Showing papers by "Olli Kallioniemi published in 1997"

AIB1, a Steroid Receptor Coactivator Amplified in Breast and Ovarian Cancer

Abstract: Members of the recently recognized SRC-1 family of transcriptional coactivators interact with steroid hormone receptors to enhance ligand-dependent transcription. AIB1, a member of the SRC-1 family, was cloned during a search on the long arm of chromosome 20 for genes whose expression and copy number were elevated in human breast cancers. AIB1 amplification and overexpression were observed in four of five estrogen receptor-positive breast and ovarian cancer cell lines. Subsequent evaluation of 105 unselected specimens of primary breast cancer found AIB1 amplification in approximately 10 percent and high expression in 64 percent of the primary tumors analyzed. AIB1 protein interacted with estrogen receptors in a ligand-dependent fashion, and transfection of AIB1 resulted in enhancement of estrogen-dependent transcription. These observations identify AIB1 as a nuclear receptor coactivator whose altered expression may contribute to development of steroid-dependent cancers.

Androgen Receptor Gene Amplification: A Possible Molecular Mechanism for Androgen Deprivation Therapy Failure in Prostate Cancer

Abstract: Progression of prostate cancer during endocrine therapy is a major clinical problem, the molecular mechanisms of which remain poorly understood. Amplification of the androgen receptor (AR) gene was recently described in recurrent prostate carcinomas from patients who had failed androgen deprivation therapy. To evaluate the hypothesis that amplification of the AR gene is a cause for the failure of androgen deprivation therapy in prostate cancer, we studied whether AR amplification leads to gene overexpression, whether the amplified AR gene is structurally intact, and whether tumors with AR amplification have distinct biological and clinical characteristics. Tumor specimens were collected from 54 prostate cancer patients at the time of a local recurrence following therapy failure. In 26 cases, paired primary tumor specimens from the same patients prior to therapy were also available. Fifteen (28%) of the recurrent therapy-resistant tumors, but none of the untreated primary tumors, contained AR gene amplification as determined by fluorescence in situ hybridization. According to single-stranded conformation polymorphism analysis, the AR gene was wild type in all but one of the 13 AR amplified cases studied. In one tumor, a presumed mutation in the hormone-binding domain at codon 674 leading to a Gly --> Ala substitution was found, but functional studies indicated that this mutation did not change the transactivational properties of the receptor. AR amplification was associated with a substantially increased level of mRNA expression of the gene by in situ hybridization. Clinicopathological correlations indicated that AR amplification was most likely to occur in tumors that had initially responded well to endocrine therapy and whose response duration was more than 12 months. Tumors that recurred earlier or those that showed no initial therapy response did not contain AR amplification. The median survival time after recurrence was two times longer for patients with AR amplification in comparison to those with no amplification (P = 0.03, Willcoxon-Breslow test). In conclusion, failure of conventional androgen deprivation therapy in prostate cancer may be caused by a clonal expansion of tumor cells that are able to continue androgen-dependent growth despite of the low concentrations of serum androgens. Amplification and the increased expression of a wild-type AR gene may play a key role in this process.

Genetic changes in intraductal breast cancer detected by comparative genomic hybridization.

Abstract: Ductal carcinoma in situ (DCIS) is considered a direct precursor of invasive ductal breast cancer (IDC). We combined tissue microdissection and comparative genomic hybridization to identify genetic changes in five DCIS lesions with no invasion and in two that were adjacent to IDC. Extensive genetic changes characterized pure DCIS cases with gains of 1q, 6q, 8q, and Xq as well as losses of 17p and chromosome 22 being most often involved. Except for the Xq gain, these changes are also common to IDC. Separate analysis of DCIS and IDC components in the same tumor revealed an almost identical pattern of genetic changes in one case, whereas substantial differences were found in another. We conclude that many of the common genetic changes in IDC may take place before development of invasive growth. However, a simple linear progression model may not always account for the DCIS-IDC transition.

Increased copy number at 17q22-q24 by CGH in breast cancer is due to high-level amplification of two separate regions.

Abstract: Studies by comparative genomic hybridization (CGH) have defined a chromosomal site at 17q22-q24 that is often overrepresented in breast cancer, neuroblastoma, and several other tumor types. Due to the limited resolution and dynamic range of CGH, it remains unclear whether this gain reflects high-level amplification of small subregion(s) or low-level gain of most of the distal 17q. We used 32 physically mapped 17q probes to construct more accurate copy number profiles for 14 breast cancer cell lines by interphase fluorescence in situ hybridization (FISH). Six cell lines (43%) showed an increased copy number of the 17q22-q24 region by CGH, and seven (50%) by FISH. FISH copy number profiles had a substantially higher dynamic range than did CGH profiles. FISH revealed two independent, highly amplified regions (A and B) at 17q23, separated by about 5 Mb of non-amplified DNA. These regions were distinctly telomeric from the ERBB2 gene locus. However, region A was often co-amplified with ERBB2, whereas B was amplified in cell lines that showed no ERBB2 amplification. We conclude that distal 17q gains recently discovered in breast cancer by CGH are due to high-level amplifications of two different regions at 17q23. This chromosomal region has previously been reported to undergo allelic loss and therefore was thought to harbor a tumor suppressor gene. The present FISH data provide support for the presence, and a starting point for the positional isolation, of 17q23 genes whose upregulation by amplification may play a role in the progression of breast cancer and many other tumor types. Genes Chromosomes Cancer 20:372–376, 1997. © 1997 Wiley-Liss, Inc.

Quality control of CGH: impact of metaphase chromosomes and the dynamic range of hybridization.

Abstract: With the recent rapid expansion in the use of the comparative genomic hybridization (CGH) technique, increased attention to quality control is essential. In the present study, we show that despite optimization and standardization of metaphase preparation techniques and the commercial availability of metaphase spreads, batch-to-batch variability of the preparations remains a significant problem. To facilitate reliable CGH analysis despite this variability, we have developed a rapid denaturation test to assess the quality of the preparations without hybridization and quantitative image analysis criteria for assuring the day-to-day quality of CGH experiments, including sensitivity, specificity, and dynamic range. Monitoring the dynamic range of the hybridizations was found to be particularly critical for achieving sensitive and reliable CGH results. This reliability can be achieved, for example, by hybridization of a green-labeled normal male DNA against red-labeled female DNA and monitoring of the green:red ratio of the X chromosome in relation to that of the autosomes.

Genetic changes associated with the acquisition of androgen-independent growth, tumorigenicity and metastatic potential in a prostate cancer model

Abstract: Genetic changes underlying the progression of human prostate cancer are incompletely understood. Recently, an experimental model system that resembles human prostate cancer progression was developed based on the serial passage of an androgen-responsive, non-tumorigenic LNCaP prostate cancer cell line into athymic castrated mice. Six different sublines, derived after one, two or three rounds of in vivo passage, sequentially acquired androgen independence and tumorigenicity as well as metastatic capacity. Here, we used comparative genomic hybridization (CGH) and locus-specific fluorescence in situ hybridization (FISH) analysis to search for genetic changes that may underlie the phenotypic progression events in this model system. Six genetic aberrations were seen by CGH in the parental LNCaP cell line. The derivative sublines shared virtually all these changes, indicating a common clonal origin, but also contained 3-7 additional genetic changes. Gain of the 13q12-q13 chromosomal region as well as losses of 4, 6q24-qter, 20p and 21q were associated with androgen independence and tumorigenicity with additional changes correlating with metastasis. In conclusion, an accumulation of genetic changes correlates with tumour progression in this experimental in vivo model of prostate cancer progression. It is possible that the specific chromosomal aberrations involved in this model system may provide clues to the location of genes involved in human prostate cancer progression and metastasis.

Frequent loss of the 11q14-24 region in chronic lymphocytic leukemia: a study by comparative genomic hybridization. Tampere CLL Group.

Abstract: The genetic basis and molecular pathogenesis of chronic lymphocytic leukemia (CLL) and the molecular mechanisms responsible for its progression remain poorly understood. Here, karyotyping techniques specifically optimized for CLL, comparative genomic hybridization (CGH), and fluorescence in situ hybridization were used to search for CLL-specific genetic aberrations. CGH and karyotyping both revealed copy number changes in 12 of the 25 CLL cases (48%) analyzed. Loss at 11q emerged as the most common aberration (6 cases), followed by a gain of chromosome 12 (4) and loss at 13q (3). Concordance between CGH and G-banding was found in 23 of the 25 cases (92%), which is more than reported in a recent similar CGH study of CLL. Owing to the basic differences in G-banding and CGH, however, their simultaneous clinical application is recommended. The frequent loss of 11q14-24 suggests that this chromosomal region deserves further attention as a candidate locus involved in the pathogenesis of CLL.