Cancer Immunotherapy : 2018 Nobel Prize

The Nobel Prize in medicine for 2018 was awarded to Prof James Allison of MD Anderson Cancer Center, USA, and Prof Tasuku Honjo of Kyoto University, Japan, to discover cancer therapy by inhibition of negative immune regulation. Previously in 2014, they both received the first Tang Prize for biopharmaceutical science for their work, Prof Allison won the Lasker prize in 2015, and Prof Honjo won the Kyoto Prize in basic sciences in 2016.

Immunologists have been trying to identify methods to activate the immune system and drive anti-tumor immune response for a long time. Prof Allison and Prof Honjo’s research helped in the development of successful strategies to enable the immune system and made tumor immunology a flourishing area of study. The Milestones in cancer immunotherapy are shown in Fig. 1a. Prof Allison is known for his work on cytotoxic T-lymphocyte-associated protein 4 (CTLA-4), also known as cluster of differentiation 152 (CD152), a receptor expressed mainly on activated lymphocytes. CTLA-4 was first discovered in 1987 as a protein belonging to the immunoglobulin superfamily of proteins [1]. Its structure is strikingly similar to the T-cell activating receptor, CD28. Both CTLA-4 and CD28 bind to the same ligands, CD80 and CD86.

Interestingly, CTLA-4 was initially thought to be a positive regulator of T-cells and to co-operate with CD28 in the activation of T-cells. Prof Allison’s research helped in clearly demonstrating the negative regulatory role of CTLA-4 and the opposing effects of CTLA-4 and CD28 in response to T-cell stimulation [2]. His lab showed that CTLA-4 engagement resulted in inhibition of IL-2 accumulation and cell cycle progression in activated T-cells and further confirmed the inhibitory role of CTLA-4 by illustrating lymphoproliferative and lethal autoimmune phenotype in Ctla-4−/− mice (Fig. 1b). More importantly, his work also demonstrated the potential of blocking CTLA-4 in the treatment of cancer.

Prof Honjo is well-known for the discovery of Programmed cell death protein 1, also known as PD-1 and CD279 (cluster of differentiation 279), and for the elucidation of its functions. PD-1 gene was isolated using subtractive hybridization techniques while working on pathways of programmed cell death [4]. PD-1 is a cell surface receptor belonging to the immunoglobulin superfamily proteins expressed on T cells, B cells, and natural killer (NK) cells. Prof Honjo worked extensively on PD-1 and demonstrated the immune inhibitory role of PD-1. His lab showed that a lack of PD-1 results in a comparatively milder autoimmune phenotype in mice that were dependent on the mice’s genetic background. He also collaborated with researchers across the world and contributed to the identification of ligands for PD-1 and showed the involvement of PD-1 ligands on tumor cells in the escape from immune response [56] (Fig. 1b).

In the past decade, CTLA-4 and PD-1 have been found to be very reliable targets for the modulation of immune response and the treatment of cancer. CTLA-4 and PD-1 blockade were shown to stimulate immune response via T-cell priming, peripheral activation of immune cells, a reinvigoration of exhausted immune cells, and inhibition of immunosuppressor cells such as regulatory T cells (Tregs) (Fig. 1b). Drugs targeting CTLA-4 and PD-1, commonly known as immune checkpoint blockers, dramatically changed the treatment landscape for advanced cancers. Before the approval of anti-CTLA-4 monoclonal antibody, ipilimumab, metastatic melanoma patients had limited treatment options with durable response rates and had a poor prognosis with a 5-year survival rate of less than 20% [7]. Long-term survival rates seen in ipilimumab-treated patients encouraged the development of anti-PD-1 antibodies, nivolumab, and pembrolizumab. Since their approval, immune checkpoint blockers have extended the survival of melanoma patients by years and wiped out all signs of disease in some patients. One among such patients is President Jimmy Carter, who had a remarkable recovery after being diagnosed with Stage IV melanoma that was metastasized to the brain.

Apart from metastatic melanoma, anti-PD-1 antibodies are approved as ‘first-line’ therapy for advanced non-small-cell lung cancer, chronic Hodgkin’s lymphoma, head and neck squamous cell carcinoma, gastric cancer, urothelial cancer, cervical cancer, renal cell carcinoma and hepatocellular carcinoma [8]. They are also broadly approved for any solid tumor with microsatellite instability-high and mismatch repair deficiency. In addition to monotherapy, a combination of CTLA-4 and PD-1 targeting antibodies has also been approved for metastatic melanoma and other types of cancers. Most importantly, the adverse events seen with immune checkpoint blockers are milder and manageable compared to those seen with conventional cancer treatments such as chemotherapy. Adverse events seen with immune checkpoint blockers are also reversed upon cessation of the therapy [9].

The significance of targeting PD-1 and other immune checkpoints for cancer treatment can be seen by the interest of various pharmaceutical and biotech companies worldwide. Almost every pharmaceutical R&D has immunotherapy in its pipeline with at least one immune checkpoint blocker under development. More than 30 monoclonal antibodies targeting PD-1 or its ligand PD-L1 are in advanced stages of development. The success of immune checkpoint blockers also paved the way for other types of immunotherapy, such as chimeric antigen receptor engineered T-cells (CAR-T cells) and neoantigen based cancer vaccines, which were previously considered as ‘high-risk’ projects for drug developers [10]. Three CAR-T cell-based therapies and one oncolytic virus-based therapy are approved for cancer treatment, and multiple new approaches are in clinical trials. Hundreds of new clinical trials have been initiated in the past five years to test new immune checkpoint blockers, new immunotherapeutic strategies, and combinations of approved PD-1 blockers. The success of CTLA-4 and PD-1 blockade for cancer treatment has had a significant impact on the fields of oncology as well as immunology and the Nobel prize for Prof Allison, and Prof Honjo is well deserved. It can be considered as recognition for the entire field of tumor immunology, which made surviving advanced stages of cancer ‘achievable.’

What is Immunotherapy?

What is immunotherapy?

Immunotherapy refers to any treatment that uses the immune system to fight diseases, including cancer. Unlike chemotherapy, which kills cancer cells, immunotherapy acts on the immune system’s cells to help them attack cancer.

What are the types of immunotherapy?

Drugs called checkpoint inhibitors are the most widely used form of immunotherapy for cancer. They block a mechanism that cancer cells use to shut down the immune system. This frees killer T-cells — a critically important part of the immune system — to attack the tumor. Four checkpoint inhibitors have been approved by the Food and Drug Administration and are on the market. They are given intravenously.

Another form of immunotherapy, called cell therapy, involves removing immune cells from the patient, altering them genetically to help them fight cancer, then multiplying them in the laboratory and dripping them, like a transfusion, back into the patient. This type of treatment is manufactured individually for each patient and is still experimental.

Bispecific antibodies are an alternative to cell therapy, one that does not require individualizing treatment for each patient. These antibodies are proteins that can attach to both a cancer cell and a T-cell. That way, bringing them close together so the T-cell can attack cancer. One such drug, called Blincyto, has been approved to treat a rare type of leukemia.

Vaccines, another form of immunotherapy, have had considerably less success than the others. Unlike childhood vaccines aimed at preventing diseases like measles and mumps, cancer vaccines are aimed at treating the disease once the person has it. The idea is to prompt the immune system to attack cancer by presenting it with some piece of cancer.

The only vaccine approved specifically to treat cancer in the United States is Provenge for prostate cancer. Another vaccine, BCG developed to prevent tuberculosis, has long been used to treat bladder cancer. As a weakened TB bacterium, BCG appears to provoke a general immune system reaction that then works against cancer. Researchers hope that other vaccines may yet be made to work by combining them with checkpoint inhibitors.

Which types of cancer are treated with immunotherapy?

Checkpoint inhibitors have been approved to treat advanced melanoma, Hodgkin’s lymphoma, and cancers of the lung, kidney, bladder, and head and neck. The drugs are being tested in many other types of cancer.

So far, cell therapy has been used mostly for blood cancers like leukemia and lymphoma.

Which cancer drugs are checkpoint inhibitors?

The four on the market are Yervoy (ipilimumab) and Opdivo (nivolumab), made by Bristol-Myers Squibb; Keytruda (pembrolizumab), by Merck; and Tecentriq (atezolizumab), by Genentech.

How well does immunotherapy work?

Though immunotherapy has been stunningly successful in some cases, it still works in only a minority of patients. Generally, 20 percent to 40 percent of patients are helped by checkpoint inhibitors — although the rate can be higher among those with melanoma. Some patients with advanced disease have had remissions that have lasted for years. In some cases, combining two checkpoint inhibitors increases the effectiveness. But for some people, the drugs do not work at all, or they help just temporarily.

Cell therapy can produce complete remissions in 25 percent to 90 percent of patients with lymphoma or leukemia, depending on the type of cancer. In some cases, the remissions can last for years, but in others, relapses occur within a year.

Opdivo (Nivolumab ) Cancer Treatment

What is nivolumab?

Nivolumab, commonly known under the trade name OpdivoÒ, is a substance that belongs to the class of anticancer drugs called monoclonal antibodies. It is mainly used for the treatment of patients with advanced melanoma (not resectable or metastatic) in adults, alone or in association with hypilimumab.

It is indicated for the treatment of locally advanced or metastatic non-small cell lung cancer (NSCLC) after previous chemotherapy in adults. OPDIVO is also indicated in monotherapy for the treatment of advanced renal cell carcinoma after previous therapy in adults. OPDIVO is finally used for the treatment of adult patients with recurrent or refractory classical Hodgkin’s lymphoma (cHL) after autologous stem cell transplantation (ASCT) and treatment with brentuximab vedotin.

What is the principle of action

Monoclonal antibodies are synthetic substances, produced in the laboratory, capable of destroying certain types of cancer cells while minimizing damage to healthy cells. Their function is to recognize certain proteins (receptors) present on the surface of certain cancer cells. When the monoclonal antibody detects the presence of the receptor on the surface of the cancer cell, it engages there (like a key that fits into the lock: each key can only fit into one lock).

In this way, it stimulates the body’s immune system to attack the neoplastic cells and may also cause them to self-destruct, or it blocks the receptor by preventing it from binding to a different protein that stimulates the growth of neoplastic cells. As a result, not only are cancer cells no longer able to grow and proliferate, but new blood vessels that feed the tumor cannot be formed. As the supply of oxygen and nutrients is thus lacking, the tumour ‘starves’, and as a result it shrinks or at least stops growing.

CAR-T Cell Therapy : a new treatment to Fight Cancer

The therapy I’m referring to is called CAR T cell therapy.
The medicines authority approved it, the FDA in 2017 and 2018, by the European Medicines Agency EMA.
Lymphomas are neoplasms of the immune system.
The most frequent are so-called non-Hodgkin’s lymphomas, most of which are derived from cells called B cells. These are the cells that, in a normal situation, produce the antibodies that defend us from viruses and bacteria, and that circulate undisturbed in the blood, stopping in the marrow, spleen, and lymph nodes as needed by the body.
Lymph nodes are generally the first to be affected when these cells grow uncontrolled, producing a neoplastic process, and typically, the patient arrives with lymphoma comes to the doctor’s attention because he notices an enlarged lymph node.
The only biopsy can confirm the diagnosis and distinguish between the more than 50 histological types.
The chimeric antigen receptor T cells (CAR T cells) are cells of the immune system (T cells, which defend us from infections.
The cells are taken from the patient’s blood, modified in the laboratory, and then reinserted through a small venous catheter, hoping that they find cancer cells and, by activating and multiplying, destroy them.
This type of immunotherapy will undoubtedly revolutionize the way we treat cancer in the future.
Even if 70-80% of patients respond to the therapy, i.e., the lymph nodes begin to fade, the symptoms to soften, the mood to improve, unfortunately, only 45-50% have a prolonged response that continues for at least one year.

Combating Cancer

The researchers have not yet officially found a solution to cancer because many of them depend on pharmaceutical companies for their good and their livelihood. Many people are not aware that disease does not have a viable solution because pharmaceutical companies tend to focus their research on cancer treatment methods to generate the best possible revenue for their business.
Patients diagnosed with cancer are often prescribed treatment involving surgery, radiotherapy, or chemotherapy. Chemotherapy is expensive, and therefore beneficial for pharmaceutical companies that provide facilities and equipment for this type of treatment. To treat cancer, chemotherapy kills cancer cells through the use of powerful chemicals. Patients are very aware of the many side effects of chemotherapy. Perhaps the best known is hair loss. Another is the general feeling of nausea that therapy induces in patients. Depression is another side effect of chemotherapy application to treat cancer.
When the patient is depressed, the effects of depression affect his body in a negative way. This is called the psychosomatic impact, which has been replicated correctly in psychological studies and real-world experiments. Depression causes worse physical conditions, particularly damage to the immune system. The immune system is responsible for fighting cancer cells. When immunity is compromised, it is only a matter of time before the bad cells take over the functional cells. These are often the circumstances that cause the tumor to return after a so-called remission. To better understand cancer as a disease, it is essential to know what cancer cells are and how these cells behave within the human body. A manager at a 7-Eleven store in Vancouver, Canada, believes that cancer cells exist in virtually every human body. The fact that a person smokes does not necessarily mean that he will get cancer sooner or later. It just means that smoking predisposes them. Theoretically, in addition to smoking, there are other risk factors: type of diet, low water intake, hygiene and beauty products, too sedentary lifestyle. In short, a possible solution would be to keep the immune system healthy so that it can continue to fight cancer cells.
Returning to cancer treatment, Signs of the Times reports that “scientists have found the cure for cancer, but no one takes note.” We say the article published as far back as May 15, 2011. “Researchers at the University of Alberta, in Edmonton, Canada, have found a cure for cancer, but it is ignored by the media. It is a simple technique that uses a straightforward drug. The method uses dichloroacetate, a substance that is currently used to treat metabolic disorders. Therefore, there is no concern for side effects or long-term effects. This drug does not require a patent, so anyone can use it widely, and it is cheap compared to expensive cancer drugs produced by large pharmaceutical companies. The drug is publicly available, and the technique is easy to use because large pharmaceutical companies are not involved? Why aren’t the media interested in this discovery? In short, a cure has already been found, but no one is happy about it. The article continues, “However, finding the treatment does not mean that all cancer research should stop. On the contrary, it is in the interest of science to continue to rigorously pursue studies on the subject. Canadian scientists have tested this dichloroacetate (DCA) on human cells and have found that diseased cells in the lungs, breast, and brain have been killed, leaving only the healthy cells.
In the human body, there is a natural element of the human cell, the mitochondria, which can fight a tumor but need to be triggered to be effective. Scientists have realized that these mitochondria cells have been damaged and, therefore, ineffective against cancer and have ended up focusing on glycolysis, which is less effective and more expensive. Drug manufacturers have focused on the method of glycolysis to combat the disease. This DCA is not based on glycolysis, but on the mitochondria, mitochondria are grafted, which in turn fight cancer cells. The side effect of this is that a process called apoptosis is also reactivated. Pharmaceutical companies do not invest in this research because the DCA method cannot be patented; without a patent, they cannot make money, as they are doing now with their AIDS patent. Since pharmaceutical companies will not develop this product,” the article continues, “other independent laboratories should begin to produce this drug and do further research to confirm all the conclusions of that research. Everything can be done in collaboration with universities, which will be happy to assist in this type of research that can develop an effective drug to treat cancer.
Unfortunately, in the light of this further boycott of simple care systems, it seems clear at this point that the medical industry will never find a cure for cancer. Why is that? Because there is too much money going on in this area. Unfortunately, the so-called “best” existing treatment, the costly and devastating chemotherapy, does not work and can even make the tumor worse. The intent of this article is to raise public awareness and the medical environment about this Canadian study, without detracting from the efforts made by many serious researchers, to verify its effectiveness and undertake a spread of the drug.

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