Project description:The reprogramming of human fibroblasts to generate induced pluripotent stem cells (hiPSCs) has been achieved through the expression of only a few exotic factors1-8, which is morphologically and molecularly verified in outer cellular states by characteristic markers, due to the remodeling of the somatic cell transcription programs in inner cellular states to the ES-like condition. Transcription factor-induced reprogramming to self-renewal and pluripotency raises the question as to how the exotic factors act to bring about these changes in the two cellular states9-11. Here, we applied RNA profiling to uncover gene expression changes and glycan profiling12 to survey structural changes in glycans, to compare hiPSCs and parental somatic cells, in total 51 cells, which were originally cultured and established, and the changes were analyzed by the combination of standard statistical techniques and a network approach13. We fist found a gene expression signature of 2502 genes with significant difference between iPSCs and SCs, and by the following network analysis by considering the expression signature, we found a network signature of 28 regulatory networks of 76 genes, which were related to the glycan biosynthetic pathways including 3 glycosyltransferase, in addition to well known signal pathways and cell-cell interaction pathways. Concomitantly, we found a glycan signature of six glycan structures characterized 16 lectins on lectin microarray by the correspondence with 12 glycosyltransferases in expression signature. In particular, the correspondence detected between the three expression signatures revealed 14 candidate glycosyltransferase, which are responsible for glycan transfer related to known epitopes for the differentiation such as SSEA epitope family in glycan biosynthesis pathway, based on characteristic changes in the cellular surface states of the hiPSCs. This sheds new light on a possible linkage between the inner and outer cellular states for reprogramming to self-renewal and pluripotency in hiPSC. Gene expressions in human induced pluripotent stem (iPS) cells and the provenance somatic cells . iPS cells were induced from four different somatic cells by infection of the retroviral vectors pMXs encoding OCT3/4, SOX2, KLF4 and c-MYC, simultaneously.

Project description:In this work, we characterized the epigenomic integrity of 17 hiPSC lines derived from six different cell types with varied reprogramming efficiencies. We demonstrate that epigenetic aberrations are a general feature of the hiPSC state and are independent of the somatic cell source. Additionally, we determine that both shared and line-specific epigenetic aberrations in hiPSCs can directly translate into changes in gene expression in both the pluripotent and differentiated states. Examination of differential methylation between iPSC and ESCs through differentiated states. Examination of differential methylation between iPSC and somatic cell source and iPSC and ESCs.

Project description:The UT-A1 urea transporter is crucial to the kidney’s ability to generate concentrated urine. Native UT-A1 from kidney inner medulla (IM) is a heavily glycosylated protein with two glycosylation forms of 97 and 117 kDa. In diabetes, UT-A1 protein abundance, particularly the 117 kD isoform, is significantly increased corresponding to an increased urea permeability in perfused IM collecting ducts, which plays an important role in preventing the osmotic diuresis caused by glucosuria. In this study, using sugar-specific binding lectins, we found that the carbohydrate structure of UT-A1 is also changed under diabetic conditions with increased amounts of sialic acid, fucose, and increased glycan branching. These changes were accompanied by altered UT-A1 association with the galectin proteins, α-galactoside glycan binding proteins. To explore the molecular basis of the alterations of glycan structures, the highly sensitive next generation sequencing (NGS) technology, Illumina RNA-seq, was employed to analyze genes involved in the process of UT-A1 glycosylation using streptozotocin (STZ) - induced diabetic rat kidney as the tissue source. Differential expression analysis combining quantitative PCR revealed that a number of important glycosylation related genes were changed under diabetic conditions. These genes include the glycosyltransferase genes Mgat4a, the sialylation enzymes St3gal1 and St3gal4and glycan binding protein galectin-3, -5, -8 and -9. In contrast, although highly expressed in kidney IM, the glycosyltransferase genes Mgat1, Mgat2, and fucosyltransferase Fut8, did not show any changes. We conclude that the alteration of these glycosylation related genes may contribute to changing the UT-A1 glycan structure, and therefore modulate kidney urea transport activity under diabetic conditions.

Project description:In our study, PRDM14 and NFRkB were found to enhance the reprogramming of human fibroblasts to hiPSCs in the presence of OCT4, SOX2, KLF4, with/without c-MYC (OSK/OSKC). To examnie if the obtained hiPSC share similar expression signature with hESC, we conducted the microarray analysis on the hiPSCs, hESCs and fibroblasts. The result showed that all of the examined hiPSCs resembled hESCs, but differed from fibroblasts MRC5. 4 hiPSC lines, 2 hESC lines and 1 type of fibroblasts were analyzed in total. Each sample is done in duplicates.

Project description:The equivalency of human induced pluripotent stem cells (hiPSCs) with human embryonic stem cells (hESCs) remains controversial. Here, we devised a strategy to assess the contribution of clonal growth, reprogramming method and genetic background to transcriptional patterns in hESCs and hiPSCs. Surprisingly, transcriptional variation originating from two different genetic backgrounds was dominant over variation due to the reprogramming method or cell type of origin of pluripotent cell lines. Moreover, the few differences we detected between isogenic hESCs and hiPSCs neither predicted functional outcome, nor distinguished an independently derived, larger set of unmatched hESC/hiPSC lines. We conclude that hESCs and hiPSCs are transcriptionally and functionally highly similar and cannot be distinguished by a consistent gene expression signature. Our data further imply that genetic background variation is a major confounding factor for transcriptional comparisons of pluripotent cell lines, explaining some of the previously observed expression differences between unmatched hESCs and hiPSCs. Expression profiling of human embryonic stem cells (ESCs), induced pluripotent stem cells (iPSCs) and fibroblasts, mostly in triplicates.

Project description:We are interested in investigating changes in both the glycome and transcriptome of human embryonic stem cells upon differentiation. We have chosen as a model system to differentiate human ES cells into neural spheres using a published protocol by Zhang, S.C. et al. (2001; Nat Biotech. 19: 1129-33). Based on the information provided by microarray analysis, proteins of interest can be further investigated to associate a particular glycosyltransferase, for example, with production of a specific glycan structure at a particular stage. Techniques such as the use of RNAi for the knock-down or transfection of hESCs to effect the overexpression of the transcript, followed by subsequent analysis of the glycan structures can be employed.

Project description:In our study, PRDM14 and NFRkB were found to enhance the reprogramming of human fibroblasts to hiPSCs in the presence of OCT4, SOX2, KLF4, with/without c-MYC (OSK/OSKC). To examnie if the obtained hiPSC share similar expression signature with hESC, we conducted the microarray analysis on the hiPSCs, hESCs and fibroblasts. The result showed that all of the examined hiPSCs resembled hESCs, but differed from fibroblasts MRC5.

Project description:In this work, we characterized the epigenomic integrity of 17 hiPSC lines derived from six different cell types with varied reprogramming efficiencies. We demonstrate that epigenetic aberrations are a general feature of the hiPSC state and are independent of the somatic cell source. Additionally, we determine that both shared and line-specific epigenetic aberrations in hiPSCs can directly translate into changes in gene expression in both the pluripotent and differentiated states.

Project description:The equivalency of human induced pluripotent stem cells (hiPSCs) with human embryonic stem cells (hESCs) remains controversial. Here, we devised a strategy to assess the contribution of clonal growth, reprogramming method and genetic background to transcriptional patterns in hESCs and hiPSCs. Surprisingly, transcriptional variation originating from two different genetic backgrounds was dominant over variation due to the reprogramming method or cell type of origin of pluripotent cell lines. Moreover, the few differences we detected between isogenic hESCs and hiPSCs neither predicted functional outcome, nor distinguished an independently derived, larger set of unmatched hESC/hiPSC lines. We conclude that hESCs and hiPSCs are transcriptionally and functionally highly similar and cannot be distinguished by a consistent gene expression signature. Our data further imply that genetic background variation is a major confounding factor for transcriptional comparisons of pluripotent cell lines, explaining some of the previously observed expression differences between unmatched hESCs and hiPSCs.

Project description:We are interested in investigating changes in both the glycome and transcriptome of human embryonic stem cells upon differentiation. We have chosen as a model system to differentiate human ES cells into neural spheres using a published protocol by Zhang, S.C. et al. (2001; Nat Biotech. 19: 1129-33). Based on the information provided by microarray analysis, proteins of interest can be further investigated to associate a particular glycosyltransferase, for example, with production of a specific glycan structure at a particular stage. Techniques such as the use of RNAi for the knock-down or transfection of hESCs to effect the overexpression of the transcript, followed by subsequent analysis of the glycan structures can be employed. Three developmental stages will be investigated: Stage 1: undifferentiated stem cells; Stage 2: differentiation into embryoid bodies; Stage 3: differentiation into neural spheres. In addition to characterizing the cell surface for glycomic “fingerprints” we want to characterize the genomic transcripts associated with the glycome.