For the first time, Princess Margaret researchers have mapped out where and how leukaemia begins and develops in infants with Down syndrome in preclinical models, paving the way to potentially prevent this cancer in the future.

Children with Down syndrome have a 150-fold increased risk of developing myeloid leukaemia within the first five years of their life. Yet the mechanism by which the extra copy of chromosome 21 predisposes to leukaemia remains unclear.

Down syndrome is a genetic disorder caused by a random error in cell division in early human development that results in an extra copy of chromosome 21.

This extra copy is what causes the developmental changes and physical traits associated with the syndrome, including the predisposition to leukaemia.

However, the exact blood cell type in which leukaemia begins in foetal development, along with the genetic alterations that cause this cell to become preleukemic, has eluded researchers until now.

Furthermore, the additional mutations that must accumulate during childhood to transform preleukaemia into acute leukaemia were unknown.

The study and results of the early evolution of leukaemia in Down syndrome from the laboratory of Princess Margaret Senior Scientist Dr. John Dick are published in Science, July 9, 2021. Post-doctoral fellow Dr. Elvin Wagenblast is first author, and Affiliate Scientist Dr. Eric Lechman is co-senior author, along with Dr. Dick.

"A whole sequence of cellular events have already happened before a person is diagnosed with the disease," explains Dr. Dick. "You can't tell at that point which sequence of events happened first, you just know that it has already happened.

"For the first time, our model is giving us insight into the human leukaemia process. Ultimately, we may be able to prevent the acute illness by treating it in its earliest phase, when it is preleukaemic, to prevent its progression to full blown leukaemia."

Using a preclinical model that includes human Down syndrome cells from a human tissue biobank, along with an enhanced CRISPR/Cas9 method for gene alteration in human blood stem cells that was developed by Drs. Wagenblast and Lechman at Princess Margaret, the team set out to chart the steps involved in this specific leukaemia evolution.

Transient preleukaemia is a unique condition frequently occurring in newborns with Down syndrome, which can either spontaneously disappear within days to months of birth, or transform into acute myeloid leukaemia within four years by acquiring additional mutations in some individuals.

What Drs. Wagenblast, Lechman and Dick revealed in this work was the distinct cellular and genetic events related to transient preleukaemia, from their beginnings in the foetus, to further progression to leukaemia in childhood.

Specifically, the team was able to test a variety of blood cell types and pinpoint that transient preleukaemia originates only from long-term haematopoietic stem cells (HSCs), with the GATA1 mutation, as early as the second trimester of a fetus with Down syndrome. Preleukaemia does not begin in HSCs from non-Down syndrome samples.

Only HSCs are able to regenerate the entire blood system and maintain long-term output due to their unique continuous capacity for self-renewal. In a broader picture, the fact that the cellular origin of paediatric leukaemia is limited to only long-term HSCs might have implications for other kinds of childhood leukaemias beyond Down syndrome.

Acute leukaemia happens only after the first two mutations - the extra copy of chromosome 21 and the GATA1 mutation - are in place and have "primed" the progeny or descendants downstream of the altered long-term HSCs to acquire further mutations that lead to fully transformed acute leukaemia, explains Dr. Lechman.

"We actually created a human disease in a preclinical model by showing how the genetically edited, as well as the normal human blood stem cells, behave in it, and we succeeded in recreating the precise, progressive steps of how leukaemia develops," says Dr. Dick. "We now have a lot of clues as to the genetic abnormalities these mutations are driving when they cause leukaemia."

The team also identified CD117/KIT as a unique protein cell surface marker on the altered disease-driving stem cells that causes the cells to proliferate. In the preclinical model and setting, the researchers were able to target and eliminate preleukaemic stem cells using small molecule CD117/KIT inhibitors to prevent their progression to acute leukaemia.

The researchers note that this preventative strategy could potentially be used in Down syndrome newborns and even expanded to other childhood leukaemias that are known to be initiated during foetal development.

"The clinical significance of being able to target pre-cancerous lesions and preventing progression to cancer is profound," says Dr. Dick, "It would transform the paediatric cancer field."

Source: University Health Network