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| How cells sense oxygen wins Nobel prize | |
| (32 minutes later) | |
| Three scientists who discovered how cells sense and adapt to oxygen levels have won the 2019 Nobel Prize. | Three scientists who discovered how cells sense and adapt to oxygen levels have won the 2019 Nobel Prize. |
| Sir Peter Ratcliffe, of the University of Oxford and Francis Crick Institute, William Kaelin, of Harvard, and Gregg Semenza, of Johns Hopkins University share the physiology or medicine prize. | Sir Peter Ratcliffe, of the University of Oxford and Francis Crick Institute, William Kaelin, of Harvard, and Gregg Semenza, of Johns Hopkins University share the physiology or medicine prize. |
| Their work is leading to new treatments for anaemia and even cancer. | Their work is leading to new treatments for anaemia and even cancer. |
| The role of oxygen-sensing is also being investigated in diseases from heart failure to chronic lung disease. | The role of oxygen-sensing is also being investigated in diseases from heart failure to chronic lung disease. |
| The Swedish Academy, which awards the prize, said: "The fundamental importance of oxygen has been understood for centuries but how cells adapt to changes in levels of oxygen has long been unknown." | The Swedish Academy, which awards the prize, said: "The fundamental importance of oxygen has been understood for centuries but how cells adapt to changes in levels of oxygen has long been unknown." |
| Oxygen levels vary in the body, particularly: | Oxygen levels vary in the body, particularly: |
| And when they drop, cells rapidly have to adapt their metabolism. | And when they drop, cells rapidly have to adapt their metabolism. |
| Why does this matter? | Why does this matter? |
| The oxygen-sensing ability of the body has a role in the immune system and the earliest stages of development inside the womb. | The oxygen-sensing ability of the body has a role in the immune system and the earliest stages of development inside the womb. |
| It can trigger the production of red blood cells or the construction of blood vessels. | It can trigger the production of red blood cells or the construction of blood vessels. |
| So, drugs that mimic it may be an effective treatment for anaemia. | So, drugs that mimic it may be an effective treatment for anaemia. |
| Tumours, meanwhile, can hijack this process to selfishly create new blood vessels and grow. | Tumours, meanwhile, can hijack this process to selfishly create new blood vessels and grow. |
| So, drugs that reverse it may help halt cancer. | So, drugs that reverse it may help halt cancer. |
| "The work of these three scientists and their teams has paved the way to a greater understanding of these common, life-threatening conditions and new strategies to treat them," Dr Andrew Murray, from the University of Cambridge, said. | "The work of these three scientists and their teams has paved the way to a greater understanding of these common, life-threatening conditions and new strategies to treat them," Dr Andrew Murray, from the University of Cambridge, said. |
| "Congratulations to the three new Nobel Laureates. This is richly deserved." | "Congratulations to the three new Nobel Laureates. This is richly deserved." |
| How was the discovery made? | How was the discovery made? |
| Levels of hormone erythropoietin (EPO) were shown to rise as those of oxygen fell. | Levels of hormone erythropoietin (EPO) were shown to rise as those of oxygen fell. |
| And the scientists discovered this was because a cluster of proteins called hypoxia-inducible factor (HIF) was changing the behaviour of DNA, the genetic code. | And the scientists discovered this was because a cluster of proteins called hypoxia-inducible factor (HIF) was changing the behaviour of DNA, the genetic code. |
| Further work showed when oxygen levels were normal, cells constantly produced HIF only for it to be destroyed by another protein, VHL. | Further work showed when oxygen levels were normal, cells constantly produced HIF only for it to be destroyed by another protein, VHL. |
| But when oxygen levels fell, VHL could no longer stick to HIF, leading to the build-up sufficient levels to change the behaviour of DNA. | But when oxygen levels fell, VHL could no longer stick to HIF, leading to the build-up sufficient levels to change the behaviour of DNA. |
| Previous winners | Previous winners |