In doxorubicin cardiomyopathy, mtDNA alterations, superoxide, and respiratory chain dysfunction accumulate long-term in the absence of the drug and are associated with a late onset.
Familial myelodysplastic syndromes arise from haploinsufficiency of genes involved in hematopoiesis and are primarily associated with early-onset disease. Here we describe a familial syndrome in seven patients from four unrelated pedigrees presenting with myelodysplastic syndrome and loss of chromosome 7/7q. Their median age at diagnosis was 2.1 years (range, 1–42). All patients presented with thrombocytopenia with or without additional cytopenias and a hypocellular marrow without an increase of blasts. Genomic studies identified constitutional mutations (p.H880Q, p.R986H, p.R986C and p.V1512M) in the SAMD9L gene on 7q21, with decreased allele frequency in hematopoiesis. The non-random loss of mutated SAMD9L alleles was attained via monosomy 7, deletion 7q, UPD7q, or acquired truncating SAMD9L variants p.R1188X and p.S1317RfsX21. Incomplete penetrance was noted in 30% (3/10) of mutation carriers. Long-term observation revealed divergent outcomes with either progression to leukemia and/or accumulation of driver mutations (n=2), persistent monosomy 7 (n=4), and transient monosomy 7 followed by spontaneous recovery with SAMD9L-wildtype UPD7q (n=2). Dysmorphic features or neurological symptoms were absent in our patients, pointing to the notion that myelodysplasia with monosomy 7 can be a sole manifestation of SAMD9L disease. Collectively, our results define a new subtype of familial myelodysplastic syndrome and provide an explanation for the phenomenon of transient monosomy 7. Registered at: www.clinicaltrials.gov; #NCT00047268.
Sterile alpha motif domain protein 9 (SAMD9) and its paralogue SAMD9-like (SAMD9L) are cytoplasmic proteins encoded by two juxtaposed single-exon genes on chromosome 7q21. They share a 60% amino acid sequence identity and likely originated from a duplication of a common ancestral gene 1 . Their function remains enigmatic; they have been linked to tumor suppression 2 , inflammation 3 , stress response 4 , development 4 , endosomal fusion 5,6 and protein translation 7,8 . Both proteins were also shown to function as restriction factors forming a cross-species barrier for poxvirus infection [9][10][11][12] . Structural analysis of these large proteins has been limited to homology modeling, which predicted identical domains in either protein (SAM, ALBA2, SIR2, P-loop/ NTPase and OB-fold) 13 . Moreover, these genes exhibit tight regulation during embryonic development and transition to ubiquitous expression levels in adult tissues 14,15 .Notably, Samd9l-haploinsufficient mice develop myeloid neoplasia mimicking human MDS with monosomy 7 5 . Several groups reported germline SAMD9 or SAMD9L mutations (SAMD9/9L mut ) underlying new human syndromes with a propensity for cytopenia, bone marrow failure (BMF) and MDS with non-random monosomy 7 or deletion of 7q 6,16-28 . SAMD9 mutations (SAMD9 mut ) were initially linked to a fatal, early-onset MIRAGE syndrome (myelodysplasia, infections, restriction of growth, adrenal hypoplasia, genital phenotypes and enteropathy) 6,29 . In contrast, SAMD9L mutations (SAMD9L mut ) were originally described in families with a progressive neurological phenotype, multi-lineage cytopenia and bone marrow hypoplasia (ataxia-pancytopenia syndrome) 16,17 . Recent reports broadened this spectrum and found missense SAMD9/9L mut in non-syndromic familial MDS [30][31][32][33] , truncating SAMD9L mut in children with autoinflammatory panniculitis resembling CANDLE
Background and purpose: Doxorubicin causes a chronic cardiomyopathy in which reactive oxygen species (ROS) accumulate over time and are associated with genetic and functional lesions of mitochondria. Dexrazoxane is a cardioprotective iron chelator that interferes with ROS production. We aim to analyze the effects of dexrazoxane on mitochondria in the prevention of doxorubicin-induced chronic myocardial lesions. Experimental approach: Wistar rats (11 weeks of age) were injected with intravenous doxorubicin (0.8 mg kg -1 weekly for 7 weeks) with or without simultaneous dexrazoxane (8 mg kg -1 ). Animals were killed at 48 weeks. Cardiomyopathy was scored clinically and histologically and cardiac mitochondria were analyzed. Key results: Compared to control rats receiving saline, rats treated with doxorubicin alone developed a clinical, macroscopic, histological and ultrastructural cardiomyopathy with low cytochrome c-oxidase (COX) activity (26% of controls). The expression of the mtDNA-encoded COX II subunit was reduced (64% of controls). Myocardia exhibited a high production of ROS (malondialdehyde 338% and superoxide 787% of controls). Mitochondria were depleted of mitochondrial DNA (mtDNA copy number 46% of controls) and contained elevated levels of mtDNA deletions. Dexrazoxane co-administration prevented all these effects of doxorubicin on mitochondria, except that hearts co-exposed to doxorubicin and dexrazoxane had a slightly lower mtDNA content (81% of controls) and mtDNA deletions at low frequency. Conclusions and Implications: Dexrazoxane prevented doxorubicin induced late-onset cardiomyopathy and also protected the cardiac mitochondria from acquired ultrastructural, genetic and functional damage.
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