Your search keyword '"Croce, Cm"' showing total 6 results

1. MicroRNA cluster 221-222 and estrogen receptor alpha interactions in breast cancer.

Author

Di Leva G, Gasparini P, Piovan C, Ngankeu A, Garofalo M, Taccioli C, Iorio MV, Li M, Volinia S, Alder H, Nakamura T, Nuovo G, Liu Y, Nephew KP, Croce CM, Di Leva, Gianpiero, Gasparini, Pierluigi, Piovan, Claudia, Ngankeu, Apollinaire, and Garofalo, Michela

Abstract

Background: Several lines of evidence have suggested that estrogen receptor alpha (ERalpha)-negative breast tumors, which are highly aggressive and nonresponsive to hormonal therapy, arise from ERalpha-positive precursors through different molecular pathways. Because microRNAs (miRNAs) modulate gene expression, we hypothesized that they may have a role in ER-negative tumor formation.Methods: Gene expression profiles were used to highlight the global changes induced by miRNA modulation of ERalpha protein. miRNA transfection and luciferase assays enabled us to identify new targets of miRNA 206 (miR-206) and miRNA cluster 221-222 (miR-221-222). Northern blot, luciferase assays, estradiol treatment, and chromatin immunoprecipitation were performed to identify the miR-221-222 transcription unit and the mechanism implicated in its regulation.Results: Different global changes in gene expression were induced by overexpression of miR-221-222 and miR-206 in ER-positive cells. miR-221 and -222 increased proliferation of ERalpha-positive cells, whereas miR-206 had an inhibitory effect (mean absorbance units [AU]: miR-206: 500 AU, 95% confidence interval [CI]) = 480 to 520; miR-221: 850 AU, 95% CI = 810 to 873; miR-222: 879 AU, 95% CI = 850 to 893; P < .05). We identified hepatocyte growth factor receptor and forkhead box O3 as new targets of miR-206 and miR-221-222, respectively. We demonstrated that ERalpha negatively modulates miR-221 and -222 through the recruitment of transcriptional corepressor partners: nuclear receptor corepressor and silencing mediator of retinoic acid and thyroid hormone receptor.Conclusions: These findings suggest that the negative regulatory loop involving miR-221-222 and ERalpha may confer proliferative advantage and migratory activity to breast cancer cells and promote the transition from ER-positive to ER-negative tumors. [ABSTRACT FROM AUTHOR]

Published

2010

2. FHIT: from gene discovery to cancer treatment and prevention.

Author

Pekarsky Y, Zanesi N, Palamarchuk A, Huebner K, Croce CM, Pekarsky, Yuri, Zanesi, Nicola, Palamarchuk, Alexey, Huebner, Kay, and Croce, Carlo M

Abstract

Chromosomal abnormalities, including homozygous deletions and loss of heterozygosity, are among the most common features of human tumours. The short arm of human chromosome 3, particularly the region 3p14.2, is a major site of such rearrangements. The 3p14.2 region spans the most active common fragile site of the human genome, encompassing a familial-kidney-cancer-associated breakpoint and a papilloma virus integration site. 6 years ago, the FHIT gene was identified in this region. Subsequent studies have shown that FHIT is commonly the target of chromosomal aberrations involving the long arm of human chromosome 3 and is thereby inactivated in most of the common human malignant diseases, including cancers of the lung, oesophagus, stomach, breast, and kidney. During the past 5 years, evidence has accumulated in support of a tumour-suppressor function for FHIT. In this review, we describe the recent findings in the molecular biology of FHIT with particular focus on the opportunities for treatment and prevention of cancer that have emerged. [ABSTRACT FROM AUTHOR]

Published

2002

3. Potential cancer therapy with the fragile histidine triad gene: review of the preclinical studies.

Author

Ishii H, Dumon KR, Vecchione A, Fong LYY, Baffa R, Huebner K, Croce CM, Ishii, H, Dumon, K R, Vecchione, A, Fong, L Y, Baffa, R, Huebner, K, and Croce, C M

Abstract

Context: The fragile histidine triad gene (FHIT) encompasses a human common fragile site, FRA3B, that is susceptible to environmental carcinogens. Deletion and inactivation of FHIT have been seen in a number of human premalignant and malignant lesions.Objective: To review and evaluate preclinical studies of cancer therapy using the FHIT tumor suppressor gene and related studies involving Fhit protein expression.Data Sources: A MEDLINE search of articles published from 1996 to June 2001 was performed; article reference lists were used to retrieve additional relevant articles.Study Selection: Immunohistochemical studies of primary tumors or relevant lesions were selected to evaluate Fhit expression in premalignant or malignant stages. Preclinical studies on antitumorigenic or therapeutic introduction of FHIT were reviewed for the effects of exogenous Fhit expression. For the immunohistochemical analyses, 26 studies were included that analyzed at least 15 cases of a single type of tumor. For precancerous lesions, 9 studies were included that analyzed at least 4 cases. For studies of FHIT introduction, 9 published studies were included.Data Extraction: Using primary data from each of the studies, we assessed the rationale and potential contribution of FHIT cancer therapy. Data was independently abstracted by 2 authors and study quality was assessed by 2 other authors.Data Synthesis: Overall, 60% (1162/1948 cases) of primary tumors showed absent or markedly reduced Fhit protein expression in cancer cells. Studies of preneoplastic lesions or early-stage cancer showed absence or marked reduction of Fhit protein expression in 0% to 93% of samples (overall, 31% [127/408 cases]). Preclinical studies using 26 cancer-derived cell lines from human lung, head and neck, esophageal, gastric, cervical, pancreatic, and kidney cancers, showed that reintroduction of FHIT resulted in inhibition of in vitro tumor cell growth or of in vivo tumorigenicity in 17 (57%) of 30 cell line experiments. Model systems for human preventive cancer therapy suggested that oral introduction of viral vector-mediated FHIT into Fhit-deficient mice may prevent carcinogen-induced tumor development in some cases.Conclusion: These findings show that FHIT gene therapy may potentially be clinically useful for treatment of cancer and also prevention of carcinogen-induced tumor development, suggesting a rationale for further research involving FHIT introduction. [ABSTRACT FROM AUTHOR]

Published

2001

4. Familial cancer associated with a polymorphism in ARLTS1.

Author

Sellick GS, Catovsky D, Houlston RS, Calin GA, Croce CM, and Neuberg D

Published

2006

5. MicroRNA in chronic lymphocytic leukemia.

Author

Borkhardt A, Fuchs U, Tuschl T, Chang WJ, Calin GA, Cimmino A, and Croce CM

Published

2006

6. Familial cancer and ARLTS1.

Author

De Brakeleer S, Teugels E, De Grève J, Frank B, Klaes R, Burwinkel B, Calin GA, Croce CM, and Neuberg D

Published

2005