Haploinsufficiency of Sf3b1 leads to compromised stem cell function but not to myelodysplasia.

SF3B1 is a core component of the mRNA splicing machinery and frequently mutated in myeloid neoplasms with myelodysplasia, particularly in those characterized by the presence of increased ring sideroblasts. Deregulated RNA splicing is implicated in the pathogenesis of SF3B1-mutated neoplasms, but the exact mechanism by which the SF3B1 mutation is associated with myelodysplasia and the increased ring sideroblasts formation is still unknown. We investigated the functional role of SF3B1 in normal hematopoiesis utilizing Sf3b1 heterozygous-deficient mice. Sf3b1(+/-) mice had a significantly reduced number of hematopoietic stem cells (CD34(-)cKit(+)ScaI(+)Lin(-) cells or CD34(-)KSL cells) compared with Sf3b1(+/+) mice, but hematopoiesis was grossly normal in Sf3b1(+/-) mice. When transplanted competitively with Sf3b1(+/+) bone marrow cells, Sf3b1(+/-) stem cells showed compromised reconstitution capacity in lethally irradiated mice. There was no increase in the number of ring sideroblasts or evidence of myeloid dysplasia in Sf3b1(+/-) mice. These data suggest that SF3B1 plays an important role in the regulation of hematopoietic stem cells, whereas SF3B1 haploinsufficiency itself is not associated with the myelodysplastic syndrome phenotype with ring sideroblasts.

Overexpression of miR-26a-2 in human liposarcoma is correlated with poor patient survival.

Approximately 90% of well-differentiated/de-differentiated liposarcomas (WDLPS/DDLPS), the most common LPS subtype, have chromosomal amplification at 12q13-q22. Many protein-coding genes in the region, such as MDM2 and , have been studied as potential therapeutic targets for LPS treatment, with minimal success. In the amplified region near the MDM2 gene, our single nucleotide polymorphism (SNP) array analysis of 75 LPS samples identified frequent amplification of miR-26a-2. Besides being in the amplicon, miR-26a-2 was overexpressed significantly in WDLPS/DDLPS (P<0.001), as well as in myxoid/round cell LPS (MRC) (P<0.05). Furthermore, Kaplan-Meier survival analysis showed that overexpression of miR-26a-2 significantly correlated with poor patient survival in both types of LPS (P<0.05 for WDLPS/DDLPS; P<0.001 for MRC). Based on these findings, we hypothesized that miR-26a-2 has an important role in LPS tumorigenesis, regardless of LPS subtypes. Overexpression of miR-26a-2 in three LPS cell lines (SW872, LPS141 and LP6) enhanced the growth and survival of these cells, including faster cell proliferation and migration, enhanced clonogenicity, suppressed adipocyte differentiation and/or resistance to apoptosis. Inhibition of miR-26a-2 in LPS cells using anti-miR-26a-2 resulted in the opposite responses. To explain further the effect of miR-26a-2 overexpression in LPS cells, we performed in silico analysis and identified 93 candidate targets of miR-26a-2. Among these genes, RCBTB1 (regulator of chromosome condensation and BTB domain-containing protein 1) is located at 13q12.3-q14.3, a region of recurrent loss of heterozygosity (LOH) in LPS. Indeed, either overexpression or inhibition of RCBTB1 made LPS cells more susceptible or resistant to apoptosis, respectively. In conclusion, our study for the first time reveals the contribution of miR-26a-2 to LPS tumorigenesis, partly through inhibiting RCBTB1, suggesting that miR-26a-2 is a novel therapeutic target for human LPS.

HapMap SNP Scanner: an online program to mine SNPs responsible for cell phenotype.

Minor histocompatibility (H) antigens are targets of graft-vs-host disease and graft-vs-tumor responses after human leukocyte antigen matched allogeneic hematopoietic stem cell transplantation. Recently, we reported a strategy for genetic mapping of linkage disequilibrium blocks that encoded novel minor H antigens using the large dataset from the International HapMap Project combined with conventional immunologic assays to assess recognition of HapMap B-lymphoid cell line by minor H antigen-specific T cells. In this study, we have constructed and provide an online interactive program and demonstrate its utility for searching for single-nucleotide polymorphisms (SNPs) responsible for minor H antigen generation. The website is available as 'HapMap SNP Scanner', and can incorporate T-cell recognition and other data with genotyping datasets from CEU, JPT, CHB, and YRI to provide a list of candidate SNPs that correlate with observed phenotypes. This method should substantially facilitate discovery of novel SNPs responsible for minor H antigens and be applicable for assaying of other specific cell phenotypes (e.g. drug sensitivity) to identify individuals who may benefit from SNP-based customized therapies.

Retinoic acid disintegrated desmosomes and hemidesmosomes in stratified oral keratinocytes.

BACKGROUND: Although it is known that retinoic acid (RA) regulates the cellular differentiation of skin keratinocytes, the effects of RA on the anchoring junction have not been clarified. The effects of all-trans RA on cell-cell and cell-matrix connections of gingival epithelial (GE)1 cells in a multilayered culture were investigated. METHODS: Ultrastructures of GE1 cells were observed and immunohistochemistry was used to detect keratin 4, keratin 13, and desmoglein expression. Reverse transcription-polymerase chain reaction was performed to detect expression of desmosome and hemidesmosome-associating adhesion molecules, keratin 13, and keratin14. RESULTS: Retinoic acid caused immunohistochemical diminution of keratin 4, keratin 13, and desmoglein. Ultrastructurally, RA induced drastic loss of typical desmosomes and complete loss of hemidesmosomes. RA significantly decreased the transcript levels of keratin 13, keratin 14, desmoglein 1, and desmocollin 1 in a dose-dependent manner. The 230-kD bullous pemphigoid antigen (BPAG1) gene expression was also reduced by RA, whereas transcript levels of integrin alpha6, integrin beta4, the 180-kD bullous pemphigoid antigen (BPAG2), and laminin 5 were not affected. CONCLUSION: These results indicated that RA disintegrated not only desmosomes by depriving the cells of desmoglein 1, desmocollin 1, keratin 13, and keratin 4, but also hemidesmosomes by reducing the expression of BPAG1 and keratin 14 in basal keratinocytes.