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E Puxeddu
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J A Knauf
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M A Sartor
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N Mitsutake
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E P Smith
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M Medvedovic
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C R Tomlinson
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S Moretti
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J A Fagin
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RET/PTC rearrangements represent key genetic events involved in papillary thyroid carcinoma (PTC) initiation. The aim of the present study was to identify the early changes in gene expression induced by RET/PTC in thyroid cells. For this purpose, microarray analysis was conducted on PCCL3 cells conditionally expressing the RET/PTC3 oncogene. Gene expression profiling 48 h after activation of RET/PTC3 identified a statistically significant modification of expression of 270 genes. Quantitative PCR confirmation of 20 of these demonstrated 90% accuracy of the microarray. Functional clustering of genes with greater than or less than 1.75-fold expression change (86 genes) revealed RET/PTC3-induced regulation of genes with key functions in apoptosis (Ripk3, Tdga), cell–cell signaling (Cdh6, Fn1), cell cycle (Il24), immune and inflammation response (Cxcl10, Scya2, Il6, Gbp2, Oas1, Tap1, RT1Aw2, C2ta, Irf1, Lmp2, Psme2, Prkr), metabolism (Aldob, Ptges, Nd2, Gss, Gstt1), signal transduction (Socs3, Nf1, Jak2, Cpg21, Dusp6, Socs1, Stat1, Stat3, Cish) and transcription (Nr4a1, Junb, Hfh1, Runx1, Foxe1). Genes coding for proteins involved in the immune response and in intracellular signal transduction pathways activated by cytokines and chemokines were strongly represented, indicating a critical role of RET/PTC3 in the early modulation of the immune response.

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M Dowsett Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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C Archer Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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L Assersohn Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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R K Gregory Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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P A Ellis Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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J Salter Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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J Chang Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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P Mainwaring Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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I Boeddinghaus Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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S R Johnston Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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T J Powles Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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I E Smith Academic Department of Biochemistry, Royal Marsden Hospital, London, UK.

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The interaction between cell death and cell proliferation determines the growth dynamics of all tissues. Studies are described here which relate the changes in proliferation and apoptosis that occur in human breast cancer during medical therapeutic manoeuvres. Xenograft studies strongly support the involvement of increased apoptosis as well as decreased proliferation after oestrogen withdrawal, and limited studies in clinical samples confirm the involvement of both processes. Cytotoxic chemotherapy induces increases in apoptosis within 24 h of starting treatment. However, after 3 months therapy the residual cell population shows apoptotic and proliferation indices much below pretreatment levels. Further molecular studies of this "dormant" population are important to characterise the mechanism of their resistance to drug therapy. The early changes in proliferation and apoptosis may provide useful intermediate response indices.

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C Orlando Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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C Casini Raggi Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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S Bianchi Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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V Distante Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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L Simi Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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V Vezzosi Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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S Gelmini Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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P Pinzani Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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M Cameron Smith Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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A Buonamano Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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E Lazzeri Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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M Pazzagli Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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L Cataliotti Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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M Maggi Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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M Serio Clinical Biochemistry Unit, Department of Clinical Physiopathology, University of Florence, Florence, Italy.

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Somatostatin analogs are effective in inhibiting growth of human breast cancer cell lines. These antiproliferative effects are mediated by specific receptors located on cell membranes. The somatostatin receptor subtype 2 (sst2) is the principal mediator of somatostatin effects in normal and cancer cells, and its presence has already been demonstrated in breast cancer. The purpose of our study was to evaluate the clinical relevance of the expression of sst2 by quantifying its mRNA in a large group of infiltrating breast cancers and their corresponding normal tissues. The expression of sst2 mRNA was measured with quantitative real time RT-PCR in 169 breast cancers and in their corresponding unaffected tissues. We evaluated the association of sst2 expression with the commonest clinical-pathologic features of breast cancer. The correlation with a marker of cell proliferation (Ki-67) and with receptor concentration was also evaluated. In cancer tissues, we found that the absolute concentrations of sst2 mRNA were significantly higher in estrogen receptor (ER)-positive samples (P=0.002) as well as in lymph-node-negative cancers (P=0.04) (Student's t-test or one-way ANOVA). In addition, sst2 mRNA was significantly higher in breast cancers than in corresponding unaffected tissues (P=0.0002). However, when the clinical-pathologic parameters were considered, this gradient maintained its statistical significance only in tumors expressing positive prognostic markers, such as the presence of ER (P=0.0005) and progesterone receptors (PgR) (P=0005), and the lack of lymph-node involvement (P=0.0003). The same difference was also significant in postmenopausal women (P=0.001) and in T1 patients (P=0.001). In addition, sst2 mRNA expression was significantly higher (P=0.008) in low-proliferating breast cancers. Finally, we found that the quantitative expression of sst2 mRNA was directly related to the PgR concentration in breast cancer tissues (P<0.001). Our data seem to indicate that an upregulation of sst2 gene expression is a common feature of breast cancers which, on the basis of conventional predictive parameters, are expected to have a better prognosis. Featuring a possible role of somatostatin analogs in combined endocrine therapies for breast cancer, our results seem to confirm that the sst2 status of the tumor should be previously investigated.

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