Protein acetylation is important in regulating DNA-templated processes specifically and protein-protein interactions more generally in eukaryotes. The geminivirus movement protein NSP is essential for virus movement, shuttling the viral DNA genome between the nucleus and the cytoplasm. We have identified a novel Arabidopsis protein, AtNSI, that interacts with NSP. AtNSI is highly conserved among widely divergent plants. Biochemical studies show that its interaction with NSP is direct and that AtNSI acetylates histones, but not NSP, in vitro. Rather, AtNSI specifically acetylates the viral coat protein. AtNSI is a nuclear protein but does not act as a transcriptional coactivator in vitro, which distinguishes it from known eukaryotic histone acetyltransferases. Its overexpression enhances the efficiency of infection by Cabbage leaf curl virus . These findings suggest a role for protein acetylation in coordinating replication of the viral DNA genome with its export from the nucleus.
DNA viruses can modulate the activity of cellular acetyltransferases to regulate virus gene expression and to affect cell cycle progression in order to support virus replication. A role for protein acetylation in regulating the nuclear export of the bipartite geminivirus DNA genome was recently suggested by the findings that the viral movement protein NSP, which shuttles the viral genome between the nucleus and the cytoplasm, interacts with a novel Arabidopsis acetyltransferase, AtNSI, and the increased expression of AtNSI enhances susceptibility to Cabbage leaf curl virus infection. To further investigate the interaction of NSP and AtNSI and to establish the importance of this interaction in virus infections, we used a reverse yeast two-hybrid selection and deletion analysis to identify NSP mutants that were impaired in their ability to bind AtNSI. These mutants identified a 38-amino-acid region of NSP, to which no function had so far been assigned, as being necessary for NSP-AtNSI interaction. Three NSP missense mutants were analyzed in detail and were found to be comparable to wild-type NSP in their levels of accumulation, nucleocytoplasmic shuttling, DNA binding, and cooperative interaction with the viral cell-to-cell movement protein MP. Despite this, Cabbage leaf curl virus that expressed each mutated NSP was defective in its ability to infect Arabidopsis, exhibiting lower levels of infectivity than the wild-type virus, and delayed systemic spread of the virus and attenuated disease symptoms. Our data demonstrate the importance of the interaction of NSP with AtNSI for virus infection and pathogenicity.Successful infection by a virus depends on its ability to express its gene products, replicate, and move to adjacent cells. For plant viruses, this last step requires the action of virusencoded movement proteins to coordinate the replication of the viral genome with its cell-to-cell transport and to overcome the barrier of the plant cell wall (27, 50). Bipartite geminiviruses (Begomovirus) such as Cabbage leaf curl virus (CLCV) and Squash leaf curl virus (SqLCV), with their single-stranded DNA (ssDNA) genomes that replicate in the nucleus, accomplish this through the cooperative interaction of two movement proteins: the nuclear shuttle protein NSP and the cell-to-cell movement protein MP. NSP is a ssDNA binding protein responsible for transporting replicated viral genomes between the nucleus and the cytoplasm (39,46,56). MP traps these complexes in the cytoplasm and directs them to and across the cell wall (36,47,57). In the newly invaded cells, NSP-DNA complexes are released, and NSP targets the viral genome back to the nucleus to initiate new rounds of replication and infection (46).Although it is well recognized that movement proteins facilitate cell-to-cell transport of the viral genome by modifying plasmodesmata (37), the complex transwall channels that connect adjacent plant cells, little is known about how movement proteins reach plasmodesmata or the host factors that regulate movement protein function...
Molecular engineering to increase the percentage identity to common human immunoglobulin sequences of non-human therapeutic antibodies and scaffolds has become standard practice. This strategy is often used to reduce undesirable immunogenic responses, accelerating the clinical development of candidate domains. The first humanized shark variable domain (VNAR) was reported by Kovalenko and colleagues and used the anti-human serum albumin (HSA) domain, clone E06, as a model to construct a number of humanized versions including huE06v1.10. This study extends this work by using huE06v1.10 as a template to isolate domains with improved biophysical properties and reduced antigenicity. Random mutagenesis was conducted on huE06v1.10 followed by refinement of clones through an off-rate ranking-based selection on target antigen. Many of these next-generation binders retained high affinity for target, together with good species cross-reactivity. Lead domains were assessed for any tendency to dimerize, tolerance to N- and C-terminal fusions, affinity, stability, and relative antigenicity in human dendritic cell assays. Functionality of candidate clones was verified in vivo through the extension of serum half-life in a typical drug format. From these analyses the domain, BA11, exhibited negligible antigenicity, high stability and high affinity for mouse, rat, and HSA. When these attributes were combined with demonstrable functionality in a rat model of PK, the BA11 clone was established as our clinical candidate.
The difference noted in Rotavirus vaccine efficiency between high and low income countries correlates with the lack of universal access to clean water and higher standards of hygiene. Overcoming these obstacles will require great investment and also time, therefore more effective vaccines should be developed to meet the needs of those who would benefit the most from them. Increasing our current knowledge of mucosal immunity, response to Rotavirus infection and its modulation by circadian rhythms could point at actionable pathways to improve vaccination efficacy, especially in the case of individuals affected by environmental enteropathy. Also, a better understanding and validation of Rotavirus entry factors as well as the systematic monitoring of dominant strains could assist in tailoring vaccines to individual's needs. Another aspect that could improve vaccine efficiency is targeting to M cells, for which new ligands could potentially be sought. Finally, alternative mucosal adjuvants and vaccine expression, storage and delivery systems could have a positive impact in the outcome of Rotavirus vaccination.
DNA viruses can suppress or enhance the activity of cellular acetyltransferases to regulate virus gene expression and to affect cell cycle progression in support of virus replication. A role for protein acetylation in regulating the nuclear export of the bipartite geminivirus (Begomovirus) DNA genome was recently suggested by the findings that the viral movement protein NSP, a nuclear shuttle protein, interacts with the Arabidopsis (Arabidopsis thaliana) nuclear acetyltransferase AtNSI (nuclear shuttle protein interactor), and that this interaction and NSI expression are necessary for cabbage leaf curl virus infection and pathogenicity. To further investigate the consequences of NSI-NSP interactions, and the potential role of NSI in Arabidopsis growth and development, we used a reverse yeast two-hybrid selection and deletion analysis to identify NSI mutants that failed to interact with NSP, and promoter fusions to a uidA reporter gene to analyze the pattern of NSI expression during plant development. We found that NSI self assembles into highly active enzyme complexes and that high concentrations of NSP, in the absence of viral DNA, can inhibit NSI activity in vitro. Based on our detailed analysis of three NSI missense mutants, we identified an 88-amino acid putative domain, which spans NSI residues 107 to 194, as being required for both NSI oligomerization and its interaction with NSP. Finally, we found that NSI is predominantly transcribed in vascular cells, and that its expression is developmentally regulated in a manner that resembles the sink-to-source transition. Our data indicate that NSP can inhibit NSI activity by interfering with its assembly into highly active complexes, and suggest a mechanism by which NSP can both recruit NSI to regulate nuclear export of the viral genome and down-regulate NSI activity on cellular targets, perhaps to affect cellular differentiation and favor virus replication.
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