Paola Riva

MicroRNA-23b mediates urokinase and c-met downmodulation and a decreased migration of human hepatocellular carcinoma cells

Urokinase‐type plasminogen activator (uPA) and c‐met play a major role in cancer invasion and metastasis. Evidence has suggested that uPA and c‐met overexpression may be coordinated in human hepatocellular carcinoma (HCC). In the present study, to understand whether the expression of these genes might be coregulated by specific microRNAs (miRs) in human cells, we predicted that Homo sapiens microRNA‐23b could recognize two sites in the 3′‐UTR of uPA and four sites in the c‐met 3′‐UTR by the algorithm pictar. The miR‐23b expression analysis in human tumor and normal cells revealed an inverse trend with uPA and c‐met expression, indicating that uPA and c‐met negative regulation might depend on miR‐23b expression. Transfection of miR‐23b molecules in HCC cells (SKHep1C3) led to inhibition of protein expression of the target genes and caused a decrease in cell migration and proliferation capabilities. Furthermore, anti‐miR‐23b transfection in human normal AB2 dermal fibroblasts upregulated the expression of endogenous uPA and c‐met. Cotransfection experiments in HCC cells of the miR‐23b with pGL4.71 Renilla luciferase reporter gene constructs, containing the putative uPA and c‐met 3′‐UTR target sites, and with the pGL3 firefly luciferase‐expressing vector showed a decrease in the relative luciferase activity. This would indicate that miR‐23b can recognize target sites in the 3′‐UTR of uPA and of c‐met mRNAs and translationally repress the expression of uPA and c‐met in HCC cells. The evidence obtained shows that overexpression of miR‐23b leads to uPA and c‐met downregulation and to decreased migration and proliferation abilities of HCC cells.

Mental retardation and cardiovascular malformations in NF1 microdeleted patients point to candidate genes in 17q11.2

Neurofibromatosis type 1 ( NF1 [MIM 162200]) is a common autosomal dominant disorder that affects 1/3500 individuals and is caused by deletion or point mutations of NF1 , a tumour suppressor gene mapping to 17q11.2. Its main features include cafe au lait spots, axillary and inguinal freckling, iris Lisch nodules, neurofibromas, and an increased risk of benign and malignant tumours, particularly optic glioma, neurofibrosarcoma, malignant peripheral nerve sheath tumours (MPNSTs),1 and childhood myeloid leukaemia.2 Over 70% of NF1 germline mutations cause truncation or loss of the encoded protein. Approximately 5–20% of all NF1 patients carry a heterozygous deletion of usually 1.5 Mb involving the NF1 gene and contiguous genes lying in its flanking regions,3,4 which is caused by unequal homologous recombination of NF1 repeats (REPs).5 Known as the “ NF1 microdeletion syndrome,” this condition is often characterised by a more severe phenotype than is observed in the general NF1 group. In particular, NF1 microdeleted patients often show variable facial dysmorphisms, mental retardation, developmental delay, and an excessive number of neurofibromas for age.3,6–12 The severe phenotype of microdeleted patients may be explained by variations in the expression of the genes involved in the rearrangement, which may be caused by different mechanisms, such as gene interruptions, position effects, and decreased gene dosages. Although NF1 microdeleted patients generally have different characteristics from those of classic NF1 patients, it remains difficult to foresee the presence of the deletion at an individual level on the basis of clinical observations. Various studies have reported the clinical characterisation of NF1 deleted patients and the precise extent of the deletion has been characterised in a subset.3–5,13,14 However, no study comparing the incidence of specific clinical signs in NF1 deleted and classical NF1 patients has yet been published. …

NF1 Microdeletion Syndrome: Refined FISH Characterization of Sporadic and Familial Deletions with Locus-Specific Probes

Two familial and seven sporadic patients with neurofibromatosis 1-who showed dysmorphism, learning disabilities/mental retardation, and additional signs and carried deletions of the NF1 gene-were investigated by use of a two-step FISH approach to characterize the deletions. With FISH of YAC clones belonging to a 7-Mb 17q11.2 contig, we estimated the extension of all of the deletions and identified the genomic regions harboring the breakpoints. Mosaicism accounted for the mild phenotype in two patients. In subsequent FISH experiments, performed with locus-specific probes generated from the same YACs by means of a novel procedure, we identified the smallest region of overlapping (SRO), mapped the deletion breakpoints, and identified the genes that map to each deletion interval. From centromere to telomere, the approximately 0.8-Mb SRO includes sequence-tagged site 64381, the SUPT6H gene (encoding a transcription factor involved in chromatin structure), and NF1. Extending telomerically from the SRO, two additional genes-BLMH, encoding a hydrolase involved in bleomycin resistance, and ACCN1, encoding an amiloride-sensitive cation channel expressed in the CNS-were located in the deleted intervals of seven and three patients, respectively. An apparently common centromeric deletion breakpoint was shared by all of the patients, whereas a different telomeric breakpoint defined a deletion interval of 0.8-3 Mb. There was no apparent correlation between the extent of the deletion and the phenotype. This characterization of gross NF1 deletions provides the premise for addressing correctly any genotype-phenotype correlation in the subset of patients with NF1 deletions.

The role of miR-103 and miR-107 in regulation of CDK5R1 expression and in cellular migration.

CDK5R1 encodes p35, a specific activator of the serine/threonine kinase CDK5, which plays crucial roles in CNS development and maintenance. CDK5 activity strongly depends on p35 levels and p35/CDK5 misregulation is deleterious for correct CNS function, suggesting that a tightly controlled regulation of CDK5R1 expression is needed for proper CDK5 activity. Accordingly, CDK5R1 expression was demonstrated to be controlled at both transcriptional and post-transcriptional levels, but a possible regulation through microRNAs (miRNAs) has never been investigated. We predicted, within the large CDK5R1 3′UTR several miRNA target sites. Among them, we selected for functional studies miR-103 and miR-107, whose expression has shown a strong inverse correlation with p35 levels in different cell lines. A significant reduction of CDK5R1 mRNA and p35 levels was observed after transfection of SK-N-BE neuroblastoma cells with the miR-103 or miR-107 precursor (pre-miR-103 or pre-miR-107). Conversely, p35 levels significantly increased following transfection of the corresponding antagonists (anti-miR-103 or anti-miR-107). Moreover, the level of CDK5R1 transcript shifts from the polysomal to the subpolysomal mRNA fraction after transfection with pre-miR-107 and, conversely, from the subpolysomal to the polysolmal mRNA fraction after transfection with anti-miR-107, suggesting a direct action on translation efficiency. We demonstrate, by means of luciferase assays, that miR-103 and miR-107 are able to directly interact with the CDK5R1 3′-UTR, in correspondence of a specific target site. Finally, miR-103 and miR-107 overexpression, as well as CDK5R1 silencing, caused a reduction in SK-N-BE migration ability, indicating that these miRNAs affect neuronal migration by modulating CDK5R1 expression. These findings indicate that miR-103 and miR-107 regulate CDK5R1 expression, allowing us to hypothesize that a miRNA-mediated mechanism may influence CDK5 activity and the associated molecular pathways.

A tumor suppressor locus in familial and sporadic chordoma maps to 1p36

Previous cytogenetic/FISH data have demonstrated 1p36 deletions in a relapsing familial clivus chordoma developed by a patient who has 2 daughters, respectively affected with childhood astrocytoma and clivus chordoma. Using an approach that combined the LOH (loss of heterozygosity) study of the father chordoma and the daughter astrocytoma and a segregation analysis from parents to sibs using 17 CA‐repeats spanning 1p36.32–1p36.11, we mapped the cancer susceptibility locus in this family to the 1p36 region. The LOH and haplotype information was elaborated using a pairwise linkage analysis that gave a maximum lod score of 1.2. Additional LOH data relating to 6 sporadic chordomas allowed us to define an SRO (the smallest region of overlapping loss) of about 25 cM from D1S2845 (1p36.31) to D1S2728 (1p36.13). Our overall findings converge on mapping to 1p36 a tumor‐suppressor gene involved in familial and sporadic chordoma. Int. J. Cancer 87:68–72, 2000.

Chromosomal instability in fibroblasts and mesenchymal tumors from 2 sibs with Rothmund-Thomson syndrome.

Rothmund‐Thomson syndrome (RTS) is a rare autosomal recessive genodermatosis associated with increased risk of mesenchymal tumors. The putative gene has been provisionally assigned to chromosome 8. Using a cytogenetic‐molecular approach, we studied lymphocytes, fibroblasts, osteosarcoma (OS) and malignant fibrous histiocytoma (MFH) from 2 affected fraternal twins, looking for constitutive markers of chromosome instability and tumor chromosomal changes which might reflect the common genetic background. The rate of spontaneous chromosome aberrations was not increased in lymphocytes. Conversely, karyotyping of primary fibroblasts from one sib evidenced chromosome breaks and both numerical and structural chromosome changes in 24% and 17% of the metaphases respectively. FISH of a 8q21.3 cosmid allowed us to detect trisomy of the target region on 7% of fibroblast nuclei from both sibs, 47% and 12% of OS and MFH cells. Pronounced chromosomal instability and clonal rearrangements leading to different chromosome‐8 derivatives were detected in both tumors. CGH experiments showed multiple gains/losses, among which del(6q), also revealed by cytogenetics, and 7p gain were common, whereas 8q amplification was present only in OS. Chromosomal instability, observed in fibroblasts from the RTS patients studied, accounts for the increased risk of mesenchymal tumors in these patients. Int. J. Cancer 77:504–510, 1998.

First cytogenetic study of a recurrent familial chordoma of the clivus.

Two recurrences of a familial clivus chordoma, arisen from a patient who developed the primary tumor at age of 8 years, were investigated by cytogenetic and the fluorescence in situ hybridization (FISH) approach. Of the patients 3 daughters, 2 developed, respectively, a clivus chordoma and an astrocytoma in infancy, a familial aggregation highly suggestive of a genetic background. After a 31‐year hiatus, 2 tumor recurrences, developed over 17 months, were removed surgically. Both were hypo‐ or nearly diploid, and had a pronounced karyotypic heterogeneity with clonal and non‐clonal rearrangements affecting several chromosomes. The same rearrangement, a dic(1;9)(p36.1;p21), was shared in both tumor specimens and, in 90% of the cells, chromosome 1p appeared to be involved in unbalanced translocations with different chromosomes, leading to variable losses of 1p. Previous cytogenetic data concerning chordoma are limited to 10 sporadic tumors with an abnormal karyotype; although no tumor‐specific rearrangements have been identified, chromosome 1p appears to be involved frequently. Int. J. Cancer 81:24–30, 1999.

Mapping of candidate region for chordoma development to 1p36.13 by LOH analysis

Various cytogenetic and molecular findings indicate 1p36 loss as a consistent change in sporadic and inherited chordoma, a rare embryogenetic neoplasm arising from notochord remnants. We studied 27 sporadic chordomas by means of loss of heterozygosity (LOH) of 31 microsatellites localized to the 1p36.32–36.11 region, and restricted the minimal LOH interval shared by 85% of the tumours to 1p36.13. We also used RT‐PCR analysis to investigate the role of the candidate genes CASP9, EPH2A, PAX7, DAN and DVL1, which were selected on the basis of the physical mapping of the LOH region and their plausible oncosuppressor function. RT‐PCR analysis showed the presence of DAN and PAX7 transcript fragments of the expected size in all of 8 chordoma samples, whereas the CASP9‐specific fragment was observed in only 3 and EPH2A was absent in one. Smaller than expected DVL1 transcripts were found in 4 tumours as well as in their normal counterpart (nucleus pulposus), which also showed a typically sized transcript. Sequencing revealed the skipping of 3 exons in the smallest DVL1 fragment, thus leading to a frameshift and predicting a truncated DVL1 gene product. Our study of the largest cohort of chordoma patients recruited so far indicates a common molecular lesion at 1p36.13, and suggests that the CASP9, EPH2A and DVL1 genes may play an onco‐suppressing role and be involved in the development of chordoma.

Mutations and novel polymorphisms in coding regions and UTRs of CDK5R1 and OMG genes in patients with non-syndromic mental retardation

Mental retardation (MR) is displayed by 57% of NF1 patients with microdeletion syndrome as a result of 17q11.2 region haploinsufficiency. We considered the cyclin-dependent kinase 5 regulatory subunit 1 (CDK5R1) and oligodendrocyte-myelin glycoprotein (OMG) genes, mapping in the NF1 microdeleted region, as candidate genes for MR susceptibility. CDK5R1 encodes for a neurone-specific activator of cyclin-dependent kinase 5 (CDK5) involved in neuronal migration during central nervous system development. OMG encodes for an inhibitor of neurite outgrowth by the binding to the Nogo-66 receptor (RTN4R). CDK5R1 and OMG genes are characterized by large 3′ and 5′ untranslated regions (UTRs), where we predict the presence of several transcription/translation regulatory elements. We screened 100 unrelated Italian patients affected by unspecific MR for mutations in CDK5R1 and OMG coding regions and in their 3′ or 5′ UTRs. Four novel mutations and two novel polymorphisms for CDK5R1 and three novel mutations for OMG were detected, including two missense changes (c.323C>T; A108V in CDK5R1 and c.1222A>G; T408A in OMG), one synonymous codon variant (c.532C>T; L178L in CDK5R1), four variants in CDK5R1 3′UTR and two changes in OMG 5′UTR. All the mutations were absent in 370 chromosomes from normal subjects. The allelic frequencies of the two novel polymorphisms in CDK5R1 3′UTR were established in both 185 normal and 100 mentally retarded subjects. Prediction of mRNA and protein secondary structures revealed that two changes lead to putative structural alterations in the mutated c.2254C>G CDK5R1 3′UTR and in OMG T408A gene product.

Evaluation of 1p36 markers and clinical outcome in a skull base chordoma study

Chordomas are rare embryogenetic tumors, arising from remnants of the notochord, characterized by local invasiveness and variable tendency for recurrence. No molecular markers are currently used in a clinical setting to distinguish chordomas with an indolent or an aggressive pattern. Among the genetic lesions observed in this tumor, one of the most commonly detected is 1p loss. In a previous study we observed 1p36 loss of heterozygosity (LOH) in 85% of the analyzed chordomas. We studied a group of 16 homogeneously treated skull base chordomas (SBCs), reporting 1p36 LOH in 75% of them and determining the expression pattern of eight apoptotic genes mapped at 1p36. No tumors shared a common expression profile with nucleus pulposus, which is considered the only adult normal tissue deriving from notochord. In particular, tumor necrosis factor receptor superfamily genes TNFRSF8, TNFRSF9, and TNFRSF14 were differently expressed compared with control in a higher percentage of tumors (40%-53%) than were the remaining analyzed genes, suggesting that the deregulation of these three genes might have a role in chordoma tumorigenesis. The presence/absence of LOH and the expression/nonexpression of each apoptotic gene were studied in a survival analysis. Our results suggest that the lack of 1p36 LOH or the presence of TNFRSF8 expression might be associated with a better prognosis in patients with SBCs.