Genetic regulation of fetal hemoglobin across global populations

Human genetic variation has enabled the identification of several key regulators of fetal-to-adult hemoglobin switching, including BCL11A, resulting in therapeutic advances. However, despite the progress made, limited further insights have been obtained to provide a fuller accounting of how genetic variation contributes to the global mechanisms of fetal hemoglobin (HbF) gene regulation. Here, we have conducted a multi-ancestry genome-wide association study of 28,279 individuals from several cohorts spanning 5 continents to define the architecture of human genetic variation impacting HbF. We have identified a total of 178 conditionally independent genome-wide significant or suggestive variants across 14 genomic windows. Importantly, these new data enable us to better define the mechanisms by which HbF switching occurs in vivo. We conduct targeted perturbations to define BACH2 as a new genetically-nominated regulator of hemoglobin switching. We define putative causal variants and underlying mechanisms at the well-studied BCL11A and HBS1L-MYB loci, illuminating the complex variant-driven regulation present at these loci. We additionally show how rare large-effect deletions in the HBB locus can interact with polygenic variation to influence HbF levels. Our study paves the way for the next generation of therapies to more effectively induce HbF in sickle cell disease and {beta}-thalassemia.

[1]  S. Orkin,et al.  Fetal Hemoglobin Regulation in Beta-Thalassemia. , 2023, Hematology/oncology clinics of North America.

[2]  Mitchell J. Weiss,et al.  Effective therapies for sickle cell disease: are we there yet? , 2022, Trends in genetics : TIG.

[3]  A. S. Hansen,et al.  Region Capture Micro-C reveals coalescence of enhancers and promoters into nested microcompartments , 2022, bioRxiv.

[4]  J. Weissman,et al.  Variant to function mapping at single-cell resolution through network propagation , 2022, bioRxiv.

[5]  Christopher M. Vockley,et al.  A Congenital Anemia Reveals Distinct Targeting Mechanisms for Master Transcription Factor GATA1. , 2022, Blood.

[6]  R. Hardison,et al.  HIC2 controls developmental hemoglobin switching by repressing BCL11A transcription , 2021, Nature Genetics.

[7]  V. Sankaran,et al.  Molecular and cellular mechanisms that regulate human erythropoiesis , 2021, Blood.

[8]  A. Regev,et al.  A genetic disorder reveals a hematopoietic stem cell regulatory network co-opted in leukemia , 2021, bioRxiv.

[9]  J. M. Verboon,et al.  Pathogenic BCL11A variants provide insights into the mechanisms of human fetal hemoglobin silencing , 2021, PLoS genetics.

[10]  J. Hoenicka,et al.  Heterozygous variants in ZBTB7A cause a neurodevelopmental disorder associated with symptomatic overgrowth of pharyngeal lymphoid tissue, macrocephaly, and elevated fetal hemoglobin , 2021, American journal of medical genetics. Part A.

[11]  S. Orkin,et al.  A unified model of human hemoglobin switching through single-cell genome editing , 2021, Nature Communications.

[12]  Sina A. Gharib,et al.  Large-scale cis- and trans-eQTL analyses identify thousands of genetic loci and polygenic scores that regulate blood gene expression , 2021, Nature Genetics.

[13]  Heather L. Mulder,et al.  A polygenic score for acute vaso-occlusive pain in pediatric sickle cell disease. , 2021, Blood advances.

[14]  R. Schwessinger,et al.  Defining genome architecture at base-pair resolution , 2021, Nature.

[15]  John P. Rice,et al.  A Comparison of Ten Polygenic Score Methods for Psychiatric Disorders Applied Across Multiple Cohorts , 2020, Biological Psychiatry.

[16]  David R. Liu,et al.  Massively parallel assessment of human variants with base editor screens , 2020, Cell.

[17]  Amanda M Li,et al.  CRISPR-Cas9 Gene Editing for Sickle Cell Disease and β-Thalassemia. , 2020, The New England journal of medicine.

[18]  David A. Williams,et al.  Post-Transcriptional Genetic Silencing of BCL11A to Treat Sickle Cell Disease. , 2020, The New England journal of medicine.

[19]  Javier Gracia Tabuenca,et al.  Inherited myeloproliferative neoplasm risk affects haematopoietic stem cells , 2020, Nature.

[20]  William J. Astle,et al.  The Polygenic and Monogenic Basis of Blood Traits and Diseases , 2020, Cell.

[21]  William J. Astle,et al.  Trans-ethnic and Ancestry-Specific Blood-Cell Genetics in 746,667 Individuals from 5 Global Populations , 2020, Cell.

[22]  Christopher D. Brown,et al.  The GTEx Consortium atlas of genetic regulatory effects across human tissues , 2019, Science.

[23]  E. Lander,et al.  Control of human hemoglobin switching by LIN28B-mediated regulation of BCL11A translation , 2018, Nature Genetics.

[24]  Howard Y. Chang,et al.  Single-cell multiomic analysis identifies regulatory programs in mixed-phenotype acute leukemia , 2019, Nature Biotechnology.

[25]  Aviv Regev,et al.  Transcriptional States and Chromatin Accessibility Underlying Human Erythropoiesis , 2019, Cell reports.

[26]  C. Lareau,et al.  Heritability of fetal hemoglobin, white cell count, and other clinical traits from a sickle cell disease family cohort , 2019, American journal of hematology.

[27]  Jacob C. Ulirsch,et al.  Impaired human hematopoiesis due to a cryptic intronic GATA1 splicing mutation , 2019, The Journal of experimental medicine.

[28]  J. Strouboulis,et al.  The Pleiotropic Effects of GATA1 and KLF1 in Physiological Erythropoiesis and in Dyserythropoietic Disorders , 2019, Front. Physiol..

[29]  B. Pace,et al.  Mechanisms of NRF2 activation to mediate fetal hemoglobin induction and protection against oxidative stress in sickle cell disease , 2019, Experimental biology and medicine.

[30]  Jacob C. Ulirsch,et al.  Gene-centric functional dissection of human genetic variation uncovers regulators of hematopoiesis , 2018, bioRxiv.

[31]  Jason R. Hodges,et al.  Sickle Cell Clinical Research and Intervention Program (SCCRIP): A lifespan cohort study for sickle cell disease progression from the pediatric stage into adulthood , 2018, Pediatric blood & cancer.

[32]  Martha L. Bulyk,et al.  Direct Promoter Repression by BCL11A Controls the Fetal to Adult Hemoglobin Switch , 2018, Cell.

[33]  Laura J. Norton,et al.  Natural regulatory mutations elevate the fetal globin gene via disruption of BCL11A or ZBTB7A binding , 2018, Nature Genetics.

[34]  J. Danesh,et al.  Efficiency and safety of varying the frequency of whole blood donation (INTERVAL): a randomised trial of 45 000 donors , 2017, The Lancet.

[35]  B. Pace,et al.  Dimethyl fumarate increases fetal hemoglobin, provides heme detoxification, and corrects anemia in sickle cell disease. , 2017, JCI insight.

[36]  B. Pace,et al.  NRF2 mediates γ-globin gene regulation and fetal hemoglobin induction in human erythroid progenitors , 2017, Haematologica.

[37]  R. Proia,et al.  IGF2BP1 overexpression causes fetal-like hemoglobin expression patterns in cultured human adult erythroblasts , 2017, Proceedings of the National Academy of Sciences.

[38]  Jonathan M. Cairns,et al.  Lineage-Specific Genome Architecture Links Enhancers and Non-coding Disease Variants to Target Gene Promoters , 2016, Cell.

[39]  S. Sawiak,et al.  BCL11A Haploinsufficiency Causes an Intellectual Disability Syndrome and Dysregulates Transcription , 2016, American journal of human genetics.

[40]  A. Perkins,et al.  Krüppeling erythropoiesis: an unexpected broad spectrum of human red blood cell disorders due to KLF1 variants. , 2016, Blood.

[41]  P. Sebastiani,et al.  A case-control genome-wide association study identifies genetic modifiers of fetal hemoglobin in sickle cell disease , 2016 .

[42]  Jacob C. Ulirsch,et al.  Targeted Application of Human Genetic Variation Can Improve Red Blood Cell Production from Stem Cells. , 2016, Cell stem cell.

[43]  Matti Pirinen,et al.  FINEMAP: efficient variable selection using summary data from genome-wide association studies , 2015, bioRxiv.

[44]  Matthew C. Canver,et al.  BCL11A enhancer dissection by Cas9-mediated in situ saturating mutagenesis , 2015, Nature.

[45]  Jacob C. Ulirsch,et al.  BCL11A deletions result in fetal hemoglobin persistence and neurodevelopmental alterations. , 2015, The Journal of clinical investigation.

[46]  T. Spector,et al.  GENOME-WIDE ASSOCIATION ANALYSES BASED ON WHOLE-GENOME SEQUENCING IN SARDINIA PROVIDE INSIGHTS INTO REGULATION OF HEMOGLOBIN LEVELS , 2015, Nature Genetics.

[47]  J. Barrett,et al.  Genome Wide Association Study of Fetal Hemoglobin in Sickle Cell Anemia in Tanzania , 2014, PloS one.

[48]  M. Gladwin,et al.  Risk Factors for Death in 632 Patients with Sickle Cell Disease in the United States and United Kingdom , 2014, PloS one.

[49]  W. V. van IJcken,et al.  HBS1L-MYB intergenic variants modulate fetal hemoglobin via long-range MYB enhancers. , 2014, The Journal of clinical investigation.

[50]  S. Glynn,et al.  The National Heart, Lung, and Blood Institute Recipient Epidemiology and Donor Evaluation Study (REDS‐III): a research program striving to improve blood donor and transfusion recipient outcomes , 2014, Transfusion.

[51]  Matthew C. Canver,et al.  An Erythroid Enhancer of BCL11A Subject to Genetic Variation Determines Fetal Hemoglobin Level , 2013, Science.

[52]  Y. T. Lee,et al.  LIN28B-mediated expression of fetal hemoglobin and production of fetal-like erythrocytes from adult human erythroblasts ex vivo. , 2013, Blood.

[53]  S. Orkin,et al.  The switch from fetal to adult hemoglobin. , 2013, Cold Spring Harbor perspectives in medicine.

[54]  Chris Fisher,et al.  A functional element necessary for fetal hemoglobin silencing. , 2011, The New England journal of medicine.

[55]  P. Visscher,et al.  GCTA: a tool for genome-wide complex trait analysis. , 2011, American journal of human genetics.

[56]  J. Hirschhorn,et al.  Supporting Online Material Materials and Methods Figs. S1 to S10 Tables S1 to S7 References Human Fetal Hemoglobin Expression Is Regulated by the Developmental Stage-specific Repressor Bcl11a , 2022 .

[57]  J. Hirschhorn,et al.  DNA polymorphisms at the BCL11A, HBS1L-MYB, and β-globin loci associate with fetal hemoglobin levels and pain crises in sickle cell disease , 2008, Proceedings of the National Academy of Sciences.

[58]  J. Vance,et al.  Identification of genetic polymorphisms associated with risk for pulmonary hypertension in sickle cell disease. , 2008, Blood.

[59]  Simon Heath,et al.  A QTL influencing F cell production maps to a gene encoding a zinc-finger protein on chromosome 2p15 , 2007, Nature Genetics.

[60]  M. Brand,et al.  Heme regulates the dynamic exchange of Bach1 and NF-E2-related factors in the Maf transcription factor network. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[61]  R. Aebersold,et al.  Dynamic changes in transcription factor complexes during erythroid differentiation revealed by quantitative proteomics , 2004, Nature Structural &Molecular Biology.

[62]  M. Groudine,et al.  Activation of β-major globin gene transcription is associated with recruitment of NF-E2 to the β-globin LCR and gene promoter , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[63]  K. Itoh,et al.  Bach proteins belong to a novel family of BTB-basic leucine zipper transcription factors that interact with MafK and regulate transcription through the NF-E2 site , 1996, Molecular and cellular biology.

[64]  S. Orkin,et al.  The ubiquitous subunit of erythroid transcription factor NF-E2 is a small basic-leucine zipper protein related to the v-maf oncogene. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[65]  Paul Tempst,et al.  Erythroid transcription factor NF-E2 is a haematopoietic-specific basic–leucine zipper protein , 1993, Nature.