Novel oncogene found in hepatoblastoma

A novel oncogene may be a key driver in hepatoblastoma, according to a new study. Hepatoblastoma is the most common form of pediatric cancer, and many tumors harbor beta-catenin mutations and alterations to the Hippo tumor suppression pathway.

In mice, cells can be turned cancerous by coexpressing beta-catenin mutants and the Hippo effector YAP. Some hepatoblastomas have mutations in NFE2L2/NRF2 (NFE2L2), which is a transcription factor that can either promote or suppress tumorigenesis.

In a report in Cellular and Molecular Gastroenterology and Hepatology, researchers led by Huabo Wang, PhD, of the UPMC Children’s Hospital of Pittsburgh investigated the potential role of NFE2L2 by expressing all combinations of mutant beta-catenin, YAP^S127A, and two NFE2L2 mutants previously discovered in patients (L30P and R34P).

The researchers found that both the L30P and R34P mutations led to an increase in cellular growth and to both necrosis and cyst formation, which are both clinically uncommon. Any two of beta-catenin, YAP^S127A, and L30P/R34P caused tumor formation, indicating that NFE2L2 is an oncogene, according to the authors.

Among tumors with changes in all three regions, unbiased RNA sequencing across all combinations of mutations revealed 22 RNA transcripts common to all of them. These are probably the most important contributors to cell transformation and may also be related to increased growth, cystogenesis, and necrosis found in these tumors. Of those transcripts, 10 were highly correlated with survival in human hepatoblastomas, and 17 correlated with survival in more than one adult cancer.

Although hepatoblastomas have fewer mutations than most tumors, around 5%-10% have mutations in NFE2L2. About half have an increase in the copy number of NFE2L2.

The results suggest that wild-type NFE2L2 plays a role in suppressing cell proliferation in response to oxidative, metabolic, and electrophilic stresses. But the picture is more complex than that because NFE2L2’s pathway can have opposite effects, depending on the timing and context. Early in the oncogenesis pathway, it may protect against the damaging effects of reactive oxygen species (ROS). Later, it can make cells more tolerant to the effects of oncoproteins and promote tumor evolution, expansion, and even resistance to therapy.

Previous in vitro and tumor xenograft studies had suggested that NFE2L2 targets might play a role in apoptosis, metabolism, angiogenesis, and chemotherapeutic drug detoxification. The new results show that the L30P/R34P mutations can accelerate tumorigenesis caused by beta-catenin mutations and can promote transformation when co-expressed with either beta-catenin or YAP^S127A. That suggests that some hepatoblastomas may be driven at least in part by changes to NFE2L2. The researchers speculate that it may also be involved in combination with other oncoproteins in other types of tumors.

The researchers noted that the cysts seen in tumors with NFE2L2 mutations are bloodless, and resembled cysts that are sometimes seen in human hepatoblastomas. They were unrelated to tumor growth rate.

“Our findings demonstrate that NFE2L2 mutants alter redox balance in beta-catenin/YAP^S127A HBs and increase growth, cystogenesis, and necrosis. The unanticipated oncogenicity of L30P/R34P when coexpressed with beta-catenin or YAP^S127A also demonstrated their direct role in transformation in vivo and unequivocally established NFE2L2 as an oncoprotein that can be activated by mutation, overexpression, or other factors that perturb the normal NFE2L2:KEAP1 balance,” the authors wrote.

The study received funding from various nonindustry sources. The study authors disclosed no conflicts of interest.

A novel oncogene may be a key driver in hepatoblastoma, according to a new study. Hepatoblastoma is the most common form of pediatric cancer, and many tumors harbor beta-catenin mutations and alterations to the Hippo tumor suppression pathway.

In mice, cells can be turned cancerous by coexpressing beta-catenin mutants and the Hippo effector YAP. Some hepatoblastomas have mutations in NFE2L2/NRF2 (NFE2L2), which is a transcription factor that can either promote or suppress tumorigenesis.

In a report in Cellular and Molecular Gastroenterology and Hepatology, researchers led by Huabo Wang, PhD, of the UPMC Children’s Hospital of Pittsburgh investigated the potential role of NFE2L2 by expressing all combinations of mutant beta-catenin, YAP^S127A, and two NFE2L2 mutants previously discovered in patients (L30P and R34P).

The researchers found that both the L30P and R34P mutations led to an increase in cellular growth and to both necrosis and cyst formation, which are both clinically uncommon. Any two of beta-catenin, YAP^S127A, and L30P/R34P caused tumor formation, indicating that NFE2L2 is an oncogene, according to the authors.

Among tumors with changes in all three regions, unbiased RNA sequencing across all combinations of mutations revealed 22 RNA transcripts common to all of them. These are probably the most important contributors to cell transformation and may also be related to increased growth, cystogenesis, and necrosis found in these tumors. Of those transcripts, 10 were highly correlated with survival in human hepatoblastomas, and 17 correlated with survival in more than one adult cancer.

Although hepatoblastomas have fewer mutations than most tumors, around 5%-10% have mutations in NFE2L2. About half have an increase in the copy number of NFE2L2.

The results suggest that wild-type NFE2L2 plays a role in suppressing cell proliferation in response to oxidative, metabolic, and electrophilic stresses. But the picture is more complex than that because NFE2L2’s pathway can have opposite effects, depending on the timing and context. Early in the oncogenesis pathway, it may protect against the damaging effects of reactive oxygen species (ROS). Later, it can make cells more tolerant to the effects of oncoproteins and promote tumor evolution, expansion, and even resistance to therapy.

Previous in vitro and tumor xenograft studies had suggested that NFE2L2 targets might play a role in apoptosis, metabolism, angiogenesis, and chemotherapeutic drug detoxification. The new results show that the L30P/R34P mutations can accelerate tumorigenesis caused by beta-catenin mutations and can promote transformation when co-expressed with either beta-catenin or YAP^S127A. That suggests that some hepatoblastomas may be driven at least in part by changes to NFE2L2. The researchers speculate that it may also be involved in combination with other oncoproteins in other types of tumors.

The researchers noted that the cysts seen in tumors with NFE2L2 mutations are bloodless, and resembled cysts that are sometimes seen in human hepatoblastomas. They were unrelated to tumor growth rate.

“Our findings demonstrate that NFE2L2 mutants alter redox balance in beta-catenin/YAP^S127A HBs and increase growth, cystogenesis, and necrosis. The unanticipated oncogenicity of L30P/R34P when coexpressed with beta-catenin or YAP^S127A also demonstrated their direct role in transformation in vivo and unequivocally established NFE2L2 as an oncoprotein that can be activated by mutation, overexpression, or other factors that perturb the normal NFE2L2:KEAP1 balance,” the authors wrote.

The study received funding from various nonindustry sources. The study authors disclosed no conflicts of interest.

A novel oncogene may be a key driver in hepatoblastoma, according to a new study. Hepatoblastoma is the most common form of pediatric cancer, and many tumors harbor beta-catenin mutations and alterations to the Hippo tumor suppression pathway.

In mice, cells can be turned cancerous by coexpressing beta-catenin mutants and the Hippo effector YAP. Some hepatoblastomas have mutations in NFE2L2/NRF2 (NFE2L2), which is a transcription factor that can either promote or suppress tumorigenesis.

In a report in Cellular and Molecular Gastroenterology and Hepatology, researchers led by Huabo Wang, PhD, of the UPMC Children’s Hospital of Pittsburgh investigated the potential role of NFE2L2 by expressing all combinations of mutant beta-catenin, YAP^S127A, and two NFE2L2 mutants previously discovered in patients (L30P and R34P).

The researchers found that both the L30P and R34P mutations led to an increase in cellular growth and to both necrosis and cyst formation, which are both clinically uncommon. Any two of beta-catenin, YAP^S127A, and L30P/R34P caused tumor formation, indicating that NFE2L2 is an oncogene, according to the authors.

Among tumors with changes in all three regions, unbiased RNA sequencing across all combinations of mutations revealed 22 RNA transcripts common to all of them. These are probably the most important contributors to cell transformation and may also be related to increased growth, cystogenesis, and necrosis found in these tumors. Of those transcripts, 10 were highly correlated with survival in human hepatoblastomas, and 17 correlated with survival in more than one adult cancer.

Although hepatoblastomas have fewer mutations than most tumors, around 5%-10% have mutations in NFE2L2. About half have an increase in the copy number of NFE2L2.

The results suggest that wild-type NFE2L2 plays a role in suppressing cell proliferation in response to oxidative, metabolic, and electrophilic stresses. But the picture is more complex than that because NFE2L2’s pathway can have opposite effects, depending on the timing and context. Early in the oncogenesis pathway, it may protect against the damaging effects of reactive oxygen species (ROS). Later, it can make cells more tolerant to the effects of oncoproteins and promote tumor evolution, expansion, and even resistance to therapy.

Previous in vitro and tumor xenograft studies had suggested that NFE2L2 targets might play a role in apoptosis, metabolism, angiogenesis, and chemotherapeutic drug detoxification. The new results show that the L30P/R34P mutations can accelerate tumorigenesis caused by beta-catenin mutations and can promote transformation when co-expressed with either beta-catenin or YAP^S127A. That suggests that some hepatoblastomas may be driven at least in part by changes to NFE2L2. The researchers speculate that it may also be involved in combination with other oncoproteins in other types of tumors.

The researchers noted that the cysts seen in tumors with NFE2L2 mutations are bloodless, and resembled cysts that are sometimes seen in human hepatoblastomas. They were unrelated to tumor growth rate.

“Our findings demonstrate that NFE2L2 mutants alter redox balance in beta-catenin/YAP^S127A HBs and increase growth, cystogenesis, and necrosis. The unanticipated oncogenicity of L30P/R34P when coexpressed with beta-catenin or YAP^S127A also demonstrated their direct role in transformation in vivo and unequivocally established NFE2L2 as an oncoprotein that can be activated by mutation, overexpression, or other factors that perturb the normal NFE2L2:KEAP1 balance,” the authors wrote.

The study received funding from various nonindustry sources. The study authors disclosed no conflicts of interest.