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1. Supplementary Excel Tables from Integrative Genomic Analysis of Pediatric Myeloid-Related Acute Leukemias Identifies Novel Subtypes and Prognostic Indicators

Author

Tanja A. Gruber, C. Michel Zwaan, Stanley Pounds, Jinghui Zhang, James R. Downing, Jeffery M. Klco, Henrik Hasle, Franco Locatelli, Marry M. van den Heuvel-Eibrink, Dirk Reinhardt, Jeffrey E. Rubnitz, Sharyn D. Baker, Jatinder K. Lamba, Sophia Polychronopoulou, Charikleia Kelaidi, Marie Jarosova, Martina Pigazzi, Esther A. Obeng, Jennifer L. Kamens, Jacquelyn Myers, Donald Yergeau, Heather L. Mulder, John Easton, Tamara Lamprecht, Guangchun Song, Yuanyuan Wang, Yanling Liu, Stephanie Nance, Lei Shi, Michael P. Walsh, Yu Liu, Sanne Noort, Jing Ma, and Maarten Fornerod

Abstract

Supplementary Excel Tables

Published
2023

2. Supplementary Tables and Figures from Integrative Genomic Analysis of Pediatric Myeloid-Related Acute Leukemias Identifies Novel Subtypes and Prognostic Indicators

Author

Tanja A. Gruber, C. Michel Zwaan, Stanley Pounds, Jinghui Zhang, James R. Downing, Jeffery M. Klco, Henrik Hasle, Franco Locatelli, Marry M. van den Heuvel-Eibrink, Dirk Reinhardt, Jeffrey E. Rubnitz, Sharyn D. Baker, Jatinder K. Lamba, Sophia Polychronopoulou, Charikleia Kelaidi, Marie Jarosova, Martina Pigazzi, Esther A. Obeng, Jennifer L. Kamens, Jacquelyn Myers, Donald Yergeau, Heather L. Mulder, John Easton, Tamara Lamprecht, Guangchun Song, Yuanyuan Wang, Yanling Liu, Stephanie Nance, Lei Shi, Michael P. Walsh, Yu Liu, Sanne Noort, Jing Ma, and Maarten Fornerod

Abstract

Supplementary Tables and Figures

Published
2023

3. Data from Integrative Genomic Analysis of Pediatric Myeloid-Related Acute Leukemias Identifies Novel Subtypes and Prognostic Indicators

Author

Tanja A. Gruber, C. Michel Zwaan, Stanley Pounds, Jinghui Zhang, James R. Downing, Jeffery M. Klco, Henrik Hasle, Franco Locatelli, Marry M. van den Heuvel-Eibrink, Dirk Reinhardt, Jeffrey E. Rubnitz, Sharyn D. Baker, Jatinder K. Lamba, Sophia Polychronopoulou, Charikleia Kelaidi, Marie Jarosova, Martina Pigazzi, Esther A. Obeng, Jennifer L. Kamens, Jacquelyn Myers, Donald Yergeau, Heather L. Mulder, John Easton, Tamara Lamprecht, Guangchun Song, Yuanyuan Wang, Yanling Liu, Stephanie Nance, Lei Shi, Michael P. Walsh, Yu Liu, Sanne Noort, Jing Ma, and Maarten Fornerod

Abstract

Genomic characterization of pediatric patients with acute myeloid leukemia (AML) has led to the discovery of somatic mutations with prognostic implications. Although gene-expression profiling can differentiate subsets of pediatric AML, its clinical utility in risk stratification remains limited. Here, we evaluate gene expression, pathogenic somatic mutations, and outcome in a cohort of 435 pediatric patients with a spectrum of pediatric myeloid-related acute leukemias for biological subtype discovery. This analysis revealed 63 patients with varying immunophenotypes that span a T-lineage and myeloid continuum designated as acute myeloid/T-lymphoblastic leukemia (AMTL). Within AMTL, two patient subgroups distinguished by FLT3-ITD and PRC2 mutations have different outcomes, demonstrating the impact of mutational composition on survival. Across the cohort, variability in outcomes of patients within isomutational subsets is influenced by transcriptional identity and the presence of a stem cell–like gene-expression signature. Integration of gene expression and somatic mutations leads to improved risk stratification.Significance:Immunophenotype and somatic mutations play a significant role in treatment approach and risk stratification of acute leukemia. We conducted an integrated genomic analysis of pediatric myeloid malignancies and found that a combination of genetic and transcriptional readouts was superior to immunophenotype and genomic mutations in identifying biological subtypes and predicting outcomes.This article is highlighted in the In This Issue feature, p. 549

Published
2023

4. Murine foetal liver supports limited detectable expansion of life-long haematopoietic progenitors

Author

Miguel Ganuza, Trent Hall, Jacquelyn Myers, Chris Nevitt, Raúl Sánchez-Lanzas, Ashley Chabot, Juan Ding, Emilia Kooienga, Claire Caprio, David Finkelstein, Guolian Kang, Esther Obeng, and Shannon McKinney-Freeman

Subjects
Mice, Liver, Animals, Cell Biology, Hematopoietic Stem Cells, Article
Abstract

Current dogma asserts that the foetal liver (FL) is an expansion niche for recently specified haematopoietic stem cells (HSCs) during ontogeny. Indeed, between embryonic day of development (E)12.5 and E14.5, the number of transplantable HSCs in the murine FL expands from 50 to about 1,000. Here we used a non-invasive, multi-colour lineage tracing strategy to interrogate the embryonic expansion of murine haematopoietic progenitors destined to contribute to the adult HSC pool. Our data show that this pool of fated progenitors expands only two-fold during FL ontogeny. Although Histone2B-GFP retention in vivo experiments confirmed substantial proliferation of phenotypic FL-HSC between E12.5 and E14.5, paired-daughter cell assays revealed that many mid-gestation phenotypic FL-HSCs are biased to differentiate, rather than self-renew, relative to phenotypic neonatal and adult bone marrow HSCs. In total, these data support a model in which the FL-HSC pool fated to contribute to adult blood expands only modestly during ontogeny.

Published
2022

7. Integrative Genomic Analysis of Pediatric Myeloid-Related Acute Leukemias Identifies Novel Subtypes and Prognostic Indicators

Author

Donald Yergeau, Marry M. van den Heuvel-Eibrink, Sanne Noort, Lei Shi, Charikleia Kelaidi, Jeffrey E. Rubnitz, Yanling Liu, Tanja A. Gruber, Stephanie Nance, C. Michel Zwaan, Jing Ma, Franco Locatelli, Yuanyuan Wang, Maarten Fornerod, Heather L. Mulder, Jeffery M. Klco, Martina Pigazzi, Esther A. Obeng, Guangchun Song, Jennifer Kamens, Sharyn D. Baker, James R. Downing, Stanley Pounds, John Easton, Tamara Lamprecht, Michael P. Walsh, Marie Jarošová, Sophia Polychronopoulou, Dirk Reinhardt, Henrik Hasle, Jinghui Zhang, Jatinder K. Lamba, Jacquelyn Myers, and Yu Liu

Subjects
Oncology, EXPRESSION, medicine.medical_specialty, Myeloid, Somatic cell, Medizin, CLASSIFICATION, 03 medical and health sciences, 0302 clinical medicine, Immunophenotyping, ACUTE MEGAKARYOBLASTIC LEUKEMIA, Internal medicine, hemic and lymphatic diseases, ACUTE LEUKEMIA, medicine, Humans, Child, neoplasms, Research Articles, 030304 developmental biology, 0303 health sciences, Acute leukemia, biology, LANDSCAPE, business.industry, Gene Expression Profiling, Myeloid leukemia, Genomics, General Medicine, Prognosis, medicine.disease, 3. Good health, Leukemia, Myeloid, Acute, Leukemia, medicine.anatomical_structure, Settore MED/38 - PEDIATRIA GENERALE E SPECIALISTICA, 030220 oncology & carcinogenesis, Mutation, Cohort, biology.protein, PRC2, business, GENE-MUTATIONS
Abstract

Integrating somatic mutation analysis and gene expression profiling distinguishes pediatric AML subtypes with differential prognoses and clinical risks., Genomic characterization of pediatric patients with acute myeloid leukemia (AML) has led to the discovery of somatic mutations with prognostic implications. Although gene-expression profiling can differentiate subsets of pediatric AML, its clinical utility in risk stratification remains limited. Here, we evaluate gene expression, pathogenic somatic mutations, and outcome in a cohort of 435 pediatric patients with a spectrum of pediatric myeloid-related acute leukemias for biological subtype discovery. This analysis revealed 63 patients with varying immunophenotypes that span a T-lineage and myeloid continuum designated as acute myeloid/T-lymphoblastic leukemia (AMTL). Within AMTL, two patient subgroups distinguished by FLT3-ITD and PRC2 mutations have different outcomes, demonstrating the impact of mutational composition on survival. Across the cohort, variability in outcomes of patients within isomutational subsets is influenced by transcriptional identity and the presence of a stem cell–like gene-expression signature. Integration of gene expression and somatic mutations leads to improved risk stratification. Significance: Immunophenotype and somatic mutations play a significant role in treatment approach and risk stratification of acute leukemia. We conducted an integrated genomic analysis of pediatric myeloid malignancies and found that a combination of genetic and transcriptional readouts was superior to immunophenotype and genomic mutations in identifying biological subtypes and predicting outcomes. This article is highlighted in the In This Issue feature, p. 549

Published
2021

8. Regulation of RNA polymerase II activity is essential for terminal erythroid maturation

Author

Jacquelyn Myers, Laurie A. Steiner, Vincent P. Schulz, Tyler A Couch, Narla Mohandas, Zachary C. Murphy, Michael Getman, Cal D. Palumbo, Hongxia Yan, Kristin Murphy, Kimberly Lezon-Geyda, and Patrick G. Gallagher

Subjects
Erythroblasts, Transcription, Genetic, Heterochromatin, Immunology, RNA polymerase II, Biochemistry, Cell Line, Histones, Red Cells, Iron, and Erythropoiesis, Erythroid Cells, Transcription (biology), hemic and lymphatic diseases, Gene expression, Humans, Erythropoiesis, Regulation of gene expression, biology, RNA, Gene Expression Regulation, Developmental, Cell Biology, Hematology, Chromatin, Cell biology, biology.protein, RNA Polymerase II, Chromatin immunoprecipitation
Abstract

The terminal maturation of human erythroblasts requires significant changes in gene expression in the context of dramatic nuclear condensation. Defects in this process are associated with inherited anemias and myelodysplastic syndromes. The progressively dense appearance of the condensing nucleus in maturing erythroblasts led to the assumption that heterochromatin accumulation underlies this process, but despite extensive study, the precise mechanisms underlying this essential biologic process remain elusive. To delineate the epigenetic changes associated with the terminal maturation of human erythroblasts, we performed mass spectrometry of histone posttranslational modifications combined with chromatin immunoprecipitation coupled with high-throughput sequencing, Assay for Transposase Accessible Chromatin, and RNA sequencing. Our studies revealed that the terminal maturation of human erythroblasts is associated with a dramatic decline in histone marks associated with active transcription elongation, without accumulation of heterochromatin. Chromatin structure and gene expression were instead correlated with dynamic changes in occupancy of elongation competent RNA polymerase II, suggesting that terminal erythroid maturation is controlled largely at the level of transcription. We further demonstrate that RNA polymerase II “pausing” is highly correlated with transcriptional repression, with elongation competent RNA polymerase II becoming a scare resource in late-stage erythroblasts, allocated to erythroid-specific genes. Functional studies confirmed an essential role for maturation stage-specific regulation of RNA polymerase II activity during erythroid maturation and demonstrate a critical role for HEXIM1 in the regulation of gene expression and RNA polymerase II activity in maturing erythroblasts. Taken together, our findings reveal important insights into the mechanisms that regulate terminal erythroid maturation and provide a novel paradigm for understanding normal and perturbed erythropoiesis.

Published
2020

9. Single cell transcriptomic profiling identifies molecular phenotypes of newborn human lung cells

Author

Andrew McDavid, Gloria S. Pryhuber, Yan Xu, Gautam Bandopadhyay, Thomas J. Mariani, Stephen Romas, Jeanne Holden-Wiltse, Ravi S. Misra, Minzhe Guo, Soula Danopoulos, Cameron D. Baker, J. Dutra, Jeffrey A. Whitsett, Denise Al Alam, Soumyaroop Bhattacharya, John M. Ashton, Heidie Huyck, Jacquelyn Myers, Jason R. Myers, and S. Steven Potter

Subjects
education.field_of_study, Lung, Cell, Population, RNA, Biology, Phenotype, Cell biology, Transcriptome, medicine.anatomical_structure, Immune system, medicine, education, Gene
Abstract

RationaleWhile animal model studies have extensively defined mechanisms controlling cell diversity in the developing mammalian lung, the limited data available from late stage human lung development represents a significant knowledge gap. The NHLBI Molecular Atlas of Lung Development Program (LungMAP) seeks to fill this gap by creating a structural, cellular and molecular atlas of the human and mouse lung.MethodsSingle cell RNA sequencing generated transcriptional profiles of 5500 cells obtained from two one-day old human lungs (born at gestational ages of 39 and 31 weeks) from the LungMAP Human Tissue Core Biorepository at the University of Rochester. Frozen single cell isolates were captured, and library preparation was completed on the Chromium 10X system. Data was analyzed in Seurat, and cellular annotation was performed using the ToppGene functional analysis tool. Single cell sequence data from 32000 postnatal day 1, 3, 7 and 10 mouse lung (n = 2 at each time point) cells generated by the LungMAP Research Center at Cincinnati Children’s Hospital and Medical Center, using Dropseq platform, was integrated with the human data. In situ hybridization was used to confirm the spatial location of cellular phenotypes.ResultsTranscriptional interrogation of donor newborn human lung cells identified distinct clusters representing multiple populations of epithelial, endothelial, fibroblasts, pericytes, smooth muscle, and immune cells and signature genes for each of these populations were identified. Computational integration of newborn human and postnatal mouse lung development cellular transcriptomes facilitated the identification of distinct cellular lineages among all the major cell types. Integration of the human and mouse cellular transcriptomes also demonstrated cell type-specific differences in developmental states of the newborn human lung cells. In particular, matrix fibroblasts could be separated into those representative of younger cells (n=393), or older cells (n=158).This is the first comprehensive molecular map of the cellular landscape of neonatal human lung, including biomarkers for cells at distinct states of development. Our results indicate that integrated single cell RNA profiling of human and mouse lung will help identify common and species-specific mechanisms of lung development and respiratory disease.

Published
2020

11. Abstract 2093: Alternative splicing in hematopoietic stem cells is affected by the loss of DNMT3A

Author

Juan Martin Barajas, Esther A. Obeng, Ana Leal-Cervantes, Yiping Fan, Jacquelyn Myers, Shondra Miller, Baranda S Hansen, LaShanale Wallace, Aparna Calindi, Chandra Rolle, and Koral Campbell

Subjects
Cancer Research, Oncology, Hematopoietic stem cell differentiation, Gene expression, RNA splicing, Alternative splicing, DNA methylation, Epigenetics, Biology, Stem cell, Gene, Cell biology
Abstract

Myelodysplastic syndromes are clonal stem cell disorders associated with low blood counts and a high risk of leukemic transformation. Survival ranges from months to years and bone marrow transplantation remains the only curative option. Large sequencing studies have revealed that somatic mutations in epigenetic regulators are one of the most commonly affected pathways in MDS. DNMT3A, a de novo methyltransferase is mutated in ~10-15% of MDS patients. Murine models of DNMT3A loss have shown that hematopoietic stem cells favor self-renewal over differentiation. Loss of function mutations in DNMT3A can lead to reduction in methylation resulting in differentially methylated regions (DMRs). The effects of altered DNA methylation at promoters and enhancers on gene expression in DNMT3A mutant cells are well characterized but do not completely explain the gene expression patterns in these cells. Previous studies have shown that DNA methylation within intragenic regions affects mRNA splicing through interactions with RNA polymerase II and DNA binding proteins. Therefore, our study aimed to determine whether altered methylation caused by DNMT3A loss affects mRNA splicing and gene expression. To address this, we used CRISPR/Cas9 to genetically knockout DNMT3A in K562 cells. Findings were further evaluated using lineage- c-kit+ hematopoietic stem and progenitor cells (HSPC) from a DMNT3A conditional knock in mouse model of the most common MDS-associated DNMT3A point mutation, R878H. Our central hypothesis is that aberrant methylation caused by loss of function mutations in DNMT3A leads to changes in RNA splicing resulting in differential isoform expression of genes involved in stem cell self-renewal and hematopoiesis. Using a combination of RNA sequencing and whole genome bisulfite sequencing we found increased alternative splicing in DNMT3A mutant cells compared to wildtype cells. Integration of methylation and splicing revealed that 15-20 percent of the alternative splicing events were associated with changes in methylation. We found that many of the genes aberrantly spliced were involved in cell cycle regulation, transcriptional regulation, and hematopoietic stem cell differentiation. In addition, isoform usage analysis revealed that genes involved in RNA processing were perturbed. We identified similar splicing patterns and affected pathways in murine HSPCs and K562 human cells. Notably, the type of splicing events changed with age. Our results show that DNMT3A mutant cells have distinct alternative splicing events and suggest an aberrant epigenome can cause dysregulated gene expression through splicing. These findings shed light onto additional mechanisms by which epigenetic regulator mutations lead to MDS development. Citation Format: LaShanale Wallace, Ana Leal-Cervantes, Jacquelyn Myers, Yiping Fan, Koral Campbell, Juan Martin Barajas, Aparna Calindi, Chandra Rolle, Baranda Hansen, Shondra Miller, Esther Obeng. Alternative splicing in hematopoietic stem cells is affected by the loss of DNMT3A [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2093.

Published
2021

12. 3027 – HSC-INDEPENDENT EMP CONTAIN ERYTHROID/MEGAKARYOCYTE AND INNATE LYMPHOID/MYELOID LINEAGE HETEROGENEITY PRIOR TO SEEDING THE FETAL LIVER

Author

Merav Socolovsky, Michael W. Becker, James Palis, Jacquelyn Myers, Kathleen E. McGrath, Paul D. Kingsley, and Daniel Hidalgo

Subjects
Hemogenic endothelium, Cancer Research, Myeloid, Monocyte, Hematopoietic stem cell, Cell Biology, Hematology, Biology, Cell biology, Haematopoiesis, medicine.anatomical_structure, Megakaryocyte, embryonic structures, Genetics, medicine, Yolk sac, Progenitor cell, Molecular Biology
Abstract

Hematopoietic ontogeny unfolds in two broad programs- a complex hematopoietic stem cell (HSC)-independent program followed by an HSC-dependent program. We have previously determined that HSC-independent, multi-lineage “erythro-myeloid” progenitors (EMP) emerge from hemogenic endothelium in the yolk sac of the murine embryo and engraft the fetal liver to generate the first definitive erythroid, granulocyte, monocyte, and NK cells prior to the establishment of HSC-derived hematopoiesis. Analysis of single cell transcriptomic data from E9.5 EMP and from hematopoietic cells in the E12.5 fetal liver provides a unique opportunity to tie predictions of progenitor identity to subsequent differentiation states. We analyzed 2,959 kit+CD41+CD16/32+ yolk sac EMP and 7,495 fetal liver hematopoietic cells pooled from 30 E9.5 and 3 E12.5 embryos, respectively, using the 10X Genomics and inDrops platforms. Dimensionality reduction coupled with graph-based clustering and analysis of differentially expressed marker genes allowed us to presumptively identify erythroid-, megakaryocyte-, macrophage-, and myeloid-biased clusters both in EMP and in the E12.5 fetal liver. Functional colony-forming assays confirm the existence of primary myeloid- and erythroid-biased EMP in E9.5 embryos. E9.5 EMP also contain a cluster of innate lymphoid-biased progenitors, consistent with the recently identified NK cell lineage potential of EMP. Integration of EMP and fetal liver datasets further supported the concept that EMP consist of a surprising, early complexity of lineage-biased progenitors, whose differentiation continue in the fetal liver. Interestingly, EMP also contained a cluster of hemogenic endothelial-biased progenitors that were not found in the fetal liver, and which serve as a source of diverging erythroid/megakaryocyte and innate lymphoid/myeloid pseudotime trajectories. Taken together, our data support the concept that EMP emerge from hemogenic endothelium and begin to differentiate into multiple lineage-biased progenitors before engrafting the fetal liver to complete their differentiation along erythroid/megakaryocytic and innate immune cell paths to meet the needs of the developing embryo prior to the establishment of HSC-derived blood cell production.

Published
2020

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