Showing papers by "Juan Ortín published in 1996"

Open reading frame 5 of porcine reproductive and respiratory syndrome virus as a cause of virus-induced apoptosis.

Abstract: The gene product of open reading frame 5 (p25) of porcine reproductive and respiratory syndrome (PRRS) virus has been expressed by coinfection of culture cells with vaccinia virus expressing the T7 RNA polymerase and a recombinant vaccinia virus encoding the open reading frame 5 gene under the T7 promoter and the encephalomyocarditis virus internal ribosome entry site. In spite of the reported efficiency of the expression system, very poor accumulation of p25 protein was observed and a strong cytotoxicity was produced in the doubly infected cells. This cell toxicity was shown to occur by induction of apoptosis, as indicated by nucleosome ladder formation, chromatin condensation, and rRNA degradation. Apoptosis induction was also observed after infection of cultured cells with an adapted PRRS virus strain and after infection of swine macrophage cells with a PRRS virus field strain. Contrary to the observations made for other cases of virus-induced apoptosis, we could not prevent p25 protein-induced apoptosis by using a cell line permanently expressing Bcl-2 protein.

Identification of Two Separate Domains in the Influenza Virus PB1 Protein Involved in the Interaction with the PB2 and PA Subunits: A Model for the Viral RNA Polymerase Structure

Abstract: The domains of the PB1 subunit of the influenza virus polymerase involved in the interaction with the PB2 and PA subunits have been defined by mutational analysis of PB1 protein. The experimental approach included in vivo competition of the PB1 activity, two-hybrid interaction assays and in vitro binding to PB1-specific matrices. Mutants of the PB1 gene including N-terminal, C-terminal and internal deletions and single amino acid insertions were constructed. They were unable to support polymerase activity in a reconstituted transcription-replication system and were tested for their competition activity when expressed in excess over wild-type PB1 protein. The pattern of competition obtained suggested that the N-terminal 78 amino acids and the sequences between positions 506 and 659 in the PB1 protein are involved in the interaction with the other components of the polymerase. We identified the N-terminal region of PB1 protein as responsible for the interaction with the PA subunit by two-hybrid assays in mammalian cells. N- and C-terminal fragments of the PB1 protein were expressed as His-tagged proteins and purified on Ni2+-NTA resin. Such PB1-specific matrices were used in binding assays in vitro with metabolically labelled PB2 and PA proteins and mutants thereof. The results obtained indicated that the N-terminal and the C-terminal regions of PB1 are responsible for binding to PA and PB2 subunits, respectively. With this information and previously published results we propose a preliminary model for the architecture of the influenza virus RNA polymerase.

The amino-terminal one-third of the influenza virus PA protein is responsible for the induction of proteolysis.

Abstract: We have previously described the fact that the individual expression of influenza virus PA protein induced a generalized proteolysis (J.J. Sanz-Ezquerro, S. de la Luna, Ortin, and A. Nieto, J. Virol. 69:2420-2426, 1995). In this study, we have further characterized this effect by mapping the regions of PA protein required and have found by deletion analysis that the first 247 amino acids are sufficient to bring about this activity. PA mutants that were able to decrease the accumulation levels of coexpressed proteins also presented lower steady-state levels due to a reduction in their half-lives. Furthermore, the PA wild type produced a decrease in the stationary levels of different PA versions, indicating that is itself a target for its induced proteolytic process. All of the PA proteins that induced proteolysis presented nuclear localization, being the sequences responsible for nuclear transport located inside the first 247 amino acids of the molecule. To distinguish between the regions involved in nuclear localization and those involved in induction of proteolysis, we fused the nuclear localization signal of the simian virus 40 T antigen to the carboxy terminus of the cytosolic versions of PA. None of the cytosolic PA versions affected in the first 247-amino-acid part of PA, which were now located in the nucleus, were able to induce proteolysis, suggesting that conservation of a particular conformation in this region of the molecule is required for the effect observed. The fact that all of the PA proteins able to induce proteolysis presented nuclear localization, together with the observation that this activity is shared by influenza virus PA proteins from two different type A viruses, suggests a physiological role for this PA protein activity in viral infection.

Mutational analysis of the influenza virus A/Victoria/3/75 PA protein: studies of interaction with PB1 protein and identification of a dominant negative mutant.

Abstract: The RNA polymerase activity and PB1 binding of influenza virus PA mutants were studied using an in vivo-reconstituted polymerase assay and a two hybrid system. Deletions covering the whole PA protein abolished polymerase activity, but the deletion of the 154 N-terminal amino acids allowed PB1 binding, indicating that the PA protein N terminus is not absolutely required for this interaction. Further internal or C-terminal deletions abolished PB1 interaction, suggesting that most of the protein is involved in this association. As a novel finding we showed that a single amino acid insertion mutant, PAI672, was responsible for a temperature-sensitive phenotype. Mutant PAS509, which had a serine insertion at position 509, bound to PB1 like wild-type PA but did not show any polymerase activity. Over-expression of PAS509 interfered with the polymerase activity of wild-type PA, identifying PAS509 as a dominant negative mutant.

Mutational analysis identifies functional domains in the influenza A virus PB2 polymerase subunit.

Abstract: A collection of influenza virus PB2 mutant genes was prepared, including N-terminal deletions, C-terminal deletions, and single-amino-acid insertions. These mutant genes, driven by a T7 promoter, were expressed by transfection into COS-1 cells infected with a vaccinia virus encoding T7 RNA polymerase. Mutant proteins accumulated to levels similar to that of wild-type PB2. Immunofluorescence analyses showed that the C-terminal region of the protein is essential for nuclear transport and that internal sequences affect nuclear localization, confirming previous results (J. Mukaijawa and D. P. Nayak, J. Virol. 65:245-253, 1991). The biological activity of these mutants was tested by determining their capacity to (i) reconstitute RNA polymerase activity in vivo by cotransfection with proteins NP, PB1, and PA and a virion-like RNA encoding the cat gene into vaccinia virus T7-infected COS-1 cells and (ii) complete with the wild-type PB2 activity. In addition, when tested at different temperatures in vivo, two mutant PB2 proteins showed a temperature-sensitive phenotype. The lack of interference shown by some N-terminal deletion mutants and the complete interference obtained with a C-terminal deletion mutant encoding only 124 amino acids indicated that this protein domain is responsible for interaction with another component of the polymerase, probably PB1. To further characterize the mutants, their ability to induce in vitro synthesis of viral cRNA or mRNA was tested by using ApG or beta-globin mRNA as a primer. One of the mutants, 1299, containing an isoleucine insertion at position 299, was able to induce cRNA and mRNA synthesis in ApG-primed reactions but required a higher beta-globin mRNA concentration than wild-type PB2 for detection of in vitro synthesis. This result suggested that mutant I299 has diminished cap-binding activity.