Genome-wide analysis of vaccinia virus protein–protein interactions

McCraith, Stephen M.; Holtzman, Ted; Moss, Bernard; Fields, Stanley

doi:10.1073/pnas.080078197

Cited by 265 publications

(222 citation statements)

References 57 publications

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“…Therefore, we can expect that the future accumulation of more interaction data will enable us to predict protein function more precisely. In addition, we will soon be able to apply our method to the proteins of other organisms, because several projects to determine protein-protein interaction data of various organisms are ongoing (Walhout et al, 2000;McCraith et al, 2000). The third column represents the frequency of proteins belonging to each class and the subsequent columns represent the percentage prediction accuracy for each n value (the dummy prediction accuracy obtained from randomized function assignments is shown in parentheses).…”

Section: Discussionmentioning

confidence: 99%

Assessment of prediction accuracy of protein function from protein–protein interaction data

Hishigaki

Nakai

Ono

et al. 2001

Yeast

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Functional prediction of open reading frames coded in the genome is one of the most important tasks in yeast genomics. Among a number of large-scale experiments for assigning certain functional classes to proteins, experiments determining protein-protein interaction are especially important because interacting proteins usually have the same function. Thus, it seems possible to predict the function of a protein when the function of its interacting partner is known. However, in vitro experiments often suffer from artifacts and a protein can often have multiple binding partners with different functions. We developed an objective prediction method that can systematically include the information of indirect interaction. Our method can predict the subcellular localization, the cellular role and the biochemical function of yeast proteins with accuracies of 72.7%, 63.6% and 52.7%, respectively. The prediction accuracy rises for proteins with more than three binding partners and thus we present the open prediction results for 16 such proteins.

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Section: Discussionmentioning

confidence: 99%

Assessment of prediction accuracy of protein function from protein–protein interaction data

Hishigaki

Nakai

Ono

et al. 2001

Yeast

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“…In fact, considering that 35 different ORFs were recognized and that a total of 258 potential ORFs were studied, it can be concluded that class I restricted responses can recognize at least 13.6% of the proteins encoded by the vaccinia virus genome. The 35 ORFs recognized were analyzed with respect to stage of expression (early͞intermediate vs. late) (21,(25)(26)(27)(28)(29) and function (structural protein, virulence factor, and regulation). We also analyzed the percent homology of the vaccinia epitopes with the comparable peptides in the genomes of variola major and MVA (Tables 8 and 9; see also Table 18, which is published as supporting information on the PNAS web site).…”

Section: Structural Analysis Of the Antigens Recognized After Vaccinamentioning

confidence: 99%

HLA class I-restricted responses to vaccinia recognize a broad array of proteins mainly involved in virulence and viral gene regulation

Oseroff

Kos

Bui

et al. 2005

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

139

178

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We have analyzed by ex vivo ELISPOT the anti-vaccinia cytotoxic T lymphocyte responses of peripheral blood mononuclear cells from humans vaccinated with Dryvax vaccine. More than 6,000 peptides from 258 putative vaccinia ORFs predicted to bind the common molecules of the HLA A1, A2, A3, A24, B7, and B44 supertypes were screened with peripheral blood mononuclear cells of 31 vaccinees. A total of 48 epitopes derived from 35 different vaccinia antigens were identified, some of which (B8R, D1R, D5R, C10L, C19L, C7L, F12, and O1L) were recognized by multiple donors and contain multiple epitopes recognized in the context of different HLA types. The antigens recognized tend to be >100 residues in length and are expressed predominantly in the early phases of infection, although some late antigens were also recognized. Viral genome regulation and virulence factor were recognized most frequently, whereas few structural proteins were immunogenic. Finally, most epitopes were highly conserved among vaccinia virus Western Reserve, variola major and modified vaccinia Ankara, supporting their potential use in vaccine and diagnostic applications.immunodominance ͉ smallpox vaccination ͉ virulence factors

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“…Protein-protein interaction maps have been studied, at different levels, in a variety of organisms including viruses (Bartel et al, 1996;Flajolet et al, 2000;McCraith et al, 2000), prokaryotes (Rain et al, 2001), yeast (Ito et al, 2000), and multicellular organisms such as C. elegans (Walhout et al, 2000). Previous studies have mainly used the so called two-hybrid assay (FromontRacine et al, 1997), based on the properties of sitespecific transcriptional activators.…”

Section: Topological Properties Of Real Proteome Mapsmentioning

confidence: 99%

Evolving protein interaction networks through gene duplication

Pastor-Satorras

Smith

Solé

2003

Journal of Theoretical Biology

355

280

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The topology of the proteome map revealed by recent large-scale hybridization methods has shown that the distribution of protein-protein interactions is highly heterogeneous, with many proteins having few links while a few of them are heavily connected. This particular topology is shared by other cellular networks, such as metabolic pathways, and it has been suggested to be responsible for the high mutational homeostasis displayed by the genome of some organisms. In this paper we explore a recent model of proteome evolution that has been shown to reproduce many of the features displayed by its real counterparts. The model is based on gene duplication plus re-wiring of the newly created genes. The statistical features displayed by the proteome of well-known organisms are reproduced, suggesting that the overall topology of the protein maps naturally emerges from the two leading mechanisms considered by the model.

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Genome-wide analysis of vaccinia virus protein–protein interactions

Cited by 265 publications

References 57 publications

Assessment of prediction accuracy of protein function from protein–protein interaction data

Assessment of prediction accuracy of protein function from protein–protein interaction data

HLA class I-restricted responses to vaccinia recognize a broad array of proteins mainly involved in virulence and viral gene regulation

Evolving protein interaction networks through gene duplication

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