Project description:In lupus autoimmunity, pathogenic IgG autoantibodies that fix complement and bind FcGammaR on inflammatory cells, are produced with help from T helper (Th1 and Th17) cells specific for peptides from nucleosomes of apoptotic cells; and these Th cells also infiltrate vital organs (1-9). Macrophages (e.g. tingible body MΦ), and DCs are normally tolerant to apoptotic cell antigens (10), but they are activated to present such autoantigens after binding to IgG immune complexes (IC) containing apoptotic cell derived DNA/RNA, which then dually stimulate their TLR and FcGammaR (11-16). Hence, to generate the activating IC, IgG-switched autoantibodies have to be made first by T cell help. Moreover, B cells become efficient antigen presenting cells (APC) to Th cells pre-primed by other APC (17), or if the B cells have developed high affinity somatically mutated receptors by T cell help (18). Thus, conventional APCs participate as disease progresses, but it is unknown who initially primes autoimmune Th cells. We fractionated spleen cells of lupus prone SNF1 mice in search of such APC. To produce lupus-prone SNF1 mice, NZB and SWR mice were purchased from The Jackson Laboratory, ME to breed the lupus-prone SNF1 hybrids (19). Female SNF1 mice, like BWF1, have high serum levels of IgG class anti-DNA and other anti-nuclear autoantibodies by 2 mo, and spontaneously begin to develop severe lupus nephritis by 5 mo age (20). We depleted spleen cells of lupus-prone SNF1 mice of cells with mature lineage markers, including conventional APC, and then isolated pure CD117+ (c-Kit+ or K+) cells from the lineage– (Lin– or L–) cells. These Lin–c-Kit+pure cells, which had morphology of hematopoietic progenitor cells, were the main type of APC inducing nuclear autoantigen-specific T helper cell (Th17) response upon feeding them with nucleosomes. These Lin–c-Kit+pure cell isolate is called &quot;LinminuscKitplus pure&quot; in the Sample titles shown below. CD117 (c-Kit) is also a marker for macrophage/dendritic cell precursors (MDP), which also express CX3CR1 (21-23). Therefore, from T and B-cell depleted spleen cells, we sorted out CD117+CX3CR1–, CD117+CX3CR1+, CD117–CX3CR1+, and CD117–CX3CR1– cell subsets, and then tested their abilities to induce Th responses to nucleosomes. The CD117+CX3CR1– cells were Lin– (Lin–c-Kit+CX3CR1– or L–K+Cx–; named as &quot;LinminuscKitplusCX3CR1minus&quot; in the sample titles below) were very similar to L–K+pure cells (LinminuscKitplus pure), which are also CX3CR1–, although isolated in a different way. Therefore, we compared gene expression profiles of nucleosome-pulsed APC that were isolated in those two ways, namely purified Lin–c-Kit+ pure (LinminuscKitplus pure) cells or the Lin–c-Kit+CX3CR1– (LinminuscKitplusCX3CR1minus) cell subset, with other types of APCs, namely the Lin–c-Kit+CX3CR1+ subset (named as &quot;LinminuscKitminusCX3CR1plus&quot; in sample titles below), or CD11c+CD11blowc-Kit– cells (Dendritic cells in the sample titles below). REFERENCES 1. Adams, S., P. Leblanc, and S. K. Datta. 1991. Junctional region sequences of T-cell receptor b chain genes expressed by pathogenic anti-DNA autoantibody-inducing T helper cells from lupus mice: Possible selection by cationic autoantigens. Proc. Natl. Acad. Sci. USA. 88:11271-11275. 2. Mohan, C., S. Adams, V. Stanik, and S. K. Datta. 1993. Nucleosome: A major immunogen for the pathogenic autoantibody-inducing T cells of lupus. J. Exp. Med. 177:1367-1381. 3. Kaliyaperumal, A., C. Mohan, W. Wu, and S. K. Datta. 1996. Nucleosomal peptide epitopes for nephritis-inducing T helper cells of murine lupus. J. Exp. Med. 183:2459-2469. 4. Lu, L., A. Kaliyaperumal, D. T. Boumpas, and S. K. Datta. 1999. Major peptide autoepitopes for nucleosome-specific T cells of human lupus. J. Clin. Invest. 104:345-355. 5. Balomenos, D., R. Rumold, and A. N. Theofilopoulos. 1998. Interferon-gamma is required for lupus-like disease and lymphoaccumulation in MRL-lpr mice. J. Clin. Invest. 101:364-371. 6. Doreau, A., A. Belot, J. Bastid, B. Riche, M. C. Trescol-Biemont, B. Ranchin, N. Fabien, P. Cochat, C. Pouteil-Noble, P. Trolliet, I. Durieu, J. Tebib, B. Kassai, S. Ansieau, A. Puisieux, J. F. Eliaou, and N. Bonnefoy-Berard. 2009. Interleukin 17 acts in synergy with B cell-activating factor to influence B cell biology and the pathophysiology of systemic lupus erythematosus. Nat. Immunol. 10:778-785. 7. Kang, H.-K., M. Liu, and S. K. Datta. 2007. Low-Dose Peptide Tolerance Therapy of Lupus Generates Plasmacytoid Dendritic Cells That Cause Expansion of Autoantigen-Specific Regulatory T Cells and Contraction of Inflammatory Th17 Cells (cover page Figure). J Immunol 178:7849-7858. 8. Hsu, H. C., P. Yang, J. Wang, Q. Wu, R. Myers, J. Chen, J. Yi, T. Guentert, A. Tousson, A. L. Stanus, T. V. Le, R. G. Lorenz, H. Xu, J. K. Kolls, R. H. Carter, D. D. Chaplin, R. W. Williams, and J. D. Mountz. 2008. Interleukin 17-producing T helper cells and interleukin 17 orchestrate autoreactive germinal center development in autoimmune BXD2 mice. Nat. Immunol. 9:166-175. 9. Crispin, J. C., M. Oukka, G. Bayliss, R. A. Cohen, C. A. Van Beek, I. E. Stillman, V. C. Kyttaris, Y. T. Juang, and G. C. Tsokos. 2008. Expanded double negative T cells in patients with systemic lupus erythematosus produce IL-17 and infiltrate the kidneys. J. Immunol. 181:8761-8766. 10. Steinman, R. M., D. Hawiger, and M. C. Nussenzweig. 2003. Tolerogenic dendritic cells. Annu Rev Immunol 21:685-711. 11. Leadbetter, E. A., I. R. Rifkin, A. M. Hohlbaum, B. C. Beaudette, M. J. Shlomchik, and A. Marshak-Rothstein. 2002. Chromatin-IgG complexes activate B cells by dual engagement of IgM and Toll-like receptors. Nature 416:595-598. 12. Blanco, P., A. K. Palucka, M. Gill, V. Pascual, and J. Banchereau. 2001. Induction of dendritic cell differentiation by IFN-alpha in systemic lupus erythematosus. Science 294:1540-1543. 13. Means, T. K., E. Latz, F. Hayashi, M. R. Murali, D. T. Golenbock, and A. D. Luster. 2005. Human lupus autoantibody-DNA complexes activate DCs through cooperation of CD32 and TLR9. J. Clin. Invest. 115:407-417. 14. Bave, U., M. Magnusson, M. L. Eloranta, A. Perers, G. V. Alm, and L. Ronnblom. 2003. Fc gamma RIIa is expressed on natural IFN-alpha-producing cells (plasmacytoid dendritic cells) and is required for the IFN-alpha production induced by apoptotic cells combined with lupus IgG. J Immunol 171:3296-3302. 15. Niewold, T. B., J. A. Kelly, M. H. Flesch, L. R. Espinoza, J. B. Harley, and M. K. Crow. 2008. Association of the IRF5 risk haplotype with high serum interferon-alpha activity in systemic lupus erythematosus patients. Arthritis Rheum. 58:2481-2487. 16. Teichmann, L. L., M. L. Ols, M. Kashgarian, B. Reizis, D. H. Kaplan, and M. J. Shlomchik. 2010. Dendritic cells in lupus are not required for activation of T and B cells but promote their expansion, resulting in tissue damage. Immunity 33:967-978. 17. Rock, K. L., B. Benacerraf, and A. K. Abbas. 1984. Antigen presentation by hapten-specific B lymphocytes. J. Exp. Med. 160:1102-1113. 18. Chaturvedi, A., D. Dorward, and S. K. Pierce. 2008. The B cell receptor governs the subcellular location of Toll-like receptor 9 leading to hyperresponses to DNA-containing antigens. Immunity 28:799-809. 19. Datta, S. K., and R. S. Schwartz. 1976. Genetics of expression of xenotropic virus and autoimmunity in NZB mice. Nature. 263:412-415. 20. Datta, S. K., N. Manny, C. Andrzejewski, J. Andre-Schwartz, and R. S. Schwartz. 1978. Genetic studies of autoimmunity and retrovirus expression in crosses of New Zealand Black mice. I. xenotropic virus. J. Exp. Med. 147:854-871. 21. Fogg, D. K., C. Sibon, C. Miled, S. Jung, P. Aucouturier, D. R. Littman, A. Cumano, and F. Geissmann. 2006. A clonogenic bone marrow progenitor specific for macrophages and dendritic cells. Science 311:83-87. 22. Onai, N., A. Obata-Onai, M. A. Schmid, T. Ohteki, D. Jarrossay, and M. G. Manz. 2007. Identification of clonogenic common Flt3+M-CSFR+ plasmacytoid and conventional dendritic cell progenitors in mouse bone marrow. Nat. Immunol. 8:1207-1216. 23. Waskow, C., K. Liu, G. Darrasse-Jeze, P. Guermonprez, F. Ginhoux, M. Merad, T. Shengelia, K. Yao, and M. Nussenzweig. 2008. The receptor tyrosine kinase Flt3 is required for dendritic cell development in peripheral lymphoid tissues. Nat. Immunol. 9:676-683. 24. Du, P., W. A. Kibbe, and S. M. Lin. 2008. lumi: a pipeline for processing Illumina microarray. Bioinformatics 24:1547-1548. 25. Lin, S. M., P. Du, W. Huber, and W. A. Kibbe. 2008. Model-based variance-stabilizing transformation for Illumina microarray data. Nucleic Acids Res 36:e11. 26. Du, P., W. A. Kibbe, and S. M. Lin. 2007. nuID: a universal naming scheme of oligonucleotides for illumina, affymetrix, and other microarrays. Biol Direct 2:16. 27. Wettenhall, J. M., and G. K. Smyth. 2004. limmaGUI: a graphical user interface for linear modeling of microarray data. Bioinformatics 20:3705-3706. Gene profiling microarray and data analysis. Spleen cells from 3 batches of three 5 mo SNF1 female mice each time were used to obtain three independent isolations of each type of APC population. Total RNA was purified from each APC after incubation with nucleosomes (20µg/ml) for 6h. RNA expression analysis of each type of APC isolate in triplicate was performed at our Genomics Core Facility using Illumina Mouse WG-6 v2.0 Expression Beadchips, which provides coverage of around 45,281 genes and expressed sequence tags. Raw signal intensities of each probe were obtained using data analysis software (Beadstudio; Illumina) and imported to the Lumi package of Bioconductor for data analysis. Before transformation and normalization (24-26), A/P call detection was performed based on detection p value. 20,890 out of 45,281 probes with less than 0.01 were considered as valid signals. For each pairs of four comparisons: Lin–c-Kit+CX3CR1– versus Lin–c-Kit+ CX3CR1+; Lin–c-Kit+pure vs. Lin–c-Kit+CX3CR1+; Lin–c-Kit+CX3CR1– vs. DC; and Lin–c-Kit+pure vs. DC; differentially expressed genes were identified using an Analysis of Variance (ANOVA) model with empirical Bayesian variance estimation (27). Thus, 1,619 genes were identified as being differentially expressed (up or down) on the basis of a statistically significant (raw P-value < 0.01 and false discovery rate adjusted P-value < 0.05), and 1.5-fold change (up or down) in expression level in at least one of the comparisons, and out of these 230 genes were significantly UP-regulated by the above criteria in all 4 pair comparisons.

Project description:The mouse prostate tissue exhibits strong power of regeneration, indicating the exisistence of prostate stem cells. Previously we showed that a single mouse prostate cells defined by Lin-CD44+CD133+Sca-1+CD117+ phenotype can generate a prostate after transplantation in vivo. In this study, we compared gene expression profiles of mouse prostate stem cells ( Lin-CD44+CD133+Sca-1+CD117+) and prostate non-stem cells (Lin-CD44-CD133-Sca-1-CD117-). Primary mouse prostate cells were isolated from BL6 mice. Lin-CD44+CD133+Sca-1+CD117+ and Lin-CD44-CD133-Sca-1-CD117- cells were sorted via FACS, and microarray was performed to compare gene expressions between the two groups of cells.

Project description:The mouse prostate tissue exhibits strong power of regeneration, indicating the exisistence of prostate stem cells. Previously we showed that a single mouse prostate cells defined by Lin-CD44+CD133+Sca-1+CD117+ phenotype can generate a prostate after transplantation in vivo. In this study, we compared gene expression profiles of mouse prostate stem cells ( Lin-CD44+CD133+Sca-1+CD117+) and prostate non-stem cells (Lin-CD44-CD133-Sca-1-CD117-).

Project description:We hypothesize that under homeostatic as well as inflammatory conditions circulating monocytes and/or their bone marrow-derived progenitors might contribute to the replenishment of CD103+ and CD103- DC in lymphoid and non-lymphoid compartments. To that end, bone marrow cells from CX3CR1+/gfp C57BL/6 mice were sorted as follows: lineage negative (CD3, CD19, NK1.1, Ter119, Ly6G and CD11c) CX3CR1+c-kit+. Sorted cells were further cultured in vitro under the continuous presence of GM-CSF. lin-CX3CR1+c-kit+ bone marrow cells gave rise to CD103+ and CD103- DC in vitro. To test whether CD103 might be a suitable marker that allows the differentiation of functionally distinct DC subsets generated in vitro, CD11c+CD103+ and CD11c+CD103- DC were sorted from day 5 cultures of lin-CX3CR1+c-kit+ cells and analyzed by whole mouse genome microarrays from Agilent technologies. Compared to CD103+ DC, CD103- DC displayed a strong up-regulation of transcripts for genes involved in innate immunity, whereas those involved in costimulation were down-modulated. Our data suggest distinct functional activity of these two DC subsets. Keywords: Transcriptional profiling-Cell type comparison

Project description:Innate lymphoid cells (ILCs) develop from common lymphoid progenitors (CLP), which further differentiate into the common ILC progenitor (CILP) that can give rise to both ILCs and NK cells. Murine ILC intermediates have recently been characterized, but the human counterparts and their developmental trajectories have not yet been identified, largely due to the lack of homologous surface receptors in both organisms. Here, we show that human CILPs (CD34+CD117+α4β7+Lin-) acquire CD48 and CD52, which define NK progenitors (NKPs) and innate lymphoid cell precursors (ILCPs). Two distinct NK cell subsets were generated in vitro from CD34+CD117+α4β7+Lin-CD48-CD52+ and CD34+CD117+α4β7+Lin-CD48+CD52+ NKPs, respectively. Independent of NKPs, ILCPs exist in the CD34+CD117+α4β7+Lin-CD48+CD52+ subset and give rise to ILC1s, ILC2s and NCR+ ILC3s, whereas CD34+CD117+α4β7+Lin-CD48+CD52- ILCPs give rise to a distinct subset of ILC3s that have lymphoid tissue inducer (LTi)-like properties. Additionally, CD48 expressing CD34+CD117+α4β7+Lin- precursors give rise to tissue-associated ILCs in vivo. We also observed that the interaction of 2B4 with CD48 induced differentiation of ILC2s, and together these findings show that expression of CD48 by human ILCPs modulates ILC differentiation.

Project description:We hypothesize that under homeostatic as well as inflammatory conditions circulating monocytes and/or their bone marrow-derived progenitors might contribute to the replenishment of CD103+ and CD103- DC in lymphoid and non-lymphoid compartments. To that end, bone marrow cells from CX3CR1+/gfp C57BL/6 mice were sorted as follows: lineage negative (CD3, CD19, NK1.1, Ter119, Ly6G and CD11c) CX3CR1+c-kit+. Sorted cells were further cultured in vitro under the continuous presence of GM-CSF. lin-CX3CR1+c-kit+ bone marrow cells gave rise to CD103+ and CD103- DC in vitro. To test whether CD103 might be a suitable marker that allows the differentiation of functionally distinct DC subsets generated in vitro, CD11c+CD103+ and CD11c+CD103- DC were sorted from day 5 cultures of lin-CX3CR1+c-kit+ cells and analyzed by whole mouse genome microarrays from Agilent technologies. Compared to CD103+ DC, CD103- DC displayed a strong up-regulation of transcripts for genes involved in innate immunity, whereas those involved in costimulation were down-modulated. Our data suggest distinct functional activity of these two DC subsets. Keywords: Transcriptional profiling-Cell type comparison We compared the transcriptional profile of CD11c+CD103+ and CD11c+CD103- dendritic cells by use of Agilent Whole Mouse Genome Microarrays. Two sets of samples were generated independently as real biological replicates. The microarray analysis was performed as a dual-color experiment, including a dye-swap.

Project description:CD117+ (c KIT) and CD117- cells were isolated from mouse bone marrow and there gene expression profile was performed to observe up regulation as well as down regulation of genes. It has been noticed that CD117+ cells has many upregaulted DNA repair genes as compare to cd117- population.

Project description:CD34+ CD117+ cells in human peripheral blood have mast cell-forming capacity. We have identified highly committed mast cell progenitors as Lin- CD34+ CD117 intermediate/high FcεRI+ cells. To explore the gene expression profile of the highly committed mast cell progenitors, we performed whole-transcriptome microarray analyses of the cells and compared them with mature basophils.

Project description:FLAG-GFP tagged LIN-41 was immunoprecipitated using FLAG dynabeads (Sigma) from lysates of young adult C.elegans. After washing steps, bound fraction (IP) was eluted from beads and associated RNAs were isolated by using the Pico pure RNA isloation kit (Invitrogen)

Project description:We characterized the longitudinal gene expression profiles of whole blood from a novel lupus model nephritis: SNF1 (SWR X NZB F1) mice treated with pristane. Genes from interferon, plasma cell, neutrophil, T-cell and protein synthesis signatures were differentially expressed in the pristane-SNF1 model compared to the untreated matched control animals.