AAV capsid CD8+ T-cell epitopes are highly conserved across AAV serotypes.

Adeno-associated virus (AAV) has become one of the most promising vectors in gene transfer in the last 10 years with successful translation to clinical trials in humans and even market approval for a first gene therapy product in Europe. Administration to humans, however, revealed that adaptive immune responses against the vector capsid can present an obstacle to sustained transgene expression due to the activation and expansion of capsid-specific T cells. The limited number of peripheral blood mononuclear cells (PBMCs) obtained from samples within clinical trials allows for little more than monitoring of T-cell responses. We were able to identify immunodominant major histocompatibility complex (MHC) class I epitopes for common human leukocyte antigen (HLA) types by using spleens isolated from subjects undergoing splenectomy for non-malignant indications as a source of large numbers of lymphocytes and restimulating them with single AAV capsid peptides in vitro. Further experiments confirmed that these epitopes are naturally processed and functionally relevant. The design of more effective and less immunogenic AAV vectors, and precise immune monitoring of vector-infused subjects, are facilitated by these findings.

Modulation of CD8+ T cell responses to AAV vectors with IgG-derived MHC class II epitopes.

Immune responses directed against viral capsid proteins constitute a main safety concern in the use of adeno-associated virus (AAV) as gene transfer vectors in humans. Pharmacological immunosuppression has been proposed as a solution to the problem; however, the approach suffers from several potential limitations. Using MHC class II epitopes initially identified within human IgG, named Tregitopes, we showed that it is possible to modulate CD8+ T cell responses to several viral antigens in vitro. We showed that incubation of peripheral blood mononuclear cells with these epitopes triggers proliferation of CD4+CD25+FoxP3+ T cells that suppress killing of target cells loaded with MHC class I antigens in an antigen-specific fashion, through a mechanism that seems to require cell-to-cell contact. Expression of a construct encoding for the AAV capsid structural protein fused to Tregitopes resulted in reduction of CD8+ T cell reactivity against the AAV capsid following immunization with an adenoviral vector expressing capsid. This was accompanied by an increase in frequency of CD4+CD25+FoxP3+ T cells in spleens and lower levels of inflammatory infiltrates in injected tissues. This proof-of-concept study demonstrates modulation of CD8+ T cell reactivity to an antigen using regulatory T cell epitopes is possible.

Overcoming preexisting humoral immunity to AAV using capsid decoys.

Adeno-associated virus (AAV) vectors delivered through the systemic circulation successfully transduce various target tissues in animal models. However, similar attempts in humans have been hampered by the high prevalence of neutralizing antibodies to AAV, which completely block vector transduction. We show in both mouse and nonhuman primate models that addition of empty capsid to the final vector formulation can, in a dose-dependent manner, adsorb these antibodies, even at high titers, thus overcoming their inhibitory effect. To further enhance the safety of the approach, we mutated the receptor binding site of AAV2 to generate an empty capsid mutant that can adsorb antibodies but cannot enter a target cell. Our work suggests that optimizing the ratio of full/empty capsids in the final formulation of vector, based on a patient's anti-AAV titers, will maximize the efficacy of gene transfer after systemic vector delivery.

Enhanced T cell function in a mouse model of human glycosylation.

Clinical evidence for a more active immune response in humans compared with our closest hominid relative, the chimpanzee, includes the progression of HIV infection to AIDS, hepatitis B- and C-related inflammation, autoimmunity, and unwanted harmful immune responses to viral gene transfer vectors. Humans have a unique mutation of the enzyme CMP-N-acetylneuraminic acid hydroxylase (CMAH), causing loss of expression of the sialic acid Neu5Gc. This mutation, occurring 2 million years ago, likely altered the expression and function of ITIM-bearing inhibitory receptors (Siglecs) that bind sialic acids. Previous work showed that human T cells proliferate faster than chimpanzee T cells upon equivalent stimulation. In this article, we report that Cmah(-/-) mouse T cells proliferate faster and have greater expression of activation markers than wild-type mouse T cells. Metabolically reintroducing Neu5Gc diminishes the proliferation and activation of both human and murine Cmah(-/-) T cells. Importantly, Cmah(-/-) mice mount greater T cell responses to an adenovirus encoding an adeno-associated virus capsid transgene. Upon lymphocytic choriomeningitis virus infection, Cmah(-/-) mice make more lymphocytic choriomeningitis virus-specific T cells than WT mice, and these T cells are more polyfunctional. Therefore, a uniquely human glycosylation mutation, modeled in mice, leads to a more proliferative and active T cell population. These findings in a human-like mouse model have implications for understanding the hyperimmune responses that characterize some human diseases.

Safety of AAV factor IX peripheral transvenular gene delivery to muscle in hemophilia B dogs.

Muscle represents an attractive target tissue for adeno-associated virus (AAV) vector-mediated gene transfer for hemophilia B (HB). Experience with direct intramuscular (i.m.) administration of AAV vectors in humans showed that the approach is safe but fails to achieve therapeutic efficacy. Here, we present a careful evaluation of the safety profile (vector, transgene, and administration procedure) of peripheral transvenular administration of AAV-canine factor IX (cFIX) vectors to the muscle of HB dogs. Vector administration resulted in sustained therapeutic levels of cFIX expression. Although all animals developed a robust antibody response to the AAV capsid, no T-cell responses to the capsid antigen were detected by interferon (IFN)-gamma enzyme-linked immunosorbent spot (ELISpot). Interleukin (IL)-10 ELISpot screening of lymphocytes showed reactivity to cFIX-derived peptides, and restimulation of T cells in vitro in the presence of the identified cFIX epitopes resulted in the expansion of CD4(+)FoxP3(+)IL-10(+) T-cells. Vector administration was not associated with systemic inflammation, and vector spread to nontarget tissues was minimal. At the local level, limited levels of cell infiltrates were detected when the vector was administered intravascularly. In summary, this study in a large animal model of HB demonstrates that therapeutic levels of gene transfer can be safely achieved using a novel route of intravascular gene transfer to muscle.

AAV-1-mediated gene transfer to skeletal muscle in humans results in dose-dependent activation of capsid-specific T cells.

In a clinical trial for adeno-associated virus serotype 1 (AAV-1)-mediated gene transfer to muscle for lipoprotein lipase (LPL) deficiency, 1 subject from the high-dose cohort experienced a transient increase in the muscle enzyme creatine phosphokinase (CPK) 4 weeks after gene transfer. Simultaneously, after an initial downward trend consistent with expression of LPL, plasma triglyceride levels returned to baseline. We characterized B- and T-cell responses to the vector and the transgene product in the subjects enrolled in this study. IFN-gamma enzyme-linked immunosorbent spot (ELISpot) and intracellular cytokine staining assays performed on peripheral blood mononuclear cells (PBMCs) from the subject who experienced the CPK elevation showed the activation of capsid-specific CD4(+) and CD8(+) T cells. Four of 8 subjects had detectable T-cell responses to capsid with dose-dependent kinetics of appearance. Subjects with detectable T-cell responses to capsid also had higher anti-AAV-1 IgG3 antibody titer. No subject developed B- or T-cell responses to the LPL transgene product. These findings suggest that T-cell responses directed to the AAV-1 capsid are dose-dependent. Whether they also limit the duration of expression of the transgene at higher doses is unclear, and will require additional analyses at later time points.

Capsid antigen presentation flags human hepatocytes for destruction after transduction by adeno-associated viral vectors.

Adeno-associated virus (AAV) vectors are effective gene delivery vehicles mediating long-lasting transgene expression. Data from a clinical trial of AAV2-mediated hepatic transfer of the Factor IX gene (F9) into hemophilia B subjects suggests that CTL responses against AAV capsid can eliminate transduced hepatocytes and prevent long-term F9 expression. However, the capacity of hepatocytes to present AAV capsid-derived antigens has not been formally demonstrated, nor whether transduction by AAV sensitizes hepatocytes for CTL-mediated destruction. To investigate the fate of capsids after transduction, we engineered a soluble TCR for the detection of capsid-derived peptide:MHC I (pMHC) complexes. TCR multimers exhibited antigen and HLA specificity and possessed high binding affinity for cognate pMHC complexes. With this reagent, capsid pMHC complexes were detectable by confocal microscopy following AAV-mediated transduction of human hepatocytes. Although antigen presentation was modest, it was sufficient to flag transduced cells for CTL-mediated lysis in an in vitro killing assay. Destruction of hepatocytes was inhibited by soluble TCR, demonstrating a possible application for this reagent in blocking undesirable CTL responses. Together, these studies provide a mechanism for the loss of transgene expression and transient elevations in aminotransferases following AAV-mediated hepatic gene transfer in humans and a potential therapeutic intervention to abrogate these limitations imposed by the host T cell response.

Diverse IgG subclass responses to adeno-associated virus infection and vector administration.

Humoral immune responses occur following exposure to Adeno-associated virus (AAV) or AAV vectors. Many studies characterized antibody responses to AAV, but human IgG subclass responses to AAV have not been previously described. In this study, IgG subclass responses were examined in serum samples of normal human subjects exposed to wild-type AAV, subjects injected intramuscularly with AAV vectors and subjects injected intravascularly with AAV vectors. A diversity of IgG subclass responses to AAV capsid were found in different subjects. IgG1 was found to be the dominant response. IgG2, IgG3, and IgG4 responses were also observed in most normal human subjects; IgG2 and IgG3 each represented the major fraction of total anti-AAV capsid IgG in a subset of normal donors. Subjects exposed to AAV vectors showed IgG responses to AAV capsid of all four IgG subclasses. IgG responses to AAV capsid in clinical trial subjects were inversely proportional to the level of pre-existing anti-AAV antibody and independent of the vector dose. The high levels of anti-AAV capsid IgG1 can mask differences in IgG2, IgG3, and IgG4 responses that were observed in this study. Analysis of IgG subclass distribution of anti-AAV capsid antibodies indicates a complex, non-uniform pattern of responses to this viral antigen. J. Med. Virol. 81:65-74, 2009. (c) 2008 Wiley-Liss, Inc.

Modulation of tolerance to the transgene product in a nonhuman primate model of AAV-mediated gene transfer to liver.

Adeno-associated virus (AAV)-mediated gene transfer of factor IX (F.IX) to the liver results in long-term expression of transgene in experimental animals, but only short-term expression in humans. Loss of F.IX expression is likely due to a cytotoxic immune response to the AAV capsid, which results in clearance of transduced hepatocytes. We used a nonhuman primate model to assess the safety of AAV gene transfer coupled with an anti-T-cell regimen designed to block this immune response. Administration of a 3-drug regimen consisting of mycophenolate mofetil (MMF), sirolimus, and the anti-IL-2 receptor antibody daclizumab consistently resulted in formation of inhibitory antibodies to human F.IX following hepatic artery administration of an AAV-hF.IX vector, whereas a 2-drug regimen consisting only of MMF and sirolimus did not. Administration of daclizumab was accompanied by a dramatic drop in the population of CD4(+)CD25(+)FoxP3(+) regulatory T cells (Tregs). We conclude that choice of immunosuppression (IS) regimen can modulate immune responses to the transgene product upon hepatic gene transfer in subjects not fully tolerant; and that induction of transgene tolerance may depend on a population of antigen-specific Tregs.

CD8(+) T-cell responses to adeno-associated virus capsid in humans.

Hepatic adeno-associated virus (AAV)-serotype 2 mediated gene transfer results in transgene product expression that is sustained in experimental animals but not in human subjects. We hypothesize that this is caused by rejection of transduced hepatocytes by AAV capsid-specific memory CD8(+) T cells reactivated by AAV vectors. Here we show that healthy subjects carry AAV capsid-specific CD8(+) T cells and that AAV-mediated gene transfer results in their expansion. No such expansion occurs in mice after AAV-mediated gene transfer. In addition, we show that AAV-2 induced human T cells proliferate upon exposure to alternate AAV serotypes, indicating that other serotypes are unlikely to evade capsid-specific immune responses.

Distinct induction patterns and functions of two closely related interferon-inducible human genes, ISG54 and ISG56.

Human P54 and P56 proteins are tetratricopeptide proteins that are encoded by two closely related genes, ISG54 and ISG56. These genes are induced strongly but transiently when cells are treated with interferons or double-stranded RNA or infected with a variety of viruses. We observed that, although double-stranded RNA or Sendai virus infection induced the two genes with similar kinetics, their induction kinetics in response to interferon-beta were quite different. The induction kinetics by virus infection were also different between two cell lines. Functionally the two proteins were similar. Like P56, P54 bound to the translation initiation factor eIF3 and inhibited translation. However, unlike P56, P54 bound to both the "e" and the "c" subunits of eIF3. Consequently, P54 inhibited two functions of eIF3. Like P56, it inhibited the ability of eIF3 to stabilize the eIF2 x GTP x Met-tRNA(i) ternary complex. But in addition, it also inhibited the formation of the 48 S pre-initiation complex between the 40 S ribosomal subunit and the 20 S complex composed of eIF3, ternary complex, eIF4F, and mRNA. Thus, although similar in structure, the human P54 and P56 proteins are induced differently and function differently.

Identification of mouse AAV capsid-specific CD8+ T cell epitopes.

Adeno-associated virus has been developed for use as a gene transfer vector. To understand the impact of AAV capsid-specific CD8(+) T cells on AAV-mediated gene transfer, we identified CD8(+) T cell epitopes for AAV-2 and AAV-8 capsid in C57BL/6 (H-2(b) MHC haplotype) and BALB/c (H-2(d) MHC haplotype) mice. Mice of both the H-2(b) and the H-2(d) haplotypes recognized epitopes on AAV-2 and AAV-8 capsid. T cells from H-2(b) mice recognized an epitope that was conserved between AAV-2 and AAV-8 capsid. Cross-reactivity of AAV-specific CD8(+) T cells induced by different AAV serotypes may have important implications for gene transfer. Identification of these epitopes will facilitate studies of immune response to AAV capsid in mouse models.

Mouse p56 blocks a distinct function of eukaryotic initiation factor 3 in translation initiation.

Members of the p56 family of mammalian proteins are strongly induced in virus-infected cells and in cells treated with interferons or double-stranded RNA. Previously, we have reported that human p56 inhibits initiation of translation by binding to the "e" subunit of eukaryotic initiation factor 3 (eIF3) and subsequently interfering with the eIF3/eIF2.GTP.Met-tRNAi (ternary complex) interaction. Here we report that mouse p56 also interferes with eIF3 functions and inhibits translation. However, the murine protein binds to the "c" subunit, not the "e" subunit, of eIF3. Consequently, it has only a marginal effect on eIF3.ternary complex interaction. Instead, the major inhibitory effect of mouse p56 is manifested at a different step of translation initiation, namely the binding of eIF4F to the 40 S ribosomal subunit.eIF3.ternary complex. Thus, mouse and human p56 proteins block different functions of eIF3 by binding to its different subunits.

Viral stress-inducible protein p56 inhibits translation by blocking the interaction of eIF3 with the ternary complex eIF2.GTP.Met-tRNAi.

Viral stress-inducible protein p56 is produced in response to viral stress-inducing agents such as double-stranded RNA and interferon, as well as other poorly understood mechanisms of viral infection. It has been shown previously that p56 is able to bind the eukaryotic initiation factor 3e(eIF3e) (p48/Int-6) subunit of the eukaryotic translation initiation factor eIF3 and function as an inhibitor of translation in vitro and in vivo. The exact mechanism by which p56 is able to interfere with protein synthesis is not understood. Based on the known roles of eIF3 in the initiation pathway, we employed assays designed to individually look at specific functions of eIF3 and the effect of p56 on these eIF3-mediated functions. These assays examined the effect of p56 on ribosome dissociation, the eIF3.eIF4F interaction, and enhancement of the ternary complex eIF2.GTP.Met-tRNAi formation. Here we report that p56 is able to inhibit translation initiation specifically at the level of eIF3.ternary complex formation. The effect of p56-mediated inhibition was also examined in two different contexts, cap-mediated and encephalomyocarditis virus internal ribosomal entry site-mediated translation. Whereas cap-dependent initiation was severely inhibited by p56, internal ribosomal entry site-mediated translation appeared to be insensitive to p56.