BACKGROUND Altered expression of actin subunits is found in multiple cancers. Alpha-cardiac actin (ACTC1) is expressed in sonic hedgehog medulloblastoma (SHH MB) and regulates both cell survival and migration. We hypothesized that cardiac actin has a unique structural and functional role in SHH MB and may be expressed in post-natal granule cell progenitors (GCPs) which share similar gene expression profiles. METHODS Actin subunit protein expression (ACTC1, ACTB, ACTG1, and ACTA2) was evaluated by mRNA expression profiling within established datasets and across MB cell lines by Western blot (WB). Immunofluorescence microscopy was performed to assess intracellular actin subunit localization. The composition of each subunit in filamentous (F-) actin was evaluated. Furthermore immunoprecipitation of filamentous ACTC1 was performed to assess protein-protein interactions. The ratio of F-actin to globular (G-) actin was determined by WB in SHH MB cells exposed to mitotic inhibitor. Cell viability was determined by colony formation following over-expression of dominant-negative mutant ACTC1 (P116C & G247D). RESULTS ACTC1, ACTG1, and ACTB are the predominant actin subunits in SHH MB. Immunofluorescence microscopy demonstrated co-localization of ACTC1 with ACTG1 and ACTB but not ACTA2. ACTC1 showed a unique cortical localization pattern. Post-natal MATH1 positive mouse GCPs (P3-5) demonstrate similar distribution of ACTC1 in cortical F-actin. WB analysis of ACTC1 pulldown from SHH MB cell F-actin fractions showed co-precipitation with ACTG1 and ACTB but not ACTA2. ACTC1 F-actin to G-actin ratio is maintained in cells that show resistance to mitotic inhibition. Expression of mutant ACTC1 G247D resulted in reduced cell survival. CONCLUSIONS ACTC1 subunit is incorporated into F-actin in SHH MB and GCPs. Filamentous ACTC1 forms a protein complex with ACTG1 and ACTB. Disruption of ACTC1 polymerization results in reduced cell survival. These findings suggest a functional role of ACTC1 in both SHH MB and in GCPs which are important in cerebellar development.
Background Alterations in actin subunit expression have been reported in multiple cancers, but have not been investigated previously in medulloblastoma. Methods Bioinformatic analysis of multiple medulloblastoma tumor databases was performed to profile ACTC1 mRNA levels. Western blot was used to verify protein expression in established medulloblastoma cell lines. Immunofluorescence microscopy was performed to assess ACTC1 localization. Stable cell lines with ACTC1 overexpression were generated and shRNA knockdown of ACTC1 was accomplished. We used PARP1 cleavage by Western blot as a marker of apoptosis and cell survival was determined by FACS viability assay and colony formation. Cell migration with overexpression or knockdown of ACTC1 was determined by the scratch assay. Stress fiber length distribution was assessed by fluorescence microscopy. Results : ACTC1 mRNA expression is highest in SHH and WNT medulloblastoma among all subgroups. ACTC1 protein was confirmed by Western blot in SHH subgroup and Group 3 subgroup cell lines with the lowest expression in Group 3 cells. Microscopy demonstrated ACTC1 co-localization with F-actin. Overexpression of ACTC1 in Group 3 cells abolished the apoptotic response to Aurora kinase B inhibition. Knockdown of ACTC1 in SHH cells and in Myc overexpressing SHH cells induced apoptosis impaired colony formation, and inhibited migration. Changes in stress fiber length distribution in medulloblastoma cells are induced by alterations in ACTC1 abundance. Conclusions Alpha-cardiac actin (ACTC1) is expressed in SHH medulloblastoma. Expression of this protein in medulloblastoma modifies stress fiber composition and functions in promoting resistance to apoptosis induced by mitotic inhibition, enhancing cell survival, and controlling migration.
Precision gene editing in primary hematopoietic stem and progenitor cells (HSPCs) would facilitate both curative treatments for monogenic disorders as well as disease modelling. Precise efficiencies even with the CRISPR/Cas system, however, remain limited. Through an optimization of guide RNA delivery, donor design, and additives, we have now obtained mean precise editing efficiencies >90% on primary cord blood HSCPs with minimal toxicity. Critically, editing is even across the progenitor hierarchy, and does not substantially distort the hierarchy or affect lineage outputs in colony-forming cell assays. As modelling of many diseases requires heterozygosity, we also demonstrated that the overall editing and zygosity can be tuned by adding in defined mixtures of mutant and wild-type donor. With these optimizations, editing at near-perfect efficiency can now be accomplished directly in human HSPCs. This will open new avenues in both therapeutic strategies and disease modelling.
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