Bertrand C. Liang

Mutagenesis, tumorigenicity, and apoptosis: Are the mitochondria involved?

Early studies have shown mitochondrially-mediated oxidative phosphorylation is diminished in cancer cells, with glycolysis being the main source of energy production. More recent provocative reports have indicated that the mitochondria may be involved in a host of different aspects of tumorigenesis, including mutagenesis, maintenance of the malignant phenotype, and control of apoptosis. These studies have broadened the possible roles mitochondria may play in malignancy. Further studies to define the importance of mitochondria should revolve around the functional assessment of these changes in vitro and in vivo, and will be interesting for determining their significance in human cancer.

Effects of hypoxia on drug resistance phenotype and genotype in human glioma cell lines

SummaryRecurrent gliomas are most often treated by chemotherapy. However, these tumors typically acquire resistance to most drugs administered, and patients will usually die of recurrent tumor. Factors which may play a role include overexpression of putative multidrug resistance genes, such as the multidrug resistance gene 1 (MDR1), multidrug resistance associated protein gene (MRP), 06-alkylguanine, DNA alkyltransferase gene (06MT) and excision repair cross complementing gene 1(ERCCl). Tumor hypoxia has also been shown to be associated with drug resistance in other soft tissue tumors. Since gliomas have regions of diminished oxygenation, and have clinical resistance to chemotherapy, the relationship between phenotypic resistance to chemotherapy after hypoxic exposure and expression of drug resistance genes was investigated in glioma cell lines (U373 MG, PFAT-MT). After a 24 hour exposure to hypoxia, drugs 1, 3-bis, 2-chloroethyl-1-nitrosurea (BCNU) and cis-diammine, dichloroplatinum II (CDDP) were administered, and cell survival was determined. Hypoxic exposure was associated with increased survival of the cell lines after administration of BCNU and CDDP, with resistance to BCNU 15 to 30-fold when compared to cells which did not undergo hypoxic exposure. Both tumor cell lines also showed some degree of resistance to CDDP, although not to the extent of BCNU (2 to 3-fold increased resistance). The expression of the drug resistance genes was found to be unchanged when comparing cells which had undergone hypoxic exposure and those which had not. Thus, hypoxic exposure is associated with substantial drug resistance in brain tumor cell lines. The lack of correlation between the induced phenotype and known drug resistance genes suggests other mechanisms may be acting in these tumors in hypoxic conditions.

Suppression of glioblastoma tumorigenicity by the Kruppel-like transcription factor KLF6

The Kruppel-like transcription factor KLF6 is a novel tumor-suppressor gene mutated in a significant fraction of human prostate cancer. It is localized to human chromosome 10p14–15, a region that displays frequent loss of heterozygosity in glioblastoma multiforme (GBM). Indeed, mutations of the KLF6 gene have recently been reported in this tumor type. In this study, we report that the expression of KLF6 is attenuated in human GBM when compared with primary astrocytes. Expression of KLF6 in GBM cells reverts their tumorigenicity both in vitro and in vivo, which is correlated with its transactivation of the p21/CIP1/WAF1 promoter. Additionally, KLF6 inhibits cellular transformation induced by several oncogenes (c-sis/PDGF-B, v-src, H-Ras, and EGFR) that are components of signaling cascades implicated in GBM. Our results provide the first evidence of functional tumor suppression by KFL6, and its loss may contribute to glial tumor progression.

Evidence for association of mitochondrial DNA sequence amplification and nuclear localization in human low-grade gliomas

Gliomas are tumors which have been found to exhibit consistent genetic changes. Recent studies have shown mitochondrial DNA is also altered in these tumors, and include large deletions and gene amplification. Other studies of the mitochondrial genome in cancer have revealed a variety of different alterations, including the localization and insertion of mitochondrial DNA into the nucleus and nuclear genome in HeLa cells and diethylnitrosurea-induced hepatoma cells. Whether these changes are ontogenically early in the multistep pathway to the development of malignancy, or if this phenomenon occurs in human glial tumors is unknown. I sought to study these questions in a panel of unselected primary glial tumors of pathologically low grade. Fifteen tumors were assessed with a mitochondrial cDNA probe with homology to positions 1679-1948, and 2017-2057. All low-grade tumors revealed increases in copy number when compared to a normal brain control. Nuclear suspensions of these tumors were evaluated by fluorescent in situ hybridization (FISH), using the entire mitochondrial genome as a probe after labeling with rhodamine. All tumors showed evidence of mitochondrial sequence localization within the nuclei. A corresponding glioblastoma and two normal brain specimens were also evaluated which did not have amplification of the mitochondrial genome; FISH with the mitochondrial probe revealed minimal hybridization signal within the nuclei of these samples. Mitochondrial DNA nuclear localization can be found in primary low-grade brain neoplasms, and is correlated to increases in mitochondrial DNA.

Genomic copy number changes of DNA repair genes ERCC1 and ERCC2 in human gliomas

Abnormalities of the genomic region of chromosome 19q13.2–13.4 are a common occurrence in brain malignancies and contain a possible tumor suppressor gene involved in gliomas. Since abnormalities of DNA repair are associated with malignancy, we assessed DNA status of the nucleotide excision repair genes located in this area, viz. ERCC1 and ERCC2.Radiodensitometry was used to assess gene copy number in samples obtained from brain tumor specimens from 24 patients. Nine tumors were of lower grade histology (3 pilocytic astrocytomas, 2 gangliogliomas, 4 astrocytomas); 15 tumors were pathologiclly higher grade (4 anaplastic astrocytomas, 11 glioblastomas). Tumor samples were obtained prior to radiation or chemotherapy. Abnormalities of gene copy number of ERCC1 and ERCC2 were observed in 11/24 specimens (46%). Whereas increased and decreased copy numbers were observed for ERCC1, only decreases in copy number of ERCC2 were seen. Three tumors (all lower grade) showed concurrent allelic loss of ERCC1 and ERCC2. Abnormalities of copy number for these genes were not associated with response to subsequent therapy nor survival. However, allelic loss of ERCC2 was associated with younger age at diagnosis when compared to those specimens which did not show loss. There were no significant differences between lower grade and higher grade tumors with respect to these investigations.Abnormalities in copy number of ERCC1 and ERCC2 are common in glial tumors. Further study of this genomic region is necessary to define the importance of these observations in tumor pathophysiology and treatment.

Receptor expression, cytogenetic, and molecular analysis of six continuous human glioma cell lines

SummarySix human glioma cell lines were established from tissues obtained from five patients diagnosed with Kernohan grade IV glioblastoma multiforme and one from a patient with a grade II astrocytoma. One line was from a recurrent patient who had received prior therapy; the other lines were derived from patients at initial diagnosis and/or before cytoreductive therapies other than surgery were given. Considerable variability in phenotypic, karyotypic, and cell surface marker expression was displayed between the six human glioma cell lines. The karyotypes ranged from apparently normal (grade II astrocytoma) to those with complex rearrangements. Trisomy of chromosome 7 was the most common abnormality. The extensive cytogenetic and molecular characterization of these lines may facilitate their utilization in cellular and molecular biologic studies.

Gene amplification elucidated by combined chromosomal microdissection and comparative genomic hybridization

Gene amplification is an important manifestation of genetic instability in cancer. Recently, the study of gene amplification has been greatly facilitated by the development of the molecular cytogenetic techniques of comparative genomic hybridization and chromosome microdissection. We describe in this brief overview a combined approach using both techniques, which allows the identification of chromosomal regions of gene amplification and provides entry point clones for target gene identification. This molecular/cytogenetic approach consisting of chromosome microdissection and comparative genomic hybridization should be valuable in identifying novel amplified genes important in neoplastic development and progression.

Familial neurogenic tumor syndromes

Cancer caused more than 0.5 million deaths in the United States in 2000. This estimate includes patients who have a genetic predisposition to neoplastic disease, including brain neoplasms. Familial tumor syndromes are important to identify clinically because family members require high degrees of monitoring and genetic counseling. Study of these individuals and families has led to the discovery of genes that are an intrinsic aspect of cell regulation and will continue to be relevant in defining mechanisms of neoplastic development in brain and other tissues.

Evidence of allelic imbalance (AI) of chromosome 6 in human astrocytomas

Transfer of human chromosome 6 can suppress the malignant phenotype of melanoma. Because of the neural ectoderm origin of melanoma and since up to 30% of gliomas have abnormalities involving chromosome 6, we performed restriction fragment length polymorphism analysis to determine the importance of allelic loss on chromosome 6 in gliomas. DNA samples from tumor and white blood cells were obtained from patients with pathologically verified gliomas. Of the 20 paired samples, there were two gangliogliomas and one grade I, four grade II, two tumors labeled “low grade,” two grade III, and nine grade IV astrocytomas. DNA was hybridized with polymorphic probes D6S29 (6p21), c-myb (6q23.3-24), SOD2 (6q25), D6S37 (6q26), and ESR (6q27). All grades of tumor revealed areas of genetic loss. Allelic imbalance (AI) was present in 11 of 47 (23%) of informative loci on 6q and four of seven (57%) on 6p. Loci at 6p21 and 6q26 were most often lost. In contrast, probes from three non-chromosome 6 loci demonstrated a combined total of 11% allelic loss. Genetic loss from chromosome 6 is a frequent event in glial neoplasms.