Breast cancer expression profiling: the impact of microarray testing on clinical decision making

Modlich, Olga; Prisack, Hans-Bernd; Bojar, Hans

doi:10.1517/14656566.7.15.2069

Cited by 8 publications

(6 citation statements)

References 51 publications

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“…One of the main questions these trials seek to answer is whether tumor molecular profiling can be used prospectively to identify those node-negative/ER-positive patients who eventually relapse, to initiate adjuvant therapy that would not be administered under current treatment protocols. One of the criticisms leveled at microarray tumor gene expression analyses has been that it is a ''black-box'' methodology that provides results without a coherent biologic explanation and that dysregulated expression of any particular gene as a marker of poor prognosis does not indicate a clear-cut condition (26). The current study allows us to further characterize the origins of poor prognosis signatures in breast cancer by demonstrating that dysregulated expression of a single gene, Brd4, can drive the expression of many genes that are frequently observed as components of metastasis-predictive gene expression signatures.…”

Section: Discussionmentioning

confidence: 99%

Bromodomain 4 activation predicts breast cancer survival

Crawford

Alsarraj

Lukes

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

173

187

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Previous work identified the Rap1 GTPase-activating protein Sipa1 as a germ-line-encoded metastasis modifier. The bromodomain protein Brd4 physically interacts with and modulates the enzymatic activity of Sipa1. In vitro analysis of a highly metastatic mouse mammary tumor cell line ectopically expressing Brd4 demonstrates significant reduction of invasiveness without altering intrinsic growth rate. However, a dramatic reduction of tumor growth and pulmonary metastasis was observed after s.c. implantation into mice, implying that activation of Brd4 may somehow be manipulating response to tumor microenvironment in the in vivo setting. Further in vitro analysis shows that Brd4 modulates extracellular matrix gene expression, a class of genes frequently present in metastasis-predictive gene signatures. Microarray analysis of the mammary tumor cell lines identified a Brd4 activation signature that robustly predicted progression and/or survival in multiple human breast cancer datasets analyzed on different microarray platforms. Intriguingly, the Brd4 signature also almost perfectly matches a molecular classifier of low-grade tumors. Taken together, these data suggest that dysregulation of Brd4-associated pathways may play an important role in breast cancer progression and underlies multiple common prognostic signatures.gene expression signatures ͉ metastasis ͉ mouse models T he majority of deaths attributable to solid cancers result from the pathophysiological impact of metastasis. This is starkly illustrated when one considers that the median survival of patients with metastatic breast cancer is Ϸ2-4 years (1), compared with an Ϸ80% survival rate for women whose disease remains nonmetastatic. Advanced disseminated breast cancer thus remains an incurable condition regardless of new treatments (2). It is therefore important to develop a comprehensive understanding of the metastasis biology to identify patients at higher risk of tumor dissemination. This in turn may permit development of therapies and initiation of more aggressive treatment in women with poorer prognoses to reduce the incidence and extent of metastatic disease. Conversely, it may also prove possible to identify women at low risk of metastasis, thus sparing them needless adjuvant therapy.Our laboratory has demonstrated that germ-line genetic variation influences tumor progression. Specifically, in a model system, the F 1 progeny of the highly metastatic polyoma middle-T (PyMT) transgenic mouse and different inbred laboratory mouse strains display wide variations in metastatic efficiency after mammary tumor development (3). The most likely explanation for this observation is that germ-line variation modulates tumor progression. Subsequent identification of heritable loci modulating metastatic efficiency support this hypothesis (4, 5). Positional cloning subsequently identified Sipa1, a GTPase activating protein (GAP) that negatively regulates Rap-GTPases, as the first polymorphic metastasis efficiency gene in mice (6). Studies of human cancer have suggeste...

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Section: Discussionmentioning

confidence: 99%

Bromodomain 4 activation predicts breast cancer survival

Crawford

Alsarraj

Lukes

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

173

187

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“…Technical differences among the studies contribute to the discrepancy in gene expression data, such as different microarray platforms, probes, RNA-labeling methods, and gene sets [ 35 ]. Microarray-based studies of breast cancer usually focus on three main uses of gene expression profiling [ 36 ]. First, gene expression profiling may can generate a molecular classification of breast cancer into different subsets according to clinical subtype, such as high versus low grade [ 37 - 41 ].…”

Section: Discussionmentioning

confidence: 99%

The rapamycin-regulated gene expression signature determines prognosis for breast cancer

et al. 2009

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Background: Mammalian target of rapamycin (mTOR) is a serine/threonine kinase involved in multiple intracellular signaling pathways promoting tumor growth. mTOR is aberrantly activated in a significant portion of breast cancers and is a promising target for treatment. Rapamycin and its analogues are in clinical trials for breast cancer treatment. Patterns of gene expression (metagenes) may also be used to simulate a biologic process or effects of a drug treatment. In this study, we tested the hypothesis that the gene-expression signature regulated by rapamycin could predict disease outcome for patients with breast cancer.

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“…The costs of systemic therapies are high and the side effects from such therapies are severe, so it is important to identify patients who are most and least likely to benefit from these treatments. To date, many gene expression profiling studies have been performed in breast cancer research with disappointingly small overlap among the prognostic signatures identified [28][29][30][31][32][33][34][35][36][37][38]. It has been demonstrated that the prognostic capacity of each of these signatures is better than the conventional outcome classifiers (stage and grade), and some of these signatures are useful enough to have been made commercially available.…”

Section: Discussionmentioning

confidence: 99%

“…Although many effective and reliable breast cancer prognostic gene signatures have been identified, there is little overlap among the identified prognostic genes across different studies [28][29][30][31][32][33][34][35][36][37][38]. This, in part, reflects the obvious heterogeneity of human breast cancers.…”

Section: Introductionmentioning

confidence: 99%

Discovery of candidate genes and pathways that may help explain fertility cycle stage dependent post-resection breast cancer outcome

Wood

Yang

et al. 2008

Breast Cancer Res Treat

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Breast cancer relapse and death occur more often and sooner among young pre-menopausal women. Breast cancer resected during luteal phase cures about a quarter more women than if the operation is performed during follicular phase. We have identified candidate breast cancer gene signatures that may point to the potential mechanisms of cycle stage-dependent surgical cure. We performed whole murine genome microarrays on mammary tumors resected during pre-ovulatory (diestrus, follicular) and post-ovulatory (estrus, luteal) phases of the estrous cycle with known post-surgical cure or relapse (pulmonary metastasis) outcome. A set of genes whose expressions are differentially modulated by fertility cycle stage of tumor resection and also associate with prognosis were identified. These identified genes were validated by qRT-PCR. From two independent microarray studies, we identified 90 genes in mammary tumors whose expressions change significantly (up to 100-fold) across the estrous cycle, 69 genes that are associated with cure/relapse independent of cycle stage at resection, and 24 genes that change significantly (up to 12-fold) across the estrous cycle and also associate with the outcome. The mRNA expression patterns of these 24 identified genes were 100% validated by qRT-PCR in the same samples. We have identified candidate breast cancer genes and pathways that may point to the potential mechanisms by which the post-resection breast cancer outcome is influenced by the menstrual cycle phase of cancer resection. Since human breast cancer outcome is influenced by the menstrual cycle phase of breast cancer resection, we consider this study in a mouse breast cancer model to be a proof of principle that such signatures may well exist in human premenopausal breast cancer. It remains to be determined in human breast cancer whether woman to woman and/or tumor to tumor variability will mask cycle phase dependent and outcome predictive genomic signatures in human premenopausal breast cancer. The pathways identified by these studies are potential targets for the development of peri-surgical neoadjuvant therapies, which may delay or prevent relapse by preventing dormant micrometastatic tumor cells from escaping that dormant state post-operatively.

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Breast cancer expression profiling: the impact of microarray testing on clinical decision making

Cited by 8 publications

References 51 publications

Bromodomain 4 activation predicts breast cancer survival

Bromodomain 4 activation predicts breast cancer survival

The rapamycin-regulated gene expression signature determines prognosis for breast cancer

Discovery of candidate genes and pathways that may help explain fertility cycle stage dependent post-resection breast cancer outcome

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