28,670 research outputs found
Rotavirus Replication Requires a Functional Proteasome for Effective Assembly of Viroplasms
The ubiquitin-proteasome system has been shown to play an important role in the replication cycle of different viruses. In this study, we describe a strong impairment of rotavirus replication upon inhibition of proteasomal activity. The effect was evidenced at the level of accumulation of viral proteins, viral RNA, and yield of infective particles. Kinetic studies revealed that the early steps of the replicative cycle following attachment, entry, and uncoating were clearly more sensitive to proteasome inhibition. We ruled out a direct inhibition of the viral polymerase activities and stability of viral proteins and found that the crucial step that was impaired by blocking proteasome activity was the assembly of new viroplasms. This was demonstrated by using chemical inhibitors of proteasome and by gene silencing using small interfering RNAs (siRNAs) specific for different proteasomal subunits and for the ubiquitin precursor RPS27A. In addition, we show that the effect of proteasome inhibition on virus infection is not due to increased levels of beta interferon (IFN-β)
Rotavirus NSP5 orchestrates recruitment of viroplasmic proteins
Rotavirus genome replication and the first steps of virus morphogenesis take place in cytoplasmic viral factories, called viroplasms, containing four structural (VP1, VP2, VP3 and VP6) and two non-structural (NSP2 and NSP5) proteins. NSP2 and NSP5 have been shown to be essential for viroplasm formation and, when co-expressed in uninfected cells, to form viroplasm-like structures (VLS). In the present work, VLS formation was shown upon co-expression of NSP5 with the core protein VP2 despite the absence of NSP2, indicating a central role for NSP5 in VLS assembly. Since VP2 and NSP2 also induce NSP5 hyperphosphorylation, the possible correlation between VLS formation and the NSP5 phosphorylation status was investigated without evidence of a direct link. In VLS induced by NSP2, the polymerase VP1 was recruited, while the middle layer protein VP6 was not, forming instead tubular structures. On the other hand, VLS induced by VP2 were able to recruit both VP1 and VP6. More importantly, in VLS formed when NSP5 was expressed with both inducers, all viroplasmic proteins were found co-localized, resembling their distribution in viroplasms. Our results suggest a key role for NSP5 in architectural assembly of viroplasms and in recruitment of viroplasmic proteins. A new role for VP2 as an inducer of viroplasms and of NSP5 hyperphosphorylation is also described. These data may contribute to the understanding of rotavirus morphogenesis
A minimal receptor-Ig chimera of human FcεRI α-chain efficiently binds secretory and membrane IgE
We constructed a soluble minimal receptor-Ig chimera in which the two extracellular domains of human FcεRI α-chain (D1 and D2) were fused to the dimerizing C-terminal domain of human IgG1 heavy chain (γ1-CH3). The protein was expressed and actively secreted by Chinese hamster ovary (CHO) cells as a fully glycosylated soluble dimeric protein. It showed efficient binding both to human membrane-bound IgE isoforms and to the two secretory IgE isoforms. Moreover, the dimeric receptor binds IgE with the expected 1:2 stoichiometry. The receptor-Ig chimera, in 2-fold molar excess, inhibited engagement of secretory IgE to rat basophilic leukemia cells expressing the human αβγ receptor. Full self-nature and inability to bind Fcγ receptors make this protein an attractive candidate for clinical applications and a novel biotechnological tool for atopic allergy research
Boosting anti-idiotype immune response with recombinant AAV enhances tumour protection induced by gene gun vaccination.
Thanks to the safety of administration, efficiency of in vivo transduction and persistence of transgene expression, vectors based on the adeno-associated virus (AAV) are extensively utilized in both preclinical and clinical experimentation. Here we thoroughly explore the potential of AAV-mediated antigen delivery for tumour vaccination. A recombinant AAV vector (rAAV) encoding a lymphoma idiotype (Id) in a single-chain variable fragment format was found to induce an efficient anti-Id immune response upon injection in immunocompetent animals. The intensity of the immune response and the protective effect of rAAV administration in vivo were systematically compared with those elicited by simple injection of naked DNA or biolistic immunization. The results indicate that Id delivery via rAAV enhances the intensity of immune response compared with injection of naked DNA, while anti-idiotypic antibodies titres are not considerably increased compared with biolistic vaccination. On the contrary, a prime-boost vaccination strategy combining biolistic and AAV DNA delivery results in a major increase in anti-Id antibody response compared with the repetitive biolistic immunization. This increased anti-Id humoral response strictly correlated with a significant improvement on tumour protection in vivo
Impaired hyperphosphorylation of rotavirus NSP5 in cells depleted of casein kinase 1 is associated with the formation of viroplasms with altered morphology and a moderate decrease in virus replication
The rotavirus (RV) non-structural protein 5, NSP5, is encoded by the smallest of the 11 genomic segments and localizes in 'viroplasms', cytoplasmic inclusion bodies in which viral RNA replication and packaging take place. NSP5 is essential for the replicative cycle of the virus because, in its absence, viroplasms are not formed and viral RNA replication and transcription do not occur. NSP5 is produced early in infection and undergoes a complex hyperphosphorylation process, leading to the formation of proteins differing in electrophoretic mobility. The role of hyperphosphorylation of NSP5 in the replicative cycle of rotavirus is unknown. Previous in vitro studies have suggested that the cellular kinase CK1alpha is responsible for the NSP5 hyperphosphorylation process. Here it is shown, by means of specific RNA interference, that in vivo, CK1alpha is the enzyme that initiates phosphorylation of NSP5. Lack of NSP5 hyperphosphorylation affected neither its interaction with the virus VP1 and NSP2 proteins normally found in viroplasms, nor the production of viral proteins. In contrast, the morphology of viroplasms was altered markedly in cells in which CK1alpha was depleted and a moderate decrease in the production of double-stranded RNA and infectious virus was observed. These data show that CK1alpha is the kinase that phosphorylates NSP5 in virus-infected cells and contribute to further understanding of the role of NSP5 in RV infection
New Tags for Recombinant Protein Detection and O-Glycosylation Reporters
Monoclonal antibodies (mAbs), because of their unique specificity, are irreplaceable tools for scientific research. Precise mapping of the antigenic determinants allows the development of epitope tagging approaches to be used with recombinant proteins for several purposes. Here we describe a new family of tags derived from the epitope recognized by a single highly specific mAb (anti-roTag mAb), which was obtained from a pool of mAbs reacting with the rotavirus nonstructural protein 5 (NSP5). The variable regions of the anti-roTag mAb were identified and their binding capacity verified upon expression as a single-chain/miniAb. The minimal epitope, termed roTag, was identified as a 10 amino acid sequence (SISSSIFKNE). The affinity of the anti-roTag/roTag interaction was found to be comparable to that of the anti-SV5/SV5 tag interaction. roTag was successfully used for detection of several recombinant cytosolic, secretory and membrane proteins. Two additional variants of roTag of 10 and 13 amino acids containing O-glycosylation susceptible sites (termed OG-tag and roTagO) were constructed and characterised. These tags were useful to detect proteins passing through the Golgi apparatus, the site of O-glycosylation
Binders based on dimerised immunoglobulin VH domains
Antibody binding to antigen is mediated by the surface formed by the association of the two variable (V) regions of the L (VL) and H (VH) chains. The capacity of VL to dimerise and the high structural similarity of VL and VH domains suggested the possibility that VH could also associate. We show here that spontaneous formation of VH dimers (VHD) is in many cases permissive, producing stable molecules with antigen binding specificity. VHD were displayed on filamentous phages for the selection of antigen-specific binders. VHD were expressed and secreted efficiently from both bacteria and mammalian cells in different formats, including single-chain (VH(1)-linker-VH(2)), double chain ((VH(2)) and IgG analogues having the VL replaced by VH. The affinity (Kd,app) achieved with a VH dimer expressed in the IgG format, specific for a glutenin subunit was around 30 nM measured by two different methods, which was about 20 times higher than that corresponding to the VL/VH counterpart
Membrane immunoglobulins are stabilized by interchain disulfide bonds occurring within the extracellular membrane-proximal domain
Membrane-bound immunoglobulins have, in addition to the transmembrane and cytoplasmic portions, an extracellular membrane-proximal domain (EMPD), absent in the secretory forms. EMPDs of immunoglobulin isotypes α, γ, and ε contain cysteines whose role has so far not been elucidated. Using a genetic strategy, we investigated the ability of these cysteines to form disulfide bridges. Shortened versions of human membrane immunoglobulins, depleted of cysteines known to form intermolecular disulfide bonds, were constructed and expressed on the surface of a B-cell line. The resulting membrane proteins contain a single chain fragment of variable regions (scFv) linked to the dimerizing domain from the immunoglobulin heavy chains (CH3 for α and γ or CH4 for ε isotypes), followed by the corresponding EMPD and the transmembrane and cytoplasmic domains. The two functional membrane versions of the ε chain, containing the short and long EMPD, were analyzed. Our results show that the single cysteine within α1L and γ1 EMPD and the short version of ε EMPD form an interchain disulfide bond. Conversely, the cysteine resident in the ε transmembrane domain remains unreacted. ε-long EMPD contains four cysteines; two are involved in interchain bonds while the remaining two are likely forming an intrachain bridge. Expression of a full-length membrane ε heavy chain mutant, in which Cys121 and Cys209 within domain CH2 (involved in interchain bridges) were mutated to alanines, confirmed that, within the complete IgE, EMPD cysteines form interchain disulfide bonds. In conclusion, we unveil evidence for additional covalent stabilization of membrane-bound immunoglobulins
"Closing the R&D Gap, Evaluating the Sources of R&D Spending"
Both spending and tax policies have been implemented in the United States with the goal of stimulating private sector research and development (R&D). Karier questions whether current R&D policy, especially the research and experimentation tax credit, can contribute to closing the gap between nondefense expenditures on R&D in the United States and such expenditures in other countries, such as Japan and Germany. He also explores possible changes to our current R&D policy to make it more effective.
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