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Why Does the Heart Rarely Develop Cancer?
The heart is one of the organs least likely to develop cancer, a long-standing biologic puzzle that may now have an explanation. A study published in Science found that the mechanical load generated by the beating heart suppresses tumor cell proliferation through a molecular pathway that alters gene expression, raising the possibility of new therapeutic targets.
Mechanical Protection
Tumors that originate directly in the myocardium are exceptionally rare, occurring in < 1% of autopsies. Even cardiac metastases, which have been reported in up to 18% of autopsies, are often small, asymptomatic, and incidentally discovered. Although this phenomenon has long been recognized, its biologic basis remains unclear.
The heart is notable for its limited capacity for regeneration. After birth, cardiomyocytes stop dividing and subsequently renew at a rate of about 1% per year. However, when the mechanical load is reduced, such as in patients supported by left ventricular assist devices, cardiomyocytes once again show signs of proliferation.
This observation prompted researchers to investigate whether the same mechanical load that restrains normal cardiac cells might also suppress cancer growth.
More Load, Less Growth
To investigate this question, researchers introduced two genetic alterations commonly found in human cancers, activation of the KRAS oncogene and loss of the TP53, into the liver, skeletal muscle, and hearts of mice. Tumors developed in multiple organs, but not in the heart.
The researchers then used a heterotopic heart transplant model in which a donor mouse’s heart is surgically connected to the neck (cervical) or abdominal vessels of a recipient mouse. The transplanted heart remained perfused but lost its normal mechanical loading (constant beating).
When researchers injected lung adenocarcinoma cells into 2 different hearts of the same animal, they observed entirely different outcomes. The cancer cells did not grow in the native mechanically loaded heart. However, the same cells grew rapidly and extensively in the mechanically unloaded transplanted heart.
Tumor cells had replaced nearly all normal tissue in the unloaded heart, whereas they occupied only approximately 20% of the ventricle in the native heart in 14 days. This difference could not be explained by differences in the initial tumor engraftment or cell death. Instead, the findings pointed to substantial differences in tumor cell proliferation.
Similar results were observed in bioengineered cardiac tissues exposed to varying degrees of mechanical stress. Tumor cells proliferated under conditions of low mechanical load but ceased proliferating as the mechanical load increased. Tumor growth was lowest in regions exposed to the greatest mechanical stimulation of cardiomyocytes in vitro.
However, the possibility of metabolic competition between cardiac and tumor cells for nutrition was ruled out.
From Mechanics to Genes
Next, we examined the influence of mechanical forces on tumor cell behavior.
Gene expression analyses of both human cardiac metastases and mouse tumor cells showed that mechanical stimulation altered chromatin accessibility through the activation of genes involved in chromatin remodeling. These changes promoted the expression of genes that suppress cell division.
The study also identified Nesprin-2, a part of the linker of the nucleoskeleton and cytoskeleton complex, which acts as a physical bridge. It is a multitasking protein that connects the cell’s outer structural network (cytoskeleton) to its inner genetic storage (nucleus) and appears to play a significant role in converting mechanical signals into changes in gene expression.
When Nesprin-2 was inactivated, cancer cells resumed proliferation despite exposure to a mechanical load, both in engineered tissues and animal models.
“Collectively, these results shed light on the role of mechanical forces in protecting the heart from cancer and may pave the way to cancer therapies based on mechanical stimulation,” concluded the authors.
An Actively Protected Organ
Speaking with Univadis Italy, part of the Medscape Professional Network, Giorgio Scita, PhD, director of the Mechanisms of Tumor Cell Migration research unit at AIRC Institute of Molecular Oncology and professor of general pathology at the University of Milan in Milan, Italy, said, “The study addressed a simple but fundamental question: Why is the heart largely resistant to cancer despite being highly vascularized and continuously exposed to circulating tumor cells?
These findings suggest that the heartbeat itself creates a mechanical environment that is hostile to tumor growth. The compressive forces generated by rhythmic myocardial contraction are sensed by cancer cells and translated into biochemical signals that limit their proliferation.
In this view, the heart is not simply an organ that is unfavorable for cancer growth but a tissue actively protected by its own mechanical forces.”
Speaking with Univadis Italy, Serena Zacchigna, PhD, study coauthor and head of the Cardiovascular Biology Laboratory at the International Centre for Genetic Engineering and Biotechnology, Trieste, Italy, said, “Until now, however, attention had focused primarily on signals from the extracellular matrix, such as tissue stiffness. Our study adds a new element: even forces generated directly by the movement of an organ — in this case, cardiac contraction — can influence the growth of cancer cells.”
Beyond the Heart
Scita said the findings have implications that extend well beyond the heart.
“The most significant aspect is that this work identifies tissue mechanics as an active regulator of tumor behavior,” he said. Stiffness, compression, tension, and confinement are not merely consequences of tumor growth, but factors capable of influencing proliferation, invasion, and dormancy.
The concept may apply to many solid tumors. Scita noted that cancer cells growing in confined environments, such as ductal carcinoma in situ of the breast, are exposed to substantial mechanical constraints. Understanding why some tumor cells remain susceptible to these forces whereas others evade them and become invasive remains a major unanswered question in cancer biology.
Research on these mechanisms is expanding internationally and in Italy as well. One example is the AIRC “5 per mille” (5 per thousand) research programs on metastatic disease, which includes projects designed to clarify how the mechanical properties of tumor tissue influence cancer initiation, metastatic spread, and disease progression.
Therapeutic Potential
According to Zacchigna, these findings open 2 principal avenues for future research.
“The first focuses on mechanical stimulation itself. In collaboration with engineers at the University of Siena, including a group led by Domenico Prattichizzo, researchers are developing wearable robotic devices designed to mimic the heartbeat and deliver mechanical stimulation to superficial solid tumors such as certain skin cancers.
The second approach is pharmacology. Researchers are investigating whether epigenetic therapies capable of modifying chromatin remodeling can reproduce the effects of cardiac contraction and suppress tumor cell proliferation.
However, Zacchigna cautioned that this work remains at an early experimental phase.”
However, before therapeutic applications can be pursued, important mechanistic questions remain unanswered.
Zacchigna noted that although the linker of nucleoskeleton and cytoskeleton (LINC) complex and Nesprin-2 are involved in signal transduction leading to chromatin reorganization and activation of cell cycle inhibitory loci, the molecular intermediates involved have yet to be fully defined.
Researchers also need to determine which genes are most critical, whether the mechanism operates across different tumor types, and whether it can be safely manipulated for therapeutic purposes.
In an accompanying commentary published in Science, Wyatt G. Paltzer, PhD, and James F. Martin, MD, from the Department of Integrative Physiology at the Baylor College of Medicine in Houston, noted that the findings suggest enhancing LINC complex activity could potentially suppress tumor growth.
However, because the complex has broad biologic functions, it may prove difficult to target therapeutically. The authors suggested that future studies should focus on identifying proteins that interact with Nesprin-2 or other components of the LINC complex and play a more specific role in inhibiting cancer cell proliferation.
Looking Ahead
Despite these challenges, Scita said that the study’s conceptual significance is already clear.
“Even if therapeutic applications remain years away, the findings suggest that cancer may one day be targeted by altering how tumor cells perceive and interpret physical forces.”
Scita and Zacchigna reported having no relevant conflicts of interest.
This story was translated from Univadis Italy.
A version of this article first appeared on Medscape.com.
The heart is one of the organs least likely to develop cancer, a long-standing biologic puzzle that may now have an explanation. A study published in Science found that the mechanical load generated by the beating heart suppresses tumor cell proliferation through a molecular pathway that alters gene expression, raising the possibility of new therapeutic targets.
Mechanical Protection
Tumors that originate directly in the myocardium are exceptionally rare, occurring in < 1% of autopsies. Even cardiac metastases, which have been reported in up to 18% of autopsies, are often small, asymptomatic, and incidentally discovered. Although this phenomenon has long been recognized, its biologic basis remains unclear.
The heart is notable for its limited capacity for regeneration. After birth, cardiomyocytes stop dividing and subsequently renew at a rate of about 1% per year. However, when the mechanical load is reduced, such as in patients supported by left ventricular assist devices, cardiomyocytes once again show signs of proliferation.
This observation prompted researchers to investigate whether the same mechanical load that restrains normal cardiac cells might also suppress cancer growth.
More Load, Less Growth
To investigate this question, researchers introduced two genetic alterations commonly found in human cancers, activation of the KRAS oncogene and loss of the TP53, into the liver, skeletal muscle, and hearts of mice. Tumors developed in multiple organs, but not in the heart.
The researchers then used a heterotopic heart transplant model in which a donor mouse’s heart is surgically connected to the neck (cervical) or abdominal vessels of a recipient mouse. The transplanted heart remained perfused but lost its normal mechanical loading (constant beating).
When researchers injected lung adenocarcinoma cells into 2 different hearts of the same animal, they observed entirely different outcomes. The cancer cells did not grow in the native mechanically loaded heart. However, the same cells grew rapidly and extensively in the mechanically unloaded transplanted heart.
Tumor cells had replaced nearly all normal tissue in the unloaded heart, whereas they occupied only approximately 20% of the ventricle in the native heart in 14 days. This difference could not be explained by differences in the initial tumor engraftment or cell death. Instead, the findings pointed to substantial differences in tumor cell proliferation.
Similar results were observed in bioengineered cardiac tissues exposed to varying degrees of mechanical stress. Tumor cells proliferated under conditions of low mechanical load but ceased proliferating as the mechanical load increased. Tumor growth was lowest in regions exposed to the greatest mechanical stimulation of cardiomyocytes in vitro.
However, the possibility of metabolic competition between cardiac and tumor cells for nutrition was ruled out.
From Mechanics to Genes
Next, we examined the influence of mechanical forces on tumor cell behavior.
Gene expression analyses of both human cardiac metastases and mouse tumor cells showed that mechanical stimulation altered chromatin accessibility through the activation of genes involved in chromatin remodeling. These changes promoted the expression of genes that suppress cell division.
The study also identified Nesprin-2, a part of the linker of the nucleoskeleton and cytoskeleton complex, which acts as a physical bridge. It is a multitasking protein that connects the cell’s outer structural network (cytoskeleton) to its inner genetic storage (nucleus) and appears to play a significant role in converting mechanical signals into changes in gene expression.
When Nesprin-2 was inactivated, cancer cells resumed proliferation despite exposure to a mechanical load, both in engineered tissues and animal models.
“Collectively, these results shed light on the role of mechanical forces in protecting the heart from cancer and may pave the way to cancer therapies based on mechanical stimulation,” concluded the authors.
An Actively Protected Organ
Speaking with Univadis Italy, part of the Medscape Professional Network, Giorgio Scita, PhD, director of the Mechanisms of Tumor Cell Migration research unit at AIRC Institute of Molecular Oncology and professor of general pathology at the University of Milan in Milan, Italy, said, “The study addressed a simple but fundamental question: Why is the heart largely resistant to cancer despite being highly vascularized and continuously exposed to circulating tumor cells?
These findings suggest that the heartbeat itself creates a mechanical environment that is hostile to tumor growth. The compressive forces generated by rhythmic myocardial contraction are sensed by cancer cells and translated into biochemical signals that limit their proliferation.
In this view, the heart is not simply an organ that is unfavorable for cancer growth but a tissue actively protected by its own mechanical forces.”
Speaking with Univadis Italy, Serena Zacchigna, PhD, study coauthor and head of the Cardiovascular Biology Laboratory at the International Centre for Genetic Engineering and Biotechnology, Trieste, Italy, said, “Until now, however, attention had focused primarily on signals from the extracellular matrix, such as tissue stiffness. Our study adds a new element: even forces generated directly by the movement of an organ — in this case, cardiac contraction — can influence the growth of cancer cells.”
Beyond the Heart
Scita said the findings have implications that extend well beyond the heart.
“The most significant aspect is that this work identifies tissue mechanics as an active regulator of tumor behavior,” he said. Stiffness, compression, tension, and confinement are not merely consequences of tumor growth, but factors capable of influencing proliferation, invasion, and dormancy.
The concept may apply to many solid tumors. Scita noted that cancer cells growing in confined environments, such as ductal carcinoma in situ of the breast, are exposed to substantial mechanical constraints. Understanding why some tumor cells remain susceptible to these forces whereas others evade them and become invasive remains a major unanswered question in cancer biology.
Research on these mechanisms is expanding internationally and in Italy as well. One example is the AIRC “5 per mille” (5 per thousand) research programs on metastatic disease, which includes projects designed to clarify how the mechanical properties of tumor tissue influence cancer initiation, metastatic spread, and disease progression.
Therapeutic Potential
According to Zacchigna, these findings open 2 principal avenues for future research.
“The first focuses on mechanical stimulation itself. In collaboration with engineers at the University of Siena, including a group led by Domenico Prattichizzo, researchers are developing wearable robotic devices designed to mimic the heartbeat and deliver mechanical stimulation to superficial solid tumors such as certain skin cancers.
The second approach is pharmacology. Researchers are investigating whether epigenetic therapies capable of modifying chromatin remodeling can reproduce the effects of cardiac contraction and suppress tumor cell proliferation.
However, Zacchigna cautioned that this work remains at an early experimental phase.”
However, before therapeutic applications can be pursued, important mechanistic questions remain unanswered.
Zacchigna noted that although the linker of nucleoskeleton and cytoskeleton (LINC) complex and Nesprin-2 are involved in signal transduction leading to chromatin reorganization and activation of cell cycle inhibitory loci, the molecular intermediates involved have yet to be fully defined.
Researchers also need to determine which genes are most critical, whether the mechanism operates across different tumor types, and whether it can be safely manipulated for therapeutic purposes.
In an accompanying commentary published in Science, Wyatt G. Paltzer, PhD, and James F. Martin, MD, from the Department of Integrative Physiology at the Baylor College of Medicine in Houston, noted that the findings suggest enhancing LINC complex activity could potentially suppress tumor growth.
However, because the complex has broad biologic functions, it may prove difficult to target therapeutically. The authors suggested that future studies should focus on identifying proteins that interact with Nesprin-2 or other components of the LINC complex and play a more specific role in inhibiting cancer cell proliferation.
Looking Ahead
Despite these challenges, Scita said that the study’s conceptual significance is already clear.
“Even if therapeutic applications remain years away, the findings suggest that cancer may one day be targeted by altering how tumor cells perceive and interpret physical forces.”
Scita and Zacchigna reported having no relevant conflicts of interest.
This story was translated from Univadis Italy.
A version of this article first appeared on Medscape.com.
The heart is one of the organs least likely to develop cancer, a long-standing biologic puzzle that may now have an explanation. A study published in Science found that the mechanical load generated by the beating heart suppresses tumor cell proliferation through a molecular pathway that alters gene expression, raising the possibility of new therapeutic targets.
Mechanical Protection
Tumors that originate directly in the myocardium are exceptionally rare, occurring in < 1% of autopsies. Even cardiac metastases, which have been reported in up to 18% of autopsies, are often small, asymptomatic, and incidentally discovered. Although this phenomenon has long been recognized, its biologic basis remains unclear.
The heart is notable for its limited capacity for regeneration. After birth, cardiomyocytes stop dividing and subsequently renew at a rate of about 1% per year. However, when the mechanical load is reduced, such as in patients supported by left ventricular assist devices, cardiomyocytes once again show signs of proliferation.
This observation prompted researchers to investigate whether the same mechanical load that restrains normal cardiac cells might also suppress cancer growth.
More Load, Less Growth
To investigate this question, researchers introduced two genetic alterations commonly found in human cancers, activation of the KRAS oncogene and loss of the TP53, into the liver, skeletal muscle, and hearts of mice. Tumors developed in multiple organs, but not in the heart.
The researchers then used a heterotopic heart transplant model in which a donor mouse’s heart is surgically connected to the neck (cervical) or abdominal vessels of a recipient mouse. The transplanted heart remained perfused but lost its normal mechanical loading (constant beating).
When researchers injected lung adenocarcinoma cells into 2 different hearts of the same animal, they observed entirely different outcomes. The cancer cells did not grow in the native mechanically loaded heart. However, the same cells grew rapidly and extensively in the mechanically unloaded transplanted heart.
Tumor cells had replaced nearly all normal tissue in the unloaded heart, whereas they occupied only approximately 20% of the ventricle in the native heart in 14 days. This difference could not be explained by differences in the initial tumor engraftment or cell death. Instead, the findings pointed to substantial differences in tumor cell proliferation.
Similar results were observed in bioengineered cardiac tissues exposed to varying degrees of mechanical stress. Tumor cells proliferated under conditions of low mechanical load but ceased proliferating as the mechanical load increased. Tumor growth was lowest in regions exposed to the greatest mechanical stimulation of cardiomyocytes in vitro.
However, the possibility of metabolic competition between cardiac and tumor cells for nutrition was ruled out.
From Mechanics to Genes
Next, we examined the influence of mechanical forces on tumor cell behavior.
Gene expression analyses of both human cardiac metastases and mouse tumor cells showed that mechanical stimulation altered chromatin accessibility through the activation of genes involved in chromatin remodeling. These changes promoted the expression of genes that suppress cell division.
The study also identified Nesprin-2, a part of the linker of the nucleoskeleton and cytoskeleton complex, which acts as a physical bridge. It is a multitasking protein that connects the cell’s outer structural network (cytoskeleton) to its inner genetic storage (nucleus) and appears to play a significant role in converting mechanical signals into changes in gene expression.
When Nesprin-2 was inactivated, cancer cells resumed proliferation despite exposure to a mechanical load, both in engineered tissues and animal models.
“Collectively, these results shed light on the role of mechanical forces in protecting the heart from cancer and may pave the way to cancer therapies based on mechanical stimulation,” concluded the authors.
An Actively Protected Organ
Speaking with Univadis Italy, part of the Medscape Professional Network, Giorgio Scita, PhD, director of the Mechanisms of Tumor Cell Migration research unit at AIRC Institute of Molecular Oncology and professor of general pathology at the University of Milan in Milan, Italy, said, “The study addressed a simple but fundamental question: Why is the heart largely resistant to cancer despite being highly vascularized and continuously exposed to circulating tumor cells?
These findings suggest that the heartbeat itself creates a mechanical environment that is hostile to tumor growth. The compressive forces generated by rhythmic myocardial contraction are sensed by cancer cells and translated into biochemical signals that limit their proliferation.
In this view, the heart is not simply an organ that is unfavorable for cancer growth but a tissue actively protected by its own mechanical forces.”
Speaking with Univadis Italy, Serena Zacchigna, PhD, study coauthor and head of the Cardiovascular Biology Laboratory at the International Centre for Genetic Engineering and Biotechnology, Trieste, Italy, said, “Until now, however, attention had focused primarily on signals from the extracellular matrix, such as tissue stiffness. Our study adds a new element: even forces generated directly by the movement of an organ — in this case, cardiac contraction — can influence the growth of cancer cells.”
Beyond the Heart
Scita said the findings have implications that extend well beyond the heart.
“The most significant aspect is that this work identifies tissue mechanics as an active regulator of tumor behavior,” he said. Stiffness, compression, tension, and confinement are not merely consequences of tumor growth, but factors capable of influencing proliferation, invasion, and dormancy.
The concept may apply to many solid tumors. Scita noted that cancer cells growing in confined environments, such as ductal carcinoma in situ of the breast, are exposed to substantial mechanical constraints. Understanding why some tumor cells remain susceptible to these forces whereas others evade them and become invasive remains a major unanswered question in cancer biology.
Research on these mechanisms is expanding internationally and in Italy as well. One example is the AIRC “5 per mille” (5 per thousand) research programs on metastatic disease, which includes projects designed to clarify how the mechanical properties of tumor tissue influence cancer initiation, metastatic spread, and disease progression.
Therapeutic Potential
According to Zacchigna, these findings open 2 principal avenues for future research.
“The first focuses on mechanical stimulation itself. In collaboration with engineers at the University of Siena, including a group led by Domenico Prattichizzo, researchers are developing wearable robotic devices designed to mimic the heartbeat and deliver mechanical stimulation to superficial solid tumors such as certain skin cancers.
The second approach is pharmacology. Researchers are investigating whether epigenetic therapies capable of modifying chromatin remodeling can reproduce the effects of cardiac contraction and suppress tumor cell proliferation.
However, Zacchigna cautioned that this work remains at an early experimental phase.”
However, before therapeutic applications can be pursued, important mechanistic questions remain unanswered.
Zacchigna noted that although the linker of nucleoskeleton and cytoskeleton (LINC) complex and Nesprin-2 are involved in signal transduction leading to chromatin reorganization and activation of cell cycle inhibitory loci, the molecular intermediates involved have yet to be fully defined.
Researchers also need to determine which genes are most critical, whether the mechanism operates across different tumor types, and whether it can be safely manipulated for therapeutic purposes.
In an accompanying commentary published in Science, Wyatt G. Paltzer, PhD, and James F. Martin, MD, from the Department of Integrative Physiology at the Baylor College of Medicine in Houston, noted that the findings suggest enhancing LINC complex activity could potentially suppress tumor growth.
However, because the complex has broad biologic functions, it may prove difficult to target therapeutically. The authors suggested that future studies should focus on identifying proteins that interact with Nesprin-2 or other components of the LINC complex and play a more specific role in inhibiting cancer cell proliferation.
Looking Ahead
Despite these challenges, Scita said that the study’s conceptual significance is already clear.
“Even if therapeutic applications remain years away, the findings suggest that cancer may one day be targeted by altering how tumor cells perceive and interpret physical forces.”
Scita and Zacchigna reported having no relevant conflicts of interest.
This story was translated from Univadis Italy.
A version of this article first appeared on Medscape.com.
Why Does the Heart Rarely Develop Cancer?
Why Does the Heart Rarely Develop Cancer?