BLVRB Redox Mutation Defines Heme Degradation in a Metabolic Pathway of Enhanced Thrombopoiesis in Humans

Overview

Journal Blood

Publisher Elsevier

Specialty Hematology

Date 2016 May 22

PMID 27207795

Citations 23

Authors

Song Wu

Zongdong Li

Dmitri V Gnatenko

Beibei Zhang

Lu Zhao

Lisa E Malone

Nedialka Markova

Timothy J Mantle

Natasha M Nesbitt

Wadie F Bahou

Affiliations

Soon will be listed here.

Abstract

Human blood cell counts are tightly maintained within narrow physiologic ranges, largely controlled by cytokine-integrated signaling and transcriptional circuits that regulate multilineage hematopoietic specification. Known genetic loci influencing blood cell production account for <10% of platelet and red blood cell variability, and thrombopoietin/cellular myeloproliferative leukemia virus liganding is dispensable for definitive thrombopoiesis, establishing that fundamentally important modifier loci remain unelucidated. In this study, platelet transcriptome sequencing and extended thrombocytosis cohort analyses identified a single loss-of-function mutation (BLVRB(S111L)) causally associated with clonal and nonclonal disorders of enhanced platelet production. BLVRB(S111L) encompassed within the substrate/cofactor [α/β dinucleotide NAD(P)H] binding fold is a functionally defective redox coupler using flavin and biliverdin (BV) IXβ tetrapyrrole(s) and results in exaggerated reactive oxygen species accumulation as a putative metabolic signal leading to differential hematopoietic lineage commitment and enhanced thrombopoiesis. These data define the first physiologically relevant function of BLVRB and implicate its activity and/or heme-regulated BV tetrapyrrole(s) in a unique redox-regulated bioenergetic pathway governing terminal megakaryocytopoiesis; these observations also define a mechanistically restricted drug target retaining potential for enhancing human platelet counts.

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