Novel delivery system could treat MCL

Micrograph showing MCL

Researchers say they have developed a system for delivering therapy at the site of mantle cell lymphoma (MCL).

The system harnesses nanoparticles coated with “GPS” antibodies that navigate toward cancerous cells, where they offload cyclin D1-blockers in the form of small interfering RNAs (siRNAs).

Experiments showed the system can halt the proliferation of cyclin D1 in both animal models and samples from MCL patients.

Dan Peer, PhD, of Tel Aviv University in Israel, and his colleagues reported these results in PNAS.

“MCL has a genetic hallmark,” Dr Peer noted. “In 85% of cases, the characteristic that defines this aggressive and prototypic B-cell lymphoma is the heightened activity of the gene CCND1, which leads to the extreme overexpression—a 3000- to 15,000-fold increase—of cyclin D1, a protein that controls the proliferation of cells. Downregulation of cyclin D1 using siRNAs is a potential therapeutic approach to this malignancy.”

For this research, Dr Peer and his colleagues designed lipid-based nanoparticles (LNPs) coated with anti-CD38 monoclonal antibodies that were taken up by human MCL cells in the bone marrow of affected mice.

When loaded with siRNAs against cyclin D1, the targeting LNPs induced gene silencing in MCL cells and prolonged the survival of tumor-bearing mice, with no observed adverse effects.

“In MCL, cyclin D1 is the exclusive cause of the overproduction of B lymphocytes, the cells responsible for generating antibodies,” Dr Peer said. “This makes the protein a perfect target for RNA therapy by siRNAs.”

“Normal, healthy cells don’t express the gene, so therapies that destroy the gene will only attack cancer cells. The RNA interference we have developed targets the faulty cyclin D1 within the cancerous cells. And when the cells are inhibited from proliferating, they sense they are being targeted and begin to die off.”

Dr Peer and his colleagues believe this work presents new opportunities for treating MCL and other similar B-cell malignancies.

“This research makes a definite contribution to the revolution of personalized medicine, whereby you tailor the drug based on the genetic profile of patient,” Dr Peer said. “In this case, MCL is a disease with a specific genetic hallmark, so you can sequence the patient to identify the mutation(s) and design RNA blockers to be placed inside a nanovehicle.”

“While the targeting antibodies—the ‘GPS’—can be used to target many different B-cell malignancies, the drug itself is designed to silence this specific disease. However, the delivery system can be used to accommodate any disease with a genetic profile. This could be the future. We are seeing it happen before our very eyes.”

Micrograph showing MCL

Researchers say they have developed a system for delivering therapy at the site of mantle cell lymphoma (MCL).

The system harnesses nanoparticles coated with “GPS” antibodies that navigate toward cancerous cells, where they offload cyclin D1-blockers in the form of small interfering RNAs (siRNAs).

Experiments showed the system can halt the proliferation of cyclin D1 in both animal models and samples from MCL patients.

Dan Peer, PhD, of Tel Aviv University in Israel, and his colleagues reported these results in PNAS.

“MCL has a genetic hallmark,” Dr Peer noted. “In 85% of cases, the characteristic that defines this aggressive and prototypic B-cell lymphoma is the heightened activity of the gene CCND1, which leads to the extreme overexpression—a 3000- to 15,000-fold increase—of cyclin D1, a protein that controls the proliferation of cells. Downregulation of cyclin D1 using siRNAs is a potential therapeutic approach to this malignancy.”

For this research, Dr Peer and his colleagues designed lipid-based nanoparticles (LNPs) coated with anti-CD38 monoclonal antibodies that were taken up by human MCL cells in the bone marrow of affected mice.

When loaded with siRNAs against cyclin D1, the targeting LNPs induced gene silencing in MCL cells and prolonged the survival of tumor-bearing mice, with no observed adverse effects.

“In MCL, cyclin D1 is the exclusive cause of the overproduction of B lymphocytes, the cells responsible for generating antibodies,” Dr Peer said. “This makes the protein a perfect target for RNA therapy by siRNAs.”

“Normal, healthy cells don’t express the gene, so therapies that destroy the gene will only attack cancer cells. The RNA interference we have developed targets the faulty cyclin D1 within the cancerous cells. And when the cells are inhibited from proliferating, they sense they are being targeted and begin to die off.”

Dr Peer and his colleagues believe this work presents new opportunities for treating MCL and other similar B-cell malignancies.

“This research makes a definite contribution to the revolution of personalized medicine, whereby you tailor the drug based on the genetic profile of patient,” Dr Peer said. “In this case, MCL is a disease with a specific genetic hallmark, so you can sequence the patient to identify the mutation(s) and design RNA blockers to be placed inside a nanovehicle.”

“While the targeting antibodies—the ‘GPS’—can be used to target many different B-cell malignancies, the drug itself is designed to silence this specific disease. However, the delivery system can be used to accommodate any disease with a genetic profile. This could be the future. We are seeing it happen before our very eyes.”

Micrograph showing MCL

Researchers say they have developed a system for delivering therapy at the site of mantle cell lymphoma (MCL).

The system harnesses nanoparticles coated with “GPS” antibodies that navigate toward cancerous cells, where they offload cyclin D1-blockers in the form of small interfering RNAs (siRNAs).

Experiments showed the system can halt the proliferation of cyclin D1 in both animal models and samples from MCL patients.

Dan Peer, PhD, of Tel Aviv University in Israel, and his colleagues reported these results in PNAS.

“MCL has a genetic hallmark,” Dr Peer noted. “In 85% of cases, the characteristic that defines this aggressive and prototypic B-cell lymphoma is the heightened activity of the gene CCND1, which leads to the extreme overexpression—a 3000- to 15,000-fold increase—of cyclin D1, a protein that controls the proliferation of cells. Downregulation of cyclin D1 using siRNAs is a potential therapeutic approach to this malignancy.”

For this research, Dr Peer and his colleagues designed lipid-based nanoparticles (LNPs) coated with anti-CD38 monoclonal antibodies that were taken up by human MCL cells in the bone marrow of affected mice.

When loaded with siRNAs against cyclin D1, the targeting LNPs induced gene silencing in MCL cells and prolonged the survival of tumor-bearing mice, with no observed adverse effects.

“In MCL, cyclin D1 is the exclusive cause of the overproduction of B lymphocytes, the cells responsible for generating antibodies,” Dr Peer said. “This makes the protein a perfect target for RNA therapy by siRNAs.”

“Normal, healthy cells don’t express the gene, so therapies that destroy the gene will only attack cancer cells. The RNA interference we have developed targets the faulty cyclin D1 within the cancerous cells. And when the cells are inhibited from proliferating, they sense they are being targeted and begin to die off.”

Dr Peer and his colleagues believe this work presents new opportunities for treating MCL and other similar B-cell malignancies.

“This research makes a definite contribution to the revolution of personalized medicine, whereby you tailor the drug based on the genetic profile of patient,” Dr Peer said. “In this case, MCL is a disease with a specific genetic hallmark, so you can sequence the patient to identify the mutation(s) and design RNA blockers to be placed inside a nanovehicle.”

“While the targeting antibodies—the ‘GPS’—can be used to target many different B-cell malignancies, the drug itself is designed to silence this specific disease. However, the delivery system can be used to accommodate any disease with a genetic profile. This could be the future. We are seeing it happen before our very eyes.”