Dr Angelica Merlot has achieved what many medical researchers could only accomplish in a decades-long career.
She completed a PhD in anti-cancer drug development at the age of 24. Four years later, she became the youngest recipient of a National Health and Medical Research Council Grant.
Now, at 29, she leads a research team at UNSW Sydney exploring targeted treatments for some of the deadliest forms of cancer.
The UNSW Scientia Fellow, who is based at the Children’s Cancer Institute, this year achieved another first: in March, she received the NSW Young Woman of the Year award for her work developing new targeted medicines that combat drug-resistant cancers and cancer spread, with a specific focus on pancreatic and brain cancer
“The power of research is that every day you can discover something new, solve problems and push barriers using your curiosity to address some of the major health issues in the community,” Dr Merlot says. “For me, a career in medical research is about a lifelong discovery and education.”
“Metal-binding agents have been shown to deprive cancer cells of essential metals such as copper and iron that are vital for cancer cell growth and proliferation. These agents have been tested on advanced cancers and they take advantage of the fact that cancer cells have altered metal metabolism and require a greater amount of these essential nutrients than normal cells,” Dr Merlot says. “These drugs have been shown to be effective in drug resistant cancers that are no longer able to be treated by standard chemotherapy. Metal-binding agents have also been shown to not only stop the growth of the primary tumour, but also block metastasis.”
These metal-binding agents work on a broad range of cancer types but also target specific proteins such as NDRG1 which can act to suppress the spread of cancer.
“One of my current projects looks at developing nanoparticles prepared from a protein found in the body known as human serum albumin. We’ve seen that this protein helps the delivery of these metal-binding drugs and helps their anti-cancer activity.”
Most of Dr Merlot’s project-based work takes place at the Children’s Cancer Institute labs, at UNSW’s Kensington campus, where a typical day involves conducting experiments in the lab, working with mouse models, patient tissue, writing grants and publications and supervising staff and students.
Dr Merlot believes the next two decades of cancer research will be defined by improvements to personalised medicine through better understanding of the genetics of the disease to predict patient response to therapy.
“The future of cancer treatment will be making sure that every patient receives the right treatment for their cancer type. In the age of personalised medicine, identifying precise molecular characteristics and genetics are critical for clinicians to identify which types of drugs are most suitable and effective for each patient,” Dr Merlot says.
For breast cancer, screening programs and identifying genomic classifiers or proteins such as HER2 have been important in improving and defining treatment options for years. But for other cancers, such as pancreatic or brain, with no detection tests and complex molecular diversity, there has been little progress.
“My hope is that cancer will become a more manageable disease. Something that is less feared and dealt with like any other disease. There is significant stigma around the word ‘cancer’ – there are cancer types that are deadly, which we hope to revolutionise, but there are many cancers that you can survive or live with for many years now.”
Dr Merlot emphasises the importance of funding early career researchers, particularly in areas such as pancreatic and brain cancer that have traditionally been under-funded.
“More funding equals more research which means better outcomes for patients. We’ve seen improvements in breast cancer, melanoma and prostate cancer survival rates but brain and pancreatic cancer still have a dismal prognosis,” she says.
Dr Merlot’s current projects are investigating part of a human cell called the endoplasmic reticulum (ER). The ER is a type of organelle, or subunit within a cell, that has been shown to help cancers grow, spread and develop drug resistance.
“I’m looking at understanding how this part of the cell helps to induce cancer progression. This knowledge will help to identify new targets and therapeutics to stop the advancement of cancers,” she says.
Some of the major advances in cancer now, says Dr Merlot, are understanding the tumour itself – how it consists of more than just cancer cells but other important cells that help the cancer adapt and survive. A major area of advancement is immunotherapy and understanding of the interactions of the immune system with cancer. Immunotherapy can help boost the immune system to attack the cancer.
“We are understanding more about the genetics of the disease and, with a more personalised approach, we are hopeful that we can improve survival rates for children and adults with cancer,” she says.
More information on the UNSW Scientia Fellowship program is available on the Scientia website.