Bicelles are used in many membrane protein studies because they are thought to be more bilayer-like than micelles. We investigated the properties of "isotropic" bicelles by small-angle neutron scattering, small-angle X-ray scattering, fluorescence anisotropy, and molecular dynamics. All data suggest that bicelles with a q value below 1 deviate from the classic bicelle that contains lipids in the core and detergent in the rim. Thus not all isotropic bicelles are bilayer-like.
High Mobility Group A1 (HMGA1) encodes proteins that act as mediators in viral integration, modification of chromatin structure, neoplastic transformation, and metastatic progression. Because HMGA1 is overexpressed in most cancers and has transcriptional relationships with several Wnt-responsive genes, we explored the involvement of HMGA1 in Wnt/β-catenin/TCF-4 signaling. In adenomatous polyposis coli (APCMin/+) mice, we observed significant upregulation of HMGA1 mRNA and protein in intestinal tumors when compared to normal intestinal mucosa. Conversely, restoration of Wnt signaling by zinc-induction of wt-APC resulted in HMGA1 downregulation in HT-29 cells. Because APC mutations are associated with mobilization of the β-catenin/TCF-4 transcriptional complex and subsequent activation of downstream oncogenic targets, we analyzed the 5′-flanking sequence of HMGA1 putative TCF-4 binding elements (TBEs). We identified two functional that specifically bind the β-catenin/TCF-4 complex in vitro and in vivo identifying HMGA1 as an immediate target of the β-catenin/TCF-4 signaling pathway in colon cancer. Collectively, these findings strongly implicate Wnt/β-catenin/TCF-4 signaling in regulating HMGA1 to further expand the extensive regulatory network affected by Wnt/β-catenin/TCF-4 signaling.
Fetal megakaryocytes (Mks) differ from adult Mks in key parameters that affect their capacity for platelet production. However, despite being smaller, more proliferative, and less polyploid, fetal Mks generally mature in the same manner as adult Mks. The phenotypic features unique to fetal Mks predispose patients to several disease conditions, including infantile thrombocytopenia, infantile megakaryoblastic leukemias, and poor platelet recovery after umbilical cord blood stem cell transplantations. Ontogenic Mk differences also affect new strategies being developed to address global shortages of platelet transfusion units. These donor-independent, ex vivo production platforms are hampered by the limited proliferative capacity of adult-type Mks and the inferior platelet production by fetal-type Mks. Understanding the molecular programs that distinguish fetal versus adult megakaryopoiesis will help in improving approaches to these clinical problems. This review summarizes the phenotypic differences between fetal and adult Mks, the disease states associated with fetal megakaryopoiesis, and recent advances in the understanding of mechanisms that determine ontogenic Mk transitions.
Infantile (fetal and neonatal) megakaryocytes have a distinct phenotype consisting of hyperproliferation, limited morphogenesis, and low platelet production capacity. These properties contribute to clinical problems that include thrombocytopenia in neonates, delayed platelet engraftment in recipients of cord blood stem cell transplants, and inefficient ex vivo platelet production from pluripotent stem cell-derived megakaryocytes.The infantile phenotype results from deficiency of the actin-regulated coactivator, MKL1, which programs cytoskeletal changes driving morphogenesis. As a strategy to complement this molecular defect, we screened pathways with potential to affect MKL1 function and found that Dyrk1a kinase inhibition dramatically enhanced megakaryocyte morphogenesis in vitro and in vivo. Dyrk1 inhibitors rescued enlargement, polyploidization, and thrombopoiesis in human neonatal megakaryocytes. Megakaryocytes derived from induced pluripotent stem cells responded in a similar manner. Progenitors undergoing Dyrk1 inhibition demonstrated filamentous actin assembly, MKL1 nuclear translocation, and modulation of MKL1 target genes. Loss of function studies confirmed MKL1 involvement in this morphogenetic pathway. Ablim2, a stabilizer of filamentous actin, increased with Dyrk1 inhibition, and Ablim2 knockdown abrogated the actin, MKL1, and morphogenetic responses to Dyrk1 inhibition. These results thus delineate a pharmacologically tractable morphogenetic pathway whose manipulation may alleviate clinical problems associated with the limited thrombopoietic capacity of infantile megakaryocytes.
All rights reserved. May 2016. iii "Call it a clan, call it a network, call it a tribe, call it a family. Whatever you call it, whoever you are, you need one."-Jane Howard (1935-1996) US journalist, writer "Nothing will work unless you do."
Growing clinical demands for platelet transfusions combined with supply limitations have created shortages which are trending toward a global crisis. Major efforts have been taken to address key issues of platelet sources, storage, and utilization. Recent progress in ex vivo culture-based production of megakaryocytes (Mk) and platelets, "pharming," has highlighted the potential for novel, donor-independent sources amenable to antigenic editing and cryo-stockpiling. Such cultures can be easily initiated from umbilical cord blood (CB) progenitors, induced pluripotent stem cells (iPSC), or directly re-programmed somatic cells. The major roadblock associated with these Mk sources consists of their fetal ontogenic status, which is beneficial for expansion but severely limits platelet production. The ability to elicit in pre-expanded Mk an adult program of morphogenesis (polyploidization, enlargement, and proplatelet formation) would enable circumvention of this scalability barrier. A master regulator of adult Mk morphogenesis consists of the transcriptional coactivator MKL1 which undergoes nuclear translocation in response to RhoA-mediated actin polymerization, stimulated by thrombopoietin and environmental mechano-sensing. Nuclear MKL1 associates with the transcription factor SRF1 to upregulate cytoskeletal remodeling factors, including filamin A and Hic-5, that act as morphogenesis effectors. Our previous studies identified in infantile CB Mk a failure in MKL1 upregulation resulting from repression by the oncofetal RNA-binding factor IGF2BP3. Pharmacologic suppression of IGF2BP3 with BET inhibitors rescued MKL1 expression and improved platelet production but caused cycle arrest preventing polyploidization. As an alternative approach to abrogate the fetal blockade in Mk morphogenesis, we sought to promote MKL1 activity by targeting a kinase, Dyrk1a, which had been shown to restrain MKL1 from nuclear translocation. Treatment of infantile CB Mk with a variety of Dyrk1-selective inhibitors including harmine and EHT 1610 strongly enhanced polyploidization (p = 0.015 and 0.009 respectively), enlargement (p < 0.005) , and in vitro platelet release (2 fold each, p = 0.001 and 0.007 respectively), attaining levels seen with adult Mk. When xenotransplanted into NSG mice, harmine-treated CB Mk demonstrated enhanced capability for in vivo platelet release (about 5 fold, p = 0.016). CB stem cells expanded with the AHR antagonist SR1 and an iPSC-Mk cell line also responded to Dyrk1 inhibition with robustly increased morphogenesis. Several findings implicated MKL1 in this response: 1) induction of nuclear translocation by the inhibitors, 2) induction of target genes (filamin A and Hic-5) by the inhibitors, and 3) loss of response to inhibitors in Mkl1-ko murine progenitors. Supporting Dyrk1a as a relevant target, mice with Mk-specific loss of one Dyrk1a allele (Dyrk1aflox/wt;Pf4-Cre) displayed increases in platelet counts (p = 0.037) and marrow Mk polyploidization (p = 0.02). In addition, retroviral expression in human progenitors of a dominant negative Dyrk1a mutant K188R promoted Mk enlargement (p = 0.014). shRNA knockdowns could not be obtained due to toxicity of > ~60% loss of Dyrk1a. To determine mechanisms for Dyrk1a control of morphogenesis, we analyzed the actin cytoskeleton, a key regulator of MKL1. Dyrk1 inhibition in all types of Mk progenitors (adult, infantile, and iPSC) induced assembly of cortical filamentous actin (F-actin), as detected by Alexa594-phalloidin staining. Prior studies showed cytoskeletal binding by Dyrk1a and direct phosphorylation of F-actin regulators N-WASP and Ablim1. A survey of human marrow expression patterns for candidate Dyrk1a substrates (The Human Protein Atlas) identified Ablim2, as showing a Mk-specific, cortical staining pattern. Dyrk1 inhibition increased Ablim2 levels ~5-fold in CB Mk (p < 0.005), and immunofluorescence displayed a cortical distribution similar to F-actin. Lentiviral shRNA knockdown of Ablim2 abrogated all effects of Dyrk1 inhibition, blocking: F-actin formation, MKL1 nuclear translocation, activation of the MKL1 targets, and Mk morphogenesis. These findings thus delineate a novel Dyrk1a-Ablim2-MKL1 regulatory module in Mk morphogenesis that can be manipulated to address the problem of scaling ex vivo production and might also serve as a future in vivo therapeutic target for thrombocytopenia. Disclosures Eto: Megakaryon Co. Ltd.: Equity Ownership, Membership on an entity's Board of Directors or advisory committees.
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