The discovery that adeno-associated virus 2 (AAV2) encodes an eighth protein, called assembly-activating protein (AAP), transformed our understanding of wild-type AAV biology. Concurrently, it raised questions about the role of AAP during production of recombinant vectors based on natural or molecularly engineered AAV capsids. Here, we show that AAP is indeed essential for generation of functional recombinant AAV2 vectors in both mammalian and insect cell-based vector production systems. Surprisingly, we observed that AAV2 capsid proteins VP1 to -3 are unstable in the absence of AAP2, likely due to rapid proteasomal degradation. Inhibition of the proteasome led to an increase of intracellular VP1 to -3 but neither triggered assembly of functional capsids nor promoted nuclear localization of the capsid proteins. Together, this underscores the crucial and unique role of AAP in the AAV life cycle, where it rapidly chaperones capsid assembly, thus preventing degradation of free capsid proteins. An expanded analysis comprising nine alternative AAV serotypes (1, 3 to 9, and rh10) showed that vector production always depends on the presence of AAP, with the exceptions of AAV4 and AAV5, which exhibited AAP-independent, albeit low-level, particle assembly. Interestingly, AAPs from all 10 serotypes could cross-complement AAP-depleted helper plasmids during vector production, despite there being distinct intracellular AAP localization patterns. These were most pronounced for AAP4 and AAP5, congruent with their inability to rescue an AAV2/AAP2 knockout. We conclude that AAP is key for assembly of genuine capsids from at least 10 different AAV serotypes, which has implications for vectors derived from wild-type or synthetic AAV capsids.IMPORTANCE Assembly of adeno-associated virus 2 (AAV2) is regulated by the assembly-activating protein (AAP), whose open reading frame overlaps with that of the viral capsid proteins. As the majority of evidence was obtained using virus-like particles composed solely of the major capsid protein VP3, AAP's role in and relevance for assembly of genuine AAV capsids have remained largely unclear. Thus, we established a trans-complementation assay permitting assessment of AAP functionality during production of recombinant vectors based on complete AAV capsids and derived from any serotype. We find that AAP is indeed a critical factor not only for AAV2, but also for generation of vectors derived from nine other AAV serotypes. Moreover, we identify a new role of AAP in maintaining capsid protein stability in mammalian and insect cells. Thereby, our study expands our current understanding
The cell sensitivity of recombinant human alpha interferons (rIFN-alpha) of greater than 95% purity (A,D and the hybrid A/D) and crude nature (B and F) was studied in human (WISH, HeLa, AG1732), bovine (MDBK, BT), monkey (Vero), mouse (L), rabbit (RK-13), and hamster (BHK-21) cells. Based on an activity of 100% in WISH cells, the other cells responded to rIFN-alpha A as follows: AG1732 (90%), HeLa (94%), and MDBK and BT cells (170-190%). Rabbit, mouse, and hamster cells had a relative sensitivity of less than 1%. rIFN-alpha B and F were essentially equivalent to rIFN-alpha A in terms of cell sensitivity, but MDBK and BT cells were about 20 times more sensitive to rIFN-alpha D than were WISH cells and rIFN-alpha D was 1/5 to 1/10 as active on L cells as on WISH cells. The activity of the hybrid IFN A/D on bovine, mouse, and human cells was similar. The inhibitory dose50 (U/ml) of rIFN-alpha A, B, D, and F against virus infections in WISH cells were: vesicular stomatitis virus (1-4), rhinovirus types 1 and 42 (2-18), and herpes simplex virus (HSV) type 2 (45-70). Type 1 HSV, Semliki Forest (SFV) and encephalomyocarditis (EMC) viruses were tested against only rIFN-alpha A and D where SFV and EMC were the most sensitive to both IFNs (ID50-SFV, 0.2 U/ml, EMC, 1.2 U/ml) while 13 U/ml of rIFN-alpha A and D inhibited Type 1 HSV. The various rIFN-alpha s did not exhibit different antiviral spectra in vitro. When tested in mice rIFN-alpha A did not protect against infections with SFV, EMC, HSV, or influenza viruses. rIFN-alpha D and A/D protected mice infected with EMC, SFV, or HSV.
Bioengineering of viral vectors for therapeutic gene delivery is a pivotal strategy to reduce doses, facilitate manufacturing, and improve efficacy and patient safety. Here, we engineered myotropic adeno-associated viral (AAV) vectors via a semirational, combinatorial approach that merges AAV capsid and peptide library screens. We first identified shuffled AAVs with increased specificity in the murine skeletal muscle, diaphragm, and heart, concurrent with liver detargeting. Next, we boosted muscle specificity by displaying a myotropic peptide on the capsid surface. In a mouse model of X-linked myotubular myopathy, the best vectors—AAVMYO2 and AAVMYO3—prolonged survival, corrected growth, restored strength, and ameliorated muscle fiber size and centronucleation. In a mouse model of Duchenne muscular dystrophy, our lead capsid induced robust microdystrophin expression and improved muscle function. Our pipeline is compatible with complementary AAV genome bioengineering strategies, as demonstrated here with two promoters, and could benefit many clinical applications beyond muscle gene therapy.
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