GENES FOR ANAEMIA TREATMENT
Targeting genes to treat anaemia By working to identify drugs that promote erythropoietin-responsive precursors, Assistant Professor Johan Flygare hopes to open up new opportunities for the treatment of patients suffering from anaemia with a drug (erythropoietin) that stimulates production of red blood cells. Can you tell us how your research is working to improve the existing treatments?
JOHAN FLYGARE
Can you summarise the existing treatments that are available to patients with anaemia? Today there are three major strategies for treating patients with anaemia. Firstly, to treat the underlying cause, such as giving the patient iron if the anaemia is caused by iron deficiency; secondly, to give the patient new red blood cells by transfusing red blood cells from a blood donor; and thirdly, to treat the patient 82
INTERNATIONAL INNOVATION
Our research focuses on improving anaemia treatment based on all three principles with the main focus on developing a new family of drugs. We are studying the underlying mechanisms that cause anaemia in patients with Diamond-Blackfan anaemia (DBA). Today, these patients have but few good treatment options. By discovering the details of the underlying cause we hope to be able to develop disease-specific treatments for these forms of anaemia. We are also developing cell culture methods that could allow large-scale production of red blood cells in a bioreactor, with the ultimate aim of being able to produce red blood cells, in a factory setting, that could be used for transfusion to patients. This would bypass the limitations relating to available blood donors and reduce the risk of infection with blood-borne pathogens. In addition, we are focusing our laboratory on the development
of better drugs for anaemia treatment. Currently, the only drugs used to increase red blood cell production in anaemic patients are recombinant erythropoietin (Epo) analogues. These drugs are based on research that in the 1980s identified erythropoietin as the main regulator of red blood cell production. Erythropoietin is, however, mostly effective in anaemic patients suffering low endogenous Epo production, while other types are completely or relatively resistant to Epo treatment. The Epo-resistant anaemias include bone marrow failure syndromes such as DBA that do not respond even to high doses of Epo. Other more common forms of anaemia are only relatively Epo-resistant, such as those associated with cancer and inflammation that often respond relatively poorly to Epo only if given in high doses. Due to the limitations of Epo therapy, blood transfusions are often used for treatment of Epo-insensitive and Epo-resistant anaemias. New erythropoiesis stimulating agents that promote Epo-responsive precursor cell production in these patients would therefore be of significant socioeconomic and medical value.