Fanconi Anemia Signaling Research Articles

Multiomics analysis reveal the impact of 17α-Ethinylestradiol on mortality in juvenile zebrafish

17α-Ethinylestradiol (EE2) is known for its endocrine-disrupting effects on embryonic and adult fish. However, its impact on juvenile zebrafish has not been well established. In this study, juvenile zebrafish were exposed to EE2 at concentrations of 5 ng/L (low dose, L), 10 ng/L (medium dose, M), and 50 ng/L (high dose, H) from 21 days post-fertilization (dpf) to 49 dpf. We assessed their growth, development, behavior, transcriptome, and metabolome. The findings showed that the survival rate in the EE2-H group was 66.8 %, with all surviving fish displaying stunted growth and swollen, transparent abdomens by 49 dpf. Moreover, severe organ deformities were observed in the gills, kidneys, intestines, and heart of fish in both the EE2-H and EE2-M groups. Co-expression analysis of mRNA and lncRNA revealed that EE2 downregulated the transcription of key genes involved in the cell cycle, DNA replication, and Fanconi anemia signaling pathways. Additionally, metabolomic analysis indicated that EE2 influenced metabolism and development-related signaling pathways. These pathways were also significantly identified based on the genes regulated by lncRNA. Consequently, EE2 induced organ deformities and mortality in juvenile zebrafish by disrupting signaling pathways associated with development and metabolism. The results of this study offer new mechanistic insights into the adverse effects of EE2 on juvenile zebrafish based on multiomics analysis. The juvenile zebrafish are highly sensitive to EE2 exposure, which is not limited to adult and embryonic stages. It is a potential model for studying developmental toxicity.

Somatic gene mutations involved in DNA damage response/Fanconi anemia signaling are tissue- and cell-type specific in human solid tumors.

With significant advancements in the study of DNA Damage Response (DDR) and Fanconi Anemia (FA) signaling, we previously introduced the term "FA signaling" to encompass "all signaling transductions involving one or more FA proteins." This network has now evolved into the largest cellular defense network, integrating over 30 key players, including ATM, ATR, BLM, HRR6, RAD18, FANCA, FANCB, FANCC, BRCA2, FANCD2, FANCE, FANCF, FANCG, FANCI, BRIP1, FANCL, FANCM, PALB2, RAD51C, SLX4, ERCC4, RAD51, BRCA1, UBE2T, XRCC2, MAD2L2, RFWD3, FAAP20, FAAP24, FAAP100, and CENPX. This system responds to both endogenous and exogenous cellular insults. However, the mutational signatures associated with this defense mechanism in non-FA human cancers have not been extensively explored. In this study, we report that different types of human cancers are characterized by distinct somatically mutated genes related to DDR/FA signaling, each accompanied by a unique spectrum of potential driver mutations. For example, in pan-cancer samples, ATM emerges as the most frequently mutated gene (5%) among the 31 genes analyzed, with the highest number of potential driver mutations (1714), followed by BRCA2 (4% with 970 putative driver mutations). However, this pattern is not universal across specific cancer types. For example, FANCT is the most frequently mutated gene in breast (14%) and liver (4%) cancers. In addition, the alteration frequency of DDR/FA signaling due to these mutations exceeds 70% in a subtype of prostate cancer, with each subtype of brain, breast, lung, and prostate cancers displaying distinct patterns of gene alteration frequency. Furthermore, these gene alteration patterns significantly impact patient survival and disease-free periods. Collectively, our findings not only enhance our understanding of cancer development and progression but also have significant implications for cancer patient care and prognosis, particularly in the development of effective therapeutic strategies.

Mutation spectrum, expression profiling, and prognosis evaluation of Fanconi anemia signaling pathway genes for 4259 patients with myelodysplastic syndromes or acute myeloid leukemia

BackgroundIndividuals diagnosed with Fanconi anemia (FA), an uncommon disorder characterized by chromosomal instability affecting the FA signaling pathway, exhibit heightened vulnerability to the onset of myelodysplastic syndromes (MDS) or acute myeloid leukemia (AML).MethodsHerein, we employed diverse bioinformatics and statistical analyses to investigate the potential associations between the expression/mutation patterns of FA pathway genes and MDS/AML.ResultsThe study included 4295 samples, comprising 3235 AML and 1024 MDS from our and nine other online cohorts. We investigated the distinct proportion of race, age, French-American-British, and gender factors. Compared to the FA wild-type group, we observed a decrease in the expression of FNACD2, FANCI, and RAD51C in the FA mutation group. The FA mutation group exhibited a more favorable clinical overall survival prognosis. We developed a random forest classifier and a decision tree based on FA gene expression for cytogenetic risk assessment. Furthermore, we created an FA-related Nomogram to predict survival rates in AML patients.ConclusionsThis investigation facilitates a deeper understanding of the functional links between FA and MDS/AML.

Establishing a novel Fanconi anemia signaling pathway-associated prognostic model and tumor clustering for pediatric acute myeloid leukemia patients.

Considering the connection between the Fanconi anemia (FA) signaling pathway and tumor development, we aim to investigate the links between the FA gene expression and the survival prognosis of acute myeloid leukemia (AML) patients. Our study begins by identifying two distinct clusters of pediatric AML patients. Following the batch matching of the TARGET-AML, TCGA-LAML GSE71014, GSE12417, and GSE37642 cohorts, the samples were divided into a training set and an internal validation set. A Lasso regression modeling analysis was performed to identify five signatures: BRIP1, FANCC, FANCL, MAD2L2, and RFWD3. The AML samples were stratified into high- and low-risk groups by evaluating the risk scores. The AML high-risk patients showed a poorer overall survival prognosis. To predict the survival rates, we developed an FA Nomogram incorporating risk score, gender, age, and French-American-British classification. We further utilized the BEAT-AML cohort for the external validation of FA-associated prognostic models and observed good clinical validity. Additionally, we found a correlation between DNA repair, cell cycle, and peroxide-related metabolic events and FA-related high/low risk or cluster 1/2. In summary, our novel FA-associated prognostic models promise to enhance the prediction of pediatric AML prognosis.

FBXL12 degrades FANCD2 to regulate replication recovery and promote cancer cell survival under conditions of replication stress

Fanconi anemia (FA) signaling, a key genomic maintenance pathway, is activated in response to replication stress. Here, we report that phosphorylation of the pivotal pathway protein FANCD2 by CHK1 triggers its FBXL12-dependent proteasomal degradation, facilitating FANCD2 clearance at stalled replication forks. This promotes efficient DNA replication under conditions of CYCLIN E- and drug-induced replication stress. Reconstituting FANCD2-deficient fibroblasts with phosphodegron mutants failed to re-establish fork progression. In the absence of FBXL12, FANCD2 becomes trapped on chromatin, leading to replication stress and excessive DNA damage. In human cancers, FBXL12, CYCLIN E, and FA signaling are positively correlated, and FBXL12 upregulation is linked to reduced survival in patients with high CYCLIN E-expressing breast tumors. Finally, depletion of FBXL12 exacerbated oncogene-induced replication stress and sensitized cancer cells to drug-induced replication stress by WEE1 inhibition. Collectively, our results indicate that FBXL12 constitutes a vulnerability and a potential therapeutic target in CYCLIN E-overexpressing cancers.

Endogenous Electric Field-Coupled PD@BP Biomimetic Periosteum Promotes Bone Regeneration through Sensory Nerve via Fanconi Anemia Signaling Pathway.

To treat bone defects, repairing the nerve-rich periosteum is critical for repairing the local electric field. In this study, an endogenous electric field is coupled with 2D black phosphorus electroactive periosteum to explore its role in promoting bone regeneration through nerves. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) are used to characterize the electrically active biomimetic periosteum. Here, the in vitro effects exerted by the electrically active periosteum on the transformation of Schwann cells into the repair phenotype, axon initial segment (AIS) and dense core vesicle (DCV) of sensory neurons, and bone marrow mesenchymal stem cells are assessed using SEM, immunofluorescence, RNA-sequencing, and calcium ion probes. The electrically active periosteum stimulates Schwann cells into a neuroprotective phenotype via the Fanconi anemia pathway, enhances the AIS effect of sensory neurons, regulates DCV transport, and releases neurotransmitters, promoting the osteogenic transformation of bone marrow mesenchymal stem cells. Microcomputed tomography and other in vivo techniques are used to study the effects of the electrically active periosteum on bone regeneration. The results show that the electrically active periosteum promotes nerve-induced osteogenic repair, providing a potential clinical strategy for bone regeneration.

And-1 Coordinates with the FANCM Complex to Regulate Fanconi Anemia Signaling and Cisplatin Resistance.

This work shows that phosphorylation of And-1 by ATR activates Fanconi anemia signaling at interstrand crosslink-stalled replication forks by recruiting the FANCM/FAAP24 complex, revealing And-1 as a potential therapeutic target in cancer.

Focal Point of Fanconi Anemia Signaling.

Among human genetic diseases, Fanconi Anemia (FA) tops all with its largest number of health complications in nearly all human organ systems, suggesting the significant roles played by FA genes in the maintenance of human health. With the accumulated research on FA, the encoded protein products by FA genes have been building up to the biggest cell defense signaling network, composed of not only 22+ FA proteins but also ATM, ATR, and many other non-FA proteins. The FA D2 group protein (FANCD2) and its paralog form the focal point of FA signaling to converge the effects of its upstream players in response to a variety of cellular insults and simultaneously with downstream players to protect humans from contracting diseases, including aging and cancer. In this review, we update and discuss how the FA signaling crucially eases cellular stresses through understanding its focal point.

Gefitinib and Afatinib Show Potential Efficacy for Fanconi Anemia-Related Head and Neck Cancer.

Fanconi anemia rare disease is characterized by bone marrow failure and a high predisposition to solid tumors, especially head and neck squamous cell carcinoma (HNSCC). Patients with Fanconi anemia with HNSCC are not eligible for conventional therapies due to high toxicity in healthy cells, predominantly hematotoxicity, and the only treatment currently available is surgical resection. In this work, we searched and validated two already approved drugs as new potential therapies for HNSCC in patients with Fanconi anemia. We conducted a high-content screening of 3,802 drugs in a FANCA-deficient tumor cell line to identify nongenotoxic drugs with cytotoxic/cytostatic activity. The best candidates were further studied in vitro and in vivo for efficacy and safety. Several FDA/European Medicines Agency (EMA)-approved anticancer drugs showed cancer-specific lethality or cell growth inhibition in Fanconi anemia HNSCC cell lines. The two best candidates, gefitinib and afatinib, EGFR inhibitors approved for non-small cell lung cancer (NSCLC), displayed nontumor/tumor IC50 ratios of approximately 400 and approximately 100 times, respectively. Neither gefitinib nor afatinib activated the Fanconi anemia signaling pathway or induced chromosomal fragility in Fanconi anemia cell lines. Importantly, both drugs inhibited tumor growth in xenograft experiments in immunodeficient mice using two Fanconi anemia patient-derived HNSCCs. Finally, in vivo toxicity studies in Fanca-deficient mice showed that administration of gefitinib or afatinib was well-tolerated, displayed manageable side effects, no toxicity to bone marrow progenitors, and did not alter any hematologic parameters. Our data present a complete preclinical analysis and promising therapeutic line of the first FDA/EMA-approved anticancer drugs exerting cancer-specific toxicity for HNSCC in patients with Fanconi anemia.

New Understanding of Fanconi Anemia Signaling Network upon Studying FANCD2

New Understanding of Fanconi Anemia Signaling Network upon Studying FANCD2

FANCD2 and DNA Damage.

Investigators have dedicated considerable effort to understanding the molecular basis underlying Fanconi Anemia (FA), a rare human genetic disease featuring an extremely high incidence of cancer and many congenital defects. Among those studies, FA group D2 protein (FANCD2) has emerged as the focal point of FA signaling and plays crucial roles in multiple aspects of cellular life, especially in the cellular responses to DNA damage. Here, we discuss the recent and relevant studies to provide an updated review on the roles of FANCD2 in the DNA damage response.

Involvement of FANCD2 in Energy Metabolism via ATP5\u03b1

Growing evidence supports a general hypothesis that aging and cancer are diseases related to energy metabolism. However, the involvement of Fanconi Anemia (FA) signaling, a unique genetic model system for studying human aging or cancer, in energy metabolism remains elusive. Here, we report that FA complementation group D2 protein (FANCD2) functionally impacts mitochondrial ATP production through its interaction with ATP5α, whereas this relationship was not observed in the mutant FANCD2 (K561R)-carrying cells. Moreover, while ATP5α is present within the mitochondria in wild-type cells, it is instead located mostly outside in cells that carry the non-monoubiquitinated FANCD2. In addition, mitochondrial ATP production is significantly reduced in these cells, compared to those cells carrying wtFANCD2. We identified one region (AA42-72) of ATP5α, contributing to the interaction between ATP5α and FANCD2, which was confirmed by protein docking analysis. Further, we demonstrated that mtATP5α (∆AA42-72) showed an aberrant localization, and resulted in a decreased ATP production, similar to what was observed in non-monoubiquitinated FANCD2-carrying cells. Collectively, our study demonstrates a novel role of FANCD2 in governing cellular ATP production, and advances our understanding of how defective FA signaling contributes to aging and cancer at the energy metabolism level.

LNK (SH2B3) Deficiency Ameliorates Hematopoietic Stem Cell Defects in Fanconi Anemi

Fanconi Anemia (FA) is one of the most common inherited bone marrow failure (iBMF) syndromes. Although initially identified over 85 years ago, FA remains a fatal genetic disease. Nineteen FA genes cooperate in a genome stability pathway that is essential for repair of DNA damage and tolerance of replication stress. Cells derived from FA patients are hypersensitive to DNA interstrand crosslink (ICL)-inducing agents, such as Mitomycin C (MMC), and exhibit DNA damage checkpoint and mitosis defects. Mutations in FA genes result in hematopoietic stem cell (HSC) defects, bone marrow failure and cancer predisposition. Importantly, interventions to mitigate HSC defects do not exist, aside from allogeneic bone marrow transplantation (BMT).HSCs deficient for FancD2, a central component of the FA signaling pathway, are markedly compromised in reconstituting the hematopoietic system in murine BMT models. Remarkably, we found that loss of the adaptor protein Lnk (also called Sh2b3) restores HSC function in FancD2 knockout mice without accelerating neoplastic transformation. LNK negatively regulates HSC self-renewal, in part by attenuating cytokine signaling-activated JAK2 signaling in HSCs (J Clin Invest. 2008;118(8):2832-2844). Fancd2-/-;Lnk-/- (DKO) mice exhibit increased phenotypic HSCs in comparison to wildtype (WT) animals, and DKOHSC function is also largely restored to WT levels in serial transplantation assays. Primary DKOHSC and progenitors (HSPCs) are still sensitive to MMC, indicating that LNK does not play an overt role in ICL repair. Instead, Lnk deficiency notably reduces spontaneous DNA damage and genome instability. This is in agreement with recent studies that reveal a requirement for FA proteins in replication stress, which is a separable function from their role in DNA repair (Cell. 2011;145(4):529-542; Cancer Cell. 2012;22(1):106-116). Strikingly, we demonstrated that Lnk deficiency mitigates replication stress by stabilizing stalled replication forks, and that this effect is dependent upon cytokine signaling.Together, our data demonstrate that Lnk deficiency ameliorates FA HSPC defects by alleviating replication stress associated DNA damage and genome instability. To our knowledge, this is one of the first examples of in vivo genetic suppression of FA-associated HSPC defects. Our work sheds light on mechanisms underlying the origin of bone marrow failure in FA patients and has implications for new therapeutic strategies to treat FA associated bone marrow failure. DisclosuresNo relevant conflicts of interest to declare.

FANCA Fine-Tunes Chromosome Segregation By Controlling BUBR1K250 Acetylation at the Kinetochores

Fanconi anemia (FA) is an inherited bone marrow failure syndrome associated with genomic instability, high risk of acute myeloid leukemia (AML) and other malignancies. Somatic mutations within the FA/BRCA signaling network occur in AML in the general population, reflecting the importance of FA genes in tumor suppression. While the role of FA signaling in DNA damage repair and replication is well-established, we and others found that the FA network is essential for error-free chromosome segregation during cell division. Both interphase and mitotic errors contribute to the evolution of genomic instability during FA-/- human and murine hematopoiesis in vivo. However, the molecular mechanisms of FA pathway-dependent genome housekeeping during mitosis are incompletely understood.Through a synthetic lethal kinome-wide shRNA screen in FANCA patient cells, we discovered interphase and mitotic phosphosignaling networks that FANCA-/- cells depend on for survival, including the BUB1-BUBR1 axis of the spindle assembly checkpoint (SAC). BUB1 and BUBR1 are essential SAC kinases that prevent premature anaphase onset and chromosome mis-segregation by inhibiting the APC (anaphase-promoting complex) ubiquitin ligase at the centromeres until all kinetochores achieve correct attachment to the spindle microtubules. Our super-resolution microscopy and biochemistry experiments revealed that FANCA shuttles to kinetochores upon mitotic entry and physically interacts with BUB1 and BUBR1 at the kinetochore-microtubule attachment sites in attachment- and tension-dependent manner. Consistent with impaired SAC, we found that that anaphase onset as well as APC-mediated degradation of cyclin B1, BUBR1 and CDC20 all occur prematurely in FANCA-/- cells. We found that FANCA is essential for BUBR1 lysine 250 (K-250) acetylation at prometaphase kinetochores, and we confirmed that endogenous BUBR1K250 acetylation is disrupted in FANCA-/- primary patient cells using a validated acetyl-specific antibody. BUBR1K250 acetylation event works as a molecular switch in which BUBR1 is converted from a degradation target to a potent inhibitor of the APC ligase. Further, we observed that loss of FANCA disrupts kinetochore recruitment of the BUBR1K250 acetyltransferase PCAF and its upstream regulator, FANCD1/BRCA2.Our findings establish the first mechanistic connection between FANCA, the canonical SAC tumor suppressor cascade and the FA effector FANCD1/BRCA2. These findings further our understanding of the mechanisms of genomic instability and carcinogenesis resulting from loss of FA signaling. Since impaired BUBR1K250 acetylation causes chromosomal instability and cancer in vivo, our results have a direct translational relevance. [Display omitted] DisclosuresNo relevant conflicts of interest to declare.

BLM promotes the activation of Fanconi Anemia signaling pathway.

Mutations in the human RecQ helicase, BLM, causes Bloom Syndrome, which is a rare autosomal recessive disorder and characterized by genomic instability and an increased risk of cancer. Fanconi Anemia (FA), resulting from mutations in any of the 19 known FA genes and those yet to be known, is also characterized by chromosomal instability and a high incidence of cancer. BLM helicase and FA proteins, therefore, may work in a common tumor-suppressor signaling pathway. To date, it remains largely unclear as to how BLM and FA proteins work concurrently in the maintenance of genome stability. Here we report that BLM is involved in the early activation of FA group D2 protein (FANCD2). We found that FANCD2 activation is substantially delayed and attenuated in crosslinking agent-treated cells harboring deficient Blm compared to similarly treated control cells with sufficient BLM. We also identified that the domain VI of BLM plays an essential role in promoting FANCD2 activation in cells treated with DNA crosslinking agents, especially ultraviolet B. The similar biological effects performed by ΔVI-BLM and inactivated FANCD2 further confirm the relationship between BLM and FANCD2. Mutations within the domain VI of BLM detected in human cancer samples demonstrate the functional importance of this domain, suggesting human tumorigenicity resulting from mtBLM may be at least partly attributed to mitigated FANCD2 activation. Collectively, our data show a previously unknown regulatory liaison in advancing our understanding of how the cancer susceptibility gene products act in concert to maintain genome stability.

Distinct Metabolic Signature of Human Bladder Cancer Cells Carrying an Impaired Fanconi Anemia Tumor-Suppressor Signaling Pathway.

Metabolic profiling has great potential to help the diagnosis and prognosis of cancer patients. Fanconi Anemia (FA) tumor-suppressor signaling has been instrumental in understanding human tumorigenesis. However, this instrumental understanding has never been demonstrated at the metabolic level. Here, we show that impaired FA signaling can lead cells to exhibit metabolic signatures of tumorigenesis. This is consistent with our original studies of the roles of FA signaling in suppressing non-FA tumorigenesis at functional and genetic levels. Using ultraperformance liquid chromatography-mass spectroscopy and gas chromatography-mass spectrometry, we characterized metabolic alterations in bladder cancer cells carrying an intact or impaired FA pathway. The latter was obtained by ectopically expressing FAVL (FAVL-high), which we previously found to be capable of inactivating FA signaling. A total of 18 metabolites, end products of cell proliferation or apoptosis, were significantly different between FAVL-high and -low cells. Methionine, phenylalanine, and threonine, resulting from a tumorigenic process, were substantially increased in FAVL-high cells. With this study, we achieved genomic, functional, and metabolomic characterization of the roles of FA signaling in the development of human cancer. Furthermore, this study provides novel insights into how to translate FA basic research into strategies for producing effective biomarkers in human cancer diagnosis and prognosis.

Kinome-Wide shRNA Screen Reveals Functional Connections Between FANCA, Mitotic Centrosomes and the Spindle Assembly Checkpoint Tumor Suppressor Pathways

Fanconi anemia (FA) is a genetic disorder characterized by progressive bone marrow failure, congenital abnormalities and predilection towards development of hematopoietic malignancies, including acute myeloid leukemia (AML). Congenital biallelic disruption of the FA/BRCA signaling network causes Fanconi anemia and somatic mutations within the same genes are increasingly identified in a variety of malignancies in non-FA individuals, consistent with the critical role of this signaling pathway in FA and in the general population.The FA/BRCA tumor suppressor network orchestrates interphase DNA-damage repair (DDR) and DNA replication to maintain genomic stability. Additionally, we and others have demonstrated that the genome housekeeping function of FA/BRCA signaling extends beyond interphase: loss of FA/BRCA signaling perturbs execution of mitosis, including the spindle assembly checkpoint (SAC), centrosome maintenance, cytokinesis and resolution of anaphase DNA bridges. Interphase errors exacerbate mitotic abnormalities and mitotic failure promotes interphase mutagenesis. Consequently, we had demonstrated that primary FA patients' cells accumulate genomic abnormalities consistent with a dual mechanism of impaired interphase DDR/replication and defective mitosis. Previous detailed studies had elucidated multiple mechanisms of interphase DDR-dependent assembly and activation of the FA complex at DNA damage sites to arrest the cell cycle and repair DNA lesions. However, the signaling cross-talk nodes between the FA and mitotic checkpoint pathways remain to be discovered.In this study, we identified functionally relevant mitotic signaling defects resulting from FANCA deficiency via a synthetic lethal kinome-wide pooled shRNA screen in primary patient-derived FANCA -deficient cells compared to isogenic FANCA -corrected cell line. Bioinformatics analysis of our screen results followed by secondary validation of selected hits with alternative shRNAs and small-molecule inhibitors revealed conserved mitotic signal transduction pathways regulating the SAC and centrosome maintenance. Our super-resolution structured illumination (SR-SIM) microscopy coupled with deconvolution imaging revealed that a fraction of FANCA co-localizes with key SAC kinases at mitotic centrosomes and kinetochores, consistent with the role of FANCA in centrosome maintenance and the SAC. Co-immunoprecipitation assays identified the biochemical interaction between FANCA and an essential SAC kinase whose loss is synthetic lethal with FANCA deficiency, providing first insights into the interactions between FA signaling and the canonical SAC network.Together, our study has unraveled functional and biochemical connections between FANCA and the centrosome/SAC kinases, consistent with the essential role of FANCA in cell division. Our ongoing work is aimed at mechanistically dissecting molecular links between these two key tumor suppressor signaling pathways in more detail. We hypothesize that impaired FANCA/SAC cross-talk may contribute to genomic instability in FA-deficient cells and provide opportunities to selectively kill FANCA-/- cells. DisclosuresNo relevant conflicts of interest to declare.

Seek and destroy—and discover

Functional analysis of a patient-derived mutation unveils a new mode of regulation for the Fanconi-anemia signaling network.

Genomic Instability in Fanconi Anemia Results from a Combination of Chromosome Mis-Segregation in Mitosis and Unresolved Interphase DNA Damage

Fanconi anemia (FA) is a complex genetic disorder characterized by bone marrow failure, multiple congenital anomalies, and genomic instability resulting in predisposition to cancer. Disruption of the FA signaling network impairs multiple genome-housekeeping processes, including DNA damage recognition and repair in interphase, DNA replication as well as high-fidelity chromosome segregation during mitosis. Recent data published by several groups, including our work (J Clin Invest 2013; 123: 3839-3847), implicated FA signaling in the control of several cell division events essential for chromosomal stability, including the spindle assembly checkpoint (SAC), centrosome maintenance, resolution of ultrafine anaphase bridges and cytokinesis. Understanding the mechanistic origins of chromosomal instability leading to carcinogenesis and bone marrow failure has important scientific and clinical implications. However, the relative contribution of the interphase and mitotic events leading to genomic instability in Fanconi anemia has not been systematically evaluated.In this work, we dissected the origins and mechanistic significance of chromosomal instability in Fanconi anemia ex vivo and in vivo. We employed the cytochalasin micronucleus assay to quantify the patterns of spontaneous and chemotherapy-induced genomic lesions in FA-A patient-derived primary fibroblasts and Fancc-/- mouse embryonic fibroblasts (MEFs). In this assay, dividing cells are treated with cytochalasin to inhibit cytokinesis and generate binucleated daughter cells. The presence of micronuclei in the resulting cells is indicative of genomic instability caused by either interphase DNA damage or chromosome mis-segregation. Centromere-negative micronuclei (CNMs) represent chromosomal fragments due to unresolved ds-DNA damage. Centromere-positive micronuclei (CPMs) result from whole-chromosome mis-segregation during mitosis. The frequency of both CPMs and CNMs was significantly increased in FA-deficient human and murine cells compared to gene-corrected isogenic control cells. These results indicate that genomic instability in FA is caused by a combination of interphase DNA damage and disordered mitosis. We confirmed the biological significance of these findings by showing that FA patient cells are hypersensitive to low concentrations of taxol (a spindle checkpoint-activating chemotherapeutic) similarly to mitomycin C (a cross-linking agent). Finally, we found increased frequency of micronuclei in Fancc-/- murine red blood cells compared to age-matched wild-type mice, which indicates that spontaneous chromosome mis-segregation occurs in FA-deficient bone marrow in vivo.Our study supports the emerging model of the FA family of proteins as holistic guardians of the genome during interphase and mitosis (see figure based on F1000Prime Rep. 2014; 6: 23, modified). This model furthers our understanding of genomic instability in Fanconi anemia and FA-deficient cancers, and opens new inroads towards targeted therapeutic interventions in these diseases. [Display omitted] DisclosuresNo relevant conflicts of interest to declare.

Stress-induced exit from dormancy alters redox signaling in HSCs, resulting in de novo DNA damage and bone marrow failure in the absence of a functional fanconi anemia signaling pathway

Stress-induced exit from dormancy alters redox signaling in HSCs, resulting in de novo DNA damage and bone marrow failure in the absence of a functional fanconi anemia signaling pathway