Using simple retroviruses as a model system, we have examined three aspects of virus assembly. We have dissected a motif that is important for virus assembly and located at the C-terminal region of murine leukemia virus (MLV) capsid (CA). From data generated in our mutational analyses, we hypothesize that the sequences in this motif form an alpha-helix;maintenance of the helical structure and the phase of the helix are critical to its function. We are performing experiments to further investigate this motif to gain insight into the functional domains of CA in virus assembly. We have performed experiments to determine the domain(s) in Gag that is important for the coassembly of MLV and spleen necrosis virus (SNV) Gag. MLV and SNV are distantly related viruses. Using hybrid viruses, we determined that homologous CA is needed for functional complementation of MLV and SNV Gag. We have also studied the MLV Gag components that are important for early virus replication events. We found that homologous CA and p12 domains are required for efficient virus infection. This study indicated that the mature CA and p12 proteins cooperate during early MLV replication, most likely for the transport of the reverse transcription/preintegration complex. We have also examined the effects of Gag mutations on virion RNA dimer maturation. We examined two Gag mutants: an MLV CA deletion mutation and an HIV-1 PTAP substitution mutant. We found that although most of Gag proteins from these virions were cleaved, virion RNA dimers did not mature. These data suggest that virion RNA dimer maturation requires more than proteolytic cleavage of Gag and is likely to be associated with virion morphological changes. We are now studying functional complementation and coassembly in lentivirus-based systems namely, HIV-1 and HIV-2. Using a genetic complementation assay and an imaging approach, we have demonstrated that HIV-1 and HIV-2 Gag can coassemble;furthermore, these coassembled viruses can be infectious. To our knowledge, this is the first study of its kind to demonstrate that two lentiviruses can have such interactions. We are currently following several leads in this study. We intend to define the extent of heterologous Gag interaction, and determine the advantage of such mixed particles in virus replication. For example, we intend to determine whether mixed particles can better counter drug treatment and adapt to replication of a different host cell via bypassing of the cellular defense proteins. Additionally, we are studying the RNA packaging mechanisms of HIV-1 and other lentiviruses. Retroviruses can interact with each other through complementation. Proteins and RNAs from two different viruses can comingle and interact in doubly infected cells. An estimated one million people are dually infected with HIV-1 and HIV-2, providing the basis for possible interactions between these two viruses in human populations. Using two different systems, we examined whether heterologous Gag proteins can coassemble and complement each others functions. We have demonstrated that Gag protein derived from certain genetically distinct viruses can coassemble into the same particle. Furthermore, mature capsid proteins from HIV-1 and SIVmac can coassemble into a functional core and generate infectious viruses. We have also probed the process of virus maturation and showed that only a small number of defects in HIV-1 Gag processing can block proper maturation resulting in noninfectious viruses. In this project, we will continue our studies on virus assembly and maturation. We will also probe the structure and distribution of viral RNAs in particles. Results from these studies will provide insights into retroviral interactions via complementation and will further our understanding of the process of virus assembly and the functions of Gag proteins in various stages of viral replication. [Corresponds to Hu Project 3 in the April 2007 site visit report of the HIV Drug Resistance Program]
| Comas-Garcia, Mauricio; Kroupa, Tomas; Datta, Siddhartha Ak et al. (2018) Efficient support of virus-like particle assembly by the HIV-1 packaging signal. Elife 7: |
| Liu, Yang; Nikolaitchik, Olga A; Rahman, Sheikh Abdul et al. (2017) HIV-1 Sequence Necessary and Sufficient to Package Non-viral RNAs into HIV-1 Particles. J Mol Biol 429:2542-2555 |
| Dilley, Kari A; Nikolaitchik, Olga A; Galli, Andrea et al. (2017) Interactions between HIV-1 Gag and Viral RNA Genome Enhance Virion Assembly. J Virol 91: |
| Burdick, Ryan C; Delviks-Frankenberry, Krista A; Chen, Jianbo et al. (2017) Dynamics and regulation of nuclear import and nuclear movements of HIV-1 complexes. PLoS Pathog 13:e1006570 |
| Chen, Jianbo; Rahman, Sheikh Abdul; Nikolaitchik, Olga A et al. (2016) HIV-1 RNA genome dimerizes on the plasma membrane in the presence of Gag protein. Proc Natl Acad Sci U S A 113:E201-8 |
| Sardo, Luca; Hatch, Steven C; Chen, Jianbo et al. (2015) Dynamics of HIV-1 RNA Near the Plasma Membrane during Virus Assembly. J Virol 89:10832-40 |
| Kuzembayeva, Malika; Dilley, Kari; Sardo, Luca et al. (2014) Life of psi: how full-length HIV-1 RNAs become packaged genomes in the viral particles. Virology 454-455:362-70 |
| Burdick, Ryan; Smith, Jessica L; Chaipan, Chawaree et al. (2010) P body-associated protein Mov10 inhibits HIV-1 replication at multiple stages. J Virol 84:10241-53 |
| Paprotka, Tobias; Venkatachari, Narasimhan J; Chaipan, Chawaree et al. (2010) Inhibition of xenotropic murine leukemia virus-related virus by APOBEC3 proteins and antiviral drugs. J Virol 84:5719-29 |
| Friew, Yeshitila N; Boyko, Vitaly; Hu, Wei-Shau et al. (2009) Intracellular interactions between APOBEC3G, RNA, and HIV-1 Gag: APOBEC3G multimerization is dependent on its association with RNA. Retrovirology 6:56 |
Showing the most recent 10 out of 12 publications
