This page lists some of the achievements of our Principal, Professor Angus Dalgleish and his team, both before and during the existence of the Cancer Vaccine Institute. Tumour cell vaccines (vaccines made from a patient's tumour OR tumour cells grown in culture). Gus was involved in some of the very early work (circa 1996) on tumour cell vaccines, and specifically how vaccines could be made from cells that were not from the patient's own tumour (these are referred to as "allo" vaccines). This interest has been key to much of Gus's work and continues almost to the present day. In addition to pre-clinical work, Gus has been involved in clinical studies, specifically the Onyvax prostate cancer vaccine and earlier the Canvaxin studies for melanoma. These early trials were very encouraging. At first, however, these were not born out in later studies, an event that ultimately hampered the development of those vaccines. It is clear now that poor results in late stage trials were down to a variety of problems. However, an understanding is now emerging from these trials which indicates that the vaccines are still useful. Dendritic cell vaccines (cells which are involved in the body's immune system to fight and protect from infections and disease) Dendritic cell (DC) vaccines are among the best therapeutic vaccines that have been developed. Gus has been interested in these vaccines and has been influential in bringing them into mainstream vaccine research. Despite this DC vaccines remain expensive (they are made bespoke for each patient) and there are arguments about the best formulation of vaccine. For this reason more research has been required to develop them further. We are now looking at ways of manipulating patients' immune systems so that a much cheaper non-bespoke vaccine can be administered. The CVI funded the development of two laboratories which allowed Gus to do DC vaccine trials; a clean-room which was used for some of the early trials and more recently the Helen Feather Laboratory which allowed him to do a DC trial in melanoma patients. This phase I trial took several years and treated about 30 patients. Results from the trial (yet to be published) have supported a possible link between inflammation and vaccination (see below).Aldara. Aldara was originally licensed for use as a wart cream, however, it was discovered that it can be effective in treating melanoma. Gus has maintained an interest in this and other drugs that stimulate the immune system through receptors called TLRs. These receptors are important in boosting immune responses and particularly in stimulating dendritic cells The CVI part-funded a clinical trial of the drug Aldara in patients with metastatic melanoma, which resulted in two scientific papers that have had an impact on
melanoma treatment. The first paper demonstrates how skin lesions respond to treatment with topically applied Aldara and cell stimulator injection. The second paper shows how treatment with Aldara alters systemic immune responses. This is one example of how it may be possible to induce the immune system to kill tumours without making complicated, expensive vaccines. The use of Aldara alongside a cell stimulating injection is now routinely prescribed by oncologists across the UK. Mycobacterial vaccines (vaccines which are prepared from a strain of bacteria) Bacterial infections have been associated with remission in some cancers. Gus has been involved in quite a few studies of vaccines based on the use of bacteria, particularly strains of mycobacteria (BCG, vaccae and more recently obuense). Gus's team did some of the original work demonstrating proof of principal that mycobacterium vaccae could be used to treat prostate cancer. A series of clinical trials in prostate cancer, melanoma, renal and lung cancer followed. Some of these trials demonstrated improved survival benefit. Late stage trials showed that patients receiving 4 or more injections of vaccine did better than those with less than 4. More recently a new mycobacterial strain has been developed by Immodulon Therapeutics. Gus has been involved clinically in recruiting and treating patients with this new vaccine. A phase I study in melanoma demonstrated the safety of the product and showed some positive clinical results. A multi-centre, phase II study for pancreatic cancer is underway. It is hoped that the vaccine will be available for future CVI funded projects. Inflammation and Cancer Gus has been publishing reviews on the links between inflammation and cancer for at least a decade. The early reviews were more specifically about the link between chronic inflammation as a causative factor in cancer. However, he has been a strong protagonist for the concept that some kinds of inflammation are bad in a cancer vaccine setting. He has suggested that anti-inflammatory drugs (such as aspirin) might enhance responses to therapeutic vaccines. This concept now has some support in the literature and has been reported widely in the media. Combination therapies (where different drugs are used in combination)
There are a range of drugs that Gus is interested in which may alter the immune response or which sensitise tumour cells to killing. A. IMiDs (variants on the drug thalidomide) Gus has worked extensively with Celgene Corporation, which manufactures IMiDs, to understand how these drugs work. He has 14 primary papers demonstrating that these drugs alter tumour vascularisation, boost some elements of the immune response and inhibit some cells which suppress immune responses. Gus's work in this area has been very important on the road to licensing for the drug Lenalidomide which is now used in myeloma and is being
trialled in other haematological malignancies. There is strong interest in combining lenalidomide with vaccines. B. Artemesinins (drugs currently used to treat malaria) A recent interest has been in this family of drugs. Currently one particular drug, artesunate is used in a clinical trial of colorectal cancer. Collaboration with our surgical colleagues led to a short project which aimed at determining the mechanism of action of artesunate and some of the other artemesinins. This work was funded by the CVI and was published recently. C. Gemcitabine (a chemotherapy drug) The CVI recently funded Gus in a project which showed how Gemcitabine alters tumour cells in a way that makes them more recognisable to the immune response. This work is ongoing and further valuable observations are being generated. In addition chemotherapy seems to induce tumours to secrete substances that would prevent further blood supply being delivered to tumours and which activate elements of the immune response. This work supports the idea that chemotherapy may be used to stimulate and maintain immune responses alongside therapeutic vaccines. D. Low Dose Naltrexone (LDN) (a drug which has been used to treat narcotic addiction) This is another drug for which new uses are becoming apparent. In particular there is some new evidence that Naltrexone targets some receptors seen predominantly on immune cells. This work is ongoing and will take the form of a PhD project funded by the CVI. In addition Gus is very interested in using LDN in patients with ovarian cancer. Several reports exist, including preclinical studies and case studies, to suggest that LDN may be useful in this application. The work that the CVI is currently funding is likely to provide an explanation, in part, for how this drug works in cancer. E. Zometa (a drug which is used for patients with bone cancer). Gus has been using Zometa with some patients who have solid tumours. There is evidence that Zometa can stimulate elements of the immune response and in particular may work well in combination with mycobacterial vaccines (see above).
GENERALITES Le dépérissement du manguier est une maladie observée au Niger depuis le début des années "80" par une équipe de la direction de la protection des végétaux conduite par l’allemand Rekhauss. En 1992, un chercheur français, Lenor-man, en mission à l’INRAN a réalisé une prospection sur les maladies des agrumes et du manguier au cours de laquelle il
Essentials of Medicinal Chemistry, CHM 310 Patrick, An Introduction to Medicinal Chemistry 4e Answers to end-of-chapter questions 1) The three molecules are very similar to each other. Structures I and II differ from acetylcholine in having an amino group and an ethyl group respectively instead of a One might expect structure II to be active since a methyl and ethyl group are more simil