Model illustrates progression to MDS, AML

Image by James Thomson

Researchers say they have created a model that shows the step-by-step progression from normal blood cells to acute myeloid leukemia (AML).

The team generated induced pluripotent stem cell (iPSC) lines capturing disease stages that included preleukemia, low-risk myelodysplastic syndrome (MDS), high-risk MDS, and AML.

The researchers then used CRISPR/Cas9 genome editing to induce disease progression and reversal.

And they used the iPSCs to uncover disease-stage-specific effects of 2 drugs.

Eirini P. Papapetrou, MD, PhD, of the Icahn School of Medicine at Mount Sinai in New York, New York, and her colleagues described this work in Cell Stem Cell.

The researchers first explained how they generated patient-derived iPSCs that represented familial predisposition to myeloid malignancy, low-risk and high-risk MDS, and AML.

By studying these iPSC lines, the team uncovered “a phenotypic road map of disease progression” that led to a “serially transplantable leukemia.”

“We are encouraged by the discovery that it was possible to generate potent, engraftable leukemia derived from AML induced pluripotent stem cells,” said study author Michael G. Kharas, PhD, of the Icahn School of Medicine at Mount Sinai.

The researchers also showed that they could revert a high-risk MDS iPSC line to a premalignant state by correcting a chromosome 7q deletion.

And they could force progression in a preleukemic iPSC line. The team induced progression to low-risk MDS by inactivating the second GATA2 allele and progression to high-risk MDS by deleting chromosome 7q.

“This work shows that integrated patient cell reprogramming and cancer genetics is a powerful way to dissect cancer progression,” Dr Kharas said.

The researchers reported that, ultimately, they were able to model the stepwise progression of normal cells to preleukemia and MDS by sequentially introducing genetic lesions associated with earlier and later disease stages (ASXL1 truncation and chromosome 7q deletion, respectively).

“The new model will empower investigation into the cellular and molecular events underlying the development of leukemia in ways that were not possible before,” Dr Papapetrou said.

She added that the group’s findings provide a framework to aid investigation into disease mechanisms, events driving progression, and drug responses.

In fact, the researchers did use hematopoietic progenitor cells (HPCs) derived from their iPSCs to analyze the disease-stage-specific effects of 2 drugs—5-azacytidine and rigosertib.

The team said they found evidence to suggest that 5-azacytidine may work in low-risk MDS by affecting differentiation, and the drug’s main therapeutic action in high-risk MDS might be mediated through selective inhibition of the MDS clone.

The researchers tested rigosertib in HPCs derived from 2 AML lines (from the same patient) that captured 2 different disease stages. One line was derived from the dominant clone (del 7q), and the other was derived from a KRAS-mutated subclone.

The team found that HPCs derived from the KRAS-mutated line demonstrated “marked sensitivity” to rigosertib, but the other HPCs were “marginally affected.”

Image by James Thomson

Researchers say they have created a model that shows the step-by-step progression from normal blood cells to acute myeloid leukemia (AML).

The team generated induced pluripotent stem cell (iPSC) lines capturing disease stages that included preleukemia, low-risk myelodysplastic syndrome (MDS), high-risk MDS, and AML.

The researchers then used CRISPR/Cas9 genome editing to induce disease progression and reversal.

And they used the iPSCs to uncover disease-stage-specific effects of 2 drugs.

Eirini P. Papapetrou, MD, PhD, of the Icahn School of Medicine at Mount Sinai in New York, New York, and her colleagues described this work in Cell Stem Cell.

The researchers first explained how they generated patient-derived iPSCs that represented familial predisposition to myeloid malignancy, low-risk and high-risk MDS, and AML.

By studying these iPSC lines, the team uncovered “a phenotypic road map of disease progression” that led to a “serially transplantable leukemia.”

“We are encouraged by the discovery that it was possible to generate potent, engraftable leukemia derived from AML induced pluripotent stem cells,” said study author Michael G. Kharas, PhD, of the Icahn School of Medicine at Mount Sinai.

The researchers also showed that they could revert a high-risk MDS iPSC line to a premalignant state by correcting a chromosome 7q deletion.

And they could force progression in a preleukemic iPSC line. The team induced progression to low-risk MDS by inactivating the second GATA2 allele and progression to high-risk MDS by deleting chromosome 7q.

“This work shows that integrated patient cell reprogramming and cancer genetics is a powerful way to dissect cancer progression,” Dr Kharas said.

The researchers reported that, ultimately, they were able to model the stepwise progression of normal cells to preleukemia and MDS by sequentially introducing genetic lesions associated with earlier and later disease stages (ASXL1 truncation and chromosome 7q deletion, respectively).

“The new model will empower investigation into the cellular and molecular events underlying the development of leukemia in ways that were not possible before,” Dr Papapetrou said.

She added that the group’s findings provide a framework to aid investigation into disease mechanisms, events driving progression, and drug responses.

In fact, the researchers did use hematopoietic progenitor cells (HPCs) derived from their iPSCs to analyze the disease-stage-specific effects of 2 drugs—5-azacytidine and rigosertib.

The team said they found evidence to suggest that 5-azacytidine may work in low-risk MDS by affecting differentiation, and the drug’s main therapeutic action in high-risk MDS might be mediated through selective inhibition of the MDS clone.

The researchers tested rigosertib in HPCs derived from 2 AML lines (from the same patient) that captured 2 different disease stages. One line was derived from the dominant clone (del 7q), and the other was derived from a KRAS-mutated subclone.

The team found that HPCs derived from the KRAS-mutated line demonstrated “marked sensitivity” to rigosertib, but the other HPCs were “marginally affected.”

Image by James Thomson

Researchers say they have created a model that shows the step-by-step progression from normal blood cells to acute myeloid leukemia (AML).

The team generated induced pluripotent stem cell (iPSC) lines capturing disease stages that included preleukemia, low-risk myelodysplastic syndrome (MDS), high-risk MDS, and AML.

The researchers then used CRISPR/Cas9 genome editing to induce disease progression and reversal.

And they used the iPSCs to uncover disease-stage-specific effects of 2 drugs.

Eirini P. Papapetrou, MD, PhD, of the Icahn School of Medicine at Mount Sinai in New York, New York, and her colleagues described this work in Cell Stem Cell.

The researchers first explained how they generated patient-derived iPSCs that represented familial predisposition to myeloid malignancy, low-risk and high-risk MDS, and AML.

By studying these iPSC lines, the team uncovered “a phenotypic road map of disease progression” that led to a “serially transplantable leukemia.”

“We are encouraged by the discovery that it was possible to generate potent, engraftable leukemia derived from AML induced pluripotent stem cells,” said study author Michael G. Kharas, PhD, of the Icahn School of Medicine at Mount Sinai.

The researchers also showed that they could revert a high-risk MDS iPSC line to a premalignant state by correcting a chromosome 7q deletion.

And they could force progression in a preleukemic iPSC line. The team induced progression to low-risk MDS by inactivating the second GATA2 allele and progression to high-risk MDS by deleting chromosome 7q.

“This work shows that integrated patient cell reprogramming and cancer genetics is a powerful way to dissect cancer progression,” Dr Kharas said.

The researchers reported that, ultimately, they were able to model the stepwise progression of normal cells to preleukemia and MDS by sequentially introducing genetic lesions associated with earlier and later disease stages (ASXL1 truncation and chromosome 7q deletion, respectively).

“The new model will empower investigation into the cellular and molecular events underlying the development of leukemia in ways that were not possible before,” Dr Papapetrou said.

She added that the group’s findings provide a framework to aid investigation into disease mechanisms, events driving progression, and drug responses.

In fact, the researchers did use hematopoietic progenitor cells (HPCs) derived from their iPSCs to analyze the disease-stage-specific effects of 2 drugs—5-azacytidine and rigosertib.

The team said they found evidence to suggest that 5-azacytidine may work in low-risk MDS by affecting differentiation, and the drug’s main therapeutic action in high-risk MDS might be mediated through selective inhibition of the MDS clone.

The researchers tested rigosertib in HPCs derived from 2 AML lines (from the same patient) that captured 2 different disease stages. One line was derived from the dominant clone (del 7q), and the other was derived from a KRAS-mutated subclone.

The team found that HPCs derived from the KRAS-mutated line demonstrated “marked sensitivity” to rigosertib, but the other HPCs were “marginally affected.”