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The effort is the National Cancer Institute Molecular Analysis for Therapy Choice (NCI-MATCH) trial. For this study, researchers performed next-generation sequencing on tumor biopsy specimens to identify therapeutically actionable molecular alterations in patients with “underexplored” cancer types.
The trial included 5,954 patients with cancers that had progressed on standard treatments or rare cancers for which there is no standard treatment. If actionable alterations were found in these patients, they could receive new drugs in development that showed promise in other clinical trials or drugs that were approved by the Food and Drug Administration to treat at least one cancer type.
Data newly reported in the Journal of Clinical Oncology showed that 37.6% of patients had alterations that could be matched to targeted drugs, and 17.8% of patients were assigned to targeted treatment. Multiple actionable tumor mutations were seen in 11.9% of specimens, and resistance-conferring mutations were seen in 71.3% of specimens.
“The bottom line from this report is that next-generation sequencing is an efficient way to identify both approved and promising investigational therapies. For this reason, it should be considered standard of care for patients with advanced cancers,” said study chair Keith T. Flaherty, MD, director of the Henri and Belinda Termeer Center for Targeted Therapy at Massachusetts General Hospital Cancer Center in Boston.
“This study sets the benchmark for the ‘actionability’ of next-generation sequencing,” Dr. Flaherty added. “We expect this number [of actionable alterations] will continue to rise steadily as further advances are made in the development of therapies that target some of the genetic alterations for which we could not offer treatment options in NCI-MATCH.”
Relapsed/refractory vs. primary tumors
The NCI-MATCH researchers focused on the most commonly found genetic alterations and performed biopsies at study entry to provide the most accurate picture of the genetic landscape of relapsed/refractory cancer patients. That makes this cohort distinct from The Cancer Genome Atlas (TCGA), a database of patients with mostly untreated primary tumors, and other published cohorts that include genetic analysis of primary tumors and biopsies from the time of initial metastatic recurrence.
The researchers compared the tumor gene makeup of NCI-MATCH and TCGA patients with seven cancer types – breast, bile duct, cervix, colorectal, lung, pancreas, and prostate.
“Perhaps the biggest surprise was the relatively minimal change in the genetic alterations found in these relapsed/refractory patients, compared to primary tumors,” Dr. Flaherty said. “These findings suggest that it is very reasonable to perform next-generation sequencing at the time of initial metastatic cancer diagnosis and to rely on those findings for the purposes of considering FDA-approved therapies and clinical trial participation.”
Multiple alterations and resistance
The complex genetics of cancers has led researchers to explore combinations of targeted and other therapies to address multiple defects at the same time.
“Not surprisingly, the most common collision of multiple genetic alterations within the same tumor was in the commonly altered tumor suppressor genes: TP53, APC, and PTEN,” Dr. Flaherty said.
“An increasing body of evidence supports a role for loss-of-function alterations in these genes to confer resistance to many targeted therapies,” he added. “While we don’t have targeted therapies yet established to directly counter this form of therapeutic resistance, we hypothesize that various types of combination therapy may be able to indirectly undercut resistance and enhance the benefit of many targeted therapies.”
The NCI-MATCH researchers will continue to mine this large dataset to better understand the many small, genetically defined cancer subpopulations.
“We will continue to report the outcome of the individual treatment subprotocols, and combining this genetic analysis with those outcomes will likely inform the next clinical trials,” Dr. Flaherty said.
Actionable mutations make a difference
Precision oncology experts agree that NCI-MATCH results are impressive and add a fuller appreciation that actionable mutations make a clinical difference.
“This is a powerful, extremely well-designed study, a tour de force of collaborative science,” said Stephen Gruber, MD, PhD, director of the Center for Precision Medicine at City of Hope National Medical Center in Duarte, Calif.
“The future holds even more promise,” he added. “Our ability to interrogate the genomic landscape of cancer is improving rapidly. Tumor testing helps get the right drug to the right tumor faster than a guidelines-based approach from historical data of combination chemotherapy. This is a likely game changer for the way oncologists will practice in the future, especially as we learn more results of subset trials. The NCI-MATCH researchers have taken a laser-focused look at the current data, but we now know we can look far more comprehensively at genomic profiles of tumors.”
From the viewpoint of the practicing oncologist, co-occurring resistance mutations make a difference in defining what combinations are likely and, more importantly, less likely to be effective. “When we see two mutations and one is likely to confer resistance, we can make a choice to avoid a drug that is not likely to work,” Dr. Gruber said.
“The NCI-MATCH trial allows both approved and investigational agents, which expands the possibility of matching patients to newer agents. This is especially relevant if there are no FDA-approved drugs yet for some molecular aberrations,” said Lillian L. Siu, MD, a senior medical oncologist at the Princess Margaret Cancer Centre in Toronto. “This trial enables such evaluations under the auspice of a clinical trial to provide important knowledge.”
Both experts agree that in-depth biological interrogations of cancer will move the field of precision oncology forward. Dr. Gruber said that “studies have not yet fully addressed the power of germline genetic testing of DNA. Inherited susceptibility will drive therapeutic choices – for example, PARP inhibitors that access homologous recombination deficiency for breast, ovarian, and prostate cancer. We will learn more about treatment choices for those cancers.”
Dr. Siu added: “I truly believe that liquid biopsies [circulating tumor DNA] will help us perform target-drug matching in a less invasive way. We need to explore beyond the genome to look at the transcriptome, proteome, epigenome, and immunome, among others. It is likely that multiomic predictors are going to be able to identify more therapeutic options compared to single genomic predictors.”
Dr. Flaherty noted that all tumor samples from patients assigned to treatment are being subjected to whole-exome sequencing to further the discovery of the genetic features of responsive and nonresponsive tumors.
NCI-MATCH was funded by the National Cancer Institute. Dr. Flaherty disclosed relationships with Clovis Oncology, Loxo, X4 Pharma, and many other companies. His coauthors disclosed many conflicts as well. Dr. Gruber is cofounder of Brogent International. Dr. Siu disclosed relationships with Agios, Treadwell Therapeutics, Merck, Pfizer, and many other companies.
SOURCE: Flaherty KT et al. J Clin Oncol. 2020 Oct 13. doi: 10.1200/JCO.19.03010.
The effort is the National Cancer Institute Molecular Analysis for Therapy Choice (NCI-MATCH) trial. For this study, researchers performed next-generation sequencing on tumor biopsy specimens to identify therapeutically actionable molecular alterations in patients with “underexplored” cancer types.
The trial included 5,954 patients with cancers that had progressed on standard treatments or rare cancers for which there is no standard treatment. If actionable alterations were found in these patients, they could receive new drugs in development that showed promise in other clinical trials or drugs that were approved by the Food and Drug Administration to treat at least one cancer type.
Data newly reported in the Journal of Clinical Oncology showed that 37.6% of patients had alterations that could be matched to targeted drugs, and 17.8% of patients were assigned to targeted treatment. Multiple actionable tumor mutations were seen in 11.9% of specimens, and resistance-conferring mutations were seen in 71.3% of specimens.
“The bottom line from this report is that next-generation sequencing is an efficient way to identify both approved and promising investigational therapies. For this reason, it should be considered standard of care for patients with advanced cancers,” said study chair Keith T. Flaherty, MD, director of the Henri and Belinda Termeer Center for Targeted Therapy at Massachusetts General Hospital Cancer Center in Boston.
“This study sets the benchmark for the ‘actionability’ of next-generation sequencing,” Dr. Flaherty added. “We expect this number [of actionable alterations] will continue to rise steadily as further advances are made in the development of therapies that target some of the genetic alterations for which we could not offer treatment options in NCI-MATCH.”
Relapsed/refractory vs. primary tumors
The NCI-MATCH researchers focused on the most commonly found genetic alterations and performed biopsies at study entry to provide the most accurate picture of the genetic landscape of relapsed/refractory cancer patients. That makes this cohort distinct from The Cancer Genome Atlas (TCGA), a database of patients with mostly untreated primary tumors, and other published cohorts that include genetic analysis of primary tumors and biopsies from the time of initial metastatic recurrence.
The researchers compared the tumor gene makeup of NCI-MATCH and TCGA patients with seven cancer types – breast, bile duct, cervix, colorectal, lung, pancreas, and prostate.
“Perhaps the biggest surprise was the relatively minimal change in the genetic alterations found in these relapsed/refractory patients, compared to primary tumors,” Dr. Flaherty said. “These findings suggest that it is very reasonable to perform next-generation sequencing at the time of initial metastatic cancer diagnosis and to rely on those findings for the purposes of considering FDA-approved therapies and clinical trial participation.”
Multiple alterations and resistance
The complex genetics of cancers has led researchers to explore combinations of targeted and other therapies to address multiple defects at the same time.
“Not surprisingly, the most common collision of multiple genetic alterations within the same tumor was in the commonly altered tumor suppressor genes: TP53, APC, and PTEN,” Dr. Flaherty said.
“An increasing body of evidence supports a role for loss-of-function alterations in these genes to confer resistance to many targeted therapies,” he added. “While we don’t have targeted therapies yet established to directly counter this form of therapeutic resistance, we hypothesize that various types of combination therapy may be able to indirectly undercut resistance and enhance the benefit of many targeted therapies.”
The NCI-MATCH researchers will continue to mine this large dataset to better understand the many small, genetically defined cancer subpopulations.
“We will continue to report the outcome of the individual treatment subprotocols, and combining this genetic analysis with those outcomes will likely inform the next clinical trials,” Dr. Flaherty said.
Actionable mutations make a difference
Precision oncology experts agree that NCI-MATCH results are impressive and add a fuller appreciation that actionable mutations make a clinical difference.
“This is a powerful, extremely well-designed study, a tour de force of collaborative science,” said Stephen Gruber, MD, PhD, director of the Center for Precision Medicine at City of Hope National Medical Center in Duarte, Calif.
“The future holds even more promise,” he added. “Our ability to interrogate the genomic landscape of cancer is improving rapidly. Tumor testing helps get the right drug to the right tumor faster than a guidelines-based approach from historical data of combination chemotherapy. This is a likely game changer for the way oncologists will practice in the future, especially as we learn more results of subset trials. The NCI-MATCH researchers have taken a laser-focused look at the current data, but we now know we can look far more comprehensively at genomic profiles of tumors.”
From the viewpoint of the practicing oncologist, co-occurring resistance mutations make a difference in defining what combinations are likely and, more importantly, less likely to be effective. “When we see two mutations and one is likely to confer resistance, we can make a choice to avoid a drug that is not likely to work,” Dr. Gruber said.
“The NCI-MATCH trial allows both approved and investigational agents, which expands the possibility of matching patients to newer agents. This is especially relevant if there are no FDA-approved drugs yet for some molecular aberrations,” said Lillian L. Siu, MD, a senior medical oncologist at the Princess Margaret Cancer Centre in Toronto. “This trial enables such evaluations under the auspice of a clinical trial to provide important knowledge.”
Both experts agree that in-depth biological interrogations of cancer will move the field of precision oncology forward. Dr. Gruber said that “studies have not yet fully addressed the power of germline genetic testing of DNA. Inherited susceptibility will drive therapeutic choices – for example, PARP inhibitors that access homologous recombination deficiency for breast, ovarian, and prostate cancer. We will learn more about treatment choices for those cancers.”
Dr. Siu added: “I truly believe that liquid biopsies [circulating tumor DNA] will help us perform target-drug matching in a less invasive way. We need to explore beyond the genome to look at the transcriptome, proteome, epigenome, and immunome, among others. It is likely that multiomic predictors are going to be able to identify more therapeutic options compared to single genomic predictors.”
Dr. Flaherty noted that all tumor samples from patients assigned to treatment are being subjected to whole-exome sequencing to further the discovery of the genetic features of responsive and nonresponsive tumors.
NCI-MATCH was funded by the National Cancer Institute. Dr. Flaherty disclosed relationships with Clovis Oncology, Loxo, X4 Pharma, and many other companies. His coauthors disclosed many conflicts as well. Dr. Gruber is cofounder of Brogent International. Dr. Siu disclosed relationships with Agios, Treadwell Therapeutics, Merck, Pfizer, and many other companies.
SOURCE: Flaherty KT et al. J Clin Oncol. 2020 Oct 13. doi: 10.1200/JCO.19.03010.
The effort is the National Cancer Institute Molecular Analysis for Therapy Choice (NCI-MATCH) trial. For this study, researchers performed next-generation sequencing on tumor biopsy specimens to identify therapeutically actionable molecular alterations in patients with “underexplored” cancer types.
The trial included 5,954 patients with cancers that had progressed on standard treatments or rare cancers for which there is no standard treatment. If actionable alterations were found in these patients, they could receive new drugs in development that showed promise in other clinical trials or drugs that were approved by the Food and Drug Administration to treat at least one cancer type.
Data newly reported in the Journal of Clinical Oncology showed that 37.6% of patients had alterations that could be matched to targeted drugs, and 17.8% of patients were assigned to targeted treatment. Multiple actionable tumor mutations were seen in 11.9% of specimens, and resistance-conferring mutations were seen in 71.3% of specimens.
“The bottom line from this report is that next-generation sequencing is an efficient way to identify both approved and promising investigational therapies. For this reason, it should be considered standard of care for patients with advanced cancers,” said study chair Keith T. Flaherty, MD, director of the Henri and Belinda Termeer Center for Targeted Therapy at Massachusetts General Hospital Cancer Center in Boston.
“This study sets the benchmark for the ‘actionability’ of next-generation sequencing,” Dr. Flaherty added. “We expect this number [of actionable alterations] will continue to rise steadily as further advances are made in the development of therapies that target some of the genetic alterations for which we could not offer treatment options in NCI-MATCH.”
Relapsed/refractory vs. primary tumors
The NCI-MATCH researchers focused on the most commonly found genetic alterations and performed biopsies at study entry to provide the most accurate picture of the genetic landscape of relapsed/refractory cancer patients. That makes this cohort distinct from The Cancer Genome Atlas (TCGA), a database of patients with mostly untreated primary tumors, and other published cohorts that include genetic analysis of primary tumors and biopsies from the time of initial metastatic recurrence.
The researchers compared the tumor gene makeup of NCI-MATCH and TCGA patients with seven cancer types – breast, bile duct, cervix, colorectal, lung, pancreas, and prostate.
“Perhaps the biggest surprise was the relatively minimal change in the genetic alterations found in these relapsed/refractory patients, compared to primary tumors,” Dr. Flaherty said. “These findings suggest that it is very reasonable to perform next-generation sequencing at the time of initial metastatic cancer diagnosis and to rely on those findings for the purposes of considering FDA-approved therapies and clinical trial participation.”
Multiple alterations and resistance
The complex genetics of cancers has led researchers to explore combinations of targeted and other therapies to address multiple defects at the same time.
“Not surprisingly, the most common collision of multiple genetic alterations within the same tumor was in the commonly altered tumor suppressor genes: TP53, APC, and PTEN,” Dr. Flaherty said.
“An increasing body of evidence supports a role for loss-of-function alterations in these genes to confer resistance to many targeted therapies,” he added. “While we don’t have targeted therapies yet established to directly counter this form of therapeutic resistance, we hypothesize that various types of combination therapy may be able to indirectly undercut resistance and enhance the benefit of many targeted therapies.”
The NCI-MATCH researchers will continue to mine this large dataset to better understand the many small, genetically defined cancer subpopulations.
“We will continue to report the outcome of the individual treatment subprotocols, and combining this genetic analysis with those outcomes will likely inform the next clinical trials,” Dr. Flaherty said.
Actionable mutations make a difference
Precision oncology experts agree that NCI-MATCH results are impressive and add a fuller appreciation that actionable mutations make a clinical difference.
“This is a powerful, extremely well-designed study, a tour de force of collaborative science,” said Stephen Gruber, MD, PhD, director of the Center for Precision Medicine at City of Hope National Medical Center in Duarte, Calif.
“The future holds even more promise,” he added. “Our ability to interrogate the genomic landscape of cancer is improving rapidly. Tumor testing helps get the right drug to the right tumor faster than a guidelines-based approach from historical data of combination chemotherapy. This is a likely game changer for the way oncologists will practice in the future, especially as we learn more results of subset trials. The NCI-MATCH researchers have taken a laser-focused look at the current data, but we now know we can look far more comprehensively at genomic profiles of tumors.”
From the viewpoint of the practicing oncologist, co-occurring resistance mutations make a difference in defining what combinations are likely and, more importantly, less likely to be effective. “When we see two mutations and one is likely to confer resistance, we can make a choice to avoid a drug that is not likely to work,” Dr. Gruber said.
“The NCI-MATCH trial allows both approved and investigational agents, which expands the possibility of matching patients to newer agents. This is especially relevant if there are no FDA-approved drugs yet for some molecular aberrations,” said Lillian L. Siu, MD, a senior medical oncologist at the Princess Margaret Cancer Centre in Toronto. “This trial enables such evaluations under the auspice of a clinical trial to provide important knowledge.”
Both experts agree that in-depth biological interrogations of cancer will move the field of precision oncology forward. Dr. Gruber said that “studies have not yet fully addressed the power of germline genetic testing of DNA. Inherited susceptibility will drive therapeutic choices – for example, PARP inhibitors that access homologous recombination deficiency for breast, ovarian, and prostate cancer. We will learn more about treatment choices for those cancers.”
Dr. Siu added: “I truly believe that liquid biopsies [circulating tumor DNA] will help us perform target-drug matching in a less invasive way. We need to explore beyond the genome to look at the transcriptome, proteome, epigenome, and immunome, among others. It is likely that multiomic predictors are going to be able to identify more therapeutic options compared to single genomic predictors.”
Dr. Flaherty noted that all tumor samples from patients assigned to treatment are being subjected to whole-exome sequencing to further the discovery of the genetic features of responsive and nonresponsive tumors.
NCI-MATCH was funded by the National Cancer Institute. Dr. Flaherty disclosed relationships with Clovis Oncology, Loxo, X4 Pharma, and many other companies. His coauthors disclosed many conflicts as well. Dr. Gruber is cofounder of Brogent International. Dr. Siu disclosed relationships with Agios, Treadwell Therapeutics, Merck, Pfizer, and many other companies.
SOURCE: Flaherty KT et al. J Clin Oncol. 2020 Oct 13. doi: 10.1200/JCO.19.03010.
FROM THE JOURNAL OF CLINICAL ONCOLOGY