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Two preclinical studies published in Cancer Discovery suggest that EZH2 inhibitors might enhance the efficacy of treatment with tyrosine kinase inhibitors (TKIs) in patients with chronic myeloid leukemia (CML).
One study showed that CML leukemic stem cells (LSCs) are dependent upon EZH2.
The other study revealed that epigenetic reprogramming sensitizes CML LSCs to combined treatment with an EZH2 inhibitor and a TKI.
EZH2 dependence
In the first study, in vitro experiments revealed that LSCs have an overabundance of EZH2. In fact, the researchers found that EZH2 helps LSCs survive and give rise to full-fledged CML cells.
Experiments in mice showed that inactivating EZH2 through gene-editing techniques caused LSCs to die, halting CML at its source.
“The stem cells’ dependence on EZH2 suggests they will be especially vulnerable to drugs that target the protein,” said study author Stuart Orkin, MD, of Boston Children’s Hospital in Massachusetts.
“Our findings suggest inhibition of EZH2 should be considered as a way to eradicate CML when used in combination with current targeted therapies. It offers a promising approach to shortening the duration of therapy in order to achieve a cure. If successful, the cost savings of such an approach could also be significant.”
Combination treatment
The second study supports the idea that combining EZH2 inhibitors and TKIs could benefit patients with CML.
Mary T. Scott, of the University of Glasgow in the UK, and her colleagues found that EZH2 and H3K27me3 reprogramming is important for LSC survival and renders the cells sensitive to combined treatment with an EZH2 inhibitor and a TKI.
The researchers treated CML CD34+ cells, normal CD34+ cells, and LSCs with the EZH2 inhibitor GSK343 and the TKI dasatinib, both alone and in combination. The team said that GSK343 selectively targeted the loss of H3K27me3 in the presence of dasatinib.
In addition, combination treatment led to a significant reduction in cell viability (even in “TKI-persistent” cells), an increase in apoptosis, and a reduction in colony-forming cell and granulocyte/erythroid/macrophage/megakaryocyte outputs, when compared to dasatinib alone.
The researchers also evaluated a TKI and an EZH2 inhibitor in a mouse model of CML. The mice received nilotinib and EPZ-6438, both alone and in combination, for either 14 days or 25 days.
After 14 days of treatment, mice that received the combination had significant reductions in levels of leukemic (Ph+) human CD45+ cells, CD45+CD34+ progenitor cells, and primitive CD45+CD34+CD38− stem cells in the bone marrow, when compared to mice that received nilotinib alone.
After 25 days of treatment, mice that received the combination had near-complete elimination of CD45+CD34+ progenitor cells and a greater than 70% reduction of CD45+CD34+CD38− cells, when compared to mice that received nilotinib alone.
The researchers said these results demonstrate a clear rationale for combining TKI treatment with an EZH2 inhibitor, as an EZH2 inhibitor can target primitive CML cells not eradicated by a TKI alone.
Image by Difu Wu
Two preclinical studies published in Cancer Discovery suggest that EZH2 inhibitors might enhance the efficacy of treatment with tyrosine kinase inhibitors (TKIs) in patients with chronic myeloid leukemia (CML).
One study showed that CML leukemic stem cells (LSCs) are dependent upon EZH2.
The other study revealed that epigenetic reprogramming sensitizes CML LSCs to combined treatment with an EZH2 inhibitor and a TKI.
EZH2 dependence
In the first study, in vitro experiments revealed that LSCs have an overabundance of EZH2. In fact, the researchers found that EZH2 helps LSCs survive and give rise to full-fledged CML cells.
Experiments in mice showed that inactivating EZH2 through gene-editing techniques caused LSCs to die, halting CML at its source.
“The stem cells’ dependence on EZH2 suggests they will be especially vulnerable to drugs that target the protein,” said study author Stuart Orkin, MD, of Boston Children’s Hospital in Massachusetts.
“Our findings suggest inhibition of EZH2 should be considered as a way to eradicate CML when used in combination with current targeted therapies. It offers a promising approach to shortening the duration of therapy in order to achieve a cure. If successful, the cost savings of such an approach could also be significant.”
Combination treatment
The second study supports the idea that combining EZH2 inhibitors and TKIs could benefit patients with CML.
Mary T. Scott, of the University of Glasgow in the UK, and her colleagues found that EZH2 and H3K27me3 reprogramming is important for LSC survival and renders the cells sensitive to combined treatment with an EZH2 inhibitor and a TKI.
The researchers treated CML CD34+ cells, normal CD34+ cells, and LSCs with the EZH2 inhibitor GSK343 and the TKI dasatinib, both alone and in combination. The team said that GSK343 selectively targeted the loss of H3K27me3 in the presence of dasatinib.
In addition, combination treatment led to a significant reduction in cell viability (even in “TKI-persistent” cells), an increase in apoptosis, and a reduction in colony-forming cell and granulocyte/erythroid/macrophage/megakaryocyte outputs, when compared to dasatinib alone.
The researchers also evaluated a TKI and an EZH2 inhibitor in a mouse model of CML. The mice received nilotinib and EPZ-6438, both alone and in combination, for either 14 days or 25 days.
After 14 days of treatment, mice that received the combination had significant reductions in levels of leukemic (Ph+) human CD45+ cells, CD45+CD34+ progenitor cells, and primitive CD45+CD34+CD38− stem cells in the bone marrow, when compared to mice that received nilotinib alone.
After 25 days of treatment, mice that received the combination had near-complete elimination of CD45+CD34+ progenitor cells and a greater than 70% reduction of CD45+CD34+CD38− cells, when compared to mice that received nilotinib alone.
The researchers said these results demonstrate a clear rationale for combining TKI treatment with an EZH2 inhibitor, as an EZH2 inhibitor can target primitive CML cells not eradicated by a TKI alone.
Image by Difu Wu
Two preclinical studies published in Cancer Discovery suggest that EZH2 inhibitors might enhance the efficacy of treatment with tyrosine kinase inhibitors (TKIs) in patients with chronic myeloid leukemia (CML).
One study showed that CML leukemic stem cells (LSCs) are dependent upon EZH2.
The other study revealed that epigenetic reprogramming sensitizes CML LSCs to combined treatment with an EZH2 inhibitor and a TKI.
EZH2 dependence
In the first study, in vitro experiments revealed that LSCs have an overabundance of EZH2. In fact, the researchers found that EZH2 helps LSCs survive and give rise to full-fledged CML cells.
Experiments in mice showed that inactivating EZH2 through gene-editing techniques caused LSCs to die, halting CML at its source.
“The stem cells’ dependence on EZH2 suggests they will be especially vulnerable to drugs that target the protein,” said study author Stuart Orkin, MD, of Boston Children’s Hospital in Massachusetts.
“Our findings suggest inhibition of EZH2 should be considered as a way to eradicate CML when used in combination with current targeted therapies. It offers a promising approach to shortening the duration of therapy in order to achieve a cure. If successful, the cost savings of such an approach could also be significant.”
Combination treatment
The second study supports the idea that combining EZH2 inhibitors and TKIs could benefit patients with CML.
Mary T. Scott, of the University of Glasgow in the UK, and her colleagues found that EZH2 and H3K27me3 reprogramming is important for LSC survival and renders the cells sensitive to combined treatment with an EZH2 inhibitor and a TKI.
The researchers treated CML CD34+ cells, normal CD34+ cells, and LSCs with the EZH2 inhibitor GSK343 and the TKI dasatinib, both alone and in combination. The team said that GSK343 selectively targeted the loss of H3K27me3 in the presence of dasatinib.
In addition, combination treatment led to a significant reduction in cell viability (even in “TKI-persistent” cells), an increase in apoptosis, and a reduction in colony-forming cell and granulocyte/erythroid/macrophage/megakaryocyte outputs, when compared to dasatinib alone.
The researchers also evaluated a TKI and an EZH2 inhibitor in a mouse model of CML. The mice received nilotinib and EPZ-6438, both alone and in combination, for either 14 days or 25 days.
After 14 days of treatment, mice that received the combination had significant reductions in levels of leukemic (Ph+) human CD45+ cells, CD45+CD34+ progenitor cells, and primitive CD45+CD34+CD38− stem cells in the bone marrow, when compared to mice that received nilotinib alone.
After 25 days of treatment, mice that received the combination had near-complete elimination of CD45+CD34+ progenitor cells and a greater than 70% reduction of CD45+CD34+CD38− cells, when compared to mice that received nilotinib alone.
The researchers said these results demonstrate a clear rationale for combining TKI treatment with an EZH2 inhibitor, as an EZH2 inhibitor can target primitive CML cells not eradicated by a TKI alone.