Harnessing the potential of radiation-induced immune modulation for cancer therapy (original) (raw)
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Oncology (Williston Park, N.Y.), 2008
The combination of radiation therapy and immunotherapy holds particular promise as a strategy for cancer therapeutics. Evidence suggests that immunotherapy is most beneficial alone when employed early in the disease process or in combination with standard therapies (eg, radiation) later in the disease process. Indeed, radiation may act synergistically with immunotherapy to enhance immune responses, inhibit immunosuppression, and/or alter the phenotype of tumor cells, thus rendering them more susceptible to immune-mediated killing. As monotherapies, both immunotherapy and radiation may be insufficient to eliminate tumor masses. However, following immunization with a cancer vaccine, the destruction of even a small percentage of tumor cells by radiation could result in crosspriming and presentation of tumor antigens to the immune system, thereby potentiating antitumor responses. Learning how to exploit radiation-induced changes to tumor-cell antigens, and how to induce effective immune...
Immunologically augmented cancer treatment using modern radiotherapy
Radiation oncology has recently seen tremendous technical advances, resulting in increasing cancer cures. However, malignant neoplasias are systemic diseases and may be lethal even with an excellent tumor local control. Immune therapy has grown to a mature approach in oncology, delivering results impossible only a few years ago. Treatment-limiting mechanisms such as the immune suppressive tumor microenvironment are now to a large extent deciphered, allowing for pharmacological intervention. Interestingly, radiation-based treatment effects have been shown to depend to a large degree on the immune system. Applying the recent advances in radiation therapy in conjunction with immune therapy can be a turning point towards the long-standing aim of curing cancer. Only a detailed understanding of the molecular mechanisms can guide the implementation of combined therapy modalities.
Immunobiology of Radiotherapy: New Paradigms
Radiation Research, 2014
It has been well demonstrated that irradiated dying cancer cells release tumor antigens. The extracellular antigens and dying tumor cells are engulfed by circulating bone marrowderived antigen-presenting cells (APCs). After antigen uptake, APCs migrate to lymph nodes, where they engage with helper T cells for post-stimulation and APC activation. Induction of Th1 response and the activation of APCs further stimulate the induction of tumor specific cytotoxic T lymphocytes (CTLs) that could potentially clear tumor cells both at primary and metastatic sites (Fig. 1). Radiation-induced immune modulation happens in two important phases. First, radiation induces damage-associated molecular pattern (DAMP) molecules. In this event, radiation normalizes tumor vasculature, modulates tumor cell phenotype and increases immune recognition of the tumor cell. Radiation treatment can cause: a. upregulation of chemokines and adhesion molecules, providing signals for T cells to be attracted to the tumor; and b. upregulation of MHC molecules and tumor-associated antigens, making it easier for endogenous or immunotherapy-induced T cells to recognize and kill tumor (immunogenic modulation). Second, amplification by abrogating immune checkpoint factors with simultaneous costimulation of effector factors can ultimately lead to the induction of multiple unique T-cell populations (antigen cascade) that can kill antigen disparate tumor cells at metastatic sites (systemic effect) (Fig. 2). Radiation-Induced Immunomodulation This issue highlights novel findings and concepts on the immunobiology of radiation therapy coupled with translational concepts. Wattenberg et al. (1) reported on several cases where radiation modulates tumor cells to undergo immunogenic cell death or immunogenic modulation and this immune response is directly proportional to radiation dose. Current clinical radiotherapy regimens involve both hypo-and hyperfractionated treatments. Therefore, it is important to understand how immune genes respond to survival adaptation of irradiated tumor cells (during multifractionation as well as after single high-dose fraction) to
Combining radiotherapy and immunotherapy: A revived partnership
International Journal of Radiation Oncology*Biology*Physics, 2005
Ionizing radiation therapy (RT) is an important local modality for the treatment of cancer. The current rationale for its use is based largely on the ability of RT to kill the cancer cells by a direct cytotoxic effect. Nevertheless, considerable evidence indicates that RT effects extend beyond the mere elimination of the more radio-sensitive fraction of cancer cells present within a tumor at the time of radiation exposure. For instance, a large body of evidence is accumulating on the ability of RT to modify the tumor microenvironment and generate inflammation. This may have far reaching consequences on the response of a patient to treatment, especially if radiation-induced tumor cell kill were to translate into the generation of effective anti-tumor immunity. Although much remains to be learned about how radiation can impact tumor immunogenicity, data from pre-clinical studies provide the proof of principle that different immunotherapeutic strategies can be combined with RT to enhance anti-tumor effects. Conversely, RT could reveal a useful tool to combine with immunotherapy.
Communications biology, 2021
A major obstacle to immunotherapy is insufficient infiltration of effector immune cells into the tumor microenvironment. Radiotherapy greatly reduces tumor burden but relapses often occur. Here we show that the immunosuppressive tumor microenvironment was gradually established by recruiting Tregs after radiation. Despite tumors being controlled after depletion of Tregs in the irradiated area, improvement of mice survival remained poor. A much better antitumor effect was achieved with vaccination followed by radiation than other treatments. Vaccination followed by radiation recruited more effector T cells in tumor regions, which responded to high levels of chemokines. Sequential combination of vaccination and radiotherapy could elicit distinct host immune responses. Our study demonstrated that optimal combination of irradiation and vaccination is required to achieve effective antitumor immune responses. We propose a combination regimen that could be easily translated into the clinic and offer an opportunity for rational combination therapies design in cancer treatment.
Immunomodulatory effects of radiation: what is next for cancer therapy?
Future Oncology, 2016
Despite its former reputation as being immunosuppressive, it has become evident that radiation therapy can enhance antitumor immune responses. This quality can be harnessed by utilizing radiation as an adjuvant to cancer immunotherapies. Most studies combine the standard radiation dose and regimens indicated for the given disease state, with novel cancer immunotherapies. It has become apparent that low-dose radiation, as well as doses within the hypofractionated range, can modulate tumor cells making them better targets for immune cell reactivity. Herein, we describe the range of phenotypic changes induced in tumor cells by radiation, and explore the diverse mechanisms of immunogenic modulation reported at these doses. We also review the impact of these doses on the immune cell function of cytotoxic cells in vivo and in vitro.
Radiation effects on antitumor immune responses: current perspectives and challenges
Therapeutic Advances in Medical Oncology, 2018
Radiotherapy (RT) is currently used in more than 50% of cancer patients during the course of their disease in the curative, adjuvant or palliative setting. RT achieves good local control of tumor growth, conferring DNA damage and impacting tumor vasculature and the immune system. Formerly regarded as a merely immunosuppressive treatment, pre- and clinical observations indicate that the therapeutic effect of RT is partially immune mediated. In some instances, RT synergizes with immunotherapy (IT), through different mechanisms promoting an effective antitumor immune response. Cell death induced by RT is thought to be immunogenic and results in modulation of lymphocyte effector function in the tumor microenvironment promoting local control. Moreover, a systemic immune response can be elicited or modulated to exert effects outside the irradiation field (so called abscopal effects). In this review, we discuss the body of evidence related to RT and its immunogenic potential for the future...
Seminars in Radiation Oncology, 2015
Radiation therapy is widely used with curative or palliative intent in the clinical management of multiple cancers. Although mainly aimed at direct tumor cell killing, mounting evidence suggests that radiation can alter the tumor to become an immunostimulatory milieu. Data suggest that the immunogenic effects of radiation can be exploited to promote synergistic antitumor effects in combination with immunotherapeutic agents. Here we review concepts associated with the immunogenic consequences of radiation therapy, and highlight how preclinical findings are translating into clinical benefit for patients receiving combination regimens of radiation therapy and therapeutic cancer vaccines.
Cancer research, 2004
Local radiation is an established therapy for human tumors. Radiation also has been shown to alter the phenotype of target tissue, including gene products that may make tumor cells more susceptible to T-cell-mediated immune attack. We demonstrate a biological synergy between local radiation of tumor and active vaccine therapy. The model used consisted of mice transgenic for human carcinoembryonic antigen (CEA) and a murine carcinoma cell line transfected with CEA. The vaccine regimen consisted of a prime and boost strategy using vaccinia and avipox recombinants expressing CEA and three T-cell costimulatory molecules. One dose of 8-Gy radiation to tumor induced up-regulation of the death receptor Fas in situ for up to 11 days. However, neither radiation at this dose nor vaccine therapy was capable of inhibiting growth of 8-day established tumor. When vaccine therapy and local radiation of tumor were used in combination, dramatic and significant cures were achieved. This was mediated by the engagement of the Fas/Fas ligand pathway because Ag-bearing tumor cells expressing dominant-negative Fas were not susceptible to this combination therapy. Following the combination of vaccine and local radiation, tumors demonstrated a massive infiltration of T cells not seen with either modality alone. Mice cured of tumors demonstrated CD4 ؉ and CD8 ؉ T-cell responses specific for CEA but also revealed the induction of high levels of T-cell responses to two other antigens (gp70 and p53) overexpressed in tumor, indicating the presence of a consequential antigen cascade. Thus, these studies demonstrate a new paradigm for the use of local tumor irradiation in combination with active specific vaccine therapy to elicit durable antitumor responses of established tumors.