Gene markers of cellular aging in human multipotent stromal cells in culture.

INTRODUCTION: Human multipotent stromal cells (MSCs) isolated from bone marrow or other tissue sources have great potential to treat a wide range of injuries and disorders in the field of regenerative medicine and tissue engineering. In particular, MSCs have inherent characteristics to suppress the immune system and are being studied in clinical studies to prevent graft-versus-host disease. MSCs can be expanded in vitro and have potential for differentiation into multiple cell lineages. However, the impact of cell passaging on gene expression and function of the cells has not been determined. METHODS: Commercially available human MSCs derived from bone marrow from six different donors, grown under identical culture conditions and harvested at cell passages 3, 5, and 7, were analyzed with gene-expression profiling by using microarray technology. RESULTS: The phenotype of these cells did not change as reported previously; however, a statistical analysis revealed a set of 78 significant genes that were distinguishable in expression between passages 3 and 7. None of these significant genes corresponded to the markers established by the International Society for Cellular Therapy (ISCT) for MSC identification. When the significant gene lists were analyzed through pathway analysis, these genes were involved in the top-scoring networks of cellular growth and proliferation and cellular development. A meta-analysis of the literature for significant genes revealed that the MSCs seem to be undergoing differentiation into a senescent cell type when cultured extensively. Consistent with the differences in gene expression at passage 3 and 7, MSCs exhibited a significantly greater potential for cell division at passage 3 in comparison to passage 7. CONCLUSIONS: Our results identified specific gene markers that distinguish aging MSCs grown in cell culture. Confirmatory studies are needed to correlate these molecular markers with biologic attributes that may facilitate the development of assays to test the quality of MSCs before clinical use.

Molecular characterization of antigen-peptide pulsed dendritic cells: immature dendritic cells develop a distinct molecular profile when pulsed with antigen peptide.

As dendritic cells (DCs) are the most potent professional antigen-presenting cells, they are being tested as cancer vaccines for immunotherapy of established cancers. Although numerous studies have characterized DCs by their phenotype and function, few have identified potential molecular markers of antigen presentation prior to vaccination of host. In this study we generated pre-immature DC (piDC), immature DC (iDC), and mature DC (mDC) from human peripheral blood monocytes (PBMC) obtained from HLA-A2 healthy donors, and pulsed them with human papillomavirus E7 peptide (p11-20), a class I HLA-A2 binding antigen. We then characterized DCs for cell surface phenotype and gene expression profile by microarray technology. We identified a set of 59 genes that distinguished three differentiation stages of DCs (piDC, iDC and mDC). When piDC, iDC and mDC were pulsed with E7 peptide for 2 hrs, the surface phenotype did not change, however, iDCs rather than mDCs showed transcriptional response by up-regulation of a set of genes. A total of 52 genes were modulated in iDC upon antigen pulsing. Elongation of pulse time for iDCs to 10 and 24 hrs did not significantly bring further changes in gene expression. The E7 peptide up-modulated immune response (KPNA7, IGSF6, NCR3, TREM2, TUBAL3, IL8, NFKBIA), pro-apoptosis (BTG1, SEMA6A, IGFBP3 and SRGN), anti-apoptosis (NFKBIA), DNA repair (MRPS11, RAD21, TXNRD1), and cell adhesion and cell migration genes (EPHA1, PGF, IL8 and CYR61) in iDCs. We confirmed our results by Q-PCR analysis. The E7 peptide but not control peptide (PADRE) induced up-regulation of NFKB1A gene only in HLA-A2 positive iDCs and not in HLA-A2 negative iDCs. These results suggest that E7 up-regulation of genes is specific and HLA restricted and that these genes may represent markers of antigen presentation and help rapidly assess the quality of dendritic cells prior to administration to the host.

Microarray multiplex assay for the simultaneous detection and discrimination of hepatitis B, hepatitis C, and human immunodeficiency type-1 viruses in human blood samples.

Hepatitis B virus (HBV), hepatitis C virus (HCV), and human immunodeficiency virus type-1 (HIV-1) are transfusion-transmitted human pathogens that have a major impact on blood safety and public health worldwide. We developed a microarray multiplex assay for the simultaneous detection and discrimination of these three viruses. The microarray consists of 16 oligonucleotide probes, immobilized on a silylated glass slide. Amplicons from multiplex PCR were labeled with Cy-5 and hybridized to the microarray. The assay detected 1 International Unit (IU), 10 IU, 20 IU of HBV, HCV, and HIV-1, respectively, in a single multiplex reaction. The assay also detected and discriminated the presence of two or three of these viruses in a single sample. Our data represent a proof-of-concept for the possible use of highly sensitive multiplex microarray assay to screen and confirm the presence of these viruses in blood donors and patients.

Designing, testing, and validating a microarray for stem cell characterization.

Microarray technology is a powerful tool that allows for simultaneous assessment of the expression of thousands of genes and identification of gene expression patterns associated with specific cell types. Here we describe a protocol using this method to examine stem cells.

Analysis of the quality of contact-pin fabricated oligonucleotide microarrays.

As the quality of microarrays is critical to successful experiments for data consistency and validity, a reliable and convenient quality control method is needed. We describe a systematic quality control method for large-scale genome oligonucleotide arrays. This method is comprised of three steps to assess the quality of printed arrays. The first step involves assessment of the autofluorescence property of DNA. This step is convenient, quick to perform, and allowed reuse of every array. The second step involves hybridization of arrays with Cy3-labeled 9-mer oligonucleotide target to assess the quality and stability of oligonucleotides. Because this step consumed arrays, one or two arrays from each batch were used to complement the quality control data from autofluorescence. The third step involves hybridization of arrays from every batch with transcripts derived from two cell lines to assess data consistency. These hybridizations were able to distinguish two closely related tissue samples by identifying a cluster of 20 genes that were differently expressed in U87MG and T98G glioblastoma cell lines. In addition, we standardized two parameters that significantly enhanced the quality of arrays. We found that longer pin contact time and crosslinking oligonucleotides at 400 mJ/cm(2) were optimal for the highest hybridization intensity. Taken together, these results indicate that the quality of spotted oligonucleotide arrays should be assessed by at least two methods, autofluorescence and 9-mer hybridization before arrays are used for hybridization experiments.

Development of a focused microarray to assess human embryonic stem cell differentiation.

Human embryonic stem cells (hESC) must be differentiated before clinical use. In addition, the extent of contamination of undifferentiated cells and the efficiency of differentiation must also be assessed prior to clinical application. In this manuscript, we describe the development of a focused microarray that may be used to discriminate between hESC and their differentiated progeny. This array contains 755 genes including embryonic stem cell markers as well as markers of differentiation into neural, mesodermal, and endodermal phenotypes. In addition, we have included candidate genes belonging to families of cytokines, chemokines, receptors, signaling pathways, and homeodomain proteins that are likely to be important in the process of differentiation. Testing and validation of the focused array was performed using RNA from hESC, human embryoid body (hEB) outgrowths, and a human embryonal carcinoma (hEC) cell line. We have compared gene expression with negative background, GAPDH, beta-actin positive controls, and human universal RNA (hURNA), showing that such an array can rapidly distinguish between undifferentiated and differentiated hESC-derived cell populations. We expect that the described array will be extremely useful in evaluating the extent of differentiation and the state of the hESC-derived population utilized for therapeutic purposes.

Gene expression in human embryonic stem cell lines: unique molecular signature.

Human embryonic stem (huES) cells have the ability to differentiate into a variety of cell lineages and potentially provide a source of differentiated cells for many therapeutic uses. However, little is known about the mechanism of differentiation of huES cells and factors regulating cell development. We have used high-quality microarrays containing 16 659 seventy-base pair oligonucleotides to examine gene expression in 6 of the 11 available huES cell lines. Expression was compared against pooled RNA from multiple tissues (universal RNA) and genes enriched in huES cells were identified. All 6 cell lines expressed multiple markers of the undifferentiated state and shared significant homology in gene expression (overall similarity coefficient > 0.85).A common subset of 92 genes was identified that included Nanog, GTCM-1, connexin 43 (GJA1), oct-4, and TDGF1 (cripto). Gene expression was confirmed by a variety of techniques including comparison with databases, reverse transcriptase-polymerase chain reaction, focused cDNA microarrays, and immunocytochemistry. Comparison with published "stemness" genes revealed a limited overlap, suggesting little similarity with other stem cell populations. Several novel ES cell-specific expressed sequence tags were identified and mapped to the human genome. These results represent the first detailed characterization of undifferentiated huES cells and provide a unique set of markers to profile and better understand the biology of huES cells.