Zuqiang Liu

Tumor Regulatory T Cells Potently Abrogate Antitumor Immunity

Regulatory T cell (Treg) from mice bearing a breast tumor were elevated (tumor Treg). In vitro, whereas tumor Treg ability to inhibit tumor-primed CD4+ T cell activity is comparable to Treg from naive mice (naive Treg), only tumor Treg suppress naive CD8+ T cell activation and DC function. Neither tumor Treg nor naive Treg can suppress antitumor immunity at the effector phase of the immune response induced by adoptively transferred tumor-primed CD4+ T cells. This is consistent with the observation that, in this model, neither tumor Treg nor naive Treg can inhibit effectors in vitro or in vivo. However, tumor Treg abrogate tumor-specific CD8+ T cell responses in tumor-draining lymph nodes and antitumor immunity at the early stage of the immune response induced by adoptively transferred tumor-primed CD4+ T cells. These data indicate that, in this model, tumor Treg potently abrogate tumor-specific CD8+ T cell responses in tumor-draining lymph nodes, thereby suppressing antitumor immunity at the early stage of the immune response induced by adoptively transferred tumor-primed CD4+ T cells.

Knockdown of HMGB1 in Tumor Cells Attenuates Their Ability To Induce Regulatory T Cells and Uncovers Naturally Acquired CD8 T Cell-Dependent Antitumor Immunity

Although high mobility group box 1 (HMGB1) in tumor cells is involved in many aspects of tumor progression, its role in tumor immune suppression remains elusive. Host cell-derived IL-10 suppressed a naturally acquired CD8 T cell-dependent antitumor response. The suppressive activity of tumor-associated Foxp3+CD4+CD25+ regulatory T cells (Treg) was IL-10 dependent. Neutralizing HMGB1 impaired tumor cell-promoted IL-10 production by Treg. Short hairpin RNA-mediated knockdown of HMGB1 (HMGB1 KD) in tumor cells did not affect tumor cell growth but uncovered naturally acquired long-lasting tumor-specific IFN-γ– or TNF-α–producing CD8 T cell responses and attenuated their ability to induce Treg, leading to naturally acquired CD8 T cell- or IFN-γ–dependent tumor rejection. The data suggest that tumor cell-derived HMGB1 may suppress naturally acquired CD8 T cell-dependent antitumor immunity via enhancing Treg to produce IL-10, which is necessary for Treg-mediated immune suppression.

Rational combination of oncolytic vaccinia virus and PD-L1 blockade works synergistically to enhance therapeutic efficacy

Both anti-PD1/PD-L1 therapy and oncolytic virotherapy have demonstrated promise, yet have exhibited efficacy in only a small fraction of cancer patients. Here we hypothesized that an oncolytic poxvirus would attract T cells into the tumour, and induce PD-L1 expression in cancer and immune cells, leading to more susceptible targets for anti-PD-L1 immunotherapy. Our results demonstrate in colon and ovarian cancer models that an oncolytic vaccinia virus attracts effector T cells and induces PD-L1 expression on both cancer and immune cells in the tumour. The dual therapy reduces PD-L1+ cells and facilitates non-redundant tumour infiltration of effector CD8+, CD4+ T cells, with increased IFN-γ, ICOS, granzyme B and perforin expression. Furthermore, the treatment reduces the virus-induced PD-L1+ DC, MDSC, TAM and Treg, as well as co-inhibitory molecules-double-positive, severely exhausted PD-1+CD8+ T cells, leading to reduced tumour burden and improved survival. This combinatorial therapy may be applicable to a much wider population of cancer patients.

Potent Tumor-Specific Protection Ignited by Adoptively Transferred CD4+ T Cells

Administration of anti-CD25 mAb before an aggressive murine breast tumor inoculation provoked effective antitumor immunity. Compared with CD4+ T cells purified from anti-CD25 mAb-pretreated mice that did not reject tumor, CD4+ T cells purified from anti-CD25 mAb-pretreated mice that rejected tumor stimulated by dendritic cells (DCs) produced more IFN-γ and IL-2, and less IL-17 in vitro, and ignited protective antitumor immunity in vivo in an adoptive transfer model. Tumor Ag-loaded DCs activated naive CD8+ T cells in the presence of these CD4+ T cells in vitro. Tumor Ag and adoptively transferred CD4+ T cells were both required for inducing a long-term tumor-specific IFN-γ-producing cellular response and potent protective antitumor activity. Although adoptively transferred CD4+ T cells ignited effective tumor-specific antitumor immunity in wild-type mice, they failed to do so in endogenous NK cell-depleted, Gr-1+ cell-depleted, CD40−/−, CD11c+ DC-depleted, B cell−/−, CD8+ T cell-depleted, or IFN-γ−/− mice. Collectively, the data suggest that adoptively transferred CD4+ T cells orchestrate both endogenous innate and adaptive immunity to generate effective tumor-specific long-term protective antitumor immunity. The data also demonstrate the pivotal role of endogenous DCs in the tumor-specific protection ignited by adoptively transferred CD4+ T cells. Thus, these findings highlight the importance of adoptively transferred CD4+ T cells, as well as host immune components, in generating effective tumor-specific long-term antitumor activity.

CXCL11-Armed oncolytic poxvirus elicits potent antitumor immunity and shows enhanced therapeutic efficacy

ABSTRACT We have armed a tumor-selective oncolytic vaccinia virus (vvDD) with the chemokine (CK) CXCL11, in order to enhance its ability to attract CXCR3+ antitumor CTLs and possibly NK cells to the tumor microenvironment (TME) and improve its therapeutic efficacy. As expected, vvDD-CXCL11 attracted high numbers of tumor-specific T cells to the TME in a murine AB12 mesothelioma model. Intratumoral virus-directed CXCL11 expression enhanced local numbers of CD8+ CTLs and levels of granzyme B, while reducing expression of several suppressive molecules, TGF-β, COX2, and CCL22 in the TME. Unexpectedly, we observed that vvDD-CXCL11, but not parental vvDD, induced a systemic increase in tumor-specific IFNγ-producing CD8+ T cells in the spleen and other lymph organs, indicating the induction of systemic antitumor immunity. This effect was associated with enhanced therapeutic efficacy and a survival benefit in tumor-bearing mice treated with vvDD-CXCL11, mediated by CD8+ T cells and IFNγ, but not CD4+ T cells. These results demonstrate that intratumoral expression of CXCL11, in addition to promoting local trafficking of T cells and to a lesser extent NK cells, has a novel function as a factor eliciting systemic immunity to cancer-associated antigens. Our data provide a rationale for expressing CXCL11 to enhance the therapeutic efficacy of oncolytic viruses (OVs) and cancer vaccines.

Oncolytic Immunotherapy: Conceptual Evolution, Current Strategies, and Future Perspectives

The concept of oncolytic virus (OV)-mediated cancer therapy has been shifted from an operational virotherapy paradigm to an immunotherapy. OVs often induce immunogenic cell death (ICD) of cancer cells, and they may interact directly with immune cells as well to prime antitumor immunity. We and others have developed a number of strategies to further stimulate antitumor immunity and to productively modulate the tumor microenvironment (TME) for potent and sustained antitumor immune cell activity. First, OVs have been engineered or combined with other ICD inducers to promote more effective T cell cross-priming, and in many cases, the breaking of functional immune tolerance. Second, OVs may be armed to express Th1-stimulatory cytokines/chemokines or costimulators to recruit and sustain the potent antitumor immunity into the TME to focus their therapeutic activity within the sites of disease. Third, combinations of OV with immunomodulatory drugs or antibodies that recondition the TME have proven to be highly promising in early studies. Fourth, combinations of OVs with other immunotherapeutic regimens (such as prime-boost cancer vaccines, CAR T cells; armed with bispecific T-cell engagers) have also yielded promising preliminary findings. Finally, OVs have been combined with immune checkpoint blockade, with robust antitumor efficacy being observed in pilot evaluations. Despite some expected hurdles for the rapid translation of OV-based state-of-the-art protocols, we believe that a cohort of these novel approaches will join the repertoire of standard cancer treatment options in the near future.

Therapeutic immunity by adoptive tumor-primed CD4(+) T-cell transfer in combination with in vivo GITR ligation.

Tumor-primed CD4+ T cells from splenocytes of tumor-rejection mice in combination with in vivo glucocorticoid-induced tumor necrosis factor receptor (GITR) ligation (the combination therapy) elicited effective host CD8+ T cell-dependent therapeutic immunity against a murine breast tumor. GITR ligation in vitro enhanced tumor-primed CD4+ T-cell activity and partially abrogated regulatory T cells (Treg) suppressor function. Dendritic cells (DCs) from tumor-draining lymph nodes (TDLNs) of tumor-bearing mice treated by the combination therapy stimulated Ag-specific T cells and produced interleukin (IL)-12 ex vivo. Whereas tumor-primed CD4+ T cells or in vivo GITR ligation alone induced a tumor-specific interferon (IFN)-γ-producing cellular response, the combination therapy enhanced and sustained it. Furthermore, the combination therapy in vivo attenuated Tregs ability to suppress IL-12 production by DCs and IFN-γ production by effectors ex vivo. Importantly, tumor-primed CD4+ CD25- T cells from splenocytes of untreated tumor-bearing mice in combination with in vivo GITR ligation also elicited an effective therapeutic effect in this model. These data suggest that the combination therapy may improve DC function, accentuate tumor-specific T-cell responses, and attenuate Treg suppressor function, thereby eliciting effective therapeutic immunity.Tumor-primed CD4(+) T cells from splenocytes of tumor-rejection mice in combination with in vivo glucocorticoid-induced tumor necrosis factor receptor (GITR) ligation (the combination therapy) elicited effective host CD8(+) T cell-dependent therapeutic immunity against a murine breast tumor. GITR ligation in vitro enhanced tumor-primed CD4(+) T-cell activity and partially abrogated regulatory T cells (Treg) suppressor function. Dendritic cells (DCs) from tumor-draining lymph nodes (TDLNs) of tumor-bearing mice treated by the combination therapy stimulated Ag-specific T cells and produced interleukin (IL)-12 ex vivo. Whereas tumor-primed CD4(+) T cells or in vivo GITR ligation alone induced a tumor-specific interferon (IFN)-gamma-producing cellular response, the combination therapy enhanced and sustained it. Furthermore, the combination therapy in vivo attenuated Tregs ability to suppress IL-12 production by DCs and IFN-gamma production by effectors ex vivo. Importantly, tumor-primed CD4(+) CD25(-) T cells from splenocytes of untreated tumor-bearing mice in combination with in vivo GITR ligation also elicited an effective therapeutic effect in this model. These data suggest that the combination therapy may improve DC function, accentuate tumor-specific T-cell responses, and attenuate Treg suppressor function, thereby eliciting effective therapeutic immunity.

Genetic Vaccines To Potentiate the Effective CD103+ Dendritic Cell–Mediated Cross-Priming of Antitumor Immunity

The development of effective cancer vaccines remains an urgent, but as yet unmet, clinical need. This deficiency is in part due to an incomplete understanding of how to best invoke dendritic cells (DC) that are crucial for the induction of tumor-specific CD8+ T cells capable of mediating durable protective immunity. In this regard, elevated expression of the transcription factor X box–binding protein 1 (XBP1) in DC appears to play a decisive role in promoting the ability of DC to cross-present Ags to CD8+ T cells in the therapeutic setting. Delivery of DNA vaccines encoding XBP1 and tumor Ag to skin DC resulted in increased IFN-α production by plasmacytoid DC (pDC) from skin/tumor draining lymph nodes and the cross-priming of Ag-specific CD8+ T cell responses associated with therapeutic benefit. Antitumor protection was dependent on cross-presenting Batf3+ DC, pDC, and CD8+ T cells. CD103+ DC from the skin/tumor draining lymph nodes of the immunized mice appeared responsible for activation of Ag-specific naive CD8+ T cells, but were dependent on pDC for optimal effectiveness. Similarly, human XBP1 improved the capacity of human blood- and skin-derived DC to activate human T cells. These data support an important intrinsic role for XBP1 in DC for effective cross-priming and orchestration of Batf3+ DC–pDC interactions, thereby enabling effective vaccine induction of protective antitumor immunity.

Dendritic cell-derived interleukin-15 is crucial for therapeutic cancer vaccine potency.

IL-15 supports improved antitumor immunity. How to best incorporate IL-15 into vaccine formulations for superior cancer immunotherapy remains a challenge. DC-derived IL-15 (DCIL-15) notably has the capacity to activate DC, to substitute for CD4+ Th and to potentiate vaccine efficacy making IL-15-based therapies attractive treatment options. We observed in transplantable melanoma, glioma and metastatic breast carcinoma models that DCIL-15-based DNA vaccines in which DC specifically express IL-15 and simultaneously produce tumor Aghsp70 were able to mediate potent therapeutic efficacy that required both host Batf3+ DC and CD8+ T cells. In an inducible BrafV600E/Pten-driven murine melanoma model, DCIL-15 (not rIL-15)-based DNA vaccines elicited durable therapeutic CD8+ T cell-dependent antitumor immunity. DCIL-15 was found to be superior to rIL-15 in “licensing” both mouse and human DC, and for activating CD8+ T cells. Such activation occurred even in the presence of Treg, without a need for CD4+ Th, but was IL-15/IL-15Rα-dependent. A single low-dose of DCIL-15 (not rIL-15)-based DC vaccines induced therapeutic antitumor immunity. CD14+ DC emigrating from human skin explants genetically-immunized by IL-15 and Aghsp70 were more effective than similar DC emigrating from the explants genetically-immunized by Aghsp70 in the presence of rIL-15 in expressing membrane-bound IL-15/IL-15Rα and activating CD8+ T cells. These results support future clinical use of DCIL-15 as a therapeutic agent in battling cancer.

Modulation of chemokines in the tumor microenvironment enhances oncolytic virotherapy for colorectal cancer

An oncolytic poxvirus such as vvDD-CXCL11 can generate potent systemic antitumor immunity as well as targeted oncolysis, yet the antitumor effect is limited probably due to limited homing to and suppressed activity of tumor-specific adaptive immune cells in the tumor microenvironment (TME). We reasoned that a chemokine modulating (CKM) drug cocktail, consisting of IFN-α, poly I:C, and a COX-2 inhibitor, may skew the chemokine (CK) and cytokine profile into a favorable one in the TME, and this pharmaceutical modulation would enhance both the trafficking into and function of antitumor immune cells in the TME, thus increasing therapeutic efficacy of the oncolytic virus. In this study we show for the first time in vivo that the CKM modulates the CK microenvironment but it does not modulate antitumor immunity by itself in a MC38 colon cancer model. Sequential treatment with the virus and then CKM results in the upregulation of Th1-attracting CKs and reduction of Treg-attracting CKs (CCL22 and CXCL12), concurrent with enhanced trafficking of tumor-specific CD8+ T cells and NK cells into the TME, thus resulting in the most significant antitumor activity and long term survival of tumor-bearing mice. This novel combined regimen, with the oncolytic virus (vvDD-CXCL11) inducing direct oncolysis and eliciting potent antitumor immunity, and the CKM inducing a favorable chemokine profile in the TME that promotes the trafficking and function of antitumor Tc1/Th1 and NK cells, may have great utility for oncolytic immunotherapy for cancer.