catch the disease

The institute's scientists located a molecule that irreversibly attaches to a protein that contributes to the development of malignant tumors. Their findings may lead to the creation of a new cancer drug

Cancerous brain tumor. Illustration: depositphotos.com
Cancerous brain tumor. Illustration: depositphotos.com

Most drugs, from paracetamol to cancer drugs, are based on molecules that move through the body, bind to proteins and help prevent or fight diseases. However, the connections between the molecules that are introduced into the body and between the proteins last for short periods of time, so their effectiveness may be limited. The laboratory of Dr Near London, from the Department of Structural and Chemical Biology at the Weizmann Institute of Science, specializes in the detection of molecules of a special type - those that bind to proteins throughout their lifetime, lasting from a few hours to a few days. This irreversible adhesion may strengthen the effect of the molecule.

בNew research, the researchers from Dr. London's laboratory focused on a protein known as Pin1, which has been known for years as playing a role in the development of various types of cancer. Researchers have previously shown that if you genetically inhibit the creation of the protein, you can prevent cancerous tumors. However, attempts are being made to find molecules that are able to bind to the protein and disrupting its activity - and from which it is possible to create a drug - did not succeed. One of the reasons for this is that Pin1 has evolved so that it easily binds to other proteins, and therefore Characterized by a smooth and flat surface, which makes it difficult for drugs to connect to it.

Magnetic resonance imaging of a neuroblastoma cancer model in mice (the tumor tissue is indicated by a dashed line). In the bottom row: after seven days of treatment with sulfofene the tumor shrunk, compared to its growth in the control group (top row)
Magnetic resonance imaging of a neuroblastoma cancer model in mice (the tumor tissue is indicated by a dashed line). In the bottom row: after seven days of treatment with sulfofene the tumor shrunk, compared to its growth in the control group (top row)

The researchers hypothesized that if they found a molecule that would irreversibly bind to Pin1 and disrupt its activity, it might prevent it from supporting the disease in two ways: it would not encourage other proteins that accelerate growth and it would not inhibit proteins that are able to fight cancer. Prof. Nathaniel Gray from the Dana Farber Cancer Research Institute in Boston and Prof. Kun Ping Lu from Harvard University Medical School also participated in the study.

To find the appropriate molecule, hundreds of potential candidates were scanned until those capable of binding to the protein were found. From the group of suitable molecules, the researchers were able to identify one that turned out to be particularly good. The indicators for this are the ability of the molecule to bind effectively to the target protein, but without disrupting the activity of other proteins in a way that could be toxic to the body.

In the long search for the molecules, the researchers were helped by methods that make it possible to follow, in the laboratory and in living cells, the irreversible microscopic connections between the molecules and proteins and to test their function in different situations. Upon finding the most effective molecule, the name Sulfopin was affixed to it - a cross between Sulfolane - the name of a chemical group that was discovered in some of the molecules bound to Pin1 - and the name of the protein itself.

Later, the researchers conducted experiments that focused on two types of cancer that Pin1 is known to contribute to their development: brain cancer of a type that is mostly common in children and pancreatic cancer. Initially, the experiments were conducted on cells in the laboratory, and it was discovered that the effect of the molecule is relatively small in the first few days, but after about a week its effect accumulates and increases - and it manages to significantly delay the rate of cell division. Later, experiments were conducted using a cancer model in mice and fish, and it became clear that thanks to the molecule's effect on Pin1 and other proteins it activates, the development of tumors in these animals was significantly inhibited, and they survived longer.

In order to promote the possibility of translating the scientific findings to the clinic, the company registered "knowledge", an arm of the intellectual property commercialization of the institute's scientists, a patent for the molecule that is already generating interest among biotech companies that are considering investing in preclinical research. However, it is important to note that the road to the hospital bed is still long: on average, more than a decade of research and development work is required and an investment of 2- 1 billion dollars - with very small chances of success - to reach, perhaps, the desired goal: creating a new cure for cancer.

Researchers from the London Cancer Research Center, Saarland University in Germany, Portland University of Health and Science, Peking University in Beijing, Mount Sinai Hospital in New York, Boston Children's Hospital and Stanford University participated in the study. The research was led by Dr. Christian Dubiala, a postdoctoral researcher from Dr. London's lab, and Dr. Benica Finch, a research student in Prof. Gray's lab.

More of the topic in Hayadan: