A functional and structural comparative analysis of large tumor antigens reveals evolution of different importin α-dependent nuclear localization signals

Structural basis for nuclear import of adeno-associated virus serotype 6 capsid protein

Adeno-associated viruses (AAVs) are the most extensively researched viral vectors for gene therapy globally. The AAV viral protein 1 (VP1) N-terminus controls the capsid's ability to translocate into the cell nucleus; however, the exact mechanism of this process is largely unknown. In this study, we sought to elucidate the precise interactions between AAV serotype 6 (AAV6), a promising vector for immune disorders, and host transport receptors responsible for vector nuclear localization. Focusing on the positively charged basic areas within the N-terminus of AAV6 VP1, we identified a 53-amino acid region that interacts with nuclear import receptors. We measured the binding affinities between this region and various nuclear import receptors, discovering a notably strong interaction with IMPα5 and IMPα7 in the low nanomolar range. We also elucidated the X-ray crystal structure of this region in complex with an importin alpha (IMPα) isoform, uncovering its binding as a bipartite nuclear localization signal (NLS). Furthermore, we show that using this bipartite NLS, AAV6 VP1 capsid protein can localize to the nucleus of mammalian cells in a manner dependent on the IMPα/IMPβ nuclear import pathway. This study provides detailed insights into the interaction between the AAV6 VP1 capsid protein and nuclear import receptors, deepening our knowledge of AAV nuclear import mechanisms and establishing a basis for the improvement of AAV6-based gene therapy vectors.IMPORTANCEAAVs, recognized as the most extensively researched viral vectors for gene therapy globally, offer significant advantages over alternatives due to their small size, non-pathogenic nature, and innate ability for tissue-specific targeting. AAVs are required to localize to the nucleus to perform their role as a gene therapy vector; however, the precise mechanisms that facilitate this process remain unknown. Despite sharing overt genomic similarities with AAV1 and AAV2, AAV6 is a unique serotype. It is currently recognized for its ability to effectively transduce hematopoietic cell lineages and, consequently, is considered promising for the treatment of immune disorders. Identifying the exact mechanisms that permit AAV6 to access the nucleus can open up new avenues for gene therapy vector engineering, which can ultimately lead to increased therapeutic benefits.

Mechanistic Insights Into an Ancient Adenovirus Precursor Protein VII Show Multiple Nuclear Import Receptor Pathways

Adenoviral pVII proteins are multifunctional, highly basic, histone-like proteins that can bind to and transport the viral genome into the host cell nucleus. Despite the identification of several nuclear localization signals (NLSs) in the pVII protein of human adenovirus (HAdV)2, the mechanistic details of nuclear transport are largely unknown. Here we provide a full characterization of the nuclear import of precursor (Pre-) pVII protein from an ancient siadenovirus, frog siadenovirus 1 (FrAdV1), using a combination of structural, functional, and biochemical approaches. Two strong NLSs (termed NLSa and NLSd) interact with importin (IMP)β1 and IMPα, respectively, and are the main drivers of nuclear import. A weaker NLS (termed NLSb) also contributes, together with an additional signal (NLSc) which we found to be important for nucleolar targeting and intranuclear binding. Expression of wild-type and NLS defective derivatives Pre-pVII in the presence of selective inhibitors of different nuclear import pathways revealed that, unlike its human counterpart, FrAdV1 Pre-pVII nuclear import is dependent on IMPα/β1 and IMPβ1, but not on transportin-1 (IMPβ2). Clearly, AdVs evolved to maximize the nuclear import pathways for the pVII proteins, whose subcellular localization is the result of a complex process. Therefore, our results pave the way for an evolutionary comparison of the interaction of different AdVs with the host cell nuclear transport machinery.

The varicella-zoster virus ORF16 protein promotes both the nuclear transport and the protein abundance of the viral DNA polymerase subunit ORF28

Although all herpesviruses utilize a highly conserved replication machinery to amplify their viral genomes, different members may have unique strategies to modulate the assembly of their replication components. Herein, we characterize the subcellular localization of seven essential replication proteins of varicella-zoster virus (VZV) and show that several viral replication enzymes such as the DNA polymerase subunit ORF28, when expressed alone, are localized in the cytoplasm. The nuclear import of ORF28 can be mediated by the viral DNA polymerase processivity factor ORF16. Besides, ORF16 could markedly enhance the protein abundance of ORF28. Noteworthily, an ORF16 mutant that is defective in nuclear transport still retained the ability to enhance ORF28 abundance. The low abundance of ORF28 in transfected cells was due to its rapid degradation mediated by the ubiquitin-proteasome system. We additionally reveal that radicicol, an inhibitor of the chaperone Hsp90, could disrupt the interaction between ORF16 and ORF28, thereby affecting the nuclear entry and protein abundance of ORF28. Collectively, our findings imply that the cytoplasmic retention and rapid degradation of ORF28 may be a key regulatory mechanism for VZV to prevent untimely viral DNA replication, and suggest that Hsp90 is required for the interaction between ORF16 and ORF28.