Helge Hartung

Of Worms and Men: An Evolutionary Perspective on the Fibroblast Growth Factor (FGF) and FGF Receptor Families

Abstract. FGFs (fibroblast growth factors) play major roles in a number of developmental processes. Recent studies of several human disorders, and concurrent analysis of gene knock-out and properties of the corresponding recombinant proteins have shown that FGFs and their receptors are prominently involved in the development of the skeletal system in mammals. We have compared the sequences of the nine known mammalian FGFs, FGFs from other vertebrates, and three additional sequences that we extracted from existing databases: two human FGF sequences that we tentatively designated FGF10 and FGF11, and an FGF sequence from Cænorhabditis elegans. Similarly, we have compared the sequences of the four FGF receptor paralogs found in chordates with four non-chordate FGF receptors, including one recently identified in C. elegans. The comparison of FGF and FGF receptor sequences in vertebrates and nonvertebrates shows that the FGF and FGF receptor families have evolved through phases of gene duplications, one of which may have coincided with the emergence of vertebrates, in relation with their new system of body scaffold.

Murine FGF-12 and FGF-13: expression in embryonic nervous system, connective tissue and heart.

The molecular cloning of cDNAs encoding murine fibroblast growth factor-13 (FGF-13/FHF-2) and three isoforms of murine FGF-12 (FHF-1) is described. Like their highly conserved human counterparts, murine FGF-12 and FGF-13 are part of a distinct subfamily of FGF-like proteins characterized by a greater degree of amino acid sequence cross-homology and by conserved N-terminal domains which do not include secretion signal sequences. In addition to their expression in several adult tissues, both of these FGF genes are prominently and regionally expressed in midgestation mouse embryos, as revealed by in situ hybridization. Fgf12 and fgf13. RNAs were detected in developing central nervous system in cells outside the proliferating ependymal layer, and fgf13 RNA was also found throughout the peripheral nervous system. Fgf12 is expressed in developing soft connective tissue of the limb skeleton and in presumptive connective tissue linking vertebrae and ribs. Both FGF genes are also expressed in the myocardium of the heart, with fgf12 RNA found only in the atrial chamber and fgf13 RNA detected in both atrium and ventricle. On the basis of their novel structure and patterns of expression, FGF-12 and FGF-13 are anticipated to perform embryonic functions distinct from other known FGF molecules.

Genome architecture marked by retrotransposons modulates predisposition to DNA methylation in cancer

Epigenetic silencing plays an important role in cancer development. An attractive hypothesis is that local DNA features may participate in differential predisposition to gene hypermethylation. We found that, compared with methylation-resistant genes, methylation-prone genes have a lower frequency of SINE and LINE retrotransposons near their transcription start site. In several large testing sets, this distribution was highly predictive of promoter methylation. Genome-wide analysis showed that 22% of human genes were predicted to be methylation-prone in cancer; these tended to be genes that are down-regulated in cancer and that function in developmental processes. Moreover, retrotransposon distribution marks a larger fraction of methylation-prone genes compared to Polycomb group protein (PcG) marking in embryonic stem cells; indeed, PcG marking and our predictive model based on retrotransposon frequency appear to be correlated but also complementary. In summary, our data indicate that retrotransposon elements, which are widespread in our genome, are strongly associated with gene promoter DNA methylation in cancer and may in fact play a role in influencing epigenetic regulation in normal and abnormal physiological states.

Retroviral Insertional Mutagenesis Identifies Genes that Collaborate with NUP98-HOXD13 during Leukemic Transformation

The t(2;11)(q31;p15) chromosomal translocation results in a fusion between the NUP98 and HOXD13 genes and has been observed in patients with myelodysplastic syndrome (MDS) or acute myelogenous leukemia. We previously showed that expression of the NUP98-HOXD13 (NHD13) fusion gene in transgenic mice results in an invariably fatal MDS; approximately one third of mice die due to complications of severe pancytopenia, and about two thirds progress to a fatal acute leukemia. In the present study, we used retroviral insertional mutagenesis to identify genes that might collaborate with NHD13 as the MDS transformed to an acute leukemia. Newborn NHD13 transgenic mice and littermate controls were infected with the MOL4070LTR retrovirus. The onset of leukemia was accelerated, suggesting a synergistic effect between the NHD13 transgene and the genes neighboring retroviral insertion events. We identified numerous common insertion sites located near protein-coding genes and confirmed dysregulation of a subset of these by expression analyses. Among these genes were Meis1, a known collaborator of HOX and NUP98-HOX fusion genes, and Mn1, a transcriptional coactivator involved in human leukemia through fusion with the TEL gene. Other putative collaborators included Gata2, Erg, and Epor. Of note, we identified a common insertion site that was >100 kb from the nearest coding gene, but within 20 kb of the miR29a/miR29b1 microRNA locus. Both of these miRNA were up-regulated, demonstrating that retroviral insertional mutagenesis can target miRNA loci as well as protein-coding loci. Our data provide new insights into NHD13-mediated leukemogenesis as well as retroviral insertional mutagenesis mechanisms.

NUP98-HOX translocations lead to myelodysplastic syndrome in mice and men

The myelodysplastic syndromes (MDS) are a group of clonal hematopoietic stem cell disorders characterized by ineffective hematopoiesis, peripheral blood cytopenias, dysplasia, and a propensity for transformation to acute myeloid leukemia (AML). A wide spectrum of genetic aberrations has been associated with MDS, including chromosomal translocations involving the NUP98 gene, most commonly leading to fusions of NUP98 with abd-b group HOX genes, including HOXD13. We used vav regulatory elements to direct expression of a NUP98-HOXD13 (NHD13) fusion gene in hematopoietic tissues. NHD13 transgenic mice faithfully recapitulate all the key features of MDS, including peripheral blood cytopenias, bone marrow dysplasia and apoptosis, and transformation to acute leukemia. The MDS that develops in NHD13 transgenic mice is highly lethal; within 14 months, 90% of the mice died of either leukemic transformation or severe anemia and leukopenia due to progressive MDS. These mice provide a preclinical model that can be used for the evaluation of MDS therapy and biology.

Acquired Aplastic Anemia in Children

This article provides a practice-based and concise review of the etiology, diagnosis, and management of acquired aplastic anemia in children. Bone marrow transplantation, immunosuppressive therapy, and supportive care are discussed in detail. The aim is to provide the clinician with a better understanding of the disease and to offer guidelines for the management of children with this uncommon yet serious disorder.

Severe hemolytic transfusion reaction due to anti-D in a D+ patient with sickle cell disease

A 5-year-old male with sickle cell disease presented with pain, dark urine, and fatigue 10 days after a red blood cell (RBC) transfusion. Laboratory evaluation demonstrated severe anemia, blood type O+, and anti-D in the serum. Anti-D in a D+ patient led to RH genotyping, which revealed homozygosity for RHD*DAU4 that encodes partial D antigen. Anti-D in this patient whose RBCs exclusively express partial D caused a delayed hemolytic transfusion reaction after exposure to D+ RBCs. The finding of anti-D in a D+patient should be investigated by molecular methods to help distinguish an alloantibody from an autoantibody.

Red blood cell alloimmunization in transfused patients with bone marrow failure syndromes.

Red blood cell (RBC) alloimmunization is a concern for patients who receive multiple or chronic transfusions. Alloimmunization prevalence in transfused patients with bone marrow failure syndrome (BMFS) is unknown. This study aimed to determine physician practice for RBC antigen matching, immunization rates, and antibody specificities in patients with BMFS.

Disrupted lymphocyte homeostasis in hepatitis‐associated acquired aplastic anemia is associated with short telomeres

Hepatitis‐associated aplastic anemia (HAA) is a variant of acquired aplastic anemia (AA) in which immune‐mediated bone marrow failure (BMF) develops following an acute episode of seronegative hepatitis. Dyskeratosis congenita (DC) is an inherited BMF syndrome characterized by the presence of short telomeres, mucocutaneous abnormalities, and cancer predisposition. While both conditions may cause BMF and hepatic impairment, therapeutic approaches are distinct, making it imperative to establish the correct diagnosis. In clinical practice, lymphocyte telomere lengths (TL) are used as a first‐line screen to rule out inherited telomeropathies before initiating treatment for AA. To evaluate the reliability of TL in the HAA population, we performed a retrospective analysis of TL in 10 consecutively enrolled HAA patients compared to 19 patients with idiopathic AA (IAA). HAA patients had significantly shorter telomeres than IAA patients (P = 0.009), including four patients with TL at or below the 1st percentile for age‐matched controls. HAA patients had no clinical features of DC and did not carry disease‐causing mutations in known genes associated with inherited telomere disorders. Instead, short TLs were significantly correlated with severe lymphopenia and skewed lymphocyte subsets, features characteristic of HAA. Our results indicate the importance of caution in the interpretation of TL measurements in HAA, because, in this patient population, short telomeres have limited specificity. Am. J. Hematol. 91:243–247, 2016.

Abstract 2977: Most patients with acquired aplastic anemia develop clonal hematopoiesis early in disease

Proceedings: AACR 106th Annual Meeting 2015; April 18-22, 2015; Philadelphia, PA Clonal hematopoiesis is an expansion of hematopoietic stem cells, caused by somatic mutations or epigenetic changes that confer a growth advantage to the host cell. Although recently recognized as a phenomenon of aging, clonal hematopoiesis has been traditionally associated with pre-cancerous states and malignant transformation. Acquired aplastic anemia (AA), a non-neoplastic autoimmune blood disorder occurring in children and adults, has been associated with clonal hematopoietic disorders; transformation to myelodysplastic syndrome (MDS) or acute leukemia is a late complication in 10-15% of AA patients. Based on the association of AA with clonal disorders, we hypothesized that clonal hematopoiesis is a general phenomenon in AA, and can be seen in the majority of AA patients, including children. To evaluate somatic genetic changes in AA, we used a combination of single nucleotide polymorphism array (SNP-A) genotyping and comparative whole exome sequencing of paired bone marrow aspirates and skin in twenty nine patients with AA. All somatic mutations were validated by bi-directional Sanger sequencing. The median age of diagnosis was 14 years (range 1.5-65). Patients were analyzed at a median of 1.1 years from diagnosis. None of the patients had histopathological evidence of MDS at the time of analysis. Somatic mutations were identified in the majority of patients, including patients with pediatric-onset AA. Three patients (10%) had somatic loss-of-function mutations in HLA class I alleles. Although MDS-associated mutations were identified in 2 of 29 patients, the majority of mutations were not in genes associated with MDS and hematologic malignancies. Pathway analysis of mutated genes revealed an enrichment of genes in pathways of immunity and transcriptional regulation. Comparison of somatic mutations in AA to a patient with a 30-year history of AA who progressed to MDS revealed that, unlike in AA, which was characterized by diverse and frequently oligoclonal hematopoiesis, progression to MDS was associated with an expansion of a dominant clone carrying multiple classical mutations linked to malignancy: pathogenic mutations in SUZ12 (homozygous for the mutated region due to copy number-neutral loss of heterozygosity (CN-LOH) at the chromosomal region 17q11.2qter), ASXL1, RUNX1, and PHF6. In conclusion, our data show that clonal hematopoiesis emerges in the majority of patients with AA, including children and young adults, can be detected early in disease, and has a mutational spectrum largely distinct from MDS. Our results highlight that in the absence of morphologic features of myelodysplasia, the presence of clonal hematopoiesis with somatic mutations cannot be used to distinguish MDS from AA. Future longitudinal studies of clonal hematopoiesis in AA will help to explain differences in patients’ disease course, and will enable personalized treatment approaches in AA. Citation Format: Daria V. Babushok, Nieves Perdigones, Juan C. Perin, Timothy S. Olson, Wenda Ye, Jacquelyn J. Roth, Curt Lind, Carine Cattier, Yimei Li, Helge Hartung, Michele E. Paessler, Dale M. Frank, Hongbo M. Xie, Tracy M. Busse, Shanna Cross, Gregory M. Podsakoff, Dimitrios Monos, Jaclyn A. Biegel, Philip J. Mason, Monica Bessler. Most patients with acquired aplastic anemia develop clonal hematopoiesis early in disease. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 2977. doi:10.1158/1538-7445.AM2015-2977