A model for genetic complementation controlling the chromosomal abnormalities and loss of heterozygosity formation in cancer

Nestor, Andrea L.; Hollopeter, S.L.; Matsui, Sei Ichi; Allison, David C.

doi:10.1159/000100406

Cited by 6 publications

(16 citation statements)

References 67 publications

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“…SNP‐maps can be classified as: (i) heterozygous with red (heterozygous) and blue (homozygous) SNPs along the entire chromosome length, indicating presence of DNA from both parental homologues; (ii) broken‐chromosome LOHs resulting from loss of a large fragment(s) from one parental homologue, with the LOH region (blue dots only) found where the DNA from only one homologue remains; and (iii) whole‐chromosome LOHs, or only a haploid genome of one parental homologue remaining (blue dots only), following complete loss of the other parental homologue (Fig. 2) (15). The occasional heterozygous SNPs (red dots) found in whole‐chromosome SNP‐maps may be due to assay errors or to represent small, translocated DNA pieces from opposing parental homologues.…”

Section: Resultsmentioning

confidence: 99%

“…Four prostate cancer cell lines (DU‐145, PC‐3, 22Rv1, LNCap), a benign prostate cell line (RWPE), three lung cancer cell lines (A549, H520, Calu‐6), two benign lung fibroblast lines (CCD‐34Lu, MRC‐5), a pancreatic cancer cell line (SUIT‐2) and a benign skin cell line (BUD‐8) made up the 12 experimental cell lines used. Each of the cell lines was obtained from the American Type Culture Collection (http://www.atcc.org), except for SUIT‐2, which had been previously characterized (15). All cell lines were expanded as monolayer cultures.…”

Section: Methodsmentioning

confidence: 99%

“…Previously reported SNP and SKY results achieved from A549, LN‐18, and SUIT‐2 lines (15) were combined with SNP and SKY data from PC‐3 and DU145 cell lines, for in‐depth analysis of five aneuploid cancer cell lines. Examined by SKY, there were 24, 29, 30, 36 and 40 karyotypes for A549, LN‐18, PC‐3, DU‐145 and SUIT‐2 cell lines respectively, at the Department of Cancer Genetics, Roswell Park Cancer Institute, Buffalo, NY.…”

Section: Methodsmentioning

confidence: 99%

“…Now, we have tested and expanded a hypothesis that aneuploidy is ‘selected’ by the majority of solid tumours to preserve genes and/or other DNA regions essential for tumour cell growth in derivative chromosomes and to eliminate selectively, genes and/or other DNA regions retarding cell proliferation in LOHs (15). In support of this model, we found a core of ∼1.23 × 10 4 genes expressed by all cells in a screen of 885 different cell types.…”

Section: Introductionmentioning

confidence: 99%

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A model for random genetic damage directing selection of diploid or aneuploid tumours

Bazeley

Nestor-Kalinoski²,

Ways³

et al. 2011

Cell Proliferation

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Random loss of cell survival/replication genes was calculated to be low enough for colon stem cells with APC gene mutations to 'select' LOH and derivative chromosome combinations favouring tumour cell proliferation. However, cell survival/replication gene loss was calculated to be too high for colonic stem cells lacking MMR genes to survive chromosomal instability, explaining why MMR mutations only produce tumours with diploid chromosome cells.

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Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A model for random genetic damage directing selection of diploid or aneuploid tumours

Bazeley

Nestor-Kalinoski²,

Ways³

et al. 2011

Cell Proliferation

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“…Paradoxically, aneuploidy is also often found in cancer cells that have gained growth advantages and divide out of control. The normally deleterious effects of simple aneuploidy (gain or loss of whole chromosomes) in diploid cells are compensated for in cancer cells (Nestor et al, 2007). These compensation mechanisms may include polypoidisation or gross chromosomal structural alterations in addition to specific genetic or epigenetic modifications on oncogenes or tumour suppressors.…”

Section: Diseases and Drugs Affecting Chromosome Segregationmentioning

confidence: 99%

Chromosomes during Cell Division

Liu

Allison

Nestor-Kalinoski

2010

Encyclopedia of Life Sciences

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In mitosis, duplicated deoxyribonucleic acid (DNA) goes through a condensation/decondensation cycle. This is followed by nuclear envelope dissolution, mitotic spindle assembly, migration of the sister chromatid pairs to the metaphase plate, division and segregation of identical sets of chromosomes into daughter nuclei and nuclear envelope reformation. This process results in the formation of two genetically identical daughter cells. Dynamic structural changes and the mitotic spindle‐mediated movement are two major features that occur to chromosomes during cell division. Both features are well coordinated with temporal progression of mitosis consisting of five distinct stages (prophase, prometaphase, metaphase, anaphase and telophase), which are regulated by checkpoint mechanisms to maintain genomic integrity. Defects in chromosome segregation are linked to cancer and several genetic diseases. Some enzymes involved in chromosome regulation during cell division have become attractive drug targets. Key Concepts: Mitosis is the process of cell division that results in two genetically identical daughter cells. Mitosis consists of five stages: prophase, prometaphase, metaphase, anaphase and telophase. Chromosomes are classified according to centromere location as metacentric, submetacentric or acrocentric. Chromosome movement in mitosis is a dynamic process controlled by microtubule dynamics and microtubule‐associated motor or nonmotor proteins. Sister chromatid cohesion is established in S phase and is dissolved in two steps in vertebrate mitoses. A kinetochore complex forms at the centromere in mitosis to allow microtubule capture. Mitosis is a coordinated process regulated by checkpoint mechanisms to maintain genomic integrity. Chromosomal missegregation results in cell death or aneuploidy.

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Corrections for mRNA extraction and sample normalization errors find increased mRNA levels may compensate for cancer haplo‐insufficiency

Weaver

Nestor-Kalinoski

Craig

et al. 2013

Genes Chromosomes & Cancer

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The relative mRNA levels of differentially expressed (DE) and housekeeping (HK) genes of six aneuploid cancer lines with large-scale genomic changes identified by SNP/SKY analysis were compared with similar genes in diploid cells. The aneuploid cancer lines had heterogeneous genomic landscapes with subdiploid, diploid, and supradiploid regions and higher overall gene copy numbers compared with diploid cells. The mRNA levels of the haploid, diploid, and triploid HK genes were found to be higher after correction of easily identifiable mRNA measurement errors. Surprisingly, diploid and aneuploid HK gene mRNA levels were the same by standard expression array analyses, despite the higher copy numbers of the cancer cell HK genes. This paradoxical result proved to be due to inaccurate inputs of true intra-cellular mRNAs for analysis. These errors were corrected by analyzing the expression intensities of DE and HK genes in mRNAs extracted from equal cell numbers (50:50) of intact cancer cell and lymphocyte mixtures. Correction for both mRNA extraction/sample normalization errors and total gene copy numbers found the SUIT-2 and PC-3 cell lines' cancer genes both had ∼50% higher mRNA levels per single allele than lymphocyte gene alleles. These increased mRNA levels for single transcribed cancer alleles may restore functional mRNA levels to cancer genes rendered haplo-insufficient by the genetic instability of cancer. © 2013 Wiley Periodicals, Inc.

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A model for genetic complementation controlling the chromosomal abnormalities and loss of heterozygosity formation in cancer

Cited by 6 publications

References 67 publications

A model for random genetic damage directing selection of diploid or aneuploid tumours

A model for random genetic damage directing selection of diploid or aneuploid tumours

Chromosomes during Cell Division

Corrections for mRNA extraction and sample normalization errors find increased mRNA levels may compensate for cancer haplo‐insufficiency

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