Breast cancer spread uncovered by new molecular microscopy

For the first time, researchers have been able to map in detail the spread of cancer clones and how they behave. The image shows a patchwork of cancer clones that have been dyed blue, orange and green. Photo: Artem Lomakin and Lucy Yates.

New technology can trace which populations of breast cancer cells are responsible for the spread of the disease, and for the first time highlights how the location of cancer cells could be as important as mutations in tumour growth.  

The method was created by a team from the Wellcome Sanger Institute, EMBL’s European Bioinformatics Institute (EMBL-EBI), the German Cancer Research Center (Deutsches Krebsforschungszentrum, DKFZ), the Science for Life Laboratory in Sweden, and collaborators. It could be used to help answer some of the big questions in cancer, such as why some cancer cells spread, how treatment resistance is formed, and why some therapies fail.

The new study, published today in Nature, shows how it is now possible to map how tumours have developed, combining the cancer cells’ genetic information, the surrounding cell types, and how they interact with their environment over time.

In the future, this approach could be used to see how treatments influence the cancer at not only the genetic level, but also any impact on how the tumour interacts with the immune system and the environment around it.

Breast cancer commonly starts when cells start to grow uncontrollably, often due to mutations in the cells. Overtime the tumour becomes a patchwork of cells, called cancer clones, each with different mutations. As they are genetically different, they can have different reactions to treatments. For example, some of these cancer cells could become resistant to treatment, or some could spread around the body.

The mutations that occur will be influenced by what is happening around the cancer, the cells that it is surrounded with, and the individual’s immune system. Therefore, being able to study the environment that a cancer cell is in, what mutations arise, and which cancer cells spread around the body gives a complete view of tumour evolution.

This new technology uses hundreds of thousands of tiny fluorescent molecular probes to interrogate cellular DNA and RNA and scan large pieces of tissue using fluorescence microscopy. It can genetically and physically map out a cancer's unique set of clones, how their gene expression programs change and show how they interact with their environment.

The environment shapes cancer development

The team found that across multiple stages of breast cancer development there were specific, and often unexpected, patterns of clone growth and that genetic clones behave differently depending on where in the breast they started.

The results also suggest that sometimes it is not only the genetics that influence how cancers grow, but also the location of the tumours. In this case, the genetics can be used as a tool to find out more about what happened in the situation that drove the cancer clones to spread around the body.

Mats Nilsson. Foto: Adam af Ekenstam

Professor Mats Nilsson, co-senior author from the Science for Life Laboratory at Stockholm University, said: “Cancer is caused by genetic mutations in a cell and this research was the first time that we were able to use DNA base specific probes to target dozens of these mutations in a set of cancer cell clones. This innovative technique allowed us to accurately reconstruct the spread of these clones. An important insight from our research is that it may not be the genetic changes alone that are the reason that the cancer cells survive and spread; it could also be where they are. This adds an additional layer of complexity as well as new potential ways to target the disease. It may also offer explanations about why some treatments only work in some individuals, even if they have similar mutations to others, as the tumours are found in different areas of the breast.”

In the future, it could be possible to develop therapies that could prevent or lessen the cancer’s ability to grow and spread, by influencing the environment around the tumour. In addition to this, researchers could use the newly developed tool to test how new treatments affect both the cancer and its interaction with the immune system, giving a complete picture of how therapies work and any possible side effects.
 

Publication: A. Lomakin, J. Svedlund, C. Strell, et al. (2022) Spatial genomics maps the structure, nature and evolution of cancer clones. Nature. DOI: 10.1038/s41586-022-05425-2