Key Points
-
Human tumours express a large number of tumour antigens; some are mutated and unique to each tumour, whereas others are differentially expressed or differentially processed in tumours compared with normal cells and are shared among different tumours.
-
Both types of antigens have been used in therapeutic cancer vaccines, with shared tumour antigens having the advantage of broader applicability.
-
More than three decades of preclinical and clinical studies of therapeutic cancer vaccines based on many different antigens and many different formulations have yielded only one cancer vaccine that is approved by the US Food and Drug Administration, Sipuleucel-T.
-
Developments in imaging and other screening methods have made possible the detection of pre-malignant lesions that express many different tumour antigens, which could be used to develop preventive vaccines for the control or elimination of these lesions.
-
Therapeutic cancer vaccines based on viral antigens for the control of viral cancers, such as human papillomavirus for cervical cancer and hepatitis B virus for hepatocellular carcinoma, have not shown effectiveness in advanced disease but have been highly effective at clearing pre-malignant lesions.
-
Vaccines based on nonviral antigens might be similarly more effective against pre-malignant lesions of nonviral cancers, and the few completed or ongoing phase I and II clinical trials of preventive cancer vaccines have already shown clinical efficacy.
Abstract
An important role of the immune system is in the surveillance for abnormal or transformed cells, which is known as cancer immunosurveillance. Through this process, the first changes to normal tissue homeostasis caused by infectious or other inflammatory insults can be detected by the immune system through the recognition of antigenic molecules (including tumour antigens) expressed by abnormal cells. However, as they develop, tumour cells can acquire antigenic and other changes that allow them to escape elimination by the immune system. To bias this process towards elimination, immunosurveillance can be improved by the administration of vaccines based on tumour antigens. Therapeutic cancer vaccines have been extensively tested in patients with advanced cancer but have had little clinical success, which has been attributed to the immunosuppressive tumour microenvironment. Thus, the administration of preventive vaccines at pre-malignant stages of the disease holds promise, as they function before tumour-associated immune suppression is established. Accordingly, immunological and clinical studies are yielding impressive results.
Similar content being viewed by others
Main
Treatment without prevention is simply unsustainable. Bill Gates
In October 2015, as part of a Grand Challenges initiative, Cancer Research UK (CRUK) published a call for proposals to develop vaccines for the prevention of nonviral cancers (see Further information). At the same time, the US National Cancer Institute (NCI) convened a Cancer Prevention Think-Tank with research experts in the areas of immunoprevention, precision prevention and early detection, and surveillance and screening. In February 2016, the American Association for Cancer Research (AACR) held a Cancer Prevention Summit with immunoprevention prominently represented on the agenda (see Further information). Several reports related to these meetings were published, setting the course for increased efforts in cancer prevention1,2,3. Among the priority areas identified were molecular and immunological studies of pre-malignant states, the generation of a precancer genome atlas4 for exploring the concept of precision prevention and the identification of new targets for prevention, including for immunoprevention. Also in early 2016, the Blue Ribbon Panel (see Further information) was appointed by the NCI to highlight priority areas in cancer research and prevention and to provide funding recommendations to the Cancer Moonshot programme. Recommendations from the Cancer Immunology Working Group to the Blue Ribbon Panel included support for basic, translational, computational and clinical research in immunotherapy and immunoprevention of all cancers5. The fiscal year 2019 NCI budget proposal for the first time includes vaccines for cancer prevention as a priority area (see Further information).
This push towards cancer prevention and the inclusion of immunoprevention by some of the most eminent cancer organizations is a welcome change. Cancer prevention research has been an active field of investigation for many years6,7 and has yielded several chemopreventive agents that have been approved by the US Food and Drug Administration (FDA). Nevertheless, cancer prevention research has always taken a back seat to the much larger effort in cancer therapy for the many millions of patients currently living with cancer. Unfortunately, even the most successful cancer therapies, such as the newest immunotherapy approaches with checkpoint inhibitors8 and adoptive transfer of engineered T cells9, are making a relatively small impact on the large numbers of patients with cancer and are having the greatest impact on patients in developed countries.
The rationale to increase research on cancer prevention is supported by not only the need to decrease human suffering subsequent to cancer diagnosis but also economic necessity. In 2010 in the United States, there were 12.8 million patients with cancer, and that number is projected to increase to 18.1 million in 2020. The associated treatment costs are projected to increase from US$124.57 billion in 2010 to $157.77 billion in 2020. With a projected annual increase of 2% in the cost of medical care, the real cost in 2020 may be closer to $173 billion10. There is also a discrepancy in the human and economic burden of cancer between developed and developing countries, as people in developing countries suffer and die in greater numbers without the benefit of effective but expensive cancer therapies and preventive measures, such as clinical surveillance and early detection. The desire to make cancer care a universal human right11,12 supports an increased effort in developing more cost-effective cancer prevention approaches.
One such disease prevention approach is vaccination. It is clear that vaccines against cancer-causing viruses, such as human papillomavirus (HPV) and hepatitis B virus (HBV), are very effective in preventing the initial infection and therefore in markedly reducing the risk of cancers caused by these viruses. However, for the majority of cancers, infectious aetiology is either unknown or nonexistent, so other targets must be evaluated as candidate antigens for preventive vaccines. Because most tumour antigens are derived from self-molecules, generating a strong immune response against them has been considered to be breaking tolerance to self and to carry the risk of autoimmunity. For this reason, most cancer vaccine efforts have focused on developing vaccines to treat advanced cancer, for which the risks inherent in the target antigen choice have been more acceptable. The results have been disappointing in the therapeutic setting and have greatly under-represented the full potential of these vaccines. Nevertheless, we have gained great insight from trying to understand the failures of various cancer vaccine approaches.
In this Review, I discuss the probably enormous but still untested potential of vaccines for cancer prevention instead of cancer therapy and the path to their development. I review how lessons learnt from work on therapeutic cancer vaccines provide a strong basis for developing preventive vaccines, describe the past successes and current efforts in developing vaccines for the prevention of cancers with an infectious origin, propose that pre-malignant lesions should be the first targets for preventive vaccines and review a small but increasing number of clinical efforts to test vaccines for cancer prevention. Examples will be limited to studies in humans.
Therapeutic cancer vaccines
If people are constantly falling off a cliff, you could place ambulances under the cliff or build a fence on the top of the cliff. We are placing all too many ambulances under the cliff. Denis Burkitt
Identifying antigens. In the late 1970s and early 1980s, some researchers considered cancer to be a strictly genetic disease, whereas others considered it to be primarily due to a failure of immunosurveillance. It proved to be both, and this was reflected in the first attempts at active specific immunotherapy of cancer. These initial approaches involved identifying and targeting cancer antigens that resulted from mutations in the newly discovered cancer-causing genes (known as oncogenes; such as those of the RAS family), tumour suppressor genes (such as TP53) and other common mutations (such as gene fusions exemplified by BCR–ABL1). Vaccines based on these mutations showed immunogenicity and antitumour efficacy in mouse models and were promptly moved to clinical testing (Table 1).
Another set of antigens that were expected to elicit strong antitumour responses are the products of oncogenic viruses such as HPV, HBV and Epstein–Barr virus (EBV). Low frequencies of T cells against such antigens could be detected in patients with cancer13,14. Various vaccines were generated to elicit or boost these responses. These vaccines were immunogenic and protective in mouse models, but when they were tested in patients with advanced cervical cancer (HPV vaccines)15, hepatocellular carcinoma (HCC; HBV vaccines)13 and oropharyngeal carcinomas and Hodgkin disease (EBV vaccines)14, they showed little or no clinical efficacy.
By far the largest number of tumour antigens detected by T cells and antibodies from patients with cancer are derived from nonmutated cellular proteins that are differentially expressed between normal and tumour cells. Many of these tumour-associated antigens (TAAs) had been previously characterized as targets of tumour-specific monoclonal antibodies that were generated in mice against human tumours. Some of the well-known examples are carcinoembryonic antigen (CEA; also known as CEACAM5) and other oncofetal antigens, melanocytic antigens, the mucin family of molecules and various tumour-specific carbohydrates. Molecular and biochemical characterization of many TAAs revealed the basis of their tumour-specific expression and triggered the field of therapeutic cancer vaccines16,17,18,19.
The vaccine effort. The period from 1990 to 2010 was characterized by a gold rush of effort to discover more TAAs and combine them with various adjuvants and delivery systems to achieve the greatest possible immunogenicity and hoped-for clinical effectiveness17,20. New developments and new knowledge in immunology and molecular biology were promptly incorporated into vaccine designs16,21 (Fig. 1). The first clinical trials either tested peptide-based vaccines using TAAs such as the epithelial tumour antigen mucin 1 (MUC1)22, melanoma-associated antigen 3 (MAGEA3)23 and the breast cancer antigen human epidermal growth factor receptor 2 (HER2; also known as ERBB2 and NEU)24, or tested vaccines composed of whole tumour cells or cell lysates that contained some of the known TAAs as well as potentially many others not yet identified25. When the importance of dendritic cells (DCs)26 as professional antigen-presenting cells was established, in vitro-generated and fully activated DCs became a delivery vehicle for TAAs, and hundreds of DC-based vaccine trials were carried out in different cancer types27. There were also vaccines developed based on viral28 or bacterial vectors29 or virus-like particles30 that were engineered to express TAAs in addition to 'naked' DNA-based31 or RNA-based vaccines32. Increasing knowledge of the importance of activating antigen-presenting cells through Toll-like receptors (TLRs) led to the development of many TLR ligands that were added to the vaccines as adjuvants to properly activate the immune system. However, despite applying the latest and best immunological knowledge to the design and testing of therapeutic cancer vaccines, the overall impact of vaccines on disease-free survival, overall survival and cancer recurrence has been minimal21.
Several meta-analyses have been carried out on the therapeutic cancer vaccine effort over the past two decades to extract some commonalities characterizing the successes and failures that could inform future directions for vaccine efforts. One study evaluated 451 trials (phases II and III only) carried out in more than 25 different cancer types from 1999 to 2015 (Ref. 33). Of those evaluated, 185 trials tested a vaccine in combination with chemotherapy, radiation, surgery, antibody therapy, hormone therapy or other therapy, and the other 266 trials applied the vaccine alone. Vaccine-only trials were more common in the first decade covered by the meta-analysis, with the combination trials dominating the second decade. Although the number of patients in phase III trials was relatively large compared with those in phase II trials, the number of phase III trials compared with phase II was very small. This indicates that the data from the numerous phase II trials were not strong enough to support further development. As a result, only one therapeutic vaccine, Sipuleucel-T, has been approved to date by the FDA for the treatment of prostate cancer on the basis of a 4.1-month increase in median survival34. Another retrospective cross-sectional and longitudinal study analysed 995 trials carried out between 1991 and 2013 (Ref. 35). In this study, it was noted that the peak number of trials was in 2008 and has declined since. Of the 995 trials, only 40 (4%) were phase III trials, which tested 15 different vaccines and 8 different adjuvants. This again indicated that the other 96% of trials did not show positive data to support progression to phase III trials.
The trials reviewed in these two studies did not have long-term follow-up data; thus, the efficacy of the vaccines may have been underestimated. A recent report reviewed the 12-year survival of patients with nonresectable metastatic melanoma who received a vaccine composed of monocyte-derived DCs matured with tumour necrosis factor (TNF), IL-1β, IL-6 and prostaglandin E2 loaded with four MHC class I-binding and six MHC class II-binding melanoma-derived peptides, which was injected intradermally over a period of 2 years36. An impressive 19% of these patients are still alive, which compares well with the results of treatment of melanoma using checkpoint blockade against cytotoxic T lymphocyte antigen 4 (CTLA4)37.
Most therapeutic vaccine trials included in the retrospective analyses were carried out in an adjuvant setting (using a wide variety of adjuvants) and were mostly composed of single antigens (which were mutated, nonmutated or viral antigens). The authors suggest that the weak or absent therapeutic efficacy was due to suboptimal vaccine design and that more complex vaccines using a wider range of tumour antigens and antigen combinations and viral vectors for their delivery would have given a different outcome. They also credit the vaccine failure to the paucity of good adjuvants. However, there is another way to interpret the data. The fact that a wide variety of antigens, adjuvants and delivery systems all gave the same lacklustre results suggests that the common denominator of vaccine failure was not the antigen, the adjuvant or the delivery vector but rather the advanced disease suppressing the patient's response to the vaccine.
Impact of the tumour microenvironment. In the first decade of therapeutic vaccine development and testing, not much was known about systemic and intratumoural immunosuppression. A few early reports of the compromised function of T cells and natural killer (NK) cells in patients with cancer38,39,40 were not immediately appreciated. Many different mechanisms of immune suppression in cancer have since been identified, including the expansion of myeloid-derived suppressor cells (MDSCs)41, tumour-associated macrophages and other myeloid cells42 and regulatory T cells43 in addition to the perturbation of cytokine networks44, changes in host metabolism45 and the production of amino acid-degrading enzymes and indoleamine 2,3-dioxygenase 1 (IDO1)46,47 (Fig. 2). In addition, a recent report reveals an unexpected suppressive activity of oxygen and potassium in the tumour microenviroment42.
In attempts to overcome immunosuppression, pharmaceutical companies are developing specific reagents, such as IDO1 inhibitors48, and various ways to inhibit MDSCs either by blocking their growth factor receptors49 or by reprogramming their metabolism50. There is accumulating evidence that standard treatments such as chemotherapy and radiation, if used appropriately, might also reverse immunosuppression51,52.
These efforts to inhibit the suppressors and modulate the tumour microenvironment in favour of antitumour immunity underlie the so far unprecedented successes of checkpoint blockade immunotherapy achieved through targeting negative regulators of effector T cell function, such as CTLA4, programmed cell death protein 1 (PD1) and PD1 ligand 1 (PDL1)53. Inhibition of additional inhibitors is considered to be a good way to increase the success of this particular therapy as well as other forms of immunotherapy, including therapeutic vaccines. The extent to which this will be successful is likely to vary greatly. There is strong evidence that T cells can be profoundly affected by the long-term stay in the tumour microenvironment and exhibit an exhausted phenotype that may not be fully reversible54. These exhausted T cells do not respond well to checkpoint inhibitors, and if they do respond, the effect is transient55. They are also unlikely to greatly increase in number in response to a vaccine. Combination therapies in mouse models are showing encouraging results in which vaccines, checkpoint blockade and inhibition of one of the other immunosuppressive mechanisms are not effective when used alone, but a combination of two or three of these therapies results in an antitumour effect56.
Combination approaches. High volumes of new data from immunotherapy trials with checkpoint inhibitors have suggested that including cancer vaccines as part of combination immunotherapy will increase the efficacy of checkpoint inhibitors as well as overall therapeutic efficacy57,58,59. This has brought a renewed enthusiasm for the therapeutic cancer vaccines field.
Many cancer vaccines have already been tested in clinical trials and so could be immediately used in combination with checkpoint inhibitors or other immunomodulators of the tumour microenvironment. However, there is a perception that many elements of therapeutic vaccines should be revisited: the choice and prioritization of tumour antigens to include new mutated neoantigens; antigen-delivery methods to include new oncolytic and other viral vectors, nanoparticles and in vivo DC targeting; vaccine formulations that will target exhausted memory T cells and trial designs to take into account immunological fitness of the patients. Some of this work is planned as an organized international collaboration between academic and industry scientists known as The Human Vaccine Project60. Although new knowledge needs to be incorporated into (not so) old vaccines, there is no need to start with a blank slate. Several vaccines based on shared TAAs that are clearly immunogenic and not subject to self-tolerance, such as the cancer–testis antigen NY-ESO-1 (also known as CTAG1A), telomerase reverse transcriptase (TERT), MUC1 and HER2, or based on viral antigens, such as HPV E6 and E7 proteins, could be immediately tested in combination trials.
One variable not addressed by this plan is the cost of these new improved vaccines. The only FDA-approved vaccine, Sipuleucel-T, costs $90,000 per treatment course. The current plan is to make vaccines more complex, vectored and perhaps even personalized. Even as a monotherapy, these complex vaccines are likely to be costly, and if used in combination therapy, as required for metastatic disease, they will add to the already enormous cost of the other agents. One way to reduce the cost of cancer vaccines and improve their effectiveness is to continue to develop them as monotherapies for individuals without cancer but who are at risk of cancer to boost spontaneous immunosurveillance and to prevent cancer development.
Preventive cancer vaccines
Diseases can rarely be eliminated through early diagnosis or good treatment, but prevention can eliminate disease. Denis Burkitt
Vaccines for prevention of viral cancers. Chronic infection with HBV leads to chronic liver diseases and is a proven cause of HCC. Transmission of infection is both vertical, from mother to baby at birth, and horizontal, from person to person throughout life. Children infected with HBV before the age of 5 have a 25–50% chance of developing chronic liver disease that can lead to HCC, whereas infections later in life carry only a 1–5% chance. An HBV immunization programme was started in Taiwan in 1982 initially targeting infants of infected mothers, then all infants and finally it was given universally. It is one of the great success stories of a preventive vaccine for controlling viral infection as a means of reducing cancer incidence. The latest study looking at the long-term effects of Taiwan's infant HBV immunization programme in preventing liver cancer showed a significant (P < 0.0001) reduction in HCC incidence in vaccinated compared with nonvaccinated birth cohorts61. This study showed for the first time that a preventive cancer vaccine given in infancy provides protection in adulthood. A similar success story comes from a programme in Thailand that implemented universal HBV immunization between 1988 and 1992 (Ref. 62).
Similar immunization strategies, repeated in other countries where HBV is endemic, as well as globally, will in time eliminate chronic liver diseases and HCC if mandatory vaccination remains enforced. A recent modelling study shows that a target of a 90% reduction in new cases and a 65% reduction in mortality can be reached by scaling up the coverage of infant immunization to 90%63. This would prevent an estimated 7.3 million deaths between now and 2030, 1.5 million of which would probably be due to HCC63.
A more recent successful prevention story is that of HPV vaccines for the prevention of cervical and HPV-positive oral cancers. Like HBV, HPV can establish a chronic infection in approximately 20% of infected individuals, putting them at risk of these two cancers. An HPV vaccine was introduced in 2006 that was recommended for females aged 11–26, and since 2011 this vaccine has also been recommended for males aged 11–21. A decade later, and after testing in multiple clinical trials64, HPV prevalence among females aged 14–19 had decreased by 64% and had decreased by 34% in females who were 20–24 years old65. Two currently approved vaccines, Gardasil (Merck) and Cervarix (GlaxoSmithKline), provide effective protection against chronic infection with HPV type 16 or type 18, and, importantly, they also protect against cervical intraepithelial neoplasia, adenocarcinoma in situ and cervical cancer66. Given already established trends, a substantial decrease in incidence and mortality from cervical cancer is projected by 2050 (Ref. 67).
Vaccine-elicited immune responses against E6 and E7 antigens from HPV types 16 and 18 are also remarkable in that they could clear pre-malignant cervical and vulvar lesions68,69. Women with HPV-16-positive grade 3 vulvar lesions were vaccinated with long peptides from E6 and E7 oncoproteins admixed with incomplete Freund's adjuvant. Of the 20 vaccinated patients, 12 had a clinical response with relief of symptoms and 5 had a complete response. At 24 months after vaccination, 15 of 19 vaccinated patients had a clinical response and 9 of 19 had a complete response with clearance of HPV-16. Importantly, the clinical response directly correlated with the vaccine-elicited T cell responses. Another trial using a vaccine composed of 13 E6-derived and E7-derived peptides and the adjuvant Montanide reported similar results70. In total, 43 patients received either the vaccine alone or the vaccine together with the TLR7 agonist imiquimod applied to the injection site. At 12 months, 52% of patients had a clinical response, 8 of whom had complete viral clearance.
In another trial, a completely different vaccine formulation composed of two plasmids encoding HPV-16 E6 and E7 proteins or HPV-18 E6 and E7 proteins was administered by electroporation to women with HPV-16-positive or HPV-18-positive cervical intraepithelial neoplasia (CIN) lesions of grade 2 or 3. Overall, 49.5% of vaccinated women experienced pathological regression of lesions compared with 30.6% of women in the placebo group71. Finally, the most stringent test of the ability of an HPV vaccine to prevent cancer was the Papilloma Trial Against Cancer in Young Adults (PATRICIA), which was carried out with the HPV-16 and HPV-18 vaccine Cervarix72. It included women with CIN grade 3 lesions and cervical adenocarcinoma in situ. The vaccine efficacy against both CIN grade 3 and adenocarcinoma in situ was 100%.
The remarkable results for HPV vaccines and viral antigens that had not shown previous clinical efficacy in invasive disease73,74,75 suggested that vaccines based on nonviral antigens that failed in the therapeutic setting were also likely to succeed in the prevention setting.
Vaccines for prevention of nonviral cancers. The idea of developing vaccines for the prevention of nonviral cancers is not new76,77,78,79,80,81. Work by chemoprevention researchers and pharmaceutical companies over the past 30 years to develop drug compounds for cancer prevention and large phase III trials led to FDA approvals of chemopreventive agents such as tamoxifen, and a question that was frequently raised was why these trials could not be a blueprint for preventive vaccine trials. Ironically, despite a steady and marked accumulation of publications on tumour antigens between the 1950s and the 1990s, there was a general belief that there were no suitable antigens for preventive vaccines for nonviral cancers. It was assumed that immune responses against nonviral antigens, specifically TAAs derived from self-molecules, would cross-react with the respective self-molecules on healthy tissues and cause damaging autoimmunity. Unfortunately, the minority of TAAs that warranted such caution, such as some melanoma antigens that caused vitiligo, received the majority of the attention82. In the meantime, many TAAs expressed on liquid and solid tumours (including melanoma) were being safely incorporated into therapeutic vaccines that caused no autoimmunity either in preclinical models, where safety could be adequately tested, or in clinical trials, where therapeutic effects were not accompanied by any substantial toxic effects. Furthermore, the cancer-reactive antibodies and T cells found in patients with cancer that led to the discovery of many TAAs were increasingly being reported as memory responses in healthy individuals83,84,85,86,87,88, and their presence at diagnosis was associated with better prognosis89,90. These immune responses could be induced either by tumours eliminated before becoming clinical disease or more likely by abnormal expression of self-molecules during nonmalignant events such as viral and bacterial infections or acute or chronic inflammation (Fig. 3). In a case–control study in ovarian cancer, immune responses against the TAA MUC1, which is abnormally expressed by epithelial cells in conditions such as breast mastitis, pelvic surgery and mumps or in individuals who are currently smoking was revealed as a potential protective mechanism91,92. Epidemiological evidence has accumulated to show that such events are associated with a marked reduction in lifetime risk of many different cancers93.
Pre-malignant lesions as initial targets. An important advance in the field of cancer immunoprevention has been the development of increasingly sophisticated clinical imaging tools and other modalities that can diagnose early cancer and even pre-cancer changes. Pre-malignant lesions are beginning to have an important role in all modes of cancer prevention, including immunoprevention94,95,96,97. Current management of pre-malignant lesions is either surgical removal or frequent screening. However, many resected lesions recur after surgery, or those that are untreated can progress to cancer. A vaccine administered at this early stage could boost immunosurveillance to eliminate pre-malignant lesions, prevent their recurrence after surgery or prevent their progression to cancer. This setting has many advantages, including a shorter time of interaction of abnormal cells with the immune system, thus presumably avoiding immune exhaustion, and a less immunosuppressive local microenvironment that allows vaccine-elicited T cells to function at the site of the lesion.
The importance of boosting pre-existing immunosurveillance of pre-malignant lesions with a vaccine, even if the lesion is surgically removed, is illustrated by one of many studies showing that apparently normal tissue adjacent to a lesion is different from normal tissues from healthy controls98. For example, in the colonic mucosa adjacent to unifocal colon polyps, there were marked alterations in gene expression that predicted polyp recurrences98. A strong immune memory response elicited by vaccination would be expected to prevent these polyp recurrences. Many pre-malignant lesions have now been shown to be under immune surveillance, and multiple target antigens have been identified. In patients with monoclonal gammopathy of undetermined significance (MGUS), which is a precursor to multiple myeloma, the presence of pre-existing T cell immunity and antibody responses against the stem cell antigen transcription factor SOX2 independently correlates with a reduced risk of progression to multiple myeloma99. This suggests a benefit from boosting anti-SOX2 immunity in all patients with MGUS by using a preventive vaccine. Patients diagnosed with intraductal papillary mucinous neoplasms (IPMNs), which are precursors to pancreatic cancer, have circulating IgG antibodies against MUC1, which is overexpressed in a hypoglycosylated abnormal form in IPMNs as well as in pancreatic cancer. In addition, the dysplastic regions of the IPMN cysts are heavily infiltrated by CD4+ and CD8+ T cells100, suggesting that both pre-existing humoral and cellular immunity can be boosted by a MUC1-based vaccine. Similarly, oral leukoplakias, which are pre-malignant precursors of oral squamous cell carcinomas, are heavily infiltrated with Langerhans cells and T cells, indicating active immunosurveillance of these lesions101.
Using the pre-malignant setting to improve the effectiveness of cancer vaccines is a good compromise between preventing cancer in completely healthy individuals, for whom vaccines may be most effective but carry a certain degree of risk, and treating patients with advanced cancer, for whom vaccine effectiveness is profoundly diminished. A new focus on understanding the pre-malignant microenvironment has revealed that highly advanced lesions may already exert multiple types of immunosuppression100,102,103,104,105,106 that could affect responses to preventive vaccines. This should motivate further studies in vaccine safety so that vaccines may eventually be given to young and healthy individuals who are at risk of nonviral cancers.
Candidate antigens. To start testing preventive cancer vaccines, it is important to identify nonviral candidate antigens that are abnormally expressed by pre-malignant lesions and cancers and to investigate their immunogenicity107. In addition to SOX2 and MUC1, other TAAs that have been identified on tumours are expressed by pre-malignant lesions. The TAA cyclin B1, which is overexpressed in the cytoplasm of many different tumours including lung cancer, is also abnormally expressed in pre-neoplastic lung lesions in individuals who smoke heavily and who are at high risk of developing lung cancer. These lesions are subject to immune surveillance, as cyclin B1-specific IgG is present in people who smoke heavily87. Cancer–testis antigens, such as MAGEA antigens, NY-ESO-1, G antigen (GAGE), sarcoma antigen 1 (SAGE1), cancer–testis antigen 47A (CT47A), nuclear RNA export factor 2 (NXF2), MAGEC1 and MAGEC2, that are commonly expressed by oesophageal cancer are also expressed to the same degree in its precursor lesions108. One of the best-known breast cancer TAAs, HER2, is overexpressed in ductal carcinoma in situ (DCIS), is a precursor to invasive breast cancer and is a target of T cell surveillance. It was recently shown that T helper 1 cell responses directed against HER2 are lost during tumorigenesis109. These responses are greatly diminished even in stage 1 breast cancer compared with those seen in DCIS109. These observations set the stage for applying HER2 vaccines, which have had limited effectiveness in invasive breast cancer, to this early, pre-malignant stage as preventive vaccines.
In addition to investigating the expression of the known TAAs, other approaches are revealing new candidate antigens. A recent study identified 150 genes in existing microarray data sets that were upregulated more than twofold in colorectal cancer as well as in pre-malignant colonic adenomas compared with normal colon tissue. Silencing of the most upregulated genes — CDH3 (which encodes cadherin 3), CLDN1 (which encodes claudin 1), KRT23 (which encodes keratin 23) and MMP7 (which encodes matrix metalloproteinase 7) — in colon cancer cell lines resulted in cell death. Most importantly, sera from patients with early stage colorectal cancer contained IgG antibodies specific for three of these proteins (cadherin 3, keratin 23 and matrix metalloproteinase 7), identifying these proteins as biologically relevant targets for preventive cancer vaccines110. The antigens mentioned above are shared, nonmutated TAAs (Table 1) and are excellent candidate antigens for preventive vaccines because they are proven targets of spontaneous immune surveillance. They are expressed by a large number of human cancers and would therefore be very broadly applicable. Furthermore, TAAs such as HER2 and MUC1 are essential for cancer progression and therefore cannot be lost by the tumour as a means to escape immune control.
Recent evidence suggests that mutated antigens are more immunogenic than nonmutated TAAs and will elicit higher affinity antibodies and higher numbers of T cells. Although this still needs to be conclusively shown, new personalized therapeutic vaccines are being designed based on sequencing of each patient's tumour to identify potential biologically and immunologically important mutated antigens111. Personalized preventive vaccines would then be possible in the setting of pre-malignant lesions that could be biopsied and sequenced, an approach that is currently highly impractical and resource-demanding. A more practical approach that could yield an off-the-shelf vaccine against mutated antigens would be to use predictable mutations, such as those in the RAS family of oncogenes or the cancer suppressor gene TP53. Mutated oncogenes initially held a lot of promise as highly cancer-specific, immunogenic and broadly applicable cancer vaccine antigens, but therapeutic vaccines based on mutated oncogenes did not perform any better than vaccines based on nonmutated shared antigens112,113. This result might be different in a preventive setting. Mutations in oncogenes and cancer suppressor genes occur very early in the process of tumorigenesis, and many pre-malignant lesions, such as those leading to pancreatic, breast, lung or colon cancers, already harbour KRAS or TP53 mutations that could be targeted with off-the-shelf preventive mutated-antigen vaccines. A set of antigens that falls somewhere between the shared mutated and the unique mutated antigens is found in cancers associated with Lynch syndrome (also known as hereditary nonpolyposis colorectal cancer), which are caused by germline mutations in DNA mismatch repair genes. These tumours induce potent immunosurveillance directed in part against frameshift mutations, some of which give rise to predictable immunogenic frameshift peptides. Carriers of Lynch syndrome mutations would be good candidates for preventive vaccination against frameshift-peptide antigens114.
In 2009, a successful effort was made to prioritize the further development of hundreds of tumour antigens as candidates for therapeutic cancer vaccines115. Many of these antigens are also candidates for preventive vaccines, and new antigens and antigen categories have since been defined. A similar effort to prioritize antigens for preventive vaccines is warranted and could be especially useful in these early steps in the development of preventive vaccines.
In addition to the challenge of selecting the right antigens, there will be challenges in selecting or developing the right adjuvants and the right delivery systems. These issues have been under intense investigation and are the subjects of other reviews116,117,118,119,120,121.
Towards clinical application
These are very early days for the clinical testing of preventive cancer vaccines. Justifiably, the initial trials involve antigens that have been previously characterized in great detail for their immunogenicity and safety in both preclinical and clinical studies as components of therapeutic cancer vaccines. Also justifiably, the chosen setting is the advanced pre-malignant state that immediately precedes stage 1 cancer, such as DCIS. In a clinical trial testing the effect of a HER2-based vaccine in DCIS122, 13 patients were vaccinated before surgery with four weekly injections of their own in vitro-matured and activated DCs loaded with HLA class I-binding and HLA class II-binding HER2-derived peptides. To increase immunogenicity, the vaccine was injected into the regional lymph nodes. All patients developed peptide-specific CD4+ and CD8+ effector T cells as well as complement-binding, tumour-lytic antibodies. At the time of surgery, 7 of 11 patients showed decreased DCIS size; the residual DCIS showed infiltration of T cells and B cells and a marked decrease in HER2 positivity. These encouraging results were replicated or bettered in a second trial in 27 patients with DCIS123. At surgery, 5 of 27 vaccinated patients had no evidence of DCIS and in the 22 patients with the disease, 50% had lost HER2 expression. The vaccine seemed to be more effective in patients who were negative for oestrogen receptor (ER), as it eradicated DCIS in 40% of these patients compared with 5.9% of patients who were positive for ER. There was also considerable immunoediting of the DCIS phenotype. If these obviously effective immune responses are confirmed to be long-lived, women with mutations in BRCA1 or BRCA2 should be the next candidate population for preventive HER2-based vaccines and other new vaccines.
The other well-known TAA that has gone into clinical testing as a preventive cancer vaccine is MUC1. Therapeutic MUC1-based vaccines have been tested in numerous trials around the world124 and were the first vaccines based on a self-molecule to be tested22. A 100-amino-acid-long MUC1 peptide admixed with the TLR3 agonist polyinosinic–polycytidylic acid stabilized with polylysine and carboxymethylcellulose (poly-ICLC) was administered to individuals with a history of pre-malignant villous adenomas, which are immediate precursors of colon cancer103. The goal was to test vaccine safety and immunogenicity in healthy people without cancer but who were at risk of adenoma recurrence and colon cancer. The vaccine was given at weeks 0, 2 and 10, and a booster was given after 1 year. Of the 39 vaccinated individuals, 17 (43.6%) developed high levels of MUC1-specific IgG and long-lasting memory responses with no evidence of any toxic effects involving normal tissues. The absence of an immune response in 56.4% of individuals correlated with increased numbers of circulating MDSCs, indicating that this advanced pre-malignant stage is already establishing an immunosuppressive microenvironment that could promote progression to cancer. The complete safety of the elicited immunity in the vaccine responders suggests that vaccinating individuals diagnosed with earlier-stage polyps would be a better choice. Nevertheless, the safety and immunogenicity of this vaccine in the responders supported the design of an ongoing multicentre, placebo-controlled and blinded efficacy trial125. The MUC1-based vaccine was administered to 110 individuals who had advanced adenomas removed within 6 months to 1 year before vaccination. Of the total, 55 participants were given the MUC1 vaccine at weeks 0, 2 and 10 with a booster given at week 55. The other 55 participants were injected with a placebo. So far, there have been no adverse events beyond reactions at the injection site. The trial is still blinded and has just entered the observation phase. Villous adenomas are expected to recur within 1–3 years after surgical resection in 48% of the participants. This timing allows for clinical trials with a somewhat small number of individuals and a moderately short time to completion. In the case of the MUC1 vaccine efficacy trials, the study should reveal the protective effect of the vaccine within 3–5 years. Because MUC1 is expressed by many tumours and their pre-malignant lesions (Fig. 4), other preventive vaccine trials are currently being considered, including a trial in people who smoke and are therefore at risk of lung cancer that was due to start in November 2017 (Ref. 126).
As this section illustrates, these are early days for preclinical and clinical studies of preventive cancer vaccines in several different settings, from fairly advanced lesions (for example, DCIS) to less advanced pre-malignant lesions (for example, colonic polyps and MGUS) or in individuals with genetic (such as Lynch syndrome), environmental or lifestyle (such as smoking) risks for cancer. Thorough evaluation in appropriate animal models of the immune responses induced in various preventive settings will be required. A preventive vaccine given early in life to an individual who is a carrier for a cancer mutation might elicit lifelong protection, whereas a vaccine given to an older individual who smokes or to a patient with advanced colonic polyps might require yearly boosters to maintain protective immunity. This research will be helped by already ongoing efforts to understand early biomarkers of vaccine effectiveness127.
Concluding remarks
Cancer is the second leading cause of death worldwide, and cancer treatments continue to be a major burden on health-care costs. It is clear that the great heterogeneity of cancer cells and the highly organized tumour microenvironment that can resist many forms of therapy, including immunotherapy, will compromise even the most scientifically sophisticated current attempts at a cure. A profoundly different approach to the cancer problem is needed, and, ironically, it might be an old approach that has resolved major health plagues throughout history — disease prevention through vaccination. For the past three decades, cancer vaccines have been designed for the treatment of late-stage disease rather than for prevention. Now, with better insight into the importance of cancer immunosurveillance during cancer development and the benefits of maintaining strong immunity to slow tumour progression, researchers are starting to turn their attention to vaccines for cancer prevention. It is hoped that vaccines given to individuals with a known genetic risk of cancer or to those showing early stages of tumour development, such as pre-malignant lesions, could strengthen and/or prolong immune surveillance and ensure a cancer-free life.
Publisher's note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Reviewer information
Nature Reviews Immunology thanks Carl Figdor and Cornelis Melief for their contribution to the peer review of this work.
References
Kensler, T. W. et al. Transforming cancer prevention through precision medicine and immune-oncology. Cancer Prev. Res. (Phila) 9, 2–10 (2016).
McCaskill-Stevens, W., Pearson, D. C., Kramer, B. S., Ford, L. G. & Lippman, S. M. Identifying and creating the next generation of community-based cancer prevention studies: summary of a National Cancer Institute think tank. Cancer Prev. Res. (Phila) 10, 99–107 (2017).
Wojtowicz, M. E., Dunn, B. K. & Umar, A. Immunologic approaches to cancer prevention-current status, challenges, and future perspectives. Semin. Oncol. 43, 161–172 (2016).
Spira, A. et al. Precancer atlas to drive precision prevention trials. Cancer Res. 77, 1510–1541 (2017).
Singer, D. S., Jacks, T. & Jaffee, E. A U.S. “cancer moonshot” to accelerate cancer research. Science 353, 1105–1106 (2016).
Maresso, K. C. et al. Molecular cancer prevention: current status and future directions. CA Cancer J. Clin. 65, 345–383 (2015).
Meyskens, F. L. Jr et al. Cancer prevention: obstacles, challenges and the road ahead. J Natl Cancer Inst. 108, djv309 (2016).
Topalian, S. L., Drake, C. G. & Pardoll, D. M. Immune checkpoint blockade: a common denominator approach to cancer therapy. Cancer Cell 27, 450–461 (2015).
Riviere, I. & Sadelain, M. Chimeric antigen receptors: a cell and gene therapy perspective. Mol. Ther. 25, 1117–1124 (2017).
Mariotto, A. B., Yabroff, K. R., Shao, Y., Feuer, E. J. & Brown, M. L. Projections of the cost of cancer care in the United States: 2010–2020. J. Natl Cancer Inst. 103, 117–128 (2011).
Eniu, A. E., Martei, Y. M., Trimble, E. L. & Shulman, L. N. Cancer care and control as a human right: recognizing global oncology as an academic field. Am. Soc. Clin. Oncol. Educ. Book 37, 409–415 (2017).
Ginsburg, O. et al. Changing global policy to deliver safe, equitable, and affordable care for women's cancers. Lancet 389, 871–880 (2017).
Qiu, S. J. et al. Induction of tumor immunity and cytotoxic t lymphocyte responses using dendritic cells transduced by adenoviral vectors encoding HBsAg: comparison to protein immunization. J. Cancer Res. Clin. Oncol. 131, 429–438 (2005).
Sing, A. P. et al. Isolation of Epstein-Barr virus (EBV)-specific cytotoxic T lymphocytes that lyse Reed-Sternberg cells: implications for immune-mediated therapy of EBV+ Hodgkin's disease. Blood 89, 1978–1986 (1997).
van der Burg, S. H. & Melief, C. J. Therapeutic vaccination against human papilloma virus induced malignancies. Curr. Opin. Immunol. 23, 252–257 (2011).
Finn, O. J. Tumor-specific immune responses and opportunities for tumor vaccines. Clin. Immunol. Immunopathol. 71, 260–262 (1994).
Finn, O. J. Tumor-rejection antigens recognized by T lymphocytes. Curr. Opin. Immunol. 5, 701–708 (1993).
Van Pel, A. et al. Genes coding for tumor antigens recognized by cytolytic T lymphocytes. Immunol. Rev. 145, 229–250 (1995).
Henderson, R. A. & Finn, O. J. Human tumor antigens are ready to fly. Adv. Immunol. 62, 217–256 (1996).
Finn, O. J. Human tumor antigens yesterday, today, and tomorrow. Cancer Immunol. Res. 5, 347–354 (2017).
Finn, O. J. Cancer vaccines: between the idea and the reality. Nat. Rev. Immunol. 3, 630–641 (2003).
Goydos, J. S., Elder, E., Whiteside, T. L., Finn, O. J. & Lotze, M. T. A phase I trial of a synthetic mucin peptide vaccine. Induction of specific immune reactivity in patients with adenocarcinoma. J. Surg. Res. 63, 298–304 (1996). This paper reports the results of the first clinical trial of a therapeutic cancer vaccine based on a TAA, the MUC1-derived peptide, showing induction of antigen-specific IgG and delayed-type hypersensitivity in patients with metastatic colon, pancreatic and breast cancers.
Marchand, M. et al. Tumor regressions observed in patients with metastatic melanoma treated with an antigenic peptide encoded by gene MAGE-3 and presented by HLA-A1. Int. J. Cancer 80, 219–230 (1999).
Disis, M. L., Grabstein, K. H., Sleath, P. R. & Cheever, M. A. Generation of immunity to the HER-2/neu oncogenic protein in patients with breast and ovarian cancer using a peptide-based vaccine. Clin. Cancer Res. 5, 1289–1297 (1999).
Coughlin, C. M. & Vonderheide, R. H. Targeting adult and pediatric cancers via cell-based vaccines and the prospect of activated B lymphocytes as a novel modality. Cancer Biol. Ther. 2, 466–470 (2003).
Steinman, R. M., Adams, J. C. & Cohn, Z. A. Identification of a novel cell type in peripheral lymphoid organs of mice. IV. Identification and distribution in mouse spleen. J. Exp. Med. 141, 804–820 (1975).
Palucka, K. & Banchereau, J. Dendritic-cell-based therapeutic cancer vaccines. Immunity 39, 38–48 (2013).
Larocca, C. & Schlom, J. Viral vector-based therapeutic cancer vaccines. Cancer J. 17, 359–371 (2011).
Toussaint, B., Chauchet, X., Wang, Y., Polack, B. & Le Gouellec, A. Live-attenuated bacteria as a cancer vaccine vector. Expert Rev. Vaccines 12, 1139–1154 (2013).
Pejawar-Gaddy, S. et al. Generation of a tumor vaccine candidate based on conjugation of a MUC1 peptide to polyionic papillomavirus virus-like particles. Cancer Immunol. Immunother. 59, 1685–1696 (2010).
Yu, M. & Finn, O. J. DNA vaccines for cancer too. Cancer Immunol. Immunother. 55, 119–130 (2006).
Grunwitz, C. & Kranz, L. M. mRNA cancer vaccines — messages that prevail. Curr. Top. Microbiol. Immunol. 405, 145–164 (2017).
Tan, A. C., Goubier, A. & Kohrt, H. E. A quantitative analysis of therapeutic cancer vaccines in phase 2 or phase 3 trial. J. Immunother. Cancer 3, 48 (2015). This is a comprehensive report on therapeutic vaccine trials carried out between 1999 and 2014 showing the relative use of different vaccine platforms, adjuvants, vaccine formulations and delivery vehicles in phase II and phase III clinical trials.
Kantoff, P. W. et al. Sipuleucel-T immunotherapy for castration-resistant prostate cancer. N. Engl. J. Med. 363, 411–422 (2010).
Lu, L., Yan, H., Shyam-Sundar, V. & Janowitz, T. Cross-sectional and longitudinal analysis of cancer vaccination trials registered on the US Clinical Trials Database demonstrates paucity of immunological trial endpoints and decline in registration since 2008. Drug Des. Devel Ther. 8, 1539–1553 (2014). This study is a detailed analysis of 995 therapeutic cancer vaccine trials listed in the US Clinical Trials Database and assesses the types of vaccine used and the most common cancers treated. It shows a 30% per year decline in such trials since the peak number in 2008, presumably owing to lack of progress and improvement in clinical outcome.
Gross, S. et al. Twelve-year survival and immune correlates in dendritic cell-vaccinated melanoma patients. JCI Insight 2, 91438 (2017). This is a rare long-term follow-up report of a therapeutic cancer vaccine trial showing an increase in long-term survival of patients with melanoma following vaccination that equals that of patients with melanoma treated with anti-CTLA4 therapy.
Hodi, F. S. et al. Improved survival with ipilimumab in patients with metastatic melanoma. N. Engl. J. Med. 363, 711–723 (2010).
Lai, P. et al. Alterations in expression and function of signal-transducing proteins in tumor-associated T and natural killer cells in patients with ovarian carcinoma. Clin. Cancer Res. 2, 161–173 (1996).
Schmielau, J. & Finn, O. J. Activated granulocytes and granulocyte-derived hydrogen peroxide are the underlying mechanism of suppression of t-cell function in advanced cancer patients. Cancer Res. 61, 4756–4760 (2001).
Schmielau, J., Nalesnik, M. A. & Finn, O. J. Suppressed T-cell receptor zeta chain expression and cytokine production in pancreatic cancer patients. Clin. Cancer Res. 7, 933s–939s (2001).
Gabrilovich, D. I. Myeloid-derived suppressor cells. Cancer Immunol. Res. 5, 3–8 (2017).
Gurusamy, D., Clever, D., Eil, R. & Restifo, N. P. Novel “elements” of immune suppression within the tumor microenvironment. Cancer Immunol. Res. 5, 426–433 (2017).
Tanaka, A. & Sakaguchi, S. Regulatory T cells in cancer immunotherapy. Cell Res. 27, 109–118 (2017).
Burkholder, B. et al. Tumor-induced perturbations of cytokines and immune cell networks. Biochim. Biophys. Acta 1845, 182–201 (2014).
Flint, T. R. et al. Tumor-induced IL-6 reprograms host metabolism to suppress anti-tumor immunity. Cell Metab. 24, 672–684 (2016).
Timosenko, E., Hadjinicolaou, A. V. & Cerundolo, V. Modulation of cancer-specific immune responses by amino acid degrading enzymes. Immunotherapy 9, 83–97 (2017).
Mondanelli, G., Ugel, S., Grohmann, U. & Bronte, V. The immune regulation in cancer by the amino acid metabolizing enzymes ARG and IDO. Curr. Opin. Pharmacol. 35, 30–39 (2017).
Markwalder, J. A. et al. Identification and optimization of a novel series of indoleamine 2,3-dioxygenase inhibitors. Bioorg. Med. Chem. Lett. 27, 582–585 (2017).
Holmgaard, R. B., Zamarin, D., Lesokhin, A., Merghoub, T. & Wolchok, J. D. Targeting myeloid-derived suppressor cells with colony stimulating factor-1 receptor blockade can reverse immune resistance to immunotherapy in indoleamine 2,3-dioxygenase-expressing tumors. EBioMedicine 6, 50–58 (2016).
Hossain, F. et al. Inhibition of fatty acid oxidation modulates immunosuppressive functions of myeloid-derived suppressor cells and enhances cancer therapies. Cancer Immunol. Res. 3, 1236–1247 (2015).
Vacchelli, E. et al. Chemotherapy-induced antitumor immunity requires formyl peptide receptor 1. Science 350, 972–978 (2015).
Formenti, S. C. & Demaria, S. Combining radiotherapy and cancer immunotherapy: a paradigm shift. J. Natl Cancer Inst. 105, 256–265 (2013).
Sharma, P. & Allison, J. P. The future of immune checkpoint therapy. Science 348, 56–61 (2015).
Wherry, E. J. & Kurachi, M. Molecular and cellular insights into T cell exhaustion. Nat. Rev. Immunol. 15, 486–499 (2015).
Ghoneim, H. E. et al. De novo epigenetic programs inhibit PD-1 blockade-mediated T cell rejuvenation. Cell 170, 142–157 (2017).
Mahoney, K. M., Rennert, P. D. & Freeman, G. J. Combination cancer immunotherapy and new immunomodulatory targets. Nat. Rev. Drug Discov. 14, 561–584 (2015).
Karaki, S. et al. Is there still room for cancer vaccines at the era of checkpoint inhibitors. Vaccines 4, E37 (2016).
Garg, A. D., Coulie, P. G., Van den Eynde, B. J. & Agostinis, P. Integrating next-generation dendritic cell vaccines into the current cancer immunotherapy landscape. Trends Immunol. 38, 577–593 (2017).
Vreeland, T. J. et al. Gaining ground on a cure through synergy: combining checkpoint inhibitors with cancer vaccines. Expert Rev. Clin. Immunol. 12, 1347–1357 (2016).
Romero, P. et al. The human vaccines project: s roadmap for cancer vaccine development. Sci. Transl Med. 8, 334ps9 (2016).
Chang, M. H. et al. Long-term effects of hepatitis B immunization of infants in preventing liver cancer. Gastroenterology 151, 472–480 (2016).
Posuwan, N. et al. The success of a universal hepatitis B immunization program as part of Thailand's EPI after 22 Years' implementation. PLOS One 11, e0150499 (2016).
Nayagam, S. et al. Requirements for global elimination of hepatitis B: a modelling study. Lancet Infect. Dis. 16, 1399–1408 (2016).
Schiller, J. T., Castellsague, X. & Garland, S. M. A review of clinical trials of human papillomavirus prophylactic vaccines. Vaccine 30 (Suppl. 5), F123–F138 (2012).
Markowitz, L. E. et al. Prevalence of HPV after introduction of the vaccination program in the United States. Pediatrics 137, e20151968 (2016).
Harper, D. M. & DeMars, L. R. HPV vaccines — a review of the first decade. Gynecol. Oncol. 146, 196–204 (2017).
Guo, T., Eisele, D. W. & Fakhry, C. The potential impact of prophylactic human papillomavirus vaccination on oropharyngeal cancer. Cancer 122, 2313–2323 (2016).
Kenter, G. G. et al. Vaccination against HPV-16 oncoproteins for vulvar intraepithelial neoplasia. N. Engl. J. Med. 361, 1838–1847 (2009). This is the first report of clinical efficacy of a preventive HPV vaccine based on E6 and E7 peptides in the setting of pre-malignant vulvar lesions.
Finn, O. J. & Edwards, R. P. Human papillomavirus vaccine for cancer prevention. N. Engl. J. Med. 361, 1899–1901 (2009).
van Poelgeest, M. I. et al. Vaccination against oncoproteins of HPV16 for noninvasive vulvar/vaginal lesions: lesion clearance is related to the strength of the T-Cell response. Clin. Cancer Res. 22, 2342–2350 (2016).
Trimble, C. L. et al. Safety, efficacy, and immunogenicity of VGX-3100, a therapeutic synthetic DNA vaccine targeting human papillomavirus 16 and 18 E6 and E7 proteins for cervical intraepithelial neoplasia 2/3: a randomised, double-blind, placebo-controlled phase 2b trial. Lancet 386, 2078–2088 (2015). This study shows encouraging results from a clinical trial in women with advanced cervical intraepithelial neoplasia grade 2 or 3 showing that an HPV DNA vaccine can elicit immunity that is capable of clearing the lesions.
Lehtinen, M. et al. Overall efficacy of HPV-16/18 AS04-adjuvanted vaccine against grade 3 or greater cervical intraepithelial neoplasia: 4-year end-of-study analysis of the randomised, double-blind PATRICIA trial. Lancet Oncol. 13, 89–99 (2012). This study shows excellent efficacy of a peptide plus adjuvant HPV vaccine against cervical intraepithelial neoplasia grade 3 or higher and adenocarcinoma in situ , illustrating the potential for cervical cancer prevention even after virus infection.
Steller, M. A. et al. Cell-mediated immunological responses in cervical and vaginal cancer patients immunized with a lipidated epitope of human papillomavirus type 16 E7. Clin. Cancer Res. 4, 2103–2109 (1998).
van Driel, W. J. et al. Vaccination with HPV16 peptides of patients with advanced cervical carcinoma: clinical evaluation of a phase I-II trial. Eur. J. Cancer 35, 946–952 (1999).
Ferrara, A. et al. Dendritic cell-based tumor vaccine for cervical cancer II: results of a clinical pilot study in 15 individual patients. J. Cancer Res. Clin. Oncol. 129, 521–530 (2003).
Finn, O. J. & Forni, G. Prophylactic cancer vaccines. Curr. Opin. Immunol. 14, 172–177 (2002).
Finn, O. J. & Beatty, P. L. Cancer immunoprevention. Curr. Opin. Immunol. 39, 52–58 (2016).
Finn, O. J. Vaccines for cancer prevention: a practical and feasible approach to the cancer epidemic. Cancer Immunol. Res. 2, 708–713 (2014).
Finn, O. History of tumour vaccines and novel approaches for preventive cancer vaccines. Dev. Biol. 116, 3–12 (2004).
Lollini, P. L., Cavallo, F., Nanni, P. & Forni, G. Vaccines for tumour prevention. Nat. Rev. Cancer 6, 204–216 (2006).
Gray, A., Raff, A. B., Chiriva-Internati, M., Chen, S. Y. & Kast, W. M. A paradigm shift in therapeutic vaccination of cancer patients: the need to apply therapeutic vaccination strategies in the preventive setting. Immunol. Rev. 222, 316–327 (2008).
Pardoll, D. M. Inducing autoimmune disease to treat cancer. Proc. Natl Acad. Sci. USA 96, 5340–5342 (1999).
Vella, L. A. et al. Healthy individuals have T-cell and antibody responses to the tumor antigen cyclin B1 that when elicited in mice protect from cancer. Proc. Natl Acad. Sci. USA 106, 14010–14015 (2009). This is a rare study of immune memory for TAAs in healthy individuals with no history of cancer.
Romo-Gonzalez, T. et al. The network of antigen-antibody reactions in adult women with breast cancer or benign breast pathology or without breast pathology. PLOS One 10, e0119014 (2015).
Egloff, A. M., Vella, L. A. & Finn, O. J. Cyclin B1 and other cyclins as tumor antigens in immunosurveillance and immunotherapy of cancer. Cancer Res. 66, 6–9 (2006).
Burford, B. et al. Autoantibodies to MUC1 glycopeptides cannot be used as a screening assay for early detection of breast, ovarian, lung or pancreatic cancer. Br. J. Cancer 108, 2045–2055 (2013).
Suzuki, H., Graziano, D. F., McKolanis, J. & Finn, O. J. T cell-dependent antibody responses against aberrantly expressed cyclin B1 protein in patients with cancer and premalignant disease. Clin. Cancer Res. 11, 1521–1526 (2005). This is one of the first reports of immune surveillance of pre-malignant lesions, in this case, pre-malignant lung lesions in heavy smokers.
Lutz, M. et al. Boost and loss of immune responses against tumor-associated antigens in the course of pregnancy as a model for allogeneic immunotherapy. Blood 125, 261–272 (2015).
Blixt, O. et al. Autoantibodies to aberrantly glycosylated MUC1 in early stage breast cancer are associated with a better prognosis. Breast Cancer Res. 13, R25 (2011).
Tabuchi, Y. et al. Protective effect of naturally occurring anti-HER2 autoantibodies on breast cancer. Breast Cancer Res. Treat. 157, 55–63 (2016).
Cramer, D. W. et al. Conditions associated with antibodies against the tumor-associated antigen MUC1 and their relationship to risk for ovarian cancer. Cancer Epidemiol. Biomarkers Prev. 14, 1125–1131 (2005). This study reports epidemiological observations and immunosurveillance data and shows that immunity to a TAA (such as MUC1) can be generated in the absence of cancer and contribute to the reduction of cancer risk.
Cramer, D. W. et al. Mumps and ovarian cancer: modern interpretation of an historic association. Cancer Causes Control 21, 1193–1201 (2010).
Cramer, D. W. & Finn, O. J. Epidemiologic perspective on immune-surveillance in cancer. Curr. Opin. Immunol. 23, 265–271 (2011).
Young, M. R. Redirecting the focus of cancer immunotherapy to premalignant conditions. Cancer Lett. 391, 83–88 (2017).
Hait, W. N. & Lebowitz, P. F. Disease interception: myths, mountains, and mole hills. Cancer Prev. Res. 9, 635–637 (2016).
Finn, O. J. Premalignant lesions as targets for cancer vaccines. J. Exp. Med. 198, 1623–1626 (2003).
Dhodapkar, M. V. Harnessing host immune responses to preneoplasia: promise and challenges. Cancer Immunol. Immunother. 54, 409–413 (2005).
Lian, J., Ma, L., Yang, J. & Xu, L. Aberrant gene expression profile of unaffected colon mucosa from patients with unifocal colon polyp. Med. Sci. Monit. 21, 3935–3940 (2015).
Dhodapkar, M. V. et al. Prospective analysis of antigen-specific immunity, stem-cell antigens, and immune checkpoints in monoclonal gammopathy. Blood 126, 2475–2478 (2015).
Beatty, P. L. et al. Immunobiology and immunosurveillance in patients with intraductal papillary mucinous neoplasms (IPMNs), premalignant precursors of pancreatic adenocarcinomas. Cancer Immunol. Immunother. 65, 771–778 (2016). This study provides evidence that pre-malignant pancreatic IPMNs express tumour antigens and are under immune surveillance, but at the same time, they have begun to establish an immunosuppressive microenvironment.
Ohman, J., Magnusson, B., Telemo, E., Jontell, M. & Hasseus, B. Langerhans cells and T cells sense cell dysplasia in oral leukoplakias and oral squamous cell carcinomas — evidence for immunosurveillance. Scand. J. Immunol. 76, 39–48 (2012).
Chu, N. J., Armstrong, T. D. & Jaffee, E. M. Nonviral oncogenic antigens and the inflammatory signals driving early cancer development as targets for cancer immunoprevention. Clin. Cancer Res. 21, 1549–1557 (2015).
Kimura, T. et al. MUC1 vaccine for individuals with advanced adenoma of the colon: a cancer immunoprevention feasibility study. Cancer Prev. Res. (Phila) 6, 18–26 (2013). This is the first trial of a preventive cancer vaccine based on a TAA administered to individuals with a history of advanced adenomas, which shows immunogenicity and safety.
Thompson, E. et al. The immune microenvironment of breast ductal carcinoma in situ. Mod. Pathol. 29, 249–258 (2016).
Hatam, L. J. et al. Immune suppression in premalignant respiratory papillomas: enriched functional CD4+Foxp3+ regulatory T cells and PD-1/PD-L1/L2 expression. Clin. Cancer Res. 18, 1925–1935 (2012).
Karlsson, J. et al. Comparative study of immune status to infectious agents in elderly patients with multiple myeloma, Waldenstrom's macroglobulinemia, and monoclonal gammopathy of undetermined significance. Clin. Vaccine Immunol. 18, 969–977 (2011).
Marquez, J. P., Stanton, S. E. & Disis, M. L. The antigenic repertoire of premalignant and high-risk lesions. Cancer Prev. Res. 8, 266–270 (2015).
Chen, Y. T., Panarelli, N. C., Piotti, K. C. & Yantiss, R. K. Cancer-testis antigen expression in digestive tract carcinomas: frequent expression in esophageal squamous cell carcinoma and its precursor lesions. Cancer Immunol. Res. 2, 480–486 (2014). This is a study showing that precursor lesions of oesophageal carcinomas express cancer–testis antigens, suggesting that these antigens would be good candidates for preventive vaccines for oesophageal cancer.
Nocera, N. F., Lee, M. C., De La Cruz, L. M., Rosemblit, C. & Czerniecki, B. J. Restoring lost Anti-HER-2 Th1 immunity in breast cancer: a crucial role for Th1 cytokines in therapy and prevention. Front. Pharmacol. 7, 356 (2016).
Broussard, E. K. et al. Identification of putative immunologic targets for colon cancer prevention based on conserved gene upregulation from preinvasive to malignant lesions. Cancer Prev. Res. 6, 666–674 (2013).
Yarchoan, M., Johnson, B. A. 3rd, Lutz, E. R., Laheru, D. A. & Jaffee, E. M. Targeting neoantigens to augment antitumour immunity. Nat. Rev. Cancer 17, 209–222 (2017).
Carbone, D. P. et al. Immunization with mutant p53- and K-ras-derived peptides in cancer patients: immune response and clinical outcome. J. Clin. Oncol. 23, 5099–5107 (2005).
Gjertsen, M. K., Saeterdal, I., Saeboe-Larssen, S. & Gaudernack, G. HLA-A3 restricted mutant ras specific cytotoxic T-lymphocytes induced by vaccination with T-helper epitopes. J. Mol. Med. 81, 43–50 (2003).
von Knebel Doeberitz, M. & Kloor, M. Towards a vaccine to prevent cancer in Lynch syndrome patients. Fam. Cancer 12, 307–312 (2013).
Cheever, M. A. et al. The prioritization of cancer antigens: a national cancer institute pilot project for the acceleration of translational research. Clin. Cancer Res. 15, 5323–5337 (2009).
Morelli, A. B. et al. ISCOMATRIX: a novel adjuvant for use in prophylactic and therapeutic vaccines against infectious diseases. J. Med. Microbiol. 61, 935–943 (2012).
Toporovski, R., Morrow, M. P. & Weiner, D. B. Interferons as potential adjuvants in prophylactic vaccines. Expert Opin. Biol. Ther. 10, 1489–1500 (2010).
Welters, M. J. et al. Vaccination during myeloid cell depletion by cancer chemotherapy fosters robust T cell responses. Sci. Transl Med. 8, 334ra352 (2016).
Mbow, M. L., De Gregorio, E., Valiante, N. M. & Rappuoli, R. New adjuvants for human vaccines. Curr. Opin. Immunol. 22, 411–416 (2010).
Gutjahr, A., Tiraby, G., Perouzel, E., Verrier, B. & Paul, S. Triggering intracellular receptors for vaccine adjuvantation. Trends Immunol. 37, 716 (2016).
Boraschi, D. & Italiani, P. From antigen delivery system to adjuvanticy: the board application of nanoparticles in vaccinology. Vaccines 3, 930–939 (2015).
Czerniecki, B. J. et al. Targeting HER-2/neu in early breast cancer development using dendritic cells with staged interleukin-12 burst secretion. Cancer Res. 67, 1842–1852 (2007).
Sharma, A. et al. HER-2 pulsed dendritic cell vaccine can eliminate HER-2 expression and impact ductal carcinoma in situ. Cancer 118, 4354–4362 (2012). This study reports on a highly effective HER2 vaccine against DCIS that leads to DCIS elimination or to elimination of HER2 expression.
Kimura, T. & Finn, O. J. MUC1 immunotherapy is here to stay. Expert Opin. Biol. Ther. 13, 35–49 (2013).
US National Library of Medicine. ClinicalTrials.gov https://clinicaltrials.gov/ct2/show/NCT02134925 (2017).
US National Library of Medicine. ClinicalTrials.gov https://clinicaltrials.gov/ct2/show/NCT03300817 (2017).
Hagan, T. & Pulendran, B. Will systems biology deliver its promise and contribute to the development of new or improved vaccines? From data to understanding through systems biology. Cold Spring Harb. Perspect. Biol. http://dx.doi.org/10.1101/cshperspect.a028894 (2017).
Prehn, R. T. & Main, J. M. Immunity to methylcholanthrene-induced sarcomas. J. Natl Cancer Inst. 18, 769–778 (1957).
Klein, G., Sjogren, H. O., Klein, E. & Hellstrom, K. E. Demonstration of resistance against methylcholanthrene-induced sarcomas in the primary autochthonous host. Cancer Res. 20, 1561–1572 (1960).
Thomas, L. On immunosurveillance in human cancer. Yale J. Biol. Med. 55, 329–333 (1982).
Burnet, F. M. Immunological surveillance in neoplasia. Transplant Rev. 7, 3–25 (1971).
Old, L. J. & Boyse, E. A. Immunology of experimental tumors. Annu. Rev. Med. 15, 167–186 (1964).
Kohler, G. & Milstein, C. Continuous cultures of fused cells secreting antibody of predefined specificity. Nature 256, 495–497 (1975).
Mier, J. W. & Gallo, R. C. Purification and some characteristics of human T-cell growth factor from phytohemagglutinin-stimulated lymphocyte-conditioned media. Proc. Natl Acad. Sci. USA 77, 6134–6138 (1980).
Lotze, M. T. & Finn, O. J. Recent advances in cellular immunology: implications for immunity to cancer. Immunol. Today 11, 190–193 (1990).
Finn, O. J. & Lotze, M. T. A decade in the life of tumor immunology. Clin. Cancer Res. 7, 759s–760s (2001).
Medzhitov, R., Preston-Hurlburt, P. & Janeway, C. A. Jr. A human homologue of the Drosophila Toll protein signals activation of adaptive immunity. Nature 388, 394–397 (1997).
Bystryn, J. C. Tumor vaccines. Cancer Metastasis Rev. 9, 81–91 (1990).
Linehan, D. C., Goedegebuure, P. S. & Eberlein, T. J. Vaccine therapy for cancer. Ann. Surg. Oncol. 3, 219–228 (1996).
Dunn, G. P., Bruce, A. T., Ikeda, H., Old, L. J. & Schreiber, R. D. Cancer immunoediting: from immunosurveillance to tumor escape. Nat. Immunol. 3, 991–998 (2002).
Acknowledgements
O.J.F. acknowledges support from the US National Institutes of Health, US National Cancer Institute, grant R35CA210039.
Author information
Authors and Affiliations
Corresponding author
Ethics declarations
Competing interests
The author declares no competing financial interests.
Glossary
- Checkpoint inhibitors
-
Antibodies or other drugs that inhibit the function of specific molecules (such as cytotoxic T lymphocyte antigen 4 (CTLA4), programmed cell death protein 1 (PD1) and PD1 ligand 1 (PDL1)) expressed on the surface of immune cells or cancer cells that serve as breaks or that keep immune responses in check at particular time points (checkpoints) in immune cell activation. Blocking the function of these molecules releases the breaks and can lead to tumour destruction.
- Engineered T cells
-
T cells that have been modified ex vivo through gene transfer to assume new functions. For example, T cells can be transduced either with chimeric antigen receptors or with T cell receptors, which endows them with different antigen specificity from that of their endogenous T cell receptors.
- Myeloid-derived suppressor cells
-
(MDSCs). A group of immature myeloid cells (including precursors of macrophages, granulocytes and dendritic cells) that are produced in response to various tumour-derived cytokines. These cells have been shown to induce tumour-associated antigen-specific CD8+ T cell tolerance and to suppress other immune effector cells.
- Tumour-associated macrophages
-
Cells that are an important component of the tumour microenvironment. They differentiate from circulating blood monocytes that have infiltrated tumours. They can have positive or negative effects on tumorigenesis (that is, tumour promotion or immunosurveillance, respectively).
- Exhausted phenotype
-
The condition of functionally impaired antigen-specific T cells, typified by increased surface expression of programmed cell death protein 1 (PD1), which occurs in the context of persistent high antigen load. The defects in effector T cell function include a progressive decrease in their ability to produce cytokines, loss of proliferative capacity and decreased cytotoxicity, and these defects can result in apoptotic cell death.
- Tamoxifen
-
A drug used for the prevention of oestrogen receptor (ER)-positive breast cancer. Tamoxifen is a pro-drug that is metabolized in the liver into active metabolites that have a high affinity for the ER and can compete with endogenous oestrogen.
- Monoclonal gammopathy of undetermined significance
-
(MGUS). A medical condition characterized by the presence of abnormal immunoglobulins and expanded clones of plasma cells that can progress to multiple myeloma, thus requiring periodic surveillance.
- Immunoediting
-
A process by which the immune system of a host may alter the gene expression of an emerging tumour such that the most immunogenic epitopes are removed or edited, thereby facilitating tumour escape from immune recognition.
Rights and permissions
About this article
Cite this article
Finn, O. The dawn of vaccines for cancer prevention. Nat Rev Immunol 18, 183–194 (2018). https://doi.org/10.1038/nri.2017.140
Published:
Issue Date:
DOI: https://doi.org/10.1038/nri.2017.140
This article is cited by
-
Dendritic cells as orchestrators of anticancer immunity and immunotherapy
Nature Reviews Clinical Oncology (2024)
-
The application of plant-exosome-like nanovesicles as improved drug delivery systems for cancer vaccines
Discover Oncology (2024)
-
Harnessing exosomes in theranostic applications: advancements and insights in gastrointestinal cancer research
Discover Oncology (2024)
-
Targeting the epigenome to reinvigorate T cells for cancer immunotherapy
Military Medical Research (2023)
-
Generation of whole tumor cell vaccine for on-demand manipulation of immune responses against cancer under near-infrared laser irradiation
Nature Communications (2023)