Sept. 19, 2014

By Medical Discovery News

While sickle cell disease has long been studied, a recent discovery revealed that the disease significantly increases the levels of a molecule called sphingosine-1-phosphate (S1P), which is generated by an enzyme called sphingosine kinase 1 (SphK1). Inhibiting the enzyme SphK1 was found to reduce the severity of sickle cell disease in mice, which will hopefully lead to new drugs that target SphK1in order to treat sickle cell disease in humans.

Sickle cell disease is caused by a change in the gene that is responsible for a type of hemoglobin, the protein molecule in red blood cells that carries oxygen. This tiny change results in hemoglobin clumping together, changing the shape of red blood cells.

The name for sickle cell disease actually comes from misshapen red blood cells. Rather than being shaped like a disk, or a donut without a whole, sickle cells are shaped like a crescent, sort of bending over on themselves. The normal shape is critical to red blood cells’ ability to easily travel through blood vessels and deliver oxygen to cells and tissues. Sickle cells become inflexible and stick to each other, blocking the flow of blood through blood vessels.

Symptoms of the disease begin to appear at about four months of age. Normally, red blood cells live for about 120 days. Sickle cells only survive 10-20 days. Although the bone marrow tries to compensate for the rapid loss of red blood cells, it cannot keep up. The disease causes pain, anemia, organ damage, and possibly infections.

Although the symptoms and their severity vary, most people with sickle cell disease will have periodic crises lasting hours or days. Symptoms include fatigue, paleness, shortness of breath, increased heart rate, jaundice, and pain. Long-term damage can occur in the spleen, eyes, and other organs, and sickle cell disease increases the risk of stroke. People who only inherit one copy of the sickle cell hemoglobin gene have a milder case of the disease than those who inherit two copies, one from each parent.

Current treatments only reduce the number and the severity of crises using hydroxyrurea, blood transfusions, pain medications, and antibiotics. As the disease advances, dialysis, kidney transplants, eye surgeries, gall bladder removal, and other treatments may be necessary. The only cure for the disease is a bone marrow transplant, which is not an option for everyone.

So it’s pretty exciting that when scientists found that levels of S1P were elevated in mice with sickle cell disease, they inhibited the enzyme SphK1 to reduce the levels of S1P. As a result, red blood cells lived longer and had less sickling. The mice also had less inflammation and tissue damage, which would reduce damage to red blood cells and prevent symptoms of the disease. When they engineered sickle cell disease mice without the gene for the enzyme SphK1 that makes S1P, again the mice had less sickling and symptoms.

How does S1P influence sickling? Apparently, it binds directly to hemoglobin and reduces its ability to collect and carry oxygen, which causes the characteristic folding of cells. S1P has other roles in the body, so it is unknown whether inhibitors to SphK1 can safely and effectively be used in humans to treat sickle cell disease.

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