Carlo M. Croce

Modulation of mismatch repair and genomic stability by miR-155

Inactivation of mismatch repair (MMR) is the cause of the common cancer predisposition disorder Lynch syndrome (LS), also known as hereditary nonpolyposis colorectal cancer (HNPCC), as well as 10–40% of sporadic colorectal, endometrial, ovarian, gastric, and urothelial cancers. Elevated mutation rates (mutator phenotype), including simple repeat instability [microsatellite instability (MSI)] are a signature of MMR defects. MicroRNAs (miRs) have been implicated in the control of critical cellular pathways involved in development and cancer. Here we show that overexpression of miR-155 significantly down-regulates the core MMR proteins, hMSH2, hMSH6, and hMLH1, inducing a mutator phenotype and MSI. An inverse correlation between the expression of miR-155 and the expression of MLH1 or MSH2 proteins was found in human colorectal cancer. Finally, a number of MSI tumors with unknown cause of MMR inactivation displayed miR-155 overexpression. These data provide support for miR-155 modulation of MMR as a mechanism of cancer pathogenesis.

MicroRNAs in human cancer: from research to therapy.

Numerous miRNAs are deregulated in human cancers, and experimental evidence indicates that they can play roles as oncogenes or tumor suppressor genes. Similarly to cancer genes that encode proteins, deregulation of miRNA-encoding genes is associated with genetic or epigenetic alterations, such as deletions, amplifications, point mutations and aberrant DNA methylation. The discovery that miRNAs interact with known oncogenes has established further links with molecular pathways implicated in malignant transformation. Finally, miRNAs can be used as diagnostic markers, and their potential as therapeutic molecules has moved miRNAs from the area of basic research to the field of cancer biotechnology.

FHIT gene therapy prevents tumor development in Fhit-deficient mice

The tumor suppressor gene FHIT spans a common fragile site and is highly susceptible to environmental carcinogens. FHIT inactivation and loss of expression is found in a large fraction of premaligant and malignant lesions. In this study, we were able to inhibit tumor development by oral gene transfer, using adenoviral or adenoassociated viral vectors expressing the human FHIT gene, in heterozygous Fhit+/− knockout mice, that are prone to tumor development after carcinogen exposure. We therefore suggest that FHIT gene therapy could be a novel clinical approach not only in treatment of early stages of cancer, but also in prevention of human cancer.

Alterations of the Tumor Suppressor Gene Parkin in Non-Small Cell Lung Cancer

Purpose: Parkin, a gene mutated in autosomal recessive juvenile Parkinsonism and mapped to the common fragile site FRA6E on human chromosome 6q25-q27, is associated with a frequent loss of heterozygosity and altered expression in breast and ovarian carcinomas. In addition, homozygous deletions of exon 2 creating deleterious truncations of the Parkin transcript were observed in the lung adenocarcinoma cell lines Calu-3 and H-1573, suggesting that the loss of this locus and the resulting changes in its expression are involved in the development of these tumors. Experimental Design: We examined 20 paired normal and non-small cell lung cancer samples for the presence of Parkin alterations in the coding sequence and changes in gene expression. We also restored gene expression in the Parkin-deficient lung carcinoma cell line H460 by use of a recombinant lentivirus containing the wild-type Parkin cDNA. Results: Loss of heterozygosity analysis identified a common region of loss in the Parkin/FRA6E locus with the highest frequency for the intragenic marker D6S1599 (45%), and semi-quantitative reverse transcription-PCR revealed reduced expression in 3 of 9 (33%) lung tumors. Although we did not observe any in vitro changes in cell proliferation or cell cycle, ectopic Parkin expression had the ability to reduce in vivo tumorigenicity in nude mice. Conclusion: These data suggest that Parkin is a tumor suppressor gene whose inactivation may play an important role in non-small cell lung cancer tumorigenesis.

Designed FHIT alleles establish that Fhit-induced apoptosis in cancer cells is limited by substrate binding

The FHIT gene is inactivated early in the development of many human tumors, and Fhit-deficient mice have increased cancer incidence. Viral reexpression of Fhit kills Fhit-deficient cells by induction of apoptosis. Fhit, a member of branch 2 of the histidine-triad superfamily of nucleoside monophosphate hydrolases and transferases, is a diadenosine polyphosphate hydrolase, the active-site histidine of which is not required for tumor suppression. To provide a rigorous test of the hypothesis that Fhit function depends on forming a complex with substrates, we designed a series of alleles of Fhit intended to reduce substrate-binding and/or hydrolytic rates, characterized these mutants biochemically, and then performed quantitative cell-death assays on cancer cells virally infected with each allele. The allele series covered defects as great as 100,000-fold in kcat and increases as large as 30-fold in KM. Nonetheless, when mutant FHIT genes were expressed in two human cancer cell lines containing FHIT deletions, reductions in apoptotic activity correlated exclusively with KM. Mutants with 2- and 7-fold increases in KM significantly reduced apoptotic indices, whereas the mutant with a 30-fold increase in KM retained little cellular function. These data indicate that the proapoptotic function of Fhit is limited by substrate binding and is unrelated to substrate hydrolysis.

Regulation of BRCA1 Transcription by Specific Single-Stranded DNA Binding Factors

ABSTRACT Since the majority of high-grade breast cancers express reduced levels of BRCA1 mRNA, we investigated the factors regulating BRCA1 transcription. Factors with specific affinity for the previously identified positive regulatory region (PRR) in the BRCA1 promoter were purified from whole-cell extracts. Identified proteins included replication protein A and a series of related factors with affinity for the sense strand of PRR. A subset of the identified factors activated the BRCA1 promoter. Identification of these families of proteins regulating the BRCA1 promoter represents an important step in the comprehension of the mechanisms responsible for breast cancer development.

Exon structure and promoter identification of STIM1 (alias GOK), a human gene causing growth arrest of the human tumor cell lines G401 and RD

The stromal interaction molecular 1 gene (STIM1) encodes a type I trans-membrane protein of unknown function, which induces growth arrest and degeneration of the human tumor cell lines G401 and RD but not HBL100 and CaLu-6, suggesting a role in the pathogenesis of rhabdomyosarcomas and rhabdoid tumors. Here, we describe the STIM1 genomic organization including the identification of the promoter region. The gene consists of 12 exons that span a region larger than 250 kb between the genes RRM1 and NUP98. Nucleotide sequences of all exon-intron boundaries were determined and oligonucleotide primers for the amplification of individual exons were designed. The promoter region was identified within a 1.8-kb SacI fragment at the 5′ end of the gene. In vitro CpG methylation of the promoter region indicated that transcription can be downregulated by this mechanism. The genetic tools developed in the present work will help to determine whether pathogenetic mechanisms that associate STIM1 with tumorigenesis involve mutations in coding sequences and/or promoter, and whether methylation could determine STIM1 transcriptional down-regulation in tumor samples.

A novel t(9;11)(p22;q23) with ALL-1 gene rearrangement associated with progression of a myeloproliferative disorder to acute myeloid leukemia

We have analyzed genomic DNAs from a patient who developed acute myeloid leukemia 1 year after a myeloproliferative disorder was diagnosed. The development of the acute leukemia was associated with the acquisition of a t(9;11)(p22;q23) chromosome translocation. ALL-1 gene rearrangement, on chromosome 11, was present at the onset of the acute phase, but not during the chronic phase of the myeloproliferative disorder. The genomic rearrangement on chromosome 9 was within an unidentified region. By the use of polymerase chain reaction, we were able to determine that the chromosomal rearrangement was completely absent during the chronic phase of the myeloproliferative disorder, indicating that the ALL-1 gene rearrangement was causally related to the development of the acute phase. The rapid progression into the acute phase suggests that this case might be therapy related. This work provides a clear example of association of a molecular defect with the development of a specific clinical leukemic stage, and supports the indication that ALL-1 gene rearrangement is associated with poor clinical outcome in adult leukemias.