236 research outputs found
Tumor-specific activity of cellular regulatory elements is down-regulated upon insertion into the herpes simplex virus genome
Transcriptional targeting of viral genes is a promising strategy to achieve tumor-specific replication of oncolytic viruses. Due to its natural tropism, herpes simplex virus type 1 (HSV-1) may be an ideal tool for oncolytic therapy of brain tumors such as malignant glioblastoma. To study whether glioma-specific gene expression can be accomplished within the HSV-1 genome, four cellular regulatory elements were exemplarily studied. Whereas the human telomerase reverse transcriptase (hTERT) and survivin promoters and the nestin and vascular endothelial growth factor A (VEGF-A) enhancers displayed pronounced glioma specificity after plasmid transfection, only the nestin enhancer conferred a certain selectivity for glioma cells and notable activity when transferred into the viral genome. The nestin enhancer was also found to be highly useful for tumor cell-specific expression of a therapeutically relevant gene (interleukin-2) when tested in combination with the hTERT or simian virus 40 (SV40) early promoter in the HSV-1 genome. Because activity of the chosen promoter in a tumor is a prerequisite for the successful application of an oncolytic virus, we examined whether the activity of a promoter can be deduced from the amounts of cellular mRNA or protein expressed under its control. We found little correlation between promoter activity and mRNA levels of the corresponding gene, whereas protein expression was more closely related to promoter activity. We conclude that the cellular elements are differently regulated in the viral and cellular genomes. Mechanistic insight into the differential regulation is required to improve and refine the design of transcriptionally targeted HSV vectors. Journal of NeuroVirology (2008) 14, 522-535
Characterization of the murine cytomegalovirus genes encoding the major DNA binding protein and the ICP18.5 homolog
In several herpesviruses the genes for the major DNA binding protein (MDBP), a putative assembly protein, the
glycoprotein B (gB), and the viral DNA polymerase (pol) coliocate. In murine cytomegalovirus (MCMV), two members
of this gene block, pol (Elliott, Clark, Jaquish, and Spector, 1991, Virology 185, 169-186) and gB (Rapp, Messerle,
BOhler, Tannheimer, Keil, and Koszinowski, 1992, J. Virol., 66,4399-4406) have been characterized. Here the two other
MCMV genes are characterized, the gene encoding the MDBP and the ICP18.5 homolog encoding a putative
assembly protein. Like in human cytomegalovirus (HCMV) the genes order is pol, gB, ICP18.5, and MDBP. The 4.2-kb
MDBP mRNA is expressed first in the early phase, whereas the 3.0-kb ICP18.5 mRNA is a late transcript. The open
reading frame of the MDBP gene has the capacity of encoding a protein of 1191 amino acids with a predicted molecular
mass of 131.7 kDa. The MCMV ICP18.5 ORF is translated into a polypeptide of 798 amino acids with a calculated
molecular mass of 89.1 kDa. Comparison of the amino acid sequences of the predicted proteins of MCMV with the
respective proteins of HCMV, Epstein-Barr virus (EBV), and herpes simplex virus type-1 (HSV-1) reveals a striking
homology ranging from 72% (HCMV), 50% (EBV), to 45% (HSV-1) for the MDBP sequence and from 74% (HCMV), 51 %
(EBV), to 49% (HSV-1) for the ICP18.5 sequence. These results establish the elose relationship of the two cytomegaloviruses,
and underline the usefulness of the murine model for studies on the biology of the CMV infection
A redshifted codon-optimized firefly luciferase is a sensitive reporter for bioluminescence imaging
Bioluminescence imaging has evolved as a powerful tool for monitoring biological processes in vivo. As transmission efficiency of light through tissue increases greatly for wavelengths above 600 nm we examined whether a redshifted codon-optimized firefly luciferase (lambda(max) = 615 nm) could be successfully employed as a sensitive reporter in mammalian cells. To this end, unmodified codon-optimized luciferase ( lmax = 557 nm) as well as the red-emitting S284T mutant luciferase were expressed simultaneously in human glioma cells in vitro as well as in quadriceps muscles of mice in vivo. We show here that activity of the redshifted enzyme in human glioma cell culture approached approximately one-fourth of that seen with the unmodified enzyme. In contrast, light emission by the red-emitting luciferase in vivo was generally more efficient than that produced by its unmodified counterpart, most likely due to reduced absorption of red light by tissue. The mean ratio of light emission produced by the redshifted luciferase to that of the unmodified enzyme in vivo was similar to 3. Application of this new redshifted luciferase together with other optical reporters may be of considerable importance to biological research as it allows for imaging of deeper tissues as well as simultaneous monitoring of two molecular events in vitro and in vivo if appropriate filter sets are employed
An acidic region of the 89K murine cytomegalovirus immediate early protein interacts with DNA
The product of the ie 1 gene, the regulatory immediate early protein pp89 of murine cytomegalovirus (MCMV), interacts with core histones, which can mediate the association of pp89 with DNA. We report the capacity of pp89 to interact directly with DNA in the absence of cellular proteins. After separation of proteins by SDS–PAGe, pp89 bound ds- and ssDNA, with a preference for ssDNA. Binding to specific DNA sequences in the MCMV genome was not detected. The DNA-binding region of pp89 was located to amino acids 438 to 534 by analysis of deletion mutants expressed as -galactosidase or TrpE fusion proteins. This region is identical to the highly acidic C-terminal region spanning amino acids 424 to 532. The human cytomegalovirus IE1 protein, which contains a similar extended C-terminal acidic region, does not react with DNA under the same experimental conditions
Structural organization, expression, and functional characterization of the murine cytomegalovirus immediate-early gene 3.
We have previously defined ie3 as a coding region located downstream of the ie1 gene which gives rise to a 2.75-kb immediate-early (IE) transcript. Here we describe the structural organization of the ie3 gene, the amino acid sequence of the gene product, and some of the functional properties of the protein. The 2.75-kb ie3 mRNA is generated by splicing and is composed of four exons. The first three exons, of 300, 111, and 191 nucleotides (nt), are shared with the ie1 mRNA and are spliced to exon 5, which is located downstream of the fourth exon used by the ie1 mRNA. Exon 5 starts 28 nt downstream of the 3' end of the ie1 mRNA and has a length of 1,701 nt. The IE3 protein contains 611 amino acids, the first 99 of which are shared with the ie1 product pp89. The IE3 protein expressed at IE times has a relative mobility of 88 kDa in gels, and a mobility shift to 90 kDa during the early phase is indicative of posttranslational modification. Sequence comparison reveals significant homology of the exon 5-encoded amino acid sequence with the respective sequence of UL 122, a component of the IE1-IE2 complex of human cytomegalovirus (HCMV). This homology is also apparent at the functional level. The IE3 protein is a strong transcriptional activator of the murine cytomegalovirus (MCMV) e1 promoter and shows an autoregulatory function by repression of the MCMV ie1/ie3 promoter. The high degree of conservation between the MCMV ie3 and HCMV IE2 genes and their products with regard to gene structure, amino acid sequence, and protein functions suggests that these genes play a comparable role in the transcriptional control of the two cytomegaloviruses
Analysis of the role of different pattern recognition receptors in murine cytomegalovirus-mediated activation of innate immunity
The Core Histone-binding Region of the Murine Cytomegalovirus 89K Immediate Early Protein
The gene regulatory immediate early protein, pp89, of murine cytomegalovirus interacts with both DNA-associated and isolated histones in vitro. We characterized the histone-binding region of pp89 and its cellular localization during cell division to examine the possible interaction between pp89 and chromatin. pp89 expressed constitutively in cell line BALB/c 3T3 IE1 does not interact with condensed chromatin. As observed in infected cells, pp89 is localized within the nucleus of cells during interphase but spreads throughout the cell plasma following degradation of the nuclear membrane during early mitosis. In late telophase, pp89 is reorganized within the nucleus. Analysis of pp89 deletion mutants and of fragments generated by cleavage at pH 2·5 revealed that the regions responsible for association with histone are located between amino acids 71 and 415, and are not identical with the domain that shows homology to histone H2B or the highly acidic carboxy-terminal region. A potential gene-activating role of the high affinity of pp89 for isolated histones and the low affinity for DNA-associated histones is discussed
An essential role of the enhancer for murine cytomegalovirus in vivo growth and pathogenesis
The transcription of cytomegalovirus (CMV) immediate-early (IE) genes is regulated by a large and complex enhancer containing an array of binding sites for a variety of cellular transcription factors. Previously, using bacterial artificial chromosome recombinants of the virus genome, it was reported that the enhancer region of murine CMV (MCMV) is dispensable but performs a key function for viral multiplication (A. Angulo, M. Messerle, U. H. Koszinowski, and P. Ghazal, J. Virol. 72:8502-8509, 1998). In the present study, we defined, through the reconstitution of infectious enhancerless MCMVs, the growth requirement for the enhancer in tissue culture and explored its significance for steering a productive infection in vivo. A comparison of cis and trans complementation systems for infection of enhancerless virus in permissive fibroblasts revealed a multiplicity-dependent growth phenotype that is severely compromised in the rate of infectious-virus multiplication. The in vivo impact of viruses that have an amputated enhancer was investigated in an extremely sensitive model of MCMV infection, the SCID mouse. Histological examination of spleens, livers, lungs, and salivary glands from animals infected with enhancer-deficient MCMV demonstrated an absence of tissue damage associated with CMV infection. The lack of pathogenic lesions correlated with a defect in replication competence. Enhancerless viruses were not detectable in major target organs harvested from SCID mice. The pathogenesis and growth defect reverted upon restoration of the enhancer. Markedly, while SCID mice infected with 5 PFU of parental MCMV died within 50 days postinfection, all mice infected with enhancerless virus survived for the duration of the experiment (1 year) after infection with 5 x 10(5) PFU. Together, these results clarify the importance of the enhancer for MCMV growth in cell culture and underscore the in vivo significance of this region for MCMV virulence and pathogenesis
Influence of HCMV proteins pUL71 and pUL77 on viral maturation
Die Bildung infektiöser Viruspartikel des humanen Zytomegalievirus (HCMV) ist ein mehr-stufiger Prozess. Sie beginnt mit der Verpackung der DNA in die Kapside im Kern, gefolgt von weiterer Reifung während des Transports durch das Zytoplasma und der abschließenden Freisetzung aus der Zelle. Im Zuge dieser Arbeit wurden zwei Proteine, die Einfluss auf die ebengenannten Prozesse haben, analysiert. Der erste Teil der Arbeit befasst sich mit der funktionellen Charakterisierung des HCMV Pro-teins pUL77. Es ist bekannt, dass das homologe Protein pUL25 in alpha-Herpesvirinae essentiell für die DNA-Verpackung ist. Zunächst konnte das Protein als Kapsid-assoziiertes strukturelles Protein identifiziert werden. Es wurden Interaktionen von pUL77 mit DNA-Verpackungs- und Kapsidproteinen gezeigt. Weiterhin wurde die DNA-Bindungsfähigkeit von pUL77 in verschiedenen „in vitro“-Experimenten untersucht. Zusammengefasst weisen unsere Ergebnisse auf eine Funktion von HCMV pUL77 bei der DNA-Verpackung hin. Im zweiten Teil der Arbeit wurde das HCMV Protein pUL71 charakterisiert, das in allen Herpesviren konserviert vorkommt, dessen Funktion jedoch nicht charakterisiert ist. Zunächst wurde das Protein als strukturelles Tegumentprotein mit “earlylate“ Expressionskinetik klassifiziert. Weiterhin wurden die subzelluläre Lokalisation sowie virale und zelluläre Interaktionspartner untersucht. Die Ergebnisse weisen auf eine Funktion von HCMV pUL71 bei der Reifung und beim Transport der Virionen im Zytoplasma hin. „In silico“-Vorhersagen zeigten ein „Leuzin Zipper“-Motiv in pUL71, das als mögliche Oligomerisationsdomäne dienen könnte. Mutationen wurden in dieses Motiv eingebracht und die resultierenden Proteine auf ihre Oligomerisationsfähigkeit mit „in vitro“-Methoden und in rekombinanten Viren untersucht. Zusammenfassend konnten wir zeigen, dass das „Leuzin Zipper“-Motiv wichtig für die Funktion von pUL71 ist und diese mit einer unbeeinträchtigten Oligomerisation des Proteins zusammen hängt.The morphogenesis of Human cytomegalovirus (HCMV) virions starts with the capsid assem-bly and DNA insertion in the nucleus followed by maturation during transport through the cytoplasm prior to release of virus progeny. In this study we are functionally characterising two proteins that are involved in those steps. The function of essential HCMV protein pUL77 is characterised in the first part of the study. HCMV pUL77 was shown to be a structural protein associated with capsids. Furthermore, our experiments demonstrated that HCMV pUL77 interacts with DNA packaging motor compo-nents and capsid proteins. The ability of HCMV pUL77 to bind double-stranded DNA was studied in “in vitro” assays designed for this study. The homologue α-Herpesvirinae protein pUL25 is described to be involved in processes connected with DNA packaging. Data ob-tained in this study demonstrates that HCMV pUL77 might serve a similar function. In the second part of the study HCMV pUL71, conserved throughout the Herpesvirus family but to date unclassified, was functionally characterised. HCMV pUL71 was defined a struc-tural tegument protein with early-late expression kinetics. We studied the sub-cellular local-isation and interactions of pUL71 with a subset of cellular and viral proteins. Thereby we could show that HCMV pUL71 function might be connected with processes of viral egress. By in silico analyses we identified a leucine zipper motif in pUL71 that might serve as a puta-tive oligomerisation domain. In order to investigate the function of the leucine zipper motif, we performed in vitro assays and investigated the alterations of the motif in the viral context. Taken together we can conclude that (i) an intact leucine zipper motif is crucial for the func-tion of pUL71 and (ii) this function is dependent upon undisturbed oligomerisation of the pro-tein
Immune response against human cytomegalovirus in the context of hematopoietic stem cell transplantation (HSCT)
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