Aneuploidy vs. gene mutation hypothesis of cancer: recent study claims mutation but is found to support aneuploidy

Polo-like kinase 1 inhibition suppresses hepatitis B virus X protein-induced transformation in an in vitro model of liver cancer progression

Chronic hepatitis B virus (HBV) infection is linked to development of hepatocellular carcinoma (HCC). The HBV X protein (pX) is implicated in HCC pathogenesis acting as a weak oncogene or a cofactor in hepatocarcinogenesis. pX induces DNA re-replication, DNA damage, and partial polyploidy in a poorly differentiated, immortalized hepatocyte cell line. In this study we employed sorted, pX-induced polyploid cells to investigate their growth and oncogenic transformation potential over the course of 70 cell doublings. Immediately after live cell-sorting, nearly 40% of pX-induced polyploid cells undergo apoptosis, whereas the surviving cells exhibit proliferation sensitive to p53. After 40 cell generations the pX-expressing polyploid cultures exhibit loss of p53 function and become growth factor- and anchorage-independent, indicative of oncogenic transformation. The pX-induced polyploid cultures in the course of 70 cell generations undergo progressively increasing DNA damage, propagate damaged DNA to daughter cells, and display increased expression of a cluster of proliferation genes shown to be elevated in human HCC, including HBV-HCC. One of these genes is the mitotic kinase Polo-like kinase 1 (Plk1). Oncogenic transformation is suppressed in the absence of pX expression, and significantly, by inhibition of Plk1. These results identify Plk1 as crucial in pX-mediated oncogenic transformation.

CONCLUSION

Partial polyploidy induced by pX is not immediately associated with oncogenic transformation. Continued DNA damage for 40 cell generations is reproducibly associated with loss of p53 function, enhanced expression of Plk1, and oncogenic transformation. Because Plk1 expression is also elevated in HBV-HCC tumors, this in vitro cellular model simulates liver cancer progression and pathogenesis in chronic HBV patients. Inhibition of Plk1 activity suppresses pX-mediated oncogenic transformation, identifying Plk1 as a promising therapeutic target for HBV-mediated HCC.

Promoter methylation in the genesis of gastrointestinal cancer

Colorectal cancers (CRC)--and probably all cancers--are caused by alterations in genes. This includes activation of oncogenes and inactivation of tumor suppressor genes (TSGs). There are many ways to achieve these alterations. Oncogenes are frequently activated by point mutation, gene amplification, or changes in the promoter (typically caused by chromosomal rearrangements). TSGs are typically inactivated by mutation, deletion, or promoter methylation, which silences gene expression. About 15% of CRC is associated with loss of the DNA mismatch repair system, and the resulting CRCs have a unique phenotype that is called microsatellite instability, or MSI. This paper reviews the types of genetic alterations that can be found in CRCs and hepatocellular carcinoma (HCC), and focuses upon the epigenetic alterations that result in promoter methylation and the CpG island methylator phenotype (CIMP). The challenge facing CRC research and clinical care at this time is to deal with the heterogeneity and complexity of these genetic and epigenetic alterations, and to use this information to direct rational prevention and treatment strategies.

Road to the crossroads of life and death: linking sister chromatid cohesion and separation to aneuploidy, apoptosis and cancer

Genomic instability, aberrant cell proliferation and defects in apoptotic cell death are critical issues in cancer. The two most prominent hallmarks of cancer cells are multiple mutations in key genes encoding proteins that regulate important cell-survival pathways, and marked restructuring or redistribution of the chromosomes (aneuploidy) indicative of genomic instability. Both these aspects have been suggested to cause cancer, though a causal role for chromosomal restructuring in tumorigenesis has not been experimentally fully substantiated. This review is aimed at understanding the mechanisms of cell cycle (proliferation) and programmed cell death (apoptosis) and chromosomal instability governed by cohesin and other aneuploidy promoters, which will provide new insights into the process of carcinogenesis and new avenues for targeted treatment.

Hydrophobic bile acids, genomic instability, Darwinian selection, and colon carcinogenesis

Sporadic colon cancer is caused predominantly by dietary factors. We have selected bile acids as a focus of this review since high levels of hydrophobic bile acids accompany a Western-style diet, and play a key role in colon carcinogenesis. We describe how bile acid-induced stresses cause cell death in susceptible cells, contribute to genomic instability in surviving cells, impose Darwinian selection on survivors and enhance initiation and progression to colon cancer. The most likely major mechanisms by which hydrophobic bile acids induce stresses on cells (DNA damage, endoplasmic reticulum stress, mitochondrial damage) are described. Persistent exposure of colon epithelial cells to hydrophobic bile acids can result in the activation of pro-survival stress-response pathways, and the modulation of numerous genes/proteins associated with chromosome maintenance and mitosis. The multiple mechanisms by which hydrophobic bile acids contribute to genomic instability are discussed, and include oxidative DNA damage, p53 and other mutations, micronuclei formation and aneuploidy. Since bile acids and oxidative stress decrease DNA repair proteins, an increase in DNA damage and increased genomic instability through this mechanism is also described. This review provides a mechanistic explanation for the important link between a Western-style diet and associated increased levels of colon cancer.

Reduced level of the spindle checkpoint protein BUB1B is associated with aneuploidy in colorectal cancers

OBJECTIVES

The majority of solid human malignancies demonstrate DNA aneuploidy as a consequence of chromosomal instability. We wanted to investigate whether Aurora A, Aurora B, BUB1B and Mad2 were associated with the development of aneuploidy in colorectal adenocarcinomas as suggested by several in vitro studies, and if their protein levels were related to alterations at the corresponding chromosomal loci.

MATERIALS AND METHODS

Expression levels of these spindle proteins were investigated by immunohistochemistry using tissue micro-arrays in a series of DNA aneuploid and diploid colorectal adenocarcinomas previously examined for genomic aberrations by comparative genomic hybridization.

RESULTS

All proteins were overexpressed in malignant tissues compared to controls (P < 0.001 for all). BUB1B level was significantly reduced in aneuploid compared to diploid cancers (P = 0.001), whereas expression of the other proteins was not associated with DNA ploidy status. High levels of Aurora A (P = 0.049) and low levels of Aurora B (P = 0.031) were associated with poor prognosis, but no associations were revealed between protein expression and genomic aberration.

CONCLUSIONS

A significant reduction of BUB1B level was detected in aneuploid compared to diploid colorectal cancers, consistent with earlier studies showing that loss of spindle checkpoint function may be involved in development of DNA aneuploidy. Our data also show that spindle proteins are overexpressed in colorectal cancers, and that expression of the Aurora kinases is associated with prognosis in colorectal cancer.

A role for polyploidy in the tumorigenicity of Pim-1-expressing human prostate and mammary epithelial cells

Background

Polyploidy is a prominent feature of many human cancers, and it has long been hypothesized that polyploidy may contribute to tumorigenesis by promoting genomic instability. In this study, we investigated whether polyploidy per se induced by a relevant oncogene can promote genomic instability and tumorigenicity in human epithelial cells.

Principal Findings

When the oncogenic serine-threonine kinase Pim-1 is overexpressed in immortalized, non-tumorigenic human prostate and mammary epithelial cells, these cells gradually converted to polyploidy and became tumorigenic. To assess the contribution of polyploidy to tumorigenicity, we obtained sorted, matched populations of diploid and polyploid cells expressing equivalent levels of the Pim-1 protein. Spectral karyotyping revealed evidence of emerging numerical and structural chromosomal abnormalities in polyploid cells, supporting the proposition that polyploidy promotes chromosomal instability. Polyploid cells displayed an intact p53/p21 pathway, indicating that the viability of polyploid cells in this system is not dependent on the inactivation of the p53 signaling pathway. Remarkably, only the sorted polyploid cells were tumorigenic in vitro and in vivo.

Conclusions

Our results support the notion that polyploidy can promote chromosomal instability and the initiation of tumorigenesis in human epithelial cells.

Selective pressures for and against genetic instability in cancer: a time-dependent problem

Genetic instability in cancer is a two-edge sword. It can both increase the rate of cancer progression (by increasing the probability of cancerous mutations) and decrease the rate of cancer growth (by imposing a large death toll on dividing cells). Two of the many selective pressures acting upon a tumour, the need for variability and the need to minimize deleterious mutations, affect the tumour's 'choice' of a stable or unstable 'strategy'. As cancer progresses, the balance of the two pressures will change. In this paper, we examine how the optimal strategy of cancerous cells is shaped by the changing selective pressures. We consider the two most common patterns in multistage carcinogenesis: the activation of an oncogene (a one-step process) and an inactivation of a tumour-suppressor gene (a two-step process). For these, we formulate an optimal control problem for the mutation rate in cancer cells. We then develop a method to find optimal time-dependent strategies. It turns out that for a wide range of parameters, the most successful strategy is to start with a high rate of mutations and then switch to stability. This agrees with the growing biological evidence that genetic instability, prevalent in early cancers, turns into stability later on in the progression. We also identify parameter regimes where it is advantageous to keep stable (or unstable) constantly throughout the growth.

Random aneuploidy in chronic hepatitis C patients

Hepatitis C virus (HCV) has been recently recognized as a potential cause of B-cell lymphoma. Both chronic hepatitis B and C with or without cirrhosis represent major preneoplastic conditions, and the majority of hepatocellular carcinomas arise in these pathological settings. According to the aneuploidy-cancer theory, carcinogenesis is initiated by random aneuploidy, which is either induced by carcinogens or arises spontaneously. The aim of this study was to evaluate random aneuploidy rate in HCV patients during chronic infection and remission (past infection eradicated), compared with non-Hodgkin lymphoma (NHL) patients and healthy controls. To determine random aneuploidy, we applied the FISH technique with probes for chromosomes 9 and 18. Significantly higher random aneuploidy rate was found in the HCV-infected and lymphoma patients than in the control group; the past HCV group in remission had intermediate rates, between those of the control group and the chronically infected patients. Patients who have eradicated HCV infection may nonetheless carry higher risk for future malignancy and therefore need long-term follow-up.

Defining the steps that lead to cancer: replicative telomere erosion, aneuploidy and an epigenetic maturation arrest of tissue stem cells

Recently, an influential sequencing study found that more than 1700 genes had non-silent mutations in either a breast or colorectal cancer, out of just 11 breast and 11 colorectal tumor samples. This is not surprising given the fact that genomic instability is the hallmark of cancer cells. The plethora of genomic alterations found in every carcinoma does not obey the 'law of genotype-phenotype correlation', since the same histological subtype of cancer harbors different gene mutations and chromosomal aberrations in every patient. In an attempt to make sense out of the observed genetic and chromosomal chaos in cancer, I propose a cascade model. According to this model, tissue regeneration depends on the proliferation and serial activation of stem cells. Replicative telomere erosion limits the proliferative life span of adult stem cells and results in the Hayflick limit (M1). However, local tissue exhaustion or old age might promote the activation of M1-deficient tissue stem cells. Extended proliferation of these cells leads to telomere-driven chromosomal instability and aneuploidy (abnormal balance of chromosomes and/or chromosome material). Several of the aforementioned steps have been already described in the literature. However, in contrast to common theories, it is proposed here that the genomic damage blocks the epigenetic differentiation switch. As a result of aneuploidy, differentiation-specific genes cannot be activated by modification of methylation patterns. Consequently, the phenotype of cancer tissue is largely determined by the epigenetic maturation arrest of tissue stem cells, which in addition enables a fraction of cancer cells to proliferate, invade and metastasize, as normal adult stem cells do. The new model combines genetic and epigenetic alterations of cancer cells in one causative cascade and offers an explanation for why identical histologic cancer types harbor a confusing variety of chromosomal and gene aberrations. The Viennese Cascade, as presented here, may end the debate on if and how 'tumor-unspecific' aneuploidy leads to cancer.

Aneuploidy in upper gastro-intestinal tract cancers--a potential prognostic marker?

Chromosomal instability manifesting as aneuploidy is the most frequently observed abnormality in solid tumours. However, the role of aneuploidy as a cause or consequence of cancer remains a controversial topic. In this review, we focus on the karyotypic imbalances recorded for cancers of the upper gastro-intestinal (GI) tract, together with their associated pre-malignant lesions and the potential of aneuploidy as a clinical tool for patient management. Numeric chromosomal aberrations are common throughout gastro-oesophageal cancers and their precursor lesions. Additionally, specific chromosomal aneusomies have been identified as early changes in pre-dysplastic tissues suggesting they may be actively involved in driving tumourigenesis. As a progressive increase in the severity of aneuploidy with neoplastic progression has also been observed, it has thus been shown to be a useful prognostic indicator for patient classification as low or high-risk cases for cancer development. However, the biological basis for the aneuploidy in cancers of the upper GI tract needs to be established to understand its consequences and role during carcinogenesis, which is necessary for improving diagnostics and establishing novel targeted therapies.

Retinoblastoma epidemiology: does the evidence matter?

It has been proposed that retinoblastoma is 'caused' by two sequential mutations affecting the RB1 gene, but this is a rather outdated view of cancer aetiology that does not take into account a large amount of new acquisitions such as chromosomal and epigenetic alterations. Retinoblastoma remains probably the only cancer in which the rather simplistic 'two hit' mutational model is still considered of value, although cancer is known to be associated with genomic and microsatellite instability, defects of the DNA mismatch repair system, alterations of DNA methylation and hystone acethylation/deacethylation, and aneuploidy. Moreover, as it is shown herein, the predictions made by the 'two hit' model, are not fulfilled by the clinical and epidemiological data reported so far. Moreover, while the role of mutational events in cancer has been largely questioned in the more recent literature, no serious effort has been done to investigate the role of epigenetic alterations and aneuploidy in retinoblastoma. Through the analysis of the specialised literature and a set of original epidemiological and biological data concerning retinoblastoma, the authors illustrate the evidences arguing against the 'two hit' hypothesis and propose that epigenetic factors and aneuploidy play central roles in the disease.

The theory of biological robustness and its implication in cancer

One of the essential issues in systems biology is to identify fundamental principles that govern living organisms at the system level. In this chapter, I argue that robustness is a fundamental feature of living systems where its relationship with evolution-trade-offs among robustness, fragility, resource demands, and performance-provides a possible framework for how biological systems have evolved and been organized. In addition, diseases can be con- sidered as a manifestation of fragility of the system. In some cases, such as cancer, the disease state establishes its own robustness against therapeutic interventions. Understanding robustness and its intrinsic properties will provide us with a more profound understanding of biological systems, their anomalies, and countermeasures.

Role of MTHFR polymorphisms and folate levels in different phenotypes of sporadic colorectal cancers

BACKGROUND AND AIMS

By altering both DNA methylation and nucleotide synthesis, folate metabolism is thought to contribute to colorectal carcinogenesis. We examined the role of folate metabolism in three different phenotypes of sporadic colorectal cancers (CRCs), phenotypes that were classified by the status of microsatellite instability (MSI) and chromosomal instability (CIN): MSI-H, microsatellite stability (MSS)/aneuploidy, and MSS/diploid.

PATIENTS AND METHODS

A total of 195 sporadic colorectal tumors and another 195 age- and gender-matched healthy volunteers in Taipei-Veteran General Hospital and Taipei City Hospital were collected. We analyzed for MTHFR (methylenetetrahydrofolate reductase) polymorphisms (C677T, A1297C), folate, and vitamin B(12) levels. We determined MSI status and DNA ploidy with fluorescent polymerase chain reaction and flow cytometry. Relations between clinicopathological variables and molecular variables were analyzed by chi (2) tests (with Yates' correction) for categorical variables and Student's t test for numerical variables.

RESULTS

Folate levels (5.02+/-4.43 ng/ml) were significantly lower in cancer patients than in controls (7.22+/-4.46 ng/ml). Vitamin B(12) level was similar between cancer patients and controls. The frequency of the TT genotype of MTHFR C627T (12.3%) was slightly higher than controls (8.2%), but it did not reach statistical significance (p=0.174). Within the low-folate group (<5 ng/ml), the frequency of the TT genotype in cancer patients (14.4%) was significantly higher than in controls (4.6%). Sixteen patients who had MSI-H CRC (8.2%) had a significantly higher frequency of TT MTHFR (37.5%) and lower folate levels (3.56+/-2.41 ng/ml) than patients with MSS tumors (10.1%, 5.14+/-3.72 ng/ml). Patients with MSS/aneuploid tumors had significantly lower folate levels (4.50+/-3.06 ng/ml) than those with MSS/diploid tumors (6.69+/-4.73 ng/ml).

CONCLUSION

Folate deficiency and the MTHFR genetic polymorphism play an important role in colorectal carcinogenesis, including MSI and CI.

SYNOPSIS

Folate metabolism plays an important role in colorectal carcinogenesis. We demonstrate that patients with MSI-H tumors had higher frequency of TT MTHFR C627T (37.5%), and patients with MSS/aneuploid tumor had lower folate level (4.50+/-3.06 ng/ml).

Application and interpretation of FISH in biomarker studies

Emerging genomic and proteomic data is creating new opportunities to identify novel biomarkers that will have pathway-specific therapeutic impact on cancer progression. Molecular cytogenetic and fluorescence in situ hybridization (FISH) methods have been primarily used in discovery genetic research laboratories until recently. New automated analytical platforms based on FISH technologies and tissue microarray methods are providing a rapid means to determine the impact of consistent genomic aberrations in clinical trials, and in studies designed to investigate differential chemotherapeutic response.

Genomic mechanisms and measurement of structural and numerical instability in cancer cells

The progression to cancer is often associated with instability and the acquisition of genomic heterogeneity, generating both clonal and non-clonal populations. Chromosomal instability (CIN) describes the excessive rate of numerical and structural genomic change in tumors. Mitotic segregation errors strongly influences copy number, while structural aberrations can occur at unstable genomic regions, or through aberrant DNA repair or methylation. Combined molecular cytogenetic analyses can evaluate cell-to-cell variation, and define the complexity of numerical and structural alterations. Because structural change may occur independently of numerical alteration, we propose the term structural chromosomal instability [(S)-CIN] to distinguish numerical from structural CIN.

Random aneuploidy in CML patients at diagnosis and under imatinib treatment

Chronic myeloid leukemia (CML) is characterized by the presence of a BCR-ABL fusion gene, which is the result of a reciprocal translocation between chromosomes 9 and 22, and is cytogenetically visible as a shortened chromosome 22 (Philadelphia). Research during the past two decades has established that BCR-ABL is probably the pathogenetic pathway leading to CML, and that constitutive tyrosine kinase activity is central to BCR-ABL capacity to transform hematopoietic cells in vitro and in vivo. The tyrosine kinase inhibitor imatinib mesylate was introduced into the treatment regimen for CML in 1998. During the last few years, reports on chromosomal changes during imatinib treatment have been described. In this study, we evaluated the random aneuploidy rate with chromosomes 9 and 18 in bone marrow from treated and untreated patients. We found higher aneuploidy rates in both treated and untreated patients compared to the control group. In three patients who were treated with imatinib mesylate for more than 1.5 years, triploidy also appeared in some nuclei. To our knowledge, this is the first report on new chromosomal changes such as random aneuploidy and triploidy under imatinib treatment, but more studies are needed to investigate the long-term effect of the imatinib treatment on genetic instability.

Dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA) and 2,4-dihydroxy-1,4-benzoxazin-3-one (DIBOA), two naturally occurring benzoxazinones contained in sprouts of Gramineae are potent aneugens in human-derived liver cells (HepG2)

Benzoxazinoids (BAs) are toxic constituents of sprouts of Gramineae such as wheat, maize and rye and are part of the plant defence system against pests. In the last years, sprouts have been increasingly consumed as health foods and are also used for the production of dietary supplements. In the present study we investigated the mutagenic activities of the two most abundant BAs, namely 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA) and 2,4-dihydroxy-1,4-benzoxazin-3-one (DIBOA) in the Salmonella/microsome assay and additionally, in micronucleus (MN) assay and single cell gel electrophoresis (SCGE) assay in a human-derived liver cell line (HepG2). DIBOA caused significant induction of his(+) revertants in all three strains in the range between 0.02 and 0.50 mg/plate; the highest activity was observed in TA100 (fivefold increase over the background at the highest dose level). The effect in YG1024 (a derivative of TA98 with increased acetyltransferase activity) was only slightly higher than the effect in the parental strain indicating that acetylation plays no crucial role in the activation of this BA. DIMBOA was in general less active and a positive result was only seen in the base substitution strain (TA100). Addition of rat liver homogenate (S9-mix) led to a significant (ca. twofold) increase of the mutagenic activities of both BAs. In SCGE assays with HepG2 cells consistently negative results were obtained with both compounds whereas in MN assays significant dose dependent effects were observed under similar experimental conditions. DIMBOA caused significant effects already at concentrations > or =1 microM; at the highest dose (20 microM) the MN frequency was sevenfold higher than the background level. DIBOA caused weaker effects and was positive at doses > or =2.5 microM, the maximal induction (twofold over background) was observed with 20 microM. Overall, DIMBOA was ca. 30-fold more active as DIBOA. Subsequent experiments with pancentromeric probes showed that >80% of the MN induced at the highest doses gave a centromere positive signal indicating that both BAs are aneugenic. This is an interesting observation as it is assumed that aneuploidy is a key event in cancer induction and at present no other aneugenic plant-derived substances of dietary relevance are known.

Intratumoral DNA stem-line heterogeneity in superficial spreading melanoma

BACKGROUND

In primary melanomas, data on the degree of intratumoral heterogeneity to date have been lacking.

OBJECTIVE

Our purpose was to investigate intratumoral DNA stem-line heterogeneity in superficial spreading melanoma (SSM).

METHODS

Multiple measuring fields of 54 SSMs (tumor thickness median 1.60 mm) were studied by DNA image cytometry to obtain data on the number of DNA stem lines per tumor, their ploidy characteristics, and intratumoral distribution. Results were compared with standard histopathological criteria.

RESULTS

Twenty-three of 54 SSMs were found to have two or three distinct proliferating tumor cell stem lines (1.46 +/- 0.57 per tumor). Stem lines appeared spatially separated in 22 of 23 SMMs. At least 3 measuring fields per tumor were necessary to identify all stem lines with a likelihood of 95%. DNA heterogeneity correlated with tumor thickness, but occurred in 5 of 19 cases of pT1 melanoma.

CONCLUSIONS

Primary SSMs can be regarded as potentially clonally unstable with a tendency for spatial separation of tumor cell stem lines.

Scientific and clinical opportunities for modeling blood disorders with embryonic stem cells

Our considerable wealth of data concerning hematologic processes has come despite difficulties working with stem and progenitor cells in vitro and their propensity to differentiate. Key methodologies that have sought to overcome such limitations include transgenic/knock-out animals and in vitro studies using murine embryonic stem cells, because both permit investigation of the formation of hematopoietic tissue from nonhematopoietic precursors. Although there have been many successful studies in model animals for understanding hematopoietic-cell development, differences between lower vertebrates and humans have left gaps in our understanding. Clearly, human-specific strategies to study the onset of hematopoiesis, particularly the earliest events leading to the specification of both normal and abnormal hematopoietic tissue, could bring an investigational renaissance. The recent availability of human embryonic stem (hES) cells suggests that such a system is now at hand. This review highlights the potential of hES cells to model human hematologic processes in vitro with an emphasis on disease targets.

Random aneuploidy and telomere capture in chronic lymphocytic leukemia and chronic myeloid leukemia patients

Telomeric regions of the human genome are of particular interest, because rearrangements of these regions are difficult to identify by conventional chromosome banding technology. With the advent of molecular cytogenetic techniques such as fluorescence in situ hybridization (FISH), it has been possible to investigate the terminus in cytogenetically visible terminal deletions and telomere rearrangements. We investigated telomere capture and aneuploidy rates in chronic lymphocytic leukemia (CLL) and chronic myeloid leukemia (CML) patients, as well as in healthy control subsets. Using a FISH technique, we estimated the random aneuploidy and telomere capture of the 21q22, SNRPN, and 15qter loci. Higher aneuploidy rates were found in the leukocytes of CLL and CML patients, compared with the control group, for the 21q22 and SNRPN loci. There was no difference in the aneuploidy rate between the CML and CLL groups. Telomere capture was found in the two groups (CLL and CML), but not in the control group. We propose that the telomere capture phenomenon is much more common than has been reported in the literature; however, its prognostic significance is yet to be established.

A comprehensive continuous-time model for the appearance of CGH signal due to chromosomal missegregations during mitosis

Aneuploidy, the gain or loss of large regions of the genome, is a common feature in cancer cells. Irregularities in chromosomal copy number caused by missegregations of chromosomes during mitosis can be visualized by cytogenetic techniques including fluorescence in situ hybridization (FISH), spectral karyotyping (SKY) and comparative genomic hybridization (CGH). In the current work, we consider the propagation of irregular copy numbers throughout a cell population as the individual cells progress through ordinary mitotic cell cycles. We use an algebraic model to track the different copy numbers as states in a stochastic process, based on the model of chromosome instability of Gusev, Kagansky, and Dooley, and consider the average copy number of a particular chromosome within a cell population as a function of the cell division rate. We review a number of mathematical models for determining the length of the cell cycle, including the Smith-Martin transition probability model and the 'sloppy size' model of Wheals, Tyson and Diekmann. The program MITOSIM simulates the growth of a population of cells using the aforementioned models of the cell cycle. MITOSIM allows the cell population to grow, with occasional resampling, until the average copy number of a given chromosome in the population reaches a preset threshold signifying a positive copy number alteration in this region. MITOSIM calculates the relationship between the missegregation rate and the growth rate of the cell population. This allows the user to test hypotheses regarding the effect chromosomal aberrations have upon the cell cycle, cell growth rates, and time to population dominance.

Profiling cytogenetic diversity with entropy-based karyotypic analysis

Regardless the high degree of variation observed in solid tumor karyotypes, the use of diversity as a measurable phenomenon remains unexplored. Here we present a systematic cytogenetic analysis using Shannon's entropy as a measure for karyotypic diversity. Karyotypes from 14 epithelial tumor types (n = 1232) have the aneuploidy status scored, resulting in highly asymmetrical sample distribution, for which we determine the index of diversity (Shannon H') of structural and numerical chromosomal aberrations. Since karyotypic diversity is tissue-specific, this approach may give rise to new insights into the processes that may account for aneuploidy progression and solid tumor outcomes.

Estrogen mediates Aurora-A overexpression, centrosome amplification, chromosomal instability, and breast cancer in female ACI rats

Estrogens play a crucial role in the causation and development of sporadic human breast cancer (BC). Chromosomal instability (CIN) is a defining trait of early human ductal carcinoma in situ (DCIS) and is believed to precipitate breast oncogenesis. We reported earlier that 100% of female ACI (August/Copenhagen/Irish) rats treated with essentially physiological serum levels of 17beta-estradiol lead to mammary gland tumors with histopathologic, cellular, molecular, and ploidy changes remarkably similar to those seen in human DCIS and invasive sporadic ductal BC. Aurora-A (Aur-A), a centrosome kinase, and centrosome amplification have been implicated in the origin of aneuploidy via CIN. After 4 mo of estradiol treatment, levels of Aur-A and centrosomal proteins, gamma-tubulin and centrin, rose significantly in female ACI rat mammary glands and remained elevated in mammary tumors at 5-6 mo of estrogen treatment. Centrosome amplification was initially detected at 3 mo of treatment in focal dysplasias, before DCIS. At 5-6 mo, 90% of the mammary tumor centrosomes were amplified. Comparative genomic hybridization revealed nonrandom amplified chromosome regions in seven chromosomes with a frequency of 55-82% in 11 primary tumors each from individual rats. Thus, we report that estrogen is causally linked via estrogen receptor alpha to Aur-A overexpression, centrosome amplification, CIN, and aneuploidy leading to BC in susceptible mammary gland cells.

High-grade neuroendocrine carcinomas display unique cytogenetic aberrations

Neuroendocrine tumors represent a spectrum of tumor types with different biologic and clinical features. The morphologic types include the low-grade typical and atypical carcinoids and the high-grade small cell and large cell neuroendocrine carcinomas (NECs). Cytogenetic descriptions of high-grade NECs are rare. Complete karyotypic descriptions of 34 high-grade NECs are reviewed: 7 extrapulmonary small cell NECs, 3 metastatic NECs of unknown primary, and 24 small cell lung carcinomas (SCLCs). Chromosomal deletions are more frequent than gains and often involve the entire chromosome arm. Typical aberrations are deletions of chromosome 3p, 5q, 10q, and 17p and gains of 1q, 3q, and 5p occurring as isochromosomes. Non-small cell lung cancers (NSCLCs) have different cytogenetic aberrations, but those with a metastatic phenotype display the identical aberrations as SCLC, a tumor known for its metastatic phenotype at onset. A genetic classification of lung cancer that incorporates the pattern of recurrent chromosome aberrations may be a better predictor of clinical outcome than a morphologic classification.

Folate deficiency induces aneuploidy in human lymphocytes in vitro-evidence using cytokinesis-blocked cells and probes specific for chromosomes 17 and 21

Folate plays a critical role in the prevention of chromosome breakage and hypomethylation of DNA. Deficiency in this vitamin may lead to demethylation of heterochromatin causing structural centromere defects that could induce abnormal distribution of replicated chromosomes during nuclear division. Because aneuploidy of chromosomes 17 and 21 is often observed in breast cancer and leukaemia and increased risk for these cancers is associated with folate deficiency, we hypothesized that folate deficiency may lead to aneuploidy of chromosomes 17 and 21. To test these hypotheses we cultured lymphocytes from eight female volunteers (aged 40-48 years) in RPMI 1640 medium containing 12 or 120nM of folic acid (FA) or 5-methyltetrahydrofolate (MF) for 9 days. Chromosomes 17 and 21 aneuploidies induced by folate deficiency were measured in mononucleated (MONO) and cytokinesis-blocked binucleated (BN) lymphocytes after dual-color fluorescent in situ hybridization (FISH) with a digoxigenin-labeled probe for the alphoid satellite sequence of chromosome 17 and a biotin-labeled probe for the pericentric region of chromosome 21. The results showed that 12nm of MF or FA caused a significant 26-35% increment in frequency of aneuploidy of chromosome 17 (P = 0.0017) and aneupoidy of chromosome 21 (P = 0.0008) relative to 120nM MF or FA. The pattern of aneuploidy in binucleated cells was significantly correlated with that observed in mononucleated cells (R = 0.51-0.75, P < 0.0004) and was consistent with a model based on chromosome loss or partial aneusomy rescue as the cause rather than non-disjunction, although the latter mechanism could not be excluded. MF was not more efficient than FA in preventing aneuploidy in this in vitro system. We conclude that folate deficiency is a risk factor for chromosomes 17 and 21 aneuploidy.

Activated oncogenes promote and cooperate with chromosomal instability for neoplastic transformation

Most cancer cells are aneuploid. The chromosomal instability hypothesis contends that aneuploidy is the catalyst for transformation, whereas the gene mutation hypothesis asserts that cancer is driven by mutations to proto-oncogenes and tumor-suppressor genes, with the aneuploidy a side effect of tumorigenesis. Because genotoxic stress induced by "culture shock" can obscure the transforming potential of exogenous genes, we cultured wild-type and p53(-/-) mouse embryo fibroblasts in a more physiological (serum-free) environment. Under these conditions, the cells were immortal and, more importantly, chromosomally stable. Expression of oncogenic H-RasV12 did not induce senescence, but sensitized these cells to p53-dependent apoptosis. In addition, H-RasV12 induced chromosomal instability, as well as accumulation and phosphorylation of p53. Significantly, whereas cells grown under standard conditions could be transformed by coexpression of H-RasV12 and E1A, the chromosomally stable cells were refractory to transformation, as measured by anchorage-independent growth and tumor formation in nude mice. These oncogenes required a third genetic alteration that abolished the p53 pathway to create a permissive environment that promotes rapid chromosomal instability and transformation. Oncogene-induced chromosomal instability and transformation was attenuated by antioxidants. These data indicate that chromosomal instability could be a catalyst for oncogenic transformation, and bring together aspects of the chromosomal instability hypothesis and the gene mutation hypothesis for tumorigenesis.

Acquired Robertsonian translocations are not rare events in acute leukemia and lymphoma

Robertsonian translocations are the most common constitutional structural abnormalities but are rarely reported as acquired aberrations in hematologic malignancies. The nonhomologous acrocentric rearrangements are designated as Robertsonian translocations, whereas the homologous acrocentric rearrangements are referred to as isochromosomes. Robertsonian rearrangements have the highest mutation rates of structural chromosome rearrangements based on surveys of newborns and spontaneous abortions. It would be expected that Robertsonian recombinations would be more common than suggested by the literature. A survey of the cytogenetics database from a single institution found 17 patients with acquired Robertsonian rearrangement and hematologic malignancies. This is combined with data from the literature for a total of 237 patients. All of the possible types of Robertsonian rearrangements have been reported in hematologic malignancies, with the i(13q), i(14q), and i(21q) accounting for nearly 60%. Complex karyotypic changes are seen in the majority of cases, corresponding with disease evolution. These karyotypes consistently show loss of chromosomes 5 and/or 7 in the myelocytic disorders, nonacrocentric isochromosomes, and centromeric breakage and reunion. However, nearly 25% of the acquired rearrangements were found as the sole abnormality or in addition to an established cytogenetic aberration. Most of these were the i(14q) with the myelodysplasia subtypes refractory anemia and chronic myelomonocytic leukemia.

Constitutional chromosome aberrations as pathogenetic events in hematologic malignancies

A predisposition to tumor development is associated with some constitutional chromosomal abnormalities. Investigations of families with an apparent hereditary cancer and constitutional chromosome rearrangements have led to the molecular identification of tumor suppressor genes. Under the somatic mutation theory for the development of cancer, two mutational events are required. The first step may be a constitutional event and the second an acquired genetic mutation. Cytogenetic studies were performed on 5633 bone marrow specimens from patients with hematologic malignancies from a single institution. Fifty cases of constitutional chromosome aberrations were detected. Data collected from the literature and from our series are reviewed and compared with the incidence of specific constitutional chromosome aberrations in the newborn population. Possible mechanisms that may predispose individuals with constitutional chromosome aberrations to the development of a hematologic malignancy are reviewed.

Molecular cytogenetic parameters in fibroblasts from patients and carriers of xeroderma pigmentosum

Xeroderma pigmentosum (XP) is a rare autosomal recessive syndrome. Laboratory investigations have failed to detect any consistent anomaly in cells from XP heterozygotic subjects, although examples of behavior intermediate between normal and XP cells have been reported. To estimate random aneuploidy we applied fluorescence in situ hybridization (FISH) with alpha-satellite probes for chromosomes 8 and 9 and replication pattern for TP53 (p53), ERBB2 (HER-2/neu), and MYCN (N-MYC) loci and for the imprinted SNRPN locus. A significantly higher rate of aneuploidy rate was observed in XP patients and carriers than in controls. The asynchrony pattern was significantly higher in XP carriers and patients with all three coding loci analyzed and significantly lower in XP patients and carriers with the imprinted locus SNRPN than in the control group. Molecular cytogenetic parameters such as random aneuploidy and replication pattern, which are known to reflect chromosomal instability, may be part of the tumorigenesis process. In XP patients and carriers, this genetic instability may represent a potential for developing malignancies.

Granulocyte colony-stimulating factor generates epigenetic and genetic alterations in lymphocytes of normal volunteer donors of stem cells

OBJECTIVE

Because the effect of granulocyte colony-stimulating factor (G-CSF), which is widely used for allogeneic stem cell transplantation, on DNA function and stability has not yet been unequivocally elucidated, the aim of this study was to determine whether G-CSF leads to epigenetic and/or genetic modifications.

MATERIALS AND METHODS

Molecular cytogenetic techniques based on fluorescence in situ hybridization technology were used.

RESULTS

Lymphocytes of G-CSF mobilized donors displayed epigenetic (altered replication timing of alleles) and genetic (aneuploidy) alterations similar to those observed in lymphocytes of cancer patients. Specifically, in the donors' lymphocytes, biallelically expressed genes (TP53 and AML1) and a repetitive noncoding DNA sequence associated with chromosome segregation (CEN17) showed loss of synchrony in allelic replication timing (allele-specific replication). Each displayed a highly asynchronous pattern of allelic replication similar to that characterizing monoallelic expressed genes. This non-locus-specific epigenetic phenomenon, which also affects DNA sequences associated with chromosome segregation, was accompanied by aneuploidy. Although the loss of replication synchrony in the lymphocytes of G-CSF mobilized donors was a transient epigenetic modification, aneuploidy remained unchanged. The G-CSF effect also was observed after G-CSF administration in vitro. 5-Azacytidine, a DNA methylation blocking agent, inhibited G-CSF in vitro induction of allele-specific replication.

CONCLUSION

G-CSF, probably via changes in DNA methylation capacity, leads to cancer-characteristic DNA modifications in lymphocytes of normal mobilized donors.

Induction of aneuploidy by increasing chromosomal instability during dedifferentiation of hepatocellular carcinoma

To gain more insight into the role of chromosomal instability (CIN), the cytogenetic hallmark of most solid tumors, we performed fluorescence in situ hybridization (FISH) on interphase nuclei of cytological specimens enabling the correct detection of chromosome copies in intact tumor cells of 18 well (G1), moderately (G2), or poorly (G3) differentiated hepatocellular carcinomas (HCCs). A close correlation between the morphological dedifferentiation and increasing copy numbers and variation of FISH signals was seen for chromosomes 1 and 8, respectively (P < or = 0.0002). Four HCC G1 had constant chromosome patterns for chromosomes 1 and/or 8 with a mean of signals per nucleus < or =5.08 and < or =3 different signal combinations, indicating a low level of CIN, as confirmed by FISH using probes for centromeres of chromosomes 3, 7, and 17. In contrast to this, five HCC G2-3 revealed > or =8.46 signals per nucleus and 23-41 different signal combinations, indicating high levels of CIN. In the remaining cases, signal counts from 5.96-8.46 and 7-15 combinations were seen. Here, nuclei with constant aberration patterns and low copy numbers occurred alongside nuclei with inconstant patterns and high copy numbers. It is evident that in these cases a transition from well to moderately differentiated HCC developed in parallel to an increase in CIN, possibly induced by a major dysregulation of mitotic control mechanisms. In conclusion, CIN may induce a stepwise increase of aneuploidy in HCC that is mirrored by the morphological dedifferentiation of tumor cells.

Refractory nature of normal human diploid fibroblasts with respect to oncogene-mediated transformation

Human cells are known to be more refractory than rodent cells against oncogenic transformation in vitro. To date, the molecular mechanisms underlying such resistance remain largely unknown. The combination of simian virus 40 early region and H-Ras V12 has been effective for transformation of rat embryo fibroblasts, but not for human cells. However, the additional ectopic expression of the telomerase catalytic subunit (hTERT) was reported to be capable of causing transformation of normal human cells. In this study, however, we demonstrate that the combined expression of the above-mentioned three genetic elements is not always sufficient to transform normal human diploid fibroblasts (HDF). Although the expression and function of these introduced genetic elements were essentially the same, among four HDF, TIG-1 and TIG-3 were resistant to transformation. The other two (BJ and IMR-90) showed transformed phenotypes, but they were much restricted compared with rat embryo fibroblasts in expressing simian virus 40 early region and H-Ras V12. In correlation with these phenotypes, TIG-1 and TIG-3 remained diploid after the introduction of these genetic elements, whereas BJ and IMR-90 became highly aneuploid. These results strongly suggest that the lack of telomerase is not the sole reason for the refractory nature of HDF against transformation and that normal human cells have still undefined intrinsic mechanisms rendering them resistant to oncogenic transformation.

Chromosome malsegregation induced by the rodent carcinogens acetamide, pyridine and diethanolamine in Drosophila melanogaster females

The effect of the rodent carcinogens acetamide (AC), pyridine (PY) and diethanolamine (DEA) on meiotic chromosome segregation was assessed in 4-day-old Drosophila melanogaster females. After oral treatment with 0.05, 0.1, 0.2 and 0.3% PY; 0.5, 1, 1.5, 2 and 4% AC; or 5, 10, 20, 40 and 80% DEA, the females were mated to 7-day-old males and three 24h broods were obtained to sample cells exposed mainly as mature oocytes (brood I), and nearly mature oocytes (brood II) with an increasing proportion of early oocytes (brood III). Viability was not affected at the two (PY) or three (AC, DEA) lowest concentrations, decreasing thereafter. PY increased the frequency of nondisjunction exclusively in brood II suggesting its interaction with specific targets. AC and DEA (the most active of the three) induced similar frequencies of nondisjunction in all broods suggesting unspecific cell division perturbations probably due to toxicity. No clear dose effect relationships were observed.

Evaluation of hyperdiploidy in the bladder epithelial cells of male F344 rats treated with ortho-phenylphenol

Ortho-phenylphenol (OPP) is a broad-spectrum fungicide and anti-bacterial agent that has been shown to cause bladder cancer in male F344 rats. An earlier study to investigate the potential role of aneuploidy in OPP-induced bladder carcinogenicity, failed to detect increases in frequencies of hyperdiploidy/polyploidy in treated animals, presumably due to the presence of polyploid cells in the bladder. To overcome this problem, we utilized a novel approach to determine increases in numerical alterations in the slowly dividing replicating cells of the rat bladder following treatment with OPP. Collagenase digestion of the bladder was used to enrich for actively-dividing cells and FISH in conjunction with BrdU was employed to detect hyperdiploidy in the replicating interphase cells. Initial studies were performed using FISH with a chromosome 4 probe. Follow-up studies were conducted with OPP and a positive control, vinblastine sulfate using probes for chromosomes 4 and 19. No significant increases in hyperdiploidy/polyploidy were seen in the replicating bladder cells of the OPP-treated rats using FISH with either the chromosome 4 or 19 probes. As expected, no significant increases in hyperdiploidy were seen in the non-replicating cells. In contrast, highly significant increases in hyperdiploidy/polyploidy, as detected using FISH with probes for either chromosome 4 or 19, were seen in the replicating cells from rats treated with a combination of OPP and vinblastine. The inability to detect increases in hyperdiploidy/polyploidy in the bladder of OPP-treated rats indicates that chromosome gain is unlikely to play a major role in the early genotoxic effects of OPP. However, the increase in hyperdiploidy/polyploidy induced by vinblastine sulfate in OPP-treated rats, clearly demonstrates that this approach using FISH in combination with BrdU is capable of detecting changes in chromosome number even in slowly-dividing tissues, such as the urinary bladder.

Instability of chromosome structure in cancer cells increases exponentially with degrees of aneuploidy

Structurally altered or marker chromosomes are the cytogenetic hallmarks of cancer cells, but their origins are still debated. Here we propose that aneuploidy, which is ubiquitous in cancer and inevitably unbalances thousands of synergistic genes, destabilizes the structure of chromosomes by catalyzing DNA breaks. Aneuploidy catalyzes such breaks by unbalancing teams of enzymes, which synthesize and maintain DNA and nucleotide pools, and even unbalancing histones via the corresponding genes. DNA breaks then initiate deletions, amplifications, and intra- and interchromosomal rearrangements. Our hypothesis predicts that the rate at which chromosomes are altered is proportional to the degree of aneuploidy: the more abnormal the number and balance of chromosomes, the higher the rate of structural alterations. To test this prediction, we have determined the rates at which clonal cultures of diploid and aneuploid Chinese hamster cells generate new, and thus nonclonal, structurally altered chromosomes per mitosis. Based on about 20 metaphases, the number of new, structurally altered chromosomes was 0 per diploid, 0-0.23 per near-diploid, 0.2-1.4 per hypotriploid, 3.25-4.8 per hypertriploid, and 0.4 per near-tetraploid cell. Thus, instability of chromosome structure increases exponentially with the deviation of ploidy from the normal diploid and tetraploid balances. The particular chromosomes engaged in aneuploidy also affected the rates of chromosome alteration, particularly at low aneuploidy indices. We conclude that aneuploidy is sufficient to cause structural instability of chromosomes. Further, we suggest that certain structurally altered chromosomes encode cancer-specific phenotypes that cannot be generated by unbalancing intact chromosomes. We also extend the evidence for aneuploidy causing numerical instability of chromosomes autocatalytically, and adduce evidence that aneuploidy can cause the many gene mutations of cancer cells that have been attributed to various mutator genes.

Genetic and biological subgroups of low-stage follicular thyroid cancer

Investigations of cancer-specific gene rearrangements have increased our understanding of human neoplasia and led to the use of the rearrangements in pathological diagnosis of blood cell and connective tissue malignancies. Here, we have investigated 3p25 rearrangements of the peroxisome proliferator-activated receptor gamma (PPAR gamma) gene in follicular epithelial tumors of the human thyroid gland. Eleven of 42 (26%) low-stage follicular carcinomas, 0 of 40 follicular adenomas, 1 of 30 Hurthle cell carcinomas, 1 of 90 papillary carcinomas, and 0 of 10 nodular goiters had 3p25 rearrangements by interphase fluorescence in situ hybridization. All 11 follicular carcinomas with 3p25 rearrangement exhibited strong, diffuse nuclear immunoreactivity for PPAR gamma, consistent with expression of PPAR gamma fusion protein. Twelve of 42 (29%) low-stage follicular carcinomas had 3p25 aneusomy without PPAR gamma rearrangement (P = 0.01), suggesting that PPAR gamma rearrangement and aneuploidy are independent early events in follicular cancer. Eleven of 12 follicular carcinomas with 3p25 aneusomy exhibited no PPAR gamma immunoreactivity, supporting the existence of two independent pathways. Follicular carcinoma patients with PPAR gamma rearrangement more frequently had vascular invasion (P = 0.01), areas of solid/nested tumor histology (P < 0.001), and previous non-thyroid cancers (P < 0.01) compared with follicular carcinoma patients without PPAR gamma rearrangement. Our experiments identify genetic subgroups of low-stage follicular thyroid cancer and provide evidence that follicular carcinomas with PPAR gamma rearrangement are a distinct biological entity. The findings support a model in which separate genetic alterations initiate distinct pathways of oncogenesis in thyroid carcinoma subtypes.

Molecular cytogenetic parameters in Ewing sarcoma

To evaluate possible genomic instability and possible random aneuploidy, we applied comparative genomic hybridization and fluorescence in situ techniques, and evaluated telomerase activity in 16 cases of Ewing sarcoma (EWS) and compared the results to 7 controls. Common secondary aberrations (gains of chromosomes 8 and 12) were found in the study group. There was a direct correlation between the detection of random aneuploidy and development of tumor relapse (P = 0.0047). Other detectable abnormal parameters (secondary) and high telomerase activity were also more common among the cases with relapse but did not reach a statistical significance (probably because of the small sample size). In EWS, the detection of random aneuploidy seems to be a sensitive parameter in the prediction of tumor relapse.

Functional and phenotypic studies of two variants of a human mast cell line with a distinct set of mutations in the c-kit proto-oncogene

The human mast cell line (HMC)-1 cell line is growth-factor independent because of a constitutive activity of the receptor tyrosine kinase Kit. Such deregulated Kit activity has also been suggested causative in gastrointestinal stromal tumours (GISTs) and mastocytosis. HMC-1 is the only established continuously growing human mast cell line and has therefore been widely employed for in vitro studies of human mast cell biology. In this paper we describe two sublines of HMC-1, named HMC-1(560 ) and HMC-1(560,816 ), with different phenotypes and designated by the locations of specific mutations in the c-kit proto-oncogene. Activating mutations in the Kit receptor were characterized using the pyrosequencing trade mark method. Both sublines have a heterozygous T to G mutation at codon 560 in the juxtamembrane region of the c-kit gene causing an amino acid substitution of Gly-560 for Val. In contrast, only HMC-1(560,816) cells have the c-kitV816 mutation found in mast cell neoplasms causing an Asp-->Val substitution in the intracellular kinase domain. Kit was constitutively phosphorylated on tyrosine residues and associated with phosphatidylinositol 3'-kinase (PI 3-kinase) in both variants of HMC-1, but this did not lead to a constitutive phosphorylation of Akt or extracellular regulated protein kinase (ERK), which are signalling molecules normally activated by the interaction of stem cell factor (SCF) with Kit. The documentation and characterization of two sublines of HMC-1 cells provides both information on the biological consequences of mutations in Kit and recognition of the availability of what in reality are two distinct cultured human mast cell lines.

Biomarkers of genetic damage for cancer epidemiology

Cancer is a disease of altered gene expression involving a complex array of epigenetic events, gene mutation, chromosome rearrangements and altered chromosome number. The coincidence of genotoxic events with the induction of cancer has fueled great interest in molecular/cytogenetic epidemiological studies aimed at linking polymorphisms in genes for DNA repair and carcinogen metabolism and biomarkers of DNA/chromosome damage with cancer risk. These studies are now being expanded to include the role of dietary factors that are known to be important in DNA metabolism and repair such as folic acid, vitamin B12 and zinc. The use of DNA damage biomarkers as a surrogate for cancer would greatly facilitate our capacity to identify the most important risk factors for cancer however these biomarkers need validation. The Nordic and Italian prospective cohort studies have confirmed that elevated rates of chromosome aberrations in lymphocytes are predictive of cancer risk and similar studies are now underway to validate other biomarkers such as the micronucleus assay which are more practical to apply in the larger population setting. Validation of these biomarkers requires a thorough understanding of the importance of methodological, demographic, environmental and dietary variables and the ongoing HUMN project is a good example how this can be achieved for the micronucleus assay. The capacity to study human populations has opened up new opportunities to define acceptable DNA damage rates and to establish recommended dietary allowances for genomic stability. Controlling DNA damage rate to its possible minimum is likely to have an important impact in preventing cancer and other DNA damage-related degenerative diseases including ageing.

The role of chromosomal instability in tumor initiation

Chromosomal instability (CIN) is a defining characteristic of most human cancers. Mutation of CIN genes increases the probability that whole chromosomes or large fractions of chromosomes are gained or lost during cell division. The consequence of CIN is an imbalance in the number of chromosomes per cell (aneuploidy) and an enhanced rate of loss of heterozygosity. A major question of cancer genetics is to what extent CIN, or any genetic instability, is an early event and consequently a driving force for tumor progression. In this article, we develop a mathematical framework for studying the effect of CIN on the somatic evolution of cancer. Specifically, we calculate the conditions for CIN to initiate the process of colorectal tumorigenesis before the inactivation of tumor suppressor genes.

Allele-specific replication associated with aneuploidy in blood cells of patients with hematologic malignancies

We hypothesize that coordination between the two DNA parental sets in somatic cells is essential for the stability of the diploid genome, and that its disruption is associated with the many alterations observed in the various cancerous phenotypes. As coordination between two allelic counterparts is well exemplified by synchrony in replication timing, we examined, in blood cells of patients suffering from various hematologic malignancies, replication patterns of five loci. These loci were three cancer-implicated genes (TP53, AML1, and RB1) and two nontranscribed sequences engaged in chromosome segregation. All five loci normally display synchrony in allelic replication timing. In addition, in order to exemplify an asynchronous mode of allelic replication, we followed the replication of allelic counterparts of an imprinted gene (SNRPN), which is distinguished by its asynchronous mode of allelic replication (allele-specific replication). Allelic replication patterns were studied by fluorescence in situ hybridization (FISH), which has been shown to distinguish between nonreplicated and replicated regions of the genome in interphase cells, based on the structure of the specific hybridization signals that are being detected. Using the FISH replication assay we observed, for all loci which normally exhibit synchrony in allelic replication, loss of synchrony when present in blood cells of patients with hematologic malignancies. The loss of synchrony in allelic replication in patients' cells was accompanied by aneuploidy (chromosome losses and gains), the hallmark of cancer. We were able to reinstate the normal pattern of replication in the patients' cells by introducing an inhibitor of DNA methylation. It thus appears loss of allelic coordination is an epigenetic alteration characterizing cancer, which is easily identified by simple cytogenetic means and has a potential use in both cancer investigation and detection.

Enhancing the in vitro and in vivo detection of aneuploidy by fluorescence in situ hybridization with the use of bromodeoxyuridine as a proliferation marker

Aneuploidy is associated with spontaneous abortions, birth defects, and many types of human cancers. Currently there are few assays developed for the efficient detection of aneuploidy in vivo. However, with the recent availability of chromosome-specific DNA probes for the rat, fluorescence in situ hybridization (FISH) techniques could be used for the rapid and sensitive detection of aneuploidy in different tissue and cell types. In order to develop a system that can detect alterations in chromosome number in rat cells in vitro, we treated cultured rat lymphocytes with three aneugens-noscapine hydrochloride (0-150 microM) and vincristine and vinblastine sulfate (0-0.06 microM). 5-Bromo-2-deoxyuridine (BrdU; 1 microM) was added to the culture medium to allow proliferating and non-proliferating cells to be distinguished. To test this assay under in vivo conditions, 21-day-old male Sprague-Dawley rats were subcutaneously implanted with osmotic pumps that delivered BrdU (approximately 12 mg/kg per day) continuously. These rats were administered vinblastine sulfate (0, 0.5 and 1mg/kg) by intraperitoneal injection. The rat lymphocytes and hepatocytes incorporating BrdU were detected by immuno-fluorescent labeling, and FISH with a rat chromosome 4 probe was performed on the labeled and unlabeled cells. Highly significant increases in hyperdiploidy were seen in the replicating rat lymphocytes treated with noscapine, vincristine or vinblastine in vitro and in the rat hepatocytes treated with vinblastine in vivo. In contrast, no significant increase in hyperdiploidy was observed in the non-replicating cells. These results demonstrate that this BrdU-enhanced FISH assay with chromosome-specific rat probes can be used to efficiently detect numerical chromosomal aberrations in vitro and in vivo in slowly or moderately replicating rat tissues. The combination of BrdU-labeling and FISH allows the scoring of hyperdiploidy to be focused on the actively replicating cells, thereby increasing the sensitivity of the FISH technique.

Chromosomal biomarkers of genomic instability relevant to cancer

It is generally acknowledged that a crucial event in the initiation and evolution of cancer is the acquisition of a genomic instability phenotype. This review focuses on mechanisms of chromosomal instability including aneuploidy, chromosome rearrangement and breakage-fusion-bridge cycles. The role of micronutrient deficiency, such as folate deficiency, in the causation of chromosomal instability is briefly reviewed and the concept of recommended dietary allowances for genomic stability is introduced. In addition, the techniques for measuring the various chromosomal instability events are discussed with a focus on the cytokinesis-block micronucleus assay as an almost complete system for measuring these various genetic mishaps.

Functional inactivation of pRB results in aneuploid mammalian cells after release from a mitotic block

The widespread chromosome instability observed in tumors and in early stage carcinomas suggests that aneuploidy could be a prerequisite for cellular transformation and tumor initiation. Defects in tumor suppressors and genes that are part of mitotic checkpoints are likely candidates for the aneuploid phenotype. By using flow cytometric, cytogenetic, and immunocytochemistry techniques we investigated whether pRB deficiency could drive perpetual aneuploidy in normal human and mouse fibroblasts after mitotic checkpoint challenge by microtubule-destabilizing drugs. Both mouse and human pRB-deficient primary fibroblasts resulted, upon release from a mitotic block, in proliferating aneuploid cells possessing supernumerary centrosomes. Aneuploid pRB-deficient cells show an elevated variation in chromosome numbers among cells of the same clone. In addition, these cells acquired the capability to grow in an anchorage-independent way at the same extent as tumor cells did suggesting aneuploidy as an initial mutational step in cell transformation. Normal Mouse Embryonic Fibroblasts (MEFs) harboring LoxP sites flanking exon 19 of the Rb gene arrested in G2/M with duplicated centrosomes after colcemid treatment. However, these cells escaped the arrest and became aneuploid upon pRB ablation by CRE recombinase, suggesting pRB as a major component of a checkpoint that controls cellular ploidy.

Multiple centrosomes arise from tetraploidy checkpoint failure and mitotic centrosome clusters in p53 and RB pocket protein-compromised cells

A high degree of aneuploidy characterizes the majority of human tumors. Aneuploid status can arise through mitotic or cleavage failure coupled with failure of tetraploid G(1) checkpoint control, or through deregulation of centrosome number, thus altering the number of mitotic spindle poles. p53 and the RB pocket proteins are important to the control of G(1) progression, and p53 has previously been suggested as important to the control of centrosome duplication. We demonstrate here that neither suppression of p53 nor of the RB pocket protein family directly generates altered centrosome numbers in any of several mammalian primary cell lines. Instead, amplification of centrosome number occurs in two steps. The first step is failure to arrest at a G(1) tetraploidy checkpoint after failure to segregate the genome in mitosis, and the second step is clustering of centrosomes at a single spindle pole in subsequent tetraploid or aneuploid mitosis. The trigger for these events is mitotic or cleavage failure that is independent of p53 or RB status. Finally, we find that mouse embryo fibroblasts spontaneously enter tetraploid G(1), explaining the previous demonstration of centrosome amplification by p53 abrogation alone in these cells.

Damaged DNA and miscounted chromosomes: human T cell leukemia virus type I tax oncoprotein and genetic lesions in transformed cells

Genetic instability is a recurring theme in human cancers. Although the molecular mechanisms mediating this effect commonly observed in transformed cells are not completely understood, it has been proposed to involve either the loss of DNA repair capabilities or the loss of chromosomal stability. The transforming retrovirus human T cell leukemia virus type I (HTLV-I) encodes a viral oncoprotein Tax, which is believed to cause the genomic instability characteristic of HTLV-I-infected cells. This review focuses on the ability of HTLV-I Tax to disrupt the cellular processes of DNA repair and chromosomal segregation. The consequences of these effects as well as the evolutionary advantage this may provide to HTLV-I are discussed.

Aneuploidy theory explains tumor formation, the absence of immune surveillance, and the failure of chemotherapy

The autocatalyzed progression of aneuploidy accounts for all cancer-specific phenotypes, the Hayflick limit of cultured cells, carcinogen-induced tumors in mice, the age distribution of human cancer, and multidrug-resistance. Here aneuploidy theory addresses tumor formation. The logistic equation, phi(n)(+1) = rphi(n) (1 - phi(n)), models the autocatalyzed progression of aneuploidy in vivo and in vitro. The variable phi(n)(+1) is the average aneuploid fraction of a population of cells at the n+1 cell division and is determined by the value at the nth cell division. The value r is the growth control parameter. The logistic equation was used to compute the probability distribution for values of phi after numerous divisions of aneuploid cells. The autocatalyzed progression of aneuploidy follows the laws of deterministic chaos, which means that certain values of phi are more probable than others. The probability map of the logistic equation shows that: 1) an aneuploid fraction of at least 0.30 is necessary to sustain a population of cancer cells; and 2) the most likely aneuploid fraction after many population doublings is 0.70, which is equivalent to a DNA(index)=1.7, the point of maximum disorder of the genome that still sustains life. Aneuploidy theory also explains the lack of immune surveillance and the failure of chemotherapy.

Understanding cancer as a formless phenomenon

Complex living organisms possess qualities that cannot be reduced to the simple addition of quantities. Among such qualities are a specific form and a specific organization. Thinking about morphological aspects is a prime example of the qualitative approach to biological matters. Such a morphogenetic perspective has been continuously developed, both theoretically and experimentally, along the past century, even though it is now rather marginal within a mainstream dominated by molecular biology. However, the morphogenetic outlook can be applied to the understanding of complex biological phenomena, such as cancer. This phenomenon is currently explained as a cellular problem caused by specific gene mutations and/or specific loss of gene regulation. Nevertheless, cancer is a problem that affects the whole organism. Contemporary research based on the genetic paradigm of cancer causation has led to paradoxes and anomalies that cannot be explained within such a reductionist paradigm. Here it is proposed that real, non-experimental, sporadic cancer may be understood as a conflict between an organized morphology (the organism) and a part of such a morphology that drifts towards an amorphous state (the tumour). Thus, rare, sporadic cancer in children can be the result of early disruption of the developmental constraints before the organism has achieved its morphological maturity. While common sporadic cancer in aged individuals may ensue as a result of the weakening or exhaustion of the developmental constraints that determine the morphological stability of the organism, once the organism is past its reproductive prime.