Literature DB >> 27663672

Type I interferon causes thrombotic microangiopathy by a dose-dependent toxic effect on the microvasculature.

David Kavanagh1, Sarah McGlasson2, Alexa Jury2, Jac Williams3, Neil Scolding4, Chris Bellamy5, Claudia Gunther6, Diane Ritchie3, Daniel P Gale7, Yashpal S Kanwar8, Rachel Challis1, Holly Buist9, James Overell10, Belinda Weller3, Oliver Flossmann11, Mark Blunden12, Eric P Meyer13, Thomas Krucker14, Stephen J W Evans15, Iain L Campbell16, Andrew P Jackson2, Siddharthan Chandran3, David P J Hunt2,3.   

Abstract

Many drugs have been reported to cause thrombotic microangiopathy (TMA), yet evidence supporting a direct association is often weak. In particular, TMA has been reported in association with recombinant type I interferon (IFN) therapies, with recent concern regarding the use of IFN in multiple sclerosis patients. However, a causal association has yet to be demonstrated. Here, we adopt a combined clinical and experimental approach to provide evidence of such an association between type I IFN and TMA. We show that the clinical phenotype of cases referred to a national center is uniformly consistent with a direct dose-dependent drug-induced TMA. We then show that dose-dependent microvascular disease is seen in a transgenic mouse model of IFN toxicity. This includes specific microvascular pathological changes seen in patient biopsies and is dependent on transcriptional activation of the IFN response through the type I interferon α/β receptor (IFNAR). Together our clinical and experimental findings provide evidence of a causal link between type I IFN and TMA. As such, recombinant type I IFN therapies should be stopped at the earliest stage in patients who develop this complication, with implications for risk mitigation.
© 2016 by The American Society of Hematology.

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Year:  2016        PMID: 27663672      PMCID: PMC5159705          DOI: 10.1182/blood-2016-05-715987

Source DB:  PubMed          Journal:  Blood        ISSN: 0006-4971            Impact factor:   25.476


  39 in total

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