Blocking IL-10 signalling at the time of immunization does not increase unwanted side effects in mice

BACKGROUND

Cancer therapeutic vaccine induced cytotoxic T cell (CTL) responses are pivotal for the killing of tumour cells. Blocking interleukin 10 (IL-10) signalling at the time of immunization increases vaccine induced CTL responses and improves prevention of tumour growth in animal models compared to immunization without an IL-10 signalling blockade. Therefore, this immunization strategy may have potential to curtail cancer in a clinical setting. However, IL-10 deficiency leads to autoimmune disease in the gut. Blocking IL-10 at the time of immunization may result in unwanted side effects, especially immune-pathological diseases in the intestine.

METHODS

We investigated whether blocking IL-10 at the time of immunization results in intestinal inflammation responses in a mouse TC-1 tumour model and in a NOD autoimmune disease prone mouse model.

RESULTS

We now show that blocking IL-10 at the time of immunization increases IL-10 production by CD4+ T cells in the spleen and draining lymph nodes, and does not result in blood cell infiltration to the intestines leading to intestinal pathological changes. Moreover, immunization with papillomavirus like particles combined with simultaneously blocking IL-10 signalling does not increase the incidence of autoimmune disease in Non-obese diabetic (NOD) mice.

CONCLUSIONS

Our results indicate that immunization with an IL-10 inhibitor may facilitate the generation of safe, effective therapeutic vaccines against chronic viral infection and cancer.

Manipulating IL-10 signalling blockade for better immunotherapy

Interleukin 10 is a cytokine with the ability to reduce or terminate inflammation. Chronic viral infection, such as infection of chronic hepatitis B, hepatitis C and HIV, has increased levels of interleukin 10 in peripheral blood. Serum IL-10 levels are also high in certain cancers. Blocking IL-10 signalling at the time of immunisation clears chronic viral infection and prevents tumour growth in animal models. We review recent advances in this area, with the emphasis on potential use of this novel strategy to treat chronic viral infection and cancer in human.

Personalized cancer vaccines

IMPORTANCE OF THE FIELD

Personalized medicine has extended to management of cancer and implies prescription of specific therapeutics best suited for an individual patient and the type of tumor. These principles have been applied to cancer vaccines.

AREAS COVERED IN THIS REVIEW

Various cancer vaccines that can be personalized. Tumor-derived vaccines have been used and active immunotherapy based on antigens specific to the tumor. Dendritic cells (DCs) can prime tumor-specific T cell responses and are considered potentially effective vaccines for cancer. DCs may be genetically modified or fused with tumor cells. Adoptive cell therapy is based on autologous antigen-specific T lymphocytes. Personalized peptide vaccination has been combined with chemotherapy. Clinical trials have been conducted. There have been many failures but a selection of those currently in progress is presented.

WHAT THE READER WILL GAIN

An overview of various types of personalized cancer vaccines, their mechanism of action and current status of development. Causes of failure of clinical trials and concepts of an ideal personalized cancer vaccine are presented.

TAKE HOME MESSAGE

A number of approaches are available for personalized cancer vaccines with variable degree of success. There are several challenges and needs for refinement of methods but it remains a promising area of cancer therapy.