Gene Therapy Approach for Sickle Cell Anemia and Beta-thalassemia

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Short:

  • Scientists designed a gene therapy for treating Beta-thalassemia disease (i.e. Anemia of Mediterranean Sea) and sickle cell anemia. They have also developed a test to predict patient response before treatment.
  • These diseases are due to the absence of a gene that produces the Beta-globin protein (a main component in the hemoglobin structure) in the case of beta-thalassemia and production of abnormal Beta-globin in the sickle cell anemia.
  • The main principle in this gene therapy is adding the Beta-globin gene to the stem cells of the bone marrow (the main site or RBCs production) in the case of beta-thalassemia or replacing the abnormal genes in the case of sickle cell anemia.
  • This is done by hooking an “ankyrin insulator” to the beta-globin gene that is carried by a lentivirus vector.
  • The vector is then incorporate the Beta-globin gene into the DNA of the stem cells and thus produce normal and healthy Beta-globin during DNA expression.

NOTES:

  • Ankrin: is a protein mainly responsible for attaching the spectrin cytoskeleton to the red blood cell plasma membrane.
  • Spectrin: is a cytoskeletal protein that lines the intracellular side of the plasma membrane of many cell types in pentagonal or hexagonal arrangements, forming a scaffolding and playing an important role in maintenance of plasma membrane integrity and cytoskeletal structure

Details:

A team of researchers led by scientists at Weill Cornell Medical College has designed what appears to be a powerful gene therapy strategy that can treat both beta-thalassemia disease and sickle cell anemia. They have also developed a test to predict patient response before treatment.

This study’s findings, published in PLoS ONE, represents a new approach to treating these related, and serious, red blood cells disorders, say the investigators.

“This gene therapy technique has the potential to cure many patients, especially if we prescreen them to predict their response using just a few of their cells in a test tube,” says the study’s lead investigator, Dr. Stefano Rivella, Ph.D., an associate professor of genetic medicine at Weill Cornell Medical College. He led a team of 17 researchers in three countries.

Dr. Rivella says this is the first time, investigators have been able to correlate the outcome of transferring a healthy beta-globin gene into diseased cells with increased production of normal hemoglobin — which has long been a barrier to effective treatment of these diseases.

So far, only one patient in France has been treated with gene therapy for beta-thalassemia, and Dr. Rivella and his colleagues believe the new treatment they developed will be a significant improvement. No known patient has received gene therapy yet to treat sickle cell anemia.

A Fresh Approach to Gene Therapy

Beta-thalassemia is an inherited disease caused by defects in the beta-globin gene. This gene produces an essential part of the hemoglobin protein, which, in the form of red blood cells, carries life-sustaining oxygen throughout the body.


The new gene transfer technique developed by Dr. Rivella and his colleagues ensures that the beta-globin gene that is delivered will be active, and that it will also provide more curative beta-globin protein. “Since the defect in thalassemia is lack of production of beta-globin protein in red blood cells, this is very important,” Dr. Rivella says.

The researchers achieved this advance by hooking an “ankyrin insulator” to the beta-globin gene that is carried by a lentivirus vector. During the gene transfer, this vector would be inserted into bone marrow stem cells taken from patients, and then delivered back via a bone marrow transplant. The stem cells would then produce healthy beta-globin protein and hemoglobin.

This ankyrin insulator achieves two goals. First, it protects delivery of the normal beta-globin gene. “In many gene therapy applications, a curative gene is introduced into the cells of patients in an indiscriminate fashion,” Dr. Rivella explains.The gene lands randomly in the genome of the patient, but where it lands is very important because not all regions of the genome are the same.” For example, some therapeutic genes may land in an area of the genome that is normally silenced — meaning the genes in this area are not expressed. “The role of ankyrin insulator is to create an active area in the genome where the new gene can work efficiently no matter where it lands,” Dr. Rivella says. He adds that the small insulator used in his vector should eliminate the kind of side effects seen in the French patient treated with beta-thalassemia gene therapy.

The research team also discovered that the insulator increases the efficiency by which the beta-globin gene is transcribed during the process of making the red blood cells. “We found the gene is integrated into cells which have not yet begun to make red blood cells, and when they do, the beta-globin gene is activated,” Dr. Rivella says. “We showed that if the insulator is present, activation of the curative gene is more efficient. This provides more curative protein to red blood cells.”

The study further provides evidence that the vector had different rates of efficiency depending on the beta-thalassemia mutation it was used in — thus providing the basis for a predictive test in patients. The investigators tested 19 different beta-thalassemia samples comprising the two types commonly found in patients — “beta-zero” cells that do not produce any beta-globin (forcing patients to receive blood transfusions throughout life), and “beta-plus” cells that produce suboptimal levels of hemoglobin. On average, they found that one copy of the vector in beta-zero cells produced 55 percent of the adult hemoglobin seen in normal individuals. Beta-plus cells, after treatment, produced hemoglobin comparable to a healthy individual, and were thus cured.

“The variable nature of the beta-thalassemia mutations suggests that some patients would be better candidates for gene therapy than others, and that success of gene therapy depends on the ability of a specific vector to make hemoglobin,” Dr. Rivella says. “This is something we can test in advance using a little bit of a patient’s blood — which is quite extraordinary.”

The issue in sickle cell anemia is very different, Dr. Rivella says. The hemoglobin protein is made in the right quantities, but it is not normal — the red cell is shaped like a sickle and is abnormal in function. “One of the problem in gene therapy of sickle cell anemia is to add a new gene without increasing too much the total amount of protein, both normal and sickle. This would cause other problems,” he says.

By treating eight cell specimens taken from sickle cell anemia patients, the investigators discovered that attaching the ankyrin insulator to a normal beta-globin gene increases the amount of normal beta globin protein while reducing the quantity of sickled protein. “The total amount of protein stays the same, which is very important,” says first author Dr. Laura Breda, pediatric research associate at Weill Cornell Medical College.

The researchers say that their advances will likely make a substantial impact on a number of fields, including gene regulation and transfer and the design of gene therapy trials. “This study represents a fresh departure from previously published work in the field of gene therapy,” Dr. Rivella says.

The study was funded by the Cooley’s Anemia Foundation (CAF), the Veneta Association for the Fight Against Thalassemia (Italy), the Carlo and Micol Schejola Foundation, the Children’s Cancer and Blood Foundation, the Clinical and Translational Science Center, Telethon, and grants from the National Institutes of Health.

ScienceDaily (Mar. 27, 2012)

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