Only about one in four people diagnosed with acute myelogenous leukaemia (AML) survive five years after the initial diagnosis.
To improve that survival rate, researchers at The University of Texas at San Antonio (UTSA) and the University of Texas MD Anderson Cancer Center created an online atlas to identify and classify protein signatures present at AML diagnosis.
The new protein classifications will help researchers and clinicians recommend better treatment and personalised medicine for patients suffering from this aggressive cancer, which occurs in the blood and bone marrow.
The breakthrough research is published in the latest April issue of Nature Biomedical Engineering.
Researcher Amina Qutub, an associate professor in the UTSA Department of Biomedical Engineering (who joined UTSA in 2018 from Rice University), and oncologist Steven M. Kornblau, a professor and practicing clinician in the Department of leukaemia at UT MD Anderson Cancer Center, examined the genetic, epigenetic and environmental diversity that occurs in cancerous cells due to AML.
Analysing proteomic screens of 205 patient biopsies obtained at MD Anderson Cancer Center, first author Chenyue Wendy Hu (then a graduate student at the Qutub Lab, now at Uber Technologies), Kornblau and Qutub developed a new computational method called MetaGalaxy to categorise the protein signatures into 154 different patterns based on their cellular functions and pathways.
By approaching this challenge through the unique lens of developing a quantitative map for each leukaemia patient from protein expression in their blood and bone marrow, rather than the standard lens of qualitative metrics and genetic risks alone, Qutub, Kornblau and their research collaborators will be able to more precisely categorise patients into risk groups and better predict their treatment outcomes.
To better understand the AML hallmarks at the proteomic (protein system) level and to share the results of their work with other researchers, the UTSA biomedical engineering professor and her team including Hu, and students Andrew Ligeralde (now at the University of California, Berkeley) and Allie Raybon (from the UTSA Department of Biomedical Engineering) built a web portal known as the leukaemia Proteome Atlas.
Designed by Qutub’s and Kornblau’s teams with input from clinical collaborators worldwide, the online portal gives oncologists and cancer scientists the tools they need to investigate AML protein expression patterns from one patient to the next.
It also provides investigators around the world with leads for new leukaemia research and new computational tools.
Since many genetic mutations cannot be targeted, the proteomic profiling and target identification process used in this research study will accelerate the identification of therapeutic targets.
It also propels researchers much closer to the development of personalised combination therapies for patients based on their unique protein signatures.
“Acute myelogenous leukaemia presents as a cancer so heterogeneous that it is often described as not one, but a collection of diseases,” said Qutub. “To decipher the clues found in proteins from blood and bone marrow of leukaemia patients, we developed a new computer analysis – MetaGalaxy – that identifies molecular hallmarks of leukaemia. These hallmarks are analogous to the way constellations guide navigation of the stars: they provide a map to protein changes for leukaemia. Our ‘hallmark’ predictions are being experimentally tested through drug screens and can be ‘programmed’ into cells through synthetic manipulation of proteins. A next step to bring this work to the clinic and impact patient care is testing whether these signatures lead to the aggressive growth or resistance to chemotherapy observed in leukaemia patients. At the same time, to rapidly accelerate research in leukaemia and advance the hunt for treatments, we provide the hallmarks in an online compendium where fellow researchers and oncologists worldwide can build from the resource, tools and findings, leukaemiaAtlas.org.”