Gene expression profiling of the stromal reaction to invasive human breast and prostate cancer

Primary tumor growth induces host tissue responses that are believed to support and promote tumor progression. Identification of the molecular characteristics of the tumor microenvironment and a deeper knowledge of its crosstalk with tumor cells may therefore be crucial for improving our understanding of the processes implicated in cancer progression, for discovering potential therapeutic targets, and for finding a stromal signature that may predict clinical outcome. To selectively address stromal gene expression changes during cancer progression, oligo-based Affymetrix microarray technology was used to analyze laser-microdissected stromal cells derived from invasive human breast and prostate carcinoma in comparison to their normal counterparts. Statistical analysis of the gene expression profile of breast and prostate stroma revealed genes differentially expressed in tumor stroma compared to normal stroma together with genes common to the stromal reaction in both tumor types. Several up and downregulated genes were validated by quantitative real-time RT-PCR and one common upregulated gene, periostin (POSTN), was validated by immunohistochemistry. The tumor-specific stromal genes as well as common stromal genes were observed to cluster breast and prostate cancer patients into two groups with statistically different clinical outcome. Univariate Cox analysis identified the genes whose expression level was most strongly associated with patient survival. Taken together, these observations provide evidence of the implication of the tumor microenvironment in tumor progression and its survival-predictive value.

A distinguishing gene signature shared by tumor-infiltrating Tie2-expressing monocytes, blood "resident" monocytes, and embryonic macrophages suggests common functions and developmental relationships

Daniela Biziato, Michele De Palma, Ferdinando Pucci

We previously showed that Tie2-expressing monocytes (TEMs) have nonredundant proangiogenic activity in tumors. Here, we compared the gene expression profile of tumor-infiltrating TEMs with that of tumor-associated macrophages (TAMs), spleen-derived Gr1(+)Cd11b(+) neutrophils/myeloid-derived suppressor cells, circulating "inflammatory" and "resident" monocytes, and tumor-derived endothelial cells (ECs) by quantitative polymerase chain reaction-based gene arrays. TEMs sharply differed from ECs and Gr1(+)Cd11b(+) cells but were highly related to TAMs. Nevertheless, several genes were differentially expressed between TEMs and TAMs, highlighting a TEM signature consistent with enhanced proangiogenic/tissue-remodeling activity and lower proinflammatory activity. We validated these findings in models of oncogenesis and transgenic mice expressing a microRNA-regulated Tie2-GFP reporter. Remarkably, resident monocytes and TEMs on one hand, and inflammatory monocytes and TAMs on the other hand, expressed coordinated gene expression profiles, suggesting that the 2 blood monocyte subsets are committed to distinct extravascular fates in the tumor microenvironment. We further showed that a prominent proportion of embryonic/fetal macrophages, which participate in tissue morphogenesis, expressed distinguishing TEM genes. It is tempting to speculate that Tie2(+) embryonic/fetal macrophages, resident blood monocytes, and tumor-infiltrating TEMs represent distinct developmental stages of a TEM lineage committed to execute physiologic proangiogenic and tissue-remodeling programs, which can be co-opted by tumors.

2009

Splicy: a web-based tool for the prediction of possible alternative splicing events from Affymetrix probeset data

Philipp Bucher

BACKGROUND: The Affymetrix technology is nowadays a well-established method for the analysis of gene expression profiles in cancer research studies. However, changes in gene expression levels are not the only way to link genes and disease. The existence of gene isoforms specifically linked with cancer or apoptosis is increasingly found in literature. Hence it is of great interest to associate the results of a gene expression study with updated evidences on the transcript structure and its possible variants. RESULTS: We present here a web-based software tool, Splicy, whose primary task is to retrieve data on the mapping of Affymetrix probes to single exons of gene transcripts and displaying graphically this information projected on the gene physical structure.Starting from a list of Affymetrix probesets the program produces a series of graphical displays, each relative to a transcript associated with the gene targeted by a given probe. The information on the transcript-by-transcript and exon-by-exon mapping of probe pairs can be retrieved both graphically and in the form of tab-separated files. The mapping of single probes to NCBI RefSeq or EMBL cDNAs is handled by the ISREC mapping tables used in the CleanEx Expression Reference Database Project. We currently maintain these mappings for most popular human and mouse Affymetrix chips, and Splicy can be queried for matches with human and mouse NCBI RefSeq or EMBL cDNAs. CONCLUSION: Splicy generates probeset annotations and images describing the relation between the single probes and intron/exon structure of the target transcript in all its known variants. We think that Splicy will be useful for giving to the researcher a clearer picture of the possible transcript variants linked with a given gene and an additional view on the interpretation of microarray experiment data. Splicy is publicly available and has been realized in the framework of a bioinformatics grant from the Italian Cancer Research Association.

2007

Characterization of cancer stem cell subpopulations from patient-derived xenografts of advanced prostate cancer

Markus Germann

Androgen-deprivation therapy is the standard treatment for prostate cancer. Despite the initial response, a fraction of cases manifest progression to castration-resistant prostate cancer. PCa recurrence is possibly due to androgen-independent cancer stem cells that reinitiate tumor growth. The properties of cancer stem cells versus highly proliferative progenitor cells remain to be further characterized at the cellular and gene expression level. To address the molecular basis of CSC switch from androgen dependency to independence, we have employed patient-derived xenograft models (LAPC-9 and BM-18) that have different androgen sensitivity properties. We have performed microarray and proteomic analysis of BM-18 tumor tissues prior to and following castration as well as androgen replacement. To characterize the cancer stem cells in these models we have isolated different subpopulations by FACS cytometry, based on combination of selected markers (CD44 and ALDH activity measured by ALDELFUOR assay) aiming to assess the transcriptomic profile of these different populations. To assess response of these CD44+/-/ALDH+/- cells to androgen targeting compounds we have established an androgen-sensitive xenograft model (PNPCa) and tested it by ex vivo tissue culture and organoid viability assays. Proteomic and microarray analysis of bulk BM-18 tumors indicates enrichment of stem cell markers upon castration: CD44, NKX3.1 and ALDH1 isoforms. Readministration of testosterone induces decrease of these markers. Castration induces a rapid tumor volume decrease in the BM-18 as opposed to LAPC-9, reflecting different androgen-dependent cell states. CD44+/-/ALDHhigh/low subpopulations were isolated by flow cytometry and for transcriptomic analysis. Castration in the BM18 model induces an increase in the subpopulations of CD44+/ALDHlow and CD44+/ALDHhigh, while ALDHsingle and ALDHhigh total populations are decreased. Both CD44 expression and ALDH activity is increased in the LAPC-9 model upon castration. Treatment of PNPCa tumor parts ex vivo with enzalutamide inhibited expression of androgen receptor and keratin 8 expression. CD44+ organoids derived from the same tissue did not show altered viability after enzalutamide treatment. Different androgen-independent cancer stem cell populations may be distinguished by ALDH activity status and CD44. Androgen-independent cells in the BM-18 androgen-dependent model are reflected by enrichment of CD44 expression. The least abundant subpopulation CD44+/ALDHhigh is present in the LAPC-9 and expanded upon castration, while in the BM-18 model it is exclusively present after castration, reflecting different androgen sensitivity. Ongoing analysis may elucidate the molecular mechanisms controlling cancer stem cell fates, androgen sensitivity and drug resistance.