THE CANCER MOSAIC, TRAITS, STRATEGIES AND ADAPTATIONS
23-24 OF AUGUST 2018 - MONTPELLIER.
AIM: Bring together experts in evolutionary biology, cancer biology, oncology and the interscetion of these fields, in order to address topics in tumor growth and diversification, metastases, and cancer treatment.
SCIENTIFIC ORGANIZERS: Benjamin Roche (CREEC), Rodrigo Hamede (University of Tasmania), Beata Ujvari (Deakin Univeersity), Frédéric Thomas (CREEC).
In the bookshops
Ecology and Evolution of Cancer
Editors: Beata Ujvari, Benjamin Roche et Frederic Thomas.
Ecology and Evolution of Cancer (Academic Press – 14 février 2017) is a timely work outlining ideas that not only represent a substantial and original contribution to the fields of evolution, ecology, and cancer, but also goes beyond by connecting the interfaces of these disciplines. This work engages the expertise of a multidisciplinary research team to collate and review the latest knowledge and developments in this exciting research field.
The evolutionary perspective of cancer has gained significant international recognition and interest, which is fully understandable given that somatic cellular selection and evolution are elegant explanations for carcinogenesis. Cancer is now generally accepted to be an evolutionary and ecological process with complex interactions between tumor cells and their environment sharing many similarities with organismal evolution. As a critical contribution to this field of research the book is important and relevant for the applications of evolutionary biology to understand the origin of cancers, to control neoplastic progression, and to prevent therapeutic failures.
On the web
About the collaboration with the Deakin University.
FROM GEELONG TO MONTPELLIER, RESEARCHERS HOPE ANIMALS HOLD KEY TO BETTER HUMAN CANCER OUTCOMES.
A Deakin University biologist is collaborating with French scientists to unlock the secrets to the animal kingdom's ability to fight cancer in an attempt to help human medicine better prevent and cure the disease. Senior Research Fellow Dr Beata Ujvari and a team from France's Montpellier University are the first research team to examine how animals fought and prevented cancer and how their natural preventative tactics could translate to humans. "Until now, the study of cancer in the human world has been undertaken in isolation to the animal world, which is unfortunate because links between these disciplines have the mutual potential to reveal new perspectives and lines of research," Dr Ujvari said.
The recently completed research, published in Animal Behaviour, is the first step in the partnership between Deakin and Montpellier universities. "So far what we have done is review data from all the available research across the globe on cancer in animals, which affects all creatures from insects to whales, and put forward new ideas and new theories, which we now want to prove or disprove in the laboratory and the wild," Dr Ujvari said. "Cancer in animals has mostly been studied in zoos and laboratory settings, which does not always represent what is really happening in the wild. We found there is not that much information available about how wild animals react to cancer, mostly because they die of parasite infections or being killed by predators before cancer can fully take effect. During our reviews we looked at how cancer might affect different organisms ranging from invertebrates (insects) to vertebrates and were interested in what kind of strategies different organisms use to avoid getting cancer, what do they do to treat it if they do get it and how do they decrease the risk of dying from it. We want to know, can the same strategies be applied to humans? But first we need to undertake more tests on animals, specifically to monitor the effect on cancer of different behaviours, such as sleeping longer when affected by cancer, in a controlled, laboratory environment."
Using easy-to-study fruit flies, the French team is now monitoring the behaviour of the organisms after they have been artificially exposed to cancer, looking at self-medicating behaviours such as sleep patterns and food choices. Dr Ujvari, from Deakin's School of Life and Environmental Sciences and within its Centre for Integrative Ecology, said she would then repeat the French experiments at Deakin University in a vertebrate model - zebra fish - to investigate whether insects and vertebrates react and respond similarly to cancer. "If the responses of flies and fish are similar, then it implies that the same behavioural pattern most likely also apply to mammals, including humans, and similar strategies could be used when preventing and treating human cancer," Dr Ujvari said. "For example, studying the unusual feeding habits of animals could help us to identify the food items they use to self-medicate, which could also potentially contribute to the discovery of novel anti-cancer drugs. Furthermore, understanding the link between sleep duration and cancer could result in preventing or treating cancers. Human studies show that shift workers with frequent nightshifts have a generally higher risk of developing cancer. We also know that animals that sleep significantly more produce a hormone, which has anti-cancer properties." Dr Ujvari said this hormone could be developed into medication to offset the negative effect of sleepless nights in shift workers and to reduce the risk of developing cancer. "And by removing habitants from highly polluted areas and increasing the awareness of cancers and risk factors, we could significantly reduce cancer prevalence across the globe," she said. "It's so easy to ignore, but Mother Nature had millions of years to overcome the effect of cancer in wild animals, it is time we exploit that knowledge to treat and prevent cancer in humans."
The team's findings from its research analysis of the strategies animals use to avoid and treat cancer included:
- Animals use preventive behaviour to avoid getting cancer, such as not mating with partners affected by cancer. Pathogens, such as viruses and bacteria are major factors in initiating many, if not most cancers, and animals can reduce the risk of getting cancer by avoiding mating with infected individuals. They also choose habitats where they are less exposed to environmental factors potentially causing cancer (e.g. pollution);
- Animals also self-medicate by consuming food containing anti-cancer compounds in them; and
- They developed behaviours to reduce the risk of cancer for their offspring, such as by preferring breeding habitats that are less polluted/contaminated, therefore giving a better chance to their babies to survive and avoid getting cancer.
Dr Ujvari said the partnership between Deakin and Montpellier universities was one of the most exciting developments in the field and came about after meeting with the head of Montpellier's Centre for Ecological and Evolutionary Cancer Research, Professor Frederic Thomas, at a conference in 2013.
ANIMAL INSTINCTS COULD HELP IN CANCER FIGHT, DEAKIN RESEARCHER SAYS
A GEELONG researcher is fighting deadly human cancers by studying how wild animals instinctively self-medicate and shield themselves from the diseases.
Deakin University biologist Beata Ujvari has teamed with colleagues at France’s Montpellier University for the groundbreaking study. Rather than examining and experimenting on animals in a laboratory, the scientists plan to observe creatures in the wild, where natural instincts will not be inhibited.
Dr Ujvari said what they learn might help the fight against human cancers by identifying ingredients for novel anti-cancer drugs and improving information on appropriate diet and sleep patterns to avoid or fight cancer. She said the work might also strengthen the understanding of the role environmental factors, such as pollution and radiation, play in causing cancers. “It’s so easy to ignore, but Mother Nature had millions of years to overcome the effect of cancer in wild animals, it is time we exploit that knowledge to treat and prevent cancer in humans,” she said. “Most of the cancer studies that use or focus on animals are focusing on laboratory animals, which loses the natural behaviour. If they’re in cages or laboratories they don’t behave as wild, so we lose out on a big pool of knowledge and experience of what wild animals can use, or potentially use, to avoid cancer. We lose knowledge and we lose information because we simplify the system and we put them into a controlled environment. We control what they feed on, what they eat. We control their movements, and how much they can move; they can’t escape from the cages.”
After pulling together all the available research on animal cancers and publishing the collated findings, the scientists are looking to expand their project. Dr Ujvari cited studies that showed how chimpanzees naturally medicate themselves and how birds protected themselves from radiation at the Ukraine’s Chernobyl nuclear disaster site as evidence of Mother Nature’s instinctive ability to fight disease. The French collaborators are presently examining how fruit flies respond to cancer, and Dr Ujvari is seeking funding to expand her research to zebra fish at Deakin’s Centre for Integrative Ecology.
“If the responses of flies and fish are similar, then it implies that the same behavioural pattern most likely also apply to mammals, including humans, and similar strategies could be used when preventing and treating human cancer,” Dr Ujvari said. “For example, studying the unusual feeding habits of animals could help us to identify the food items they use to self-medicate, which could also potentially contribute to the discovery of novel anti-cancer drugs. Furthermore, understanding the link between sleep duration and cancer could result in preventing or treating cancers. Human studies show that shift workers with frequent night shifts have a generally higher risk of developing cancer. We also know that animals that sleep significantly more produce a hormone, which has anti-cancer properties.”
Picture: Breast cancer cells in a lab mouse, seen under a hi-tech microscope. PIC: Garvan Institute.
Last accepted publications
The article "Do cell-autonomous and non-cell-autonomous effects drive the structure of tumor ecosystems?" will be soon in Reviews on Cancer.
The article "The evolutionary ecology of transmissible cancers. Infection Genetics and Evolution" will be soon in Infection Genetics and Evolution.
All CREEC publications here.