Abstract
Fanconi anemia is an inherited disease characterized by genomic instability, hypersensitivity to DNA cross-linking agents, bone marrow failure, short stature, skeletal abnormalities, and a high relative risk of myeloid leukemia and epithelial malignancies. The 21 Fanconi anemia genes encode proteins involved in multiple nuclear biochemical pathways that effect DNA interstrand crosslink repair. In the past, bone marrow failure was attributed solely to the failure of stem cells to repair DNA. Recently, non-canonical functions of many of the Fanconi anemia proteins have been described, including modulating responses to oxidative stress, viral infection, and inflammation as well as facilitating mitophagic responses and enhancing signals that promote stem cell function and survival. Some of these functions take place in non-nuclear sites and do not depend on the DNA damage response functions of the proteins. Dysfunctions of the canonical and non-canonical pathways that drive stem cell exhaustion and neoplastic clonal selection are reviewed, and the potential therapeutic importance of fully investigating the scope and interdependences of the canonical and non-canonical pathways is emphasized.
Keywords: Fanconi anemia, hematopoiesis, stem cells, DNA repair, oxidative stress, mitophagy, autophagy, virophagy, inflammation, interferon, tumor necrosis factor, TGF, leukemogenesis, bone marrow failure, aplastic anemia, gene therapy, bone marrow transplantation
Introduction
Fanconi anemia (FA) is a rare inherited syndrome characterized by progressive bone marrow failure (BMF) and a high relative risk of hematopoietic and epithelial malignancies in children who sometimes have characteristic developmental abnormalities, including short stature and radial ray defects. Since the first clinical report of this disease 90 years ago 1, important clinical advances have included the development of the gold-standard diagnostic test (chromosomal breakage responses when lymphocytes or fibroblasts are exposed to low doses of either mitomycin C or diepoxybutane) 2– 4 and major improvements in the application of stem cell transplantation to cure the hematopoietic defect in children with FA 5– 13. Not all patients have a suitable donor, and successful transplants are not infrequently associated with the subsequent development of solid tumors and other unique ‘late effects’ 14– 17, so less toxic forms of therapy are clearly desirable. Their development does, however, require a more complete understanding of molecular pathogenesis than any of us has today. The first hurdle cleared on this point of pathogenesis was the identification of the commonly mutated genes. Since the cloning of the first gene ( FANCC) in 1992 18, 19, 20 other genes have been identified ( Table 1) and others may soon be confirmed 20. The field of DNA damage repair has advanced substantially as a result of this work, and novel factors that contribute to BMF in FA have emerged. Although this is a rare disorder, it is increasingly serving as a pathophysiological paradigm for more common acquired hematopoietic disorders in patients without FA 21– 24.
Table 1. Fanconi anemia genes.
| Gene | Synonyms | Chromosome | References |
|---|---|---|---|
| FANCA | 16q24.3 | 29 | |
| FANCC | 9q22.32 | 18, 19 | |
| FANCG | XRCC9 | 9p13.3 | 30 |
| FANCE | 6p21.31 | 31 | |
| FANCF | 11p14.3 | 32 | |
| FANCL | 2p16.1 | 33 | |
| FANCB | FAAP95 | Xp22.2 | 25 |
| FANCM | 14q21.1 | 27, 34 | |
| FANCI | 15q26.1 | 35, 36 | |
| FANCD2 | 3p25.3 | 37 | |
| FANCD1 | BRCA2 | 13q13.1 | 38 |
| FANCJ | BRIP1 | 17q23.2 | 39, 40 |
| FANCN | PALB2 | 16p12.2 | 41 |
| FANCO | RAD51C | 17q22 | 42 |
| FANCP | SLX4 | 16p13.3 | 43, 44 |
| FANCQ | ERCC4 and XPF | 16p13.12 | 45 |
| FANCR | RAD51 | 15q15.1 | 46 |
| FANCS | BRCA1 | 17q21.31 | 47, 48 |
| FANCT | UBE2T | 1q31.3 | 49 |
| FANCU | XRCC2 | 7q36.1 | 50, 51 |
| FANCV | REV7 and MAD2L2 | 1p36.22 | 52 |
Genetics
FA is an autosomal recessive disorder (except those rare cases associated with mutations of FANCB located on chromosome X 25 and autosomal dominant mutations of FANCR 26). For a DNA sequence to be considered an FA gene, an inactivating mutation must be associated with classic chromosomal breakage in response to ex vivo challenge with cross-linking agents (mitomycin C or diepoxybutane) in at least one patient and complementation with the wild-type version of the mutant alleles must correct the aberrant chromosomal breakage response. Most patients will have signs of BMF and a high likelihood of developing epithelial malignancies early in life, but few patients (for example, those with FANCM mutations) develop malignancies without first showing clinical signs of marrow failure 27. Whether the hematopoietic stem cells (HSCs) of FANCM patients are truly ‘fit’ is still in question because HSCs in the FANCM-deficient murine model have not been stringently tested in vivo (for example, using competitive repopulation analysis or exposure to inflammatory stressors) 28.
Stabilizing the genome: the canonical functions of Fanconi anemia proteins
Every FA gene encodes a protein that functions unambiguously to facilitate repair of cross-linked DNA. In response to interstrand crosslinks (ICLs), a core complex of eight proteins (FANCA, -B, -C, -E, -F, -G, -L, and -M) is required 53, 54 for monoubiquitinylation of two other proteins (FANCD2 and FANCI) 53, 35, 55– 57. This post-translational modification is required for the ‘downstream’ activation of other proteins that unhook ICLs (FANCP and FANCQ) and facilitate homologous recombination (FANCD1, -J, -N, -O, -R, -S, and -U) 58. Other nuclear functions of FA proteins in mitosis prevent aneuploidy and aberrant centrosome accumulation 59– 61. This review focuses on molecular pathogenesis in FA hematopoietic tissues and addresses the question of whether the canonical functions of the FA proteins account for all of the phenotypic features characteristic of this disease.
Hematopoietic defects and the prospects of gene therapy
Although clinical marrow failure progresses over time in the lives of patients with FA, it is clear that HSCs are defective early in development. That functionally corrective somatic mutations in a single human HSC prenatally are capable of completely replacing the hematopoietic tissues in twins by the time of birth 62 is conclusive proof that the repopulating capacity and overall fitness of the mutant HSCs are unambiguously reduced during development and can be overtaken by even one HSC in which the mutation has been corrected. This conclusion has been confirmed in human embryonic stem cells 63 and Fancc –/– and Fancd2 –/– mice 64, 65. The experiment of nature 62 provides clear theoretical evidence that if a single corrected stem cell can so massively outperform all of the mutant ones during development, gene therapy for this disease early in life (or perhaps in utero 66) can be successful in the future. In fact, many preclinical and a few clinical gene therapy studies have been completed or are ongoing 67– 72. Although there have been no clear successes in patients yet 73, the goal is within sight and entirely rational.
Endogenous cross-linking factors
Although hypersensitivity to cross-linking agents remains the sine qua non of FA diagnosis, until recently it had not been clear that cross-linking agents, apart from those that might be lurking in the external environment, played a role in the BMF so commonly found in FA. Work by Patel and colleagues has provided some important answers on this point. Having observed that alcohol dehydrogenase-5 (ADH5) deficiency results in synthetic lethality when combined with FA gene suppression in the chicken DT40 cell line 74, the group confirmed that loss of either ADH5 75 or aldehyde dehydrogenase-2 (ALDH2) 76—enzymes that catabolically inactivate formaldehyde and acetaldehyde, respectively—markedly increases the intensity and onset of severe BMF in Fancd2-deficient mice. Given the universal intolerance of FA cells to cross-linking agents (the basis of the gold-standard diagnostic test), it is not surprising that reducing the catalysis of endogenous cross-linking agents would make the disease worse, but what is clear from these studies is that endogenous aldehydes represent major threats to FA-HSCs. Based upon these findings, it was soon discovered that Japanese FA patients with the dominant negative ALDH2 allele (rs671) have accelerated BMF 77. Some investigators have proposed that steady-state endogenous aldehydes themselves account for marrow failure through DNA damage-induced cell death 78. This might be true but more experiments need to be done on this score because aldehydes are capable of cross-linking many more types of molecules than just DNA 79 and some cross-linked non-DNA targets stimulate two other inter-related processes known to be involved in FA pathogenesis, namely inflammation and oxidative stress 80– 82. Autophagosome formation can also be directly inhibited by singlet oxygen-mediated cross-linking of p62, a scaffold protein normally involved in proper autophagosome formation and function 83. Moreover, inflammatory processes can suppress the expression of ALDHs in other non-hematopoietic tissues as well as macrophages 84– 87. Therefore, in seeking pharmacological remedies for BMF in FA, one needs to consider not only agents that activate or otherwise enhance the function of ALDHs 88 but also the basic mechanisms leading to their suppression in the face of inflammation and other stressful cues. It should also be considered that normal FA proteins might enhance the activity of ALDH isoforms directly or indirectly.
Non-canonical biochemical functions contribute to molecular pathogenesis
The coordinated interactions of FA proteins play an essential role in responding to environmental toxins, and the loss of function of any one of them destabilizes genomes. Because these proteins are so unambiguously essential in nuclear processes that protect and repair the genome, there has been a widespread tendency to simply attribute HSC dysfunction to accrued DNA damage and cell death resulting from the lost canonical functions of the proteins in DNA repair. However, recently, studies have shown that at least some of the FA proteins participate in control of signaling pathways that stress HSCs and the loss of those functions can play a role in disease progression.
Two things have become clear: (1) while all FA proteins play a role in stabilizing the genome, many of them have additional functions 89– 100, some of which are independent of other FA proteins or effected outside the nuclear envelope 90– 93 and some are functionally independent of the DNA damage response 102– 104, and (2) important endogenous factors that suppress FA HSC function are emerging and include proteins normally involved in the inflammatory response 91, 93, 94, 105– 108, pathways functionally linked to or activated by inflammation, including oxidative stress 109– 117, mitophagy 102, and the production of endogenous aldehydes 74– 77, 118. Some of the non-canonical functions of FA proteins are listed in Table 2. In light of these disparate functions, it is no surprise that the cellular consequences of FA mutations in HSCs would necessarily include loss of quiescence 108, 119, 120, excessive apoptosis when challenged with inflammatory cytokines or redox stress 110, 121, 122, and ultimately progressive stem cell attrition in the face of inflammatory stress 108, 123.
Table 2. Non-canonical functions of Fanconi anemia proteins.
| Fanconi anemia
proteins |
Biochemical function | Expected effects |
|---|---|---|
| FANCD2 and
FANCA |
In response to oxidative stress, FANCD2 and FANCA form a
complex with BRG1 within promoters of antioxidant genes 128. |
Enhance antioxidant defenses |
| FANCD2 | Binds to FOXO3A and reduces reactive oxygen species (ROS)
accumulation and enhances antioxidant gene expression 129. |
Reduces accumulation of ROS and
enhances cellular resistance to oxidative stress |
| FANCG | Binds to and stabilizes mitochondrial PRDX3. Loss of FANCA or
FANCC also destabilizes PRDX3 98. |
Enhances resistance to resistance to
H 2O 2 and mitomycin C |
| FANCC | Binds GSTP1 and activates its activity in response to apoptotic
stimuli 110. |
Prevents apoptosis in growth factor-
deprived hematopoietic cells |
| FANCN | Binds to KEAP1 99 | Enhances the oxidative stress response |
| FANCC, -A,
-F, -L, -D1, -D2, and -S |
Clear damaged mitochondria (mitophagy)
102.
FANCA and FANCC interact with Parkin and translocate to damaged mitochondria. Knockdown of FANCC, -F, or -L leads to defective selective autophagy 101. |
Decrease mitochondrial ROS production
136
Reduce activation of inflammasomes 130 |
| FANCD2 | Localizes to mitochondria and interacts with mitochondrial protein
(Atad3) 100. |
Stabilizes mitochondria, enhances
cisplatin resistance, and suppresses apoptosis 137 |
| FANCP | Using different domains, FANCP interacts with XPF and ERCC1
to repair interstrand crosslinks and interacts with MUS81 to resist TOP1 inhibitors 89. |
Mediates resistance to both cross-linking
agents and topoisomerase I inhibitors |
| FANCD2 and
FANCA |
Suppress transforming growth factor beta signaling in
hematopoietic stem and progenitor cells (HSPCs) in the ground state and during inflammatory stress and enhance expression of genes involved in homologous recombination 94. |
Enhance HSPC survival and function in
the face of inflammation and cross-linking agents |
| FANCC | Binds hsp70 and suppresses the kinase activity of PKR
independently of the core complex 91, 93. |
Enhances survival of cells exposed to
inflammatory cytokines |
| FANCC | Binds to and facilitates activation of STAT1 in response to
hematopoietic growth factors 90, 92. |
Facilitates hematopoietic growth factor
signaling |
| FANCC and
FANCA |
Suppress Toll-like receptor (TLR)-induced tumor necrosis
factor alpha ( TNFα) and interleukin 1 beta ( IL-1β) expression in macrophages 130, 132. |
Prevent overproduction of inflammatory
cytokines in macrophages |
| FANCC | Complexes with CtBP1 and suppresses
DKK1 (a
WNT
suppressor) gene expression 133. |
Facilitates WNT signaling and
hematopoietic stem cell self-renewal |
| FANCL | Ubiquitinates beta-catenin, enhancing its nuclear function 134. | Enhances pluripotency of HSPCs |
| FANCP | Suppresses accumulation of cytoplasmic DNA and the
consequent activation of the interferon pathway 135. |
Suppresses cGAS-STING and reduces
pro-inflammatory cytokine production induced by replication stress |
| FANCD2 and
FANCI |
Associate with the spliceosomal protein SF3B1 independently of
the core complex and influence SF3B1 trafficking 97. |
Enhance stem cell function
138, coordinate
DNA replication and co-transcriptional processes, and likely enhance erythropoiesis |
Inflammation: a damaging stressor in Fanconi anemia hematopoietic cells
Because of the known myelosuppressive role of interferon gamma (IFNγ) in the pathogenesis of acquired aplastic anemia 124– 126, early in vitro studies on FA cells were conducted to test the idea that FA cells might somehow be hypersensitive to this and other known inhibitory cytokines (for example, tumor necrosis factor [TNF]). These studies were positive 105, 106, 127 and led to the identification of some non-canonical signaling pathways with which FA proteins were directly involved 91, 93. These early studies were conducted in vitro, but more recent work has unambiguously confirmed that murine FA stem cells are uniquely vulnerable to inflammatory stresses of many different kinds 108, 123 and that, in one informative model, blocking the function of the inflammatory cytokine interleukin 1 beta (IL-1β) (a suppressor of FA HSC proliferation in vitro) 130 prevented marrow failure 123. Multiple inflammatory cytokines and adhesion molecules are involved in the inflammatory response, including factors that can enhance and others that inhibit the replicative capacity of hematopoietic stem and progenitor cells (HSPCs), so it will be important to sort out whether the ‘replicative stress’ induced in the FA HSPC pool plays a role in damaging the cells or whether the suppressive and pro-apoptotic and differentiation-inducing effects of inflammatory cytokines cause them to perish. But the inflammatory response and its association with oxidative stress (to which FA cells are also hypersensitive 128, 129, 139– 141) provide opportunities for pharmacological intervention either in the ground state or during episodes of overt inflammation.
A variety of complex indirect effects likely account for some of the inflammatory vulnerabilities of FA HSCs. For example, wild-type FANCC interacts with hsp70 to suppress activation of eukaryotic translation initiation factor 2-alpha kinase 2 (PKR) in wild-type cells exposed to IFNγ and double-stranded RNA or IFN and TNF. The interaction involves the canonical substrate-binding domain of HSP70, and loss of the FANCC/hsp70 interaction results in hyperactivation of PKR in FA cells 91, 93, 107. Interestingly, mutations of FANCA, FANCG, and FANCC enhance the binding interaction of FANCC and PKR and result in PKR hyperactivation as well 142. The recently described differential FANCA-binding functions of HSP90 and HSP70 and the functional consequences of such differential binding on the canonical function of various FANCA mutant substrates 143 add to the complexity of the future in vivo studies now required to confirm that these effects are truly independent of induced DNA damage. Finally, that ALDH and hsp70 are induced by and collaborate to control certain viral infections 144 suggests that the relationships between ALDH, heat shock proteins, IFN-dependent pathways, and FA proteins should also be formally examined because they may be perturbed interdependently in FA cells.
Macrophage dysfunction fans the flames
One of the additional challenges associated with the aberrant FA inflammatory response is that FA mononuclear phagocytes, the progeny of FA HSCs, overproduce such cytokines in response to Toll-like receptor (TLR) activation 104, 130, 132– 145. So the pharmacological suppression of induced cytokine production or function may also reduce the stress on the HSPC pool. Some preliminary in vitro evidence of this had been reported 145, but the scope of non-canonical signaling defects in FA is increasingly broad and involves interdependent pathways that pose a challenge for picking a particular molecular focus. Cross-talking environmental cues that induce inflammation, for example, regularly induce oxidative stress 146– 149 and enhance endogenous aldehyde loads 82, 84, 86. Any one of these stressors can excessively suppress FA HSPCs and induce hyperactive inflammatory cytokine production in more well-differentiated myeloid cells.
Mitophagic defects
Some FA proteins now provide novel functional insights on long-recognized ties between inflammation and oxidative stress. Many of the non-canonical functions outlined in Table 2 have to do with controlling oxidative stress. For example, FANCC and FANCA normally participate in mitophagic responses by binding to Parkin (which itself is known to play a role in removing damaged mitochondria 150), thereby clearing damaged mitochondria and reducing reactive oxygen species. Knockdown of FANCC, -F, or - L also leads to defective mitophagy 101. Importantly, the function of FANCC in Parkin-mediated mitophagy is independent of its role in genomic DNA damage repair 102. This point was recently demonstrated by using a FANCC mutant which does not rectify the dysfunction induced by FA mutations in the canonical pathway but does correct the Parkin-mediated mitophagic function of the protein 102. This same FANCC mutant (c.67delG, also known as 322delG) also rescues defective STAT1 activation in FANCC-deficient cells without correcting the canonical pathway 90, 92 and is reportedly associated with a milder phenotype 151, suggesting that parallel non-canonical pathways contribute to progression of BMF in FA.
Experimental therapeutics
In small-molecule therapy of FA, target candidates could include hyperactive signaling pathways in mutant cells that include p53 and p21 152, PKR 91, p38 MAPK 130, 141, the TLR pathway (p38 MAPK and MK2) 130, 132, and, most recently, hyperactive transforming growth factor beta (TGFβ) signaling 94. The ideal therapeutic agent would be one that in vivo: (1) reduces chromosomal breakage of all FA somatic cells exposed to endogenous and exogenous cross-linking agents, (2) enhances survival of FA cells exposed to genotoxic agents, (3) relieves the defects in FA HSCs in the ground state and in the face of inflammatory challenges, (4) reduces overproduction of or aberrant responses to reactive oxygen species, (5) enhances the metabolic inactivation of endogenous aldehydes, and (6) relieves the overproduction of inflammatory cytokines in more well-differentiated cells (hematopoietic and otherwise). In fact, the TGFβ ‘pathway’ results in many of these favorable responses in FA cells 94, so it is currently an appealing target.
Transforming growth factor beta signaling
Antibody-mediated inhibition of the myelosuppressive protein TGFβ enhanced survival and performance of murine Fancd2 –/– HSCs, increased the percentage of quiescent HSPCs in Fancd2-deficient mice after exposure to polyinosinic:polycytidylic acid (pI:pC), and prevented pI:pC-induced marrow failure. Interestingly, the titer of DNA damage in mutant HSPCs was also reduced by the treatment with the antibody, a finding that led to the discovery that TGFβ inhibition enhanced homologous recombination repair of double-strand breaks (more likely to be error-free 153) and decreased non-homologous end joining (error prone 153) in FA cells and the confirmation that the same effect could be achieved by using a small-molecule inhibitor (SD208) 94. Why the TGFβ pathway is hyperactivated in FA cells is unclear, so a number of important questions remain to be addressed, including the potential impact on induced cytokine production in FA auxiliary cells (for example, macrophages) and on expression of various ALDHs in both auxiliary cells and HSCs. The role of non-SMAD signaling pathways 154, 155 ought to be tested, particularly since some of them are known to be involved in TLR hyper-responsiveness in FA macrophages 130, 131 and in suppression of FA erythropoiesis in vitro 145. Paracrine and autocrine sources of such factors must be identified and HSPC subtypes need to be carefully investigated because responses to TGFβ pathway disruption of various subsets can differ substantially 156. Ruling out functional interference with other molecules of the 33-member TGFβ superfamily 157 (for example, BMP-6) 158, 159 would help address safety concerns for any candidate molecule as would consideration of the anti-oncogenic function of TGFβ1 in modulating the transforming activity of HOXA9 160. This latter point is essential given the known high risk in FA patients of clonal evolution to myelodysplastic syndrome or acute myeloid leukemia. Nonetheless, although more work is required, the identification of the TGFβ pathway as a potential therapeutic target is buttressed by having met more standards for pharmacological candidacy than any other small-molecule approach to date.
Evolution and clonal selection
Loss of the non-canonical functions of the FA proteins likely serves to exacerbate or activate processes that result in HSC dysfunction. Involvement of these proteins in protection from oxidative stress, inflammatory cues, and endogenous aldehydes and in facilitating selective autophagic responses occurs, at least in part, by way of parallel pathways that have evolved to protect the genome and protect germ cells 106, 161, 162 and HSCs. This makes evolutionary sense. In multicellular organisms, this would simply ensure that loss of FA protein function would be attended by loss of fitness in the stem cell pool, limiting the rapid emergence of mutants. Unfortunately, in patients with FA, loss of HSC fitness leads most frequently to life-threatening BMF.
In nature, three things can happen to FA HSCs and two of them are undesirable. HSCs take the one good path least commonly. Here, a single FA HSC can mutate in a way that causes reversion of the mutation on one of the FA alleles (known as mosaicism 163– 165). In some cases in which mosaicism occurred in utero, the progeny of one mutant stem cell replaced the entire hematopoietic systems of twins, neither of whom ever developed BMF 62. The second pathway, stem cell death and stem cell exhaustion, leads to the first of two undesirable outcomes, BMF. This is the most common early life-threatening complication in patients with FA. The third pathway is the selection of neoplastic stem cell clones. In this process, the loss of HSC fitness in the face of such an unstable genome creates an opportunity for selection of stem cell clones that have gained, through somatic mutations, a new capacity to either exploit or resist the very factors that had previously controlled their state of unfitness.
For example, FA hematopoietic progenitor cells are characteristically suppressed by TNF and IFNγ in vitro during the non-clonal aplastic phase have been seen to proliferate abundantly in response to IFNγ and TNF in vitro during the myelodysplastic (clonal) phase 23. This process has also been confirmed in FA mice. Specifically, exposure of Fancc-deficient HSPCs to both growth factors and the inhibitory factor TNF in vitro suppressed their growth compared with the growth of wild-type cells, but over time, in some cases, rapid in vitro growth of FA-deficient cells ensued. The rapidly proliferating cells had clonal cytogenetic defects and had acquired resistance to TNF. When transplanted into congenic wild-type mice, they induced fatal acute myelogenous leukemia 166. The canonical pathway in these surviving leukemic cells was still fully defective but they had gained a survival advantage by ‘quasi-adaptively’ developing cytokine resistance.
The idea of multifunctionality of some of the FA proteins has met with some resistance in large part because the non-canonical processes affected can be either the cause of DNA damage or a consequence of it. To those who would argue that non-canonical pathways play a minor role or no role at all in reducing fitness of FA HSCs and that all non-canonical functions of FA proteins described to date are simply downstream consequences of DNA damage, I would raise two points. First, the natural selection of ‘adapted’ stem cell clones serves as evidence that non-canonical pathways are involved and contribute in a major way to the selection of neoplastic clonal hematopoiesis. Second, it is worth re-emphasizing that the murine models of FA develop truly fulminant BMF only when an inflammatory response is provoked in vivo 108, 123, so even if the non-canonical functions play a minor role, interdiction of the non-canonical phenomena that provoke stem cell attrition should have therapeutic value. In fact, Eklund’s group has shown that this is the case at least in FA mice 123. These observations have created some enthusiasm for attacking the molecular basis of stress intolerances in FA cells. They also create hope that by reducing selective pressures and selective inflammatory sweeps through the FA HSC pool, BMF could be prevented or forestalled and neoplastic clones would not emerge.
In summary, the advances in the FA field are exciting. They have resulted not only from a focus of the research community on the biochemistry of DNA damage repair but from an increasing recognition that the FA proteins are multifunctional and participate directly in biochemical pathways that effect protective responses to endogenous aldehydes, oxidative stress, inflammation, mitophagy, and virophagy. This increasingly complex expansion of the FA field may lead to more holistic clarity on molecular pathogenesis not only of BMF, leukemogenesis and cancer but of skeletal and cutaneous manifestations of this disease. Finally, today we recognize that this disease provides a uniquely informative window through which we can view more clearly the potential role of selective sweeps in the pathogenesis of myeloid neoplasms in the general population 21, 22, 167.
Editorial Note on the Review Process
F1000 Faculty Reviews are commissioned from members of the prestigious F1000 Faculty and are edited as a service to readers. In order to make these reviews as comprehensive and accessible as possible, the referees provide input before publication and only the final, revised version is published. The referees who approved the final version are listed with their names and affiliations but without their reports on earlier versions (any comments will already have been addressed in the published version).
The referees who approved this article are:
Alex Lyakhovich, Biomedical Research in Cancer Stem Cells, Vall d'Hebron Research Institute, Barcelona, Spain
Jakub Tolar, Department of Pediatrics, University of Minnesota, Minneapolis, USA
Andrew Deans, St. Vincent's Institute of Medical Research, Fitzroy, Victoria, Australia
Qishen Pang, Division of Experimental Hematology and Cancer Biology, Cincinnati Children's Hospital Medical Center, Cincinnati, Ohio, USA
Funding Statement
This work was supported by National Institutes of Health Grants (P01 HL048546, R01 CA 1138237, P30 CA69533) and the U.S. Department of Veterans Affairs (Merit Review).
The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
[version 1; referees: 4 approved]
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