane defined by the first two principal components shows a clustering effect in the trajectory, absent in the vacuum trajectory. This is thought to be due to many local minima in the free energy surface caused by solute-solvent interactions. In order to assess the viscous effect of the solvent, friction coefficients for the principal components were determined by analyzing their velocity correlation functions in terms of the Langevin equation for an independent damped oscillator. Consistent with this analysis is that all modes have friction coefficients centered on the value of 47 cm-1 in a range of +/- 10 cm-1. With this friction coefficient, all modes of effective frequencies below 23.5 cm-1 display overdamped motion. By assuming the harmonic approximation for the conformational energy surface for BPTI in vacuum to be valid for BPTI in water, and treating each mode as an independent damped oscillator with a friction coefficient of 47 cm-1, the shift to higher frequencies in the water spectrum relative to the vacuum spectrum could be almost exactly reproduced, indicating this shift is due solely to the viscous effect of the solvent. By analyzing the time correlation functions of the first four principal components it is found that they can be very well described as independent damped oscillators each with a friction coefficient of 47 cm-1.

Replication of Epstein-Barr virus oriLyt: lack of a dedicated virally encoded origin-binding protein and dependence on Zta in cotransfection assays

Using a transient replication assay in which cosmid DNAs were cotransfected into Vero cells, we had previously demonstrated that oriLyt replication required six Epstein-Barr virus (EBV)-encoded replication genes. No oriLyt origin-binding protein was identified in this study, but oriLyt replication in the cotransfection assay was also dependent on the three lytic cycle transactivators Zta, Rta, and Mta and an activity encoded by the EBV Sal/I F fragment. We have now used expression plasmids for the six known replication proteins to further examine the question of the requirement for an oriLyt origin-binding protein. The activity in Sal/I-F was shown to be encoded by BKRF3. The predicted product of this open reading frame is an enzyme, uracyl DNA glycosylase, not an origin-binding protein, and is dispensable for replication in assays using expression plasmids. BBLF2, which is positionally related to the gene for the herpes simplex virus (HSV) UL9 origin-binding protein, was confirmed to be expressed as a spliced transcript with BBLF3 and not as an independent product. Examination of the requirement for the EBV transactivators revealed that Rta, while contributing to replication efficiency, was dispensable. Mta could be substituted by HSV IE63, and in complementation experiments with HSV replication genes, Mta was no longer required for replication of EBV oriLyt, suggesting that the contribution of Mta to replication may be indirect. Zta continued to be required for detectable oriLyt replication both with the EBV replication proteins and in the complementation assays with HSV replication proteins. We conclude that EBV does not encode an equivalent of HSV UL9 and that Zta is the sole virally encoded protein serving an essential origin-binding function.

The Epstein-Barr virus immortalizing protein EBNA-2 is targeted to DNA by a cellular enhancer-binding protein

The Epstein-Barr virus nuclear antigen EBNA-2 is essential for Epstein-Barr virus-induced immortalization of B cells. EBNA-2 is a transcriptional activator capable of modifying the expression of specific viral and cellular genes. However, the mechanism of EBNA-2 transactivation has been an enigma. We used a fractionated extract of CA46 lymphoblastoid cells and bacterially expressed EBNA-2 polypeptides to demonstrate that EBNA-2 is targeted to the Epstein-Barr virus latency C promoter (Cp) through interaction with a cellular DNA binding protein designated Cp binding factor 1 (CBF1). A glutathione S-transferase-EBNA-2 fusion protein containing aa 252-425 of EBNA-2 interacted with CBF1 to yield a slowly migrating complex in an electrophoretic mobility shift assay. Mutation of EBNA-2 aa 323 and 324, which lie within a highly conserved amino acid motif, abolished the interaction with CBF1. This same mutation also abolished the ability of EBNA-2 to activate the Cp in a cotransfection assay. The binding site for CBF1 was localized to residues -359 to -388 of the Cp by using an electrophoretic mobility shift assay and DNase I footprinting. Introduction of multiple copies of the CBF1 binding site upstream of a minimal heterologous promoter conferred EBNA-2 responsiveness on that promoter. Mutation of a core sequence CNGTGGGAA abolished CBF1 binding, and the mutated sequence was unable to mediate EBNA-2 transactivation. The CBF1 core sequence also occurs in other EBNA-2-responsive promoters suggesting that CBF1 may mediate EBNA-2 transactivation of both cellular and viral targets.

Domain motions in bacteriophage T4 lysozyme: a comparison between molecular dynamics and crystallographic data

A comparison of a series of extended molecular dynamics (MD) simulations of bacteriophage T4 lysozyme in solvent with X-ray data is presented. Essential dynamics analyses were used to derive collective fluctuations from both the simulated trajectories and a distribution of crystallographic conformations. In both cases the main collective fluctuations describe domain motions. The protein consists of an N- and C-terminal domain connected by a long helix. The analysis of the distribution of crystallographic conformations reveals that the N-terminal helix rotates together with either of these two domains. The main domain fluctuation describes a closure mode of the two domains in which the N-terminal helix rotates concertedly with the C-terminal domain, while the domain fluctuation with second largest amplitude corresponds to a twisting mode of the two domains, with the N-terminal helix rotating concertedly with the N-terminal domain. For the closure mode, the difference in hinge-bending angle between the most open and most closed X-ray structure along this mode is 49 degrees. In the MD simulation that shows the largest fluctuation along this mode, a rotation of 45 degrees was observed. Although the twisting mode has much less freedom than the closure mode in the distribution of crystallographic conformations, experimental results suggest that it might be functionally important. Interestingly, the twisting mode is sampled more extensively in all MD simulations than it is in the distribution of X-ray conformations.

Origin-independent assembly of Kaposi's sarcoma-associated herpesvirus DNA replication compartments in transient cotransfection assays and association with the ORF-K8 protein and cellular PML

Six predicted Kaposi's sarcoma virus herpesvirus (KSHV) proteins have homology with other well-characterized herpesvirus core DNA replication proteins and are expected to be essential for viral DNA synthesis. Intact Flag-tagged protein products from all six were produced from genomic expression vectors, although the ORF40/41 transcript encoding a primase-helicase component proved to be spliced with a 127-bp intron. The intracellular localization of these six KSHV replication proteins and the mechanism of their nuclear translocation were investigated. SSB (single-stranded DNA binding protein, ORF6) and PPF (polymerase processivity factor, ORF59) were found to be intrinsic nuclear proteins, whereas POL (polymerase, ORF9), which localized in the cytoplasm on its own, was translocated to the nucleus when cotransfected with PPF. PAF (primase-associated factor, ORF40/41), a component of the primase-helicase tripartite subcomplex together with PRI (primase, ORF56) and HEL (helicase, ORF44), required the presence of all five other replication proteins for efficient nuclear translocation. Surprisingly, even in the absence of a lytic cycle replication origin (ori-Lyt) and any known initiator or origin binding protein, the protein products of all six KSHV core replication genes cooperated in a transient cotransfection assay to form large globular shaped pseudo-replication compartments (pseudo-RC), which excluded cellular DNA. These pseudo-RC structures were confirmed to include POL, SSB, PRI, and PAF but did not contain any newly synthesized DNA. Similar to the human cytomegalovirus system, the peripheries of these KSHV pre-RC were also found to be surrounded by punctate PML oncogenic domains (PODs). Furthermore, by transient cotransfection, the six KSHV core replication machinery proteins successfully replicated a plasmid containing EBV ori-Lyt in the presence of the Epstein-Barr virus-encoded DNA binding initiator protein, ZTA. The KSHV-encoded K8 (ORF-K8) protein, which is a distant evolutionary homologue to ZTA, was incorporated into pseudo-RC structures formed by transient cotransfection with the six core KSHV replication genes. However, unlike ZTA, K8 displayed a punctate nuclear pattern both in transfected cells and at early stages of lytic infection and colocalized with the cellular PML proteins in PODs. Finally, K8 was also found to accumulate in functional viral RC, detected by incorporation of pulse-labeled bromodeoxyuridine into newly synthesized DNA in both tetradecanoyl phorbol acetate-induced JSC-1 primary effusion lymphoblasts and in KSHV lytically infected endothelial cells.