Conrad Russell Cruz

Latent HIV reservoirs exhibit inherent resistance to elimination by CD8+ T cells

The presence of persistent, latent HIV reservoirs in CD4+ T cells obstructs current efforts to cure infection. The so-called kick-and-kill paradigm proposes to purge these reservoirs by combining latency-reversing agents with immune effectors such as cytotoxic T lymphocytes. Support for this approach is largely based on success in latency models, which do not fully reflect the makeup of latent reservoirs in individuals on long-term antiretroviral therapy (ART). Recent studies have shown that CD8+ T cells have the potential to recognize defective proviruses, which comprise the vast majority of all infected cells, and that the proviral landscape can be shaped over time due to in vivo clonal expansion of infected CD4+ T cells. Here, we have shown that treating CD4+ T cells from ART-treated individuals with combinations of potent latency-reversing agents and autologous CD8+ T cells consistently reduced cell-associated HIV DNA, but failed to deplete replication-competent virus. These CD8+ T cells recognized and potently eliminated CD4+ T cells that were newly infected with autologous reservoir virus, ruling out a role for both immune escape and CD8+ T cell dysfunction. Thus, our results suggest that cells harboring replication-competent HIV possess an inherent resistance to CD8+ T cells that may need to be addressed to cure infection.

Cord blood natural killer cells expressing a dominant negative TGF-β receptor: Implications for adoptive immunotherapy for glioblastoma.

Cord blood (CB) natural killer (NK) cells are promising effector cells for tumor immunotherapy but are currently limited by immune-suppressive cytokines in the tumor microenvironment, such as transforming growth factor (TGF-β). We observed that TGF-β inhibits expression of activating receptors such as NKG2D and DNAM1 and decreases killing activity against glioblastoma tumor cells through inhibition of perforin secretion. To overcome the detrimental effects of TGF-β, we engrafted a dominant negative TGF-β receptor II (DNRII) on CB-derived NK cells by retroviral transduction and evaluated their ability to kill glioblastoma cells in the presence of TGF-β. After manufacture using Good Manufacturing Practice-compliant methodologies and transduction with DNRII, CB-derived DNRII-transduced NK cells expanded to clinically relevant numbers and retained both their killing ability and their secretion of interferon-γ upon activation. More important, these cells maintained both perforin expression and NKG2D/DNMA1 expression in the presence of TGF-β allowing for recognition and killing of glioblastoma tumor cells. Hence, NK cells expressing a DNRII should have a functional advantage over unmodified NK cells in the presence of TGF-β-secreting tumors and may be an important therapeutic approach for patients with cancer.

Gene Modification of Human Natural Killer Cells Using a Retroviral Vector

As part of the innate immune system, natural killer (NK) cells are regarded as promising effector cells for adoptive cell therapy approaches to treat patients with cancer. In some cases, genetic modification of the NK cells may be considered but such manipulation has to be integrated into the expansion method to allow the generation of clinically relevant numbers of gene-modified NK cells. Therefore, an efficient gene transfer procedure is needed.Our group developed a retrovirus-based transduction protocol capable of robust expansion of gene-modified NK cells with a high rate of transgene expression. Actively dividing cells is a prerequisite for efficient gene transfer when using a retroviral vector. In the procedure presented here, strong activation of the NK cells was provided by a combination of IL-15 and the K-562 feeder cells. Beside the interest in developing a simple procedure compliant with good manufacturing practice (GMP) for the production of therapeutic products, this approach also provides a valuable means of generating genetically modified primary NK cells for future preclinical studies.

HIV Receives a "One Two Knockout Punch".

T cell therapies have shown promise against viral infections and malignancies. Moreover, advances in gene-editing technology hold the promise that T cell potency can be enhanced by gene modification, deletion, or addition.1 In this issue of Molecular Therapy, Hale et al.,2 in a single construct, combine CCR5 knockdown with a chimeric antigen receptor targeting the HIV envelope, a combination strategy that can potentially provide both anti-HIV activity independent of major histocompatibility complex (MHC) expression and protection of gene-modified T cells from HIV infection.

763. HIV-Specific T Cells Can Be Expanded from Virus-Naive Donors to Target a Range of Viral Epitopes: Implications for a Cure Strategy After Allogeneic HSCT

Background: Adoptive T cell therapy has been successful in boosting viral-specific immunity post-hematopoietic stem cell transplant (HSCT), preventing viral rebound of CMV and EBV. However, the therapeutic use of T cells to boost HIV-specific T cell immunity in HIV+ patients has been met with limited success. Despite multiple attempts to eradicate HIV infection with allogeneic HSCT, the Berlin patient remains the only case of functional HIV cure. Previous infusions of HIV-specific T cells have resulted in immune escape from single epitope specificity and limited persistence of the T cell product. Our approach to address these limitations is to expand HIV-specific T cells derived from virus-naive donors including umbilical cord blood, employing a non-HLA restricted approach for HIV+ patients receiving allogeneic HSCT for HIV-associated hematologic malignancies. Design: We have developed a robust, reproducible platform that can expand HIV-specific T cells (HXTCs) from the naive pool in the allogeneic setting. Peripheral blood mononuclear cells isolated from virus-naive donors are used to generate dendritic cells and T cells. T cells are stimulated with antigen presenting cells pulsed with HIV-pepmix and a combination of cytokines that promote proliferation and differentiation. T cells were tested for: (1) specificity against HIV antigens and individual peptides, (2) pro-inflammatory cytokine secretion in response to stimulation with HIV peptides, and (3) ability to suppress HIV replication in vitro. Results: We successfully expanded (75.705 mean fold expansion) HXTCs recognizing HIV antigens from virus naive donors. IFNg ELISPOT showed HXTCs (n=8) were specific against Gag (mean=331.25 SFC/1e5 cells) and Nef (mean=242.63 SFC/1e5 cells) vs Irrelevant (mean=13 SFC/1e5 cells). HXTCs produced significantly pro-inflammatory responses (p less than 0.05) to stimulation by gag/nef, as determined by levels of TNF-alpha, IL-2, IL-6, IL-8, and perforin (n=3). Importantly, HXTCs (n=4) were able to suppress HIV replication more than non-specific CD8+ T cells when co-cultured with autologous CD4+ T cells infected with HIV SF162 (HXTC 78.62% viral suppression compared to CD8+ T cell 34.19% viral suppression). HXTCs showed both HLA Class I or II specificity for individual HIV epitopes, as determined by HLA blocking and IFNg ELISPOT. Conclusion: This is the first report demonstrating generation of functional, multi-HIV antigen specific T-cells from HIV-negative donors, which has implications for using allogeneic HSCT as a functional HIV cure. The low frequency of circulating HXTCs post-infusion suggests these HXTCs could have a significant effect on preventing viral rebound. The generation of HXTCs from cord blood could provide a further advantage to increase the donor pool.