Desmin mutations in the terminal consensus motif prevent synemin-desmin heteropolymer filament assembly

Disorganization of the desmin network is associated with cardiac and skeletal myopathies characterized by accumulation of desmin-containing aggregates in the cells. Multiple associations of intermediate filament proteins form a network to increase mechanical and functional stability. Synemin is a desmin-associated type VI intermediate filament protein. Neither its impact on desmin network nor how it integrates into desmin filament is yet elucidated. To gain more insight into the molecular basis of these processes, we coexpressed synemin with different desmin mutants in ex vivo models. The screening of fourteen desmin mutants showed that synemin with desmin mutants revealed two behaviors. Firstly, synemin was co-localized in desmin aggregates and its coexpression decreased the number of cells containing aggregates. Secondly, synemin was excluded from the aggregates, then synemin had no effect on desmin network organization. Among fourteen desmin mutants, there were only three mutants, p.E401K, p.R406W and p.E413K, in which synemin was not found in aggregates. This behavior was correlated to the abnormal salt-bridges of desmin-dimer as seen in silico constructs. Moreover, desmin constructs in silico and published results in literature have predicted that the salt-bridges absence in the desmin filament building prevent longitudinal annealing and/or radial compaction. These results suggest that the state of desmin-filament assembly is crucial for synemin anchorage and consequently might involve mechanical and functional stability of the cytoskeletal network. © 2011 Elsevier Inc

New Role for Granulocyte Colony-Stimulating Factor-Induced Extracellular Signal-Regulated Kinase 1/2 in Histone Modification and Retinoic Acid Receptor α Recruitment to Gene Promoters: Relevance to Acute Promyelocytic Leukemia Cell Differentiation ▿

The induction of the granulocytic differentiation of leukemic cells by all-trans retinoic acid (RA) has been a major breakthrough in terms of survival for acute promyelocytic leukemia (APL) patients. Here we highlight the synergism and the underlying novel mechanism between RA and the granulocyte colony-stimulating factor (G-CSF) to restore differentiation of RA-refractory APL blasts. First, we show that in RA-refractory APL cells (UF-1 cell line), PML-RA receptor alpha (RARα) is not released from target promoters in response to RA, resulting in the maintenance of chromatin repression. Consequently, RARα cannot be recruited, and the RA target genes are not activated. We then deciphered how the combination of G-CSF and RA successfully restored the activation of RA target genes to levels achieved in RA-sensitive APL cells. We demonstrate that G-CSF restores RARα recruitment to target gene promoters through the activation of the extracellular signal-regulated kinase (ERK)/mitogen-activated protein kinase (MAPK) pathway and the subsequent derepression of chromatin. Thus, combinatorial activation of cytokines and RARs potentiates transcriptional activity through epigenetic modifications induced by specific signaling pathways