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ABSTRACT: Homeobox-containing genes are involved in different stages of kidney organogenesis, from the early events in intermediate mesoderm to terminal differentiation of glomerular and tubular epithelia. The HOX genes show a unique genomic network organization and regulate normal development. The targeted disruption of paralogous group 11 HOX genes (HOX A11, HOX C11 and HOX D11) results in a complete loss of metanephric kidney induction. Despite a large amount of data are related to the early events in the kidney development, not much is known about HOX genes in advanced kidney organogenesis and carcinogenesis. Here, we compare the expression of the whole HOX gene network in late-stage human foetal kidney development with the same patterns detected in 25 pairs of normal clear cell renal carcinomas (RCCs) and 15 isolated RCC biopsy samples. In the majority of RCCs tested, HOX C11 is upregulated, whereas HOX D11, after an early involvement becomes active again at the 23rd week of the foetal kidney development, is always expressed in normal adult kidneys and is deregulated, together with HOX A11 and lumbosacral locus D HOX genes. Thus, through its function of regulating phenotype cell identity, the HOX network plays an important role in kidney carcinogenesis. Lumbosacral HOX genes are involved in the molecular alterations associated with clear cell kidney cancers and represent, through their deregulation, a molecular mark of tubular epithelial dedifferentiation occurring along tumour evolution, with the restoration of genetic programs associated with kidney organogenesis. The deregulation of lumbosacral HOX genes in RCCs supports (i) the consideration of the HOX gene transcriptome as the potential prognostic tool in kidney carcinogenesis and (ii) the possibility to foresee clinical trials with the purpose of targeting these genes to achieve a therapeutic effect in RCC patients.
Anti-cancer drugs 03/2011; 22(5):392-401. · 2.23 Impact Factor
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Clemente Cillo, Giulia Schiavo,
Monica Cantile,
Michel P Bihl,
Paolo Sorrentino,
Vincenza Carafa,
Maria D' Armiento,
Massimo Roncalli,
Sebastiano Sansano,
Raffaela Vecchione,
Luigi Tornillo,
Lucia Mori,
Gennaro De Libero,
Jessica Zucman-Rossi,
Luigi Terracciano
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ABSTRACT: Liver organogenesis and cancerogenesis share common mechanisms. HOX genes control normal development, primary cellular processes and are characterized by a unique genomic network organization. Less is known about the involvement of HOX genes with liver cancerogenesis. The comparison of the HOX gene network expression between nontumorous livers and hepatocellular carcinomas (HCCs) highlights significant differences in the locus A HOX genes, located on chromosome 7, with a consistent overexpression of HOXA13 mRNA thus validating this gene deregulation as a feature of HCC. HOXA13 is a determinant of gut primordia and posterior body structures. Transcriptome analysis of HCC/nontumorous liver mRNAs, selected on the basis of HOXA13 overexpression, recognizes a set of deregulated genes. The matching of these genes with previously reported HCC transcriptome analysis identifies cell-cycle and nuclear pore-related HCC phenotype displaying poor prognosis. HOXA13 and HOXA7 homeoproteins share a consensus sequence that physically links eIF4E nuclear bodies acting on the export of specific mRNAs (c-myc, FGF-2, vascular endothelial growth factor (VEGF), ornithine decarboxylase (ODC) and cyclin D1). We report the protein-protein interaction between HOXA13 and eIF4E in liver cancer cells and the deregulation of eIF4E mRNA and protein in cell cycle/nuclear pore HCC group phenotype and in T4 stage HCCs, respectively. Thus, transcriptional and post-transcriptional HOXA13 deregulation is involved in HCC possibly through the mRNA nuclear export of eIF4E-dependent transcripts.
International Journal of Cancer 01/2011; 129(11):2577-87. · 5.44 Impact Factor
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ABSTRACT: The expression of the HOX gene network in mid-stage human tooth development mostly concerns the epithelial tooth germ compartment and involves the C and D HOX loci. To further dissect the HOX gene implication with tooth epithelium differentiation we compared the expression of the whole HOX network in human ameloblastomas, as paradigm of epithelial odontogenic tumors, with tooth germs. We identified two ameloblastoma molecular types with respectively low and high number of active HOX C genes. The highly expressing HOX C gene ameloblastomas were characterized by a strong keratinized phenotype. Locus C HOX genes are located on chromosome 12q13–15 in physical contiguity with one of the two keratin gene clusters included in the human genome. The most posterior HOX C gene, HOX C13, is capable to interact with hair keratin genes located on the other keratin gene cluster in physical contiguity with the HOX B locus on chromosome 17q21– 22. Inside the HOX C locus, a 2.2 kb ncRNA (HOTAIR) able to repress transcription, in cis, along the entire HOX C locus and, in trans, at the posterior region of the HOX D locus has recently been identified. Interestingly both loci are deregulated in ameloblastomas. Our finding support an important role of the HOX network in characterizing the epithelial tooth compartment. Furthermore, the physical contiguity between locus C HOX and keratin genes in normal tooth epithelium and their deregulation in the neoplastic counterparts suggest they may act on the same mechanism potentially involved with epithelial tumorigenesis.
Journal of Cellular Biochemistry 01/2011; 112:3206-3215. · 2.87 Impact Factor
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Monica Cantile,
Renato Franco,
Adrienne Tschan,
Daniel Baumhoer,
Inti Zlobec, Giulia Schiavo,
Iris Forte,
Michel Bihl,
Giuseppina Liguori,
Gerardo Botti,
Luigi Tornillo,
Eva Karamitopoulou-Diamantis,
Luigi Terracciano,
Clemente Cillo
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ABSTRACT: HOX genes control normal development, primary cellular processes and are characterized by a unique genomic network organization. Locus D HOX genes play an important role in limb generation and mesenchymal condensation. Dysregulated HOXD13 expression has been detected in breast cancer, melanoma, cervical cancer and astrocytomas. We have investigated the epidemiology of HOXD13 expression in human tissues and its potential deregulation in the carcinogenesis of specific tumors. HOXD13 homeoprotein expression has been detected using microarray technology comprising more than 4,000 normal and neoplastic tissue samples including 79 different tumor categories. Validation of HOXD13 expression has been performed, at mRNA level, for selected tumor types. Significant differences are detectable between specific normal tissues and corresponding tumor types with the majority of cancers showing an increase in HOXD13 expression (16.1% normal vs. 57.7% cancers). In contrast, pancreas and stomach tumor subtypes display the opposite trend. Interestingly, detection of the HOXD13 homeoprotein in pancreas-tissue microarrays shows that its negative expression has a significant and adverse effect on the prognosis of patients with pancreatic cancer independent of the T or N stage at the time of diagnosis. Our study provides, for the first time, an overview of a HOX protein expression in a large series of normal and neoplastic tissue types, identifies pancreatic cancer as one of the most affected by the HOXD13 hoemoprotein and underlines the way homeoproteins can be associated to human cancerogenesis.
International Journal of Cancer 04/2009; 125(7):1532-41. · 5.44 Impact Factor
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Luca Cindolo,
Renato Franco,
Monica Cantile, Giulia Schiavo,
Giuseppina Liguori,
Paolo Chiodini,
Liugi Salzano,
Riccardo Autorino,
Arturo Di Blasi,
Mario Falsaperla,
Elisa Feudale,
Gerardo Botti,
Antonio Gallo,
Clemente Cillo
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ABSTRACT: Neuroendocrine differentiation is a common feature of prostate cancer (pCA). NeuroD1 is a neuronal transcription factor able to convert epithelial cells into neurons. The aim of the study is to investigate NeuroD1 expression and compare it with chromogranin-A, synaptophysin, and CD56 staining in human prostate cell lines and surgical specimens.
We detected NeuroD1 gene expression, by duplex reverse transcriptase-polymerase chain reaction, in primary human prostate fibroblasts, in EPN, LNCaP, DU145, and PC3 cell lines before and after cAMP exposure, in 6 BPH and 11 pCA samples. Thereafter 166 paraffin sections from normal and neoplastic prostates were stained with NeuroD1, chromogranin-A, synaptophysin, and CD56 antibodies. The relationships between chromogranin-A and NeuroD1 and clinicopathologic parameters were evaluated by multivariate logistic regression analysis.
NeuroD1 is inactive in baseline prostate cell lines and BPHs, whereas it is actively expressed in cAMP-treated EPN, PC3, and DU145 cells. In our surgical series, positive chromogranin-A, synaptophysin, CD56, and NeuroD1 staining was detected in 26.5%, 4.3%, 3.1%, and 35.5%, respectively (difference between chromogranin-A and NeuroD1: p<0.05). The multivariate analysis showed a strong association between chromogranin-A and microscopic perineural invasion (OR: 2.49; 95%CI, 0.85-7.32; p=0.097) and a high primary Gleason score (OR: 1.96; 95%CI, 1.14-3.39; p=0.015), whereas NeuroD1 expression strictly correlated to microscopic perineural invasion (OR: 2.97; 95%CI, 1.05-8.41; p=0.04).
Expression of NeuroD1 versus chromogranin-A is more frequent in pCA, and correlates to increased indicators of malignancy in moderately to poorly differentiated pCA, and could be involved in the pathophysiology of the neuroendocrine differentiation of pCA.
European Urology 12/2007; 52(5):1365-73. · 8.49 Impact Factor
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ABSTRACT: Although Hox genes have been identified as master regulatory genes controlling embryonic development, an alternative view on the role of the Hox gene network suggests that it regulates crucial processes at cellular level in eukaryotic organisms. The Hox network acts at the nuclear cell level as a decoding system for external inductive signals to activate specific genetic programs. Cancer can be considered as an anomalous structure growing inside the human body and following, from an architectural viewpoint, the rules controlling body shape as occurs during embryonic development. As a consequence of this viewpoint, it has been proposed that the whole HOX gene network is involved in controlling phenotype cell identity and three-dimensionality of tissues and organs and, furthermore, that specific HOX genes or groups of genes are implicated in the neoplastic alterations of organs and tissues such as kidney, colon, lung, skin, bladder, breast, prostate. Despite our limited understanding of the mechanisms involved, it has already been possible to identify the specific HOX genes perturbed in certain types of human cancers with greater benefit for cancer patients than for better known oncogenes. Here we foresee the start of clinical trials with the purpose of targeting specific HOX genes in order to achieve a therapeutic effect in cancer patients.
Current Cancer Therapy Reviews 01/2007; 300.
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ABSTRACT: Homeobox-containing genes play a crucial role in odontogenesis. After the detection of Dlx and Msx genes in overlapping domains along maxillary and mandibular processes, a homeobox odontogenic code has been proposed to explain the interaction between different homeobox genes during dental lamina patterning. No role has so far been assigned to the Hox gene network in the homeobox odontogenic code due to studies on specific Hox genes and evolutionary considerations. Despite its involvement in early patterning during embryonal development, the HOX gene network, the most repeat-poor regions of the human genome, controls the phenotype identity of adult eukaryotic cells. Here, according to our results, the HOX gene network appears to be active in human tooth germs between 18 and 24 weeks of development. The immunohistochemical localization of specific HOX proteins mostly concerns the epithelial tooth germ compartment. Furthermore, only a few genes of the network are active in embryonal retromolar tissues, as well as in ectomesenchymal dental pulp cells (DPC) grown in vitro from adult human molar. Exposure of DPCs to cAMP induces the expression of from three to nine total HOX genes of the network in parallel with phenotype modifications with traits of neuronal differentiation. Our observations suggest that: (i) by combining its component genes, the HOX gene network determines the phenotype identity of epithelial and ectomesenchymal cells interacting in the generation of human tooth germ; (ii) cAMP treatment activates the HOX network and induces, in parallel, a neuronal-like phenotype in human primary ectomesenchymal dental pulp cells.
Journal of Cellular Biochemistry 04/2006; 97(4):836-48. · 2.87 Impact Factor
